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Integrated, Quad RF Transceiver with Observation Path
Data Sheet ADRV9010
Rev. E Document Feedback Information furnished by Analog Devices is believed to be accurate and reliable. However, no responsibility is assumed by Analog Devices for its use, nor for any infringements of patents or other rights of third parties that may result from its use. Specifications subject to change without notice. No license is granted by implication or otherwise under any patent or patent rights of Analog Devices. Trademarks and registered trademarks are the property of their respective owners.
One Technology Way, P.O. Box 9106, Norwood, MA 02062-9106, U.S.A.Tel: 781.329.4700 ©2019–2021 Analog Devices, Inc. All rights reserved. Technical Support www.analog.com
FEATURES 4 differential transmitters 4 differential receivers 2 observation receivers with 2 inputs each Center frequency
650 MHz to 3800 MHz (ADRV9010BBCZ) 650 MHz to 6000 MHz (ADRV9010BBCZ-A)
Maximum receiver bandwidth: 200 MHz Maximum transmitter bandwidth: 200 MHz Maximum transmitter synthesis bandwidth: 450 MHz Maximum observation receiver bandwidth: 450 MHz Fully integrated independent fractional-N radio frequency
synthesizers Fully integrated clock synthesizer Multichip phase synchronization for all local oscillators and
baseband clocks JESD204B/JESD204C digital interface
APPLICATIONS 3G/4G/5G TDD macro and small cell base stations TDD active antenna systems for advanced LTE and 5G
GENERAL DESCRIPTION The ADRV9010 is a highly integrated, radio frequency (RF) agile transceiver that offers four independently controlled transmitters, dedicated observation receiver inputs for monitoring each transmitter channel, four independently controlled receivers, integrated synthesizers, and digital signal processing functions to provide a complete transceiver solution. The device provides the high radio performance and low power consumption demanded by cellular infrastructure applications such as TDD-based small cell base station radios, macro 3G/4G/5G TDD systems, and TDD based massive multiple in/multiple out (MIMO) base stations. The ADRV9010BBCZ operates from 650 MHz to 3800 MHz, covering most of the licensed and unlicensed cellular bands. The ADRV9010BBCZ-A operates from 650 MHz to 6000 MHz.
The receiver subsystem consists of four independent, wide bandwidth, direct conversion receivers with state-of-the-art dynamic range. The four independent transmitters use an innovative direct conversion modulator that achieves high modulation accuracy with exceptionally low noise. The ADRV9010 device also includes two wide bandwidth, time shared observation path receivers with two inputs each for monitoring transmitter outputs.
The complete transceiver subsystem includes automatic and manual attenuation control, dc offset correction, quadrature error correction (QEC), and digital filtering, eliminating the need for these functions in the digital baseband. Other auxiliary functions such as analog-to-digital converters (ADCs), digital-to-analog converters (DACs), and general-purpose input/outputs (GPIOs) that provide an array of digital control options are also integrated.
To achieve a high level of RF performance, the transceiver includes five fully integrated phase-locked loops (PLLs). Two PLLs provide high performance, low power fractional-N RF synthesis for the transmitter and receiver signal paths. One fully integrated PLL also supports an independent local oscillator (LO) mode for the observation receiver. Another PLL generates the clocks needed for the converters and digital circuits and a fifth PLL provides the clock for the serial data interface. A multichip synchronization mechanism synchronizes the phases of all LOs and baseband clocks between multiple ADRV9010 chips. All voltage controlled oscillators (VCOs) and loop filter components are integrated and adjustable through the digital control interface.
The serial data interface consists of eight serializer lanes and eight deserializer lanes. The interface supports both the JESD204B and JESD204C standards, operating at data rates up to 16.22016 Gbps. The interface also supports interleaved mode for lower bandwidths, thus reducing the number of high speed data interface lanes to one. Both fixed and floating-point data formats are supported. The floating-point format allows internal automatic gain control (AGC) to be invisible to the demodulator device.
The ADRV9010 is powered directly from 1.0 V, 1.3 V, and 1.8 V regulators and is controlled via a standard serial peripheral interface (SPI). Comprehensive power-down modes are included to minimize power consumption in normal use. The ADRV9010 is packaged in a 14 mm × 14 mm, 289-ball chip scale ball grid array (CSP_BGA).
ADRV9010 Data Sheet
Rev. E | Page 2 of 115
TABLE OF CONTENTS Features .............................................................................................. 1
Applications ...................................................................................... 1
General Description ......................................................................... 1
Revision History ............................................................................... 2
Functional Block Diagram .............................................................. 3
Specifications .................................................................................... 4
Power Supply Specifications ..................................................... 17
Current Consumption ............................................................... 18
Digital Interface and Timing Specifications ........................... 19
Absolute Maximum Ratings ......................................................... 20
Junction Temperature ............................................................... 20
Reflow Profile .............................................................................. 20
Thermal Resistance .................................................................... 20
ESD Caution................................................................................ 20
Pin Configuration and Function Descriptions .......................... 21
Typical Performance Characteristics ........................................... 26
800 MHz Band ............................................................................ 26
1800 MHz Band .......................................................................... 40
2600 MHz Band .......................................................................... 54
3800 MHz Band .......................................................................... 68
4800 MHz Band .......................................................................... 82
5700 MHz Band .......................................................................... 96
Theory of Operation .................................................................... 110
General ....................................................................................... 110
Transmitter ............................................................................... 110
Receiver ..................................................................................... 110
Observation Receiver ............................................................... 110
Clock Input ............................................................................... 111
Synthesizers ............................................................................... 111
SPI Interface .............................................................................. 111
Power Supply Sequence ........................................................... 111
GPIO_x Pins ............................................................................. 112
Auxiliary Converters ............................................................... 112
JTAG Boundary Scan .............................................................. 112
Applications Information ........................................................... 113
Power Supply Sequence ........................................................... 113
Data Interface ........................................................................... 113
Outline Dimensions ..................................................................... 115
Ordering Guide ........................................................................ 115
REVISION HISTORY 1/2021—Revision E: Initial Version
Data Sheet ADRV9010
Rev. E | Page 3 of 115
FUNCTIONAL BLOCK DIAGRAM
ADC
LO3
LO1LO2
ADCDECIMATION,
pFIR,DC OFFSET,
QEC,TUNING,
OVERLOAD
DECIMATION,pFIR,AGC,
DC OFFSET,QEC,
TUNING,RSSI,
OVERLOAD
pFIR,LO LEAKAGE,
QEC,TUNING,
INTERPOLATION
JESD204B/JESD204C
SERIALINTERFACE
CONTROLINTERFACE
SPI PORT
GPIOAUXILIARY ADCAUXILIARY DAC
CLOCK GENERATIONAND
SYNCHRONIZATION
POWERMANAGEMENT
VDDA_1P8 GPIO_ANA_x
AUXADC_x
GPIO_x
VDIG_1P0
EXT_LO1±
DEVCLK±
SYSREF±
SPI_CLK
SPI_EN
SPI_DO
SPI_DIO
GPINT1
TEST_EN
SERDOUTA±
SERDINA±
SERDINB±
SERDINC±
SERDIND±
SERDINE±
SERDINF±
SERDING±
SERDINH±
SYNCOUT1±
SYNCOUT2±
SERDOUTB±
SERDOUTC±
SERDOUTD±
SERDOUTE±
SERDOUTF±
SERDOUTG±
SERDOUTH±
SYNCIN1±
SYNCIN2±
SYNCIN3±
RESET
ORX_CTRL_x
TXx_EN
RXx_EN
GPINT2
EXT_LO2±
RX3+RX3–
RX4+RX4–
RX1+RX1–
RX2+RX2–
TX3+TX3–
TX4+TX4–
TX1+TX1–
TX2+TX2–
ORX3+ORX3–
ORX4+ORX4–
ORX1+ORX1–
ORX2+ORX2–
NOTES1. VDDA_1P8 REPRESENTS VCONV1_1P8, VCONV2_1P8, VANA1_1P8, VANA2_1P8, VANA3_1P8, VANA4_1P8, AND VJVCO_1P8. VDDA_1P3 REPRESENTS VANA1_1P3, VANA2_1P3, VCONV1_1P3, VCONV2_1P3, VRFVCO1_1P3, VRFVCO2_1P3, VAUXVCO_1P3, VCLKVCO_1P3, VRFSYN1_1P3, VRFSYN2_1P3, VCLKSYN_1P3, VAUXSYN_1P3, VRXLO_1P3, AND VTXLO_1P3. VDDA_1P0 REPRESENTS VJSYN_1P0, VDES_1P0, VTT_DES, AND VSER_1P0.
VIF
VDDA_1P0
VDDA_1P3
RF SYNTHESIZERRF SYNTHESIZER
RF SYNTHESIZER
MICROPROCESSOR
ORx1/ORx2
900
DAC
DAC
Tx2
Tx1
900
LO1LO2
LO1
LO3
LO2
ADC
ADC
Rx2
Rx1
Rx1, Rx2, Tx1, Tx2, ORx1/ORx2
Rx3, Rx4, Tx3, Tx4, ORx3/ORx4
900
4
4
4
4
19
8
ADRV9010
20043-001
Figure 1.
ADRV9010 Data Sheet
Rev. E | Page 4 of 115
SPECIFICATIONS All specifications are verified using a Wenzel Associates Model 500-23867, 245.76 MHz voltage controlled crystal oscillator (VCXO) as the device clock, unless otherwise noted. Specifications are applicable over the lifetime of the device. Power supplies are as follows: VDDA_1P8 = 1.8 V, VIF = 1.8 V, VDDA_1P3 = 1.3 V, VDDA_1P0 = 1.0 V, and VDIG_1P0 = 1.0 V. VDDA_1P8 represents VCONV1_1P8, VCONV2_1P8, VANA1_1P8, VANA2_1P8, VANA3_1P8, VANA4_1P8, and VJVCO_1P8. VDDA_1P3 represents VANA1_1P3, VANA2_1P3, VCONV1_1P3, VCONV2_1P3, VRFVCO1_1P3, VRFVCO2_1P3, VAUXVCO_1P3, VCLKVCO_1P3, VRFSYN1_1P3, VRFSYN2_1P3, VCLKSYN_1P3, VAUXSYN_1P3, VRXLO_1P3, and VTXLO_1P3. VDDA_1P0 represents VJSYN_1P0, VDES_1P0, VTT_DES, and VSER_1P0. All RF specifications are based on measurements that include printed circuit board (PCB) and matching circuit losses, unless otherwise noted. Table 1. Parameter Symbol Min Typ Max Unit Test Conditions/Comments TRANSMITTERS (Tx)
Center Frequency 650 3800 MHz ADRV9010BBCZ 650 6000 MHz ADRV9010BBCZ-A Tx Synthesis Bandwidth 450 MHz Wider bandwidth for use in digital
processing algorithms Tx Large Signal
Bandwidth 200 MHz Zero-IF mode
Peak-to-Peak Gain Deviation
1.0 dB 450 MHz bandwidth, includes compensation by programmable finite impulse response (pFIR) filter
0.1 dB Any 20 MHz bandwidth span within the large signal bandwidth, includes compensation by pFIR filter
Deviation from Linear Phase
1 Degrees 450 MHz bandwidth
Maximum Output Power 0 dBFS, 1 MHz signal input, 50 Ω load, 0 dB Tx attenuation
800 MHz 6.4 dBm 1800 MHz 6.0 dBm 2600 MHz 6.1 dBm 3800 MHz 6.5 dBm 4800 MHz 6.0 dBm 5700 MHz 5.7 dBm
Power Control Range 32 dB Power Control Resolution 0.05 dB Attenuation Accuracy
Integral Nonlinearity (Gain)
INL 0.1 dB Valid over full power control range for any 4 dB step
Differential Nonlinearity (Gain)
DNL ±0.04 dB Monotonic
Output Power Temperature Slope
−4.5 mdB/°C Valid over full power control range
LO Delay Temperature Slope
1.05 ps/°C Valid over full power control range
Data Sheet ADRV9010
Rev. E | Page 5 of 115
Parameter Symbol Min Typ Max Unit Test Conditions/Comments Adjacent Channel
Leakage Power Ratio (ACLR) Long Term Evolution (LTE)
20 MHz LTE at −12 dBFS
800 MHz −67 dB 1800 MHz −67 dB 2600 MHz −67 dB 3800 MHz −67 dB 4800 MHz −65 dB 5700 MHz −65 dB
Inband Noise Floor −154.5 dBFS/Hz 0 dB attenuation, inband noise falls 1 dB for each decibel of attenuation for attenuation settings between 0 dB and 20 dB
Interpolation Images −76 dBc Tx to Tx Isolation: All Tx
Output Effects on All Other Tx Outputs
800 MHz 80 dB 1800 MHz 76 dB 2600 MHz 74 dB 3800 MHz 70 dB 4800 MHz 70 dB 5700 MHz 64 dB
Image Rejection Within Large Signal
Bandwidth QEC active up to 20 dB of attenuation,
continuous wave (CW) tone swept across the large signal bandwidth
800 MHz 75 dB 1800 MHz 75 dB 2600 MHz 76 dB 3800 MHz 65 dB 4800 MHz 65 dB 5700 MHz 61 dB
Beyond Large Signal Bandwidth
Assumes that distortion power density is 25 dB less than the desired power density
800 MHz 40 dB 1800 MHz 38 dB 2600 MHz 34 dB 3800 MHz 37 dB 4800 MHz 37 dB 5700 MHz 37 dB
Output Impedance ZOUT 50 Ω Differential and nominal Maximum Output Load
Voltage Standing Wave Ratio (VSWR)
3 Maximum value to ensure adequate calibration
Output Return Loss 10 dB
ADRV9010 Data Sheet
Rev. E | Page 6 of 115
Parameter Symbol Min Typ Max Unit Test Conditions/Comments Output Third-Order
Intercept Point OIP3 0 dB Tx attenuation, 90 MHz and
95 MHz tones 800 MHz 30 dBm 1800 MHz 30 dBm 2600 MHz 29 dBm 3800 MHz 27 dBm 4800 MHz 27 dBm 5700 MHz 27 dBm
Carrier Leakage With LO leakage correction active, 0 dB Tx attenuation; scales dB for dB with attenuation
Carrier Offset from LO −82 dBFS/MHz Carrier on the LO −71 dBFS/MHz Measured using an LTE 20 MHz signal
Error Vector Magnitude EVM PLL optimized for narrow-band noise, measured using LTE 20 MHz signal
800 MHz 0.36 % 50 kHz PLL bandwidth 1800 MHz 0.60 % 50 kHz PLL bandwidth 2600 MHz 0.42 % 500 kHz PLL bandwidth 3800 MHz 0.50 % 200 kHz PLL bandwidth 4800 MHz 0.67 % 400 kHz PLL bandwidth 5700 MHz 0.84 % 500 kHz PLL bandwidth
Transmitter TDD Parameters
Time from SPI_EN Going High to Change in Tx Attenuation
tSCH 12 ns
Time Between Consecutive Microattenuation Steps
tACH 20 ns A large change in attenuation may be broken up into a series of smaller attenuation changes
Attenuation Overshoot During Transition
0.1 dB
Change in Attenuation per Microstep
0.1 dB
RECEIVERS (Rx) Center Frequency 650 3800 MHz ADRV9010BBCZ 650 6000 MHz ADRV9010BBCZ-A Gain Range 30 dB Attenuation Accuracy
Analog Gain Step 0.5 dB Attenuator steps from 0 dB to 6 dB 1 dB Attenuator steps from 6 dB to 30 dB Residual Gain Step
Error 0.1 dB
Gain Temperature Slope
−6.4 mdB/°C
Internal LO Delay Temperature Slope
1.0 ps/°C
Data Sheet ADRV9010
Rev. E | Page 7 of 115
Parameter Symbol Min Typ Max Unit Test Conditions/Comments Frequency Response
Peak-to-Peak Gain Deviation
1 dB 200 MHz bandwidth, includes compensation by pFIR filter
0.2 dB Any 20 MHz span, includes compensation by pFIR filter
Rx Bandwidth 200 MHz Rx Alias Band Rejection 80 dB Due to digital filters Maximum Useable
Input Level PHIGH This CW signal level corresponds to
the signal level seen at the matching circuit input that produces −2 dBFS at the digital output with 0 dB channel attenuation
800 MHz −12.7 dBm 1800 MHz −12.2 dBm 2600 MHz −12 dBm 3800 MHz −12 dBm 4800 MHz −11.3 dBm 5700 MHz −10.3 dBm
Maximum Source VSWR 3 Input Impedance ZIN 100 Ω Differential Input Port Return Loss 10 dB Noise Figure 0 dB attenuation at Rx port
800 MHz 11 dB 1800 MHz 11.5 dB 2600 MHz 11.9 dB 3800 MHz 12 dB 4800 MHz 12.5 dB 5700 MHz 14.5 dB
Noise Figure Ripple 1.5 dB At band edge Second-Order Input
Intermodulation Intercept Point
IIP2 0 dB attenuation, complex
800 MHz 65 dBm 1800 MHz 65 dBm 2600 MHz 68 dBm 3800 MHz 62 dBm 4800 MHz 58 dBm 5700 MHz 58 dBm
Third-Order Input Intermodulation Intercept Point, Difference Product
Wideband WB-IIP3DIFF Two tones near the band edge; PHIGH − 9 dB per tone
800 MHz 14.5 dBm 1800 MHz 17 dBm 2600 MHz 17 dBm 3800 MHz 16.5 dBm 4800 MHz 17 dBm 5700 MHz 18 dBm
ADRV9010 Data Sheet
Rev. E | Page 8 of 115
Parameter Symbol Min Typ Max Unit Test Conditions/Comments Midband MB-IIP3DIFF Two tones near middle of the band;
PHIGH − 9 dB per tone 800 MHz 18.8 dBm 1800 MHz 27 dBm 2600 MHz 22 dBm 3800 MHz 22 dBm 4800 MHz 22 dBm 5700 MHz 20 dBm
Wideband WB-IIP3SUM Two tones approximately bandwidth/6 offset from the LO; PHIGH − 9 dB per tone
800 MHz 18 dBm 1800 MHz 20 dBm 2600 MHz 21 dBm 3800 MHz 23 dBm 4800 MHz 22 dBm 5700 MHz 22 dBm
Second-Order Harmonic Distortion
Maximum Input HD2MAX −72 dBc PHIGH CW signal, harmonic distortion tones falling within 100 MHz of the LO
Recommended Input HD2 −75 dBc PHIGH − 3 dB CW signal, harmonic distortion tones falling within 100 MHz of the LO
Third-Order Harmonic Distortion
Maximum Input HD3MAX −66 dBc PHIGH CW signal, harmonic distortion tones falling within 100 MHz of the LO
Recommended Input HD3 −72 dBc PHIGH − 3 dB CW signal, harmonic distortion tones falling within 100 MHz of the LO
Fourth-Order Harmonic Distortion
Maximum Input HD4MAX −90 dBc PHIGH CW signal, harmonic distortion tones falling within 100 MHz of the LO
Recommended Input HD4 −90 dBc PHIGH − 3 dB CW signal, harmonic distortion tones falling within 100 MHz of the LO
Fifth-Order Harmonic Distortion
Maximum Input HD5MAX −87 dBc PHIGH CW signal, harmonic distortion tones falling within 100 MHz of the LO
Recommended Input HD5 −90 dBc PHIGH − 3 dB CW signal, harmonic distortion tones falling within 100 MHz of the LO
Image Rejection 75 dB QEC active, within 200 MHz Rx bandwith
Rx to Rx Signal Isolation 800 MHz 75 dB 1800 MHz 69 dB 2600 MHz 69 dB 3800 MHz 64 dB 4800 MHz 61 dB 5700 MHz 58 dB
Data Sheet ADRV9010
Rev. E | Page 9 of 115
Parameter Symbol Min Typ Max Unit Test Conditions/Comments Rx Band Spurs
Referenced to RF Input at Maximum Gain
−95 dBm No more than one spur at this level per 10 MHz of Rx bandwidth; excludes converter clock spurs; no input signal applied
Spurious-Free Dynamic Range
SFDR 81 dBc PHIGH CW signal anywhere inside the band ±20 MHz, excludes harmonic distortion products
Rx Input LO Leakage at Maximum Gain
Leakage decreased dB for dB with attenuation for first 12 dB
800 MHz −65 dBm 1800 MHz −63 dBm 2600 MHz −65 dBm 3800 MHz −59 dBm 4800 MHz −53 dBm 5700 MHz −55 dBm
Tx to Rx Signal Isolation All Tx output effects on all Rx inputs 800 MHz 80 dB 1800 MHz 73 dB 2600 MHz 73 dB 3800 MHz 72 dB 4800 MHz 68 dB 5700 MHz 66 dB
OBSERVATION RECEIVER (ORx)
Center Frequency 650 3800 MHz ADRV9010BBCZ 650 6000 MHz ADRV9010BBCZ-A
Gain Range 30 dB Analog Gain Step 0.5 dB For attenuator steps from 0 dB to
6 dB Peak-to-Peak Gain
Deviation 1 dB 450 MHz RF bandwidth,
compensation by pFIR filter 0.1 dB Any 20 MHz bandwidth span,
compensation by pFIR filter Deviation from Linear
Phase 1 Degrees 450 MHz RF bandwidth
ORx Bandwidth 450 MHz ORx Alias Band
Rejection 60 dB Due to digital filters
Maximum Useable Input Level
PHIGH This CW signal level corresponds to the signal level seen at the matching circuit input that produces −2 dBFS at the digital output with 0 dB channel attenuation
800 MHz −12.7 dBm 1800 MHz −12.2 dBm 2600 MHz −10.6 dBm 3800 MHz −12.0 dBm 4800 MHz −11.3 dBm 5700 MHz −9.0 dBm
Input Impedance ZIN 100 Ω Differential Input Source VSWR 3 Input Port Return Loss 10 dB
ADRV9010 Data Sheet
Rev. E | Page 10 of 115
Parameter Symbol Min Typ Max Unit Test Conditions/Comments Integrated Noise
450 MHz Bandwidth −58.5 dBFS Sample rate at maximum value integrated from 500 kHz to 225 MHz, no input signal
491.52 MHz Bandwidth (Nyquist)
−57.5 dBFS Sample rate at maximum value integrated from 500 kHz to 245.76 MHz, no input signal
Second-Order Input Intermodulation Intercept Point
IIP2 Maximum ORx gain; PHIGH – 11 dB per tone
800 MHz 53 dBm 1800 MHz 53 dBm 2600 MHz 65 dBm 3800 MHz 48 dBm 4800 MHz 45 dBm 5700 MHz 55 dBm
Third-Order Input Intermodulation Intercept Point
Maximum ORx gain; PHIGH – 11 dB per tone
Narrow Band IIP3NB IM3 product < 130 MHz at baseband; PHIGH – 11 dB per tone, 491.52 MSPS
800 MHz 12 dBm 1800 MHz 15 dBm 2600 MHz 18 dBm 3800 MHz 17 dBm 4800 MHz 17 dBm 5700 MHz 18 dBm
Wide Band IIP3WB IM3 products > 130 MHz at baseband; PHIGH − 11 dB per tone, 491.52 MSPS
800 MHz 9 dBm 1800 MHz 12 dBm 2600 MHz 12 dBm 3800 MHz 11 dBm 4800 MHz 11 dBm 5700 MHz 13 dBm
Third-Order Intermodulation Product
Narrow Band IM3NB IM3 product < 130 MHz at baseband; two tones, each at PHIGH − 11 dB, 491.52 MSPS
800 MHz −71.5 dBc 1800 MHz −76.5 dBc 2600 MHz −80 dBc 3800 MHz −80 dBc 4800 MHz −77 dBc 5700 MHz −76 dBc
Data Sheet ADRV9010
Rev. E | Page 11 of 115
Parameter Symbol Min Typ Max Unit Test Conditions/Comments Wide Band IM3WB IM3 product > 130 MHz at baseband;
two tones, each at PHIGH – 11 dB, 491.52 MSPS
800 MHz −65.5 dBc 1800 MHz −70.5 dBc 2600 MHz −67 dBc 3800 MHz −68 dBc 4800 MHz −65 dBc 5700 MHz −66 dBc
Fifth-Order Intermodulation Product
Narrow Band IM5NB IM5 product < 130 MHz at baseband; two tones, each at PHIGH − 11 dB, 491.52 MSPS
800 MHz −91 dBc 1800 MHz −96 dBc 2600 MHz −85 dBc 3800 MHz −82 dBc 4800 MHz −82 dBc 5700 MHz −78 dBc
Wide Band IM5WB IM5 product > 130 MHz at baseband; two tones, each at PHIGH − 11 dB, 491.52 MSPS
800 MHz −87 dBc 1800 MHz −85 dBc 2600 MHz −85 dBc 3800 MHz −73 dBc 4800 MHz −73 dBc 5700 MHz −78 dBc
Seventh-Order Intermodulation Product
Narrow Band IM7NB IM7 product < 130 MHz at baseband; two tones, each at PHIGH − 11 dB, 491.52 MSPS
800 MHz −74 dBc 1800 MHz −79 dBc 2600 MHz −77 dBc 3800 MHz −71 dBc 4800 MHz −71 dBc 5700 MHz −74 dBc
Wide Band IM7WB IM7 product > 130 MHz at baseband; two tones, each at PHIGH − 11 dB, 491.52 MSPS
800 MHz −79 dBc 1800 MHz −79 dBc 2600 MHz −80 dBc 3800 MHz −71 dBc 4800 MHz −71 dBc 5700 MHz −84 dBc
ADRV9010 Data Sheet
Rev. E | Page 12 of 115
Parameter Symbol Min Typ Max Unit Test Conditions/Comments Spurious-Free Dynamic
Range SFDR 64 dB Nonintermodulation related spurs;
does not include harmonic distortion; input set at PHIGH − 8 dB
Second-Order Harmonic Distortion
HD2 Input set at PHIGH − 8 dB
Inband −80 dBc Inband harmonic distortion falls within ±100 MHz
Out of Band −73 dBc Out of band harmonic distortion falls within ±225 MHz
Third-Order Harmonic Distortion
HD3 Input set at PHIGH − 8 dB
Inband −70 dBc Harmonic distortion falls within ±100 MHz
Out of Band −65 dBc Harmonic distortion falls within ±225 MHz
Image Rejection After online tone calibration, QEC active
Within Large Signal Bandwidth
75 dB
Outside Large Signal Bandwidth
75 dB
Tx to ORx Signal Isolation All Tx output effects on all ORx inputs
800 MHz 90 dB 1800 MHz 85 dB 2600 MHz 88 dB 3800 MHz 88 dB 4800 MHz 77 dB 5700 MHz 76 dB
LO SYNTHESIZER LO1, LO2 LO Frequency Step 7.3 Hz 1.6 GHz to 3.2 GHz, 245.76 MHz phase
frequency detector (PFD) frequency LO Spectral Purity −80 dBc Integrated Phase Noise Integrated from 1 kHz to 100 MHz
Narrow Bandwidth Optimized
PLL optimized to minimize phase noise at offsets > 200 kHz
800 MHz LO 0.12 °rms 1800 MHz LO 0.27 °rms 2600 MHz LO 0.66 °rms 3800 MHz LO 0.53 °rms 4800 MHz LO 0.91 °rms 5700 MHz LO 1.57 °rms
Wide Bandwidth Optimized
PLL bandwidth optimized for integrated phase noise and phase noise at offsets > 1 MHz
800 MHz LO 0.07 °rms 1800 MHz LO 0.11 °rms 2600 MHz LO 0.17 °rms 3800 MHz LO 0.26 °rms 4800 MHz LO 0.30 °rms 5700 MHz LO 0.42 °rms
Data Sheet ADRV9010
Rev. E | Page 13 of 115
Parameter Symbol Min Typ Max Unit Test Conditions/Comments Spot Phase Noise,
Narrow Band PLL optimized to minimize phase
noise at offsets > 200 kHz 800 MHz LO
100 kHz Offset −115 dBc/Hz 1 MHz Offset −141 dBc/Hz 10 MHz Offset −162 dBc/Hz
1800 MHz LO 100 kHz Offset −107 dBc/Hz 200 kHz Offset −115 dBc/Hz 400 kHz Offset −123 dBc/Hz 600 kHz Offset −128 dBc/Hz 800 kHz Offset −131 dBc/Hz 1.2 MHz Offset −136 dBc/Hz 1.8 MHz Offset −140 dBc/Hz 6 MHz Offset −151 dBc/Hz 10 MHz Offset −156 dBc/Hz
2600 MHz LO 100 kHz Offset −97 dBc/Hz 1 MHz Offset −124 dBc/Hz 10 MHz Offset −150 dBc/Hz
3800 MHz LO 100 kHz Offset −100 dBc/Hz 1 MHz Offset −126 dBc/Hz 10 MHz Offset −149 dBc/Hz
4800 MHz LO 100 kHz Offset −94 dBc/Hz 1 MHz Offset −120 dBc/Hz 10 MHz Offset −145 dBc/Hz
5700 MHz LO 100 kHz Offset −89 dBc/Hz 1 MHz Offset −115 dBc/Hz 10 MHz Offset −141 dBc/Hz
Spot Phase Noise, Wide Band
PLL bandwidth optimized for integrated phase noise and phase noise at offsets > 1 MHz
800 MHz LO 100 kHz Offset −114 dBc/Hz 1 MHz Offset −141 dBc/Hz 10 MHz Offset −162 dBc/Hz
1800 MHz LO 100 kHz Offset −112 dBc/Hz 1 MHz Offset −133 dBc/Hz 10 MHz Offset −156 dBc/Hz
2600 MHz LO 100 kHz Offset −112 dBc/Hz 1 MHz Offset −120 dBc/Hz 10 MHz Offset −149 dBc/Hz
3800 MHz LO 100 kHz Offset −104 dBc/Hz 1 MHz Offset −125 dBc/Hz 10 MHz Offset −149 dBc/Hz
ADRV9010 Data Sheet
Rev. E | Page 14 of 115
Parameter Symbol Min Typ Max Unit Test Conditions/Comments 4800 MHz LO
100 kHz Offset −106 dBc/Hz 1 MHz Offset −117 dBc/Hz 10 MHz Offset −144 dBc/Hz
5700 MHz LO 100 kHz Offset −104 dBc/Hz 1 MHz Offset −112 dBc/Hz 10 MHz Offset −140 dBc/Hz
AUXILIARY SYNTHESIZER LO3 LO Frequency Step 1.8 Hz 1.625 GHz to 3.25 GHz, 61.44 MHz
PFD frequency LO Spectral Purity −65 dBc |fRFLO − fAUXLO|1 > 15 MHz Integrated Phase Noise Integrated from 1 kHz to 100 MHz,
PLL bandwidth optimized for integrated phase noise
800 MHz LO 0.18 °rms 1800 MHz LO 0.22 °rms 2600 MHz LO 0.46 °rms 3800 MHz LO 0.43 °rms 4800 MHz LO 0.70 °rms 5700 MHz LO 1.12 °rms
Spot Phase Noise 800 MHz LO
100 kHz Offset −112 dBc/Hz 1 MHz Offset −121 dBc/Hz 10 MHz Offset −141 dBc/Hz
1800 MHz LO 100 kHz Offset −110 dBc/Hz 1 MHz Offset −120 dBc/Hz 10 MHz Offset −134 dBc/Hz
2600 MHz LO 100 kHz Offset −103 dBc/Hz 1 MHz Offset −114 dBc/Hz 10 MHz Offset −132 dBc/Hz
3800 MHz LO 100 kHz Offset −104 dBc/Hz 1 MHz Offset −114 dBc/Hz 10 MHz Offset −128 dBc/Hz
4800 MHz LO 100 kHz Offset −100 dBc/Hz 1 MHz Offset −110 dBc/Hz 10 MHz Offset −127 dBc/Hz
5700 MHz LO 100 kHz Offset −95 dBc/Hz 1 MHz Offset −106 dBc/Hz 10 MHz Offset −126 dBc/Hz
Data Sheet ADRV9010
Rev. E | Page 15 of 115
Parameter Symbol Min Typ Max Unit Test Conditions/Comments LO PHASE
SYNCHRONIZATION
Initial Phase Synchronization Accuracy
0.9 ps
EXTERNAL LO INPUT Input Frequency fEXTLO 1600 12000 MHz Input frequency must be 2× the
desired frequency for LO frequency (fLO)2 ≥ 1 GHz and 4× the desired fLO for fLO < 1 GHz
Input Signal Power −6 0 +6 dBm 50 Ω matching at the source Input Signal Differential
Phase Balance 15 Degrees To ensure adequate quadrature error
correction Input Signal Differential
Amplitude Balance 2 dB
Input Signal Duty Cycle Error
2 %
CLOCK SYNTHESIZER 4915.2 MHz Sample Clock
Integrated Phase Noise
0.69 °rms 1 kHz to 10 MHz, PLL bandwidth optimized for low jitter
Spot Phase Noise PLL bandwidth optimized for integrated phase noise
100 kHz Offset −96 dBc/Hz 1 MHz Offset −113 dBc/Hz 10 MHz Offset −140 dBc/Hz
3932.16 MHz Sample Clock
Integrated Phase Noise
0.89 °rms 1 kHz to 10 MHz, PLL bandwidth optimized to minimize phase noise at offsets > 200 kHz
Spot Phase Noise PLL bandwidth optimized to minimize phase noise at offsets > 200 kHz
100 kHz Offset −92 dBc/Hz 1 MHz Offset −120 dBc/Hz 10 MHz Offset −143 dBc/Hz
REFERENCE CLOCK (DEVCLK± SIGNAL)
Frequency Range 15 1000 MHz Signal Level
(Differential) 0.2 1.0 V p-p AC-coupled, common-mode voltage
internally supplied; for best spurious performance and to meet the specified PLL performance parameters, use a 1 V p-p input clock
SYSTEM REFERENCE INPUTS SYSREF+, SYSREF−
Logic Compliance LVDS/LVPECL Differential Input Voltage 400 800 1800 mV p-p External 100 Ω termination Input Common-Mode
Voltage 0.675 2.0 V
Input Resistance (Differential)
18 kΩ
Input Capacitance (Differential)
1 pF
ADRV9010 Data Sheet
Rev. E | Page 16 of 115
Parameter Symbol Min Typ Max Unit Test Conditions/Comments AUXILIARY CONVERTERS
ADC Resolution 10 Bits Input Voltage
Minimum 0.05 V Maximum 0.95 V
DAC Resolution 12 Bits Output Voltage:
AUXDAC_0
Minimum 0.2 V Maximum VDDA_1P8 −
0.25 V
Output Voltage: AUXDAC_1 to AUXDAC_7
Minimum 0.1 V Maximum VDDA_1P8 −
0.1 V
Drive Capability 10 mA DIGITAL SPECIFICATIONS:
SINGLE-ENDED SIGNALS Applies to the following pins:
GPIO_x, GPINTx, TXx_EN, RXx_EN, ORX_CTRL_x, TEST_EN, RESET, SPI_EN, SPI_CLK, SPI_DO, and SPI_DIO
Logic Inputs Input Voltage
High Level VIF × 0.65 VIF + 0.18 V Low Level −0.30 VIF × 0.35 V
Input Current High Level −10 +10 μA Low Level −10 +10 μA
Logic Outputs Output Voltage
High Level VIF − 0.45 V Low Level 0.45 V
Drive Capability 10 mA DIGITAL SPECIFICATIONS:
DIFFERENTIAL SIGNALS Applies to the SYNCINx± and
SYNCOUTx± pins Logic Inputs
Input Voltage Range 825 1675 mV Each differential input in the pair Input Differential
Voltage Threshold −100 +100 mV
Receiver Differential Input Impedance
100 Ω Internal termination enabled
Data Sheet ADRV9010
Rev. E | Page 17 of 115
Parameter Symbol Min Typ Max Unit Test Conditions/Comments Logic Outputs
Output Voltage High 1375 mV Low 1025 mV Differential 225 mV Offset 1200 mV
DIGITAL SPECIFICATIONS: VDDA_1P8 REFERENCED SIGNALS
Applies to the GPIO_ANA_x pin
Logic Inputs Input Voltage
High Level VDDA_1P8 × 0.65
VDDA_1P8 + 0.18
V
Low Level −0.30 VDDA_1P8 × 0.35
V
Input Current High Level −10 +10 μA Low Level −10 +10 μA
Logic Outputs Output Voltage High Level VDDA_1P8
− 0.45 V
Low Level 0.45 V Drive Capability 10 mA
1 fRFLO is the frequency of the RF LO synthesizer and fAUXLO is the frequency of the auxiliary synthesizer. 2 fLO is the frequency of the internal local oscillator generator.
POWER SUPPLY SPECIFICATIONS
Table 2. Parameter Min Typ Max Unit Test Conditions/Comments SUPPLY CHARACTERISTICS Voltage range requirements must be met at each ball input for the respective
voltage supply rail VDDA_1P0 Supply 0.95 1.0 1.05 V VDIG_1P0 Supply 0.95 1.0 1.05 V VDDA_1P3 Supply 1.235 1.3 1.365 V VDDA_1P8 Supply 1.71 1.8 1.89 V VIF Supply 1.71 1.8 1.89 V
ADRV9010 Data Sheet
Rev. E | Page 18 of 115
CURRENT CONSUMPTION TDD Operation (Typical Values)
Table 3. TDD Mode: 4 Rx Channels Enabled, Maximum Gain Supply (A)
Total Average Power (W) 75% Tx, 25% Rx Average Power (W) Profile Conditions1 1.0 V 1.3 V 1.8 V USE CASE 26 NONLINK SHARING (16 BITS) 1.750 2.197 0.241 5.048 5.456
491.52 MSPS Tx/ORx Data Rate 245.76 MSPS Rx Data Rate 245.76 MHz Device Clock
USE CASE 14 LINK SHARING (12 BITS) 1.570 2.184 0.271 4.907 5.491 491.52 MSPS Tx/ORx Data Rate 245.76 MSPS Rx Data Rate 245.76 MHz Device Clock
USE CASE 47 LINK SHARING (16 BITS) 1.409 2.210 0.245 4.731 5.134 491.52 MSPS Tx/ORx Data Rate 245.76 MSPS Rx Data Rate 245.76 MHz Device Clock
1 All current measurements made at room temperature without a heat sink.
Table 4. TDD Mode: 4 Tx and 1 ORx Channels Enabled, 0 dB Attenuation, Maximum Gain Supply (A)
Total Average Power (W) 75% Tx, 25% Rx Average Power (W) Profile Conditions1 1.0 V 1.3 V 1.8 V USE CASE 26 NONLINK SHARING (16 BITS) 1.731 2.088 0.633 5.592 5.456
491.52 MSPS Tx/ORx Data Rate 245.76 MSPS Rx Data Rate 245.76 MHz Device Clock
USE CASE 14 LINK SHARING (12 BITS) 1.796 2.061 0.668 5.686 5.491 491.52 MSPS Tx/ORx Data Rate 245.76 MSPS Rx Data Rate 245.76 MHz Device Clock
USE CASE 47 LINK SHARING (16 BITS) 1.419 2.081 0.631 5.269 5.134 491.52 MSPS Tx/ORx Data Rate 245.76 MSPS Rx Data Rate 245.76 MHz Device Clock
1 All current measurements made at room temperature without a heatsink.
Data Sheet ADRV9010
Rev. E | Page 19 of 115
DIGITAL INTERFACE AND TIMING SPECIFICATIONS
Table 5. Parameter Symbol Min Typ Max Unit Test Conditions/Comments SPI TIMING
Write SPI_CLK Period tCP 40 100 ns SPI_CLK High Pulse Width tMP 10 ns SPI_EN Setup to First SPI_CLK Rising Edge tSC 4 ns Last SPI_CLK Falling Edge to SPI_EN Hold tHC 0 ns SPI_DIO Data Input Setup to SPI_CLK tS 4 ns SPI_DIO Data Input Hold to SPI_CLK tH 0 ns SPI_CLK Falling Edge to Output Data Delay (3- or
4-Wire Mode) tCO 10 16 ns
Bus Turnaround Time After Baseband Processor Drives Last Address Bit
tHZM tH tCO ns
Bus Turnaround Time After ADRV9010 Drives Last Address Bit
tHZS 0 tCO ns
Byte to Byte Delay Time tINT 400 ns Pause duration between any two bytes of the 3-byte operation (write or read)
DIGITAL TIMING TXx_EN Pulse Width1 10 μs RXx_EN Pulse Width1 10 μs ORX_CTRL_x Pulse Width2 10 μs TXx_EN to Valid Data1 2 μs RXx_EN to Valid Data1 2 μs ORX_CTRL_x to Valid Data2 3 μs
JESD204B/JESD204C DATA OUTPUT INTERFACE Unit Interval UI 61.65 1000 ps Data Rate per Channel (Nonreturn to Zero (NRZ)) 1000 16220 Mbps Rise Time tR 17 26 ps 20% to 80% in 100 Ω load Fall Time tF 17 26 ps 20% to 80% in 100 Ω load Output Common-Mode Voltage VCM 0 1.8 V AC-coupled Termination Voltage = 1.0 V VTT 735 1135 mV DC-coupled Differential Output Voltage VDIFF 360 466 770 mV Short-Circuit Current IDSHORT −100 +100 mA Differential Termination Impedance ZRDIFF 80 100 120 Ω SYSREF_IN Signal Setup Time to DEVCLK± Signal tS 200 ps SYSREF_IN Signal Hold Time to DEVCLK± Signal tH 200 ps
JESD204B/JES204C DATA INPUT INTERFACE Unit Interval UI 61.65 1000 ps Data Rate per Channel (NRZ) 1000 16220 Mbps Input Common-Mode Voltage VCM 0.05 1.65 V AC-coupled
VTT = 1.0 V 720 1200 mV DC-coupled (not recommended) Differential Input Voltage VDIFF 125 750 mV VTT Source Impedance ZTT 1.2 30 Ω Differential Termination Impedance ZRDIFF 80 106 120 Ω VTT
AC-Coupled 1.27 1.33 V DC-Coupled 1.14 1.26 V
1 Where x represents the channel number. 2 Where x represents A, B, C, or D.
ADRV9010 Data Sheet
Rev. E | Page 20 of 115
ABSOLUTE MAXIMUM RATINGS Table 6. Parameter Rating VDDA_1P8 to VSSA −0.3 V to +2.2 V VDDA_1P3 to VSSA −0.2 V to +1.5 V VDDA_1P0, VDIG_1P0 to VSSD, VSSA −0.2 V to +1.2 V VIF Referenced Logic Inputs and
Outputs to VSSD −0.3 V to VIF + 0.3 V
JESD204B Logic Outputs to VSSA −0.3 V to VSER_1P0 JESD204B Logic Inputs to VSSA −0.3 V to VDES_1P0 Input Current to Any Pin Except Supplies ±10 mA Maximum Input Power into RF Ports See Table 8 for limits
vs. survival time Junction Temperature Range1 −40°C to +110°C Storage Temperature Range −65°C to +150°C
1 The maximum junction temperature for continuous operation is 110°C. See the Junction Temperature section for more details.
Stresses at or above those listed under Absolute Maximum Ratings may cause permanent damage to the product. This is a stress rating only; functional operation of the product at these or any other conditions above those indicated in the operational section of this specification is not implied. Operation beyond the maximum operating conditions for extended periods may affect product reliability.
JUNCTION TEMPERATURE The maximum junction temperature for continuous operation is 110°C. Although operation up to 125°C is supported, specification compliance is only guaranteed up to 110°C. To avoid a reduction in operating lifetime by operating above 110°C, the device must operate at a temperature less than 110°C for a period (tUNITS) determined by the following equation:
tUNITS < 110 = (AFT > 110 − 1)/(1 − AFT < 110)
where AFT > 110 and AFT < 110 are acceleration factors obtained from Table 7.
For example, if the device operates at 125°C for 1 hour, expected device lifetime is maintained if the device operates at 100°C for 4.5 hours to offset the time operating above 110°C.
Table 7. Acceleration Factors for High Temperature Operation Operating Junction Temperature (°C) Acceleration Factor (AF) 125 3.75 120 2.44 115 1.57 110 1.00 105 0.63 100 0.39 95 0.24 90 0.14
Table 8. Maximum Input Power into RF Ports vs. Lifetime
RF Port Input Power, CW Signal (dBm)
Lifetime Gain = −30 dB Gain = 0 dB
7 >10 years >10 years 10 >10 years 20,000 hours 20 >10 years 14 hours 23 >10 years 110 minutes 25 >7 years 60 minutes
REFLOW PROFILE The ADRV9010 reflow profile is in accordance with the JEDEC JESD20 criteria for Pb-free devices. The maximum reflow temperature is 260°C.
THERMAL RESISTANCE Thermal resistance values specified in Table 9 are calculated based on JEDEC specifications (unless specified otherwise) and should be used in compliance with JESD51-12. Note that using enhanced heat removal techniques (PCB, heat sink, air flow, and so forth) improves thermal resistance.
θJA is the natural convection junction to ambient thermal resistance measured in a one cubic foot sealed enclosure.
θJC is the junction to case thermal resistance.
Table 9. Thermal Resistance Values Package Type θJA θJC Unit BC-289-3 14.8 0.03 (°C/W)
ESD CAUTION
Data Sheet ADRV9010
Rev. E | Page 21 of 115
PIN CONFIGURATION AND FUNCTION DESCRIPTIONS
VSSA
SERDOUTH+
SERDOUTD+
VSSA
TX4+
TX4–
VSSA
GPIO_ANA_5
VSSA
RX4+
RX4–
VSSA
AUXADC_2
AUXADC_3
VSSA
RX3+
RX3–
U
T
R
P
N
M
L
K
J
H
G
F
E
D
C
B
A VSSA VSSA TX3+ TX3– VSSA VTXLO_IP3 VSSA VRXLO_
IP3 VSSA VSSA VSSA TX2+ TX2– VSSA VSSA VSSA
VSSA VSSA VANA3_1P8 VSSA VSSA VSSA VSSA VSSA VSSA VAUXVCO
_1P0 VSSA VSSA VSSA VSSA RX2+
VSSA GPIO_ANA_7
GPIO_ANA_6
VAUXSYN_1P3 VSSA DEVCLK+ DEVCLK– VSSA VAUXVCO
_1P3GPIO_ANA_1
GPIO_ANA_0 VSSA RBIAS VSSA RX2–
VSSA VANA2_1P3 VSSA VSSA VSSA VSSA SYSREF+ SYSREF– VSSA VSSA VSSA VSSA VSSA VANA1_
1P3 VSSA VSSA
EXT_LO2– VSSA ORX3+ ORX3– VSSA TX3_EN GPIO_11 GPIO_9 GPIO_3 TX2_EN VSSA ORX1+ ORX1– VSSA EXT_
LO1+AUXADC
_1
EXT_LO2+ VSSA VSSA VSSA VSSA ORX_
CTRL_C GPIO_12 GPIO_10 GPIO_4 ORX_CTRL_B VSSA VSSA VSSA VSSA EXT_
LO1–AUXADC
_0
VSSA VRFVCO2_1P3 VSSA VRFVCO2
_1P0 VSSA RX3_EN GPIO_13 VDIG_1P0 GPIO_5 RX2_EN VSSA VRFVCO1_1P0 VSSA VRFVCO1
_1P3 VSSA VSSA
VSSA VCONV2_1P8 VSSA VSSA VSSA GPIO_17 GPIO_14 VSSD GPIO_6 GPIO_0 VSSA VSSA VSSA VCONV1
_1P8 VSSA RX1+
VSSA VCONV2_1P3 VSSA VRFSYN2
_1P3 VSSA RX4_EN GPIO_15 VDIG_1P0 GPIO_7 RX1_EN VSSA VRFSYN1_1P3 VSSA VCONV1
_1P3 VSSA RX1–
VSSA VCONV2_1P0 VSSA VSSA VSSA GPIO_18 GPIO_16 VSSD GPIO_8 GPIO_1 VSSA VSSA VSSA VCONV1
_1P0 VSSA VSSA
GPIO_ANA_4 VSSA ORX4+ ORX4– VSSA ORX_
CTRL_D SPI_DIO VDIG_1P0 SPI_EN ORX_CTRL_A VSSA ORX2+ ORX2– VSSA GPIO_
ANA_2GPIO_ANA_3
VSSA VSSA VSSA VSSA VSSA TX4_EN SPI_DO VSSD SPI_CLK TX1_EN VSSA VSSA VSSA VSSA VSSA VSSA
VANA4_1P8 VSSA VSSA VCLKVCO
_1P3 SYNCIN3+ GPINT2 GPINT1 GPIO_2 SYNCIN1+ SYNCIN1– SYNCOUT2+
SYNCOUT2–
VANA1_1P8 TX1+
VSSA VSSA VSSA VCLKVCO_1P0 SYNCIN3– SYNCIN2+ SYNCIN2– VSSA TEST_EN VJVCO
_1P8SYNCOUT1+ VSSA TX1–
VSSA VSSA VSSA VCLKSYN_1P3 VSSA VJSYN
_1P0 VSSA NIC VSSA VSSA VSSA SYNCOUT1– VSSA VSSA
SERDOUTD–
SERDOUTC+
SERDOUTC–
SERDOUTB+
SERDOUTB–
SERDOUTA+
SERDOUTA– VSSA SERD
IND–SERDIND+
SERDINC+
SERDINC–
SERDINB–
SERDINB+
SERDINA+
SERDINA–
SERDOUTH–
SERDOUTG+
SERDOUTG–
SERDOUTF+
ANALOG GROUND
DIGITAL GROUND
ANALOG POWER
DIGITAL POWER
ANALOGINPUTS/OUTPUTS
DIGITALINPUTS/OUTPUTS
ANALOG GPIO
AUXILIARYADC INPUTS
SPI BUS
LVDS SERDES CONTROLS
SERDES INPUTS/OUTPUTS
DIFFERENTIAL SYSREF SIGNAL
NOT INTERNALLY CONNECTED
SERDOUTF–
SERDOUTE+
SERDOUTE– VSSA SERD
INH–SERDINH+
SERDING+
SERDING–
SERDINF–
SERDINF+
SERDINE+
SERDINE–
1 2 3 4 5 6 7 8 9
ADRV9010TOP VIEW
(Not to Scale)
10 11 12 13 14 15 16 17
RESET
NIC
20043-002
VANA2_1P8
VDES_1P0
VDES_1P0 VTT_DES
VSER_1P0
VSER_1P0
VIF
Figure 2. Pin Configuration
ADRV9010 Data Sheet
Rev. E | Page 22 of 115
Table 10. Pin Function Descriptions Ball No. Type1 Mnemonic Description A1 to A3, A6, A8, A10 to A12, A15 to A17, B2, B3, B5 to B10,
B12, B13, B15, B16, C2, C7, C10, C14, C16, D1, D2, D4 to D7, D10 to D14, D16, D17, E3, E6, E12, E15, F3 to F6, F12 to F15, G1, G2, G4, G6, G12, G14, G16, G17, H2, H4 to H6, H12 to H14, H16, J2, J4, J6, J12, J14, J16, K1, K2, K4 to K6, K12 to K14, K16, K17, L3, L6, L12, L15, M1 to M6, M12 to M17, N3, N4, P2 to P4, P9, P16, R1, R2, R5, R6, R8, R10, R12 to R14, R16, R17, T9, U9
I VSSA Analog Grounds.
A4, A5 O TX3+, TX3− Differential Outputs for Transmitter Channel 3. Do not connect if unused.
A7 I VTXLO_1P3 1.3 V Supply Input. A9 I VRXLO_1P3 1.3 V Supply Input. A13, A14 O TX2+, TX2− Differential Outputs for Transmitter Channel 2.
Do not connect if unused. B1, C1 I RX3−, RX3+ Differential Inputs for Receiver Channel 3.
Connect to VSSA if unused. B4 I VANA3_1P8 1.8 V Supply Input. B11 O VAUXVCO_1P0 1.0 V Internal Supply Node. Bypass Pin B11
with a 4.7 μF capacitor. B14 I VANA2_1P8 1.8 V Supply Input. B17, C17 I RX2+, RX2− Differential Inputs for Receiver Channel 2.
Connect to VSSA if unused. C3, R11 N/A NIC Not Internally Connected. Pin C3 and R11
must remain disconnected. C4, C5, C12, C13, L1, L2, L17, L16 I/O GPIO_ANA_7 to
GPIO_ANA_0 General-Purpose Inputs and Outputs. The GPIO pins are referenced to 1.8 V but can also function as auxiliary DAC outputs. If unused, these pins can be connected to VSSA with a 10 kΩ resistor or configured as outputs, driven low, and left disconnected.
C6 I VAUXSYN_1P3 1.3 V Supply Input. C8, C9 I DEVCLK+, DEVCLK− Device Clock Differential Inputs. C11 I VAUXVCO_1P3 1.3 V Supply Input. C15 I RBIAS Bias Resistor Connection. Pin C15 generates
an internal current based on an external 1% resistor. Connect a 4.99 kΩ resistor between C15 and analog ground (VSSA).
D3 I VANA2_1P3 1.3 V Supply Input. D8, D9 I SYSREF+, SYSREF− LVDS System Reference Clock Inputs for the
Serializer/Deserializer (SERDES) Interface. Connect a 100 Ω termination between these pins.
D15 I VANA1_1P3 1.3 V Supply Input. E1 I AUXADC_3 Auxiliary ADC 3 Input. Do not connect if
unused. E2, F2 I/O EXT_LO2−,
EXT_LO2+ Differential External LO Input/Output 2. If used for the external LO input, the input frequency must be 2× the desired carrier frequency. Do not connect if unused.
E4, E5 I ORX3+, ORX3− Differential Inputs for Observation Receiver Channel 3. Connect to VSSA if unused.
E7 I TX3_EN Enable Input for Transmitter Channel 3. Connect to VSSA if unused.
Data Sheet ADRV9010
Rev. E | Page 23 of 115
Ball No. Type1 Mnemonic Description E8 to E10, F8 to F10, G8, G10, H7, H8, H10, H11, J8, J10, K7,
K8, K10, K11, N11 I/O GPIO_0 to GPIO_18 General-Purpose Digital Inputs and Outputs.
See Figure 2 to match the ball location to the GPIO_x signal name. If unused, these pins can be connected to VSSA with a 10 kΩ resistor or configured as outputs, driven low, and left disconnected.
E11 I TX2_EN Enable Input for Transmitter Channel 2. Connect to VSSA if unused.
E13, E14 I ORX1+, ORX1− Differential Inputs for Observation Receiver Channel 1. Connect to VSSA if unused.
E16, F16 I/O EXT_LO1+, EXT_LO1−
Differential External LO Input/Output 1. If used for the external LO input, the input frequency must be 2× the desired carrier frequency. Do not connect if unused.
E17 I AUXADC_1 Auxiliary ADC 1 Input. Do not connect if unused.
F1 I AUXADC_2 Auxiliary ADC2 Input. Do not connect if unused.
F7, F11, L7, L11 I ORX_CTRL_C, ORX_CTRL_B, ORX_CTRL_D, ORX_CTRL_A
These pins determines the active ORX_x path. Connect to VSSA directly or with a pull-down resistor if unused.
F17 I AUXADC_0 Auxiliary ADC0 Input. Do not connect if unused.
G3 I VRFVCO2_1P3 1.3 V Supply Input. G5 O VRFVCO2_1P0 1.0 V Internal Supply Node. Bypass this pin
with a 4.7 μF capacitor. G7 I RX3_EN Enable Input for Receiver Channel 3.
Connect to VSSA if unused. G9, J9, L9 I VDIG_1P0 1.0 V Digital Supply Input. G11 I RX2_EN Enable Input for Receiver Channel 2.
Connect to VSSA if unused. G13 O VRFVCO1_1P0 1.0 V Internal Supply Node. Bypass this pin
with a 4.7 μF capacitor. G15 I VRFVCO1_1P3 1.3 V Supply Input. H1, J1 I RX4−, RX4+ Differential Inputs for Receiver Channel 4.
Connect to VSSA if unused. H3 I VCONV2_1P8 1.8 V Supply Input. H9, K9, M9 I VSSD Digital Ground. H15 I VCONV1_1P8 1.8 V Supply Input. H17, J17 I RX1+, RX1− Differential Inputs for Receiver Channel 1.
Connect to VSSA if unused. J3 I VCONV2_1P3 1.3 V Supply Input. J5 I VRFSYN2_1P3 1.3 V Supply Input. J7 I RX4_EN Enable Input for Receiver Channel 4.
Connect to VSSA if unused. J11 I RX1_EN Enable Input for Receiver Channel 1.
Connect to VSSA if unused. J13 I VRFSYN1_1P3 1.3 V Supply Input. J15 I VCONV1_1P3 1.3 V Supply Input. K3 O VCONV2_1P0 1.0 V Internal Supply Node. Bypass this pin
with a 4.7 μF capacitor. K15 O VCONV1_1P0 1.0 V Internal Supply Node. Bypass this pin
with a 4.7 μF capacitor.
ADRV9010 Data Sheet
Rev. E | Page 24 of 115
Ball No. Type1 Mnemonic Description L4, L5 I ORX4+, ORX4− Differential Inputs for Observation Receiver
Channel 4. Connect to VSSA if unused. L8 I/O SPI_DIO Serial Data Input/Output. Pin L8 is a serial data
input only when in 4-wire mode. When L8 is in 3-wire mode, it is a serial data input/output.
L10 I SPI_EN Serial Data Bus Chip Select. Active low. L13, L14 I ORX2+, ORX2− Differential Inputs for Observation Receiver
Channel 2. Connect to VSSA if unused. M7 I TX4_EN Enable Input for Transmitter Channel 4.
Connect to VSSA if unused. M8 O SPI_DO Serial Data Output. M10 I SPI_CLK Serial Data Bus Clock Input. M11 I TX1_EN Enable Input for Transmitter Channel 1.
Connect to VSSA if unused. N1, P1 O TX4−, TX4+ Differential Outputs for Transmitter Channel 4.
Do not connect if unused. N2 I VANA4_1P8 1.8 V Supply Input. N5 I VCLKVCO_1P3 1.3 V Supply Input. N6, P6 I SYNCIN3+,
SYNCIN3− Low Voltage Differential Signal (LVDS) Synchronization Signal Input 3. Connect to VSSA if unused.
N7 O GPINT2 General-Purpose Interrupt Output 2. Do not connect if unused.
N8 O GPINT1 General-Purpose Interrupt Output 1. Do not connect if unused.
N9 I VIF 1.8 V Interface Supply Input. N10 I RESET Active Low Chip Reset.
N12, N13 I SYNCIN1+, SYNCIN1−
LVDS Synchronization Signal Input 1. Connect to VSSA if unused.
N14, N15 O SYNCOUT2+, SYNCOUT2−
LVDS Synchronization Signal Output 2. Do not connect if unused.
N16 I VANA1_1P8 1.8 V Supply Input. N17, P17 O TX1+, TX1− Differential Outputs for Transmitter Channel 1.
Do not connect if unused. P5 O VCLKVCO_1P0 1.0 V Internal Supply Node. Bypass this pin
with a 4.7 μF capacitor. P7, P8 I SYNCIN2+,
SYNCIN2− LVDS Synchronization Signal Input 2. Connect to VSSA if unused.
P10 I TEST_EN Test Input for JTAG Boundary Scan. Pull high to enable boundary scan, and tie to VSSA if unused.
P11 I VJVCO_1P8 1.8 V Supply Input. P12, P13 I VDES_1P0 1.0 V Analog Supply Input. P14 I VTT_DES 1.0 V Analog Supply Input. P15, R15 O SYNCOUT1+,
SYNCOUT1− LVDS Synchronization Signal Output 1. Do not connect if unused.
R3, R4 I VSER_1P0 1.0 V Analog Supply Input. R7 I VCLKSYN_1P3 1.3 V Supply Input. R9 I VJSYN_1P0 1.0 V Analog Supply Input.
Data Sheet ADRV9010
Rev. E | Page 25 of 115
Ball No. Type1 Mnemonic Description T1, T2 O SERDOUTD+,
SERDOUTD− SERDES Differential Output D. Do not connect if unused.
T3, T4 O SERDOUTC+, SERDOUTC−
SERDES Differential Output C. Do not connect if unused.
T5, T6 O SERDOUTB+, SERDOUTB−
SERDES Differential Output B. Do not connect if unused.
T7, T8 O SERDOUTA+, SERDOUTA−
SERDES Differential Output A. Do not connect if unused.
T10, T11 I SERDIND−, SERDIND+
SERDES Differential Input D. Do not connect if unused.
T12, T13 I SERDINC+, SERDINC−
SERDES Differential Input C. Do not connect if unused.
T14, T15 I SERDINB−, SERDINB+
SERDES Differential Input B. Do not connect if unused.
T16, T17 I SERDINA+, SERDINA−
SERDES Differential Input A. Do not connect if unused.
U1, U2 O SERDOUTH+, SERDOUTH−
SERDES Differential Output H. Do not connect if unused.
U3, U4 O SERDOUTG+, SERDOUTG−
SERDES Differential Output G. Do not connect if unused.
U5, U6 O SERDOUTF+, SERDOUTF−
SERDES Differential Output F. Do not connect if unused.
U7, U8 O SERDOUTE+, SERDOUTE−
SERDES Differential Output E. Do not connect if unused.
U10, U11 I SERDINH−, SERDINH+
SERDES Differential Input H. Do not connect if unused.
U12, U13 I SERDING+, SERDING−
SERDES Differential Input G. Do not connect if unused.
U14, U15 I SERDINF−, SERDINF+
SERDES Differential Input F. Do not connect if unused.
U16, U17 I SERDINE+, SERDINE−
SERDES Differential Input E. Do not connect if unused.
1 I is input, O is output, N/A is not applicable, and I/O is input/output.
ADRV9010 Data Sheet
Rev. E | Page 26 of 115
TYPICAL PERFORMANCE CHARACTERISTICS 800 MHz BAND The temperature settings refer to the die temperature. All LO frequencies set to 800 MHz, unless otherwise noted.
7.0
3.0
3.5
4.0
4.5
5.0
5.5
6.0
6.5
650 700 750 800 850 900 950 1000
TR
AN
SM
ITT
ER
CW
OU
TP
UT
PO
WE
R (
dB
m)
TRANSMITTER LO FREQUENCY (MHz)
+110°C+25°C–40°C
20043-003
Figure 3. Transmitter CW Output Power vs. Transmitter LO Frequency, 10 MHz Offset, 0 dB Attenuation
0
–100
–80
–60
–90
–70
–50
–40
–20
–30
–10
650
900
1100850
1050
1250800
750
1000
1200700
950
1150
1300
TR
AN
SM
ITT
ER
OU
TP
UT
PO
WE
R S
PE
CT
RU
M (
dB
m)
FREQUENCY (MHz)
SIGNALNOISE FLOOR
20043-004
Figure 4. Transmitter Output Power Spectrum, Tx1, 5 MHz LTE, 10 MHz Offset, −10 dBFS RMS, 1 MHz Resolution Bandwidth, T = 25°C
–40
–100
–90
–80
–70
–60
–50
–100 –80 –60 –40 0 40 80–20 20 60 100
TR
AN
SM
ITT
ER
IM
AG
E R
EJE
CT
ION
(d
Bc)
BASEBAND OFFSET FREQUENCY (MHz)
+110°C, Tx1+110°C, Tx2+110°C, Tx3+110°C, Tx4
+25°C, Tx1+25°C, Tx2+25°C, Tx3+25°C, Tx4
–40°C, Tx1–40°C, Tx2–40°C, Tx3–40°C, Tx4
20043-005
Figure 5. Transmitter Image Rejection vs. Baseband Offset Frequency, 0 dB Attenuation, QEC Tracking Enabled
–100
–180
–150
–170
–130
–110
–160
–140
–120
0 10 205 15
TR
AN
SM
ITT
ER
NO
ISE
(d
Bm
/Hz)
TRANSMITTER ATTENUATION (dB)
+110°C, Tx1+110°C, Tx2+110°C, Tx3+110°C, Tx4
+25°C, Tx1+25°C, Tx2+25°C, Tx3+25°C, Tx4
–40°C, Tx1–40°C, Tx2–40°C, Tx3–40°C, Tx4
20043-006
Figure 6. Transmitter Noise vs. Transmitter Attenuation, 50 MHz Offset
1.0
–0.1
0.1
0.3
0.5
0
0.2
0.4
0.6
0.7
0.8
0.9
–250 –200 –150 –100 0 100 200–50 50 150 250
TR
AN
SM
ITT
ER
PA
SS
BA
ND
FL
AT
NE
SS
(d
B)
BASEBAND OFFSET FREQUENCY (MHz)
+110°C+25°C–40°C
20043-007
Figure 7. Transmitter Pass Band Flatness vs. Baseband Offset Frequency
–40
–80
–75
–70
–65
–60
–55
–50
–45
0 5 10 15 20
AD
JAC
EN
T C
HA
NN
EL
PO
WE
R L
EV
EL
(d
Bc)
TRANSMITTER ATTENUATION (dB)
+110°C+25°C–40°C
20043-008
Figure 8. Adjacent Channel Power Level vs. Transmitter Attenuation, −10 MHz Baseband Offset, 20 MHz LTE, PAR = 12 dB,
Loop Filter Bandwidth = 50 kHz, Loop Filter Phase Margin = 40°
Data Sheet ADRV9010
Rev. E | Page 27 of 115
–40
–80
–75
–70
–65
–60
–55
–50
–45
0 5 10 15 20
AD
JAC
EN
T C
HA
NN
EL
PO
WE
R L
EV
EL
(d
Bc)
TRANSMITTER ATTENUATION (dB)
+110°C+25°C–40°C
20043-009
Figure 9. Adjacent Channel Power Level vs. Transmitter Attenuation, 90 MHz Baseband Offset, 20 MHz LTE, PAR = 12 dB,
Loop Filter Bandwidth = 50 kHz, Loop Filter Phase Margin = 40°
–60
–110
–100
–90
–80
–70
0 2 8 144 10 166 12 18 20
TR
AN
SM
ITT
ER
HD
2 (d
Bc)
TRANSMITTER ATTENUATION (dB)
+110°C, UPPER HD2+25°C, UPPER HD2–40°C, UPPER HD2+110°C, LOWER HD2+25°C, LOWER HD2–40°C, LOWER HD2
20043-010
Figure 10. Transmitter Second Harmonic Distortion (HD2) vs. Transmitter Attenuation, 10 MHz Offset
–60
–120
–110
–100
–90
–80
–70
0 2 8 144 10 166 12 18 20
TR
AN
SM
ITT
ER
HD
3 (d
Bc)
TRANSMITTER ATTENUATION (dB)
+110°C, UPPER HD3+25°C, UPPER HD3–40°C, UPPER HD3+110°C, LOWER HD3+25°C, LOWER HD3–40°C, LOWER HD3
20043-011
Figure 11. Transmitter Third Harmonic Distortion (HD3) vs. Transmitter Attenuation, 10 MHz Offset
0.05
–0.05
–0.04
0
–0.02
0.02
0.04
–0.01
–0.03
0.01
0.03
0 8 16 24 324 12 20 28
TR
AN
SM
ITT
ER
AT
TE
NU
AT
OR
ST
EP
ER
RO
R (
dB
)
TRANSMITTER ATTENUATION (dB)
+110°C+25°C–40°C
20043-012
Figure 12. Transmitter Attenuator Step Error vs. Transmitter Attenuation, 10 MHz Offset
–42
–52
–50
–48
–46
–44
0 5 10 15 20
TR
AN
SM
ITT
ER
ER
RO
R V
EC
TO
R M
AG
NIT
UD
E (
dB
)
TRANSMITTER ATTENUATION (dB)
+110°C, Tx1+110°C, Tx2+110°C, Tx3+110°C, Tx4
+25°C, Tx1+25°C, Tx2+25°C, Tx3+25°C, Tx4
–40°C, Tx1–40°C, Tx2–40°C, Tx3–40°C, Tx4
20043-013
Figure 13. Transmitter Error Vector Magnitude vs. Transmitter Attenuation, 20 MHz LTE Signal Centered at LO Frequency, Sample Rate = 491.52 MSPS, QEC
Tracking Enabled, Loop Filter Bandwidth = 50 kHz, Loop Filter Phase Margin = 40°
45
–10
0
20
–5
10
30
40
15
5
25
35
0 8 16 24 324 12 20 28
TR
AN
SM
ITT
ER
OIP
3, 2
f1 –
f2
(dB
m)
TRANSMITTER ATTENUATION (dB)
+110°C, Tx1+110°C, Tx2+110°C, Tx3+110°C, Tx4
+25°C, Tx1+25°C, Tx2+25°C, Tx3+25°C, Tx4
–40°C, Tx1–40°C, Tx2–40°C, Tx3–40°C, Tx4
20043-014
Figure 14. Transmitter OIP3, 2f1 − f2 vs. Transmitter Attenuation, 15 dB Digital Backoff per Tone, f1 = 50.5 MHz, f2 = 55.5 MHz
ADRV9010 Data Sheet
Rev. E | Page 28 of 115
45
–10
0
20
–5
10
30
40
15
5
25
35
0 8 16 24 324 12 20 28
TR
AN
SM
ITT
ER
OIP
3, 2
f2 –
f1
(dB
m)
TRANSMITTER ATTENUATION (dB)
+110°C, Tx1+110°C, Tx2+110°C, Tx3+110°C, Tx4
+25°C, Tx1+25°C, Tx2+25°C, Tx3+25°C, Tx4
–40°C, Tx1–40°C, Tx2–40°C, Tx3–40°C, Tx4
20043-015
Figure 15. Transmitter OIP3, 2f2 − f1 vs. Transmitter Attenuation, 15 dB Digital Backoff per Tone, f1 = 50.5 MHz, f2 = 55.5 MHz
50
45
0
20
10
30
40
15
5
25
35
10 50 90 130 19030 70 110 150 170
TR
AN
SM
ITT
ER
OIP
3, 2
f1 –
f2
(dB
m)
f1 BASEBAND OFFSET TONE FREQUENCY (MHz)
+110°C, Tx1+110°C, Tx2+110°C, Tx3+110°C, Tx4
+25°C, Tx1+25°C, Tx2+25°C, Tx3+25°C, Tx4
–40°C, Tx1–40°C, Tx2–40°C, Tx3–40°C, Tx4
20043-016
Figure 16. Transmitter OIP3, 2f1 − f2 vs. f1 Baseband Offset Tone Frequency, f2 = f1 + 5 MHz, 15 dB Digital Backoff per Tone
50
45
0
20
10
30
40
15
5
25
35
10 50 90 130 19030 70 110 150 170
TR
AN
SM
ITT
ER
OIP
3, 2
f2 –
f1
(dB
m)
f1 BASEBAND OFFSET TONE FREQUENCY (MHz)
+110°C, Tx1+110°C, Tx2+110°C, Tx3+110°C, Tx4
+25°C, Tx1+25°C, Tx2+25°C, Tx3+25°C, Tx4
–40°C, Tx1–40°C, Tx2–40°C, Tx3–40°C, Tx4
20043-017
Figure 17. Transmitter OIP3, 2f2 − f1 vs. f1 Baseband Offset Tone Frequency, f2 = f1 + 5 MHz, 15 dB Digital Backoff per Tone
50
45
0
20
10
30
40
15
5
25
35
10 50 90 130 19030 70 110 150 170
TR
AN
SM
ITT
ER
OIP
3, 2
f1 +
f2
(dB
m)
f1 BASEBAND OFFSET TONE FREQUENCY (MHz)
+110°C, Tx1+110°C, Tx2+110°C, Tx3+110°C, Tx4
+25°C, Tx1+25°C, Tx2+25°C, Tx3+25°C, Tx4
–40°C, Tx1–40°C, Tx2–40°C, Tx3–40°C, Tx4
20043-018
Figure 18. Transmitter OIP3, 2f1 + f2 vs. f1 Baseband Offset Tone Frequency, f2 = f1 + 5 MHz, 15 dB Digital Backoff per Tone
50
45
0
20
10
30
40
15
5
25
35
10 50 90 130 19030 70 110 150 170
TR
AN
SM
ITT
ER
OIP
3, 2
f2 +
f1
(dB
m)
f1 BASEBAND OFFSET TONE FREQUENCY (MHz)
+110°C, Tx1+110°C, Tx2+110°C, Tx3+110°C, Tx4
+25°C, Tx1+25°C, Tx2+25°C, Tx3+25°C, Tx4
–40°C, Tx1–40°C, Tx2–40°C, Tx3–40°C, Tx4
20043-019
Figure 19. Transmitter OIP3, 2f2 + f1 vs. f1 Baseband Offset Tone Frequency, f2 = f1 + 5 MHz, 15 dB Digital Backoff per Tone
120
50
70
90
60
80
100
110
800 850 900 950 1000
TR
AN
SM
ITT
ER
TO
TR
AN
SM
ITT
ER
IS
OL
AT
ION
(d
B)
TRANSMITTER LO FREQUENCY (MHz)
Tx1 TO Tx2Tx2 TO Tx1Tx3 TO Tx1Tx4 TO Tx1
Tx1 TO Tx3Tx2 TO Tx3Tx3 TO Tx4Tx4 TO Tx4
Tx1 TO Tx4Tx2 TO Tx4Tx3 TO Tx4Tx4 TO Tx3
20043-021
Figure 20. Transmitter to Transmitter Isolation vs. Transmitter LO Frequency
Data Sheet ADRV9010
Rev. E | Page 29 of 115
130
50
70
90
60
80
100
110
120
800 850 900 950 1000
TR
AN
SM
ITT
ER
TO
RE
CE
IVE
R I
SO
LA
TIO
N (
dB
)
RECEIVER LO FREQUENCY (MHz)
Tx1 TO Rx1Tx2 TO Rx1Tx3 TO Rx1Tx4 TO Rx1
Tx1 TO Rx2Tx2 TO Rx2Tx3 TO Rx2Tx4 TO Rx2
Tx1 TO Rx3Tx2 TO Rx3Tx3 TO Rx3Tx4 TO Rx3
Tx1 TO Rx4Tx2 TO Rx4Tx3 TO Rx4Tx4 TO Rx4
20043-022
Figure 21. Transmitter to Receiver Isolation vs. Receiver LO Frequency
140
130
50
70
90
60
80
100
110
120
800 850 900 950 1000
TR
AN
SM
ITT
ER
TO
OB
SE
RV
AT
ION
RE
CE
IVE
RIS
OL
AT
ION
(d
B)
TRANSMITTER LO FREQUENCY (MHz)
Tx1 TO ORx1Tx2 TO ORx1Tx3 TO ORx1Tx4 TO ORx1
Tx1 TO ORx2Tx2 TO ORx2Tx3 TO ORx2Tx4 TO ORx2
Tx1 TO ORx3Tx2 TO ORx3Tx3 TO ORx3Tx4 TO ORx3
Tx1 TO ORx4Tx2 TO ORx4Tx3 TO ORx4Tx4 TO ORx4
20043-023
Figure 22. Transmitter to Observation Receiver Isolation vs. Transmitter LO Frequency
120
50
70
90
60
80
100
110
800 850 900 950 1000
RE
CE
IVE
R T
O R
EC
EIV
ER
IS
OL
AT
ION
(d
B)
RECEIVER LO FREQUENCY (MHz)
Rx1 TO Rx2Rx2 TO Rx1Rx3 TO Rx1Rx4 TO Rx1
Rx1 TO Rx3Rx2 TO Rx3Rx3 TO Rx2Rx4 TO Rx2
Rx1 TO Rx4Rx2 TO Rx4Rx3 TO Rx4Rx4 TO Rx3
20043-024
Figure 23. Receiver to Receiver Isolation vs. Receiver LO Frequency
50
0
25
5
35
45
15
10
20
30
40
0 10 305 20 2515
RE
CE
IVE
R I
NT
EG
RA
TE
D N
OIS
E F
IGU
RE
(d
B)
RECEIVER ATTENUATION (dB)
+110°C, Rx1+110°C, Rx2+110°C, Rx3+110°C, Rx4
+25°C, Rx1+25°C, Rx2+25°C, Rx3+25°C, Rx4
–40°C, Rx1–40°C, Rx2–40°C, Rx3–40°C, Rx4
20043-025
Figure 24. Receiver Integrated Noise Figure vs. Receiver Attenuation, 200 MHz Bandwidth, Sample Rate = 245.76 MSPS,
Integration Bandwidth = 500 kHz to 100 MHz
25
0
10
20
5
15
–100 –60 –20 40 100–80 –40 0 8020 60
RE
CE
IVE
R I
NT
EG
RA
TE
D N
OIS
E F
IGU
RE
(d
B)
BASEBAND OFFSET FREQUENCY (MHz)
+110°C+25°C–40°C
20043-027
Figure 25. Receiver Integrated Noise Figure vs. Baseband Offset Frequency, 200 MHz Bandwidth, Sample Rate = 245.76 MSPS, Integrated in 200 kHz Steps
–40
–100
–90
–80
–70
–60
–50
650 700 800 900750 850 950 1000
RE
CE
IVE
R L
O L
EA
KA
GE
(d
Bm
)
RECEIVER LO FREQUENCY (MHz)
+110°C+25°C–40°C
20043-028
Figure 26. Receiver LO Leakage vs. Receiver LO Frequency, Attenuation = 0 dB, Sample Rate = 245.76 MSPS
ADRV9010 Data Sheet
Rev. E | Page 30 of 115
20
–15
–5
5
15
–10
0
10
0 10 255 2015
RE
CE
IVE
R G
AIN
(d
B)
RECEIVER ATTENUATION (dB)
+110°C, Rx1+110°C, Rx2+110°C, Rx3+110°C, Rx4
+25°C, Rx1+25°C, Rx2+25°C, Rx3+25°C, Rx4
–40°C, Rx1–40°C, Rx2–40°C, Rx3–40°C, Rx4
20043-029
Figure 27. Receiver Gain vs. Receiver Attenuation, 20 MHz Offset, 200 MHz Bandwidth, Sample Rate = 245.76 MSPS
20
15
16
17
19
18
650 750 1000700 800 900850 950
RE
CE
IVE
R G
AIN
(d
B)
RECEIVER LO FREQUENCY (MHz)
+110°C, Rx1+110°C, Rx2+110°C, Rx3+110°C, Rx4
+25°C, Rx1+25°C, Rx2+25°C, Rx3+25°C, Rx4
–40°C, Rx1–40°C, Rx2–40°C, Rx3–40°C, Rx4
20043-030
Figure 28. Receiver Gain vs. Receiver LO Frequency, 10 MHz Offset, 200 MHz Bandwidth, Sample Rate = 245.76 MSPS
0.20
–0.20
–0.10
0.05
0.15
0
–0.15
–0.05
0.10
0 302010 15 255
RE
CE
IVE
R G
AIN
ST
EP
ER
RO
R (
dB
)
RECEIVER ATTENUATION (dB)
+110°C, Rx1+110°C, Rx2+110°C, Rx3+110°C, Rx4
+25°C, Rx1+25°C, Rx2+25°C, Rx3+25°C, Rx4
–40°C, Rx1–40°C, Rx2–40°C, Rx3–40°C, Rx4
20043-031
Figure 29. Receiver Gain Step Error vs. Receiver Attenuation, 20 MHz Offset, −5 dBFS Input Signal
0.5
–0.5
–0.3
–0.1
–0.4
–0.2
0
0.1
0.2
0.3
0.4
–100 –80 –60 –40 0 40 80–20 20 60 100
NO
RM
AL
IZE
D R
EC
EIV
ER
FL
AT
NE
SS
(d
B)
BASEBAND OFFSET FREQUENCY (MHz)
+110°C+25°C–40°C
20043-032
Figure 30. Normalized Receiver Flatness vs. Baseband Offset Frequency, −5 dBFS Input Signal, 0 dB Attenuation
–40
–100
–90
–70
–80
–60
–50
–100 –80 –40 40–60 0 8020–20 60 100
RE
CE
IVE
R I
MA
GE
(d
Bc)
BASEBAND OFFSET FREQUENCY (MHz)
+110°C, Rx1+110°C, Rx2+110°C, Rx3+110°C, Rx4
+25°C, Rx1+25°C, Rx2+25°C, Rx3+25°C, Rx4
–40°C, Rx1–40°C, Rx2–40°C, Rx3–40°C, Rx4
20043-033
Figure 31. Receiver Image vs. Baseband Offset Frequency, Tracking Calibration Active, Sample Rate = 245.76 MSPS, −5 dBFS Input Signal
–40
–100
–90
–70
–80
–60
–50
0 10 205 15 25
RE
CE
IVE
R I
MA
GE
(d
Bc)
RECEIVER ATTENUATION (dB)
+110°C, Rx1+110°C, Rx2+110°C, Rx3+110°C, Rx4
+25°C, Rx1+25°C, Rx2+25°C, Rx3+25°C, Rx4
–40°C, Rx1–40°C, Rx2–40°C, Rx3–40°C, Rx4
20043-034
Figure 32. Receiver Image vs. Receiver Attenuation, 20 MHz Offset, Tracking Calibration Active, Sample Rate = 245.76 MSPS, −5 dBFS Input Signal
Data Sheet ADRV9010
Rev. E | Page 31 of 115
–40
–110
–100
–90
–70
–80
–60
–50
0 10 205 15 25
RE
CE
IVE
R D
C O
FF
SE
T (
dB
FS
)
RECEIVER ATTENUATION (dB)
+110°C, Rx1+110°C, Rx2+110°C, Rx3+110°C, Rx4
+25°C, Rx1+25°C, Rx2+25°C, Rx3+25°C, Rx4
–40°C, Rx1–40°C, Rx2–40°C, Rx3–40°C, Rx4
20043-036
Figure 33. Receiver DC Offset vs. Receiver Attenuation, 20 MHz Offset, −5 dBFS Input Signal
–40
–120
–110
–100
–90
–70
–80
–60
–50
–60 –20 20–40 0 6040
RE
CE
IVE
R H
D2,
LE
FT
SID
E (
dB
c)
BASEBAND OFFSET FREQUENCY (MHz)
+110°C, Rx1+110°C, Rx2+110°C, Rx3+110°C, Rx4
+25°C, Rx1+25°C, Rx2+25°C, Rx3+25°C, Rx4
–40°C, Rx1–40°C, Rx2–40°C, Rx3–40°C, Rx4
20043-037
Figure 34. Receiver HD2, Left Side vs. Baseband Offset Frequency, −5 dBFS Input Signal, Distortion Tone Measured Left of 0 Hz
(HD2 Canceller Not Enabled)
–40
–120
–110
–100
–90
–70
–80
–60
–50
–60 –20 20–40 0 6040
RE
CE
IVE
R H
D2,
RIG
HT
SID
E (
dB
c)
BASEBAND OFFSET FREQUENCY (MHz)
+110°C, Rx1+110°C, Rx2+110°C, Rx3+110°C, Rx4
+25°C, Rx1+25°C, Rx2+25°C, Rx3+25°C, Rx4
–40°C, Rx1–40°C, Rx2–40°C, Rx3–40°C, Rx4
20043-038
Figure 35. Receiver HD2, Right Side vs. Baseband Offset Frequency, −5 dBFS Input Signal, Distortion Tone Measured Right of 0 Hz
(HD2 Canceller Not Enabled)
–40
–120
–110
–100
–90
–70
–80
–60
–50
–40 –30 –10 10–20 0 403020
RE
CE
IVE
R H
D3,
LE
FT
SID
E (
dB
c)
BASEBAND OFFSET FREQUENCY (MHz)
+110°C, Rx1+110°C, Rx2+110°C, Rx3+110°C, Rx4
+25°C, Rx1+25°C, Rx2+25°C, Rx3+25°C, Rx4
–40°C, Rx1–40°C, Rx2–40°C, Rx3–40°C, Rx4
20043-039
Figure 36. Receiver HD3, Left Side vs. Baseband Offset Frequency, −5 dBFS Input Signal, Distortion Tone Measured Left of 0 Hz
–40
–120
–110
–100
–90
–70
–80
–60
–50
–40 –30 –10 10–20 0 403020
RE
CE
IVE
R H
D3,
RIG
HT
SID
E (
dB
c)
BASEBAND OFFSET FREQUENCY (MHz)
+110°C, Rx1+110°C, Rx2+110°C, Rx3+110°C, Rx4
+25°C, Rx1+25°C, Rx2+25°C, Rx3+25°C, Rx4
–40°C, Rx1–40°C, Rx2–40°C, Rx3–40°C, Rx4
20043-040
Figure 37. Receiver HD3, Right Side vs. Baseband Offset Frequency, −5 dBFS Input Signal, Distortion Tone Measured Right of 0 Hz
90
50
55
60
65
75
70
80
85
805 815 845835825
RE
CE
IVE
R I
IP2,
f1
+ f
2 (d
Bm
)
TONE 2 FREQUENCY (MHz)
+110°C, Rx1+110°C, Rx2+110°C, Rx3+110°C, Rx4
+25°C, Rx1+25°C, Rx2+25°C, Rx3+25°C, Rx4
–40°C, Rx1–40°C, Rx2–40°C, Rx3–40°C, Rx4
20043-041
Figure 38. Receiver IIP2, f1 + f2 vs. Tone 2 Frequency, Both Tones at −11 dBFS, 0 dB Attenuation, f1 = f2 + 2 MHz
ADRV9010 Data Sheet
Rev. E | Page 32 of 115
90
50
55
60
65
75
70
80
85
805 825 895885865845815 875855835
RE
CE
IVE
R I
IP2,
f1
– f2
(d
Bm
)
TONE 2 FREQUENCY (MHz)
+110°C, Rx1+110°C, Rx2+110°C, Rx3+110°C, Rx4
+25°C, Rx1+25°C, Rx2+25°C, Rx3+25°C, Rx4
–40°C, Rx1–40°C, Rx2–40°C, Rx3–40°C, Rx4
20043-042
Figure 39. Receiver IIP2, f1 − f2 vs. Tone 2 Frequency, Both Tones at −11 dBFS, 0 dB Attenuation, f1 = f2 + 2 MHz
90
50
55
60
65
75
70
80
85
RE
CE
IVE
R I
IP2,
f1
+ f
2 (d
Bm
)
TWO-TONE FREQUENCY SPACING (MHz)
+110°C, Rx1+110°C, Rx2+110°C, Rx3+110°C, Rx4
+25°C, Rx1+25°C, Rx2+25°C, Rx3+25°C, Rx4
–40°C, Rx1–40°C, Rx2–40°C, Rx3–40°C, Rx4
10 30 90705020 806040
20043-043
Figure 40. Receiver IIP2, f1 + f2 vs. Two-Tone Frequency Spacing, Both Tones at −11 dBFS, 0 dB Attenuation, f2 = 2 MHz
85
50
55
60
65
75
70
80
RE
CE
IVE
R I
IP2,
f1
– f2
(d
Bm
)
TWO-TONE FREQUENCY SPACING (MHz)
+110°C, Rx1+110°C, Rx2+110°C, Rx3+110°C, Rx4
+25°C, Rx1+25°C, Rx2+25°C, Rx3+25°C, Rx4
–40°C, Rx1–40°C, Rx2–40°C, Rx3–40°C, Rx4
10 30 90705020 806040
20043-044
Figure 41. Receiver IIP2, f1 − f2 vs. Two-Tone Frequency Spacing, Both Tones at −11 dBFS, 0 dB Attenuation, f2 = 2 MHz
90
40
50
55
45
60
65
75
70
80
85
RE
CE
IVE
R I
IP2,
f1
+ f
2 (d
Bm
)
RECEIVER ATTENUATION (dB)
+110°C, Rx1+110°C, Rx2+110°C, Rx3+110°C, Rx4
+25°C, Rx1+25°C, Rx2+25°C, Rx3+25°C, Rx4
–40°C, Rx1–40°C, Rx2–40°C, Rx3–40°C, Rx4
0 10 205 15
20043-045
Figure 42. Receiver IIP2, f1 + f2 vs. Receiver Attenuation, Both Tones at −11 dBFS, f1 = 92 MHz, f2 = 2 MHz
100
90
60
65
75
70
80
85
95
RE
CE
IVE
R I
IP2,
f1
– f2
(d
Bm
)
RECEIVER ATTENUATION (dB)
+110°C, Rx1+110°C, Rx2+110°C, Rx3+110°C, Rx4
+25°C, Rx1+25°C, Rx2+25°C, Rx3+25°C, Rx4
–40°C, Rx1–40°C, Rx2–40°C, Rx3–40°C, Rx4
0 10 205 15
20043-046
Figure 43. Receiver IIP2, f1 − f2 vs. Receiver Attenuation, Both Tones at −11 dBFS, f1 = 92 MHz, f2 = 2 MHz
40
30
0
5
15
10
20
25
35
RE
CE
IVE
R I
IP3,
2f1
+ f
2 (d
Bm
)
TONE 2 FREQUENCY (MHz)
+110°C, Rx1+110°C, Rx2+110°C, Rx3+110°C, Rx4
+25°C, Rx1+25°C, Rx2+25°C, Rx3+25°C, Rx4
–40°C, Rx1–40°C, Rx2–40°C, Rx3–40°C, Rx4
805 815 825810 820
20043-047
Figure 44. Receiver IIP3, 2f1 + f2 vs. Tone 2 Frequency, Both Tones at −11 dBFS, 0 dB Attenuation, f1 = f2 + 2 MHz
Data Sheet ADRV9010
Rev. E | Page 33 of 115
40
30
0
5
15
10
20
25
35
RE
CE
IVE
R I
IP3,
2f2
+ f
1 (d
Bm
)
TONE 2 FREQUENCY (MHz)
+110°C, Rx1+110°C, Rx2+110°C, Rx3+110°C, Rx4
+25°C, Rx1+25°C, Rx2+25°C, Rx3+25°C, Rx4
–40°C, Rx1–40°C, Rx2–40°C, Rx3–40°C, Rx4
805 815 825810 820
20043-048
Figure 45. Receiver IIP3, 2f2 + f1 vs. Tone 2 Frequency, Both Tones at −11 dBFS, 0 dB Attenuation, f1 = f2 + 2 MHz
40
30
0
5
15
10
20
25
35
RE
CE
IVE
R I
IP3,
2f1
– f
2 (d
Bm
)
TONE 2 FREQUENCY (MHz)
+110°C, Rx1+110°C, Rx2+110°C, Rx3+110°C, Rx4
+25°C, Rx1+25°C, Rx2+25°C, Rx3+25°C, Rx4
–40°C, Rx1–40°C, Rx2–40°C, Rx3–40°C, Rx4
805 845 895885825 865835 875815 855
20043-049
Figure 46. Receiver IIP3, 2f1 − f2 vs. Tone 2 Frequency, Both Tones at −11 dBFS, 0 dB Attenuation, f1 = f2 + 2 MHz
40
30
0
5
15
10
20
25
35
RE
CE
IVE
R I
IP3,
2f2
– f
1 (d
Bm
)
TONE 2 FREQUENCY (MHz)
+110°C, Rx1+110°C, Rx2+110°C, Rx3+110°C, Rx4
+25°C, Rx1+25°C, Rx2+25°C, Rx3+25°C, Rx4
–40°C, Rx1–40°C, Rx2–40°C, Rx3–40°C, Rx4
805 845 895885825 865835 875815 855
20043-050
Figure 47. Receiver IIP3, 2f2 − f1 vs. Tone 2 Frequency, Both Tones at −11 dBFS, 0 dB Attenuation, f1 = f2 + 2 MHz
35
10
15
25
20
30
RE
CE
IVE
R I
IP3,
2f1
+ f
2 (d
Bm
)
TWO-TONE FREQUENCY SPACING (MHz)
+110°C, Rx1+110°C, Rx2+110°C, Rx3+110°C, Rx4
+25°C, Rx1+25°C, Rx2+25°C, Rx3+25°C, Rx4
–40°C, Rx1–40°C, Rx2–40°C, Rx3–40°C, Rx4
10 20 403015 3525
20043-051
Figure 48. Receiver IIP3, 2f1 + f2 vs. Two-Tone Frequency Spacing, Both Tones at −11 dBFS, 0 dB Attenuation, f2 = 2 MHz
35
10
15
25
20
30
RE
CE
IVE
R I
IP3,
2f2
+ f
1 (d
Bm
)
TWO-TONE FREQUENCY SPACING (MHz)
10 30 90705020 806040
+110°C, Rx1+110°C, Rx2+110°C, Rx3+110°C, Rx4
+25°C, Rx1+25°C, Rx2+25°C, Rx3+25°C, Rx4
–40°C, Rx1–40°C, Rx2–40°C, Rx3–40°C, Rx4
20043-052
Figure 49. Receiver IIP3, 2f2 + f1 vs. Two-Tone Frequency Spacing, Both Tones at −11 dBFS, 0 dB Attenuation, f2 = 2 MHz
35
10
15
25
20
30
RE
CE
IVE
R I
IP3,
2f1
– f
2 (d
Bm
)
TWO-TONE FREQUENCY SPACING (MHz)
10 20 403015 3525
+110°C, Rx1+110°C, Rx2+110°C, Rx3+110°C, Rx4
+25°C, Rx1+25°C, Rx2+25°C, Rx3+25°C, Rx4
–40°C, Rx1–40°C, Rx2–40°C, Rx3–40°C, Rx4
20043-053
Figure 50. Receiver IIP3, 2f1 − f2 vs. Two-Tone Frequency Spacing, Both Tones at −11 dBFS, 0 dB Attenuation, f2 = 2 MHz
ADRV9010 Data Sheet
Rev. E | Page 34 of 115
35
10
15
25
20
30
RE
CE
IVE
R I
IP3,
2f2
– f
1 (d
Bm
)
TWO-TONE FREQUENCY SPACING (MHz)
10 30 90705020 806040
+110°C, Rx1+110°C, Rx2+110°C, Rx3+110°C, Rx4
+25°C, Rx1+25°C, Rx2+25°C, Rx3+25°C, Rx4
–40°C, Rx1–40°C, Rx2–40°C, Rx3–40°C, Rx4
20043-054
Figure 51. Receiver IIP3, 2f2 − f1 vs. Two-Tone Frequency Spacing, Both Tones at −11 dBFS, 0 dB Attenuation, f2 = 2 MHz
–20
–25
–50
–45
–35
–40
–30
RE
CE
IVE
R E
RR
OR
VE
CT
OR
MA
GN
ITU
DE
(d
B)
RECEIVER INPUT POWER (dBm)
–60 –45 0–10–25–55 –5–15–35–40 –20–50 –30
+110°C, Rx1+110°C, Rx2+110°C, Rx3+110°C, Rx4
+25°C, Rx1+25°C, Rx2+25°C, Rx3+25°C, Rx4
–40°C, Rx1–40°C, Rx2–40°C, Rx3–40°C, Rx4
20043-055
Figure 52. Receiver Error Vector Magnitude vs. Receiver Input Power, 20 MHz LTE Signal Centered at LO Frequency, Sample Rate = 245.76 MSPS,
Loop Filter Bandwidth = 50 kHz, Loop Filter Phase Margin = 40°
–170
–160
–150
–140
–130
–120
–110
–100
–90
–80
100 1k 10k 100k 1M 10M
LO
PH
AS
E N
OIS
E (
dB
c/H
z)
FREQUENCY OFFSET (Hz) 20043-264
Figure 53. LO Phase Noise vs. Frequency Offset, Loop Bandwidth = 50 kHz, Phase Margin = 85°
–170
–160
–150
–140
–130
–120
–110
–100
–90
–80
LO
PH
AS
E N
OIS
E (
dB
c/H
z)
FREQUENCY OFFSET (Hz)
100 1k 10k 100k 1M 10M
20043-265
Figure 54. LO Phase Noise vs. Frequency Offset, Loop Bandwidth = 600 kHz, Phase Margin = 60°
50
45
0
5
25
15
35
40
20
10
30
OB
SE
RV
AT
ION
RE
CE
IVE
R I
NT
EG
RA
TE
DN
OIS
E F
IGU
RE
(d
B)
0 10 205 15
OBSERVATION RECEIVER ATTENUATION (dB)
+110°C, ORx1+110°C, ORx2+110°C, ORx3+110°C, ORx4
+25°C, ORx1+25°C, ORx2+25°C, ORx3+25°C, ORx4
–40°C, ORx1–40°C, ORx2–40°C, ORx3–40°C, ORx4
20043-058
Figure 55. Observation Receiver Integrated Noise Figure vs. Observation Receiver Attenuation, 20 MHz Offset, 450 MHz Bandwidth,
Sample Rate = 491.52 MSPS, Integration Bandwidth = 500 kHz to 100 MHz
35
0
5
25
15
20
10
30
OB
SE
RV
AT
ION
RE
CE
IVE
R I
NT
EG
RA
TE
DN
OIS
E F
IGU
RE
(d
B)
–250 –50 250–150 15050
BASEBAND OFFSET FREQUENCY (MHz)
+110°C+25°C–40°C
20043-060
Figure 56. Observation Receiver Integrated Noise Figure vs. Baseband Offset Frequency, 450 MHz Bandwidth, Sample Rate = 491.52 MSPS,
Integrated in 200 kHz Steps
Data Sheet ADRV9010
Rev. E | Page 35 of 115
–40
–100
–90
–60
–80
–70
–50
OB
SE
RV
AT
ION
RE
CE
IVE
R L
O L
EA
KA
GE
(d
Bm
)
650 750 1000700 950850 900800
OBSERVATION RECEIVER LO FREQUENCY (MHz)
+110°C+25°C–40°C
20043-061
Figure 57. Observation Receiver LO Leakage vs. Observation Receiver LO Frequency, 0 dB Attenuation, Sample Rate = 491.52 MSPS
20
15
–15
–10
5
–5
0
10
OB
SE
RV
AT
ION
RE
CE
IVE
R G
AIN
(d
B)
0 10 305 20 2515
OBSERVATION RECEIVER ATTENUATION (dB)
+110°C, ORx1+110°C, ORx2+110°C, ORx3+110°C, ORx4
+25°C, ORx1+25°C, ORx2+25°C, ORx3+25°C, ORx4
–40°C, ORx1–40°C, ORx2–40°C, ORx3–40°C, ORx4
20043-062
Figure 58. Observation Receiver Gain vs. Observation Receiver Attenuation, 20 MHz Offset, 450 MHz Bandwidth, Sample Rate = 491.52 MSPS
20
15
16
19
17
18
OB
SE
RV
AT
ION
RE
CE
IVE
R G
AIN
(d
B)
650 750 1000700 950850 900800
OBSERVATION RECEIVER LO FREQUENCY (MHz)
+110°C, ORx1+110°C, ORx2+110°C, ORx3+110°C, ORx4
+25°C, ORx1+25°C, ORx2+25°C, ORx3+25°C, ORx4
–40°C, ORx1–40°C, ORx2–40°C, ORx3–40°C, ORx4
20043-063
Figure 59. Observation Receiver Gain vs. Observation Receiver LO Frequency, 450 MHz Bandwidth, Sample Rate = 491.52 MSPS
0.20
–0.20
–0.15
0.15
–0.05
0.05
0.10
–0.10
0
OB
SE
RV
AT
ION
RE
CE
IVE
R G
AIN
ST
EP
ER
RO
R (
dB
)
0 10 305 20 2515
OBSERVATION RECEIVER ATTENUATION (dB)
+110°C, ORx1+110°C, ORx2+110°C, ORx3+110°C, ORx4
+25°C, ORx1+25°C, ORx2+25°C, ORx3+25°C, ORx4
–40°C, ORx1–40°C, ORx2–40°C, ORx3–40°C, ORx4
20043-064
Figure 60. Observation Receiver Gain Step Error vs. Observation Receiver Attenuation, 20 MHz Offset, −5 dBFS Input Signal
0.6
–0.6
–0.4
0.2
–0.2
0
0.4
NO
RM
AL
IZE
D O
BS
ER
VA
TIO
N R
EC
EIV
ER
FL
AT
NE
SS
(d
B)
–220 –140 220–180 18020 100–60 140–20 60–100
BASEBAND OFFSET FREQUENCY (MHz)
+110°C+25°C–40°C
20043-065
Figure 61. Normalized Observation Receiver Flatness vs. Baseband Offset Frequency, −25 dBm Input Signal, 0 dB Attenuation
–40
–100
–90
–70
–80
–50
–60
OB
SE
RV
AT
ION
RE
CE
IVE
R I
MA
GE
(d
Bc)
–225 –125 225–175 75 175–25 25 125–75
BASEBAND OFFSET FREQUENCY (MHz)
+110°C, ORx1+110°C, ORx2+110°C, ORx3+110°C, ORx4
+25°C, ORx1+25°C, ORx2+25°C, ORx3+25°C, ORx4
–40°C, ORx1–40°C, ORx2–40°C, ORx3–40°C, ORx4
20043-066
Figure 62. Observation Receiver Image vs. Baseband Offset Frequency, Tracking Calibration Active, Sample Rate = 491.52 MSPS
ADRV9010 Data Sheet
Rev. E | Page 36 of 115
–40
–100
–90
–70
–80
–50
–60
OB
SE
RV
AT
ION
RE
CE
IVE
R I
MA
GE
(d
Bc)
0 10 305 20 2515
OBSERVATION RECEIVER ATTENUATION (dB)
+110°C, ORx1+110°C, ORx2+110°C, ORx3+110°C, ORx4
+25°C, ORx1+25°C, ORx2+25°C, ORx3+25°C, ORx4
–40°C, ORx1–40°C, ORx2–40°C, ORx3–40°C, ORx4
20043-067
Figure 63. Observation Receiver Image vs. Observation Receiver Attenuation, 20 MHz Offset, Tracking Calibration Active, Sample Rate = 491.52 MSPS
–40
–120
–80
–50
–60
–100
–90
–110
–70
–100 100–20 60 80–60 20–40 40–80 0
OB
SE
RV
AT
ION
RE
CE
IVE
R H
D2,
LE
FT
SID
E (
dB
c)
BASEBAND OFFSET FREQUENCY (MHz)
+110°C, ORx1+110°C, ORx2+110°C, ORx3+110°C, ORx4
+25°C, ORx1+25°C, ORx2+25°C, ORx3+25°C, ORx4
–40°C, ORx1–40°C, ORx2–40°C, ORx3–40°C, ORx4
20043-070
Figure 64. Observation Receiver HD2, Left Side vs. Baseband Offset Frequency, −5 dBFS Input Signal, Distortion Tone Measured Left of 0 Hz
–40
–120
–80
–50
–60
–100
–90
–110
–70
–100 100–20 60 80–60 20–40 40–80 0
OB
SE
RV
AT
ION
RE
CE
IVE
R H
D2,
RIG
HT
SID
E (
dB
c)
BASEBAND OFFSET FREQUENCY (MHz)
+110°C, ORx1+110°C, ORx2+110°C, ORx3+110°C, ORx4
+25°C, ORx1+25°C, ORx2+25°C, ORx3+25°C, ORx4
–40°C, ORx1–40°C, ORx2–40°C, ORx3–40°C, ORx4
20043-071
Figure 65. Observation Receiver HD2, Right Side vs. Baseband Offset Frequency, −5 dBFS Input Signal, Distortion Tone Measured Right of 0 Hz
–40
–120
–80
–50
–60
–100
–90
–110
–70
–60 60–20 20–40 400
OB
SE
RV
AT
ION
RE
CE
IVE
R H
D3,
LE
FT
SID
E (
dB
c)
BASEBAND OFFSET FREQUENCY (MHz)
+110°C, ORx1+110°C, ORx2+110°C, ORx3+110°C, ORx4
+25°C, ORx1+25°C, ORx2+25°C, ORx3+25°C, ORx4
–40°C, ORx1–40°C, ORx2–40°C, ORx3–40°C, ORx4
20043-072
Figure 66. Observation Receiver HD3, Left Side vs. Baseband Offset Frequency, −5 dBFS Input Signal, Distortion Tone Measured Left of 0 Hz
–40
–120
–80
–50
–60
–100
–90
–110
–70
–60 60–20 20–40 400
OB
SE
RV
AT
ION
RE
CE
IVE
R H
D3,
RIG
HT
SID
E (
dB
c)
BASEBAND OFFSET FREQUENCY (MHz)
+110°C, ORx1+110°C, ORx2+110°C, ORx3+110°C, ORx4
+25°C, ORx1+25°C, ORx2+25°C, ORx3+25°C, ORx4
–40°C, ORx1–40°C, ORx2–40°C, ORx3–40°C, ORx4
20043-073
Figure 67. Observation Receiver HD3, Right Side vs. Baseband Offset Frequency, −5 dBFS Input Signal, Distortion Tone Measured Right of 0 Hz
90
40
50
80
70
60
805 905825 865815 885845835 875 895855
OB
SE
RV
AT
ION
RE
CE
IVE
R I
IP2,
f1
+ f
2 (d
Bm
)
TONE 2 FREQUENCY (MHz)
+110°C, ORx1+110°C, ORx2+110°C, ORx3+110°C, ORx4
+25°C, ORx1+25°C, ORx2+25°C, ORx3+25°C, ORx4
–40°C, ORx1–40°C, ORx2–40°C, ORx3–40°C, ORx4
20043-074
Figure 68. Observation Receiver IIP2, f1 + f2 vs. Tone 2 Frequency, Both Tones at −11 dBFS, 0 dB Attenuation, f1 = f2 + 2 MHz
Data Sheet ADRV9010
Rev. E | Page 37 of 115
90
40
50
80
70
60
805 1015865 985835 925895 955
OB
SE
RV
AT
ION
RE
CE
IVE
R I
IP2,
f1
– f2
(d
Bm
)
TONE 2 FREQUENCY (MHz)
+110°C, ORx1+110°C, ORx2+110°C, ORx3+110°C, ORx4
+25°C, ORx1+25°C, ORx2+25°C, ORx3+25°C, ORx4
–40°C, ORx1–40°C, ORx2–40°C, ORx3–40°C, ORx4
20043-075
Figure 69. Observation Receiver IIP2, f1 − f2 vs. Tone 2 Frequency, Both Tones at −11 dBFS, 0 dB Attenuation, f1 = f2 + 2 MHz
90
40
50
80
70
60
10 22070 19040 130100 160
OB
SE
RV
AT
ION
RE
CE
IVE
R I
IP2,
f1
+ f
2 (d
Bm
)
TWO-TONE FREQUENCY SPACING (MHz)
+110°C, ORx1+110°C, ORx2+110°C, ORx3+110°C, ORx4
+25°C, ORx1+25°C, ORx2+25°C, ORx3+25°C, ORx4
–40°C, ORx1–40°C, ORx2–40°C, ORx3–40°C, ORx4
20043-076
Figure 70. Observation Receiver IIP2, f1 + f2 vs. Two-Tone Frequency Spacing, Both Tones at −11 dBFS, 0 dB Attenuation, f2 = 2 MHz
90
40
50
80
70
60
10 22070 19040 130100 160
OB
SE
RV
AT
ION
RE
CE
IVE
R I
IP2,
f1
– f2
(d
Bm
)
TWO-TONE FREQUENCY SPACING (MHz)
+110°C, ORx1+110°C, ORx2+110°C, ORx3+110°C, ORx4
+25°C, ORx1+25°C, ORx2+25°C, ORx3+25°C, ORx4
–40°C, ORx1–40°C, ORx2–40°C, ORx3–40°C, ORx4
20043-077
Figure 71. Observation Receiver IIP2, f1 − f2 vs. Two-Tone Frequency Spacing, Both Tones at −11 dBFS, 0 dB Attenuation, f2 = 2 MHz
100
90
40
50
80
70
60
0 30105 2015 25
OB
SE
RV
AT
ION
RE
CE
IVE
R I
IP2,
f1
+ f
2 (d
Bm
)
OBSERVATION RECEIVER ATTENUATION (dB)
+110°C, ORx1+110°C, ORx2+110°C, ORx3+110°C, ORx4
+25°C, ORx1+25°C, ORx2+25°C, ORx3+25°C, ORx4
–40°C, ORx1–40°C, ORx2–40°C, ORx3–40°C, ORx4
20043-078
Figure 72. Observation Receiver IIP2, f1 + f2 vs. Observation Receiver Attenuation, Both Tones at −11 dBFS, f1 = 102 MHz, f2 = 2 MHz
100
90
40
50
80
70
60
0 30105 2015 25
OB
SE
RV
AT
ION
RE
CE
IVE
R I
IP2,
f1
– f2
(d
Bm
)
OBSERVATION RECEIVER ATTENUATION (dB)
+110°C, ORx1+110°C, ORx2+110°C, ORx3+110°C, ORx4
+25°C, ORx1+25°C, ORx2+25°C, ORx3+25°C, ORx4
–40°C, ORx1–40°C, ORx2–40°C, ORx3–40°C, ORx4
20043-079
Figure 73. Observation Receiver IIP2, f1 − f2 vs. Observation Receiver Attenuation, Both Tones at −11 dBFS, f1 = 102 MHz, f2 = 2 MHz
40
0
20
35
30
10
15
5
25
805 865825 845 855815 835
OB
SE
RV
AT
ION
RE
CE
IVE
R I
IP3,
2f1
+ f
2 (d
Bm
)
TONE 2 FREQUENCY (MHz)
+110°C, ORx1+110°C, ORx2+110°C, ORx3+110°C, ORx4
+25°C, ORx1+25°C, ORx2+25°C, ORx3+25°C, ORx4
–40°C, ORx1–40°C, ORx2–40°C, ORx3–40°C, ORx4
20043-080
Figure 74. Observation Receiver IIP3, 2f1 + f2 vs. Tone 2 Frequency, Both Tones at −11 dBFS, 0 dB Attenuation, f1 = f2 + 2 MHz
ADRV9010 Data Sheet
Rev. E | Page 38 of 115
40
0
20
35
30
10
15
5
25
805 865825 845 855815 835
OB
SE
RV
AT
ION
RE
CE
IVE
R I
IP3,
2f2
+ f
1 (d
Bm
)
TONE 2 FREQUENCY (MHz)
+110°C, ORx1+110°C, ORx2+110°C, ORx3+110°C, ORx4
+25°C, ORx1+25°C, ORx2+25°C, ORx3+25°C, ORx4
–40°C, ORx1–40°C, ORx2–40°C, ORx3–40°C, ORx4
20043-081
Figure 75. Observation Receiver IIP3, 2f2 + f1 vs. Tone 2 Frequency, Both Tones at −11 dBFS, 0 dB Attenuation, f1 = f2 + 2 MHz
40
0
20
35
30
10
15
5
25
805 1015985865 925 955835 895
OB
SE
RV
AT
ION
RE
CE
IVE
R I
IP3,
2f1
– f
2 (d
Bm
)
TONE 2 FREQUENCY (MHz)
+110°C, ORx1+110°C, ORx2+110°C, ORx3+110°C, ORx4
+25°C, ORx1+25°C, ORx2+25°C, ORx3+25°C, ORx4
–40°C, ORx1–40°C, ORx2–40°C, ORx3–40°C, ORx4
20043-082
Figure 76. Observation Receiver IIP3, 2f1 − f2 vs. Tone 2 Frequency, Both Tones at −11 dBFS, 0 dB Attenuation, f1 = f2 + 2 MHz
40
0
20
35
30
10
15
5
25
805 1015985865 925 955835 895
OB
SE
RV
AT
ION
RE
CE
IVE
R I
IP3,
2f2
– f
1 (d
Bm
)
TONE 2 FREQUENCY (MHz)
+110°C, ORx1+110°C, ORx2+110°C, ORx3+110°C, ORx4
+25°C, ORx1+25°C, ORx2+25°C, ORx3+25°C, ORx4
–40°C, ORx1–40°C, ORx2–40°C, ORx3–40°C, ORx4
20043-083
Figure 77. Observation Receiver IIP3, 2f2 − f1 vs. Tone 2 Frequency, Both Tones at −11 dBFS, 0 dB Attenuation, f1 = f2 + 2 MHz
30
0
10
25
20
5
15
10 1007030 9050 6020 8040
OB
SE
RV
AT
ION
RE
CE
IVE
R I
IP3,
2f1
+ f
2 (d
Bm
)
TWO-TONE FREQUENCY SPACING (MHz)
+110°C, ORx1+110°C, ORx2+110°C, ORx3+110°C, ORx4
+25°C, ORx1+25°C, ORx2+25°C, ORx3+25°C, ORx4
–40°C, ORx1–40°C, ORx2–40°C, ORx3–40°C, ORx4
20043-084
Figure 78. Observation Receiver IIP3, 2f1 + f2 vs. Two-Tone Frequency Spacing, Both Tones at −11 dBFS, 0 dB Attenuation, f2 = 2 MHz
30
0
10
25
20
5
15
10 21013050 17090 19011030 15070
OB
SE
RV
AT
ION
RE
CE
IVE
R I
IP3,
2f2
+ f
1 (d
Bm
)
TWO-TONE FREQUENCY SPACING (MHz)
+110°C, ORx1+110°C, ORx2+110°C, ORx3+110°C, ORx4
+25°C, ORx1+25°C, ORx2+25°C, ORx3+25°C, ORx4
–40°C, ORx1–40°C, ORx2–40°C, ORx3–40°C, ORx4
20043-085
Figure 79. Observation Receiver IIP3, 2f2 + f1 vs. Two-Tone Frequency Spacing, Both Tones at −11 dBFS, 0 dB Attenuation, f2 = 2 MHz
30
0
10
25
20
5
15
10 11050 9030 70
OB
SE
RV
AT
ION
RE
CE
IVE
R I
IP3,
2f1
– f
2 (d
Bm
)
TWO-TONE FREQUENCY SPACING (MHz)
+110°C, ORx1+110°C, ORx2+110°C, ORx3+110°C, ORx4
+25°C, ORx1+25°C, ORx2+25°C, ORx3+25°C, ORx4
–40°C, ORx1–40°C, ORx2–40°C, ORx3–40°C, ORx4
20043-086
Figure 80. Observation Receiver IIP3, 2f1 − f2 vs. Two-Tone Frequency Spacing, Both Tones at −11 dBFS, 0 dB Attenuation, f2 = 2 MHz
Data Sheet ADRV9010
Rev. E | Page 39 of 115
30
0
10
25
20
5
15
10 22019070 130 16040 100
OB
SE
RV
AT
ION
RE
CE
IVE
R I
IP3,
2f2
– f
1 (d
Bm
)
TWO-TONE FREQUENCY SPACING (MHz)
+110°C, ORx1+110°C, ORx2+110°C, ORx3+110°C, ORx4
+25°C, ORx1+25°C, ORx2+25°C, ORx3+25°C, ORx4
–40°C, ORx1–40°C, ORx2–40°C, ORx3–40°C, ORx4
20043-087
Figure 81. Observation Receiver IIP3, 2f2 − f1 vs. Two-Tone Frequency Spacing, Both Tones at −11 dBFS, 0 dB Attenuation, f2 = 2 MHz
40
0
20
35
30
10
15
5
25
0 20105 15
OB
SE
RV
AT
ION
RE
CE
IVE
R I
IP3,
2f2
+ f
1 (d
Bm
)
OBSERVATION RECEIVER ATTENUATION (dB)
+110°C, ORx1+110°C, ORx2+110°C, ORx3+110°C, ORx4
+25°C, ORx1+25°C, ORx2+25°C, ORx3+25°C, ORx4
–40°C, ORx1–40°C, ORx2–40°C, ORx3–40°C, ORx4
20043-088
Figure 82. Observation Receiver IIP3, 2f2 + f1 vs. Observation Receiver Attenuation, Both Tones at −11 dBFS, f1 = 122 MHz, f2 = 2 MHz
40
0
20
35
30
10
15
5
25
0 20105 15
OB
SE
RV
AT
ION
RE
CE
IVE
R I
IP3,
2f2
– f
1 (d
Bm
)
OBSERVATION RECEIVER ATTENUATION (dB)
+110°C, ORx1+110°C, ORx2+110°C, ORx3+110°C, ORx4
+25°C, ORx1+25°C, ORx2+25°C, ORx3+25°C, ORx4
–40°C, ORx1–40°C, ORx2–40°C, ORx3–40°C, ORx4
20043-089
Figure 83. Observation Receiver IIP3, 2f2 − f1 vs. Observation Receiver Attenuation, Both Tones at −11 dBFS, f1 = 122 MHz, f2 = 2 MHz
ADRV9010 Data Sheet
Rev. E | Page 40 of 115
1800 MHz BAND The temperature settings refer to the die temperature. All LO frequencies set to 1800 MHz, unless otherwise noted.
7.0
3.0
3.5
4.0
4.5
5.0
5.5
6.0
6.5
1500 1600 1700 1800 1900 2000
TR
AN
SM
ITT
ER
CW
OU
TP
UT
PO
WE
R (
dB
m)
TRANSMITTER LO FREQUENCY (MHz)
+110°C+25°C–40°C
20043-090
Figure 84. Transmitter CW Output Power vs. Transmitter LO Frequency, 10 MHz Offset, 0 dB Attenuation
0
–100
–80
–60
–90
–70
–50
–40
–20
–30
–10
1300
1800
2200
1700
2100
1600
1500
2000
1400
1900
2300
TR
AN
SM
ITT
ER
OU
TP
UT
PO
WE
R S
PE
CT
RU
M (
dB
m)
FREQUENCY (MHz)
SIGNALNOISE FLOOR
20043-091
Figure 85. Transmitter Output Power Spectrum, Tx1, 5 MHz LTE, 10 MHz Offset, −10 dBFS RMS, 1 MHz Resolution Bandwidth, T = 25°C
–40
–100
–90
–80
–70
–60
–50
–100 –80 –60 –40 0 40 80–20 20 60 100
TR
AN
SM
ITT
ER
IM
AG
E R
EJE
CT
ION
(d
Bc)
BASEBAND OFFSET FREQUENCY (MHz)
+110°C, Tx1+110°C, Tx2+110°C, Tx3+110°C, Tx4
+25°C, Tx1+25°C, Tx2+25°C, Tx3+25°C, Tx4
–40°C, Tx1–40°C, Tx2–40°C, Tx3–40°C, Tx4
20043-092
Figure 86. Transmitter Image Rejection vs. Baseband Offset Frequency, 0 dB Attenuation, QEC Tracking Enabled
–100
–180
–160
–140
–170
–150
–130
–120
–110
0 5 10 15 20
TR
AN
SM
ITT
ER
NO
ISE
(d
Bm
/Hz)
TRANSMITTER ATTENUATION (dB)
+110°C, Tx1+110°C, Tx2+110°C, Tx3+110°C, Tx4
+25°C, Tx1+25°C, Tx2+25°C, Tx3+25°C, Tx4
–40°C, Tx1–40°C, Tx2–40°C, Tx3–40°C, Tx4
20043-093
Figure 87. Transmitter Noise vs. Transmitter Attenuation, 50 MHz Offset Frequency
1.0
–0.1
0.1
0.3
0.5
0
0.2
0.4
0.6
0.7
0.8
0.9
–250 –200 –150 –100 0 100 200–50 50 150 250
TR
AN
SM
ITT
ER
PA
SS
BA
ND
FL
AT
NE
SS
(d
B)
BASEBAND OFFSET FREQUENCY (MHz)
+110°C+25°C–40°C
20043-094
Figure 88. Transmitter Pass Band Flatness vs. Baseband Offset Frequency
–40
–80
–70
–60
–75
–65
–55
–50
–45
0 5 10 15 20
AD
JAC
EN
T C
HA
NN
EL
PO
WE
R L
EV
EL
(d
Bc)
TRANSMITTER ATTENUATION (dB)
+110°C+25°C–40°C
20043-095
Figure 89. Adjacent Channel Power Level vs. Transmitter Attenuation, −10 MHz Baseband Offset, 20 MHz LTE, PAR = 12 dB,
Loop Filter Bandwidth = 50 kHz, Loop Filter Phase Margin = 40°
Data Sheet ADRV9010
Rev. E | Page 41 of 115
–40
–80
–70
–60
–75
–65
–55
–50
–45
0 5 10 15 20
AD
JAC
EN
T C
HA
NN
EL
PO
WE
R L
EV
EL
(d
Bc)
TRANSMITTER ATTENUATION (dB)
+110°C+25°C–40°C
20043-096
Figure 90. Adjacent Channel Power Level vs. Transmitter Attenuation, 90 MHz Baseband Offset, 20 MHz LTE, PAR = 12 dB,
Loop Filter Bandwidth = 50 kHz, Loop Filter Phase Margin = 40°
–60
–105
–95
–80
–85
–100
–90
–75
–70
–65
0 6 12 184 10 162 8 14 20
TR
AN
SM
ITT
ER
HD
2 (d
Bc)
TRANSMITTER ATTENUATION (dB)
+110°C, UPPER HD2+25°C, UPPER HD2–40°C, UPPER HD2+110°C, LOWER HD2+25°C, LOWER HD2–40°C, LOWER HD2
20043-097
Figure 91. Transmitter HD2 vs. Transmitter Attenuation, 10 MHz Offset
–60
–120
–80
–100
–110
–90
–70
0 6 12 184 10 162 8 14 20
TR
AN
SM
ITT
ER
HD
3 (d
Bc)
TRANSMITTER ATTENUATION (dB)
+110°C, UPPER HD3+25°C, UPPER HD3–40°C, UPPER HD3+110°C, LOWER HD3+25°C, LOWER HD3–40°C, LOWER HD3
20043-098
Figure 92. Transmitter HD3 vs. Transmitter Attenuation, 10 MHz Offset
0.05
–0.05
–0.04
–0.02
0
–0.03
–0.01
0.01
0.02
0.03
0.04
0 4 8 12 20 2816 24 32
TR
AN
SM
ITT
ER
AT
TE
NU
AT
OR
ST
EP
ER
RO
R (
dB
)
TRANSMITTER ATTENUATION (dB)
+110°C+25°C–40°C
20043-099
Figure 93. Transmitter Attenuator Step Error vs. Transmitter Attenuation, 10 MHz Offset
–40
–50
–48
–46
–44
–42
0 5 10 15 20
TR
AN
SM
ITT
ER
ER
RO
R V
EC
TO
R M
AG
NIT
UD
E (
dB
)
TRANSMITTER ATTENUATION (dB)
+110°C, Tx1+110°C, Tx2+110°C, Tx3+110°C, Tx4
+25°C, Tx1+25°C, Tx2+25°C, Tx3+25°C, Tx4
–40°C, Tx1–40°C, Tx2–40°C, Tx3–40°C, Tx4
20043-100
Figure 94. Transmitter Error Vector Magnitude vs. Transmitter Attenuation, 20 MHz LTE Signal Centered at LO Frequency, Sample Rate = 491.52 MSPS, QEC
Tracking Enabled, Loop Filter Bandwidth = 50 kHz, Loop Filter Phase Margin = 40°
45
40
–10
0
10
20
30
35
–5
5
15
25
0 8 16 24 324 12 20 28
TR
AN
SM
ITT
ER
OIP
3, 2
f1 –
f2
(dB
m)
TRANSMITTER ATTENUATION (dB)
+110°C, Tx1+110°C, Tx2+110°C, Tx3+110°C, Tx4
+25°C, Tx1+25°C, Tx2+25°C, Tx3+25°C, Tx4
–40°C, Tx1–40°C, Tx2–40°C, Tx3–40°C, Tx4
20043-101
Figure 95. Transmitter OIP3, 2f1 − f2 vs. Transmitter Attenuation, 15 dB Digital Backoff per Tone, f1 = 50.5 MHz, f2 = 55.5 MHz
ADRV9010 Data Sheet
Rev. E | Page 42 of 115
45
40
–10
0
10
20
30
35
–5
5
15
25
0 8 16 24 324 12 20 28
TR
AN
SM
ITT
ER
OIP
3, 2
f2 –
f1
(dB
m)
TRANSMITTER ATTENUATION (dB)
+110°C, Tx1+110°C, Tx2+110°C, Tx3+110°C, Tx4
+25°C, Tx1+25°C, Tx2+25°C, Tx3+25°C, Tx4
–40°C, Tx1–40°C, Tx2–40°C, Tx3–40°C, Tx4
20043-102
Figure 96. Transmitter OIP3, 2f2 − f1 vs. Transmitter Attenuation, 15 dB Digital Backoff per Tone, f1 = 50.5 MHz, f2 = 55.5 MHz
50
45
40
0
10
20
30
35
5
15
25
10 50 90 130 19017030 70 110 150
TR
AN
SM
ITT
ER
OIP
3, 2
f1 –
f2
(dB
m)
f1 BASEBAND OFFSET TONE FREQUENCY (MHz)
+110°C, Tx1+110°C, Tx2+110°C, Tx3+110°C, Tx4
+25°C, Tx1+25°C, Tx2+25°C, Tx3+25°C, Tx4
–40°C, Tx1–40°C, Tx2–40°C, Tx3–40°C, Tx4
20043-103
Figure 97. Transmitter OIP3, 2f1 − f2 vs. f1 Baseband Offset Tone Frequency, f2 = f1 + 5 MHz, 15 dB Digital Backoff per Tone
50
45
40
0
10
20
30
35
5
15
25
10 50 90 130 19017030 70 110 150
TR
AN
SM
ITT
ER
OIP
3, 2
f2 –
f1
(dB
m)
f1 BASEBAND OFFSET TONE FREQUENCY (MHz)
+110°C, Tx1+110°C, Tx2+110°C, Tx3+110°C, Tx4
+25°C, Tx1+25°C, Tx2+25°C, Tx3+25°C, Tx4
–40°C, Tx1–40°C, Tx2–40°C, Tx3–40°C, Tx4
20043-104
Figure 98. Transmitter OIP3, 2f2 − f1 vs. f1 Baseband Offset Tone Frequency, f2 = f1 + 5 MHz, 15 dB Digital Backoff per Tone
50
45
40
0
10
20
30
35
5
15
25
10 50 90 130 19017030 70 110 150
TR
AN
SM
ITT
ER
OIP
3, 2
f1 +
f2
(dB
m)
f1 BASEBAND OFFSET TONE FREQUENCY (MHz)
+110°C, Tx1+110°C, Tx2+110°C, Tx3+110°C, Tx4
+25°C, Tx1+25°C, Tx2+25°C, Tx3+25°C, Tx4
–40°C, Tx1–40°C, Tx2–40°C, Tx3–40°C, Tx4
20043-105
Figure 99. Transmitter OIP3, 2f1 + f2 vs. f1 Baseband Offset Tone Frequency, f2 = f1 + 5 MHz, 15 dB Digital Backoff per Tone
50
45
40
0
10
20
30
35
5
15
25
10 50 90 130 19017030 70 110 150
TR
AN
SM
ITT
ER
OIP
3, 2
f2 +
f1
(dB
m)
f1 BASEBAND OFFSET TONE FREQUENCY (MHz)
+110°C, Tx1+110°C, Tx2+110°C, Tx3+110°C, Tx4
+25°C, Tx1+25°C, Tx2+25°C, Tx3+25°C, Tx4
–40°C, Tx1–40°C, Tx2–40°C, Tx3–40°C, Tx4
20043-106
Figure 100. Transmitter OIP3, 2f2 + f1 vs. f1 Baseband Offset Tone Frequency, f2 = f1 + 5 MHz, 15 dB Digital Backoff per Tone
120
50
70
90
60
80
100
110
1500 1550 1650 17501600 1700 1800
TR
AN
SM
ITT
ER
TO
TR
AN
SM
ITT
ER
IS
OL
AT
ION
(d
B)
TRANSMITTER LO FREQUENCY (MHz)
Tx1 TO Tx2Tx2 TO Tx1Tx3 TO Tx1Tx4 TO Tx1
Tx1 TO Tx3Tx2 TO Tx3Tx3 TO Tx2Tx4 TO Tx2
Tx1 TO Tx4Tx2 TO Tx4Tx3 TO Tx4Tx4 TO Tx3
20043-108
Figure 101. Transmitter to Transmitter Isolation vs. Transmitter LO Frequency
Data Sheet ADRV9010
Rev. E | Page 43 of 115
130
120
50
70
90
60
80
100
110
1500 1550 1650 17501600 1700 1800
TR
AN
SM
ITT
ER
TO
RE
CE
IVE
R I
SO
LA
TIO
N (
dB
)
RECEIVER LO FREQUENCY (MHz)
Tx1 TO Rx1Tx2 TO Rx1Tx3 TO Rx1Tx4 TO Rx1
Tx1 TO Rx2Tx2 TO Rx2Tx3 TO Rx2Tx4 TO Rx2
Tx1 TO Rx3Tx2 TO Rx3Tx3 TO Rx3Tx4 TO Rx3
Tx1 TO Rx4Tx2 TO Rx4Tx3 TO Rx4Tx4 TO Rx4
20043-109
Figure 102. Transmitter to Receiver Isolation vs. Receiver LO Frequency
140
130
120
50
70
90
60
80
100
110
1500 1550 1650 17501600 1700 1800
TR
AN
SM
ITT
ER
TO
OB
SE
RV
AT
ION
RE
CE
IVE
R I
SO
LA
TIO
N (
dB
)
TRANSMITTER LO FREQUENCY (MHz)
Tx1 TO ORx1Tx2 TO ORx1Tx3 TO ORx1Tx4 TO ORx1
Tx1 TO ORx2Tx2 TO ORx2Tx3 TO ORx2Tx4 TO ORx2
Tx1 TO ORx3Tx2 TO ORx3Tx3 TO ORx3Tx4 TO ORx3
Tx1 TO ORx4Tx2 TO ORx4Tx3 TO ORx4Tx4 TO ORx4
20043-110
Figure 103. Transmitter to Observation Receiver Isolation vs. Transmitter LO Frequency
120
50
70
90
60
80
100
110
1500 1550 1650 17501600 1700 1800
RE
CE
IVE
R T
O R
EC
EIV
ER
IS
OL
AT
ION
(d
B)
RECEIVER LO FREQUENCY (MHz)
Rx1 TO Rx2Rx2 TO Rx1Rx3 TO Rx1Rx4 TO Rx1
Rx1 TO Rx3Rx2 TO Rx3Rx3 TO Rx2Rx4 TO Rx2
Rx1 TO Rx4Rx2 TO Rx4Rx3 TO Rx4Rx4 TO Rx3
20043-111
Figure 104. Receiver to Receiver Isolation vs. Receiver LO Frequency
50
0
25
5
35
45
15
10
20
30
40
0 10 305 20 2515
RE
CE
IVE
R I
NT
EG
RA
TE
D N
OIS
E F
IGU
RE
(d
B)
RECEIVER ATTENUATION (dB)
+110°C, Rx1+110°C, Rx2+110°C, Rx3+110°C, Rx4
+25°C, Rx1+25°C, Rx2+25°C, Rx3+25°C, Rx4
–40°C, Rx1–40°C, Rx2–40°C, Rx3–40°C, Rx4
20043-112
Figure 105. Receiver Integrated Noise Figure vs. Receiver Attenuation, 20 MHz Offset, 200 MHz Bandwidth, Sample Rate = 245.76 MSPS,
Integration Bandwidth = 500 kHz to 100 MHz
25
0
5
10
15
20
–100 –80 –60 –40 0 40 80–20 20 60 100
RE
CE
IVE
R I
NT
EG
RA
TE
D N
OIS
E F
IGU
RE
(d
B)
BASEBAND OFFSET FREQUENCY (MHz)
+110°C+25°C–40°C
20043-114
Figure 106. Receiver Integrated Noise Figure vs. Baseband Offset Frequency, 200 MHz Bandwidth, Sample Rate = 245.76 MSPS, Integrated in 200 kHz Steps
–40
–100
–80
–90
–70
–60
–50
1500 1600 1700 1800 20001900
RE
CE
IVE
R L
O L
EA
KA
GE
(d
Bm
)
RECEIVER LO FREQUENCY (MHz)
+110°C+25°C–40°C
20043-115
Figure 107. Receiver LO Leakage vs. Receiver LO Frequency, Attenuation = 0 dB, Sample Rate = 245.76 MSPS
ADRV9010 Data Sheet
Rev. E | Page 44 of 115
20
15
–15
–10
0
10
–5
5
0 10 305 20 2515
RE
CE
IVE
R G
AIN
(d
B)
RECEIVER ATTENUATION (dB)
+110°C, Rx1+110°C, Rx2+110°C, Rx3+110°C, Rx4
+25°C, Rx1+25°C, Rx2+25°C, Rx3+25°C, Rx4
–40°C, Rx1–40°C, Rx2–40°C, Rx3–40°C, Rx4
20043-116
Figure 108. Receiver Gain vs. Receiver Attenuation, 20 MHz Offset, 200 MHz Bandwidth, Sample Rate = 245.76 MSPS
20
15
17
16
18
19
1500 1600 1700 1800 20001900
RECEIVER LO FREQUENCY (MHz)
RE
CE
IVE
R G
AIN
(d
B)
+110°C, Rx1+110°C, Rx2+110°C, Rx3+110°C, Rx4
+25°C, Rx1+25°C, Rx2+25°C, Rx3+25°C, Rx4
–40°C, Rx1–40°C, Rx2–40°C, Rx3–40°C, Rx4
20043-117
Figure 109. Receiver Gain vs. Receiver LO Frequency, 10 MHz Offset, 200 MHz Bandwidth, Sample Rate = 245.76 MSPS
0.20
–0.20
–0.05
–0.15
0.05
0.15
–0.10
0
0.10
0 5 10 15 302520
RECEIVER ATTENUATION (dB)
RE
CE
IVE
R G
AIN
ST
EP
ER
RO
R (
dB
)
+110°C, Rx1+110°C, Rx2+110°C, Rx3+110°C, Rx4
+25°C, Rx1+25°C, Rx2+25°C, Rx3+25°C, Rx4
–40°C, Rx1–40°C, Rx2–40°C, Rx3–40°C, Rx4
20043-118
Figure 110. Receiver Gain Step Error vs. Receiver Attenuation, 20 MHz Offset, −5 dBFS Input Signal
0.5
–0.5
–0.4
–0.2
0
–0.3
–0.1
0.1
0.2
0.3
0.4
NO
RM
AL
IZE
D R
EC
EIV
ER
FL
AT
NE
SS
(d
B) +110°C
+25°C–40°C
–100 –80 –60 –40 0 40 80–20 20 60 100
BASEBAND OFFSET FREQUENCY (MHz) 20043-119
Figure 111. Normalized Receiver Flatness vs. Baseband Offset Frequency, −5 dBFS Input Signal
–40
–100
–90
–70
–80
–60
–50
RE
CE
IVE
R I
MA
GE
(d
Bc)
–100 –80 –60 –40 0 40 80–20 20 60 100
BASEBAND OFFSET FREQUENCY (MHz)
+110°C, Rx1+110°C, Rx2+110°C, Rx3+110°C, Rx4
+25°C, Rx1+25°C, Rx2+25°C, Rx3+25°C, Rx4
–40°C, Rx1–40°C, Rx2–40°C, Rx3–40°C, Rx4
20043-120
Figure 112. Receiver Image vs. Baseband Offset Frequency, Tracking Calibration Active, Sample Rate = 245.76 MSPS, −5 dBFS Input Signal
–40
–100
–90
–70
–80
–60
–50
RE
CE
IVE
R I
MA
GE
(d
Bc)
+110°C, Rx1+110°C, Rx2+110°C, Rx3+110°C, Rx4
+25°C, Rx1+25°C, Rx2+25°C, Rx3+25°C, Rx4
–40°C, Rx1–40°C, Rx2–40°C, Rx3–40°C, Rx4
0 5 10 15 302520
RECEIVER ATTENUATION (dB) 20043-121
Figure 113. Receiver Image vs. Receiver Attenuation, 20 MHz Offset, Tracking Calibration Active, Sample Rate = 245.76 MSPS, −5 dBFS Input Signal
Data Sheet ADRV9010
Rev. E | Page 45 of 115
–40
–110
–100
–90
–70
–80
–60
–50
RE
CE
IVE
R D
C O
FF
SE
T (
dB
FS
)
+110°C, Rx1+110°C, Rx2+110°C, Rx3+110°C, Rx4
+25°C, Rx1+25°C, Rx2+25°C, Rx3+25°C, Rx4
–40°C, Rx1–40°C, Rx2–40°C, Rx3–40°C, Rx4
0 5 10 15 302520
RECEIVER ATTENUATION (dB) 20043-123
Figure 114. Receiver DC Offset vs. Receiver Attenuation, 20 MHz Offset, −5 dBFS Input Signal
–40
–120
–100
–110
–90
–70
–80
–60
–50
RE
CE
IVE
R H
D2,
LE
FT
SID
E (
dB
c)
+110°C, Rx1+110°C, Rx2+110°C, Rx3+110°C, Rx4
+25°C, Rx1+25°C, Rx2+25°C, Rx3+25°C, Rx4
–40°C, Rx1–40°C, Rx2–40°C, Rx3–40°C, Rx4
–60 –40 –20 0 604020
BASEBAND OFFSET FREQUENCY (MHz) 20043-124
Figure 115. Receiver HD2, Left Side vs. Baseband Offset Frequency, −5 dBFS Input Signal, Distortion Tone Measured Left of 0 Hz
(HD2 Canceller Not Enabled)
–40
–120
–100
–110
–90
–70
–80
–60
–50
RE
CE
IVE
R H
D2,
RIG
HT
SID
E (
dB
c)
+110°C, Rx1+110°C, Rx2+110°C, Rx3+110°C, Rx4
+25°C, Rx1+25°C, Rx2+25°C, Rx3+25°C, Rx4
–40°C, Rx1–40°C, Rx2–40°C, Rx3–40°C, Rx4
–60 –40 –20 0 604020
BASEBAND OFFSET FREQUENCY (MHz) 20043-125
Figure 116. Receiver HD2, Right Side vs. Baseband Offset Frequency, −5 dBFS Input Signal, Distortion Tone Measured Right of 0 Hz
(HD2 Canceller Not Enabled)
–40
–120
–100
–110
–90
–70
–80
–60
–50
RE
CE
IVE
R H
D3,
LE
FT
SID
E (
dB
c)
+110°C, Rx1+110°C, Rx2+110°C, Rx3+110°C, Rx4
+25°C, Rx1+25°C, Rx2+25°C, Rx3+25°C, Rx4
–40°C, Rx1–40°C, Rx2–40°C, Rx3–40°C, Rx4
–40 –30 –20 –10 0 40302010
BASEBAND OFFSET FREQUENCY (MHz) 20043-126
Figure 117. Receiver HD3, Left Side vs. Baseband Offset Frequency, −5 dBFS Input Signal, Distortion Tone Measured Left of 0 Hz
–40
–120
–100
–110
–90
–70
–80
–60
–50
RE
CE
IVE
R H
D3,
RIG
HT
SID
E (
dB
c)
+110°C, Rx1+110°C, Rx2+110°C, Rx3+110°C, Rx4
+25°C, Rx1+25°C, Rx2+25°C, Rx3+25°C, Rx4
–40°C, Rx1–40°C, Rx2–40°C, Rx3–40°C, Rx4
–40 –30 –20 –10 0 40302010
BASEBAND OFFSET FREQUENCY (MHz) 20043-127
Figure 118. Receiver HD3, Right Side vs. Baseband Offset Frequency, −5 dBFS Input Signal, Distortion Tone Measured Right of 0 Hz
90
50
60
55
65
75
70
80
85
RE
CE
IVE
R I
IP2,
f1
+ f
2 (d
Bm
)
+110°C, Rx1+110°C, Rx2+110°C, Rx3+110°C, Rx4
+25°C, Rx1+25°C, Rx2+25°C, Rx3+25°C, Rx4
–40°C, Rx1–40°C, Rx2–40°C, Rx3–40°C, Rx4
1805 1815 1825 1835 1845
TONE 2 FREQUENCY (MHz) 20043-128
Figure 119. Receiver IIP2, f1 + f2 vs. Tone 2 Frequency, Both Tones at −11 dBFS, 0 dB Attenuation, f1 = f2 + 2 MHz
ADRV9010 Data Sheet
Rev. E | Page 46 of 115
90
50
60
55
65
75
70
80
85
RE
CE
IVE
R I
IP2,
f1
– f2
(d
Bm
)
+110°C, Rx1+110°C, Rx2+110°C, Rx3+110°C, Rx4
+25°C, Rx1+25°C, Rx2+25°C, Rx3+25°C, Rx4
–40°C, Rx1–40°C, Rx2–40°C, Rx3–40°C, Rx4
1805 1825 1845 1865 189518851815 1835 1855 1875
TONE 2 FREQUENCY (MHz) 20043-129
Figure 120. Receiver IIP2, f1 − f2 vs. Tone 2 Frequency, Both Tones at −11 dBFS, 0 dB Attenuation, f1 = f2 + 2 MHz
90
50
60
55
65
75
70
80
85
RE
CE
IVE
R I
IP2,
f1
+ f
2 (d
Bm
)
+110°C, Rx1+110°C, Rx2+110°C, Rx3+110°C, Rx4
+25°C, Rx1+25°C, Rx2+25°C, Rx3+25°C, Rx4
–40°C, Rx1–40°C, Rx2–40°C, Rx3–40°C, Rx4
10 30 50 70 9020 40 60 80
TWO-TONE FREQUENCY SPACING (MHz) 20043-130
Figure 121. Receiver IIP2, f1 + f2 vs. Two-Tone Frequency Spacing, Both Tones at −11 dBFS, 0 dB Attenuation, f2 = 2 MHz
80
50
60
55
65
75
70
RE
CE
IVE
R I
IP2,
f1
– f2
(d
Bm
)
+110°C, Rx1+110°C, Rx2+110°C, Rx3+110°C, Rx4
+25°C, Rx1+25°C, Rx2+25°C, Rx3+25°C, Rx4
–40°C, Rx1–40°C, Rx2–40°C, Rx3–40°C, Rx4
10 30 50 70 9020 40 60 80
TWO-TONE FREQUENCY SPACING (MHz) 20043-131
Figure 122. Receiver IIP2, f1 − f2 vs. Two-Tone Frequency Spacing, Both Tones at −11 dBFS, 0 dB Attenuation, f2 = 2 MHz
100
60
70
65
75
85
80
90
95
RE
CE
IVE
R I
IP2,
f1
+ f
2 (d
Bm
)
+110°C, Rx1+110°C, Rx2+110°C, Rx3+110°C, Rx4
+25°C, Rx1+25°C, Rx2+25°C, Rx3+25°C, Rx4
–40°C, Rx1–40°C, Rx2–40°C, Rx3–40°C, Rx4
0 10 305 20 2515
RECEIVER ATTENUATION (dB) 20043-132
Figure 123. Receiver IIP2, f1 + f2 vs. Receiver Attenuation, Both Tones at −11 dBFS, f1 = 92 MHz, f2 = 2 MHz
100
60
70
65
75
85
80
90
95
RE
CE
IVE
R I
IP2,
f1
– f2
(d
Bm
)
+110°C, Rx1+110°C, Rx2+110°C, Rx3+110°C, Rx4
+25°C, Rx1+25°C, Rx2+25°C, Rx3+25°C, Rx4
–40°C, Rx1–40°C, Rx2–40°C, Rx3–40°C, Rx4
0 10 305 20 2515
RECEIVER ATTENUATION (dB) 20043-133
Figure 124. Receiver IIP2, f1 − f2 vs. Receiver Attenuation, Both Tones at −11 dBFS, f1 = 92 MHz, f2 = 2 MHz
40
0
10
5
15
25
20
30
35
RE
CE
IVE
R I
IP3,
2f1
+ f
2 (d
Bm
)
+110°C, Rx1+110°C, Rx2+110°C, Rx3+110°C, Rx4
+25°C, Rx1+25°C, Rx2+25°C, Rx3+25°C, Rx4
–40°C, Rx1–40°C, Rx2–40°C, Rx3–40°C, Rx4
1805 1810 1815 1820 1825
TONE 2 FREQUENCY (MHz) 20043-134
Figure 125. Receiver IIP3, 2f1 + f2 vs. Tone 2 Frequency, Both Tones at −11 dBFS, 0 dB Attenuation, f1 = f2 + 2 MHz
Data Sheet ADRV9010
Rev. E | Page 47 of 115
40
0
10
5
15
25
20
30
35
RE
CE
IVE
R I
IP3,
2f2
+ f
1 (d
Bm
)
+110°C, Rx1+110°C, Rx2+110°C, Rx3+110°C, Rx4
+25°C, Rx1+25°C, Rx2+25°C, Rx3+25°C, Rx4
–40°C, Rx1–40°C, Rx2–40°C, Rx3–40°C, Rx4
1805 1810 1815 1820 1825
TONE 2 FREQUENCY (MHz) 20043-135
Figure 126. Receiver IIP3, 2f2 + f1 vs. Tone 2 Frequency, Both Tones at −11 dBFS, 0 dB Attenuation, f1 = f2 + 2 MHz
40
0
10
5
15
25
20
30
35
RE
CE
IVE
R I
IP3,
2f1
– f
2 (d
Bm
)
+110°C, Rx1+110°C, Rx2+110°C, Rx3+110°C, Rx4
+25°C, Rx1+25°C, Rx2+25°C, Rx3+25°C, Rx4
–40°C, Rx1–40°C, Rx2–40°C, Rx3–40°C, Rx4
1805 1825 1845 1865 189518851815 1835 1855 1875
TONE 2 FREQUENCY (MHz) 20043-136
Figure 127. Receiver IIP3, 2f1 − f2 vs. Tone 2 Frequency, Both Tones at −11 dBFS, 0 dB Attenuation, f1 = f2 + 2 MHz
40
0
10
5
15
25
20
30
35
RE
CE
IVE
R I
IP3,
2f2
– f
1 (d
Bm
)
+110°C, Rx1+110°C, Rx2+110°C, Rx3+110°C, Rx4
+25°C, Rx1+25°C, Rx2+25°C, Rx3+25°C, Rx4
–40°C, Rx1–40°C, Rx2–40°C, Rx3–40°C, Rx4
1805 1825 1845 1865 189518851815 1835 1855 1875
TONE 2 FREQUENCY (MHz) 20043-137
Figure 128. Receiver IIP3, 2f2 − f1 vs. Tone 2 Frequency, Both Tones at −11 dBFS, 0 dB Attenuation, f1 = f2 + 2 MHz
35
10
15
25
20
30
RE
CE
IVE
R I
IP3,
2f1
+ f
2 (d
Bm
)
+110°C, Rx1+110°C, Rx2+110°C, Rx3+110°C, Rx4
+25°C, Rx1+25°C, Rx2+25°C, Rx3+25°C, Rx4
–40°C, Rx1–40°C, Rx2–40°C, Rx3–40°C, Rx4
10 20 30 4015 25 35
TWO-TONE FREQUENCY SPACING (MHz) 20043-138
Figure 129. Receiver IIP3, 2f1 + f2 vs. Two-Tone Frequency Spacing, Both Tones at −11 dBFS, 0 dB Attenuation, f2 = 2 MHz
35
10
15
25
20
30
RE
CE
IVE
R I
IP3,
2f2
+ f
1 (d
Bm
)
+110°C, Rx1+110°C, Rx2+110°C, Rx3+110°C, Rx4
+25°C, Rx1+25°C, Rx2+25°C, Rx3+25°C, Rx4
–40°C, Rx1–40°C, Rx2–40°C, Rx3–40°C, Rx4
10 30 60 9020 40 8050 70
TWO-TONE FREQUENCY SPACING (MHz) 20043-139
Figure 130. Receiver IIP3, 2f2 + f1 vs. Two-Tone Frequency Spacing, Both Tones at −11 dBFS, 0 dB Attenuation, f2 = 2 MHz
35
10
15
25
20
30
RE
CE
IVE
R I
IP3,
2f1
– f
2 (d
Bm
)
+110°C, Rx1+110°C, Rx2+110°C, Rx3+110°C, Rx4
+25°C, Rx1+25°C, Rx2+25°C, Rx3+25°C, Rx4
–40°C, Rx1–40°C, Rx2–40°C, Rx3–40°C, Rx4
10 20 35 4015 25 30
TWO-TONE FREQUENCY SPACING (MHz) 20043-140
Figure 131. Receiver IIP3, 2f1 − f2 vs. Two-Tone Frequency Spacing, Both Tones at −11 dBFS, 0 dB Attenuation, f2 = 2 MHz
ADRV9010 Data Sheet
Rev. E | Page 48 of 115
35
10
15
25
20
30
RE
CE
IVE
R I
IP3,
2f2
– f
1 (d
Bm
)
+110°C, Rx1+110°C, Rx2+110°C, Rx3+110°C, Rx4
+25°C, Rx1+25°C, Rx2+25°C, Rx3+25°C, Rx4
–40°C, Rx1–40°C, Rx2–40°C, Rx3–40°C, Rx4
10 30 60 9020 40 8050 70
TWO-TONE FREQUENCY SPACING (MHz) 20043-141
Figure 132. Receiver IIP3, 2f2 − f1 vs. Two-Tone Frequency Spacing, Both Tones at −11 dBFS, 0 dB Attenuation, f2 = 2 MHz
–20
–25
–50
–45
–35
–40
–30
RE
CE
IVE
R E
RR
OR
VE
CT
OR
MA
GN
ITU
DE
(d
B)
+110°C, Rx1+110°C, Rx2+110°C, Rx3+110°C, Rx4
+25°C, Rx1+25°C, Rx2+25°C, Rx3+25°C, Rx4
–40°C, Rx1–40°C, Rx2–40°C, Rx3–40°C, Rx4
–60 –45 –15 5–55 –35 0–25–40 –10–50 –30 –20 –5
RECEIVER INPUT POWER (dBm) 20043-142
Figure 133. Receiver Error Vector Magnitude vs. Receiver Input Power, 20 MHz LTE Signal Centered at LO Frequency, Sample Rate = 245.76 MSPS,
Loop Filter Bandwidth = 50 kHz, Loop Filter Phase Margin = 40°
100 1k 10k 100k 1M 10M–170
–160
–150
–140
–130
–120
–110
–100
–90
–80
LO
PH
AS
E N
OIS
E (
dB
c/H
z)
FREQUENCY OFFSET (Hz) 20043-266
Figure 134. LO Phase Noise vs. Frequency Offset, Loop Bandwidth = 50 kHz, Phase Margin = 85°
100 1k 10k 100k 1M 10M–170
–160
–150
–140
–130
–120
–110
–100
–90
–80
LO
PH
AS
E N
OIS
E (
dB
c/H
z)
FREQUENCY OFFSET (Hz) 20043-267
Figure 135. LO Phase Noise vs. Frequency Offset, Loop Bandwidth = 100 kHz, Phase Margin = 60°
50
45
0
5
25
15
35
40
20
10
30
OB
SE
RV
AT
ION
RE
CE
IVE
R I
NT
EG
RA
TE
DN
OIS
E F
IGU
RE
(d
B)
0 10 205 15
OBSERVATION RECEIVER ATTENUATION (dB)
+110°C, ORx1+110°C, ORx2+110°C, ORx3+110°C, ORx4
+25°C, ORx1+25°C, ORx2+25°C, ORx3+25°C, ORx4
–40°C, ORx1–40°C, ORx2–40°C, ORx3–40°C, ORx4
20043-145
Figure 136. Observation Receiver Integrated Noise Figure vs. Observation Receiver Attenuation, 20 MHz Offset, 450 MHz Bandwidth, Sample Rate = 491.52 MSPS,
Integration Bandwidth = 500 kHz to 100 MHz
35
0
5
25
15
20
10
30
OB
SE
RV
AT
ION
RE
CE
IVE
R I
NT
EG
RA
TE
DN
OIS
E F
IGU
RE
(d
B)
–250 –50 250–150 15050
BASEBAND OFFSET FREQUENCY (MHz)
+110°C+25°C–40°C
20043-147
Figure 137. Observation Receiver Integrated Noise Figure vs. Baseband Offset Frequency, 450 MHz Bandwidth, Sample Rate = 491.52 MSPS,
Integrated in 200 kHz Steps
Data Sheet ADRV9010
Rev. E | Page 49 of 115
–40
–100
–90
–60
–80
–70
–50
OB
SE
RV
AT
ION
RE
CE
IVE
R L
O L
EA
KA
GE
(d
Bm
)
1500 1700 20001600 19001800
OBSERVATION RECEIVER LO FREQUENCY (MHz)
+110°C+25°C–40°C
20043-148
Figure 138. Observation Receiver LO Leakage vs. Observation Receiver LO Frequency, 0 dB Attenuation, Sample Rate = 491.52 MSPS
20
15
–15
–5
5
10
–10
0
OB
SE
RV
AT
ION
RE
CE
IVE
R G
AIN
(d
B)
0 10 305 15 20 25
OBSERVATION RECEIVER ATTENUATION (dB)
+110°C, ORx1+110°C, ORx2+110°C, ORx3+110°C, ORx4
+25°C, ORx1+25°C, ORx2+25°C, ORx3+25°C, ORx4
–40°C, ORx1–40°C, ORx2–40°C, ORx3–40°C, ORx4
20043-149
Figure 139. Observation Receiver Gain vs. Observation Receiver Attenuation, 20 MHz Offset, 450 MHz Bandwidth, Sample Rate = 491.52 MSPS
20
19
15
17
18
16
OB
SE
RV
AT
ION
RE
CE
IVE
R G
AIN
(d
B)
+110°C, ORx1+110°C, ORx2+110°C, ORx3+110°C, ORx4
+25°C, ORx1+25°C, ORx2+25°C, ORx3+25°C, ORx4
–40°C, ORx1–40°C, ORx2–40°C, ORx3–40°C, ORx4
1500 1700 20001600 19001800
OBSERVATION RECEIVER LO FREQUENCY (MHz) 20043-150
Figure 140. Observation Receiver Gain vs. Observation Receiver LO Frequency, 450 MHz Bandwidth, Sample Rate = 491.52 MSPS
0.20
–0.20
–0.15
0.15
–0.05
0.05
0.10
–0.10
0
OB
SE
RV
AT
ION
RE
CE
IVE
R G
AIN
ST
EP
ER
RO
R (
dB
)
0 10 305 20 2515
OBSERVATION RECEIVER ATTENUATION (dB)
+110°C, ORx1+110°C, ORx2+110°C, ORx3+110°C, ORx4
+25°C, ORx1+25°C, ORx2+25°C, ORx3+25°C, ORx4
–40°C, ORx1–40°C, ORx2–40°C, ORx3–40°C, ORx4
20043-151
Figure 141. Observation Receiver Gain Step Error vs. Observation Receiver Attenuation, 20 MHz Offset, −5 dBFS Input Signal
0.6
–0.6
–0.4
0.2
–0.2
0
0.4
NO
RM
AL
IZE
D O
BS
ER
VA
TIO
N R
EC
EIV
ER
FL
AT
NE
SS
(d
B)
–220 –140 220–180 18020 100–60 140–20 60–100
BASEBAND OFFSET FREQUENCY (MHz)
+110°C+25°C–40°C
20043-152
Figure 142. Normalized Observation Receiver Flatness vs. Baseband Offset Frequency, −25 dBm Input Signal, 0 dB Attenuation
–40
–100
–90
–70
–80
–50
–60
OB
SE
RV
AT
ION
RE
CE
IVE
R I
MA
GE
(d
Bc)
–225 –125 225–175 75 175–25 25 125–75
BASEBAND OFFSET FREQUENCY (MHz)
+110°C, ORx1+110°C, ORx2+110°C, ORx3+110°C, ORx4
+25°C, ORx1+25°C, ORx2+25°C, ORx3+25°C, ORx4
–40°C, ORx1–40°C, ORx2–40°C, ORx3–40°C, ORx4
20043-153
Figure 143. Observation Receiver Image vs. Baseband Offset Frequency, Tracking Calibration Active, Sample Rate = 491.52 MSPS
ADRV9010 Data Sheet
Rev. E | Page 50 of 115
–40
–100
–90
–70
–80
–50
–60
OB
SE
RV
AT
ION
RE
CE
IVE
R I
MA
GE
(d
Bc)
0 10 305 20 2515
OBSERVATION RECEIVER ATTENUATION (dB)
+110°C, ORx1+110°C, ORx2+110°C, ORx3+110°C, ORx4
+25°C, ORx1+25°C, ORx2+25°C, ORx3+25°C, ORx4
–40°C, ORx1–40°C, ORx2–40°C, ORx3–40°C, ORx4
20043-154
Figure 144. Observation Receiver Image vs. Observation Receiver Attenuation, 20 MHz Offset, Tracking Calibration Active, Sample Rate = 491.52 MSPS
–40
–120
–80
–50
–60
–100
–90
–110
–70
–100 100–20 60 80–60 20–40 40–80 0
OB
SE
RV
AT
ION
RE
CE
IVE
R H
D2,
LE
FT
SID
E (
dB
c)
BASEBAND OFFSET FREQUENCY (MHz)
+110°C, ORx1+110°C, ORx2+110°C, ORx3+110°C, ORx4
+25°C, ORx1+25°C, ORx2+25°C, ORx3+25°C, ORx4
–40°C, ORx1–40°C, ORx2–40°C, ORx3–40°C, ORx4
20043-157
Figure 145. Observation Receiver HD2, Left Side vs. Baseband Offset Frequency, −5 dBFS Input Signal, Distortion Tone Measured Left of 0 Hz
–40
–120
–80
–50
–60
–100
–90
–110
–70
–100 100–20 60 80–60 20–40 40–80 0
OB
SE
RV
AT
ION
RE
CE
IVE
R H
D2,
RIG
HT
SID
E (
dB
c)
BASEBAND OFFSET FREQUENCY (MHz)
+110°C, ORx1+110°C, ORx2+110°C, ORx3+110°C, ORx4
+25°C, ORx1+25°C, ORx2+25°C, ORx3+25°C, ORx4
–40°C, ORx1–40°C, ORx2–40°C, ORx3–40°C, ORx4
20043-158
Figure 146. Observation Receiver HD2, Right Side vs. Baseband Offset Frequency, −5 dBFS Input Signal, Distortion Tone Measured Right of 0 Hz
–40
–120
–80
–50
–60
–100
–90
–110
–70
–60 60–20 20–40 400
OB
SE
RV
AT
ION
RE
CE
IVE
R H
D3,
LE
FT
SID
E (
dB
c)
BASEBAND OFFSET FREQUENCY (MHz)
+110°C, ORx1+110°C, ORx2+110°C, ORx3+110°C, ORx4
+25°C, ORx1+25°C, ORx2+25°C, ORx3+25°C, ORx4
–40°C, ORx1–40°C, ORx2–40°C, ORx3–40°C, ORx4
20043-159
Figure 147. Observation Receiver HD3, Left Side vs. Baseband Offset Frequency, −5 dBFS Input Signal, Distortion Tone Measured Left of 0 Hz
–40
–120
–80
–50
–60
–100
–90
–110
–70
–60 60–20 20–40 400
OB
SE
RV
AT
ION
RE
CE
IVE
R H
D3,
RIG
HT
SID
E (
dB
c)
BASEBAND OFFSET FREQUENCY (MHz)
+110°C, ORx1+110°C, ORx2+110°C, ORx3+110°C, ORx4
+25°C, ORx1+25°C, ORx2+25°C, ORx3+25°C, ORx4
–40°C, ORx1–40°C, ORx2–40°C, ORx3–40°C, ORx4
20043-160
Figure 148. Observation Receiver HD3, Right Side vs. Baseband Offset Frequency, −5 dBFS Input Signal, Distortion Tone Measured Right of 0 Hz
90
40
70
85
80
60
65
50
55
45
75
1805 19051825 18651815 188518451835 1875 18951855
OB
SE
RV
AT
ION
RE
CE
IVE
R I
IP2,
f1
+ f
2 (d
Bm
)
TONE 2 FREQUENCY (MHz)
+110°C, ORx1+110°C, ORx2+110°C, ORx3+110°C, ORx4
+25°C, ORx1+25°C, ORx2+25°C, ORx3+25°C, ORx4
–40°C, ORx1–40°C, ORx2–40°C, ORx3–40°C, ORx4
20043-161
Figure 149. Observation Receiver IIP2, f1 + f2 vs. Tone 2 Frequency, Both Tones at −11 dBFS, 0 dB Attenuation, f1 = f2 + 2 MHz
Data Sheet ADRV9010
Rev. E | Page 51 of 115
90
40
70
85
80
60
65
50
55
45
75
1805 20151865 19851835 19251895 1955
OB
SE
RV
AT
ION
RE
CE
IVE
R I
IP2,
f1
– f2
(d
Bm
)
TONE 2 FREQUENCY (MHz)
+110°C, ORx1+110°C, ORx2+110°C, ORx3+110°C, ORx4
+25°C, ORx1+25°C, ORx2+25°C, ORx3+25°C, ORx4
–40°C, ORx1–40°C, ORx2–40°C, ORx3–40°C, ORx4
20043-162
Figure 150. Observation Receiver IIP2, f1 − f2 vs. Tone 2 Frequency, Both Tones at −11 dBFS, 0 dB Attenuation, f1 = f2 + 2 MHz
90
40
70
80
60
50
10 22070 19040 130100 160
OB
SE
RV
AT
ION
RE
CE
IVE
R I
IP2,
f1
+ f
2 (d
Bm
)
TWO-TONE FREQUENCY SPACING (MHz)
+110°C, ORx1+110°C, ORx2+110°C, ORx3+110°C, ORx4
+25°C, ORx1+25°C, ORx2+25°C, ORx3+25°C, ORx4
–40°C, ORx1–40°C, ORx2–40°C, ORx3–40°C, ORx4
20043-163
Figure 151. Observation Receiver IIP2, f1 + f2 vs. Two-Tone Frequency Spacing, Both Tones at −11 dBFS, 0 dB Attenuation, f2 = 2 MHz
10 22070 19040 130100 160
OB
SE
RV
AT
ION
RE
CE
IVE
R I
IP2,
f1
– f2
(d
Bm
)
TWO-TONE FREQUENCY SPACING (MHz)
+110°C, ORx1+110°C, ORx2+110°C, ORx3+110°C, ORx4
+25°C, ORx1+25°C, ORx2+25°C, ORx3+25°C, ORx4
–40°C, ORx1–40°C, ORx2–40°C, ORx3–40°C, ORx4
80
40
70
60
65
50
55
45
75
20043-164
Figure 152. Observation Receiver IIP2, f1 − f2 vs. Two-Tone Frequency Spacing, Both Tones at −11 dBFS, 0 dB Attenuation, f2 = 2 MHz
0 30105 2015 25
OB
SE
RV
AT
ION
RE
CE
IVE
R I
IP2,
f1
+ f
2 (d
Bm
)
OBSERVATION RECEIVER ATTENUATION (dB)
+110°C, ORx1+110°C, ORx2+110°C, ORx3+110°C, ORx4
+25°C, ORx1+25°C, ORx2+25°C, ORx3+25°C, ORx4
–40°C, ORx1–40°C, ORx2–40°C, ORx3–40°C, ORx4
100
40
80
60
70
50
90
20043-165
Figure 153. Observation Receiver IIP2, f1 + f2 vs. Observation Receiver Attenuation, Both Tones at −11 dBFS, f1 = 102 MHz, f2 = 2 MHz
0 30105 2015 25
OB
SE
RV
AT
ION
RE
CE
IVE
R I
IP2,
f1
– f2
(d
Bm
)
OBSERVATION RECEIVER ATTENUATION (dB)
+110°C, ORx1+110°C, ORx2+110°C, ORx3+110°C, ORx4
+25°C, ORx1+25°C, ORx2+25°C, ORx3+25°C, ORx4
–40°C, ORx1–40°C, ORx2–40°C, ORx3–40°C, ORx4
100
40
80
60
70
50
90
20043-166
Figure 154. Observation Receiver IIP2, f1 − f2 vs. Observation Receiver Attenuation, Both Tones at −11 dBFS, f1 = 102 MHz, f2 = 2 MHz
1805 186518251815 18451835 1855
OB
SE
RV
AT
ION
RE
CE
IVE
R I
IP3,
2f1
+ f
2 (d
Bm
)
TONE 2 FREQUENCY (MHz)
+110°C, ORx1+110°C, ORx2+110°C, ORx3+110°C, ORx4
+25°C, ORx1+25°C, ORx2+25°C, ORx3+25°C, ORx4
–40°C, ORx1–40°C, ORx2–40°C, ORx3–40°C, ORx4
40
0
25
10
15
5
35
20
30
20043-167
Figure 155. Observation Receiver IIP3, 2f1 + f2 vs. Tone 2 Frequency, Both Tones at −11 dBFS, 0 dB Attenuation, f1 = f2 + 2 MHz
ADRV9010 Data Sheet
Rev. E | Page 52 of 115
1805 186518251815 18451835 1855
OB
SE
RV
AT
ION
RE
CE
IVE
R I
IP3,
2f2
+ f
1 (d
Bm
)
TONE 2 FREQUENCY (MHz)
+110°C, ORx1+110°C, ORx2+110°C, ORx3+110°C, ORx4
+25°C, ORx1+25°C, ORx2+25°C, ORx3+25°C, ORx4
–40°C, ORx1–40°C, ORx2–40°C, ORx3–40°C, ORx4
40
0
25
10
15
5
35
20
30
20043-168
Figure 156. Observation Receiver IIP3, 2f2 + f1 vs. Tone 2 Frequency, Both Tones at −11 dBFS, 0 dB Attenuation, f1 = f2 + 2 MHz
1805 2015196518651835 19251895 1955
OB
SE
RV
AT
ION
RE
CE
IVE
R I
IP3,
2f1
– f
2 (d
Bm
)
TONE 2 FREQUENCY (MHz)
+110°C, ORx1+110°C, ORx2+110°C, ORx3+110°C, ORx4
+25°C, ORx1+25°C, ORx2+25°C, ORx3+25°C, ORx4
–40°C, ORx1–40°C, ORx2–40°C, ORx3–40°C, ORx4
40
0
25
10
15
5
35
20
30
20043-169
Figure 157. Observation Receiver IIP3, 2f1 − f2 vs. Tone 2 Frequency, Both Tones at −11 dBFS, 0 dB Attenuation, f1 = f2 + 2 MHz
1805 2015196518651835 19251895 1955
OB
SE
RV
AT
ION
RE
CE
IVE
R I
IP3,
2f2
– f
1 (d
Bm
)
TONE 2 FREQUENCY (MHz)
+110°C, ORx1+110°C, ORx2+110°C, ORx3+110°C, ORx4
+25°C, ORx1+25°C, ORx2+25°C, ORx3+25°C, ORx4
–40°C, ORx1–40°C, ORx2–40°C, ORx3–40°C, ORx4
40
0
25
10
15
5
35
20
30
20043-170
Figure 158. Observation Receiver IIP3, 2f2 − f1 vs. Tone 2 Frequency, Both Tones at −11 dBFS, 0 dB Attenuation, f1 = f2 + 2 MHz
10 100903020 5040 70 8060
OB
SE
RV
AT
ION
RE
CE
IVE
R I
IP3,
2f1
+ f
2 (d
Bm
)
TWO-TONE FREQUENCY SPACING (MHz)
+110°C, ORx1+110°C, ORx2+110°C, ORx3+110°C, ORx4
+25°C, ORx1+25°C, ORx2+25°C, ORx3+25°C, ORx4
–40°C, ORx1–40°C, ORx2–40°C, ORx3–40°C, ORx4
30
0
25
10
15
5
20
20043-171
Figure 159. Observation Receiver IIP3, 2f1 + f2 vs. Two-Tone Frequency Spacing, Both Tones at −11 dBFS, 0 dB Attenuation, f2 = 2 MHz
10 210170 1905030 9070 130 150110
OB
SE
RV
AT
ION
RE
CE
IVE
R I
IP3,
2f2
+ f
1 (d
Bm
)
TWO-TONE FREQUENCY SPACING (MHz)
+110°C, ORx1+110°C, ORx2+110°C, ORx3+110°C, ORx4
+25°C, ORx1+25°C, ORx2+25°C, ORx3+25°C, ORx4
–40°C, ORx1–40°C, ORx2–40°C, ORx3–40°C, ORx4
30
0
25
10
15
5
20
20043-172
Figure 160. Observation Receiver IIP3, 2f2 + f1 vs. Two-Tone Frequency Spacing, Both Tones at −11 dBFS, 0 dB Attenuation, f2 = 2 MHz
10 1105030 9070
OB
SE
RV
AT
ION
RE
CE
IVE
R I
IP3,
2f1
– f
2 (d
Bm
)
TWO-TONE FREQUENCY SPACING (MHz)
+110°C, ORx1+110°C, ORx2+110°C, ORx3+110°C, ORx4
+25°C, ORx1+25°C, ORx2+25°C, ORx3+25°C, ORx4
–40°C, ORx1–40°C, ORx2–40°C, ORx3–40°C, ORx4
30
0
25
10
15
5
20
20043-173
Figure 161. Observation Receiver IIP3, 2f1 − f2 vs. Two-Tone Frequency Spacing, Both Tones at −11 dBFS, 0 dB Attenuation, f2 = 2 MHz
Data Sheet ADRV9010
Rev. E | Page 53 of 115
10 2201901607040 130100
OB
SE
RV
AT
ION
RE
CE
IVE
R I
IP3,
2f2
– f
1 (d
Bm
)
TWO-TONE FREQUENCY SPACING (MHz)
+110°C, ORx1+110°C, ORx2+110°C, ORx3+110°C, ORx4
+25°C, ORx1+25°C, ORx2+25°C, ORx3+25°C, ORx4
–40°C, ORx1–40°C, ORx2–40°C, ORx3–40°C, ORx4
30
0
25
10
15
5
20
20043-174
Figure 162. Observation Receiver IIP3, 2f2 − f1 vs. Two-Tone Frequency Spacing, Both Tones at −11 dBFS, 0 dB Attenuation, f2 = 2 MHz
0 3025105 2015
OB
SE
RV
AT
ION
RE
CE
IVE
R I
IP3,
2f2
+ f
1 (d
Bm
)
OBSERVATION RECEIVER ATTENUATION (dB)
+110°C, ORx1+110°C, ORx2+110°C, ORx3+110°C, ORx4
+25°C, ORx1+25°C, ORx2+25°C, ORx3+25°C, ORx4
–40°C, ORx1–40°C, ORx2–40°C, ORx3–40°C, ORx4
60
0
50
20
30
10
40
20043-175
Figure 163. Observation Receiver IIP3, 2f2 + f1 vs. Observation Receiver Attenuation, Both Tones at −11 dBFS, f1 = 122 MHz, f2 = 2 MHz
0 3025105 2015
OB
SE
RV
AT
ION
RE
CE
IVE
R I
IP3,
2f2
– f
1 (d
Bm
)
OBSERVATION RECEIVER ATTENUATION (dB)
+110°C, ORx1+110°C, ORx2+110°C, ORx3+110°C, ORx4
+25°C, ORx1+25°C, ORx2+25°C, ORx3+25°C, ORx4
–40°C, ORx1–40°C, ORx2–40°C, ORx3–40°C, ORx4
60
0
50
20
30
10
40
20043-176
Figure 164. Observation Receiver IIP3, 2f2 − f1 vs. Observation Receiver Attenuation, Both Tones at −11 dBFS, f1 = 122 MHz, f2 = 2 MHz
ADRV9010 Data Sheet
Rev. E | Page 54 of 115
2600 MHz BAND The temperature settings refer to the die temperature. All LO frequencies set to 2600 MHz, unless otherwise noted.
3.0
3.5
4.0
4.5
5.0
5.5
6.0
6.5
7.0
1800 1900 2000 2100 2200 2300 2400 2500 2600 2700 2800
TR
AN
SM
ITT
ER
CW
OU
TP
UT
PO
WE
R (
dB
m)
TRANSMITTER LO FREQUENCY (MHz)
–40°C+25°C+110°C
20043-301
Figure 165. Transmitter CW Output Power vs. Transmitter LO Frequency, 10 MHz Offset, 0 dB Attenuation
–100
–90
–80
–70
–60
–50
–40
–30
–20
–10
0
2100 2200 2300 2400 2500 2600 2700 2800 2900 3000 3100
TR
AN
SM
ITT
ER
OU
TP
UT
PO
WE
R S
PE
CT
RU
M (
dB
m)
FREQUENCY (MHz)
SIGNALANALYZER NOISE FLOOR
20043-385
Figure 166. Transmitter Output Power Spectrum, Tx1, 5 MHz LTE, 10 MHz Offset, −10 dBFS RMS, 1 MHz Resolution Bandwidth, T = 25°C
–100 –80 –60 –40 –20 0 20 40 60 80 100
TR
AN
SM
ITT
ER
IM
AG
E R
EJE
CT
ION
(d
Bc)
BASEBAND OFFSET FREQUENCY (MHz)
–40°C, Tx1–40°C, Tx2–40°C, Tx3–40°C, Tx4
+25°C, Tx1+25°C, Tx2+25°C, Tx3+25°C, Tx4
+110°C, Tx1+110°C, Tx2+110°C, Tx3+110°C, Tx4
20043-302
Figure 167. Transmitter Image Rejection vs. Baseband Offset Frequency, 0 dB Attenuation, QEC Tracking Enabled
0 5 10 15 20
TR
AN
SM
ITT
ER
NO
ISE
(d
Bm
/Hz)
TRANSMITTER ATTENUATION (dB)
–40°C, Tx1–40°C, Tx2–40°C, Tx3–40°C, Tx4
+25°C, Tx1+25°C, Tx2+25°C, Tx3+25°C, Tx4
+110°C, Tx1+110°C, Tx2+110°C, Tx3+110°C, Tx4
20043-303
Figure 168. Transmitter Noise vs. Transmitter Attenuation, 50 MHz Offset
–0.4
–0.2
0
0.2
0.4
0.6
0.8
–250 –200 –150 –100 –50 0 50 100 150 200 250
TR
AN
SM
ITT
ER
PA
SS
BA
ND
FL
AT
NE
SS
(d
B)
BASEBAND OFFSET FREQUENCY (MHz)
–40°C+25°C+110°C
20043-304
Figure 169. Transmitter Pass Band Flatness vs. Baseband Offset Frequency
–80
–75
–70
–65
–60
–55
–50
–45
–40
0 5 10 15 20
AD
JAC
EN
T C
HA
NN
EL
PO
WE
R L
EV
EL
(d
Bc)
TRANSMITTER ATTENUATION (dB)
–40°C+25°C+110°C
20043-320
Figure 170. Adjacent Channel Power Level vs. Transmitter Attenuation, −10 MHz Baseband Offset, 20 MHz LTE, PAR = 12 dB, Loop Filter Bandwidth =
500 kHz, Loop Filter Phase Margin = 60°
Data Sheet ADRV9010
Rev. E | Page 55 of 115
–80
–75
–70
–65
–60
–55
–50
–45
–40
0 5 10 15 20
AD
JAC
EN
T C
HA
NN
EL
PO
WE
R L
EV
EL
(d
Bc)
TRANSMITTER ATTENUATION (dB)
–40°C+25°C+110°C
20043-321
Figure 171. Adjacent Channel Power Level vs. Transmitter Attenuation, 90 MHz Baseband Offset, 20 MHz LTE, PAR = 12 dB,
Loop Filter Bandwidth = 500 kHz, Loop Filter Phase Margin = 60°
–120
–110
–100
–90
–80
–70
–60
0 2 4 6 8 10 12 14 16 18 20
TR
AN
SM
ITT
ER
HD
2(d
Bc)
TRANSMITTER ATTENUATION (dB)
–40°C, LOWER HD2+25°C, LOWER HD2+110°C, LOWER HD2
–40°C, UPPER HD2+25°C, UPPER HD2+110°C, UPPER HD2
20043-307
Figure 172. Transmitter HD2 vs. Transmitter Attenuation, 10 MHz Offset
–120
–110
–100
–90
–80
–70
–60
0 2 4 6 8 10 12 14 16 18 20
TR
AN
SM
ITT
ER
HD
3 (d
Bc)
TRANSMITTER ATTENUATION (dB)
–40°C, LOWER HD3+25°, LOWER HD3+110°C, LOWER HD3
–40°C, UPPER HD3+25°C, UPPER HD3+110°C, UPPER HD3
20043-308
Figure 173. Transmitter HD3 vs. Transmitter Attenuation, 10 MHz Offset
–0.05
–0.04
–0.03
–0.02
–0.01
0
0.01
0.02
0.03
0.04
0.05
0 4 8 12 16 20 24 28 32
TR
AN
SM
ITT
ER
AT
TE
NU
AT
OR
ST
EP
ER
RO
R (
dB
)
TRANSMITTER ATTENUATION (dB)
–40°C+25°C+110°C
20043-309
Figure 174. Transmitter Attenuator Step Error vs. Transmitter Attenuation, 10 MHz Offset
0 2 4 6 8 10 12 14 16 18 20
TR
AN
SM
ITT
ER
ER
RO
R V
EC
TO
R M
AG
NIT
UD
E (
dB
)
TRANSMITTER ATTENUATION (dB)
–40°C, Tx1–40°C, Tx2–40°C, Tx3–40°C, Tx4
+25°C, Tx1+25°C, Tx2+25°C, Tx3+25°C, Tx4
+110°C, Tx1+110°C, Tx2+110°C, Tx3+110°C, Tx4
20043-310
Figure 175. Transmitter Error Vector Magnitude vs. Transmitter Attenuation, 20 MHz LTE Signal Centered at LO Frequency, Sample Rate = 491.52 MSPS,
QEC Tracking Enabled, Loop Filter Bandwidth = 500 kHz, Loop Filter Phase Margin = 60°
0 4 8 12 16 20 24 28 32
TR
AN
SM
ITT
ER
OIP
3, 2
f1 –
f2
(dB
m)
TRANSMITTER ATTENUATION (dB)
–40°C, Tx1–40°C, Tx2–40°C, Tx3–40°C, Tx4
+25°C, Tx1+25°C, Tx2+25°C, Tx3+25°C, Tx4
+110°C, Tx1+110°C, Tx2+110°C, Tx3+110°C, Tx4
20043-311
Figure 176. Transmitter OIP3, 2f1 − f2 vs. Transmitter Attenuation, 15 dB Digital Backoff per Tone, f1 = 50.5 MHz, f2 = 55.5 MHz
ADRV9010 Data Sheet
Rev. E | Page 56 of 115
0 4 8 12 16 20 24 28 32
TR
AN
SM
ITT
ER
OIP
3, 2
f2 –
f1
(dB
m)
TRANSMITTER ATTENUATION (dB)
–40°C, Tx1–40°C, Tx2–40°C, Tx3–40°C, Tx4
+25°C, Tx1+25°C, Tx2+25°C, Tx3+25°C, Tx4
+110°C, Tx1+110°C, Tx2+110°C, Tx3+110°C, Tx4
20043-312
Figure 177. Transmitter OIP3, 2f2 − f1 vs. Transmitter Attenuation, 15 dB Digital Backoff per Tone, f1 = 50.5 MHz, f2 = 55.5 MHz
10 30 50 70 90 110 130 150 170 190
TR
AN
SM
ITT
ER
OIP
3, 2
f1 –
f2
(dB
m)
f1 BASEBAND OFFSET TONE FREQUENCY (MHz)
–40°C, Tx1–40°C, Tx2–40°C, Tx3–40°C, Tx4
+25°C, Tx1+25°C, Tx2+25°C, Tx3+25°C, Tx4
+110°C, Tx1+110°C, Tx2+110°C, Tx3+110°C, Tx4
20043-313
Figure 178. Transmitter OIP3, 2f1 − f2 vs. f1 Baseband Offset Tone Frequency, f2 = f1 + 5 MHz, 15 dB Digital Backoff per Tone
10 30 50 70 90 110 130 150 170 190
TR
AN
SM
ITT
ER
OIP
3, 2
f2 –
f1
(dB
m)
f1 BASEBAND OFFSET TONE FREQUENCY (MHz)
–40°C, Tx1–40°C, Tx2–40°C, Tx3–40°C, Tx4
+25°C, Tx1+25°C, Tx2+25°C, Tx3+25°C, Tx4
+110°C, Tx1+110°C, Tx2+110°C, Tx3+110°C, Tx4
20043-314
Figure 179. Transmitter OIP3, 2f2 − f1 vs. f1 Baseband Offset Tone Frequency, f2 = f1 + 5 MHz, 15 dB Digital Backoff per Tone
10 30 50 70 90 110 130 150 170 190
TR
AN
SM
ITT
ER
OIP
3, 2
f1 +
f2
(dB
m)
f1 BASEBAND OFFSET TONE FREQUENCY (MHz)
–40°C, Tx1–40°C, Tx2–40°C, Tx3–40°C, Tx4
+25°C, Tx1+25°C, Tx2+25°C, Tx3+25°C, Tx4
+110°C, Tx1+110°C, Tx2+110°C, Tx3+110°C, Tx4
20043-315
Figure 180. Transmitter OIP3, 2f1 + f2 vs. f1 Baseband Offset Tone Frequency, f2 = f1 + 5 MHz, 15 dB Digital Backoff per Tone
10 30 50 70 90 110 130 150 170 190
TR
AN
SM
ITT
ER
OIP
3, 2
f2 +
f1
(dB
m)
f1 BASEBAND OFFSET TONE FREQUENCY (MHz)
–40°C, Tx1–40°C, Tx2–40°C, Tx3–40°C, Tx4
+25°C, Tx1+25°C, Tx2+25°C, Tx3+25°C, Tx4
+110°C, Tx1+110°C, Tx2+110°C, Tx3+110°C, Tx4
20043-316
Figure 181. Transmitter OIP3, 2f2 + f1 vs. f1 Baseband Offset Tone Frequency, f2 = f1 + 5 MHz, 15 dB Digital Backoff per Tone
1800 1900 2000 2100 2200 2300 2400 2500 2600 2700 2800
TR
AN
SM
ITT
ER
TO
TR
AN
SM
ITT
ER
IS
OLA
TIO
N (
dB
)
TRANSMITTER LO FREQUENCY (MHz)
Tx1 TO Tx2 Tx1 TO Tx3 Tx1 TO Tx4Tx2 TO Tx1 Tx2 TO Tx3 Tx2 TO Tx4Tx3 TO Tx1 Tx3 TO Tx2 Tx3 TO Tx4Tx4 TO Tx1 Tx4 TO Tx2 Tx4 TO Tx3
20043-317
Figure 182. Transmitter to Transmitter Isolation vs. Transmitter LO Frequency
Data Sheet ADRV9010
Rev. E | Page 57 of 115
1800 1900 2000 2100 2200 2300 2400 2500 2600 2700 2800
TR
AN
SM
ITT
ER
TO
RE
CE
IVE
R I
SO
LA
TIO
N (
dB
)
RECEIVER LO FREQUENCY (MHz)
Tx1 TO Rx1 Tx1 TO Rx2 Tx1 TO Rx3 Tx1 TO Rx4Tx2 TO Rx1 Tx2 TO Rx2 Tx2 TO Rx3 Tx2 TO Rx4Tx3 TO Rx1 Tx3 TO Rx2 Tx3 TO Rx3 Tx3 TO Rx4Tx4 TO Rx1 Tx4 TO Rx2 Tx4 TO Rx3 Tx4 TO Rx4
20043-318
Figure 183. Transmitter to Receiver Isolation vs. Receiver LO Frequency
1800 1900 2000 2100 2200 2300 2400 2500 2600 2700 2800
TR
AN
SM
ITT
ER
TO
OB
SE
RV
AT
ION
RE
CE
IVE
RIS
OL
AT
ION
(d
B)
TRANSMITTER LO FREQUENCY (MHz)
Tx1 TO ORx1Tx2 TO ORx1Tx3 TO ORx1Tx4 TO ORx1
Tx1 TO ORx2Tx2 TO ORx2Tx3 TO ORx2Tx4 TO ORx2
Tx1 TO ORx3Tx2 TO ORx3Tx3 TO ORx3Tx4 TO ORx3
Tx1 TO ORx4Tx2 TO ORx4Tx3 TO ORx4Tx4 TO ORx4
20043-319
Figure 184. Transmitter to Observation Receiver Isolation vs. Transmitter LO Frequency
1800 2000 2200 2400 2600 2800
RE
CE
IVE
RT
O R
EC
EIV
ER
IS
OL
AT
ION
(d
B)
RECEIVER LO FREQUENCY (MHz)
Rx1 TO Rx2Rx2 TO Rx1Rx3 TO Rx1Rx4 TO Rx1
Rx1 TO Rx3Rx2 TO Rx3Rx3 TO Rx2Rx4 TO Rx2
Rx1 TO Rx4Rx2 TO Rx4Rx3 TO Rx4Rx4 TO Rx3
20043-322
Figure 185. Receiver to Receiver Isolation vs. Receiver LO Frequency
0 5 10 15 20
RE
CE
IVE
R I
NT
EG
RA
TE
D N
OIS
E F
IGU
RE
(d
B)
RECEIVER ATTENUATION (dB)
–40°C, Rx1–40°C, Rx2–40°C, Rx3–40°C, Rx4
+25°C, Rx1+25°C, Rx2+25°C, Rx3+25°C, Rx4
+110°C, Rx1+110°C, Rx2+110°C, Rx3+110°C, Rx4
20043-323
Figure 186. Receiver Integrated Noise Figure vs. Receiver Attenuation, 20 MHz Offset, 200 MHz Bandwidth, Sample Rate = 245.76 MSPS, Integration
Bandwidth = 500 kHz to 100 MHz
0
5
10
15
20
25
–100 –80 –60 –40 –20 0 20 40 60 80 100
RE
CE
IVE
R I
NT
EG
RA
TE
D N
OIS
E F
IGU
RE
(d
B)
BASEBAND OFFSET FREQUENCY (MHz)
–40°C+25°C+110°C
20043-324
Figure 187. Receiver Integrated Noise Figure vs. Baseband Offset Frequency, 200 MHz Bandwidth, Sample Rate = 245.76 MSPS, Integrated in 200 kHz Steps
20043-325–80
–75
–70
–65
–60
–55
–50
1800 1900 2000 2100 2200 2300 2400 2500 2600 2700 2800
RE
CE
IVE
R L
O L
EA
KA
GE
(d
Bm
)
RECEIVER LO FREQUENCY (MHz)
–40°C+25°C+110°C
Figure 188. Receiver LO Leakage vs. Receiver LO Frequency, Attenuation = 0 dB, Sample Rate = 245.76 MSPS
ADRV9010 Data Sheet
Rev. E | Page 58 of 115
–40°C, Rx1–40°C, Rx2–40°C, Rx3–40°C, Rx4
+25°C, Rx1+25°C, Rx2+25°C, Rx3+25°C, Rx4
+110°C, Rx1+110°C, Rx2+110°C, Rx3+110°C, Rx4
0 5 10 15 20 25 30
RE
CE
IVE
R G
AIN
(d
B)
RECEIVER ATTENUATION (dB) 20043-326
Figure 189. Receiver Gain vs. Receiver Attenuation, 20 MHz Offset, 200 MHz Bandwidth, Sample Rate = 245.76 MSPS
1800 1900 2000 2100 2200 2300 2400 2500 2600 2700 2800
RE
CE
IVE
R G
AIN
(d
B)
RECEIVER LO FREQUENCY (MHz)
–40°C, Rx1–40°C, Rx2–40°C, Rx3–40°C, Rx4
+25°C, Rx1+25°C, Rx2+25°C, Rx3+25°C, Rx4
+110°C, Rx1+110°C, Rx2+110°C, Rx3+110°C, Rx4
20043-327
Figure 190. Receiver Gain vs. Receiver LO Frequency, 10 MHz Offset, 200 MHz Bandwidth, Sample Rate = 245.76 MSPS
0 5 10 15 20 25 30
RE
CE
IVE
R G
AIN
ST
EP
ER
RO
R (
dB
)
RECEIVER ATTENUATION (dB)
–40°C, Rx1–40°C, Rx2–40°C, Rx3–40°C, Rx4
+25°C, Rx1+25°C, Rx2+25°C, Rx3+25°C, Rx4
+110°C, Rx1+110°C, Rx2+110°C, Rx3+110°C, Rx4
20043-328
Figure 191. Receiver Gain Step Error vs. Receiver Attenuation, 20 MHz Offset, −5 dBFS Input Signal
–0.5
–0.4
–0.3
–0.2
–0.1
0
0.1
0.2
0.3
0.4
0.5
–100 –80 –60 –40 –20 0 20 40 60 80 100
NO
RM
AL
IZE
D R
EC
EIV
ER
FL
AT
NE
SS
(d
B)
BASEBAND OFFSET FREQUENCY (MHz)
–40°C+25°C+110°C
20043-329
Figure 192. Normalized Receiver Flatness vs. Baseband Offset Frequency, −5 dBFS Input Signal
–100 –80 –60 –40 –20 0 20 40 60 80 100
RE
CE
IVE
R I
MA
GE
(d
Bc)
BASEBAND OFFSET FREQUENCY (MHz)
–40°C, Rx1–40°C, Rx2–40°C, Rx3–40°C, Rx4
+25°C, Rx1+25°C, Rx2+25°C, Rx3+25°C, Rx4
+110°C, Rx1+110°C, Rx2+110°C, Rx3+110°C, Rx4
20043-330
Figure 193. Receiver Image vs. Baseband Offset Frequency, Tracking Calibration Active, Sample Rate = 245.76 MSPS, −5 dBFS Input Signal
0 5 10 15 20 25 30
RE
CE
IVE
R I
MA
GE
(d
Bc)
RECEIVER ATTENUATION (dB)
–40°C, Rx1–40°C, Rx2–40°C, Rx3–40°C, Rx4
+25°C, Rx1+25°C, Rx2+25°C, Rx3+25°C, Rx4
+110°C, Rx1+110°C, Rx2+110°C, Rx3+110°C, Rx4
20043-331
Figure 194. Receiver Image vs. Receiver Attenuation, 20 MHz Offset, Tracking Calibration Active, Sample Rate = 245.76 MSPS, −5 dBFS Input Signal
Data Sheet ADRV9010
Rev. E | Page 59 of 115
0 5 10 15 20 25 30
RE
CE
IVE
R D
C O
FF
SE
T (
dB
FS
)
RECEIVER ATTENUATION (dB)
–40°C, Rx1–40°C, Rx2–40°C, Rx3–40°C, Rx4
+25°C, Rx1+25°C, Rx2+25°C, Rx3+25°C, Rx4
+110°C, Rx1+110°C, Rx2+110°C, Rx3+110°C, Rx4
20043-332
Figure 195. Receiver DC Offset vs. Receiver Attenuation, 20 MHz Offset, −5 dBFS Input Signal
0 20 40 60
RE
CE
IVE
R H
D2,
LE
FT
SID
E (
dB
c)
BASEBAND OFFSET FREQUENCY (MHz)
–40°C, Rx1–40°C, Rx2–40°C, Rx3–40°C, Rx4
+25°C, Rx1+25°C, Rx2+25°C, Rx3+25°C, Rx4
+110°C, Rx1+110°C, Rx2+110°C, Rx3+110°C, Rx4
20043-333
Figure 196. Receiver HD2, Left Side vs. Baseband Offset Frequency, −5 dBFS Input Signal, Distortion Tone Measured Left of 0 Hz
(HD2 Canceller Not Enabled)
–60 –40 –20 0 20 40 60
RE
CE
IVE
R H
D2,
RIG
HT
SID
E (
dB
c)
BASEBAND OFFSET FREQUENCY (MHz)
–40°C, Rx1–40°C, Rx2–40°C, Rx3–40°C, Rx4
+25°C, Rx1+25°C, Rx2+25°C, Rx3+25°C, Rx4
+110°C, Rx1+110°C, Rx2+110°C, Rx3+110°C, Rx4
20043-334
Figure 197. Receiver HD2, Right Side vs. Baseband Offset Frequency, −5 dBFS Input Signal, Distortion Tone Measured Right of 0 Hz
(HD2 Canceller Not Enabled)
–40 –30 –20 –10 0 10 20 30 40
RE
CE
IVE
R H
D3,
LE
FT
SID
E (
dB
c)
BASEBAND OFFSET FREQUENCY (MHz)
–40°C, Rx1–40°C, Rx2–40°C, Rx3–40°C, Rx4
+25°C, Rx1+25°C, Rx2+25°C, Rx3+25°C, Rx4
+110°C, Rx1+110°C, Rx2+110°C, Rx3+110°C, Rx4
20043-335
Figure 198. Receiver HD3, Left Side vs. Baseband Offset Frequency, −5 dBFS Input Signal, Distortion Tone Measured Left of 0 Hz
–40 –30 –20 –10 0 10 20 30 40
RE
CE
IVE
R H
D3,
RIG
HT
SID
E (
dB
c)
BASEBAND OFFSET FREQUENCY (MHz) 20043-336
–40°C, Rx1–40°C, Rx2–40°C, Rx3–40°C, Rx4
+25°C, Rx1+25°C, Rx2+25°C, Rx3+25°C, Rx4
+110°C, Rx1+110°C, Rx2+110°C, Rx3+110°C, Rx4
Figure 199. Receiver HD3, Right Side vs. Baseband Offset Frequency, −5 dBFS Input Signal, Distortion Tone Measured Right of 0 Hz
2605 2615 2625 2635 2645
RE
CE
IVE
R I
IP2,
f1
+ f
2 (d
Bm
)
TONE 2 FREQUENCY (MHz)
–40°C, Rx1–40°C, Rx2–40°C, Rx3–40°C, Rx4
+25°C, Rx1+25°C, Rx2+25°C, Rx3+25°C, Rx4
+110°C, Rx1+110°C, Rx2+110°C, Rx3+110°C, Rx4
20043-337
Figure 200. Receiver IIP2, f1 + f2 vs. Tone 2 Frequency, Both Tones at −11 dBFS, 0 dB Attenuation, f1 = f2 + 2 MHz
ADRV9010 Data Sheet
Rev. E | Page 60 of 115
2605 2615 2625 2635 2645 2655 2665 2675 2685 2695
RE
CE
IVE
R I
IP2,
f1
– f2
(d
Bm
)
TONE 2 FREQUENCY (MHz)
–40°C, Rx1–40°C, Rx2–40°C, Rx3–40°C, Rx4
+25°C, Rx1+25°C, Rx2+25°C, Rx3+25°C, Rx4
+110°C, Rx1+110°C, Rx2+110°C, Rx3+110°C, Rx4
20043-338
Figure 201. Receiver IIP2, f1 − f2 vs. Tone 2 Frequency, Both Tones at −11 dBFS, 0 dB Attenuation, f1 = f2 + 2 MHz
10 20 30 40 50 60 70 80 90
RE
CE
IVE
R I
IP2,
f1
+ f
2 (d
Bm
)
TWO-TONE FREQUENCY SPACING (MHz)
–40°C, Rx1–40°C, Rx2–40°C, Rx3–40°C, Rx4
+25°C, Rx1+25°C, Rx2+25°C, Rx3+25°C, Rx4
+110°C, Rx1+110°C, Rx2+110°C, Rx3+110°C, Rx4
20043-339
Figure 202. Receiver IIP2, f1 + f2 vs. Two-Tone Frequency Spacing, Both Tones at −11 dBFS, 0 dB Attenuation, f2 = 2 MHz
10 20 30 40 50 60 70 80 90
RE
CE
IVE
R I
IP2,
f1
– f2
(d
Bm
)
TWO-TONE FREQUENCY SPACING (MHz)
–40°C, Rx1–40°C, Rx2–40°C, Rx3–40°C, Rx4
+25°C, Rx1+25°C, Rx2+25°C, Rx3+25°C, Rx4
+110°C, Rx1+110°C, Rx2+110°C, Rx3+110°C, Rx4
20043-340
Figure 203. Receiver IIP2, f1 − f2 vs. Two-Tone Frequency Spacing, Both Tones at −11 dBFS, 0 dB Attenuation, f2 = 2 MHz
0 5 10 15 20 25 30
RE
CE
IVE
R I
IP2,
f1
+ f
2 (d
Bm
)
RECEIVER ATTENUATION (dB)
–40°C, Rx1–40°C, Rx2–40°C, Rx3–40°C, Rx4
+25°C, Rx1+25°C, Rx2+25°C, Rx3+25°C, Rx4
+110°C, Rx1+110°C, Rx2+110°C, Rx3+110°C, Rx4
20043-341
Figure 204. Receiver IIP2, f1 + f2 vs. Receiver Attenuation, Both Tones at −11 dBFS, f1 = 92 MHz, f2 = 2 MHz
0 5 10 15 20 25 30
RE
CE
IVE
R I
IP2,
f1
– f2
(d
Bm
)
RECEIVER ATTENUATION (dB)
–40°C, Rx1–40°C, Rx2–40°C, Rx3–40°C, Rx4
+25°C, Rx1+25°C, Rx2+25°C, Rx3+25°C, Rx4
+110°C, Rx1+110°C, Rx2+110°C, Rx3+110°C, Rx4
20043-342
Figure 205. Receiver IIP2, f1 − f2 vs. Receiver Attenuation, Both Tones at −11 dBFS, f1 = 92 MHz, f2 = 2 MHz
2605 2610 2615 2620 2625
RE
CE
IVE
R I
IP3,
2f1
+ f
2 (d
Bm
)
TONE 2 FREQUENCY (MHz)
–40°C, Rx1–40°C, Rx2–40°C, Rx3–40°C, Rx4
+25°C, Rx1+25°C, Rx2+25°C, Rx3+25°C, Rx4
+110°C, Rx1+110°C, Rx2+110°C, Rx3+110°C, Rx4
20043-343
Figure 206. Receiver IIP3, 2f1 + f2 vs. Tone 2 Frequency, Both Tones at −11 dBFS, 0 dB Attenuation, f1 = f2 + 2 MHz
Data Sheet ADRV9010
Rev. E | Page 61 of 115
2605 2610 2615 2620 2625
RE
CE
IVE
R I
IP3,
2f2
+ f
1 (d
Bm
)
TONE 2 FREQUENCY (MHz)
–40°C, Rx1–40°C, Rx2–40°C, Rx3–40°C, Rx4
+25°C, Rx1+25°C, Rx2+25°C, Rx3+25°C, Rx4
+110°C, Rx1+110°C, Rx2+110°C, Rx3+110°C, Rx4
20043-344
Figure 207. Receiver IIP3, 2f2 + f1 vs. Tone 2 Frequency, Both Tones at −11 dBFS, 0 dB Attenuation, f1 = f2 + 2 MHz
2605 2615 2625 2635 2645 2655 2665 2675 2685 2695
RE
CE
IVE
R I
IP3,
2f1
– f
2 (d
Bm
)
TONE 2 FREQUENCY (MHz)
–40°C, Rx1–40°C, Rx2–40°C, Rx3–40°C, Rx4
+25°C, Rx1+25°C, Rx2+25°C, Rx3+25°C, Rx4
+110°C, Rx1+110°C, Rx2+110°C, Rx3+110°C, Rx4
20043-345
Figure 208. Receiver IIP3, 2f1 − f2 vs. Tone 2 Frequency, Both Tones at −11 dBFS, 0 dB Attenuation, f1 = f2 + 2 MHz
2605 2615 2625 2635 2645 2655 2665 2675 2685 2695
RE
CE
IVE
R I
IP3,
2f2
– f
1 (d
Bm
)
TONE 2 FREQUENCY (MHz)
–40°C, Rx1–40°C, Rx2–40°C, Rx3–40°C, Rx4
+25°C, Rx1+25°C, Rx2+25°C, Rx3+25°C, Rx4
+110°C, Rx1+110°C, Rx2+110°C, Rx3+110°C, Rx4
20043-346
Figure 209. Receiver IIP3, 2f2 − f1 vs. Tone 2 Frequency, Both Tones at −11 dBFS, 0 dB Attenuation, f1 = f2 + 2 MHz
10 15 20 25 30 35 40
RE
CE
IVE
R I
IP3,
2f1
+ f
2 (d
Bm
)
TWO-TONE FREQUENCY SPACING (MHz)
–40°C, Rx1–40°C, Rx2–40°C, Rx3–40°C, z4
+25°C, Rx1+25°C, Rx2+25°C, Rx3+25°C, Rx4
+110°C, Rx1+110°C, Rx2+110°C, Rx3+110°C, Rx4
20043-347
Figure 210. Receiver IIP3, 2f1 + f2 vs. Two-Tone Frequency Spacing, Both Tones at −11 dBFS, 0 dB Attenuation, f2 = 2 MHz
10 20 30 40 50 60 70 80 90
RE
CE
IVE
R I
IP3,
2f2
+ f
1 (d
Bm
)
TWO-TONE FREQUENCY SPACING (MHz)
–40°C, Rx1–40°C, Rx2–40°C, Rx3–40°C, Rx4
+25°C, Rx1+25°C, Rx2+25°C, Rx3+25°C, Rx4
+110°C, Rx1+110°C, Rx2+110°C, Rx3+110°C, Rx4
20043-348
Figure 211. Receiver IIP3, 2f2 + f1 vs. Two-Tone Frequency Spacing, Both Tones at −11 dBFS, 0 dB Attenuation, f2 = 2 MHz
10 15 20 25 30 35 40
RE
CE
IVE
R I
IP3,
2f1
– f
2 (d
Bm
)
TWO-TONE FREQUENCY SPACING (MHz)
–40°C, Rx1–40°C, Rx2–40°C, Rx3–40°C, Rx4
+25°C, Rx1+25°C, Rx2+25°C, Rx3+25°C, Rx4
+110°C, Rx1+110°C, Rx2+110°C, Rx3+110°C, Rx4
20043-349
Figure 212. Receiver IIP3, 2f1 − f2 vs. Two-Tone Frequency Spacing, Both Tones at −11 dBFS, 0 dB Attenuation, f2 = 2 MHz
ADRV9010 Data Sheet
Rev. E | Page 62 of 115
10 20 30 40 50 60 70 80 90
RE
CE
IVE
R I
IP3,
2f2
– f
1 (d
Bm
)
TWO-TONE FREQUENCY SPACING (MHz)
–40°C, Rx1–40°C, Rx2–40°C, Rx3–40°C, Rx4
+25°C, Rx1+25°C, Rx2+25°C, Rx3+25°C, Rx4
+110°C, Rx1+110°C, Rx2+110°C, Rx3+110°C, Rx4
20043-350
Figure 213. Receiver IIP3, 2f2 − f1 vs. Two-Tone Frequency Spacing, Both Tones at −11 dBFS, 0 dB Attenuation, f2 = 2 MHz
–60 –55 –50 –45 –40 –35 –30 –25 –20 –15 –10 –5 0 5
RE
CE
IVE
R E
RR
OR
VE
CT
OR
MA
GN
ITU
DE
(d
B)
RECEIVER INPUT POWER (dBm)
–40°C, Rx1–40°C, Rx2–40°C, Rx3–40°C, Rx4
+25°C, Rx1+25°C, Rx2+25°C, Rx3+25°C, Rx4
+110°C, Rx1+110°C, Rx2+110°C, Rx3+110°C, Rx4
20043-379
Figure 214. Receiver Error Vector Magnitude vs. Receiver Input Power, 20 MHz LTE Signal Centered at LO Frequency, Sample Rate = 245.76 MSPS,
Loop Filter Bandwidth = 500 kHz, Loop Filter Phase Margin = 60°
–150
–140
–130
–120
–110
–100
–90
–80
100 1k 10k 100k 1M 10M
LO
PH
AS
E N
OIS
E (
dB
c/H
z)
FREQUENCY OFFSET (Hz) 20043-383
Figure 215. LO Phase Noise vs. Frequency Offset, Loop Bandwidth = 75 kHz, Phase Margin = 85°
–150
–140
–130
–120
–110
–100
–90
–80
100 1k 10k 100k 1M 10M
LO
PH
AS
E N
OIS
E (
dB
c/H
z)
FREQUENCY OFFSET (Hz) 20043-384
Figure 216. LO Phase Noise vs. Frequency Offset, Loop Bandwidth = 500 kHz, Phase Margin = 60°
0 5 10 15 20
OB
SE
RV
AT
ION
RE
CE
IVE
R I
NT
EG
RA
TE
D N
OIS
EF
IGU
RE
(d
B)
OBSERVATION RECEIVER ATTENUATION (dB)
–40°C, ORx1–40°C, ORx2–40°C, ORx3–40°C, ORx4
+25°C, ORx1+25°C, ORx2+25°C, ORx3+25°C, ORx4
+110°C, ORx1+110°C, ORx2+110°C, ORx3+110°C, ORx4
20043-353
Figure 217. Observation Receiver Integrated Noise Figure vs. Observation Receiver Attenuation, 20 MHz Offset, 450 MHz Bandwidth,
Sample Rate = 491.52 MSPS, Integration Bandwidth = 500 kHz to 100 MHz
–250 –150 –50 50 150 250
OB
SE
RV
AT
ION
RE
CE
IVE
R I
NT
EG
RA
TE
DN
OIS
E F
IGU
RE
(d
B)
BASEBAND OFFSET FREQUENCY (MHz)
–40°C+25°C+110°C
20043-354
Figure 218. Observation Receiver Integrated Noise Figure vs. Baseband Offset Frequency, 450 MHz Bandwidth, Sample Rate = 491.52 MSPS,
Integrated in 200 kHz Steps
Data Sheet ADRV9010
Rev. E | Page 63 of 115
–80
–75
–70
–65
–60
–55
–50
1800 1900 2000 2100 2200 2300 2400 2500 2600 2700 2800
OB
SE
RV
AT
ION
RE
CE
IVE
R L
O L
EA
KA
GE
(d
Bm
)
OBSERVATION RECEIVER LO FREQUENCY (MHz)
–40°C+25°C+110°C
20043-380
Figure 219. Observation Receiver LO Leakage vs. Observation Receiver LO Frequency, 0 dB Attenuation, Sample Rate = 491.52 MSPS
0 5 10 15 20 25 30
OB
SE
RV
AT
ION
RE
CE
IVE
R G
AIN
(d
B)
OBSERVATION RECEIVER ATTENUATION (dB)
–40°C, ORx1–40°C, ORx2–40°C, ORx3–40°C, ORx4
+25°C, ORx1+25°C, ORx2+25°C, ORx3+25°C, ORx4
+110°C, ORx1+110°C, ORx2+110°C, ORx3+110°C, ORx4
20043-355
Figure 220. Observation Receiver Gain vs. Observation Receiver Attenuation, 20 MHz Offset, 450 MHz Bandwidth, Sample Rate = 491.52 MSPS
1800 1900 2000 2100 2200 2300 2400 2500 2600 2700 2800
OB
SE
RV
AT
ION
RE
CE
IVE
R G
AIN
(d
B)
OBSERVATION RECEIVER LO FREQUENCY (MHz)
–40°C, ORx1–40°C, ORx2–40°C, ORx3–40°C, ORx4
+25°C, ORx1+25°C, ORx2+25°C, ORx3+25°C, ORx4
+110°C, ORx1+110°C, ORx2+110°C, ORx3+110°C, ORx4
20043-381
Figure 221. Observation Receiver Gain vs. Observation Receiver LO Frequency, 450 MHz Bandwidth, Sample Rate = 491.52 MSPS
20043-388O
BS
ER
VA
TIO
N R
EC
EIV
ER
GA
IN S
TE
P E
RR
OR
(d
B)
0 5 10 15 20 25 30
OBSERVATION RECEIVER ATTENUATION (dB)
–40°C, ORx1–40°C, ORx2–40°C, ORx3–40°C, ORx4
+25°C, ORx1+25°C, ORx2+25°C, ORx3+25°C, ORx4
+110°C, ORx1+110°C, ORx2+110°C, ORx3+110°C, ORx4
Figure 222. Observation Receiver Gain Step Error vs. Observation Receiver Attenuation, 20 MHz Offset, −5 dBFS Input Signal
1801401006020 220
NO
RM
AL
IZE
D O
BS
ER
VA
TIO
NR
EC
EIV
ER
FL
AT
NE
SS
(d
B)
BASEBAND OFFSET FREQUENCY (MHz)
–40°C+25°C+85°C
20043-386
Figure 223. Normalized Observation Receiver Flatness vs. Baseband Offset Frequency, −25 dBm Input Signal, 0 dB Attenuation
–225 –175 –125 –75 –25 25 75 125 175 225
OB
SE
RV
AT
ION
RE
CE
IVE
R I
MA
GE
(d
Bc)
BASEBAND OFFSET FREQUENCY (MHz)
–40°C, ORx1–40°C, ORx2–40°C, ORx3–40°C, ORx4
+25°C, ORx1+25°C, ORx2+25°C, ORx3+25°C, ORx4
+110°C, ORx1+110°C, ORx2+110°C, ORx3+110°C, ORx4
20043-356
Figure 224. Observation Receiver Image vs. Baseband Offset Frequency, Tracking Calibration Active, Sample Rate = 491.52 MSPS
ADRV9010 Data Sheet
Rev. E | Page 64 of 115
0 5 10 15 20 25 30
OB
SE
RV
AT
ION
RE
CE
IVE
R I
MA
GE
(d
Bc)
OBSERVATION RECEIVER ATTENUATION (dB)
–40°C, ORx1–40°C, ORx2–40°C, ORx3–40°C, ORx4
+25°C, ORx1+25°C, ORx2+25°C, ORx3+25°C, ORx4
+110°C, ORx1+110°C, ORx2+110°C, ORx3+110°C, ORx4
20043-357
Figure 225. Observation Receiver Image vs. Observation Receiver Attenuation, 20 MHz Offset, Tracking Calibration Active,
Sample Rate = 491.52 MSPS
–100 –80 –60 –40 –20 0 20 40 60 80 100
OB
SE
RV
AT
ION
RE
CE
IVE
R H
D2,
LE
FT
SID
E (
dB
c)
BASEBAND OFFSET FREQUENCY (MHz)
–40°C, ORx1–40°C, ORx2–40°C, ORx3–40°C, ORx4
+25°C, ORx1+25°C, ORx2+25°C, ORx3+25°C, ORx4
+110°C, ORx1+110°C, ORx2+110°C, ORx3+110°C, ORx4
20043-359
Figure 226. Observation Receiver HD2, Left Side vs. Baseband Offset Frequency, −5 dBFS Input Signal, Distortion Tone Measured Left of 0 Hz
–100 –80 –60 –40 –20 0 20 40 60 80 100
OB
SE
RV
AT
ION
RE
CE
IVE
R H
D2,
RIG
HT
SID
E (
dB
c)
BASEBAND OFFSET FREQUENCY (MHz)
–40°C, ORx1–40°C, ORx2–40°C, ORx3–40°C, ORx4
+25°C, ORx1+25°C, ORx2+25°C, ORx3+25°C, ORx4
+110°C, ORx1+110°C, ORx2+110°C, ORx3+110°C, ORx4
20043-360
Figure 227. Observation Receiver HD2, Right Side vs. Baseband Offset Frequency, −5 dBFS Input Signal, Distortion Tone Measured Right of 0 Hz
–60 –40 –20 0 20 40 60
OB
SE
RV
AT
ION
RE
CE
IVE
R H
D3,
LE
FT
SID
E (
dB
c)
BASEBAND OFFSET FREQUENCY (MHz)
–40°C, ORx1–40°C, ORx2–40°C, ORx3–40°C, ORx4
+25°C, ORx1+25°C, ORx2+25°C, ORx3+25°C, ORx4
+110°C, ORx1+110°C, ORx2+110°C, ORx3+110°C, ORx4
20043-361
Figure 228. Observation Receiver HD3, Left Side vs. Baseband Offset Frequency, −5 dBFS Input Signal, Distortion Tone Measured Left of 0 Hz
–60 –40 –20 0 20 40 60
OB
SE
RV
AT
ION
RE
CE
IVE
R H
D3,
RIG
HT
SID
E (
dB
c)
BASEBAND OFFSET FREQUENCY (MHz)
–40°C, ORx1–40°C, ORx2–40°C, ORx3–40°C, ORx4
+25°C, ORx1+25°C, ORx2+25°C, ORx3+25°C, ORx4
+110°C, ORx1+110°C, ORx2+110°C, ORx3+110°C, ORx4
20043-362
Figure 229. Observation Receiver HD3, Right Side vs. Baseband Offset Frequency, −5 dBFS Input Signal, Distortion Tone Measured Right of 0 Hz
2605 2615 2625 2635 2645 2655 2665 2675 2685 2695 2705
OB
SE
RV
AT
ION
RE
CE
IVE
R I
IP2,
f1
+ f
2 (d
Bm
)
TONE 2 FREQUENCY(MHz)
–40°C, ORx1–40°C, ORx2–40°C, ORx3–40°C, ORx4
+25°C, ORx1+25°C, ORx2+25°C, ORx3+25°C, ORx4
+110°C, ORx1+110°C, ORx2+110°C, ORx3+110°C, ORx4
20043-363
Figure 230. Observation Receiver IIP2, f1 + f2 vs. Tone 2 Frequency, Both Tones at −11 dBFS, 0 dB Attenuation, f1 = f2 + 2 MHz
Data Sheet ADRV9010
Rev. E | Page 65 of 115
2605 2625 2645 2665 2685 2705 2725 2745 2765 2785 2805 2825
OB
SE
RV
AT
ION
RE
CE
IVE
R I
IP2,
f1
– f2
(d
Bm
)
TONE 2 FREQUENCY (MHz)
–40°C, ORx1–40°C, ORx2–40°C, ORx3–40°C, ORx4
+25°C, ORx1+25°C, ORx2+25°C, ORx3+25°C, ORx4
+110°C, ORx1+110°C, ORx2+110°C, ORx3+110°C, ORx4
20043-364
Figure 231. Observation Receiver IIP2, f1 − f2 vs. Tone 2 Frequency, Both Tones at −11 dBFS, 0 dB Attenuation, f1 = f2 + 2 MHz
10 40 70 100 130 160 190 220
OB
SE
RV
AT
ION
RE
CE
IVE
R I
IP2,
f1
+ f
2 (d
Bm
)
TWO-TONE FREQUENCY SPACING (MHz)
–40°C, ORx1–40°C, ORx2–40°C, ORx3–40°C, ORx4
+25°C, ORx1+25°C, ORx2+25°C, ORx3+25°C, ORx4
+110°C, ORx1+110°C, ORx2+110°C, ORx3+110°C, ORx4
20043-365
Figure 232. Observation Receiver IIP2, f1 + f2 vs. Two-Tone Frequency Spacing, Both Tones at −11 dBFS, 0 dB Attenuation, f2 = 2 MHz
10 40 70 100 130 160 190 220
OB
SE
RV
AT
ION
RE
CE
IVE
R I
IP2,
f1
– f2
(d
Bm
)
TWO-TONE FREQUENCY SPACING (MHz)
–40°C, ORx1–40°C, ORx2–40°C, ORx3–40°C, ORx4
+25°C, ORx1+25°C, ORx2+25°C, ORx3+25°C, ORx4
+110°C, ORx1+110°C, ORx2+110°C, ORx3+110°C, ORx4
20043-366
Figure 233. Observation Receiver IIP2, f1 − f2 vs. Two-Tone Frequency Spacing, Both Tones at −11 dBFS, 0 dB Attenuation, f2 = 2 MHz
0 5 10 15 20 25 30
OB
SE
RV
AT
ION
RE
CE
IVE
R I
IP2,
f1
+ f
2 (d
Bm
)
OBSERVATION RECEIVER ATTENUATION (dB)
–40°C, ORx1–40°C, ORx2–40°C, ORx3–40°C, ORx4
+25°C, ORx1+25°C, ORx2+25°C, ORx3+25°C, ORx4
+110°C, ORx1+110°C, ORx2+110°C, ORx3+110°C, ORx4
20043-367
Figure 234. Observation Receiver IIP2, f1 + f2 vs. Observation Receiver Attenuation, Both Tones at −11 dBFS, f1 = 102 MHz, f2 = 2 MHz
0 5 10 15 20 25 30
OB
SE
RV
AT
ION
RE
CE
IVE
R I
IP2,
f1
– f2
(d
Bm
)
OBSERVATION RECEIVER ATTENUATION (dB)
–40°C, ORx1–40°C, ORx2–40°C, ORx3–40°C, ORx4
+25°C, ORx1+25°C, ORx2+25°C, ORx3+25°C, ORx4
+110°C, ORx1+110°C, ORx2+110°C, ORx3+110°C, ORx4
20043-368
Figure 235. Observation Receiver IIP2, f1 − f2 vs. Observation Receiver Attenuation, Both Tones at −11 dBFS, f1 = 102 MHz, f2 = 2 MHz
2605 2615 2625 2635 2645 2655 2665
OB
SE
RV
AT
ION
RE
CE
IVE
R I
IP3,
2f1
+ f
2 (d
Bm
)
TONE 2 FREQUENCY (MHz)
–40°C, ORx1–40°C, ORx2–40°C, ORx3–40°C, ORx4
+25°C, ORx1+25°C, ORx2+25°C, ORx3+25°C, ORx4
+110°C, ORx1+110°C, ORx2+110°C, ORx3+110°C, ORx4
20043-369
Figure 236. Observation Receiver IIP3, 2f1 + f2 vs. Tone 2 Frequency, Both Tones at −11 dBFS, 0 dB Attenuation, f1 = f2 + 2 MHz
ADRV9010 Data Sheet
Rev. E | Page 66 of 115
2605 2615 2625 2635 2645 2655 2665
OB
SE
RV
AT
ION
RE
CE
IVE
R I
IP3,
2f2
+ f
1 (d
Bm
)
TONE 2 FREQUENCY (MHz)
–40°C, ORx1–40°C, ORx2–40°C, ORx3–40°C, ORx4
+25°C, ORx1+25°C, ORx2+25°C, ORx3+25°C, ORx4
+110°C, ORx1+110°C, ORx2+110°C, ORx3+110°C, ORx4
20043-370
Figure 237. Observation Receiver IIP3, 2f2 + f1 vs. Tone 2 Frequency, Both Tones at −11 dBFS, 0 dB Attenuation, f1 = f2 + 2 MHz
2605 2635 2665 2695 2725 2755 2785 2815
OB
SE
RV
AT
ION
RE
CE
IVE
R I
IP3,
2f1
– f
2 (d
Bm
)
TONE 2 FREQUENCY (MHz)
–40°C, ORx1–40°C, ORx2–40°C, ORx3–40°C, ORx4
+25°C, ORx1+25°C, ORx2+25°C, ORx3+25°C, ORx4
+110°C, ORx1+110°C, ORx2+110°C, ORx3+110°C, ORx4
20043-371
Figure 238. Observation Receiver IIP3, 2f1 − f2 vs. Tone 2 Frequency, Both Tones at −11 dBFS, 0 dB Attenuation, f1 = f2 + 2 MHz
2605 2635 2665 2695 2725 2755 2785 2815
OB
SE
RV
AT
ION
RE
CE
IVE
R I
IP3,
2f2
– f
1 (d
Bm
)
TONE 2 FREQUENCY (MHz)
–40°C, ORx1–40°C, ORx2–40°C, ORx3–40°C, Oz4
+25°C, ORx1+25°C, ORx2+25°C, ORx3+25°C, ORx4
+110°C, ORx1+110°C, ORx2+110°C, ORx3+110°C, ORx4
20043-372
Figure 239. Observation Receiver IIP3, 2f2 − f1 vs. Tone 2 Frequency, Both Tones at −11 dBFS, 0 dB Attenuation, f1 = f2 + 2 MHz
10 20 30 40 50 60 70 80 90 100
OB
SE
RV
AT
ION
RE
CE
IVE
R I
IP3,
2f1
+ f
2 (d
Bm
)
TWO-TONE FREQUENCY SPACING (MHz)
–40°C, ORx1–40°C, ORx2–40°C, ORx3–40°C, ORx4
+25°C, ORx1+25°C, ORx2+25°C, ORx3+25°C, ORx4
+110°C, ORx1+110°C, ORx2+110°C, ORx3+110°C, ORx4
20043-373
Figure 240. Observation Receiver IIP3, 2f1 + f2 vs. Two-Tone Frequency Spacing, Both Tones at −11 dBFS, 0 dB Attenuation, f2 = 2 MHz
10 30 50 70 90 110 130 150 170 190 210
OB
SE
RV
AT
ION
RE
CE
IVE
R I
IP3,
2f2
+ f
1 (d
Bm
)
TWO-TONE FREQUENCY SPACING (MHz)
–40°C, ORx1–40°C, ORx2–40°C, ORx3–40°C, ORx4
+25°C, ORx1+25°C, ORx2+25°C, ORx3+25°C, ORx4
+110°C, ORx1+110°C, ORx2+110°C, ORx3+110°C, ORx4
20043-375
Figure 241. Observation Receiver IIP3, 2f2 + f1 vs. Two-Tone Frequency Spacing, Both Tones at −11 dBFS, 0 dB Attenuation, f2 = 2 MHz
10 30 50 70 90 110
OB
SE
RV
AT
ION
RE
CE
IVE
R I
IP3,
2f1
– f
2 (d
Bm
)
TWO-TONE FREQUENCY SPACING (MHz)
–40°C, ORx1–40°C, ORx2–40°C, ORx3–40°C, ORx4
+25°C, ORx1+25°C, ORx2+25°C, ORx3+25°C, ORx4
+110°C, ORx1+110°C, ORx2+110°C, ORx3+110°C, ORx4
20043-376
Figure 242. Observation Receiver IIP3, 2f1 − f2 vs. Two-Tone Frequency Spacing, Both Tones at −11 dBFS, 0 dB Attenuation, f2 = 2 MHz
Data Sheet ADRV9010
Rev. E | Page 67 of 115
–40°C, ORx1–40°C, ORx2–40°C, ORx3–40°C, ORx4
+25°C, ORx1+25°C, ORx2+25°C, ORx3+25°C, ORx4
+110°C, ORx1+110°C, ORx2+110°C, ORx3+110°C, ORx4
10 40 70 100 130 160 190 220
OB
SE
RV
AT
ION
RE
CE
IVE
R I
IP3,
2f2
– f
1 (d
Bm
)
TWO-TONE FREQUENCY SPACING (MHz) 20043-387
Figure 243. Observation Receiver IIP3, 2f2 − f1 vs. Two-Tone Frequency Spacing, Both Tones at −11 dBFS, 0 dB Attenuation, f2 = 2 MHz
0 5 10 15 20 25 30
OB
SE
RV
AT
ION
RE
CE
IVE
R I
IP3,
2f2
+ f
1 (d
Bm
)
OBSERVATION RECEIVER ATTENUATION (dB)
–40°C, ORx1–40°C, ORx2–40°C, ORx3–40°C, ORx4
+25°C, ORx1+25°C, ORx2+25°C, ORx3+25°C, ORx4
+110°C, ORx1+110°C, ORx2+110°C, ORx3+110°C, ORx4
20043-377
Figure 244. Observation Receiver IIP3, 2f2 + f1 vs. Observation Receiver Attenuation, Both Tones at −11 dBFS, f1 = 122 MHz, f2 = 2 MHz
0 5 10 15 20 25 30
OB
SE
RV
AT
ION
RE
CE
IVE
R I
IP3,
2f2
– f
1 (d
Bm
)
OBSERVATION RECEIVER ATTENUATION (dB)
–40°C, ORx1–40°C, ORx2–40°C, ORx3–40°C, ORx4
+25°C, ORx1+25°C, ORx2+25°C, ORx3+25°C, ORx4
+110°C, ORx1+110°C, ORx2+110°C, ORx3+110°C, ORx4
20043-378
Figure 245. Observation Receiver IIP3, 2f2 − f1 vs. Observation Receiver Attenuation, Both Tones at −11 dBFS, f1 = 122 MHz, f2 = 2 MHz
ADRV9010 Data Sheet
Rev. E | Page 68 of 115
3800 MHz BAND The temperature settings refer to the die temperature. All LO frequencies set to 3800 MHz, unless otherwise noted.
7.0
3.0
3.5
4.0
4.5
5.0
5.5
6.0
6.5
3500 3600 3700 3800 3900 4000
TR
AN
SM
ITT
ER
CW
OU
TP
UT
PO
WE
R (
dB
m)
TRANSMITTER LO FREQUENCY (MHz)
+110°C+25°C–40°C
20043-177
Figure 246. Transmitter CW Output Power vs. Transmitter LO Frequency, 10 MHz Offset, 0 dB Attenuation
3300 3500 3700 3900 4100 43003400 3600 3800 4000 4200
FREQUENCY (MHz)
0
–100
–80
–60
–90
–70
–50
–40
–20
–30
–10
TR
AN
SM
ITT
ER
OU
TP
UT
PO
WE
R S
PE
CT
RU
M (
dB
m)
SIGNALNOISE FLOOR
20043-178
Figure 247. Transmitter Output Power Spectrum, Tx1, 5 MHz LTE, 10 MHz Offset, −10 dBFS RMS, 1 MHz Resolution Bandwidth, T = 25°C
(Step at 3600 MHz Due to Spectrum Analyzer)
–20
–100
–90
–80
–70
–60
–40
–50
–30
–100 –80 –60 –40 0 40 80–20 20 60 100
TR
AN
SM
ITT
ER
IM
AG
E R
EJE
CT
ION
(d
Bc)
BASEBAND OFFSET FREQUENCY (MHz)
+110°C, Tx1+110°C, Tx2+110°C, Tx3+110°C, Tx4
+25°C, Tx1+25°C, Tx2+25°C, Tx3+25°C, Tx4
–40°C, Tx1–40°C, Tx2–40°C, Tx3–40°C, Tx4
20043-179
Figure 248. Transmitter Image Rejection vs. Baseband Offset Frequency, 0 dB Attenuation, QEC Tracking Enabled
–100
–180
–150
–170
–130
–110
–160
–140
–120
0 10 205 15
TR
AN
SM
ITT
ER
NO
ISE
(d
Bm
/Hz)
TRANSMITTER ATTENUATION (dB)
+110°C, Tx1+110°C, Tx2+110°C, Tx3+110°C, Tx4
+25°C, Tx1+25°C, Tx2+25°C, Tx3+25°C, Tx4
–40°C, Tx1–40°C, Tx2–40°C, Tx3–40°C, Tx4
20043-180
Figure 249. Transmitter Noise vs. Transmitter Attenuation, 50 MHz Offset Frequency
1.0
–0.2
0
0.2
0.4
0.6
0.8
–250 –200 –150 –100 0 100 200–50 50 150 250
TR
AN
SM
ITT
ER
PA
SS
BA
ND
FL
AT
NE
SS
(d
B)
BASEBAND OFFSET FREQUENCY (MHz)
+110°C+25°C–40°C
20043-181
Figure 250. Transmitter Pass Band Flatness vs. Baseband Offset Frequency
–40
–80
–70
–60
–75
–65
–55
–50
–45
0 5 10 15 20
AD
JAC
EN
T C
HA
NN
EL
PO
WE
R L
EV
EL
(d
Bc)
TRANSMITTER ATTENUATION (dB)
+110°C+25°C–40°C
20043-182
Figure 251. Adjacent Channel Power Level vs. Transmitter Attenuation, −10 MHz Baseband Offset, 20 MHz LTE, PAR = 12 dB, Loop Filter
Bandwidth = 600 kHz, Loop Filter Phase Margin = 75°
Data Sheet ADRV9010
Rev. E | Page 69 of 115
–40
–80
–70
–60
–75
–65
–55
–50
–45
0 5 10 15 20
AD
JAC
EN
T C
HA
NN
EL
PO
WE
R L
EV
EL
(d
Bc)
TRANSMITTER ATTENUATION (dB)
+110°C+25°C–40°C
20043-183
Figure 252. Adjacent Channel Power Level vs. Transmitter Attenuation, 90 MHz Baseband Offset, 20 MHz LTE, PAR = 12 dB, Loop Filter Bandwidth
= 600 kHz, Loop Filter Phase Margin = 75°
–60
–110
–105
–95
–80
–85
–100
–90
–75
–70
–65
0 6 12 184 10 162 8 14 20
TR
AN
SM
ITT
ER
HD
2 (d
Bc)
TRANSMITTER ATTENUATION (dB)
+110°C, UPPER HD2+25°C, UPPER HD2–40°C, UPPER HD2+110°C, LOWER HD2+25°C, LOWER HD2–40°C, LOWER HD2
20043-184
Figure 253. Transmitter HD2 vs. Transmitter Attenuation, 10 MHz Offset
–60
–110
–105
–95
–80
–85
–100
–90
–75
–70
–65
0 6 12 184 10 162 8 14 20
TR
AN
SM
ITT
ER
HD
3 (d
Bc)
TRANSMITTER ATTENUATION (dB)
+110°C, UPPER HD3+25°C, UPPER HD3–40°C, UPPER HD3+110°C, LOWER HD3+25°C, LOWER HD3–40°C, LOWER HD3
20043-185
Figure 254. Transmitter HD3 vs. Transmitter Attenuation, 10 MHz Offset
0.05
–0.05
–0.04
–0.02
0
–0.03
–0.01
0.01
0.02
0.03
0.04
0 4 8 12 20 2816 24 32
TR
AN
SM
ITT
ER
AT
TE
NU
AT
OR
ST
EP
ER
RO
R (
dB
)
TRANSMITTER ATTENUATION (dB)
+110°C+25°C–40°C
20043-186
Figure 255. Transmitter Attenuator Step Error vs. Transmitter Attenuation, 10 MHz Offset
–38
–48
–46
–44
–42
–40
–39
–47
–45
–43
–41
0 2 8 14 206 12 184 10 16
TR
AN
SM
ITT
ER
ER
RO
R V
EC
TO
R M
AG
NIT
UD
E (
dB
)
TRANSMITTER ATTENUATION (dB)
+110°C, Tx1+110°C, Tx2+110°C, Tx3+110°C, Tx4
+25°C, Tx1+25°C, Tx2+25°C, Tx3+25°C, Tx4
–40°C, Tx1–40°C, Tx2–40°C, Tx3–40°C, Tx4
20043-187
Figure 256. Transmitter Error Vector Magnitude vs. Transmitter Attenuation, 20 MHz LTE Signal Centered at LO Frequency, Sample Rate = 491.52 MSPS,
QEC Tracking Enabled, Loop Filter Bandwidth = 600 kHz, Loop Filter Phase Margin = 75°
45
40
–10
0
10
20
30
35
–5
5
15
25
0 8 16 24 324 12 20 28
TR
AN
SM
ITT
ER
OIP
3, 2
f1 –
f2
(dB
m)
TRANSMITTER ATTENUATION (dB)
+110°C, Tx1+110°C, Tx2+110°C, Tx3+110°C, Tx4
+25°C, Tx1+25°C, Tx2+25°C, Tx3+25°C, Tx4
–40°C, Tx1–40°C, Tx2–40°C, Tx3–40°C, Tx4
20043-188
Figure 257. Transmitter OIP3, 2f1 − f2 vs. Transmitter Attenuation, 15 dB Digital Backoff per Tone, f1 = 50.5 MHz, f2 = 55.5 MHz
ADRV9010 Data Sheet
Rev. E | Page 70 of 115
45
40
–10
0
10
20
30
35
–5
5
15
25
0 8 16 24 324 12 20 28
TR
AN
SM
ITT
ER
OIP
3, 2
f2 –
f1
(dB
m)
TRANSMITTER ATTENUATION (dB)
+110°C, Tx1+110°C, Tx2+110°C, Tx3+110°C, Tx4
+25°C, Tx1+25°C, Tx2+25°C, Tx3+25°C, Tx4
–40°C, Tx1–40°C, Tx2–40°C, Tx3–40°C, Tx4
20043-189
Figure 258. Transmitter OIP3, 2f2 − f1 vs. Transmitter Attenuation, 15 dB Digital Backoff per Tone, f1 = 50.5 MHz, f2 = 55.5 MHz
50
45
40
0
10
20
30
35
5
15
25
10 50 90 130 19017030 70 110 150
TR
AN
SM
ITT
ER
OIP
3, 2
f1 –
f2
(dB
m)
f1 BASEBAND OFFSET TONE FREQUENCY (MHz)
+110°C, Tx1+110°C, Tx2+110°C, Tx3+110°C, Tx4
+25°C, Tx1+25°C, Tx2+25°C, Tx3+25°C, Tx4
–40°C, Tx1–40°C, Tx2–40°C, Tx3–40°C, Tx4
20043-190
Figure 259. Transmitter OIP3, 2f1 − f2 vs. f1 Baseband Offset Tone Frequency, f2 = f1 + 5 MHz, 15 dB Digital Backoff per Tone
50
45
40
0
10
20
30
35
5
15
25
10 50 90 130 19017030 70 110 150
TR
AN
SM
ITT
ER
OIP
3, 2
f2 –
f1
(dB
m)
f1 BASEBAND OFFSET TONE FREQUENCY (MHz)
+110°C, Tx1+110°C, Tx2+110°C, Tx3+110°C, Tx4
+25°C, Tx1+25°C, Tx2+25°C, Tx3+25°C, Tx4
–40°C, Tx1–40°C, Tx2–40°C, Tx3–40°C, Tx4
20043-191
Figure 260. Transmitter OIP3, 2f2 − f1 vs. f1 Baseband Offset Tone Frequency, f2 = f1 + 5 MHz, 15 dB Digital Backoff per Tone
50
45
40
0
10
20
30
35
5
15
25
10 50 90 130 19017030 70 110 150
TR
AN
SM
ITT
ER
OIP
3, 2
f1 +
f2
(dB
m)
f1 BASEBAND OFFSET TONE FREQUENCY (MHz)
+110°C, Tx1+110°C, Tx2+110°C, Tx3+110°C, Tx4
+25°C, Tx1+25°C, Tx2+25°C, Tx3+25°C, Tx4
–40°C, Tx1–40°C, Tx2–40°C, Tx3–40°C, Tx4
20043-192
Figure 261. Transmitter OIP3, 2f1 + f2 vs. f1 Baseband Offset Tone Frequency, f2 = f1 + 5 MHz, 15 dB Digital Backoff per Tone
50
45
40
0
10
20
30
35
5
15
25
10 50 90 130 19017030 70 110 150
TR
AN
SM
ITT
ER
OIP
3, 2
f2 +
f1
(dB
m)
f1 BASEBAND OFFSET TONE FREQUENCY (MHz)
+110°C, Tx1+110°C, Tx2+110°C, Tx3+110°C, Tx4
+25°C, Tx1+25°C, Tx2+25°C, Tx3+25°C, Tx4
–40°C, Tx1–40°C, Tx2–40°C, Tx3–40°C, Tx4
20043-193
Figure 262. Transmitter OIP3, 2f2 + f1 vs. f1 Baseband Offset Tone Frequency, f2 = f1 + 5 MHz, 15 dB Digital Backoff per Tone
120
40
50
70
90
60
80
100
110
3500 3600 38003700 3900 4000
TR
AN
SM
ITT
ER
TO
TR
AN
SM
ITT
ER
IS
OL
AT
ION
(d
B)
TRANSMITTER LO FREQUENCY (MHz)
Tx1 TO Tx2Tx2 TO Tx1Tx3 TO Tx1Tx4 TO Tx1
Tx1 TO Tx3Tx2 TO Tx3Tx3 TO Tx2Tx4 TO Tx2
Tx1 TO Tx4Tx2 TO Tx4Tx3 TO Tx4Tx4 TO Tx3
20043-195
Figure 263. Transmitter to Transmitter Isolation vs. Transmitter LO Frequency
Data Sheet ADRV9010
Rev. E | Page 71 of 115
130
120
40
50
70
90
60
80
100
110
3500 3600 38003700 3900 4000
RECEIVER LO FREQUENCY (MHz)
TR
AN
SM
ITT
ER
TO
RE
CE
IVE
R I
SO
LA
TIO
N (
dB
)
Tx1 TO Rx1Tx2 TO Rx1Tx3 TO Rx1Tx4 TO Rx1
Tx1 TO Rx2Tx2 TO Rx2Tx3 TO Rx2Tx4 TO Rx2
Tx1 TO Rx3Tx2 TO Rx3Tx3 TO Rx3Tx4 TO Rx3
Tx1 TO Rx4Tx2 TO Rx4Tx3 TO Rx4Tx4 TO Rx4
20043-196
Figure 264. Transmitter to Receiver Isolation vs. Receiver LO Frequency
140
130
120
40
50
70
90
60
80
100
110
3500 3600 38003700 3900 4000
TRANSMITTER LO FREQUENCY (MHz)
TR
AN
SM
ITT
ER
TO
OB
SE
RV
AT
ION
RE
CE
IVE
R I
SO
LA
TIO
N (
dB
)
Tx1 TO ORx1Tx2 TO ORx1Tx3 TO ORx1Tx4 TO ORx1
Tx1 TO ORx2Tx2 TO ORx2Tx3 TO ORx2Tx4 TO ORx2
Tx1 TO ORx3Tx2 TO ORx3Tx3 TO ORx3Tx4 TO ORx3
Tx1 TO ORx4Tx2 TO ORx4Tx3 TO ORx4Tx4 TO ORx4
20043-197
Figure 265. Transmitter to Observation Receiver Isolation vs. Transmitter LO Frequency
3500 3600 38003700 3900 4000
RECEIVER LO FREQUENCY (MHz)
120
50
70
90
60
80
100
110
RE
CE
IVE
R T
O R
EC
EIV
ER
IS
OL
AT
ION
(d
B) Rx1 TO Rx2
Rx2 TO Rx1Rx3 TO Rx1Rx4 TO Rx1
Rx1 TO Rx3Rx2 TO Rx3Rx3 TO Rx2Rx4 TO Rx2
Rx1 TO Rx4Rx2 TO Rx4Rx3 TO Rx4Rx4 TO Rx3
20043-198
Figure 266. Receiver to Receiver Isolation vs. Receiver LO Frequency
50
0
25
5
35
45
15
10
20
30
40
0 10 305 20 2515
RE
CE
IVE
R I
NT
EG
RA
TE
D N
OIS
E F
IGU
RE
(d
B)
RECEIVER ATTENUATION (dB)
+110°C, Rx1+110°C, Rx2+110°C, Rx3+110°C, Rx4
+25°C, Rx1+25°C, Rx2+25°C, Rx3+25°C, Rx4
–40°C, Rx1–40°C, Rx2–40°C, Rx3–40°C, Rx4
20043-199
Figure 267. Receiver Integrated Noise Figure vs. Receiver Attenuation, 20 MHz Offset, 200 MHz Bandwidth, Sample Rate = 245.76 MSPS,
Integration Bandwidth = 500 kHz to 100 MHz
25
0
5
10
15
20
–100 –80 –60 –40 0 40 80–20 20 60 100
RE
CE
IVE
R I
NT
EG
RA
TE
D N
OIS
E F
IGU
RE
(d
B)
BASEBAND OFFSET FREQUENCY (MHz)
+110°C+25°C–40°C
20043-201
Figure 268. Receiver Integrated Noise Figure vs. Baseband Offset Frequency, 200 MHz Bandwidth, Sample Rate = 245.76 MSPS,
Integrated in 200 kHz Steps
–40
–100
–80
–90
–70
–60
–50
3500 3600 3700 3800 40003900
RE
CE
IVE
R L
O L
EA
KA
GE
(d
Bm
)
RECEIVER LO FREQUENCY (MHz)
+110°C+25°C–40°C
20043-202
Figure 269. Receiver LO Leakage vs. Receiver LO Frequency, Attenuation = 0 dB, Sample Rate = 245.76 MSPS
ADRV9010 Data Sheet
Rev. E | Page 72 of 115
20
–15
5
5
0
–10
10
15
0 5 10 15 302520
RECEIVER ATTENUATION (dB)
RE
CE
IVE
R G
AIN
(d
B)
+110°C, Rx1+110°C, Rx2+110°C, Rx3+110°C, Rx4
+25°C, Rx1+25°C, Rx2+25°C, Rx3+25°C, Rx4
–40°C, Rx1–40°C, Rx2–40°C, Rx3–40°C, Rx4
20043-203
Figure 270. Receiver Gain vs. Receiver Attenuation, 20 MHz Offset, 200 MHz Bandwidth, Sample Rate = 245.76 MSPS
20
15
17
16
18
19
3500 3600 3700 3800 40003900
RECEIVER LO FREQUENCY (MHz)
RE
CE
IVE
R G
AIN
(d
B)
+110°C, Rx1+110°C, Rx2+110°C, Rx3+110°C, Rx4
+25°C, Rx1+25°C, Rx2+25°C, Rx3+25°C, Rx4
–40°C, Rx1–40°C, Rx2–40°C, Rx3–40°C, Rx4
20043-204
Figure 271. Receiver Gain vs. Receiver LO Frequency, 10 MHz Offset, 200 MHz Bandwidth, Sample Rate = 245.76 MSPS
0.20
–0.20
–0.05
–0.15
0.05
0.15
–0.10
0
0.10
0 5 10 15 302520
RECEIVER ATTENUATION (dB)
RE
CE
IVE
R G
AIN
ST
EP
ER
RO
R (
dB
)
+110°C, Rx1+110°C, Rx2+110°C, Rx3+110°C, Rx4
+25°C, Rx1+25°C, Rx2+25°C, Rx3+25°C, Rx4
–40°C, Rx1–40°C, Rx2–40°C, Rx3–40°C, Rx4
20043-205
Figure 272. Receiver Gain Step Error vs. Receiver Attenuation, 20 MHz Offset, −5 dBFS Input Signal
0.5
–0.5
–0.4
–0.2
0
–0.3
–0.1
0.1
0.2
0.3
0.4
NO
RM
AL
IZE
D R
EC
EIV
ER
FL
AT
NE
SS
(d
B) +110°C
+25°C–40°C
–100 –80 –60 –40 0 40 80–20 20 60 100
BASEBAND OFFSET FREQUENCY (MHz) 20043-206
Figure 273. Normalized Receiver Flatness vs. Baseband Offset Frequency, −5 dBFS Input Signal
–40
–100
–90
–70
–80
–60
–50
RE
CE
IVE
R I
MA
GE
(d
Bc)
–100 –80 –60 –40 0 40 80–20 20 60 100
BASEBAND OFFSET FREQUENCY (MHz)
+110°C, Rx1+110°C, Rx2+110°C, Rx3+110°C, Rx4
+25°C, Rx1+25°C, Rx2+25°C, Rx3+25°C, Rx4
–40°C, Rx1–40°C, Rx2–40°C, Rx3–40°C, Rx4
20043-207
Figure 274. Receiver Image vs. Baseband Offset Frequency, Tracking Calibration Active, Sample Rate = 245.76 MSPS, −5 dBFS Input Signal
–40
–100
–90
–70
–80
–60
–50
RE
CE
IVE
R I
MA
GE
(d
Bc)
+110°C, Rx1+110°C, Rx2+110°C, Rx3+110°C, Rx4
+25°C, Rx1+25°C, Rx2+25°C, Rx3+25°C, Rx4
–40°C, Rx1–40°C, Rx2–40°C, Rx3–40°C, Rx4
0 5 10 15 302520
RECEIVER ATTENUATION (dB) 20043-208
Figure 275. Receiver Image vs. Receiver Attenuation, 20 MHz Offset, Tracking Calibration Active, Sample Rate = 245.76 MSPS, −5 dBFS Input Signal
Data Sheet ADRV9010
Rev. E | Page 73 of 115
–40
–110
–100
–90
–70
–80
–60
–50
RE
CE
IVE
R D
C O
FF
SE
T (
dB
FS
)
+110°C, Rx1+110°C, Rx2+110°C, Rx3+110°C, Rx4
+25°C, Rx1+25°C, Rx2+25°C, Rx3+25°C, Rx4
–40°C, Rx1–40°C, Rx2–40°C, Rx3–40°C, Rx4
0 5 10 15 302520
RECEIVER ATTENUATION (dB) 20043-210
Figure 276. Receiver DC Offset vs. Receiver Attenuation, 20 MHz Offset, −5 dBFS Input Signal
–40
–120
–100
–110
–90
–70
–80
–60
–50
RE
CE
IVE
R H
D2,
LE
FT
SID
E (
dB
c)
+110°C, Rx1+110°C, Rx2+110°C, Rx3+110°C, Rx4
+25°C, Rx1+25°C, Rx2+25°C, Rx3+25°C, Rx4
–40°C, Rx1–40°C, Rx2–40°C, Rx3–40°C, Rx4
–60 –40 –20 0 604020
BASEBAND OFFSET FREQUENCY (MHz) 20043-211
Figure 277. Receiver HD2, Left Side vs. Baseband Offset Frequency, −5 dBFS Input Signal, Distortion Tone Measured Left of 0 Hz
(HD2 Canceller Not Enabled)
–40
–120
–100
–110
–90
–70
–80
–60
–50
RE
CE
IVE
R H
D2,
RIG
HT
SID
E (
dB
c)
+110°C, Rx1+110°C, Rx2+110°C, Rx3+110°C, Rx4
+25°C, Rx1+25°C, Rx2+25°C, Rx3+25°C, Rx4
–40°C, Rx1–40°C, Rx2–40°C, Rx3–40°C, Rx4
–60 –40 –20 0 604020
BASEBAND OFFSET FREQUENCY (MHz) 20043-212
Figure 278. Receiver HD2, Right Side vs. Baseband Offset Frequency, −5 dBFS Input Signal, Distortion Tone Measured Right of 0 Hz
(HD2 Canceller Not Enabled)
–40
–120
–100
–110
–90
–70
–80
–60
–50
RE
CE
IVE
R H
D3,
LE
FT
SID
E (
dB
c)
+110°C, Rx1+110°C, Rx2+110°C, Rx3+110°C, Rx4
+25°C, Rx1+25°C, Rx2+25°C, Rx3+25°C, Rx4
–40°C, Rx1–40°C, Rx2–40°C, Rx3–40°C, Rx4
–40 –30 –20 –10 0 40302010
BASEBAND OFFSET FREQUENCY (MHz) 20043-213
Figure 279. Receiver HD3, Left Side vs. Baseband Offset Frequency, −5 dBFS Input Signal, Distortion Tone Measured Left of 0 Hz
–40
–120
–100
–110
–90
–70
–80
–60
–50
RE
CE
IVE
R H
D3,
RIG
HT
SID
E (
dB
c)
+110°C, Rx1+110°C, Rx2+110°C, Rx3+110°C, Rx4
+25°C, Rx1+25°C, Rx2+25°C, Rx3+25°C, Rx4
–40°C, Rx1–40°C, Rx2–40°C, Rx3–40°C, Rx4
–40 –30 –20 –10 0 40302010
BASEBAND OFFSET FREQUENCY (MHz) 20043-214
Figure 280. Receiver HD3, Right Side vs. Baseband Offset Frequency, −5 dBFS Input Signal, Distortion Tone Measured Right of 0 Hz
80
50
60
55
65
75
70
RE
CE
IVE
R I
IP2,
f1
+ f
2 (d
Bm
)
+110°C, Rx1+110°C, Rx2+110°C, Rx3+110°C, Rx4
+25°C, Rx1+25°C, Rx2+25°C, Rx3+25°C, Rx4
–40°C, Rx1–40°C, Rx2–40°C, Rx3–40°C, Rx4
3805 3815 3825 3835 3845
TONE 2 FREQUENCY (MHz) 20043-215
Figure 281. Receiver IIP2, f1 + f2 vs. Tone 2 Frequency, Both Tones at −11 dBFS, 0 dB Attenuation, f1 = f2 + 2 MHz
ADRV9010 Data Sheet
Rev. E | Page 74 of 115
80
50
60
55
65
75
70
RE
CE
IVE
R I
IP2,
f1
– f2
(d
Bm
)
+110°C, Rx1+110°C, Rx2+110°C, Rx3+110°C, Rx4
+25°C, Rx1+25°C, Rx2+25°C, Rx3+25°C, Rx4
–40°C, Rx1–40°C, Rx2–40°C, Rx3–40°C, Rx4
3805 3825 3845 3865 389538853815 3835 3855 3875
TONE 2 FREQUENCY (MHz) 20043-216
Figure 282. Receiver IIP2, f1 − f2 vs. Tone 2 Frequency, Both Tones at −11 dBFS, 0 dB Attenuation, f1 = f2 + 2 MHz
80
50
60
55
65
75
70
RE
CE
IVE
R I
IP2,
f1
+ f
2 (d
Bm
)
+110°C, Rx1+110°C, Rx2+110°C, Rx3+110°C, Rx4
+25°C, Rx1+25°C, Rx2+25°C, Rx3+25°C, Rx4
–40°C, Rx1–40°C, Rx2–40°C, Rx3–40°C, Rx4
10 30 50 70 9020 40 60 80
TWO-TONE FREQUENCY SPACING (MHz) 20043-217
Figure 283. Receiver IIP2, f1 + f2 vs. Two-Tone Frequency Spacing, Both Tones at −11 dBFS, 0 dB Attenuation, f2 = 2 MHz
80
50
60
55
65
75
70
RE
CE
IVE
R I
IP2,
f1
– f2
(d
Bm
)
+110°C, Rx1+110°C, Rx2+110°C, Rx3+110°C, Rx4
+25°C, Rx1+25°C, Rx2+25°C, Rx3+25°C, Rx4
–40°C, Rx1–40°C, Rx2–40°C, Rx3–40°C, Rx4
10 30 50 70 9020 40 60 80
TWO-TONE FREQUENCY SPACING (MHz) 20043-218
Figure 284. Receiver IIP2, f1 − f2 vs. Two-Tone Frequency Spacing, Both Tones at −11 dBFS, 0 dB Attenuation, f2 = 2 MHz
100
60
70
65
75
85
80
90
95
RE
CE
IVE
R I
IP2,
f1
+ f
2 (d
Bm
)
+110°C, Rx1+110°C, Rx2+110°C, Rx3+110°C, Rx4
+25°C, Rx1+25°C, Rx2+25°C, Rx3+25°C, Rx4
–40°C, Rx1–40°C, Rx2–40°C, Rx3–40°C, Rx4
0 10 305 20 2515
RECEIVER ATTENUATION (dB) 20043-219
Figure 285. Receiver IIP2, f1 + f2 vs. Receiver Attenuation, Both Tones at −11 dBFS, f1 = 92 MHz, f2 = 2 MHz
100
60
70
65
75
85
80
90
95
RE
CE
IVE
R I
IP2,
f1
– f2
(d
Bm
)
+110°C, Rx1+110°C, Rx2+110°C, Rx3+110°C, Rx4
+25°C, Rx1+25°C, Rx2+25°C, Rx3+25°C, Rx4
–40°C, Rx1–40°C, Rx2–40°C, Rx3–40°C, Rx4
0 10 305 20 2515
RECEIVER ATTENUATION (dB) 20043-220
Figure 286. Receiver IIP2, f1 − f2 vs. Receiver Attenuation, Both Tones at −11 dBFS, f1 = 92 MHz, f2 = 2 MHz
40
0
10
5
15
25
20
30
35
RE
CE
IVE
R I
IP3,
2f1
+ f
2 (d
Bm
)
+110°C, Rx1+110°C, Rx2+110°C, Rx3+110°C, Rx4
+25°C, Rx1+25°C, Rx2+25°C, Rx3+25°C, Rx4
–40°C, Rx1–40°C, Rx2–40°C, Rx3–40°C, Rx4
3805 3810 3815 3820 3825
TONE 2 FREQUENCY (MHz) 20043-221
Figure 287. Receiver IIP3, 2f1 + f2 vs. Tone 2 Frequency, Both Tones at −11 dBFS, 0 dB Attenuation, f1 = f2 + 2 MHz
Data Sheet ADRV9010
Rev. E | Page 75 of 115
40
0
10
5
15
25
20
30
35
+110°C, Rx1+110°C, Rx2+110°C, Rx3+110°C, Rx4
+25°C, Rx1+25°C, Rx2+25°C, Rx3+25°C, Rx4
–40°C, Rx1–40°C, Rx2–40°C, Rx3–40°C, Rx4
3805 3810 3815 3820 3825
TONE 2 FREQUENCY (MHz)
RE
CE
IVE
R I
IP3,
2f2
+ f
1 (d
Bm
)
20043-222
Figure 288. Receiver IIP3, 2f2 + f1 vs. Tone 2 Frequency, Both Tones at −11 dBFS, 0 dB Attenuation, f1 = f2 + 2 MHz
40
0
10
5
15
25
20
30
35+110°C, Rx1+110°C, Rx2+110°C, Rx3+110°C, Rx4
+25°C, Rx1+25°C, Rx2+25°C, Rx3+25°C, Rx4
–40°C, Rx1–40°C, Rx2–40°C, Rx3–40°C, Rx4
RE
CE
IVE
R I
IP3,
2f1
– f
2 (d
Bm
)
3805 3825 3845 3865 389538853815 3835 3855 3875
TONE 2 FREQUENCY (MHz) 20043-223
Figure 289. Receiver IIP3, 2f1 − f2 vs. Tone 2 Frequency, Both Tones at −11 dBFS, 0 dB Attenuation, f1 = f2 + 2 MHz
40
0
10
5
15
25
20
30
35+110°C, Rx1+110°C, Rx2+110°C, Rx3+110°C, Rx4
+25°C, Rx1+25°C, Rx2+25°C, Rx3+25°C, Rx4
–40°C, Rx1–40°C, Rx2–40°C, Rx3–40°C, Rx4
RE
CE
IVE
R I
IP3,
2f2
– f
1 (d
Bm
)
3805 3825 3845 3865 389538853815 3835 3855 3875
TONE 2 FREQUENCY (MHz) 20043-224
Figure 290. Receiver IIP3, 2f2 − f1 vs. Tone 2 Frequency, Both Tones at −11 dBFS, 0 dB Attenuation, f1 = f2 + 2 MHz
35
10
15
25
20
30
RE
CE
IVE
R I
IP3,
2f1
+ f
2 (d
Bm
)
+110°C, Rx1+110°C, Rx2+110°C, Rx3+110°C, Rx4
+25°C, Rx1+25°C, Rx2+25°C, Rx3+25°C, Rx4
–40°C, Rx1–40°C, Rx2–40°C, Rx3–40°C, Rx4
10 20 30 4015 25 35
TWO-TONE FREQUENCY SPACING (MHz) 20043-225
Figure 291. Receiver IIP3, 2f1 + f2 vs. Two-Tone Frequency Spacing, Both Tones at −11 dBFS, 0 dB Attenuation, f2 = 2 MHz
35
10
15
25
20
30
RE
CE
IVE
R I
IP3,
2f2
+ f
1 (d
Bm
)
+110°C, Rx1+110°C, Rx2+110°C, Rx3+110°C, Rx4
+25°C, Rx1+25°C, Rx2+25°C, Rx3+25°C, Rx4
–40°C, Rx1–40°C, Rx2–40°C, Rx3–40°C, Rx4
10 30 60 9020 40 8050 70
TWO-TONE FREQUENCY SPACING (MHz) 20043-226
Figure 292. Receiver IIP3, 2f2 + f1 vs. Two-Tone Frequency Spacing, Both Tones at −11 dBFS, 0 dB Attenuation, f2 = 2 MHz
35
10
15
25
20
30
RE
CE
IVE
R I
IP3,
2f1
– f
2 (d
Bm
)
+110°C, Rx1+110°C, Rx2+110°C, Rx3+110°C, Rx4
+25°C, Rx1+25°C, Rx2+25°C, Rx3+25°C, Rx4
–40°C, Rx1–40°C, Rx2–40°C, Rx3–40°C, Rx4
10 20 35 4015 25 30
TWO-TONE FREQUENCY SPACING (MHz) 20043-227
Figure 293. Receiver IIP3, 2f1 − f2 vs. Two-Tone Frequency Spacing, Both Tones at −11 dBFS, 0 dB Attenuation, f2 = 2 MHz
ADRV9010 Data Sheet
Rev. E | Page 76 of 115
35
10
15
25
20
30
RE
CE
IVE
R I
IP3,
2f2
– f
1 (d
Bm
)
+110°C, Rx1+110°C, Rx2+110°C, Rx3+110°C, Rx4
+25°C, Rx1+25°C, Rx2+25°C, Rx3+25°C, Rx4
–40°C, Rx1–40°C, Rx2–40°C, Rx3–40°C, Rx4
10 30 60 9020 40 8050 70
TWO-TONE FREQUENCY SPACING (MHz) 20043-228
Figure 294. Receiver IIP3, 2f2 − f1 vs. Two-Tone Frequency Spacing, Both Tones at −11 dBFS, 0 dB Attenuation, f2 = 2 MHz
–20
–25
–50
–45
–35
–40
–30
RE
CE
IVE
R E
RR
OR
VE
CT
OR
MA
GN
ITU
DE
(d
B)
+110°C, Rx1+110°C, Rx2+110°C, Rx3+110°C, Rx4
+25°C, Rx1+25°C, Rx2+25°C, Rx3+25°C, Rx4
–40°C, Rx1–40°C, Rx2–40°C, Rx3–40°C, Rx4
–60 –45 –15 5–55 –35 0–25–40 –10–50 –30 –20 –5
RECEIVER INPUT POWER (dBm) 20043-229
Figure 295. Receiver Error Vector Magnitude vs. Receiver Input Power, 20 MHz LTE Signal Centered at LO Frequency, Sample Rate = 245.76 MSPS,
Loop Filter Bandwidth = 600 kHz, Loop Filter Phase Margin = 75°
100 1k 10k 100k 1M 10M–150
–140
–130
–120
–110
–100
–90
–80
LO
PH
AS
E N
OIS
E (
dB
c/H
z)
FREQUENCY OFFSET (Hz) 20043-268
Figure 296. LO Phase Noise vs. Frequency Offset, Loop Bandwidth = 75 kHz, Phase Margin = 85°
100 1k 10k 100k 1M 10M–150
–140
–130
–120
–110
–100
–90
–80
LO
PH
AS
E N
OIS
E (
dB
c/H
z)
FREQUENCY OFFSET (Hz) 20043-269
Figure 297. LO Phase Noise vs. Frequency Offset, Loop Bandwidth = 600 kHz, Phase Margin = 60°
50
45
0
5
25
15
35
40
20
10
30
OB
SE
RV
AT
ION
RE
CE
IVE
R I
NT
EG
RA
TE
DN
OIS
E F
IGU
RE
(d
B)
0 10 205 15
OBSERVATION RECEIVER ATTENUATION (dB)
+110°C, ORx1+110°C, ORx2+110°C, ORx3+110°C, ORx4
+25°C, ORx1+25°C, ORx2+25°C, ORx3+25°C, ORx4
–40°C, ORx1–40°C, ORx2–40°C, ORx3–40°C, ORx4
20043-232
Figure 298. Observation Receiver Integrated Noise Figure vs. Observation Receiver Attenuation, 20 MHz Offset, 450 MHz Bandwidth, Sample Rate =
491.52 MSPS, Integration Bandwidth = 500 kHz to 100 MHz
35
0
5
25
15
20
10
30
OB
SE
RV
AT
ION
RE
CE
IVE
R I
NT
EG
RA
TE
DN
OIS
E F
IGU
RE
(d
B)
–250 –50 250–150 15050
BASEBAND OFFSET FREQUENCY (MHz)
+110°C+25°C–40°C
20043-234
Figure 299. Observation Receiver Integrated Noise Figure vs. Baseband Offset Frequency, 450 MHz Bandwidth, Sample Rate = 491.52 MSPS,
Integrated in 200 kHz Steps
Data Sheet ADRV9010
Rev. E | Page 77 of 115
–40
–100
–90
–60
–80
–70
–50
OB
SE
RV
AT
ION
RE
CE
IVE
R L
O L
EA
KA
GE
(d
Bm
)
3500 3700 40003600 39003800
OBSERVATION RECEIVER LO FREQUENCY (MHz)
+110°C+25°C–40°C
20043-235
Figure 300. Observation Receiver LO Leakage vs. Observation Receiver LO Frequency, 0 dB Attenuation, Sample Rate = 491.52 MSPS
20
15
–15
–5
5
10
–10
0
OB
SE
RV
AT
ION
RE
CE
IVE
R G
AIN
(d
B)
0 10 305 15 20 25
OBSERVATION RECEIVER ATTENUATION (dB)
+110°C, ORx1+110°C, ORx2+110°C, ORx3+110°C, ORx4
+25°C, ORx1+25°C, ORx2+25°C, ORx3+25°C, ORx4
–40°C, ORx1–40°C, ORx2–40°C, ORx3–40°C, ORx4
20043-236
Figure 301. Observation Receiver Gain vs. Observation Receiver Attenuation, 20 MHz Offset, 450 MHz Bandwidth, Sample Rate = 491.52 MSPS
20
19
15
17
18
16
OB
SE
RV
AT
ION
RE
CE
IVE
R G
AIN
(d
B)
+110°C, ORx1+110°C, ORx2+110°C, ORx3+110°C, ORx4
+25°C, ORx1+25°C, ORx2+25°C, ORx3+25°C, ORx4
–40°C, ORx1–40°C, ORx2–40°C, ORx3–40°C, ORx4
3500 3700 40003600 39003800
OBSERVATION RECEIVER LO FREQUENCY (MHz) 20043-237
Figure 302. Observation Receiver Gain vs. Observation Receiver LO Frequency, 450 MHz Bandwidth, Sample Rate = 491.52 MSPS
0.20
–0.20
–0.15
0.15
–0.05
0.05
0.10
–0.10
0
OB
SE
RV
AT
ION
RE
CE
IVE
R G
AIN
ST
EP
ER
RO
R (
dB
)
0 10 305 20 2515
OBSERVATION RECEIVER ATTENUATION (dB)
+110°C, ORx1+110°C, ORx2+110°C, ORx3+110°C, ORx4
+25°C, ORx1+25°C, ORx2+25°C, ORx3+25°C, ORx4
–40°C, ORx1–40°C, ORx2–40°C, ORx3–40°C, ORx4
20043-238
Figure 303. Observation Receiver Gain Step Error vs. Observation Receiver Attenuation, 20 MHz Offset, −5 dBFS Input Signal
0.5
–0.5
–0.3
0.1
–0.1
–0.4
–0.2
0
0.3
0.2
0.4
NO
RM
AL
IZE
D O
BS
ER
VA
TIO
N R
EC
EIV
ER
FL
AT
NE
SS
(d
B)
–220 –140 220–180 18020 100–60 140–20 60–100
BASEBAND OFFSET FREQUENCY (MHz)
+110°C+25°C–40°C
20043-239
Figure 304. Normalized Observation Receiver Flatness vs. Baseband Offset Frequency, −25 dBm Input Signal, 0 dB Attenuation
–40
–100
–90
–70
–80
–50
–60
OB
SE
RV
AT
ION
RE
CE
IVE
R I
MA
GE
(d
Bc)
–225 –125 225–175 75 175–25 25 125–75
BASEBAND OFFSET FREQUENCY (MHz)
+110°C, ORx1+110°C, ORx2+110°C, ORx3+110°C, ORx4
+25°C, ORx1+25°C, ORx2+25°C, ORx3+25°C, ORx4
–40°C, ORx1–40°C, ORx2–40°C, ORx3–40°C, ORx4
20043-240
Figure 305. Observation Receiver Image vs. Baseband Offset Frequency, Tracking Calibration Active, Sample Rate = 491.52 MSPS
ADRV9010 Data Sheet
Rev. E | Page 78 of 115
–40
–100
–90
–70
–80
–50
–60
OB
SE
RV
AT
ION
RE
CE
IVE
R I
MA
GE
(d
Bc)
0 10 305 20 2515
OBSERVATION RECEIVER ATTENUATION (dB)
+110°C, ORx1+110°C, ORx2+110°C, ORx3+110°C, ORx4
+25°C, ORx1+25°C, ORx2+25°C, ORx3+25°C, ORx4
–40°C, ORx1–40°C, ORx2–40°C, ORx3–40°C, ORx4
20043-241
Figure 306. Observation Receiver Image vs. Observation Receiver Attenuation, 20 MHz Offset, Tracking Calibration Active, Sample Rate = 491.52 MSPS
–40
–120
–80
–50
–60
–100
–90
–110
–70
–100 100–20 60 80–60 20–40 40–80 0
OB
SE
RV
AT
ION
RE
CE
IVE
R H
D2,
LE
FT
SID
E (
dB
c)
BASEBAND OFFSET FREQUENCY (MHz)
+110°C, ORx1+110°C, ORx2+110°C, ORx3+110°C, ORx4
+25°C, ORx1+25°C, ORx2+25°C, ORx3+25°C, ORx4
–40°C, ORx1–40°C, ORx2–40°C, ORx3–40°C, ORx4
20043-244
Figure 307. Observation Receiver HD2, Left Side vs. Baseband Offset Frequency, −5 dBFS Input Signal, Distortion Tone Measured Left of 0 Hz
–40
–120
–80
–50
–60
–100
–90
–110
–70
–100 100–20 60 80–60 20–40 40–80 0
BASEBAND OFFSET FREQUENCY (MHz)
+110°C, ORx1+110°C, ORx2+110°C, ORx3+110°C, ORx4
+25°C, ORx1+25°C, ORx2+25°C, ORx3+25°C, ORx4
–40°C, ORx1–40°C, ORx2–40°C, ORx3–40°C, ORx4
OB
SE
RV
AT
ION
RE
CE
IVE
R H
D2,
RIG
HT
SID
E (
dB
c)
20043-245
Figure 308. Observation Receiver HD2, Right Side vs. Baseband Offset Frequency, −5 dBFS Input Signal, Distortion Tone Measured Right of 0 Hz
–40
–120
–80
–50
–60
–100
–90
–110
–70
–60 60–20 20–40 400
OB
SE
RV
AT
ION
RE
CE
IVE
R H
D3,
LE
FT
SID
E (
dB
c)
BASEBAND OFFSET FREQUENCY (MHz)
+110°C, ORx1+110°C, ORx2+110°C, ORx3+110°C, ORx4
+25°C, ORx1+25°C, ORx2+25°C, ORx3+25°C, ORx4
–40°C, ORx1–40°C, ORx2–40°C, ORx3–40°C, ORx4
20043-246
Figure 309. Observation Receiver HD3, Left Side vs. Baseband Offset Frequency, −5 dBFS Input Signal, Distortion Tone Measured Left of 0 Hz
–40
–120
–80
–50
–60
–100
–90
–110
–70
–60 60–20 20–40 400
BASEBAND OFFSET FREQUENCY (MHz)
+110°C, ORx1+110°C, ORx2+110°C, ORx3+110°C, ORx4
+25°C, ORx1+25°C, ORx2+25°C, ORx3+25°C, ORx4
–40°C, ORx1–40°C, ORx2–40°C, ORx3–40°C, ORx4
OB
SE
RV
AT
ION
RE
CE
IVE
R H
D3,
RIG
HT
SID
E (
dB
c)
20043-247
Figure 310. Observation Receiver HD3, Right Side vs. Baseband Offset Frequency, −5 dBFS Input Signal, Distortion Tone Measured Right of 0 Hz
80
40
70
60
65
50
55
45
75
3805 39053825 38653815 388538453835 3875 38953855
OB
SE
RV
AT
ION
RE
CE
IVE
R I
IP2,
f1
+ f
2 (d
Bm
)
TONE 2 FREQUENCY (MHz)
+110°C, ORx1+110°C, ORx2+110°C, ORx3+110°C, ORx4
+25°C, ORx1+25°C, ORx2+25°C, ORx3+25°C, ORx4
–40°C, ORx1–40°C, ORx2–40°C, ORx3–40°C, ORx4
20043-248
Figure 311. Observation Receiver IIP2, f1 + f2 vs. Tone 2 Frequency, Both Tones at −11 dBFS, 0 dB Attenuation, f1 = f2 + 2 MHz
Data Sheet ADRV9010
Rev. E | Page 79 of 115
80
40
70
60
65
50
55
45
75
OB
SE
RV
AT
ION
RE
CE
IVE
R I
IP2,
f1
– f2
(d
Bm
)
+110°C, ORx1+110°C, ORx2+110°C, ORx3+110°C, ORx4
+25°C, ORx1+25°C, ORx2+25°C, ORx3+25°C, ORx4
–40°C, ORx1–40°C, ORx2–40°C, ORx3–40°C, ORx4
3805 40153865 39853835 39253895 3955
TONE 2 FREQUENCY (MHz) 20043-249
Figure 312. Observation Receiver IIP2, f1 − f2 vs. Tone 2 Frequency, Both Tones at −11 dBFS, 0 dB Attenuation, f1 = f2 + 2 MHz
75
40
60
70
55
65
50
45
10 22070 19040 130100 160
OB
SE
RV
AT
ION
RE
CE
IVE
R I
IP2,
f1
+ f
2 (d
Bm
)
TWO-TONE FREQUENCY SPACING (MHz)
+110°C, ORx1+110°C, ORx2+110°C, ORx3+110°C, ORx4
+25°C, ORx1+25°C, ORx2+25°C, ORx3+25°C, ORx4
–40°C, ORx1–40°C, ORx2–40°C, ORx3–40°C, ORx4
20043-250
Figure 313. Observation Receiver IIP2, f1 + f2 vs. Two-Tone Frequency Spacing, Both Tones at −11 dBFS, 0 dB Attenuation, f2 = 2 MHz
75
40
60
70
55
65
50
45
10 22070 19040 130100 160
TWO-TONE FREQUENCY SPACING (MHz)
+110°C, ORx1+110°C, ORx2+110°C, ORx3+110°C, ORx4
+25°C, ORx1+25°C, ORx2+25°C, ORx3+25°C, ORx4
–40°C, ORx1–40°C, ORx2–40°C, ORx3–40°C, ORx4O
BS
ER
VA
TIO
N R
EC
EIV
ER
IIP
2, f
1 –
f2 (
dB
m)
20043-251
Figure 314. Observation Receiver IIP2, f1 − f2 vs. Two-Tone Frequency Spacing, Both Tones at −11 dBFS, 0 dB Attenuation, f2 = 2 MHz
0 30105 2015 25
OB
SE
RV
AT
ION
RE
CE
IVE
R I
IP2,
f1
+ f
2 (d
Bm
)
OBSERVATION RECEIVER ATTENUATION (dB)
+110°C, ORx1+110°C, ORx2+110°C, ORx3+110°C, ORx4
+25°C, ORx1+25°C, ORx2+25°C, ORx3+25°C, ORx4
–40°C, ORx1–40°C, ORx2–40°C, ORx3–40°C, ORx4
90
40
80
60
70
50
20043-252
Figure 315. Observation Receiver IIP2, f1 + f2 vs. Observation Receiver Attenuation, Both Tones at −11 dBFS, f1 = 102 MHz, f2 = 2 MHz
0 30105 2015 25
OB
SE
RV
AT
ION
RE
CE
IVE
R I
IP2,
f1
– f2
(d
Bm
)
OBSERVATION RECEIVER ATTENUATION (dB)
+110°C, ORx1+110°C, ORx2+110°C, ORx3+110°C, ORx4
+25°C, ORx1+25°C, ORx2+25°C, ORx3+25°C, ORx4
–40°C, ORx1–40°C, ORx2–40°C, ORx3–40°C, ORx4
90
40
80
60
70
50
20043-253
Figure 316. Observation Receiver IIP2, f1 − f2 vs. Observation Receiver Attenuation, Both Tones at −11 dBFS, f1 = 102 MHz, f2 = 2 MHz
3805 386538253815 38453835 3855
OB
SE
RV
AT
ION
RE
CE
IVE
R I
IP3,
2f1
+ f
2 (d
Bm
)
TONE 2 FREQUENCY (MHz)
+110°C, ORx1+110°C, ORx2+110°C, ORx3+110°C, ORx4
+25°C, ORx1+25°C, ORx2+25°C, ORx3+25°C, ORx4
–40°C, ORx1–40°C, ORx2–40°C, ORx3–40°C, ORx4
40
0
25
10
15
5
35
20
30
20043-254
Figure 317. Observation Receiver IIP3, 2f1 + f2 vs. Tone 2 Frequency, Both Tones at −11 dBFS, 0 dB Attenuation, f1 = f2 + 2 MHz
ADRV9010 Data Sheet
Rev. E | Page 80 of 115
3805 386538253815 38453835 3855
TONE 2 FREQUENCY (MHz)
+110°C, ORx1+110°C, ORx2+110°C, ORx3+110°C, ORx4
+25°C, ORx1+25°C, ORx2+25°C, ORx3+25°C, ORx4
–40°C, ORx1–40°C, ORx2–40°C, ORx3–40°C, ORx4
40
0
25
10
15
5
35
20
30
OB
SE
RV
AT
ION
RE
CE
IVE
R I
IP3,
2f2
+ f
1 (d
Bm
)
20043-255
Figure 318. Observation Receiver IIP3, 2f2 + f1 vs. Tone 2 Frequency, Both Tones at −11 dBFS, 0 dB Attenuation, f1 = f2 + 2 MHz
3805 401538653835 39253895 39853955
TONE 2 FREQUENCY (MHz)
+110°C, ORx1+110°C, ORx2+110°C, ORx3+110°C, ORx4
+25°C, ORx1+25°C, ORx2+25°C, ORx3+25°C, ORx4
–40°C, ORx1–40°C, ORx2–40°C, ORx3–40°C, ORx4
40
0
25
10
15
5
35
20
30
OB
SE
RV
AT
ION
RE
CE
IVE
R I
IP3,
2f1
– f
2 (d
Bm
)
20043-256
Figure 319. Observation Receiver IIP3, 2f1 − f2 vs. Tone 2 Frequency, Both Tones at −11 dBFS, 0 dB Attenuation, f1 = f2 + 2 MHz
3805 401538653835 39253895 39853955
TONE 2 FREQUENCY (MHz)
+110°C, ORx1+110°C, ORx2+110°C, ORx3+110°C, ORx4
+25°C, ORx1+25°C, ORx2+25°C, ORx3+25°C, ORx4
–40°C, ORx1–40°C, ORx2–40°C, ORx3–40°C, ORx4
40
0
25
10
15
5
35
20
30
OB
SE
RV
AT
ION
RE
CE
IVE
R I
IP3,
2f2
– f
1 (d
Bm
)
20043-257
Figure 320. Observation Receiver IIP3, 2f2 − f1 vs. Tone 2 Frequency, Both Tones at −11 dBFS, 0 dB Attenuation, f1 = f2 + 2 MHz
10 100903020 5040 70 8060
OB
SE
RV
AT
ION
RE
CE
IVE
R I
IP3,
2f1
+ f
2 (d
Bm
)
TWO-TONE FREQUENCY SPACING (MHz)
+110°C, ORx1+110°C, ORx2+110°C, ORx3+110°C, ORx4
+25°C, ORx1+25°C, ORx2+25°C, ORx3+25°C, ORx4
–40°C, ORx1–40°C, ORx2–40°C, ORx3–40°C, ORx4
30
0
25
10
15
5
20
20043-258
Figure 321. Observation Receiver IIP3, 2f1 + f2 vs. Two-Tone Frequency Spacing, Both Tones at −11 dBFS, 0 dB Attenuation, f2 = 2 MHz
OB
SE
RV
AT
ION
RE
CE
IVE
R I
IP3,
2f2
+ f
1 (d
Bm
)
+110°C, ORx1+110°C, ORx2+110°C, ORx3+110°C, ORx4
+25°C, ORx1+25°C, ORx2+25°C, ORx3+25°C, ORx4
–40°C, ORx1–40°C, ORx2–40°C, ORx3–40°C, ORx4
30
0
25
10
15
5
20
10 210170 1905030 9070 130 150110
TWO-TONE FREQUENCY SPACING (MHz) 20043-259
Figure 322. Observation Receiver IIP3, 2f2 + f1 vs. Two-Tone Frequency Spacing, Both Tones at −11 dBFS, 0 dB Attenuation, f2 = 2 MHz
10 1105030 9070
OB
SE
RV
AT
ION
RE
CE
IVE
R I
IP3,
2f1
– f
2 (d
Bm
)
TWO-TONE FREQUENCY SPACING (MHz)
+110°C, ORx1+110°C, ORx2+110°C, ORx3+110°C, ORx4
+25°C, ORx1+25°C, ORx2+25°C, ORx3+25°C, ORx4
–40°C, ORx1–40°C, ORx2–40°C, ORx3–40°C, ORx4
30
0
25
10
15
5
2020043-260
Figure 323. Observation Receiver IIP3, 2f1 − f2 vs. Two-Tone Frequency Spacing, Both Tones at −11 dBFS, 0 dB Attenuation, f2 = 2 MHz
Data Sheet ADRV9010
Rev. E | Page 81 of 115
10 22013070 10040 190160
OB
SE
RV
AT
ION
RE
CE
IVE
R I
IP3,
2f2
– f
1 (d
Bm
)
TWO-TONE FREQUENCY SPACING (MHz)
+110°C, ORx1+110°C, ORx2+110°C, ORx3+110°C, ORx4
+25°C, ORx1+25°C, ORx2+25°C, ORx3+25°C, ORx4
–40°C, ORx1–40°C, ORx2–40°C, ORx3–40°C, ORx4
30
0
25
10
15
5
20
20043-261
Figure 324. Observation Receiver IIP3, 2f2 − f1 vs. Two-Tone Frequency Spacing, Both Tones at −11 dBFS, 0 dB Attenuation, f2 = 2 MHz
0 3025105 2015
OB
SE
RV
AT
ION
RE
CE
IVE
R I
IP3,
2f2
+ f
1 (d
Bm
)
OBSERVATION RECEIVER ATTENUATION (dB)
+110°C, ORx1+110°C, ORx2+110°C, ORx3+110°C, ORx4
+25°C, ORx1+25°C, ORx2+25°C, ORx3+25°C, ORx4
–40°C, ORx1–40°C, ORx2–40°C, ORx3–40°C, ORx4
60
0
50
20
30
10
40
20043-262
Figure 325. Observation Receiver IIP3, 2f2 + f1 vs. Observation Receiver Attenuation, Both Tones at −11 dBFS, f1 = 122 MHz, f2 = 2 MHz
0 3025105 2015
OB
SE
RV
AT
ION
RE
CE
IVE
R I
IP3,
2f2
– f
1 (d
Bm
)
OBSERVATION RECEIVER ATTENUATION (dB)
+110°C, ORx1+110°C, ORx2+110°C, ORx3+110°C, ORx4
+25°C, ORx1+25°C, ORx2+25°C, ORx3+25°C, ORx4
–40°C, ORx1–40°C, ORx2–40°C, ORx3–40°C, ORx4
60
0
50
20
30
10
40
20043-263
Figure 326. Observation Receiver IIP3, 2f2 − f1 vs. Observation Receiver Attenuation, Both Tones at −11 dBFS, f1 = 122 MHz, f2 = 2 MHz
ADRV9010 Data Sheet
Rev. E | Page 82 of 115
4800 MHz BAND The temperature settings refer to the die temperature. All LO frequencies set to 4800 MHz, unless otherwise noted.
3.0
3.5
4.0
4.5
5.0
5.5
6.0
6.5
7.0
4500 4600 4700 4800 4900 5000
TR
AN
SM
ITT
ER
CW
OU
TP
UT
PO
WE
R (
dB
m)
TRANSMITTER LO FREQUENCY (MHz)
–40°C+25°C+110°C
20043-401
Figure 327. Transmitter CW Output Power vs. Transmitter LO Frequency, 10 MHz Offset, 0 dB Attenuation
–100
–90
–80
–70
–60
–50
–40
–30
–20
–10
0
4300 4400 4500 4600 4700 4800 4900 5000 5100 5200 5300
TR
AN
SM
ITT
ER
OU
TP
UT
PO
WE
R S
PE
CT
RU
M (
dB
m)
FREQUENCY (MHz)
SIGNALANALYZER NOISE FLOOR
20043-402
Figure 328. Transmitter Output Power Spectrum, Tx1, 5 MHz LTE, 10 MHz Offset, −10 dBFS RMS, 1 MHz Resolution Bandwidth, T = 25°C
–100 –80 –60 –40 –20 0 20 40 60 80 100
TR
AN
SM
ITT
ER
IM
AG
E R
EJE
CT
ION
(d
Bc)
BASEBAND OFFSET FREQUENCY (MHz)
–40°C, Tx1 +25°C, Tx1 +110°C, Tx1–40°C, Tx2 +25°C, Tx2 +110°C, Tx2–40°C, Tx3 +25°C, Tx3 +110°C, Tx3–40°C, Tx4 +25°C, Tx4 +110°C, Tx4
20043-403
Figure 329. Transmitter Image Rejection vs. Baseband Offset Frequency, 0 dB Attenuation, QEC Tracking Enabled
–180
–170
–160
–150
–140
–130
–120
–110
–100
0 5 10 15 20
TR
AN
SM
ITT
ER
NO
ISE
(d
Bm
/Hz)
TRANSMITTER ATTENUATION (dB)
–40°C, Tx1 +25°C, Tx1 +110°C, Tx1–40°C, Tx2 +25°C, Tx2 +110°C, Tx2–40°C, Tx3 +25°C, Tx3 +110°C, Tx3–40°C, Tx4 +25°C, Tx4 +110°C, Tx4
20043-404
Figure 330. Transmitter Noise vs. Transmitter Attenuation, 50 MHz Offset
–0.2
0
0.2
0.4
0.6
0.8
1.0
–250 –200 –150 –100 –50 0 50 100 150 200 250
TR
AN
SM
ITT
ER
PA
SS
BA
ND
FL
AT
NE
SS
(d
B)
BASEBAND OFFSET FREQUENCY (MHz)
–40°C+25°C+110°C
20043-405
Figure 331. Transmitter Pass Band Flatness vs. Baseband Offset Frequency
–80
–75
–70
–65
–60
–55
–50
–45
–40
0 5 10 15 20
AD
JAC
EN
T C
HA
NN
EL
PO
WE
R L
EV
EL
(d
Bc)
TRANSMITTER ATTENUATION (dB)
–40°C+25°C+110°C
20043-406
Figure 332. Adjacent Channel Power Level vs. Transmitter Attenuation, −10 MHz Baseband Offset, 20 MHz LTE, PAR = 12 dB, Loop Filter Bandwidth =
800 kHz, Loop Filter Phase Margin = 75°
Data Sheet ADRV9010
Rev. E | Page 83 of 115
–80
–75
–70
–65
–60
–55
–50
–45
–40
0 5 10 15 20
AD
JAC
EN
T C
HA
NN
EL
PO
WE
R L
EV
EL
(d
Bc)
TRANSMITTER ATTENUATION (dB)
–40°C+25°C+110°C
20043-407
Figure 333. Adjacent Channel Power Level vs. Transmitter Attenuation, 90 MHz Baseband Offset, 20 MHz LTE, PAR = 12 dB, Loop Filter Bandwidth =
800 kHz, Loop Filter Phase Margin = 75°
–110
–105
–100
–95
–90
–85
–80
–75
–70
–65
–60
0 2 4 6 8 10 12 14 16 18 20
TR
AN
SM
ITT
ER
HD
2 (d
Bc)
TRANSMITTER ATTENUATION (dB)
–40°C, LOWER HD2+25°C, LOWER HD2+110°C, LOWER HD2
–40°C, UPPER HD2+25°C, UPPER HD2+110°C, UPPER HD2
20043-408
Figure 334. Transmitter HD2 vs. Transmitter Attenuation, 10 MHz Offset
–110
–105
–100
–95
–90
–85
–80
–75
–70
–65
–60
0 2 4 6 8 10 12 14 16 18 20
TR
AN
SM
ITT
ER
HD
3 (d
Bc)
TRANSMITTER ATTENUATION (dB)
–40°C, LOWER HD3+25°C, LOWER HD3+110°C, LOWER HD3
–40°C, UPPER HD3+25°C, UPPER HD3+110°C, UPPER HD3
20043-409
Figure 335. Transmitter HD3 vs. Transmitter Attenuation, 10 MHz Offset
–0.05
–0.04
–0.03
–0.02
–0.01
0
0.01
0.02
0.03
0.04
0.05
0 4 8 12 16 20 24 28 32
TR
AN
SM
ITT
ER
AT
TE
NU
AT
OR
ST
EP
ER
RO
R (
dB
)
TRANSMITTER ATTENUATION (dB)
–40°C+25°C+110°C
20043-410
Figure 336. Transmitter Attenuator Step Error vs. Transmitter Attenuation, 10 MHz Offset
0 2 4 6 8 10 12 14 16 18 20
TR
AN
SM
ITT
ER
ER
RO
R V
EC
TO
R M
AG
NIT
UD
E (
dB
)
TRANSMITTER ATTENUATION (dB)
–40°C, Tx1 +25°C, Tx1 +110°C, Tx1–40°C, Tx2 +25°C, Tx2 +110°C, Tx2–40°C, Tx3 +25°C, Tx3 +110°C, Tx3–40°C, Tx4 +25°C, Tx4 +110°C, Tx4
20043-411
Figure 337. Transmitter Error Vector Magnitude vs. Transmitter Attenuation, 20 MHz LTE Signal Centered at LO Frequency, Sample Rate = 491.52 MSPS,
QEC Tracking Enabled, Loop Filter Bandwidth = 800 kHz, Loop Filter Phase Margin = 75°
0 4 8 12 16 20 24 28 32
TR
AN
SM
ITT
ER
OIP
3, 2
f1 –
f2
(dB
m)
TRANSMITTER ATTENUATION (dB)
–40°C, Tx1 +25°C, Tx1 +110°C, Tx1–40°C, Tx2 +25°C, Tx2 +110°C, Tx2–40°C, Tx3 +25°C, Tx3 +110°C, Tx3–40°C, Tx4 +25°C, Tx4 +110°C, Tx4
20043-412
Figure 338. Transmitter OIP3, 2f1 − f2 vs. Transmitter Attenuation, 15 dB Digital Backoff per Tone, f1 = 50.5 MHz, f2 = 55.5 MHz
ADRV9010 Data Sheet
Rev. E | Page 84 of 115
0 4 8 12 16 20 24 28 32
TR
AN
SM
ITT
ER
OIP
3, 2
f2 –
f1
(dB
m)
TRANSMITTER ATTENUATION (dB)
–40°C, Tx1 +25°C, Tx1 +110°C, Tx1–40°C, Tx2 +25°C, Tx2 +110°C, Tx2–40°C, Tx3 +25°C, Tx3 +110°C, Tx3–40°C, Tx4 +25°C, Tx4 +110°C, Tx4
20043-413
Figure 339. Transmitter OIP3, 2f2 − f1 vs. Transmitter Attenuation, 15 dB Digital Backoff per Tone, f1 = 50.5 MHz, f2 = 55.5 MHz
10 30 50 70 90 110 130 150 170 190
TR
AN
SM
ITT
ER
OIP
3, 2
f1 –
f2
(dB
m)
f1 BASEBAND OFFSET TONE FREQUENCY (MHz)
–40°C, Tx1 +25°C, Tx1 +110°C, Tx1–40°C, Tx2 +25°C, Tx2 +110°C, Tx2–40°C, Tx3 +25°C, Tx3 +110°C, Tx3–40°C, Tx4 +25°C, Tx4 +110°C, Tx4
20043-414
Figure 340. Transmitter OIP3, 2f1 − f2 vs. f1 Baseband Offset Tone Frequency, f2 = f1 + 5 MHz, 15 dB Digital Backoff per Tone
10 30 50 70 90 110 130 150 170 190
TR
AN
SM
ITT
ER
OIP
3, 2
f2 –
f1
(dB
m)
f1 BASEBAND OFFSET TONE FREQUENCY (MHz)
–40°C, Tx1 +25°C, Tx1 +110°C, Tx1–40°C, Tx2 +25°C, Tx2 +110°C, Tx2–40°C, Tx3 +25°C, Tx3 +110°C, Tx3–40°C, Tx4 +25°C, Tx4 +110°C, Tx4
20043-415
Figure 341. Transmitter OIP3, 2f2 − f1 vs. f1 Baseband Offset Tone Frequency, f2 = f1 + 5 MHz, 15 dB Digital Backoff per Tone
10 30 50 70 90 110 130 150 170 190
TR
AN
SM
ITT
ER
OIP
3, 2
f1 +
f2
(dB
m)
f1 BASEBAND OFFSET TONE FREQUENCY (MHz)
–40°C, Tx1 +25°C, Tx1 +110°C, Tx1–40°C, Tx2 +25°C, Tx2 +110°C, Tx2–40°C, Tx3 +25°C, Tx3 +110°C, Tx3–40°C, Tx4 +25°C, Tx4 +110°C, Tx4
20043-416
Figure 342. Transmitter OIP3, 2f1 + f2 vs. f1 Baseband Offset Tone Frequency, f2 = f1 + 5 MHz, 15 dB Digital Backoff per Tone
10 30 50 70 90 110 130 150 170 190
TR
AN
SM
ITT
ER
OIP
3, 2
f2 +
f1
(dB
m)
f1 BASEBAND OFFSET TONE FREQUENCY (MHz)
–40°C, Tx1 +25°C, Tx1 +110°C, Tx1–40°C, Tx2 +25°C, Tx2 +110°C, Tx2–40°C, Tx3 +25°C, Tx3 +110°C, Tx3–40°C, Tx4 +25°C, Tx4 +110°C, Tx4
20043-417
Figure 343. Transmitter OIP3, 2f2 + f1 vs. f1 Baseband Offset Tone Frequency, f2 = f1 + 5 MHz, 15 dB Digital Backoff per Tone
4500 4600 4700 4800 4900 5000
TR
AN
SM
ITT
ER
TO
TR
AN
SM
ITT
ER
IS
OLA
TIO
N (
dB
)
TRANSMITTER LO FREQUENCY (MHz)
Tx1 TO Tx2Tx2 TO Tx1Tx3 TO Tx1Tx4 TO Tx1
Tx1 TO Tx3Tx2 TO Tx3Tx3 TO Tx2Tx4 TO Tx2
Tx1 TO Tx4Tx2 TO Tx4Tx3 TO Tx4Tx4 TO Tx3
20043-420
Figure 344. Transmitter to Transmitter Isolation vs. Transmitter LO Frequency
Data Sheet ADRV9010
Rev. E | Page 85 of 115
4500 4600 4700 4800 4900 5000
TR
AN
SM
ITT
ER
TO
RE
CE
IVE
R I
SO
LAT
ION
(d
B)
RECEIVER LO FREQUENCY (MHz)
Tx1 TO Rx1 Tx1 TO Rx2 Tx1 TO Rx3 Tx1 TO Rx4Tx2 TO Rx1 Tx2 TO Rx2 Tx2 TO Rx3 Tx2 TO Rx4Tx3 TO Rx1 Tx3 TO Rx2 Tx3 TO Rx3 Tx3 TO Rx4Tx4 TO Rx1 Tx4 TO Rx2 Tx4 TO Rx3 Tx4 TO Rx4
20043-421
Figure 345. Transmitter to Receiver Isolation vs. Receiver LO Frequency
4500 4600 4700 4800 4900 5000
TR
AN
SM
ITT
ER
TO
OB
SE
RV
AT
ION
RE
CE
IVE
RIS
OL
AT
ION
(d
B)
TRANSMITTER LO FREQUENCY (MHz)
Tx1 TO ORx1Tx2 TO ORx1Tx3 TO ORx1Tx4 TO ORx1
Tx1 TO ORx2Tx2 TO ORx2Tx3 TO ORx2Tx4 TO ORx2
Tx1 TO ORx3Tx2 TO ORx3Tx3 TO ORx3Tx4 TO ORx3
Tx1 TO ORx4Tx2 TO ORx4Tx3 TO ORx4Tx4 TO ORx4
20043-422
Figure 346. Transmitter to Observation Receiver Isolation vs. Transmitter LO Frequency
4500 4600 4700 4800 4900 5000
RE
CE
IVE
RT
O R
EC
EIV
ER
IS
OL
AT
ION
(d
B)
RECEIVER LO FREQUENCY (MHz)
Rx1 TO Rx2Rx2 TO Rx1Rx3 TO Rx1Rx4 TO Rx1
Rx1 TO Rx3Rx2 TO Rx3Rx3 TO Rx2Rx4 TO Rx2
Rx1 TO Rx4Rx2 TO Rx4Rx3 TO Rx4Rx4 TO Rx3
20043-423
Figure 347. Receiver to Receiver Isolation vs. Receiver LO Frequency
0 5 10 15 20 25 30
RE
CE
IVE
R I
NT
EG
RA
TE
D N
OIS
E F
IGU
RE
(d
B)
RECEIVER ATTENUATION (dB)
–40°C, Rx1 +25°C, Rx1 +110°C, Rx1–40°C, Rx2 +25°C, Rx2 +110°C, Rx2–40°C, Rx3 +25°C, Rx3 +110°C, Rx3–40°C, Rx4 +25°C, Rx4 +110°C, Rx4
20043-424
Figure 348. Receiver Integrated Noise Figure vs. Receiver Attenuation, 20 MHz Offset, 200 MHz Bandwidth, Sample Rate = 245.76 MSPS, Integration
Bandwidth = 500 kHz to 100 MHz
0
5
10
15
20
25
–100 –80 –60 –40 –20 0 20 40 60 80 100
RE
CE
IVE
R I
NT
EG
RA
TE
D N
OIS
E F
IGU
RE
(d
B)
BASEBAND OFFSET FREQUENCY (MHz)
–40°C+25°C+110°C
20043-425
Figure 349. Receiver Integrated Noise Figure vs. Baseband Offset Frequency, 200 MHz Bandwidth, Sample Rate = 245.76 MSPS, Integrated in 200 kHz Steps
–100
–90
–80
–70
–60
–50
–40
4500 4600 4700 4800 4900 5000
RE
CE
IVE
R L
O L
EA
KA
GE
(d
Bm
)
RECEIVER LO FREQUENCY (MHz)
–40°C+25°C+110°C
20043-426
Figure 350. Receiver LO Leakage vs. Receiver LO Frequency, Attenuation = 0 dB, Sample Rate = 245.76 MSPS
ADRV9010 Data Sheet
Rev. E | Page 86 of 115
0 5 10 15 20 25 30
RE
CE
IVE
R G
AIN
(d
B)
RECEIVER ATTENUATION (dB)
–40°C, Rx1 +25°C, Rx1 +110°C, Rx1–40°C, Rx2 +25°C, Rx2 +110°C, Rx2–40°C, Rx3 +25°C, Rx3 +110°C, Rx3–40°C, Rx4 +25°C, Rx4 +110°C, Rx4
20043-427
Figure 351. Receiver Gain vs. Receiver Attenuation, 20 MHz Offset, 200 MHz Bandwidth, Sample Rate = 245.76 MSPS
4500 4600 4700 4800 4900 5000
RE
CE
IVE
R G
AIN
(d
B)
RECEIVER LO FREQUENCY (MHz)
–40°C, Rx1 +25°C, Rx1 +110°C, Rx1–40°C, Rx2 +25°C, Rx2 +110°C, Rx2–40°C, Rx3 +25°C, Rx3 +110°C, Rx3–40°C, Rx4 +25°C, Rx4 +110°C, Rx4
20043-428
Figure 352. Receiver Gain vs. Receiver LO Frequency, 10 MHz Offset, 200 MHz Bandwidth, Sample Rate = 245.76 MSPS
0 5 10 15 20 25 30
RE
CE
IVE
R G
AIN
ST
EP
ER
RO
R (
dB
)
RECEIVER ATTENUATION (dB)
–40°C, Rx1 +25°C, Rx1 +110°C, Rx1–40°C, Rx2 +25°C, Rx2 +110°C, Rx2–40°C, Rx3 +25°C, Rx3 +110°C, Rx3–40°C, Rx4 +25°C, Rx4 +110°C, Rx4
20043-429
Figure 353. Receiver Gain Step Error vs. Receiver Attenuation, 20 MHz Offset, −5 dBFS Input Signal
–0.5
–0.4
–0.3
–0.2
–0.1
0
0.1
0.2
0.3
0.4
0.5
–100 –80 –60 –40 –20 0 20 40 60 80 100
NO
RM
AL
IZE
D R
EC
EIV
ER
FL
AT
NE
SS
(d
B)
BASEBAND OFFSET FREQUENCY (MHz)
–40°C+25°C+110°C
20043-430
Figure 354. Normalized Receiver Flatness vs. Baseband Offset Frequency, −5 dBFS Input Signal
–100 –80 –60 –40 –20 0 20 40 60 80 100
RE
CE
IVE
R I
MA
GE
(d
Bc)
BASEBAND OFFSET FREQUENCY (MHz)
–40°C, Rx1 +25°C, Rx1 +110°C, Rx1–40°C, Rx2 +25°C, Rx2 +110°C, Rx2–40°C, Rx3 +25°C, Rx3 +110°C, Rx3–40°C, Rx4 +25°C, Rx4 +110°C, Rx4
20043-431
Figure 355. Receiver Image vs. Baseband Offset Frequency, Tracking Calibration Active, Sample Rate = 245.76 MSPS, −5 dBFS Input Signal
0 5 10 15 20 25 30
RE
CE
IVE
R I
MA
GE
(d
Bc)
RECEIVER ATTENUATION (dB)
–40°C, Rx1 +25°C, Rx1 +110°C, Rx1–40°C, Rx2 +25°C, Rx2 +110°C, Rx2–40°C, Rx3 +25°C, Rx3 +110°C, Rx3–40°C, Rx4 +25°C, Rx4 +110°C, Rx4
20043-432
Figure 356. Receiver Image vs. Receiver Attenuation, 20 MHz Offset, Tracking Calibration Active, Sample Rate = 245.76 MSPS, −5 dBFS Input Signal
Data Sheet ADRV9010
Rev. E | Page 87 of 115
0 5 10 15 20 25 30
RE
CE
IVE
R D
C O
FF
SE
T (
dB
Fs)
RECEIVER ATTENUATION (dB)
–40°C, Rx1 +25°C, Rx1 +110°C, Rx1–40°C, Rx2 +25°C, Rx2 +110°C, Rx2–40°C, Rx3 +25°C, Rx3 +110°C, Rx3–40°C, Rx4 +25°C, Rx4 +110°C, Rx4
20043-433
Figure 357. Receiver DC Offset vs. Receiver Attenuation, 20 MHz Offset, −5 dBFS Input Signal
–60 –40 –20 0 20 40 60
RE
CE
IVE
R H
D2,
LE
FT
SID
E (
dB
c)
BASEBAND OFFSET FREQUENCY (MHz)
–40°C, Rx1 +25°C, Rx1 +110°C, Rx1–40°C, Rx2 +25°C, Rx2 +110°C, Rx2–40°C, Rx3 +25°C, Rx3 +110°C, Rx3–40°C, Rx4 +25°C, Rx4 +110°C, Rx4
20043-434
Figure 358. Receiver HD2, Left Side vs. Baseband Offset Frequency, −5 dBFS Input Signal, Distortion Tone Measured Left of 0 Hz
(HD2 Canceller Not Enabled)
–60 –40 –20 0 20 40 60
RE
CE
IVE
R H
D2,
RIG
HT
SID
E (
dB
c)
BASEBAND OFFSET FREQUENCY (MHz)
–40°C, Rx1 +25°C, Rx1 +110°C, Rx1–40°C, Rx2 +25°C, Rx2 +110°C, Rx2–40°C, Rx3 +25°C, Rx3 +110°C, Rx3–40°C, Rx4 +25°C, Rx4 +110°C, Rx4
20043-435
Figure 359. Receiver HD2, Right Side vs. Baseband Offset Frequency, −5 dBFS Input Signal, Distortion Tone Measured Right of 0 Hz
(HD2 Canceller Not Enabled)
–40 –30 –20 –10 0 10 20 30 40
RE
CE
IVE
R H
D3,
LE
FT
SID
E (
dB
c)
BASEBAND OFFSET FREQUENCY (MHz)
–40°C, Rx1 +25°C, Rx1 +110°C, Rx1–40°C, Rx2 +25°C, Rx2 +110°C, Rx2–40°C, Rx3 +25°C, Rx3 +110°C, Rx3–40°C, Rx4 +25°C, Rx4 +110°C, Rx4
20043-436
Figure 360. Receiver HD3, Left Side vs. Baseband Offset Frequency, −5 dBFS Input Signal, Distortion Tone Measured Left of 0 Hz
–40 –30 –20 –10 0 10 20 30 40
RE
CE
IVE
R H
D3,
RIG
HT
SID
E (
dB
c)
BASEBAND OFFSET FREQUENCY (MHz)
–40°C, Rx1 +25°C, Rx1 +110°C, Rx1–40°C, Rx2 +25°C, Rx2 +110°C, Rx2–40°C, Rx3 +25°C, Rx3 +110°C, Rx3–40°C, Rx4 +25°C, Rx4 +110°C, Rx4
20043-437
Figure 361. Receiver HD3, Right Side vs. Baseband Offset Frequency, −5 dBFS Input Signal, Distortion Tone Measured Right of 0 Hz
4805 4815 4825 4835 4845
RE
CE
IVE
R I
IP2,
f1
+ f
2 (d
Bm
)
TONE 2 FREQUENCY (MHz)
–40°C, Rx1 +25°C, Rx1 +110°C, Rx1–40°C, Rx2 +25°C, Rx2 +110°C, Rx2–40°C, Rx3 +25°C, Rx3 +110°C, Rx3–40°C, Rx4 +25°C, Rx4 +110°C, Rx4
20043-438
Figure 362. Receiver IIP2, f1 + f2 vs. Tone 2 Frequency, Both Tones at −11 dBFS, 0 dB Attenuation, f1 = f2 + 2 MHz
ADRV9010 Data Sheet
Rev. E | Page 88 of 115
4805 4815 4825 4835 4845 4855 4865 4875 4885 4895
RE
CE
IVE
R I
IP2,
f1
– f2
(d
Bm
)
TONE 2 FREQUENCY (MHz)
–40°C, Rx1 +25°C, Rx1 +110°C, Rx1–40°C, Rx2 +25°C, Rx2 +110°C, Rx2–40°C, Rx3 +25°C, Rx3 +110°C, Rx3–40°C, Rx4 +25°C, Rx4 +110°C, Rx4
20043-439
Figure 363. Receiver IIP2, f1 − f2 vs. Tone 2 Frequency, Both Tones at −11 dBFS, 0 dB Attenuation, f1 = f2 + 2 MHz
10 20 30 40 50 60 70 80 90
RE
CE
IVE
R I
IP2,
f1
+ f
2 (d
Bm
)
TWO-TONE FREQUENCY SPACING (MHz)
–40°C, Rx1 +25°C, Rx1 +110°C, Rx1–40°C, Rx2 +25°C, Rx2 +110°C, Rx2–40°C, Rx3 +25°C, Rx3 +110°C, Rx3–40°C, Rx4 +25°C, Rx4 +110°C, Rx4
20043-440
Figure 364. Receiver IIP2, f1 + f2 vs. Two-Tone Frequency Spacing, Both Tones at −11 dBFS, 0 dB Attenuation, f2 = 2 MHz
10 20 30 40 50 60 70 80 90
RE
CE
IVE
R I
IP2,
f1
– f2
(d
Bm
)
TWO-TONE FREQUENCY SPACING (MHz)
–40°C, Rx1 +25°C, Rx1 +110°C, Rx1–40°C, Rx2 +25°C, Rx2 +110°C, Rx2–40°C, Rx3 +25°C, Rx3 +110°C, Rx3–40°C, Rx4 +25°C, Rx4 +110°C, Rx4
20043-441
Figure 365. Receiver IIP2, f1 − f2 vs. Two-Tone Frequency Spacing, Both Tones at −11 dBFS, 0 dB Attenuation, f2 = 2 MHz
0 5 10 15 20 25 30
RE
CE
IVE
R I
IP2,
f1
+ f
2 (d
Bm
)
RECEIVER ATTENUATION (dB)
–40°C, Rx1 +25°C, Rx1 +110°C, Rx1–40°C, Rx2 +25°C, Rx2 +110°C, Rx2–40°C, Rx3 +25°C, Rx3 +110°C, Rx3–40°C, Rx4 +25°C, Rx4 +110°C, Rx4
20043-442
Figure 366. Receiver IIP2, f1 + f2 vs. Receiver Attenuation, Both Tones at −11 dBFS, f1 = 92 MHz, f2 = 2 MHz
0 5 10 15 20 25 30
RE
CE
IVE
R I
IP2,
f1
– f2
(d
Bm
)
RECEIVER ATTENUATION (dB)
–40°C, Rx1 +25°C, Rx1 +110°C, Rx1–40°C, Rx2 +25°C, Rx2 +110°C, Rx2–40°C, Rx3 +25°C, Rx3 +110°C, Rx3–40°C, Rx4 +25°C, Rx4 +110°C, Rx4
20043-443
Figure 367. Receiver IIP2, f1 − f2 vs. Receiver Attenuation, Both Tones at −11 dBFS, f1 = 92 MHz, f2 = 2 MHz
4805 4810 4815 4820 4825
RE
CE
IVE
R I
IP3,
2f1
+ f
2 (d
Bm
)
TONE 2 FREQUENCY (MHz)
–40°C, Rx1 +25°C, Rx1 +110°C, Rx1–40°C, Rx2 +25°C, Rx2 +110°C, Rx2–40°C, Rx3 +25°C, Rx3 +110°C, Rx3–40°C, Rx4 +25°C, Rx4 +110°C, Rx4
20043-444
Figure 368. Receiver IIP3, 2f1 + f2 vs. Tone 2 Frequency, Both Tones at −11 dBFS, 0 dB Attenuation, f1 = f2 + 2 MHz
Data Sheet ADRV9010
Rev. E | Page 89 of 115
4805 4810 4815 4820 4825
RE
CE
IVE
R I
IP3,
2f2
+ f
1 (d
Bm
)
TONE 2 FREQUENCY (MHz)
–40°C, Rx1 +25°C, Rx1 +110°C, Rx1–40°C, Rx2 +25°C, Rx2 +110°C, Rx2–40°C, Rx3 +25°C, Rx3 +110°C, Rx3–40°C, Rx4 +25°C, Rx4 +110°C, Rx4
20043-445
Figure 369. Receiver IIP3, 2f2 + f1 vs. Tone 2 Frequency, Both Tones at −11 dBFS, 0 dB Attenuation, f1 = f2 + 2 MHz
4805 4815 4825 4835 4845 4855 4865 4875 4885 4895
RE
CE
IVE
R I
IP3,
2f1
– f
2 (d
Bm
)
TONE 2 FREQUENCY (MHz)
–40°C, Rx1 +25°C, Rx1 +110°C, Rx1–40°C, Rx2 +25°C, Rx2 +110°C, Rx2–40°C, Rx3 +25°C, Rx3 +110°C, Rx3–40°C, Rx4 +25°C, Rx4 +110°C, Rx4
20043-446
Figure 370. Receiver IIP3, 2f1 − f2 vs. Tone 2 Frequency, Both Tones at −11 dBFS, 0 dB Attenuation, f1 = f2 + 2 MHz
4805 4815 4825 4835 4845 4855 4865 4875 4885 4895
RE
CE
IVE
R I
IP3,
2f2
– f
1 (d
Bm
)
TONE 2 FREQUENCY (MHz)
–40°C, Rx1 +25°C, Rx1 +110°C, Rx1–40°C, Rx2 +25°C, Rx2 +110°C, Rx2–40°C, Rx3 +25°C, Rx3 +110°C, Rx3–40°C, Rx4 +25°C, Rx4 +110°C, Rx4
20043-447
Figure 371. Receiver IIP3, 2f2 − f1 vs. Tone 2 Frequency, Both Tones at −11 dBFS, 0 dB Attenuation, f1 = f2 + 2 MHz
10 15 20 25 30 35 40
RE
CE
IVE
R I
IP3,
2f1
+ f
2 (d
Bm
)
TWO-TONE FREQUENCY SPACING (MHz)
–40°C, Rx1 +25°C, Rx1 +110°C, Rx1–40°C, Rx2 +25°C, Rx2 +110°C, Rx2–40°C, Rx3 +25°C, Rx3 +110°C, Rx3–40°C, Rx4 +25°C, Rx4 +110°C, Rx4
20043-448
Figure 372. Receiver IIP3, 2f1 + f2 vs. Two-Tone Frequency Spacing, Both Tones at −11 dBFS, 0 dB Attenuation, f2 = 2 MHz
10 20 30 40 50 60 70 80 90
RE
CE
IVE
R I
IP3,
2f2
+ f
1 (d
Bm
)
TWO-TONE FREQUENCY SPACING (MHz)
–40°C, Rx1 +25°C, Rx1 +110°C, Rx1–40°C, Rx2 +25°C, Rx2 +110°C, Rx2–40°C, Rx3 +25°C, Rx3 +110°C, Rx3–40°C, Rx4 +25°C, Rx4 +110°C, Rx4
20043-449
Figure 373. Receiver IIP3, 2f2 + f1 vs. Two-Tone Frequency Spacing, Both Tones at −11 dBFS, 0 dB Attenuation, f2 = 2 MHz
10 15 20 25 30 35 40
RE
CE
IVE
R I
IP3,
2f1
– f
2 (d
Bm
)
TWO-TONE FREQUENCY SPACING (MHz)
–40°C, Rx1 +25°C, Rx1 +110°C, Rx1–40°C, Rx2 +25°C, Rx2 +110°C, Rx2–40°C, Rx3 +25°C, Rx3 +110°C, Rx3–40°C, Rx4 +25°C, Rx4 +110°C, Rx4
20043-450
Figure 374. Receiver IIP3, 2f1 − f2 vs. Two-Tone Frequency Spacing, Both Tones at −11 dBFS, 0 dB Attenuation, f2 = 2 MHz
ADRV9010 Data Sheet
Rev. E | Page 90 of 115
10 20 30 40 50 60 70 80 90
RE
CE
IVE
R I
IP3,
2f2
– f
1 (d
Bm
)
TWO-TONE FREQUENCY SPACING (MHz)
–40°C, Rx1 +25°C, Rx1 +110°C, Rx1–40°C, Rx2 +25°C, Rx2 +110°C, Rx2–40°C, Rx3 +25°C, Rx3 +110°C, Rx3–40°C, Rx4 +25°C, Rx4 +110°C, Rx4
20043-451
Figure 375. Receiver IIP3, 2f2 − f1 vs. Two-Tone Frequency Spacing, Both Tones at −11 dBFS, 0 dB Attenuation, f2 = 2 MHz
–60 –55 –50 –45 –40 –35 –30 –25 –20 –15 –10 –5 0 5
RE
CE
IVE
R E
RR
OR
VE
CT
OR
MA
GN
ITU
DE
(d
B)
RECEIVER INPUT POWER (dBm)
–40°C, Rx1 +25°C, Rx1 +110°C, Rx1–40°C, Rx2 +25°C, Rx2 +110°C, Rx2–40°C, Rx3 +25°C, Rx3 +110°C, Rx3–40°C, Rx4 +25°C, Rx4 +110°C, Rx4
20043-452
Figure 376. Receiver Error Vector Magnitude vs. Receiver Input Power, 20 MHz LTE Signal Centered at LO Frequency, Sample Rate = 245.76 MSPS,
Loop Filter Bandwidth = 800 kHz, Loop Filter Phase Margin = 75°
100 1k 10k 100k 1M 10M–150
–140
–130
–120
–110
–100
–90
–80
LO
PH
AS
E N
OIS
E (
dB
c/H
z)
FREQUENCY OFFSET (Hz) 20043-272
Figure 377. LO Phase Noise vs. Frequency Offset, Loop Bandwidth = 75 kHz, Phase Margin = 85°
–150
–140
–130
–120
–110
–100
–90
–80
100 1k 10k 100k 1M 10M
LO
PH
AS
E N
OIS
E (
dB
c/H
z)
FREQUENCY OFFSET (Hz) 20043-273
Figure 378. LO Phase Noise vs. Frequency Offset, Loop Bandwidth = 400 kHz, Phase Margin = 60°
0
5
10
15
20
25
30
35
40
45
50
0 5 10 15 20
OB
SE
RV
AT
ION
RE
CE
IVE
R I
NT
EG
RA
TE
DN
OIS
E F
IGU
RE
(d
B)
OBSERVATION RECEIVER ATTENUATION (dB)
–40°C, ORx1–40°C, ORx2–40°C, ORx3–40°C, ORx4
+25°C, ORx1+25°C, ORx2+25°C, ORx3+25°C, ORx4
+110°C, ORx1+110°C, ORx2+110°C, ORx3+110°C, ORx4
20043-455
Figure 379. Observation Receiver Integrated Noise Figure vs. Observation Receiver Attenuation, 20 MHz Offset, 450 MHz Bandwidth, Sample Rate =
491.52 MSPS, Integration Bandwidth = 500 kHz to 100 MHz
0
5
10
15
20
25
30
35
–250 –150 –50 50 150 250
OB
SE
RV
AT
ION
RE
CE
IVE
R I
NT
EG
RA
TE
DN
OIS
E F
IGU
RE
(d
B)
BASEBAND OFFSET FREQUENCY (MHz)
–40°C+25°C+110°C
20043-456
Figure 380. Observation Receiver Integrated Noise Figure vs. Baseband Offset Frequency, 450 MHz Bandwidth, Sample Rate = 491.52 MSPS,
Integrated in 200 kHz Steps
Data Sheet ADRV9010
Rev. E | Page 91 of 115
–100
–90
–80
–70
–60
–50
–40
4500 4600 4700 4800 4900 5000
OB
SE
RV
AT
ION
RE
CE
IVE
RL
OL
EA
KA
GE
(dB
m)
OBSERVATION RECEIVER LO FREQUENCY (MHz)
–40°C+25°C+110°C
20043-457
Figure 381. Observation Receiver LO Leakage vs. Observation Receiver LO Frequency, 0 dB Attenuation, Sample Rate = 491.52 MSPS
0 5 10 15 20 25 30
OB
SE
RV
AT
ION
RE
CE
IVE
R G
AIN
(d
B)
OBSERVATION RECEIVER ATTENUATION (dB)
–40°C, ORx1–40°C, ORx2–40°C, ORx3–40°C, ORx4
+25°C, ORx1+25°C, ORx2+25°C, ORx3+25°C, ORx4
+110°C, ORx1+110°C, ORx2+110°C, ORx3+110°C, ORx4
20043-458
Figure 382. Observation Receiver Gain vs. Observation Receiver Attenuation, 20 MHz Offset, 450 MHz Bandwidth, Sample Rate = 491.52 MSPS
4500 4600 4700 4800 4900 5000
OB
SE
RV
AT
ION
RE
CE
IVE
R G
AIN
(d
B)
OBSERVATION RECEIVER LO FREQUENCY (MHz)
–40°C, ORx1–40°C, ORx2–40°C, ORx3–40°C, ORx4
+25°C, ORx1+25°C, ORx2+25°C, ORx3+25°C, ORx4
+110°C, ORx1+110°C, ORx2+110°C, ORx3+110°C, ORx4
20043-459
Figure 383. Observation Receiver Gain vs. Observation Receiver LO Frequency, 450 MHz Bandwidth, Sample Rate = 491.52 MSPS
0 5 10 15 20 25 30
OB
SE
RV
AT
ION
RE
CE
IVE
R G
AIN
ST
EP
ER
RO
R (
dB
)
OBSERVATION RECEIVER ATTENUATION (dB)
–40°C, ORx1 +25°C, ORx1 +110°C, ORx1–40°C, ORx2 +25°C, ORx2 +110°C, ORx2–40°C, ORx3 +25°C, ORx3 +110°C, ORx3–40°C, ORx4 +25°C, ORx4 +110°C, ORx4
20043-460
Figure 384. Observation Receiver Gain Step Error vs. Observation Receiver Attenuation, 20 MHz Offset, −5 dBFS Input Signal
BASEBAND OFFSET FREQUENCY (MHz)
NO
RM
AL
IZE
D O
BS
ER
VA
TIO
N R
EC
EIV
ER
FL
AT
NE
SS
(d
B)
–220 220–180 180–140 140–100 100–60 60–20 20
0.5
–0.5
0.4
–0.4
0.3
–0.3
0.2
–0.2
0.1
–0.1
0
–40°C+25°C+110°C
20043-461
Figure 385. Normalized Observation Receiver Flatness vs. Baseband Offset Frequency, −25 dBm Input Signal, 0 dB Attenuation
–225 –175 –125 –75 –25 25 75 125 175 225
OB
SE
RV
AT
ION
RE
CE
IVE
R I
MA
GE
(d
Bc)
BASEBAND OFFSET FREQUENCY (MHz)
–40°C, ORx1–40°C, ORx2–40°C, ORx3–40°C, ORx4
+25°C, ORx1+25°C, ORx2+25°C, ORx3+25°C, ORx4
+110°C, ORx1+110°C, ORx2+110°C, ORx3+110°C, ORx4
20043-462
Figure 386. Observation Receiver Image vs. Baseband Offset Frequency, Tracking Calibration Active, Sample Rate = 491.52 MSPS
ADRV9010 Data Sheet
Rev. E | Page 92 of 115
0 5 10 15 20 25 30
OB
SE
RV
AT
ION
RE
CE
IVE
R I
MA
GE
(d
Bc)
OBSERVATION RECEIVER ATTENUATION (dB)
–40°C, ORx1–40°C, ORx2–40°C, ORx3–40°C, ORx4
+25°C, ORx1+25°C, ORx2+25°C, ORx3+25°C, ORx4
+110°C, ORx1+110°C, ORx2+110°C, ORx3+110°C, ORx4
20043-463
Figure 387. Observation Receiver Image vs. Observation Receiver Attenuation, 20 MHz Offset, Tracking Calibration Active, Sample Rate = 491.52 MSPS
–100 –80 –60 –40 –20 0 20 40 60 80 100
OB
SE
RV
AT
ION
RE
CE
IVE
R H
D2,
LE
FT
SID
E (
dB
c)
BASEBAND OFFSET FREQUENCY (MHz)
–40°C, ORx1–40°C, ORx2–40°C, ORx3–40°C, ORx4
+25°C, ORx1+25°C, ORx2+25°C, ORx3+25°C, ORx4
+110°C, ORx1+110°C, ORx2+110°C, ORx3+110°C, ORx4
20043-465
Figure 388. Observation Receiver HD2, Left Side vs. Baseband Offset Frequency, −5 dBFS Input Signal, Distortion Tone Measured Left of 0 Hz
–100 –80 –60 –40 –20 0 20 40 60 80 100
OB
SE
RV
AT
ION
RE
CE
IVE
R H
D2,
RIG
HT
SID
E (
dB
c)
BASEBAND OFFSET FREQUENCY (MHz)
–40°C, ORx1–40°C, ORx2–40°C, ORx3–40°C, ORx4
+25°C, ORx1+25°C, ORx2+25°C, ORx3+25°C, ORx4
+110°C, ORx1+110°C, ORx2+110°C, ORx3+110°C, ORx4
20043-466
Figure 389. Observation Receiver HD2, Right Side vs. Baseband Offset Frequency, −5 dBFS Input Signal, Distortion Tone Measured Right of 0 Hz
–60 –40 –20 0 20 40 60
OB
SE
RV
AT
ION
RE
CE
IVE
R H
D3,
LE
FT
SID
E (
dB
c)
BASEBAND OFFSET FREQUENCY (MHz)
–40°C, ORx1–40°C, ORx2–40°C, ORx3–40°C, ORx4
+25°C, ORx1+25°C, ORx2+25°C, ORx3+25°C, ORx4
+110°C, ORx1+110°C, ORx2+110°C, ORx3+110°C, ORx4
20043-467
Figure 390. Observation Receiver HD3, Left Side vs. Baseband Offset Frequency, −5 dBFS Input Signal, Distortion Tone Measured Left of 0 Hz
–60 –40 –20 0 20 40 60
OB
SE
RV
AT
ION
RE
CE
IVE
R H
D3,
RIG
HT
SID
E (
dB
c)
BASEBAND OFFSET FREQUENCY (MHz)
–40°C, ORx1–40°C, ORx2–40°C, ORx3–40°C, ORx4
+25°C, ORx1+25°C, ORx2+25°C, ORx3+25°C, ORx4
+110°C, ORx1+110°C, ORx2+110°C, ORx3+110°C, ORx4
20043-468
Figure 391. Observation Receiver HD3, Right Side vs. Baseband Offset Frequency, −5 dBFS Input Signal, Distortion Tone Measured Right of 0 Hz
4805 4815 4825 4835 4845 4855 4865 4875 4885 4895 4905
OB
SE
RV
AT
ION
RE
CE
IVE
R I
IP2,
f1
+ f
2 (d
Bm
)
TONE 2 FREQUENCY(MHz)
–40°C, ORx1–40°C, ORx2–40°C, ORx3–40°C, ORx4
+25°C, ORx1+25°C, ORx2+25°C, ORx3+25°C, ORx4
+110°C, ORx1+110°C, ORx2+110°C, ORx3+110°C, ORx4
20043-469
Figure 392. Observation Receiver IIP2, f1 + f2 vs. Tone 2 Frequency, Both Tones at −11 dBFS, 0 dB Attenuation, f1 = f2 + 2 MHz
Data Sheet ADRV9010
Rev. E | Page 93 of 115
4805 4835 4865 4895 4925 4955 4985 5015
OB
SE
RV
AT
ION
RE
CE
IVE
R I
IP2,
f1
– f2
(d
Bm
)
TONE 2 FREQUENCY (MHz)
–40°C, ORx1–40°C, ORx2–40°C, ORx3–40°C, ORx4
+25°C, ORx1+25°C, ORx2+25°C, ORx3+25°C, ORx4
+110°C, ORx1+110°C, ORx2+110°C, ORx3+110°C, ORx4
20043-470
Figure 393. Observation Receiver IIP2, f1 − f2 vs. Tone 2 Frequency, Both Tones at −11 dBFS, 0 dB Attenuation, f1 = f2 + 2 MHz
10 40 70 100 130 160 190 220
OB
SE
RV
AT
ION
RE
CE
IVE
R I
IP2,
f1
+ f
2 (d
Bm
)
TWO-TONE FREQUENCY SPACING (MHz)
–40°C, ORx1–40°C, ORx2–40°C, ORx3–40°C, ORx4
+25°C, ORx1+25°C, ORx2+25°C, ORx3+25°C, ORx4
+110°C, ORx1+110°C, ORx2+110°C, ORx3+110°C, ORx4
20043-471
Figure 394. Observation Receiver IIP2, f1 + f2 vs. Two-Tone Frequency Spacing, Both Tones at −11 dBFS, 0 dB Attenuation, f2 = 2 MHz
10 40 70 100 130 160 190 220
OB
SE
RV
AT
ION
RE
CE
IVE
R I
IP2,
f1
– f2
(d
Bm
)
TWO-TONE FREQUENCY SPACING (MHz)
–40°C, ORx1–40°C, ORx2–40°C, ORx3–40°C, ORx4
+25°C, ORx1+25°C, ORx2+25°C, ORx3+25°C, ORx4
+110°C, ORx1+110°C, ORx2+110°C, ORx3+110°C, ORx4
20043-472
Figure 395. Observation Receiver IIP2, f1 − f2 vs. Two-Tone Frequency Spacing, Both Tones at −11 dBFS, 0 dB Attenuation, f2 = 2 MHz
0 5 10 15 20 25 30
OB
SE
RV
AT
ION
RE
CE
IVE
R I
IP2,
f1
+ f
2 (d
Bm
)
OBSERVATION RECEIVER ATTENUATION (dB)
–40°C, ORx1–40°C, ORx2–40°C, ORx3–40°C, ORx4
+25°C, ORx1+25°C, ORx2+25°C, ORx3+25°C, ORx4
+110°C, ORx1+110°C, ORx2+110°C, ORx3+110°C, ORx4
20043-473
Figure 396. Observation Receiver IIP2, f1 + f2 vs. Observation Receiver Attenuation, Both Tones at −11 dBFS, f1 = 102 MHz, f2 = 2 MHz
0 5 10 15 20 25 30
OB
SE
RV
AT
ION
RE
CE
IVE
R I
IP2,
f1
– f2
(d
Bm
)
OBSERVATION RECEIVER ATTENUATION (dB)
–40°C, ORx1–40°C, ORx2–40°C, ORx3–40°C, ORx4
+25°C, ORx1+25°C, ORx2+25°C, ORx3+25°C, ORx4
+110°C, ORx1+110°C, ORx2+110°C, ORx3+110°C, ORx4
20043-474
Figure 397. Observation Receiver IIP2, f1 − f2 vs. Observation Receiver Attenuation, Both Tones at −11 dBFS, f1 = 102 MHz, f2 = 2 MHz
4805 4815 4825 4835 4845 4855 4865
OB
SE
RV
AT
ION
RE
CE
IVE
R I
IP3,
2f1
+ f
2 (d
Bm
)
TONE 2 FREQUENCY (MHz)
–40°C, ORx1–40°C, ORx2–40°C, ORx3–40°C, ORx4
+25°C, ORx1+25°C, ORx2+25°C, ORx3+25°C, ORx4
+110°C, ORx1+110°C, ORx2+110°C, ORx3+110°C, ORx4
20043-475
Figure 398. Observation Receiver IIP3, 2f1 + f2 vs. Tone 2 Frequency, Both Tones at −11 dBFS, 0 dB Attenuation, f1 = f2 + 2 MHz
ADRV9010 Data Sheet
Rev. E | Page 94 of 115
4805 4815 4825 4835 4845 4855 4865
OB
SE
RV
AT
ION
RE
CE
IVE
R I
IP3,
2f2
+ f
1 (d
Bm
)
TONE 2 FREQUENCY (MHz)
–40°C, ORx1–40°C, ORx2–40°C, ORx3–40°C, ORx4
+25°C, ORx1+25°C, ORx2+25°C, ORx3+25°C, ORx4
+110°C, ORx1+110°C, ORx2+110°C, ORx3+110°C, ORx4
20043-476
Figure 399. Observation Receiver IIP3, 2f2 + f1 vs. Tone 2 Frequency, Both Tones at −11 dBFS, 0 dB Attenuation, f1 = f2 + 2 MHz
4805 4835 4865 4895 4925 4955 4985 5015
OB
SE
RV
AT
ION
RE
CE
IVE
R I
IP3,
2f1
– f
2 (d
Bm
)
TONE 2 FREQUENCY (MHz)
–40°C, ORx1–40°C, ORx2–40°C, ORx3–40°C, ORx4
+25°C, ORx1+25°C, ORx2+25°C, ORx3+25°C, ORx4
+110°C, ORx1+110°C, ORx2+110°C, ORx3+110°C, ORx4
20043-270
Figure 400. Observation Receiver IIP3, 2f1 − f2 vs. Tone 2 Frequency, Both Tones at −11 dBFS, 0 dB Attenuation, f1 = f2 + 2 MHz
4805 4835 4865 4895 4925 4955 4985 5015
OB
SE
RV
AT
ION
RE
CE
IVE
R I
IP3,
2f2
– f
1 (d
Bm
)
TONE 2 FREQUENCY (MHz)
–40°C, ORx1–40°C, ORx2–40°C, ORx3–40°C, ORx4
+25°C, ORx1+25°C, ORx2+25°C, ORx3+25°C, ORx4
+110°C, ORx1+110°C, ORx2+110°C, ORx3+110°C, ORx4
20043-271
Figure 401. Observation Receiver IIP3, 2f2 − f1 vs. Tone 2 Frequency, Both Tones at −11 dBFS, 0 dB Attenuation, f1 = f2 + 2 MHz
10 20 30 40 50 60 70 80 90 100
OB
SE
RV
AT
ION
RE
CE
IVE
R I
IP3,
2f1
+ f
2 (d
Bm
)
TWO-TONE FREQUENCY SPACING (MHz)
–40°C, ORx1–40°C, ORx2–40°C, ORx3–40°C, ORx4
+25°C, ORx1+25°C, ORx2+25°C, ORx3+25°C, ORx4
+110°C, ORx1+110°C, ORx2+110°C, ORx3+110°C, ORx4
20043-477
Figure 402. Observation Receiver IIP3, 2f1 + f2 vs. Two-Tone Frequency Spacing, Both Tones at −11 dBFS, 0 dB Attenuation, f2 = 2 MHz
10 30 50 70 90 110 130 150 170 190 210
OB
SE
RV
AT
ION
RE
CE
IVE
R I
IP3,
2f2
+ f
1 (d
Bm
)
TWO-TONE FREQUENCY SPACING (MHz)
–40°C, ORx1–40°C, ORx2–40°C, ORx3–40°C, ORx4
+25°C, ORx1+25°C, ORx2+25°C, ORx3+25°C, ORx4
+110°C, ORx1+110°C, ORx2+110°C, ORx3+110°C, ORx4
20043-478
Figure 403. Observation Receiver IIP3, 2f2 + f1 vs. Two-Tone Frequency Spacing, Both Tones at −11 dBFS, 0 dB Attenuation, f2 = 2 MHz
10 30 50 70 90 110
OB
SE
RV
AT
ION
RE
CE
IVE
R I
IP3,
2f1
– f
2 (d
Bm
)
TWO-TONE FREQUENCY SPACING (MHz)
–40°C, ORx1–40°C, ORx2–40°C, ORx3–40°C, ORx4
+25°C, ORx1+25°C, ORx2+25°C, ORx3+25°C, ORx4
+110°C, ORx1+110°C, ORx2+110°C, ORx3+110°C, ORx4
20043-479
Figure 404. Observation Receiver IIP3, 2f1 − f2 vs. Two-Tone Frequency Spacing, Both Tones at −11 dBFS, 0 dB Attenuation, f2 = 2 MHz
Data Sheet ADRV9010
Rev. E | Page 95 of 115
10 40 70 100 130 160 190 220
OB
SE
RV
AT
ION
RE
CE
IVE
R I
IP3,
2f2
– f
1 (d
Bm
)
TWO-TONE FREQUENCY SPACING (MHz)
–40°C, ORx1–40°C, ORx2–40°C, ORx3–40°C, ORx4
+25°C, ORx1+25°C, ORx2+25°C, ORx3+25°C, ORx4
+110°C, ORx1+110°C, ORx2+110°C, ORx3+110°C, ORx4
20043-480
Figure 405. Observation Receiver IIP3, 2f2 − f1 vs. Two-Tone Frequency Spacing, Both Tones at −11 dBFS, 0 dB Attenuation, f2 = 2 MHz
0 5 10 15 20 25 30
OB
SE
RV
AT
ION
RE
CE
IVE
R I
IP3,
2f2
+ f
1 (d
Bm
)
OBSERVATION RECEIVER ATTENUATION (dB)
–40°C, ORx1–40°C, ORx2–40°C, ORx3–40°C, ORx4
+25°C, ORx1+25°C, ORx2+25°C, ORx3+25°C, ORx4
+110°C, ORx1+110°C, ORx2+110°C, ORx3+110°C, ORx4
20043-481
Figure 406. Observation Receiver IIP3, 2f2 + f1 vs. Observation Receiver Attenuation, Both Tones at −11 dBFS, f1 = 122 MHz, f2 = 2 MHz
0 5 10 15 20 25 30
OB
SE
RV
AT
ION
RE
CE
IVE
R I
IP3,
2f2
– f
1 (d
Bm
)
OBSERVATION RECEIVER ATTENUATION (dB)
–40°C, ORx1–40°C, ORx2–40°C, ORx3–40°C, ORx4
+25°C, ORx1+25°C, ORx2+25°C, ORx3+25°C, ORx4
+110°C, ORx1+110°C, ORx2+110°C, ORx3+110°C, ORx4
20043-482
Figure 407. Observation Receiver IIP3, 2f2 − f1 vs. Observation Receiver Attenuation, Both Tones at −11 dBFS, f1 = 122 MHz, f2 = 2 MHz
ADRV9010 Data Sheet
Rev. E | Page 96 of 115
5700 MHz BAND The temperature settings refer to the die temperature. All LO frequencies set to 5700 MHz, unless otherwise noted.
3.0
3.5
4.0
4.5
5.0
5.5
6.0
6.5
7.0
5000 5100 5200 5300 5400 5500 5600 5700 5800 5900
TR
AN
SM
ITT
ER
CW
OU
TP
UT
PO
WE
R (
dB
m)
TRANSMITTER LO FREQUENCY (MHz)
–40°C+25°C+110°C
20043-501
Figure 408. Transmitter CW Output Power vs. Transmitter LO Frequency, 10 MHz Offset, 0 dB Attenuation
–100
–90
–80
–70
–60
–50
–40
–30
–20
–10
0
5200 5300 5400 5500 5600 5700 5800 5900 6000
TR
AN
SM
ITT
ER
OU
TP
UT
PO
WE
R S
PE
CT
RU
M (
dB
m)
FREQUENCY (MHz)
SIGNALANALYZER NOISE FLOOR
20043-502
Figure 409. Transmitter Output Power Spectrum, Tx1, 5 MHz LTE, 10 MHz Offset, −10 dBFS RMS, 1 MHz Resolution Bandwidth, T = 25°C
–100 –80 –60 –40 –20 0 20 40 60 80 100
TR
AN
SM
ITT
ER
IM
AG
E R
EJE
CT
ION
(d
Bc)
BASEBAND OFFSET FREQUENCY (MHz)
–40°C, Tx1 +25°C, Tx1 +110°C, Tx1–40°C, Tx2 +25°C, Tx2 +110°C, Tx2–40°C, Tx3 +25°C, Tx3 +110°C, Tx3–40°C, Tx4 +25°C, Tx4 +110°C, Tx4
20043-503
Figure 410. Transmitter Image Rejection vs. Baseband Offset Frequency, 0 dB Attenuation, QEC Tracking Enabled
0 5 10 15 20
TR
AN
SM
ITT
ER
NO
ISE
(d
Bm
/Hz)
TRANSMITTER ATTENUATION (dB)
–40°C, Tx1 +25°C, Tx1 +110°C, Tx1–40°C, Tx2 +25°C, Tx2 +110°C, Tx2–40°C, Tx3 +25°C, Tx3 +110°C, Tx3–40°C, Tx4 +25°C, Tx4 +110°C, Tx4
20043-504
Figure 411. Transmitter Noise vs. Transmitter Attenuation, 50 MHz Offset Frequency
–250 –200 –150 –100 –50 0 50 100 150 200 250
TR
AN
SM
ITT
ER
PA
SS
BA
ND
FL
AT
NE
SS
(d
B)
BASEBAND OFFSET FREQUENCY (MHz)
–40°C+25°C+110°C
20043-505
Figure 412. Transmitter Pass Band Flatness vs. Baseband Offset Frequency
0 5 10 15 20
AD
JAC
EN
T C
HA
NN
EL
PO
WE
R L
EV
EL
(d
Bc)
TRANSMITTER ATTENUATION (dB)
–40°C+25°C+110°C
20043-506
Figure 413. Adjacent Channel Power Level vs. Transmitter Attenuation, −10 MHz Baseband Offset, 20 MHz LTE, PAR = 12 dB, Loop Filter Bandwidth =
500 kHz, Loop Filter Phase Margin = 60°
Data Sheet ADRV9010
Rev. E | Page 97 of 115
–80
–75
–70
–65
–60
–55
–50
–45
–40
0 5 10 15 20
AD
JAC
EN
T C
HA
NN
EL
PO
WE
R L
EV
EL
(d
Bc)
TRANSMITTER ATTENUATION (dB)
–40°C+25°C+110°C
20043-507
Figure 414. Adjacent Channel Power Level vs. Transmitter Attenuation, 90 MHz Baseband Offset, 20 MHz LTE, PAR = 12 dB, Loop Filter Bandwidth =
500 kHz, Loop Filter Phase Margin = 60°
–110
–105
–100
–95
–90
–85
–80
–75
–70
–65
–60
0 2 4 6 8 10 12 14 16 18 20
TR
AN
SM
ITT
ER
HD
2 (d
Bc)
TRANSMITTER ATTENUATION (dB)
–40°C, LOWER HD2+25°C, LOWER HD2+110°C, LOWER HD2
–40°C, UPPER HD2+25°C, UPPER HD2+110°C, UPPER HD2
20043-508
Figure 415. Transmitter HD2 vs. Transmitter Attenuation, 10 MHz Offset
–110
–105
–100
–95
–90
–85
–80
–75
–70
–65
–60
0 2 4 6 8 10 12 14 16 18 20
TR
AN
SM
ITT
ER
HD
3 (d
Bc)
TRANSMITTER ATTENUATION (dB)
–40°C, LOWER HD3+25°C, LOWER HD3+110°C, LOWER HD3
–40°C, UPPER HD3+25°C, UPPER HD3+110°C, UPPER HD3
20043-509
Figure 416. Transmitter HD3 vs. Transmitter Attenuation, 10 MHz Offset
–0.05
–0.04
–0.03
–0.02
–0.01
0
0.01
0.02
0.03
0.04
0.05
0 4 8 12 16 20 24 28 32
TR
AN
SM
ITT
ER
AT
TE
NU
AT
OR
ST
EP
ER
RO
R (
dB
)
TRANSMITTER ATTENUATION (dB)
–40°C+25°C+110°C
20043-510
Figure 417. Transmitter Attenuator Step Error vs. Transmitter Attenuation, 10 MHz Offset
–40°C, Tx1 +25°C, Tx1 +110°C, Tx1–40°C, Tx2 +25°C, Tx2 +110°C, Tx2–40°C, Tx3 +25°C, Tx3 +110°C, Tx3–40°C, Tx4 +25°C, Tx4 +110°C, Tx4
0 2 4 6 8 10 12 14 16 18 20
TR
AN
SM
ITT
ER
ER
RO
R V
EC
TO
R M
AG
NIT
UD
E (
dB
)
TRANSMITTER ATTENUATION (dB) 20043-511
Figure 418. Transmitter Error Vector Magnitude vs. Transmitter Attenuation, 20 MHz LTE Signal Centered at LO Frequency, Sample Rate = 491.52MSPS, QEC
Tracking Enabled, Loop Filter Bandwidth = 500 kHz, Loop Filter Phase Margin = 60°
0 4 8 12 16 20 24 28 32
TR
AN
SM
ITT
ER
OIP
3, 2
f1 –
f2
(dB
m)
TRANSMITTER ATTENUATION (dB)
–40°C, Tx1 +25°C, Tx1 +110°C, Tx1–40°C, Tx2 +25°C, Tx2 +110°C, Tx2–40°C, Tx3 +25°C, Tx3 +110°C, Tx3–40°C, Tx4 +25°C, Tx4 +110°C, Tx4
20043-512
Figure 419. Transmitter OIP3, 2f1 − f2 vs. Transmitter Attenuation, 15 dB Digital Backoff per Tone, f1 = 50.5 MHz, f2 = 55.5 MHz
ADRV9010 Data Sheet
Rev. E | Page 98 of 115
0 4 8 12 16 20 24 28 32
TR
AN
SM
ITT
ER
OIP
3, 2
f2 –
f1
(dB
m)
TRANSMITTER ATTENUATION (dB)
–40°C, Tx1 +25°C, Tx1 +110°C, Tx1–40°C, Tx2 +25°C, Tx2 +110°C, Tx2–40°C, Tx3 +25°C, Tx3 +110°C, Tx3–40°C, Tx4 +25°C, Tx4 +110°C, Tx4
20043-513
Figure 420. Transmitter OIP3, 2f2 − f1 vs. Transmitter Attenuation, 15 dB Digital Backoff per Tone, f1 = 50.5 MHz, f2 = 55.5 MHz
10 30 50 70 90 110 130 150 170 190
TR
AN
SM
ITT
ER
OIP
3, 2
f1 –
f2
(dB
m)
f1 BASEBAND OFFSET TONE FREQUENCY (MHz)
–40°C, Tx1 +25°C, Tx1 +110°C, Tx1–40°C, Tx2 +25°C, Tx2 +110°C, Tx2–40°C, Tx3 +25°C, Tx3 +110°C, Tx3–40°C, Tx4 +25°C, Tx4 +110°C, Tx4
20043-514
Figure 421. Transmitter OIP3, 2f1 − f2 vs. f1 Baseband Offset Tone Frequency, f2 = f1 + 5 MHz, 15 dB Digital Backoff per Tone
10 30 50 70 90 110 130 150 170 190
TR
AN
SM
ITT
ER
OIP
3, 2
f2 –
f1
(dB
m)
f1 BASEBAND OFFSET TONE FREQUENCY (MHz)
–40°C, Tx1 +25°C, Tx1 +110°C, Tx1–40°C, Tx2 +25°C, Tx2 +110°C, Tx2–40°C, Tx3 +25°C, Tx3 +110°C, Tx3–40°C, Tx4 +25°C, Tx4 +110°C, Tx4
20043-515
Figure 422. Transmitter OIP3, 2f2 − f1 vs. f1 Baseband Offset Tone Frequency, f2 = f1 + 5 MHz, 15 dB Digital Backoff per Tone
10 30 50 70 90 110 130 150 170 190
TR
AN
SM
ITT
ER
OIP
3, 2
f1 +
f2
(dB
m)
f1 BASEBAND OFFSET TONE FREQUENCY (MHz)
–40°C, Tx1 +25°C, Tx1 +110°C, Tx1–40°C, Tx2 +25°C, Tx2 +110°C, Tx2–40°C, Tx3 +25°C, Tx3 +110°C, Tx3–40°C, Tx4 +25°C, Tx4 +110°C, Tx4
20043-516
Figure 423. Transmitter OIP3, 2f1 + f2 vs. f1 Baseband Offset Tone Frequency, f2 = f1 + 5 MHz, 15 dB Digital Backoff per Tone
10 30 50 70 90 110 130 150 170 190
TR
AN
SM
ITT
ER
OIP
3, 2
f2 +
f1
(dB
m)
f1 BASEBAND OFFSET TONE FREQUENCY (MHz)
–40°C, Tx1 +25°C, Tx1 +110°C, Tx1–40°C, Tx2 +25°C, Tx2 +110°C, Tx2–40°C, Tx3 +25°C, Tx3 +110°C, Tx3–40°C, Tx4 +25°C, Tx4 +110°C, Tx4
20043-517
Figure 424. Transmitter OIP3, 2f2 + f1 vs. f1 Baseband Offset Tone Frequency, f2 = f1 + 5 MHz, 15 dB Digital Backoff per Tone
5000 5100 5200 5300 5400 5500 5600 5700 5800 5900 6000
TR
AN
SM
ITT
ER
TO
TR
AN
SM
ITT
ER
IS
OLA
TIO
N (
dB
)
TRANSMITTER LO FREQUENCY (MHz)
Tx1 TO Tx1 Tx1 TO Tx2 Tx1 TO Tx3 Tx1 TO Tx4Tx2 TO Tx1 Tx2 TO Tx2 Tx2 TO Tx3 Tx2 TO Tx4Tx3 TO Tx1 Tx3 TO Tx2 Tx3 TO Tx3 Tx3 TO Tx4Tx4 TO Tx1 Tx4 TO Tx2 Tx4 TO Tx3 Tx4 TO Tx4
20043-518
Figure 425. Transmitter to Transmitter Isolation vs. Transmitter LO Frequency
Data Sheet ADRV9010
Rev. E | Page 99 of 115
5000 5100 5200 5300 5400 5500 5600 5700 5800 5900 6000
TR
AN
SM
ITT
ER
TO
RE
CE
IVE
R I
SO
LA
TIO
N (
dB
)
RECEIVER LO FREQUENCY (MHz)
Tx1 TO Rx1 Tx1 TO Rx2 Tx1 TO Rx3 Tx1 TO Rx4Tx2 TO Rx1 Tx2 TO Rx2 Tx2 TO Rx3 Tx2 TO Rx4Tx3 TO Rx1 Tx3 TO Rx2 Tx3 TO Rx3 Tx3 TO Rx4Tx4 TO Rx1 Tx4 TO Rx2 Tx4 TO Rx3 Tx4 TO Rx4
20043-519
Figure 426. Transmitter to Receiver Isolation vs. Receiver LO Frequency
5000 5100 5200 5300 5400 5500 5600 5700 5800 5900 6000
TR
AN
SM
ITT
ER
TO
OB
SE
RV
AT
ION
RE
CE
IVE
RIS
OL
AT
ION
(d
B)
TRANSMITTER LO FREQUENCY (MHz)
Tx1 TO ORx1Tx2 TO ORx1Tx3 TO ORx1Tx4 TO ORx1
Tx1 TO ORx2Tx2 TO ORx2Tx3 TO ORx2Tx4 TO ORx2
Tx1 TO ORx3Tx2 TO ORx3Tx3 TO ORx3Tx4 TO ORx3
Tx1 TO ORx4Tx2 TO ORx4Tx3 TO ORx4Tx4 TO ORx4
20043-520
Figure 427. Transmitter to Observation Receiver Isolation vs. Transmitter LO Frequency
Rx1 TO Rx2 Rx1 TO Rx3 Rx1 TO Rx4Rx2 TO Rx1 Rx2 TO Rx3 Rx2 TO Rx4Rx3 TO Rx1 Rx3 TO Rx2 Rx3 TO Rx4Rx4 TO Rx1 Rx4 TO Rx2 Rx4 TO Rx3
5000 5100 5200 5300 5400 5500 5600 5700 5800 5900 6000
RE
CE
IVE
RT
O R
EC
EIV
ER
IS
OL
AT
ION
(d
B)
RECEIVER LO FREQUENCY (MHz) 20043-549
Figure 428. Receiver to Receiver Isolation vs. Receiver LO Frequency
0 5 10 15 20 25 30
RE
CE
IVE
R I
NT
EG
RA
TE
D N
OIS
E F
IGU
RE
(d
B)
RECEIVER ATTENUATION (dB)
–40°C, Rx1 +25°C, Rx1 +110°C, Rx1–40°C, Rx2 +25°C, Rx2 +110°C, Rx2–40°C, Rx3 +25°C, Rx3 +110°C, Rx3–40°C, Rx4 +25°C, Rx4 +110°C, Rx4
20043-521
Figure 429. Receiver Integrated Noise Figure vs. Receiver Attenuation, 20 MHz Offset, 200 MHz Bandwidth, Sample Rate = 245.76 MSPS,
Integration Bandwidth = 500 kHz to 100 MHz
0
5
10
15
20
25
–100 –80 –60 –40 –20 0 20 40 60 80 100
RE
CE
IVE
R I
NT
EG
RA
TE
D N
OIS
E F
IGU
RE
(d
B)
BASEBAND OFFSET FREQUENCY (MHz)
–40°C+25°C+110°C
20043-522
Figure 430. Receiver Integrated Noise Figure vs. Baseband Offset Frequency, 200 MHz Bandwidth, Sample Rate = 245.76 MSPS, Integrated in 200 kHz Steps
–100
–90
–80
–70
–60
–50
–40
5000 5100 5200 5300 5400 5500 5600 5700 5800 5900 6000
RE
CE
IVE
R L
O L
EA
KA
GE
(d
Bm
)
RECEIVER LO FREQUENCY (MHz)
–40°C+25°C+110°C
20043-523
Figure 431. Receiver LO Leakage vs. Receiver LO Frequency, Attenuation = 0 dB, Sample Rate = 245.76 MSPS
ADRV9010 Data Sheet
Rev. E | Page 100 of 115
0 5 10 15 20 25 30
RE
CE
IVE
R G
AIN
(d
B)
RECEIVER ATTENUATION (dB)
–40°C, Rx1 +25°C, Rx1 +110°C, Rx1–40°C, Rx2 +25°C, Rx2 +110°C, Rx2–40°C, Rx3 +25°C, Rx3 +110°C, Rx3–40°C, Rx4 +25°C, Rx4 +110°C, Rx4
20043-524
Figure 432. Receiver Gain vs. Receiver Attenuation, 20 MHz Offset, 200 MHz Bandwidth, Sample Rate = 245.76 MSPS
5000 5100 5200 5300 5400 5500 5600 5700 5800 5900 6000
RE
CE
IVE
R G
AIN
(d
B)
RECEIVER LO FREQUENCY (MHz)
–40°C, Rx1–40°C, Rx2–40°C, Rx3–40°C, Rx4
+25°C, Rx1+25°C, Rx2+25°C, Rx3+25°C, Rx4
+110°C, Rx1+110°C, Rx2+110°C, Rx3+110°C, Rx4
20043-583
Figure 433. Receiver Gain vs. Receiver LO Frequency, 10 MHz Offset, 200 MHz Bandwidth, Sample Rate = 245.76 MSPS
0 5 10 15 20 25 30
RE
CE
IVE
R G
AIN
ST
EP
ER
RO
R (
dB
)
RECEIVER ATTENUATION (dB)
–40°C, Rx1 +25°C, Rx1 +110°C, Rx1–40°C, Rx2 +25°C, Rx2 +110°C, Rx2–40°C, Rx3 +25°C, Rx3 +110°C, Rx3–40°C, Rx4 +25°C, Rx4 +110°C, Rx4
20043-525
Figure 434. Receiver Gain Step Error vs. Receiver Attenuation, 20 MHz Offset, −5 dBFS Input Signal
–0.5
–0.4
–0.3
–0.2
–0.1
0.0
0.1
0.2
0.3
0.4
0.5
–100 –80 –60 –40 –20 0 20 40 60 80 100
NO
RM
AL
IZE
D R
EC
EIV
ER
FL
AT
NE
SS
(d
B)
BASEBAND OFFSET FREQUENCY (MHz)
–40°C+25°C+110°C
20043-526
Figure 435. Normalized Receiver Flatness vs. Baseband Offset Frequency, −5 dBFS Input Signal
–100 –80 –60 –40 –20 0 20 40 60 80 100
RE
CE
IVE
R I
MA
GE
(d
Bc)
BASEBAND OFFSET FREQUENCY (MHz)
–40°C, Rx1 +25°C, Rx1 +110°C, Rx1–40°C, Rx2 +25°C, Rx2 +110°C, Rx2–40°C, Rx3 +25°C, Rx3 +110°C, Rx3–40°C, Rx4 +25°C, Rx4 +110°C, Rx4
20043-527
Figure 436. Receiver Image vs. Baseband Offset Frequency, Tracking Calibration Active, Sample Rate = 245.76 MSPS, −5 dBFS Input Signal
0 5 10 15 20 25 30
RE
CE
IVE
R I
MA
GE
(d
Bc)
RECEIVER ATTENUATION (dB)
–40°C, Rx1 +25°C, Rx1 +110°C, Rx1–40°C, Rx2 +25°C, Rx2 +110°C, Rx2–40°C, Rx3 +25°C, Rx3 +110°C, Rx3–40°C, Rx4 +25°C, Rx4 +110°C, Rx4
20043-528
Figure 437. Receiver Image vs. Receiver Attenuation, 20 MHz Offset, Tracking Calibration Active, Sample Rate = 245.76 MSPS, −5 dBFS Input Signal
Data Sheet ADRV9010
Rev. E | Page 101 of 115
0 5 10 15 20 25 30
RE
CE
IVE
R D
C O
FF
SE
T (
dB
Fs)
RECEIVER ATTENUATION (dB)
–40°C, Rx1 +25°C, Rx1 +110°C, Rx1–40°C, Rx2 +25°C, Rx2 +110°C, Rx2–40°C, Rx3 +25°C, Rx3 +110°C, Rx3–40°C, Rx4 +25°C, Rx4 +110°C, Rx4
20043-529
Figure 438. Receiver DC Offset vs. Receiver Attenuation, 20 MHz Offset, −5 dBFS Input Signal
–60 –40 –20 0 20 40 60
RE
CE
IVE
R H
D2,
LE
FT
SID
E (
dB
c)
BASEBAND OFFSET FREQUENCY (MHz)
–40°C, Rx1 +25°C, Rx1 +110°C, Rx1–40°C, Rx2 +25°C, Rx2 +110°C, Rx2–40°C, Rx3 +25°C, Rx3 +110°C, Rx3–40°C, Rx4 +25°C, Rx4 +110°C, Rx4
20043-530
Figure 439. Receiver HD2, Left Side vs. Baseband Offset Frequency, −5 dBFS Input Signal, Distortion Tone Measured Left of 0 Hz
(HD2 Canceller Not Enabled)
–60 –40 –20 0 20 40 60
RE
CE
IVE
R H
D2,
RIG
HT
SID
E (
dB
c)
BASEBAND OFFSET FREQUENCY (MHz)
–40°C, Rx1 +25°C, Rx1 +110°C, Rx1–40°C, Rx2 +25°C, Rx2 +110°C, Rx2–40°C, Rx3 +25°C, Rx3 +110°C, Rx3–40°C, Rx4 +25°C, Rx4 +110°C, Rx4
20043-531
Figure 440. Receiver HD2, Right Side vs. Baseband Offset Frequency, −5 dBFS Input Signal, Distortion Tone Measured Right of 0 Hz
(HD2 Canceller Not Enabled)
–40 –30 –20 –10 0 10 20 30 40
RE
CE
IVE
R H
D3,
LE
FT
SID
E (
dB
c)
BASEBAND OFFSET FREQUENCY (MHz)
–40°C, Rx1 +25°C, Rx1 +110°C, Rx1–40°C, Rx2 +25°C, Rx2 +110°C, Rx2–40°C, Rx3 +25°C, Rx3 +110°C, Rx3–40°C, Rx4 +25°C, Rx4 +110°C, Rx4
20043-532
Figure 441. Receiver HD3, Left Side vs. Baseband Offset Frequency, −5 dBFS Input Signal, Distortion Tone Measured Left of 0 Hz
–40 –30 –20 –10 0 10 20 30 40
RE
CE
IVE
R H
D3,
RIG
HT
SID
E (
dB
c)
BASEBAND OFFSET FREQUENCY (MHz)
–40°C, Rx1 +25°C, Rx1 +110°C, Rx1–40°C, Rx2 +25°C, Rx2 +110°C, Rx2–40°C, Rx3 +25°C, Rx3 +110°C, Rx3–40°C, Rx4 +25°C, Rx4 +110°C, Rx4
20043-533
Figure 442. Receiver HD3, Right Side vs. Baseband Offset Frequency, −5 dBFS Input Signal, Distortion Tone Measured Right of 0 Hz
5705 5715 5725 5735 5745
RE
CE
IVE
R I
IP2,
f1
+ f
2 (d
Bm
)
TONE 2 FREQUENCY (MHz)
–40°C, Rx1–40°C, Rx2–40°C, Rx3–40°C, Rx4
+25°C, Rx1+25°C, Rx2+25°C, Rx3+25°C, Rx4
+110°C, Rx1+110°C, Rx2+110°C, Rx3+110°C, Rx4
20043-552
Figure 443. Receiver IIP2, f1 + f2 vs. Tone 2 Frequency, Both Tones at −11 dBFS, 0 dB Attenuation, f1 = f2 + 2 MHz
ADRV9010 Data Sheet
Rev. E | Page 102 of 115
5705 5715 5725 5735 5745 5755 5765 5775 5785 5795
RE
CE
IVE
R I
IP2,
f1
– f2
(d
Bm
)
TONE 2 FREQUENCY (MHz)
–40°C, Rx1–40°C, Rx2–40°C, Rx3–40°C, Rx4
+25°C, Rx1+25°C, Rx2+25°C, Rx3+25°C, Rx4
+110°C, Rx1+110°C, Rx2+110°C, Rx3+110°C, Rx4
20043-553
Figure 444. Receiver IIP2, f1 − f2 vs. Tone 2 Frequency, Both Tones at −11 dBFS, 0 dB Attenuation, f1 = f2 + 2 MHz
10 20 30 40 50 60 70 80 90
RE
CE
IVE
R I
IP2,
f1
+ f
2 (d
Bm
)
TWO-TONE FREQUENCY SPACING (MHz)
–40°C, Rx1–40°C, Rx2–40°C, Rx3–40°C, Rx4
+25°C, Rx1+25°C, Rx2+25°C, Rx3+25°C, Rx4
+110°C, Rx1+110°C, Rx2+110°C, Rx3+110°C, Rx4
20043-554
Figure 445. Receiver IIP2, f1 + f2 vs. Two-Tone Frequency Spacing, Both Tones at −11 dBFS, 0 dB Attenuation, f2 = 2 MHz
10 20 30 40 50 60 70 80 90
RE
CE
IVE
R I
IP2,
f1
– f2
(d
Bm
)
TWO-TONE FREQUENCY SPACING (MHz)
–40°C, Rx1–40°C, Rx2–40°C, Rx3–40°C, Rx4
+25°C, Rx1+25°C, Rx2+25°C, Rx3+25°C, Rx4
+110°C, Rx1+110°C, Rx2+110°C, Rx3+110°C, Rx4
20043-555
Figure 446. Receiver IIP2, f1 − f2 vs. Two-Tone Frequency Spacing, Both Tones at −11 dBFS, 0 dB Attenuation, f2 = 2 MHz
20043-5560 5 10 15 20 25 30
RE
CE
IVE
R I
IP2,
f1
+ f
2 (d
Bm
)
RECEIVER ATTENUATION (dB)
–40°C, Rx1–40°C, Rx2–40°C, Rx3–40°C, Rx4
+25°C, Rx1+25°C, Rx2+25°C, Rx3+25°C, Rx4
+110°C, Rx1+110°C, Rx2+110°C, Rx3+110°C, Rx4
Figure 447. Receiver IIP2, f1 + f2 vs. Receiver Attenuation, Both Tones at −11 dBFS, f1 = 92 MHz, f2 = 2 MHz
–40°C, Rx1–40°C, Rx2–40°C, Rx3–40°C, Rx4
+25°C, Rx1+25°C, Rx2+25°C, Rx3+25°C, Rx4
+110°C, Rx1+110°C, Rx2+110°C, Rx3+110°C, Rx4
20043-5570 5 10 15 20 25 30
RE
CE
IVE
R I
IP2,
f1
– f2
(d
Bm
)
RECEIVER ATTENUATION (dB)
Figure 448. Receiver IIP2, f1 − f2 vs. Receiver Attenuation, Both Tones at −11 dBFS, f1 = 92 MHz, f2 = 2 MHz
0
5
10
15
20
25
30
35
40
5705 5710 5715 5720 5725
RE
CE
IVE
R I
IP3,
2f1
+ f
2 (d
Bm
)
TONE 2 FREQUENCY (MHz)
–40°C, Rx1–40°C, Rx2–40°C, Rx3–40°C, Rx4
+25°C, Rx1+25°C, Rx2+25°C, Rx3+25°C, Rx4
+110°C, Rx1+110°C, Rx2+110°C, Rx3+110°C, Rx4
20043-558
Figure 449. Receiver IIP3, 2f1 + f2 vs. Tone 2 Frequency, Both Tones at −11 dBFS, 0 dB Attenuation, f1 = f2 + 2 MHz
Data Sheet ADRV9010
Rev. E | Page 103 of 115
5705 5710 5715 5720 5725
RE
CE
IVE
R I
IP3,
2f2
+ f
1 (d
Bm
)
TONE 2 FREQUENCY (MHz)
–40°C, Rx1–40°C, Rx2–40°C, Rx3–40°C, Rx4
+25°C, Rx1+25°C, Rx2+25°C, Rx3+25°C, Rx4
+110°C, Rx1+110°C, Rx2+110°C, Rx3+110°C, Rx4
20043-559
Figure 450. Receiver IIP3, 2f2 + f1 vs. Tone 2 Frequency, Both Tones at −11 dBFS, 0 dB Attenuation, f1 = f2 + 2 MHz
5705 5715 5725 5735 5745 5755 5765 5775 5785
RE
CE
IVE
R I
IP3,
2f1
– f
2 (d
Bm
)
TONE 2 FREQUENCY (MHz)
–40°C, Rx1–40°C, Rx2–40°C, Rx3–40°C, Rx4
+25°C, Rx1+25°C, Rx2+25°C, Rx3+25°C, Rx4
+110°C, Rx1+110°C, Rx2+110°C, Rx3+110°C, Rx4
20043-560
Figure 451. Receiver IIP3, 2f1 − f2 vs. Tone 2 Frequency, Both Tones at −11 dBFS, 0 dB Attenuation, f1 = f2 + 2 MHz
5705 5715 5725 5735 5745 5755 5765 5775 5785 5795
RE
CE
IVE
R I
IP3,
2f2
– f
1 (d
Bm
)
TONE 2 FREQUENCY (MHz)
–40°C, Rx1–40°C, Rx2–40°C, Rx3–40°C, Rx4
+25°C, Rx1+25°C, Rx2+25°C, Rx3+25°C, Rx4
+110°C, Rx1+110°C, Rx2+110°C, Rx3+110°C, Rx4
20043-561
Figure 452. Receiver IIP3, 2f2 − f1 vs. Tone 2 Frequency, Both Tones at −11 dBFS, 0 dB Attenuation, f1 = f2 + 2 MHz
10 15 20 25 30 35 40
RE
CE
IVE
R I
IP3,
2f1
+ f
2 (d
Bm
)
TWO-TONE FREQUENCY SPACING (MHz)
–40°C, Rx1–40°C, Rx2–40°C, Rx3–40°C, Rx4
+25°C, Rx1+25°C, Rx2+25°C, Rx3+25°C, Rx4
+110°C, Rx1+110°C, Rx2+110°C, Rx3+110°C, Rx4
20043-562
Figure 453. Receiver IIP3, 2f1 + f2 vs. Two-Tone Frequency Spacing, Both Tones at −11 dBFS, 0 dB Attenuation, f2 = 2 MHz
10 20 30 40 50 60 70 80 90
RE
CE
IVE
R I
IP3,
2f2
+ f
1 (d
Bm
)
TWO-TONE FREQUENCY SPACING (MHz)
–40°C, Rx1–40°C, Rx2–40°C, Rx3–40°C, Rx4
+25°C, Rx1+25°C, Rx2+25°C, Rx3+25°C, Rx4
+110°C, Rx1+110°C, Rx2+110°C, Rx3+110°C, Rx4
20043-563
Figure 454. Receiver IIP3, 2f2 + f1 vs. Two-Tone Frequency Spacing, Both Tones at −11 dBFS, 0 dB Attenuation, f2 = 2 MHz
10 15 20 25 30 35 40
RE
CE
IVE
R I
IP3,
2f1
– f
2 (d
Bm
)
TWO-TONE FREQUENCY SPACING (MHz)
–40°C, Rx1–40°C, Rx2–40°C, Rx3–40°C, Rx4
+25°C, Rx1+25°C, Rx2+25°C, Rx3+25°C, Rx4
+110°C, Rx1+110°C, Rx2+110°C, Rx3+110°C, Rx4
20043-564
Figure 455. Receiver IIP3, 2f1 − f2 vs. Two-Tone Frequency Spacing, Both Tones at −11 dBFS, 0 dB Attenuation, f2 = 2 MHz
ADRV9010 Data Sheet
Rev. E | Page 104 of 115
10 20 30 40 50 60 70 80 90
RE
CE
IVE
R I
IP3,
2f2
– f
1 (d
Bm
)
TWO-TONE FREQUENCY SPACING (MHz)
–40°C, Rx1–40°C, Rx2–40°C, Rx3–40°C, Rx4
+25°C, Rx1+25°C, Rx2+25°C, Rx3+25°C, Rx4
+110°C, Rx1+110°C, Rx2+110°C, Rx3+110°C, Rx4
20043-565
Figure 456. Receiver IIP3, 2f2 − f1 vs. Two-Tone Frequency Spacing, Both Tones at −11 dBFS, 0 dB Attenuation, f2 = 2 MHz
–60 –55 –50 –45 –40 –35 –30 –25 –20 –15 –10 –5 0 5
RE
CE
IVE
R E
RR
OR
VE
CT
OR
MA
GN
ITU
DE
(d
B)
RECEIVER INPUT POWER (dBm)
–40°C, Rx1 +25°C, Rx1 +110°C, Rx1–40°C, Rx2 +25°C, Rx2 +110°C, Rx2–40°C, Rx3 +25°C, Rx3 +110°C, Rx3–40°C, Rx4 +25°C, Rx4 +110°C, Rx4
20043-534
Figure 457. Receiver Error Vector Magnitude vs. Receiver Input Power, 20 MHz LTE Signal Centered at LO Frequency, Sample Rate = 245.76 MSPS, Loop Filter Bandwidth = 500 kHz, Loop Filter Phase Margin = 60°
–150
–140
–130
–120
–110
–100
–90
–80
100 1k 10k 100k 1M 10M
LO
PH
AS
E N
OIS
E (
dB
c/H
z)
FREQUENCY OFFSET (Hz) 20043-581
Figure 458. LO Phase Noise vs. Frequency Offset, Loop Bandwidth = 75 kHz, Phase Margin = 85°
–150
–140
–130
–120
–110
–100
–90
–80
100 1k 10k 100k 1M 10M
LO
PH
AS
E N
OIS
E (
dB
c/H
z)
FREQUENCY OFFSET (Hz) 20043-582
Figure 459. LO Phase Noise vs. Frequency Offset, Loop Bandwidth = 500 kHz, Phase Margin = 60°
0 5 10 15 20
OB
SE
RV
AT
ION
RE
CE
IVE
R I
NT
EG
RA
TE
DN
OIS
E F
IGU
RE
(d
B)
OBSERVATION RECEIVER ATTENUATION (dB)
–40°C, ORx1–40°C, ORx2–40°C, ORx3–40°C, ORx4
+25°C, ORx1+25°C, ORx2+25°C, ORx3+25°C, ORx4
+110°C, ORx1+110°C, ORx2+110°C, ORx3+110°C, ORx4
20043-566
Figure 460. Observation Receiver Integrated Noise Figure vs. Observation Receiver Attenuation, 20 MHz Offset, 450 MHz Bandwidth, Sample Rate = 491.52 MSPS,
Integration Bandwidth = 500 kHz to 100 MHz
0
5
10
15
20
25
30
35
40
–250 –150 –50 50 150 250
OB
SE
RV
AT
ION
RE
CE
IVE
R I
NT
EG
RA
TE
DN
OIS
E F
IGU
RE
(d
B)
BASEBAND OFFSET FREQUENCY (MHz)
–40°C+25°C+110°C
20043-536
Figure 461. Observation Receiver Integrated Noise Figure vs. Baseband Offset Frequency, 450 MHz Bandwidth, Sample Rate = 491.52 MSPS,
Integrated in 200 kHz Steps
Data Sheet ADRV9010
Rev. E | Page 105 of 115
–100
–90
–80
–70
–60
–50
–40
5000 5100 5200 5300 5400 5500 5600 5700 5800 5900 6000
OB
SE
RV
AT
ION
RE
CE
IVE
R L
O L
EA
KA
GE
(d
Bm
)
OBSERVATION RECEIVER LO FREQUENCY (MHz)
–40°C+25°C+110°C
20043-537
Figure 462. Observation Receiver LO Leakage vs. Observation Receiver LO Frequency, 0 dB Attenuation, Sample Rate = 491.52 MSPS
0 5 10 15 20 25 30
OB
SE
RV
AT
ION
RE
CE
IVE
R G
AIN
(d
B)
OBSERVATION RECEIVER ATTENUATION (dB)
–40°C, ORx1 +25°C, ORx1 +110°C, ORx1–40°C, ORx2 +25°C, ORx2 +110°C, ORx2–40°C, ORx3 +25°C, ORx3 +110°C, ORx3–40°C, ORx4 +25°C, ORx4 +110°C, ORx4
20043-538
Figure 463. Observation Receiver Gain vs. Observation Receiver Attenuation, 20 MHz Offset, 450 MHz Bandwidth, Sample Rate = 491.52 MSPS
5000 5100 5200 5300 5400 5500 5600 5700 5800 5900 6000
OB
SE
RV
AT
ION
RE
CE
IVE
R G
AIN
(d
B)
OBSERVATION RECEIVER LO FREQUENCY (MHz)
–40°C, ORx1–40°C, ORx2–40°C, ORx3–40°C, ORx4
+25°C, ORx1+25°C, ORx2+25°C, ORx3+25°C, ORx4
+110°C, ORx1+110°C, ORx2+110°C, ORx3+110°C, ORx4
20043-584
Figure 464. Observation Receiver Gain vs. Observation Receiver LO Frequency, 450 MHz Bandwidth, Sample Rate = 491.52 MSPS
0 5 10 15 20 25 30
OB
SE
RV
AT
ION
RE
CE
IVE
R G
AIN
ST
EP
ER
RO
R (
dB
)
OBSERVATION RECEIVER ATTENUATION (dB)
–40°C, ORx1 +25°C, ORx1 +110°C, ORx1–40°C, ORx2 +25°C, ORx2 +110°C, ORx2–40°C, ORx3 +25°C, ORx3 +110°C, ORx3–40°C, ORx4 +25°C, ORx4 +110°C, ORx4
20043-539
Figure 465. Observation Receiver Gain Step Error vs. Observation Receiver Attenuation, 20 MHz Offset, −5 dBFS Input Signal
BASEBAND OFFSET FREQUENCY (MHz)
NO
RM
AL
IZE
D O
BS
ER
VA
TIO
N R
EC
EIV
ER
FL
AT
NE
SS
(d
B)
–220 220–180 180–140 140–100 100–60 60–20 20
0.5
–0.5
0.4
–0.4
0.3
–0.3
0.2
–0.2
0.1
–0.1
0
–40°C+25°C+110°C
20043-540
Figure 466. Normalized Observation Receiver Flatness vs. Baseband Offset Frequency, −25 dBm Input Signal, 0 dB Attenuation
–225 –175 –125 –75 –25 25 75 125 175 225
OB
SE
RV
AT
ION
RE
CE
IVE
R I
MA
GE
(d
Bc)
BASEBAND OFFSET FREQUENCY (MHz)
–40°C, ORx1–40°C, ORx2–40°C, ORx3–40°C, ORx4
+25°C, ORx1+25°C, ORx2+25°C, ORx3+25°C, ORx4
+110°C, ORx1+110°C, ORx2+110°C, ORx3+110°C, ORx4
20043-541
Figure 467. Observation Receiver Image vs. Baseband Offset Frequency, Tracking Calibration Active, Sample Rate = 491.52 MSPS
ADRV9010 Data Sheet
Rev. E | Page 106 of 115
0 5 10 15 20 25 30
OB
SE
RV
AT
ION
RE
CE
IVE
R I
MA
GE
(d
Bc)
OBSERVATION RECEIVER ATTENUATION (dB)
–40°C, ORx1–40°C, ORx2–40°C, ORx3–40°C, ORx4
+25°C, ORx1+25°C, ORx2+25°C, ORx3+25°C, ORx4
+110°C, ORx1+110°C, ORx2+110°C, ORx3+110°C, ORx4
20043-542
Figure 468. Observation Receiver Image vs. Observation Receiver Attenuation, 20 MHz Offset, Tracking Calibration Active, Sample Rate = 491.52 MSPS
–100 –80 –60 –40 –20 0 20 40 60 80 100
OB
SE
RV
AT
ION
RE
CE
IVE
R H
D2,
LE
FT
SID
E (
dB
c)
BASEBAND OFFSET FREQUENCY (MHz)
–40°C, ORx1–40°C, ORx2–40°C, ORx3–40°C, ORx4
+25°C, ORx1+25°C, ORx2+25°C, ORx3+25°C, ORx4
+110°C, ORx1+110°C, ORx2+110°C, ORx3+110°C, ORx4
20043-545
Figure 469. Observation Receiver HD2, Left Side vs. Baseband Offset Frequency, −5 dBFS Input Signal, Distortion Tone Measured Left of 0 Hz
–100 –80 –60 –40 –20 0 20 40 60 80 100
OB
SE
RV
AT
ION
RE
CE
IVE
R H
D2,
RIG
HT
SID
E (
dB
c)
BASEBAND OFFSET FREQUENCY (MHz)
–40°C, ORX1–40°C, ORX2–40°C, ORX3–40°C, ORX4
+25°C, ORX1+25°C, ORX2+25°C, ORX3+25°C, ORX4
+110°C, ORX1+110°C, ORX2+110°C, ORX3+110°C, ORX4
20043-546
Figure 470. Observation Receiver HD2, Right Side vs. Baseband Offset Frequency, −5 dBFS Input Signal, Distortion Tone Measured Right of 0 Hz
–60 –40 –20 0 20 40 60
OB
SE
RV
AT
ION
RE
CE
IVE
R H
D3,
LE
FT
SID
E (
dB
c)
BASEBAND OFFSET FREQUENCY (MHz)
–40°C, ORx1–40°C, ORx2–40°C, ORx3–40°C, ORx4
+25°C, ORx1+25°C, ORx2+25°C, ORx3+25°C, ORx4
+110°C, ORx1+110°C, ORx2+110°C, ORx3+110°C, ORx4
20043-547
Figure 471. Observation Receiver HD3, Left Side vs. Baseband Offset Frequency, −5 dBFS Input Signal, Distortion Tone Measured Left of 0 Hz
–60 –40 –20 0 20 40 60
OB
SE
RV
AT
ION
RE
CE
IVE
R H
D3,
RIG
HT
SID
E (
dB
c)
BASEBAND OFFSET FREQUENCY (MHz)
–40°C, ORx1–40°C, ORx2–40°C, ORx3–40°C, ORx4
+25°C, ORx1+25°C, ORx2+25°C, ORx3+25°C, ORx4
+110°C, ORx1+110°C, ORx2+110°C, ORx3+110°C, ORx4
20043-548
Figure 472. Observation Receiver HD3, Right Side vs. Baseband Offset Frequency, −5 dBFS Input Signal, Distortion Tone Measured Right of 0 Hz
5705 5715 5725 5735 5745 5755 5765 5775 5785 5795 5805
OB
SE
RV
AT
ION
RE
CE
IVE
R I
IP2,
f1
+ f
2 (d
Bm
)
TONE 2 FREQUENCY(MHz)
–40°C, ORx1–40°C, ORx2–40°C, ORx3–40°C, ORx4
+25°C, ORx1+25°C, ORx2+25°C, ORx3+25°C, ORx4
+110°C, ORx1+110°C, ORx2+110°C, ORx3+110°C, ORx4
20043-585
Figure 473. Observation Receiver IIP2, f1 + f2 vs. Tone 2 Frequency, Both Tones at −11 dBFS, 0 dB Attenuation, f1 = f2 + 2 MHz
Data Sheet ADRV9010
Rev. E | Page 107 of 115
5705 5735 5765 5795 5825 5855 5885 5915
OB
SE
RV
AT
ION
RE
CE
IVE
R I
IP2,
f1
– f2
(d
Bm
)
TONE 2 FREQUENCY (MHz)
–40°C, ORx1–40°C, ORx2–40°C, ORx3–40°C, ORx4
+25°C, ORx1+25°C, ORx2+25°C, ORx3+25°C, ORx4
+110°C, ORx1+110°C, ORx2+110°C, ORx3+110°C, ORx4
20043-586
Figure 474. Observation Receiver IIP2, f1 − f2 vs. Tone 2 Frequency, Both Tones at −11 dBFS, 0 dB Attenuation, f1 = f2 + 2 MHz
10 40 70 100 130 160 190 220
OB
SE
RV
AT
ION
RE
CE
IVE
R I
IP2,
f1
+ f
2 (d
Bm
)
TWO–TONE FREQUENCY SPACING (MHz)
–40°C, ORx1–40°C, ORx2–40°C, ORx3–40°C, ORx4
+25°C, ORx1+25°C, ORx2+25°C, ORx3+25°C, ORx4
+110°C, ORx1+110°C, ORx2+110°C, ORx3+110°C, ORx4
20043-567
Figure 475. Observation Receiver IIP2, f1 + f2 vs. Two-Tone Frequency Spacing, Both Tones at −11 dBFS, f2 = 2 MHz
10 40 70 100 130 160 190 220
OB
SE
RV
AT
ION
RE
CE
IVE
R I
IP2,
f1
– f2
(d
Bm
)
TWO-TONE FREQUENCY SPACING (MHz)
–40°C, ORx1–40°C, ORx2–40°C, ORx3–40°C, ORx4
+25°C, ORx1+25°C, ORx2+25°C, ORx3+25°C, ORx4
+110°C, ORx1+110°C, ORx2+110°C, ORx3+110°C, ORx4
20043-568
Figure 476. Observation Receiver IIP2, f1 − f2 vs. Two-Tone Frequency Spacing, Both Tones at −11 dBFS, 0 dB Attenuation, f2 = 2 MHz
0 5 10 15 20 25 30
OB
SE
RV
AT
ION
RE
CE
IVE
R I
IP2,
f1
+ f
2 (d
Bm
)
OBSERVATION RECEIVER ATTENUATION (dB)
–40°C, ORx1–40°C, ORx2–40°C, ORx3–40°C, ORx4
+25°C, ORx1+25°C, ORx2+25°C, ORx3+25°C, ORx4
+110°C, ORx1+110°C, ORx2+110°C, ORx3+110°C, ORx4
20043-569
Figure 477. Observation Receiver IIP2, f1 + f2 vs. Observation Receiver Attenuation, Both Tones at −11 dBFS, f1 = 102 MHz, f2 = 2 MHz
0 5 10 15 20 25 30
OB
SE
RV
AT
ION
RE
CE
IVE
R I
IP2,
f1
– f2
(d
Bm
)
OBSERVATION RECEIVER ATTENUATION (dB)
–40°C, ORx1–40°C, ORx2–40°C, ORx3–40°C, ORx4
+25°C, ORx1+25°C, ORx2+25°C, ORx3+25°C, ORx4
+110°C, ORx1+110°C, ORx2+110°C, ORx3+110°C, ORx4
20043-570
Figure 478. Observation Receiver IIP2, f1 − f2 vs. Observation Receiver Attenuation, Both Tones at −11 dBFS, f1 = 102 MHz, f2 = 2 MHz
5705 5715 5725 5735 5745 5755 5765
OB
SE
RV
AT
ION
RE
CE
IVE
R I
IP3,
2f1
+ f
2 (d
Bm
)
TONE 2 FREQUENCY (MHz)
–40°C, ORx1–40°C, ORx2–40°C, ORx3–40°C, ORx4
+25°C, ORx1+25°C, ORx2+25°C, ORx3+25°C, ORx4
+110°C, ORx1+110°C, ORx2+110°C, ORx3+110°C, ORx4
20043-571
Figure 479. Observation Receiver IIP3, 2f1 + f2 vs. Tone 2 Frequency, Both Tones at −11 dBFS, 0 dB Attenuation, f1 = f2 + 2 MHz
ADRV9010 Data Sheet
Rev. E | Page 108 of 115
5705 5715 5725 5735 5745 5755 5765
OB
SE
RV
AT
ION
RE
CE
IVE
R I
IP3,
2f2
+ f
1 (d
Bm
)
TONE 2 FREQUENCY (MHz)
–40°C, ORx1–40°C, ORx2–40°C, ORx3–40°C, ORx4
+25°C, ORx1+25°C, ORx2+25°C, ORx3+25°C, ORx4
+110°C, ORx1+110°C, ORx2+110°C, ORx3+110°C, ORx4
20043-572
Figure 480. Observation Receiver IIP3, 2f2 + f1 vs. Tone 2 Frequency, Both Tones at −11 dBFS, 0 dB Attenuation, f1 = f2 + 2 MHz
5705 5735 5765 5795 5825 5855 5885 5915
OB
SE
RV
AT
ION
RE
CE
IVE
R I
IP3,
2f1
– f
2 (d
Bm
)
TONE 2 FREQUENCY (MHz)
–40°C, ORx1–40°C, ORx2–40°C, ORx3–40°C, ORx4
+25°C, ORx1+25°C, ORx2+25°C, ORx3+25°C, ORx4
+110°C, ORx1+110°C, ORx2+110°C, ORx3+110°C, ORx4
20043-573
Figure 481. Observation Receiver IIP3, 2f1 − f2 vs. Tone 2 Frequency, Both Tones at −11 dBFS, 0 dB Attenuation, f1 = f2 + 2 MHz
5705 5735 5765 5795 5825 5855 5885 5915
OB
SE
RV
AT
ION
RE
CE
IVE
R I
IP3,
2f2
– f
1 (d
Bm
)
TONE 2 FREQUENCY (MHz)
–40°C, ORx1–40°C, ORx2–40°C, ORx3–40°C, ORx4
+25°C, ORx1+25°C, ORx2+25°C, ORx3+25°C, ORx4
+110°C, ORx1+110°C, ORx2+110°C, ORx3+110°C, ORx4
20043-574
Figure 482. Observation Receiver IIP3, 2f2 − f1 vs. Tone 2 Frequency, Both Tones at −11 dBFS, 0 dB Attenuation, f1 = f2 + 2 MHz
10 20 30 40 50 60 70 80 90 100
OB
SE
RV
AT
ION
RE
CE
IVE
R I
IP3,
2f1
+ f
2 (d
Bm
)
TWO-TONE FREQUENCY SPACING (MHz)
–40°C, ORx1–40°C, ORx2–40°C, ORx3–40°C, ORx4
+25°C, ORx1+25°C, ORx2+25°C, ORx3+25°C, ORx4
+110°C, ORx1+110°C, ORx2+110°C, ORx3+110°C, ORx4
20043-575
Figure 483. Observation Receiver IIP3, 2f1 + f2 vs. Two-Tone Frequency Spacing, Both Tones at −11 dBFS, 0 dB Attenuation, f2 = 2 MHz
TWO-TONE FREQUENCY SPACING (MHz)
10 30 50 70 90 110 130 150 170 190 210
OB
SE
RV
AT
ION
RE
CE
IVE
R I
IP3,
2f2
+ f
1 (d
Bm
)
–40°C, ORx1–40°C, ORx2–40°C, ORx3–40°C, ORx4
+25°C, ORx1+25°C, ORx2+25°C, ORx3+25°C, ORx4
+110°C, ORx1+110°C, ORx2+110°C, ORx3+110°C, ORx4
20043-576
Figure 484. Observation Receiver IIP3, 2f2 + f1 vs. Two-Tone Frequency Spacing, Both Tones at −11 dBFS, 0 dB Attenuation, f2 = 2 MHz
10 30 50 70 90 110
OB
SE
RV
AT
ION
RE
CE
IVE
R I
IP3,
2f1
– f
2 (d
Bm
)
TWO-TONE FREQUENCY SPACING (MHz)
–40°C, ORx1–40°C, ORx2–40°C, ORx3–40°C, ORx4
+25°C, ORx1+25°C, ORx2+25°C, ORx3+25°C, ORx4
+110°C, ORx1+110°C, ORx2+110°C, ORx3+110°C, ORx4
20043-577
Figure 485. Observation Receiver IIP3, 2f1 − f2 vs. Two-Tone Frequency Spacing, Both Tones at −11 dBFS, 0 dB Attenuation, f2 = 2 MHz
Data Sheet ADRV9010
Rev. E | Page 109 of 115
10 40 70 100 130 160 190 220
OB
SE
RV
AT
ION
RE
CE
IVE
R I
IP3,
2f2
– f
1 (d
Bm
)
TWO-TONE FREQUENCY SPACING (MHz)
–40°C, ORx1–40°C, ORx2–40°C, ORx3–40°C, ORx4
+25°C, ORx1+25°C, ORx2+25°C, ORx3+25°C, ORx4
+110°C, ORx1+110°C, ORx2+110°C, ORx3+110°C, ORx4
20043-578
Figure 486. Observation Receiver IIP3, 2f2 − f1 vs. Two-Tone Frequency Spacing, Both Tones at −11 dBFS, 0 dB Attenuation, f2 = 2 MHz
0 5 10 15 20 25 30
OB
SE
RV
AT
ION
RE
CE
IVE
R I
IP3,
2f2
+ f
1 (d
Bm
)
OBSERVATION RECEIVER ATTENUATION (dB)
–40°C, ORx1–40°C, ORx2–40°C, ORx3–40°C, ORx4
+25°C, ORx1+25°C, ORx2+25°C, ORx3+25°C, ORx4
+110°C, ORx1+110°C, ORx2+110°C, ORx3+110°C, ORx4
20043-579
Figure 487. Observation Receiver IIP3, 2f2 + f1 vs. Observation Receiver Attenuation, Both Tones at −11 dBFS, f1 = 122 MHz, f2 = 2 MHz
0 5 10 15 20 25 30
OB
SE
RV
AT
ION
RE
CE
IVE
R I
IP3,
2f2
– f
1 (d
Bm
)
OBSERVATION RECEIVER ATTENUATION (dB)
–40°C, ORx1–40°C, ORx2–40°C, ORx3–40°C, ORx4
+25°C, ORx1+25°C, ORx2+25°C, ORx3+25°C, ORx4
+110°C, ORx1+110°C, ORx2+110°C, ORx3+110°C, ORx4
20043-580
Figure 488. Observation Receiver IIP3, 2f2 − f1 vs. Observation Receiver Attenuation, Both Tones at −11 dBFS, f1 = 122 MHz, f2 = 2 MHz
ADRV9010 Data Sheet
Rev. E | Page 110 of 115
THEORY OF OPERATION GENERAL The ADRV9010 is a highly integrated RF transceiver capable of being configured for a wide range of applications. The device integrates all the RF, mixed-signal, and digital blocks necessary to provide all transmitter, traffic receiver, and observation receiver functions in a single device. Programmability allows the device to be adapted for use in various TDD systems using 3G/4G/5G cellular standards.
Four observation receiver channels are included to monitor the transmitter outputs and to provide tracking correction of dc offset, quadrature error, and transmitter LO leakage to maintain a high performance level under varying temperatures and input signal conditions. Firmware supplied with the device implements all initialization and calibration with no user interaction. Additionally, the device includes test modes allowing system designers to debug designs during prototyping and to optimize radio configurations.
The ADRV9010 contains eight high speed serial interface (SERDES) links for the transmit chain and eight high speed links shared by the receiver and observation receiver chains (JESD204B Subclass 1 compliant and JESD204C supported).
TRANSMITTER The ADRV9010 transmitter section consists of four identical and independently controlled channels that provide all the digital processing, mixed-signal, and RF blocks necessary to implement a direct conversion system while sharing a common frequency synthesizer. The digital data from the SERDES lanes pass through a digital processing block that includes a series of programmable half-band filters, interpolation stages, and FIR filters, including a programmable FIR filter with variable interpolation rates and up to 80 taps. The output of this digital chain is connected to the DAC. The DAC sample rate is adjustable up to 2.5 GHz. The in phase (I) and quadrature (Q) channels are identical in each transmitter signal chain.
After conversion to baseband analog signals, the I and Q signals are filtered to remove sampling artifacts and fed to the upconversion mixers. Each transmit chain provides a wide attenuation adjustment range with fine granularity to help designers optimize signal-to-noise ratio (SNR).
RECEIVER The ADRV9010 provides four independent receiver channels. Each channel contains all the blocks necessary to receive RF signals and to convert these signals to digital data usable by a baseband processor. Each receiver can be configured as a direct conversion system that supports up to a 200 MHz bandwidth. Each channel contains a programmable attenuator stage, followed
by matched I and Q mixers that downconvert received signals to baseband for digitization.
Two gain control options are available. Users can implement their own gain control algorithms by using their baseband processor to manage manual gain control mode, or users can use the on-chip automatic gain control (AGC) system. Performance is optimized by mapping each gain control setting to specific attenuation levels at each adjustable gain block in the receive signal path. Additionally, each channel contains independent receive signal strength indication (RSSI) measurement capability, dc offset tracking, and all the circuitry necessary for self-calibration.
The receivers include ADCs and adjustable sample rates that produce data streams from the received signals. The signals can be conditioned further by a series of decimation filters and a programmable FIR filter with additional decimation settings. The sample rate of each digital filter block is adjustable by changing decimation factors to produce the desired output data rate. The receiver outputs are all connected to the SERDES block, where the data is formatted and serialized for transmission to the baseband processor.
OBSERVATION RECEIVER The ADRV9010 provides four independent observation receiver inputs. These inputs are similar in implementation to the standard receiver channels in terms of the mixers, ADCs, and filtering blocks. The main difference is that these receivers are designed to operate with an observation bandwidth up to 450 MHz, allowing the receivers to receive all the transmitter channel information needed for implementing digital correction algorithms.
Each input is used as the feedback monitor channel for a corresponding transmitter channel. Table 11 shows the possible combinations of transmitter and observation channels.
Table 11. Possible Transmitter/Observation Channel Combinations Transmitter Channel Observation Channel TX1± ORX1± or ORX2± TX2± ORX1± or ORX2± TX3± ORX3± or ORX4± TX4± ORX3± or ORX4±
The observation receiver channels can either share a common frequency synthesizer with the transmitters or use the auxiliary synthesizer to offset the LO frequency from the transmitter channel being monitored.
Data Sheet ADRV9010
Rev. E | Page 111 of 115
CLOCK INPUT The ADRV9010 requires a differential clock connected to the DEVCLK± pins. The frequency of the clock input signal must be between 15 MHz and 1000 MHz and must have low phase noise because this signal generates the RF LO and internal sampling clocks.
SYNTHESIZERS The ADRV9010 contains four fractional-N PLLs to generate the RF LO for the signal paths and all internal clock sources. This group of PLLs includes two RF PLLs for the transmit and receive LO generation, an auxiliary PLL that can be used by the observation receivers, and a clock PLL. Each PLL is independently controlled with no need for external components to set frequencies.
RF Synthesizers
The two RF synthesizers use fractional-N PLLs to generate RF LOs for the multiple receiver and transmitter channels. This PLL incorporates a four-core internal VCO and loop filter, capable of generating low phase noise signals with no external components required. An internal LO multiplexer (mux) enables each PLL to supply LOs to any or all receivers and transmitters (for example, LO1 to all transmitters and LO2 to all receivers), resulting in maximum flexibility when configuring the device for TDD operation. The LOs on multiple devices can be phase synchronized to support active antenna systems and beam forming applications.
Auxiliary Synthesizer
The auxiliary synthesizer uses a single core VCO fractional-N PLL to generate the signals necessary to calibrate the device. The output of this block uses a separate mux system to route LOs for calibrating different functions during initialization. The auxiliary synthesizer can also be used to generate LO signals for the observation receivers or as an offset LO used in the receiver signal chains.
Clock Synthesizer
The ADRV9010 contains a single core VCO fractional-N PLL synthesizer that generates all baseband related clock signals and SERDES clocks. This PLL is programmed based on the data rate and sample rate requirements of the system, which typically require the synthesizer to operate in integer mode.
For JESD204B configurations with Np = 12 and JESD204C configurations, a dedicated PLL included in the SERDES block generates the SERDES clocks.
External LO Inputs
The ADRV9010 provides two external LO inputs to allow an external synthesizer to be used with the device. These inputs must be 2× the desired LO frequency. One input is multiplexed with the RF1 PLL, and the other input is multiplexed with the RF2 PLL. Each observation receiver can obtain the LO from either the same input as the associated transmitter channel or the corresponding, dedicated PLL.
SPI INTERFACE The ADRV9010 uses a SPI to communicate with the baseband processor. This interface can either be configured as a 4-wire interface with dedicated receive and transmit ports, or as a 3-wire interface with a bidirectional data communications port. This SPI allows the baseband processor to set all device control parameters using a simple address data serial bus protocol.
Write commands follow a 24-bit format. The first bit sets the bus direction of the bus transfer. The next 15 bits set the address where data is written. The final eight bits are the data being transferred to the specific register address.
Read commands follow a similar format with the exception that the first 16 bits are transferred on the SPI_DIO pin, and the final eight bits are read from the ADRV9010, either on the SPI_DO pin in 4-wire mode or on the SPI_DIO pin in 3-wire mode.
POWER SUPPLY SEQUENCE The ADRV9010 requires a specific power-up sequence to avoid undesired power-up currents. In the optimal power-up sequence, the VDIG_1P0 supply is activated first. If the same supply is used to power the VDDA_1P0 supply, then all 1.0 V supplies can be powered on at the same time.
If the VDIG_1P0 supply is isolated, all VDDA_1P8, VDDA_1P3, and VDDA_1P0 supplies must be powered up after the VDIG_1P0 supply is activated. The VIF supply can be powered up at any time.
It is also recommended to toggle the RESET signal after power has stabilized prior to configuration.
If a power-down sequence is followed, avoid any back biasing of the digital control lines by removing the VDIG_1P0 supply last. If no sequencing is used, it is recommended to power down all supplies simultaneously.
ADRV9010 Data Sheet
Rev. E | Page 112 of 115
GPIO_x PINS The ADRV9010 provides 19 GPIOs referenced to VIF that can be configured for numerous functions. When configured as outputs, certain pins can provide real-time signal information to the baseband processor, allowing the baseband processor to determine receiver performance. A pointer register selects what information is output to these pins.
Signals used for manual gain mode, calibration flags, state machine status, and various receiver parameters are among the outputs that can be monitored on these pins. Additionally, certain pins can be configured as inputs and used for various functions such as setting the receiver gain in real time.
AUXILIARY CONVERTERS GPIO_ANA_x/AUXDAC_x
The ADRV9010 contains eight analog GPIOs (the GPIO_ANA_x pins) that are multiplexed with eight identical auxiliary DACs (AUXDAC_x). The analog GPIO ports can be used to control other analog devices or receive control inputs referenced to the VDDA_1P8 supply. The auxiliary DACs are 12-bit converters capable of supplying up to 10 mA. These outputs are typically used to supply bias current or variable control voltages for other related components with analog control inputs.
AUXADC_x
The ADRV9010 contains two auxiliary ADCs with four total input pins (AUXADC_x). These auxiliary ADCs provide 10-bit monotonic outputs with an input voltage range of 0.05 V to 0.95 V. When enabled, each auxiliary ADC is free running. An application programing interface (API) command latches the ADC output value to a register. The ADRV9010 also contains an ADC that supports a built-in diode-based temperature sensor.
JTAG BOUNDARY SCAN The ADRV9010 provides support for a JTAG boundary scan. There are five dual-function pins associated with the JTAG interface. These pins, listed in Table 12, are used to access the on-chip test access port. To enable the JTAG functionality, set the GPIO_0 through GPIO_2 pins according to Table 13 depending on how the desired JESD204B sync signals are configured in the software (differential or single-ended mode). Pull the TEST_EN pin high to the VIF supply to enable the JTAG mode.
Table 12. Dual-Function Boundary Scan Test Pins Mnemonic JTAG Mnemonic Description GPIO_14 TRST
Test access port reset
GPIO_15 TDO Test data output GPIO_16 TDI Test data input GPIO_17 TMS Test access port mode select GPIO_18 TCK Test clock
Table 13. JTAG Modes Test Pin Level GPIO_2 to GPIO_0 Description 0 xxx1 Normal operation 1 000 JTAG mode with
differential JESD204B sync signals
1 011 JTAG mode with single-ended JESD204B sync signals
1 x means any combination.
Data Sheet ADRV9010
Rev. E | Page 113 of 115
APPLICATIONS INFORMATION POWER SUPPLY SEQUENCE The ADRV9010 requires a specific power-up sequence to avoid undesired power-up currents. In the optimal power-up sequence, the VDIG_1P0 supply is activated first. When VDIG_1P0 powers VDDA_1P0, all 1.0 V supplies can be powered on at the same time.
When VDIG_1P0 is isolated, all VDDA_1P8, VDDA_1P3, and VDDA_1P0 supplies must be powered up after VDIG_1P0 is activated. The VIF supply can be powered up at any time.
It is also recommended prior to configuration to toggle the RESET signal after power has stabilized.
If a power-down sequence is followed, to avoid any back biasing of the digital control lines, remove the VDIG_1P0 supply last. If no sequencing is used, it is recommended to power down all supplies simultaneously.
DATA INTERFACE The digital data interface for the ADRV9010 implements the JEDEC Standard JESD204B Subclass 1 and JESD204C. The serial interface operates at speeds of up to 14.7456 Gbps in JESD204B mode and 16.22016 Gbps in JESD204C mode.
Table 14, Table 15, and Table 16 list example parameters for various JESD204x interface settings.
ADRV9010 Data Sheet
Rev. E | Page 114 of 115
Table 14. Example Receiver Interface Rates with Four Channels Active (M = 8)1
Bandwidth (MHz)
Output Rate (MSPS)
JESD204x Np Parameter
JESD204B F Parameter
JESD204B Lane Rate (Mbps)
JESD204B Number of Lanes
JESD204C F Parameter
JESD204C Lane Rate (Mbps)
JESD204C Number of Lanes
40 61.44 16 16 9830.4 1 16 8110.08 1 60 76.8 16 16 12288 1 16 10137.6 1 100 122.88 16 8 9830.4 2 16 16220.16 1 150 184.32 16 8 14745.6 2 8 12165.12 2 200 245.76 16 4 9830.4 4 8 16220.16 2 200 245.76 12 6 14745.6 2 6 12165.12 2
1 Other output rates, bandwidth, and number of lanes also supported.
Table 15. Transmitter Interface Rates with Four Channels Active (M = 8)1 Primary Signal Bandwidth (MHz)
Total Bandwidth (MHz)
Input Rate (MSPS)
JESD204x Np Parameter
JESD204B F Parameter
JESD204B Lane Rate (Mbps)
JESD204BNumber of Lanes
JESD204C F Parameter
JESD204C Lane Rate (Mbps)
JESD204CNumber of Lanes
50 113 122.88 16 8 9830.4 2 16 16220.16 1 75 150 184.32 16 8 14745.6 2 8 12165.12 2 100 225 245.76 16 4 9830.4 4 4 16220.16 2 150 300 368.64 16 4 14745.6 4 4 12165.12 4 200 450 491.52 16 2 9830.4 8 4 16220.16 4
1 Other output rates, bandwidth, and number of lanes also supported.
Table 16. Observation Path Interface Rates with 1 Channel Active (M = 2)1
Total Bandwidth (MHz)
Output Rate (MSPS)
JESD204x Np Parameter
JESD204B F Parameter
JESD204B Lane Rate (Mbps)
JESD204B Number of Lanes
JESD204C F Parameter
JESD204C Lane Rate (Mbps)
JESD204C Number of Lanes
150 184.32 16 4 7372.8 1 4 6082.56 1 220 245.76 16 4 9830.4 1 4 8110.08 1 250 307.2 16 4 12288 1 4 10137.6 1 300 368.64 16 4 14745.6 1 2 6082.56 2 450 491.52 16 2 9830.4 2 2 8110.08 2 450 491.52 12 3 14745.6 1 3 12165.12 1
1 Other output rates, bandwidth, and number of lanes also supported.
Data Sheet ADRV9010
Rev. E | Page 115 of 115
OUTLINE DIMENSIONS
COMPLIANT TO JEDEC STANDARDS MO-275-JJAB-1 09-
01
-20
20-C
0.80
0.60 REF
BOTTOM VIEW
12.80 REFSQ
DETAIL A
TOP VIEW
DETAIL A
COPLANARITY0.12
0.500.450.40
BALL DIAMETER
14.1014.00 SQ13.90
1.431.341.25
8.704REF
10.78
8.744 REF
10.441.041.000.96
0.390.340.29
PK
G-0
05
41
7
AB
CD
EF
GH
JK
LM
NP
R
151714
1312
1110
98
76
54
32
116
TU
SEATINGPLANE
BALL A1INDICATOR
A1 BALLCORNER
A1 BALLCORNER
Solder MaskDam
0.6750.6000.525
Figure 489. 289-Ball Chip Scale Package Ball Grid Array [CSP_BGA]
(BC-289-3) Dimensions shown in millimeters
ORDERING GUIDE Model1 Temperature Range Package Description Package Option ADRV9010BBCZ −40°C to +110°C 289-Ball Chip Scale Package Ball Grid Array [CSP_BGA] BC-289-3 ADRV9010BBCZ-REEL −40°C to +110°C 289-Ball Chip Scale Package Ball Grid Array [CSP_BGA] BC-289-3 ADRV9010BBCZ-A −40°C to +110°C 289-Ball Chip Scale Package Ball Grid Array [CSP_BGA] BC-289-3 ADRV9010BBCZ-A-RL −40°C to +110°C 289-Ball Chip Scale Package Ball Grid Array [CSP_BGA] BC-289-3 ADRV9026-HB/PCBZ High Band Evaluation Board for 2.8 GHz to 6 GHz ADRV9026-MB/PCBZ Mid Band Evaluation Board for 650 MHz to 2.8 GHz 1 Z = RoHS Compliant Part.
©2019–2021 Analog Devices, Inc. All rights reserved. Trademarks and registered trademarks are the property of their respective owners. D20043-1/21(E)