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Keysight Press Conference – May 24, 2016
www.Keysight.com/find/IMSpress
Page
Agenda
IMS2016 Press Conference 2
• Keysight Highlights at IMS2016 • Luciana Taylor, Market Segment Manager, Communications Solutions
Group
• Keysight, Georgia Tech Plan to Launch Keysight Software
Development Center• Todd Cutler, Vice President & General Manager, Software Products
Organization, EEsof EDA
• Keysight, Cascade Microtech: 25 Years Solving Customers’
Semiconductor R&D Challenges• Gregg Peters, Vice President & General Manager,
Aerospace/Defense/Government Solutions
• Rob Selley, Cascade Microtech, Vice President, Global Sales and Service
• Technology Waves in Communications • Mark Pierpoint, Vice President & General Manager, Internet Infrastructure
Solutions Group
Page
Boot Camp and Books
IMS2016 Press Conference 3
Page
MicroApps, Keynote, and Panel
IMS2016 Press Conference 4
Page
18 Keysight Community Partners
IMS2016 Press Conference 5
Page
5G, IoT, NewSpace, Aerospace & Defense
IMS2016 Press Conference 6
Latest design and test solutions for systems and components
Design & Simulation
5G & mmWave
Component TestSat, Radar, EW
IoT, WLAN, 4G
Handhelds, Power,
& Univ Program
Services
Page
Workshops and Technical Sessions
IMS2016 Press Conference 7
Page
Additional Activities
IMS2016 Press Conference 8
Page
Agenda
IMS2016 Press Conference 9
• Keysight Highlights at IMS2016 • Luciana Taylor, Market Segment Manager, Communications Solutions
Group
• Keysight, Georgia Tech Plan to Launch Keysight Software
Development Center• Todd Cutler, Vice President & General Manager, Software Products
Organization, EEsof EDA
• Keysight, Cascade Microtech: 25 Years Solving Customers’
Semiconductor R&D Challenges• Gregg Peters, Vice President & General Manager,
Aerospace/Defense/Government Solutions
• Rob Selley, Cascade Microtech, Vice President, Global Sales and Service
• Technology Waves in Communications • Mark Pierpoint, Vice President & General Manager, Internet Infrastructure
Solutions Group
Page
Keysight, Georgia Tech: Software Development Center
IMS2016 Press Conference
Keysight Corporate Strategy:
Transform Keysight from a hardware-centric products company
to a software-centric solutions company
10
Page
Keysight Charters Software Development Center
– Combines talent from a top 10 engineering program with resources of the
leading electronic design and test company
– Located in Atlanta’s Midtown Tech Square, a growing center of innovation
and technology talent adjacent to Georgia Tech
– Planning a staff of more than 200 software developers over next five years
– Will feature an open environment that fosters collaboration; supports an
agile software development approach
– Focused on developing next-generation software for use in design and test
of electronic products created by Keysight’s global customers
IMS2016 Press Conference 11
Partnership with Georgia Tech to focus on next-generation software design
Page
Agenda
IMS2016 Press Conference 12
• Keysight Highlights at IMS2016 • Luciana Taylor, Market Segment Manager, Communications Solutions
Group
• Keysight, Georgia Tech Plan to Launch Keysight Software
Development Center• Todd Cutler, Vice President & General Manager, Software Products
Organization, EEsof EDA
• Keysight, Cascade Microtech: 25 Years Solving Customers’
Semiconductor R&D Challenges• Gregg Peters, Vice President & General Manager,
Aerospace/Defense/Government Solutions
• Rob Selley, Cascade Microtech, Vice President, Global Sales and Service
• Technology Waves in Communications • Mark Pierpoint, Vice President & General Manager, Internet Infrastructure
Solutions Group
Page
Keysight & Cascade Microtech Celebrate 25 Years of Solving Customers’ Semiconductor R&D Challenges
IMS2016 Press Conference 13
Innovations Help Customers Meet & Exceed Their Time to Market Goals
Page
25 Years of Solving Semiconductor R&D Challenges
IMS2016 Press Conference 14
Keysight, Cascade Microtech Customer Solution Highlights
1991
HP/Keysight 4155
semiconductor analyzer spurred
Cascade Microtech
MicroChamber® technology
1999
8510XF network analyzer
systems
2015
Turn-key wafer-level
measurement solution
Page
25 Years of Solving Semiconductor R&D Challenges
IMS2016 Press Conference 15
Turn-key Wafer-level Measurement Solution (WMS)
• Offered by Keysight Technologies and Cascade Microtech
• Package includes all the required hardware, software, interface
cables, probes, calibration, software for a given device application
• Customers receive single point of contact for all technical support
requirements
• With guaranteed system configuration, installation and support,
WMS:
• Provides fast, accurate, and repeatable testing
• Minimizes time to first measurement
• Ensures date correlation between multiple locations
• Reduces customer risk
A WMS Package for component
modeling and characterization.
Page
Agenda
IMS2016 Press Conference 16
• Keysight Highlights at IMS2016 • Luciana Taylor, Market Segment Manager, Communications Solutions
Group
• Keysight, Georgia Tech Plan to Launch Keysight Software
Development Center• Todd Cutler, Vice President & General Manager, Software Products
Organization, EEsof EDA
• Keysight, Cascade Microtech: 25 Years Solving Customers’
Semiconductor R&D Challenges• Gregg Peters, Vice President & General Manager,
Aerospace/Defense/Government Solutions
• Rob Selley, Cascade Microtech, Vice President, Global Sales and Service
• Technology Waves in Communications • Mark Pierpoint, Vice President & General Manager, Internet Infrastructure
Solutions Group
Mark PierpointVice President & General Manager
Internet Infrastructure
Keysight Technologies, Inc.
Thro
ugh
put(
%)
EbNo(dB)
OFDM
GFDM
Technology Waves in Communications - or -
From IoT to IoS and between
Page
• Keysight is a brand new company with over 75
years of electronic design and test success
under our belts.
• Founded in 1939 by Bill Hewlett and Dave
Packard as HP, our expertise continued as
Agilent’s Electronic Measurement Group.
• Today, we are 100% focused on helping
companies tackle the toughest electronic
design and test issues through trusted
hardware, innovative software and our global
network of industry experts.
Our Role is to Help You Get to Market FasterThe experience to help you create. Innovate. And deliver what’s next
+
IMS2016 Press Conference 18
Page
Bimodal Distributions in the Real World
IMS2016 Press Conference
Flexibility vs Optimization
Bimodal Distribution:
• Systems analysis
• Likert scale ratings
• Color of galaxies
• Economics
19
Page
A World of Extremes
IMS2016 Press Conference
SigFox 5G Pre-Standardization
902/868MHz <6, ~28, 31-33, 37-42GHz +
BPSK/FSK OFDM+
≤1% duty cycle 800MHz (8 CA)
12 bytes/msg (96 bits) ≥10 Gbps
≤140 msgs/day Continuous
~20 yr AA life minutes?
20
Page
From Less to More
IMS2016 Press Conference
Less is more:
Lower frequency
Lower bandwidth
Lower data rate
Lower power
Lower price
More is more:
Higher frequency
Higher bandwidth
Higher channel count
Higher availability
But…
Many, many more devices
21
Page
To a Galaxy of Extremes
IMS2016 Press Conference 22
Page
IoT
IMS2016 Press Conference 23
Page
Complete Simulation & Characterization for IoT
IMS2016 Press Conference
CX3300
Power Dissipation
and Current Density
visualization
24
Page
802.11ac evolution to 11ax
IMS2016 Press Conference
Simulate. Generate. Analyze.
Feature Description Test Challenges
Bands 2.4GHz and 5GHz Dual band
Channel bandwidth 20 MHz, 40 MHz, 80 MHz, 160
MHz, 80+80 MHz
Need to generate and analyze wide BW signals
FFT size 256, 512, 1024, 2048 Smaller sub-carrier space(78.125KHz). More sensitive to frequency
and phase error and CFO impact.
Modulation types Up to 1024QAM Need better EVM and better power amplifier linearity
Spatial streams Max 8 More channels of signal generation and analysis, up to 8x8, and
MIMO channel simulator needed.
Multi-user OFDMA + MU-MIMO Test simultaneous transmission and receiving for multiple users and
signal from each user would experience different impairments.
25
Page
Everything to Everyone?
IMS2016 Press Conference
5G = A Complex Compound System
4G3G
5G
Traffic capacity
Reliability
Spectrum and
bandwidth
flexibility
Achievable
user data-
rates [Mbps]
Mobility
and
coverage
Massive number
of devices [B]
Latency
[ms]
Network
and device
energy
efficiency
Ultra-high
Ultra-
high
Ultra-high
Massive
Source for Spider Diagram: ITU: 5D/TEMP/390-E
26
Page
mmWave Channel Model and RAT
IMS2016 Press Conference
“5G Will Roll out Faster!”2014 2015 2016 2017 2018 2019 2020 2021 2022
Rel. 14 Rel. 15 Rel. 16 Rel. 17 & beyond
Research Standards development Products Commercial deployment
Pre-standard research
(vision, technology, spectrum)
Technical reqs and
evaluation methodology
Proposal
submission
Evaluation and
specification
WRC-15 WRC-19
SI: Channel
Model
SI: Scenarios and
Requirements
SI: 5G new RAT
WI: 5G new RAT
(Phase 1)
WI: 5G new RAT
(Phase 2)
WI: LTE Evolution
Yo
u A
re H
ere
27
Page
5G mmW Frequency Bands Recommended for Study
IMS2016 Press Conference
Frequency Ofcom
(Apr 2015)
FCC
(Oct 2015)
ITU
(Oct 2015)
28GHz (25-27GHz) 24.25-27.5GHz
37GHz 37-40.5GHz
39GHz
40.5-43.5GHz 42.5-43.5GHz
45.5-48.9GHz 45.5-47GHz
47.2-50.2GHz
50.4-52.6GHz
57-66GHz Unlicensed Unlicensed Unlicensed
64-71GHz 66-71GHz 66-76GHz
71-76GHz
81-86GHz
28
Page
Challenges to Progress in 5G
IMS2016 Press Conference
Simulate. Measure. ImplementEnabling Technology Challenges
Centimeter-wave and millimeter-
wave frequency bands
• Wide channel bandwidth (A-D/D-A, flatness, etc.)
• Complete and accurate channel models
• Directional and active antenna schemes (code-books, calibration)
• Radiated testing – no test connections
• Amplifier Efficiency & Link Budgets
Higher-order MIMO (FD, Massive) • Channel and UL/DL reciprocity (including active antennas)
• Digital vs. RF power consumption
• PHY and MAC design (MAC meets antenna)
• Amplifier and antenna design
• Beamforming schemes (Digital/Analog/Hybrid)
New radio access technologies
(RATs)
• New PHY waveforms, Frame Structure & Numerology
• Support for multi-RAT: Compatibility, co-existence
• Performance testing with existing 3G/4G standards
• In-channel and out-of-channel performance
• End-to-End testing (performance and functional)
• New use cases ex. IoT/M2M
In-band full duplex • Self-interference cancellation including channel issues
• Co-existence with FDD and TDD duplex schemes
High speed data • Complex optical modulation (digital and analog)
• Extremely high digital data-rates
• Signal and power integrity
29
Page
Waveform Technologies
Requirements1
• Enable steeper spectrum roll-off
• Reduced peak to average power ratio
• Enable framework with low latency
• Address M2M specific requirement
• Higher spectral efficiency
• Enable synchronous-constrained applications
• Combination with Massive MIMO in higher
frequency bands
Industry Proposals
• Enhancements of OFDM
• Universal Filtered OFDM (UF-OFDM)2
• Filtered-OFDM (F-OFDM)3
• Filter-Bank Multi-Carrier (FBMC)
• Faster Than Nyquist (FTN)
• Wave Amplitude Modulation (WAM)
• Generalized Frequency Division Multiplexing (GFDM)
IMS2016 Press Conference 30
Note 1. NGMN white paper, “A deliverable by the NGMN Alliance,” February 2015
Note 2. Bell lab
Note 3. Huawei Canada
Page
mmWave ≠ 10x RF
Path loss can be
mitigated by high
gain directional
antennas
mmWave geometry allows for very
small, high gain antennas
Large available bandwidth at mmWave
Frequency
range6-20 GHz 20-40 GHz 40-60 GHz 60-100 GHz
Specific
bands
identified
10 GHz band
10.125-10.225 GHz
10.475–10.575 GHz
32 GHz band
31.8-33.4
GHz
40 GHz band
40.5-43.5 GHz
‘45 GHz’ band
45.5-48.9 GHz
66 GHz band
66-71 GHz
Potential
bandwidth
2 x 100 MHz 1.6 GHz 5.8 GHz total 5 GHz
High path loss due to atmospheric absorption
Source: Ofcom, Apr 2015
IMS2016 Press Conference 31
Page
UC San Diego 60 GHz Link Measurements
IMS2016 Press Conference
Link (distance): 4, 30 100 meters
~100 meters
30 metersEVM (9.5%)2-4 Gbps+/-45o scan
100 metersEVM (20%)1.5 Gbps+/-45o scan
32
Page
Mobility and the Challenge of Directional Antennas
Connected
high gain
tracking
Search Strategies
High Gain
Large volume to search
Low probability of both stations
pointing in the same direction
Low Gain:
Higher probability of looking in
the right direction, but much
less energy to detect
Why Search:
We should know where it is,
how fast it is moving and in
which direction it is traveling
33IMS2016 Press Conference
Page
Massive MIMO Channel Coherence Time
How Long Does it Take to Move ¼ Wavelength
Speed 2 GHz 28 GHz 60 GHz
3 km/h
30 km/h
120 km/h
34IMS2016 Press Conference
Page
Massive MIMO AntennasReal-Time Beamforming Measurement System
SystemVueSystemVue
IQ Data Files
8 channels at
1800 MHz
Waveform Generation
Beam
WeightsDemodulated
Symbols
Digitizer Control &
Dynamic Plotting
IMS2016 Press Conference
Facebook ARIES prototype35
Page
Channel Models and Validation
Better Assess how your designs will work in new channel models
Modified 3GPP 3D channel model and initial access to emerging fading channels
Channel Emulation to Link Simulation to Performance Evaluation
IMS2016 Press Conference 36
Increase Insight into 5G MIMO and mmWave channel propagation
UE1_Data
CQI_Bits
frm_TD
frm_FD
UE1_ModSymbols
UE1_ChannelBits
SC_Status
HARQ_Bits
LTE_A
DL
Src
PDCCH_Fill_OCNG=NO
CSIRS_Enable=NO
UE1_AMC_Enable=NO
UEs_n_RNTI=(1x6) [1,2,3,4,5,6]
UEs_SpecificRS=(1x6) [0,0,0,0,0,0]
UEs_TransMode=(1x6) [8,1,1,1,1,1]
LTE_A_DL_Src_1
1 1 0 1 0
1 1 0 1 0
Frame
UE1_RawBits
UE1_ChannelBits
UE1_ModSymbols
UE2_ModSymbols
UE3_ModSymbols
UE4_ModSymbols
UE5_ModSymbols
UE6_ModSymbols
PDCCH_ModSymbols
PHICH_ModSymbols
PCFICH_ModSymbols
PBCH_ModSymbols
SSS_ModSymbols
PSS_ModSymbols
DataOutUE1_HARQ_BitsUE1_TBS
UE1_PMIUE1_CQI
LTE_A
DL
Baseband
Receiver
CSIRS_Enable=NO
UE1_AMC_Enable=NO
UEs_SpecificRS=(1x6) [1,0,0,0,0,0]
UEs_TransMode=(1x6) [8,1,1,1,1,1]
LTE_A_DL_Rcv_1
MIMO_FastFadingEngine
FadedSignals
Delay
CIR
TransmittingSignals
{MIMO_FastFadingEngine@5G Advanced Modem Models}
SystemVue Link Simulation with METIS Channel Coefficients
Page
5G & Satellite Coexistence @ 28 GHz
IMS2016 Press Conference
Evaluate Potential Interference Scenarios
Wideband Satellite
Waveform
Wideband 5G
Candidate
Waveform
Wideband
Satellite
Waveform
5G Candidate
Waveform
37
Page
5G & Satellite Coexistence @ 39 GHz
IMS2016 Press Conference
Evaluate Potential Interference Scenarios
Source: http://en.wikipedia.org/wiki/High_throughput_satellite
Satellite Multicarrier
Waveforms
Wideband 5G
Candidate
Waveform
Satellite Multicarrier
Waveforms (1:N)
5G Candidate
Waveform
38
Page
mmWave Validation & Manufacturing Solution
Integrated & calibrated mmWave Signal Analysis & Generation
Integrated & Calibrated mmWave Signal Analysis and Generation
• RF TX/RX 55GHz – 67GHz (other frequencies in plan)
• IF TX/RX 2-18 GHz
• Analog I/Q TX/RX 2GHz
• 2 GHz Vector Bandwidth
• OTA RF Measurements at multi-frequency support
• Beam forming / beam steering testing made easy with
6 calibrated Tx/Rx vector mmWave transceiver heads
• Closed loop (RF-IF) measurements
• SCPI control over LAN
• Software Tools for Automated testing
• 5G Technology Ready
Launched at
Mobile World Congress 2016
First introduction for 802.11ad
mmW TX/RX Head
39IMS2016 Press Conference
Page
Link budget elements for Tx test:
- Transmitter output power
- Transmitter antenna gain
- Path loss
- Receive antenna gain
- Receiver noise power
- Link margin
OTA Measurement ChallengesLink Budget (DUT to TE)
11ad
DUT
mmW
TCVR
HEAD
US
B
US
B
US
B
US
B
US
B
US
B
A1 A2 A3 B1 B2 B3
RFIO1 RFIO2
mmW PORTS
A1 A2 A3B1 B2 B3
RFIO1 RFIO2
+
Air loss:
50dB
Horn Antenna gain:
15dBi
Plane of
Measurement
Input Power @ mmW head
-25 dBm
Thermal Noise
over 2GHz BW:
-81dBm
Plane of spec
Plane of Cal.DUT Tx Power:
+10dBm
Input power @ Rx
antenna: -40dBm
IF power / control signal
40IMS2016 Press Conference
Page
E-Band and Beyond
IMS2016 Press Conference
73/83GHz Freq and 5GHz BW
DARPAs Mobile Hotspot
Source: MWJ Oct 14,2014 - DARPA’s Mobile Hotspots Program Drives
E-Band Performance Benchmarks 41
Page
Delivering Wider Bandwidths at E-Band
IMS2016 Press Conference
EVM= 1.8%
Span 4GHz
42
Page
Millimeter Wave Network Analysis
IMS2016 Press Conference
Accurate Spectrum Analysis Up to 1.1 THz with Your Vector Network Analyzer
Integrated VNA delivers a unique capability for millimeter wave (MMW,
67-110 GHz) and sub-millimeter wave applications (Sub-MMW, 110
GHz -1.1 THz).
Easily switch from a standard VNA to a SA operation to get deeper
insights to standard S Parameter behavior
Broadband from 10 MHz to 110GHz Banded solutions to 1.1 THz
S21 Marker To SA Function S11 Marker To SA Function
43
Page
Measure Spectrum a DUT PortFull De-embed of fixture loss
Port 2
Without Fixture Compensation
Fixture Loss De-embedded
Uncalibrated Measurement
44IMS2016 Press Conference
Page
Keysight mmWave SolutionComplete E2E Solution To Solve the mmWave and OTA Challenges
Core Platform
Software Automation
Design & Support Services C
om
ple
te S
olu
tion
Services
• Calibration, operator training, mmWave consulting
• Service Level Agreements for Maximized Uptime
Fixturing and Test Bed Considerations
• Chamber design and system calibration
• Distance from DUT Antenna, Link Budgeting
Fully Calibrated connector-less (OTA) Testing
• OTA Near field vs. far field measurement science
• Flexible architecture to go beyond the instrument (chamber, positioner, etc)
Chipset Software for Automated Design Verification
• Integrated chipset control
• Complete 802.11ad test plan for integration into shop floor
Differentiated Domain Expertise in mmW Technology
• Firsthand experience in our own design, test and manufacturing of mmW solutions
• Support 802.11ad IF/RF frequency, BW and measurements, up to 6 mmW RF heads
IMS2016 Press Conference 45
Page
Thank you and enjoy the show!
IMS2016 Press Conference 46
www.Keysight.com/find/IMSpress