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<4D6963726F736F667420576F7264202D20414D4F4C4544CFF1CBD8B2B9B3A5BCBCCAF5BCB0B8DFD0D4C4DCBBF9D7BCD4B4D1D0BEBF2DCEA2B5E7D7D32D313630313231333936322DD2D7CBAEC6BD2E646F6378>
OLED
—
-
CMOS
II
References for Active Matrix Organic Light Emitting Diode
Displays
Directed by Hailong Jiao
ABSTRACT
Active matrix organic light-emitting diode (AMOLED) display is
regarded as the next-
generation mainstream display due to the advantages of fast
response, wide viewing angle,
high contrast, high saturation, low power consumption, and low
cost. AMOLED is widely
used in flexible and transparent displays. However, due to the
issues such as the drift of thin
film transistor (TFT) threshold voltage, non-uniform mobility, and
degradation of OLED, the
prevalence of AMOLED is still constrained. To obtain better display
effect, these undesirable
factors must be eliminated or at least mitigated. A systematic
research on two existing
compensation technologies is carried out in this thesis:
intra-pixel circuit compensation and
peripheral compensation. The main contributions of this thesis are
as follows.
First of all, a voltage-programming pixel circuit with mobility
compensation is proposed.
While compensating the threshold voltage variation, the proposed
pixel circuit can also
compensate the non-uniformity of mobility. Only two control signal
lines are required, which
can effectively reduce the complexity of the peripheral driver
integrated circuit (IC) and
increase the aperture ratio of the pixel array. Furthermore, the
propsoed pixel circuit is suitable
for microdisplay. The mobility compensation structure can
effectively increase the data input
range by controlling the discharge time of the data input
stage.
Second, an alternative voltage-programming pixel circuit also with
mobility
compensation is proposed. This circuit utilizes the fact that the
source voltage of the driving
TFT (TD), namely the anode voltage of OLED, follows the change of
the mobility to maintain
the gate voltage of TD through the coupling effect of capacitance
during the emission stage.
Therefore, the gate-source voltage can be tuned to reduce the
influence of mobility non-
uniformity on the saturation current of TD (the OLED luminous
current). Furthermore, the
timing of the pixel circuit is simple. The scan line can be
multiplexed to realize continuous
ABSTRACT
III
input of data, which can simplify the design of the timing control
circuit and improve the pixel
aperture ratio.
Third, based on the importance of the reference in the peripheral
compensation, a high
power supply rejection ratio (PSRR), low temperature coefficient
(TC), and variable output
voltage mode bandgap reference is studied. By adding a PSRR
enhancement structure, a
cascode current mirror, and a negative feedback loop in the startup
circuit, the PSRR of the
reference output is increased. Furthermore, the high-order
compensation of the reference
output is achieved by utilizing the mismatch of the current.
Fourth, a hybrid current mode voltage reference with low
temperature coefficient and low
power consumption is proposed. The different temperature
characteristics of the BJT-based
and MOS-based references in the subthreshold region are used to
obtain this current mode
reference with ultra-low temperature coefficient. This proposed
reference is especially suitable
for circuits that are with low supply voltage and require low power
consumption.
Finally, a hybrid current mode voltage reference with ultra-wide
range of operating
temperature is proposed. The negative temperature characteristics
of BJT and sub-threshold
MOS are used to make high-order compensation. Furthermore, the
low-temperature
segmentation compensation module is added to widen the operating
temperature range of the
circuit. This reference can be applied for circuits operating at
low supply voltage and
extremely wide temperature range.
IV
2.1
...........................................................................
12
2.1.1
....................................................................................
12
2.1.2
........................................................................................................
14
2.2
...........................................................................
18
2.2.1
....................................................................................
19
2.2.2
........................................................................................................
20
2.3
...................................................................................................................
22
3.2
...................................................................................................
26
3.3 ....................................... 27
3.3.1
............................................................................
27
3.3.2
....................................................................................
30
3.3.3
........................................................................................................
34
3.4
...................................................................................................................
37
....................................................................................
38
4.1
...........................................................................................
39
4.2
.......................................................................................................
42
4.3.1
........................................................................................
44
4.4.1
........................................................................................
52
4.4.2
........................................................................................................
54
4.5
...........................................................................................
56
4.5.1
....................................................................................................
57
4.5.2
................................................................................................
59
4.6
.....................................................................................................................
62
............................................................................................................
63
Active Matrix Liquid Crystal Display, AMLCD
AMLCD 80%
AMLCD
TFT
AMLCD
1. 2.
3. AMLCD
OLED
1.1 OLED
ELElectroluminescence
OLED Bernanose Vouaux
EL[1] 10 Pope
OLED
[2] W. Helfrich 1965
100 V 5%
[3]1983 R. H. Partridge PVCz
[4] 1987 OLED
C.W. Tang Steve
Van Slyke OLED
10 V 1%[5]
OLED C.W. Tang Alq3
40% Alq3 3~5 10 V
2
Friend
OLED [7] 1998 OLED
[8] OLED
AMOLED OLED
OLED OLED
“”OLED 1.1a Al
ITO EIL HIL N
P
1.1b OLED
/ EIL HIL / ETL
HTL EML ETL HTL //
EML
BGR
OLED LCD
[11]
[12]OLED
OLED PMOLED AMOLEDOLED
TFT PMOLED
TFT-
LCD AMOLED TFT PMOLED
a b
1.3 aPMbAM
60 Hz 60
VDD
OLED
TD
CS1
PMOLED
N 16.7/N ms
× Ldisplay
PMOLED [14][15]
PM AM
TFT OLED
1.1 PMOLED AMOLED
PMOLED AMOLED
IC
OLED AMOLED
2T1C 1.2b TS TD
CS CS TD
OLED
AMOLED PMOLED
PM
AM
AM OLED
1.2 AMOLED
AMOLED PMOLED OLED [16]
OLED
OLED OLED
AMOLED a-Si:HTFT
LTPSTFT IGZOAOSTFT
a-Si:H TFT
[18][19][20] AMOLED
LTPS TFT [21][22][23] IGZO TFT
AOS TFT a-Si:H LTPS TFT
TFT [24][25][26]OLED
OLED
1.2 AMOLED
TFT Type NMOS CMOS NMOS
TFT Uniformity Good Poor Good
Channel Mobility 1 cm 2 /Vs 50-100 cm
2 /Vs 5~50 cm
2 /Vs
Mask Numbers 4~5 5~11 4~5
Cost/Yield Low/high High/low Low/high
Resolution Low High High
6
1.3b 2T1C
TS
TD CS
IOLED OLED
21 ( )
W I C V V V
L 1.1
VDATAVOLED VTHOLED
VOLED OLED VTH_OLED1.1
IOLED OLED
TFT OLED OLED
OLED OLED
OLED
OLED
OLED
12
34
1.4a TD
VHIGH VREFVREF < VHIGH - VTH TD -
VTHTD
- VREF + VTHTD
[29][30][31]
VTHVTH
VTH OLED
VREF VLOWVLOW < VREF - VTH TD
VDD TD TD TD
TD TD VREF
TFT
OLED
OLED
[33]
OLED
OLED
IPIXEL IPIXEL
= IREF
OLED
trimming
CMOS
a-IGZO TFT
TDT1~T4CS1
CS2 2.1b
1234
1
VDD T1T2 CS1
A B OLED T3
VL VREFVREF = 0 T4 C
2
VSCAN2 T2T3T4 VSCAN1 T1
TD -TD A
T2TD T3 TD A VL + VTH_TD
3
VSCAN1 VSCAN2 T1 T2T3T4
0 VDATA CS2 CS1 CS2
A TD -TD A
ΔVµ_TD
S S
C C
2.2
2.2T k = µ • COX • (W/L)_TDµ
COX TFT W L TFT
CS1
V V Ck
VSCAN1 VSCAN2 T2T3 CS2
OLED T1TD OLED B
TD A B
OLED TD
C C C C C 2.4
OLED TFT OLED TFT
OLED µ
ΔVµ_TD ΔVµ_TD T
2.1.2
RPIRensselaer Polytechnic Institue IGZO TFT
Thin Film Transistor and Advanced Display Lab
OLED TFT OLED
I-V IGZO TFT OLED OLED
COLED
TFT OLED 2.1
WT1~T4 (µm) 3.5 VSCAN (V) -5~15
L (µm) 3.5 VDATA (V) 0~10
CS1 (pF) 0.5 CS2 (pF) 0.3
AMOLED
2
4
6
8
10
-0.6 -0.4 -0.2 0.0 0.2 0.4 0.6 0
5
10
15
20
2.3 OLED OLED
2.2 VAVBVA - VB IOLED VREF = 0VDATA = 5 V
A
B VA - VB
OLED
Current Error Rate, CERCER =IOLED1 - IOLED/ IOLED IOLED
IOLED1
OLED TD -
16
0.6 V ~ + 0.6 V 0.5 V 4
V 2.3 10% TD
0.4 V
TD ΔVTH_TD = 0.4 V 2T1C
26.1% 77.6%
10% 11.6%
0 1 2 3 4 5 6 7 8 9 10 0
200
400
600
800
1000
1200
1400
a
0 1 2 3 4 5 6 7 8 9 10 -60 -50 -40 -30 -20 -10
0 10 20 30 40 50 60 70 80 90
coventional 2T1C V
b
2.4 VTH_TD±0.4 V 2T1C aOLED b
0 5 10 15 20 25 30 35 40 0
1
2
3
4
5
6
VGS_TD
VGS_TD
VGS_TD
a
0 1 2 3 4 5 6 7 8 9 10 -30
-20
-10
0
10
20
30
2.5 a-b±30%OLED
OLED 2.5a
μ - VGS_TD μ
- 2.5
b 30%OLED 6%
TFT
VTH
- VGS_TD = VGS_TH
TFT TFT -
- VGS μ
μ
0 1 2 3 4 5 6 7 8 9 10 0
200
400
600
800
1000
1200
% )
2.6 ΔVTH_TD = ±0.4 V ΔVTH_TD = 0.4 V OLED
2.6 OLED VTH_TD±0.4 V VTH_OLED 0.4 V
OLED
TFT OLED VTH_TD VTH_OLED 0.4 V
15.1%
OLED OLED
OLED
OLED OLED
AMOLED
2.2.1
2.7a CS1
-
a b
1
VEM(n) VSCAN(n) T1T2 T3
T3 A VDD T1T2 B VB
VHIGH
VEM(n)T1 BC
TD TD VB T2 TD TD
VB VTH_TD + VTH_OLEDVTH_TD VTH_OLED TD OLED
3
VSCAN(n+1)A T4 0 B
CS1 VB
VDATA VDD
VEM(n)T1 TD TD
OLED OLED
OLED TD VC VOLED(µ) OLED
2 _ ( )(| | )
C W I V V V
L
2.6
2.6OLED TD VTH_TD OLED
VTH_OLEDVOLED(μ)VOLED(μ)VTH_OLED
VOLED(μ) μ
VOLED(μ) VOLED(μ)
VTH_OLED OLED VTH_OLEDOLED VOLED(μ)
OLED
2.9 0.5 V
8% 2.10
±30%
OLED
0
5
10
15
V C
0 200 400 600 800 1000 1200 1400 1600 1800 2000
IOLED
-4 -3 -2 -1 0 1 0
200 400 600 800
VTH = 0V VTH_TD = -0.5V VTH_OLED = +0.5V VTH_TD = +0.5V
I O L
VDATA (V)
-10 -8 -6 -4 -2 0 2 4 6 8 10
C E
% )
2.9 ΔVTH_TD = ±0.5 V ΔVTH_OLED = 0.5 V IOLED
Reset VTH extraction Data coupling Emission
22
-4 -3 -2 -1 0 1 -30 -25 -20 -15 -10 -5 0 5
10 15 20 25 30
C E
5T2C
CS1
OLED
30%OLED
6% VTH_TD±0.4 V VTH_OLED 0.4 V
OLED 15.1%
OLED
AMOLED
0.5V 8%
CS1
OLED
Types of signal line 1 3 1 3 2 2
VTH variation No Yes No Yes Yes Yes
OLED degradation No Yes No Yes Yes Yes
Mobility deviation No No Yes No Yes Yes
IR-drop No Yes Yes Yes Yes Yes
24
3.1
“1”
[39]
DAC
Gamma [45][46]
8-bit 10-bit Gamma 10-bit
8-bit 10-bit 11-bit
AMOLED
PTL 1-bit
PTL
[47]
8-bit Gamma DAC 8-
bit DAC VDATA VTH
VDATA + VTH 8-bit DAC
11-bit DAC 1/4
3.2
Compensation Block
OLED IPIXEL IREF
Pixel [1][1]
Pixel [1][2]
Pixel [2][1]
Pixel [2][2]
Pixel [n][1]
Pixel [n][2]
Pixel [1][m]
Pixel [2][m]
Pixel [n][m]
Look_up Table, LUT
IPIXEL
IPIXEL = IREFIREF
LUT TCON Gate Driver Data Driver
Gate Driver VSCAN VFB
VFB VSCAN
AMPEN C Vref
Vref < VOLEDVFB VSCANT2T3
VDATA T2 A T1 B OLED
AMOLED
OLED Ipixel T3 Cp
C C Vref C
C Ipixel
IFBIFB Iref
C1
C1C2 Vref IFB > Iref
VOUT
OLED
ΔVBE
MN Q1Q2 Q2Q1
VREF
Q3 - VEB3 Q1Q2 - ΔVEB
AMOLED
R 3.1
r r
T T
ln = T
VEB VTln(T/Tr)
Tr
r r r r
T kT T T T V ln T q T T T 3.2
PSRR
[ ( ) ]g ma B A mdd dd oav g v v g v r 3.3
1 1( )A m dd g Qv g v v r 3.4
30
3 1 2( )B m dd g Qv g v v R r 3.5
5 2 3( )( )ref m dd g Qv g v v R r 3.6
gmaroa gmddroa Ai Addgm1
gm2gm3 M1M2M3 rQ1rQ2rQ3 Q1Q2Q3
gm1 = gm2 = gm3 = gm
20 log ref
v A g R r r
Add = 1 vref/vdd
3.8 Strat Up
IBIASPSRR PSRR EnhancementBGR
CoreV-VV-I
ln =( )
+ T
R R R
ln =( )
+ T
R R R 3.10
ln =( )
( + ) T
3.11ROUT R2 32
trimming 3.9 R2
A PM6 B
AMOLED
NM17
C
Vg1
IB
Vg2
trimming trimming
trimming —
R— TC
32
VREF R I
3.9 trimming D<0:N-1> N
2N 2N
N = 5R20 = 0.8R2ΔR = 0.4R2/2N 10000
17 S17
V-V
AB PMOS
NMOS 1/f
PSRR 3.8 PSRR
3.6 PM3 PM4 VDD AB
VDD B R1 A
Vg1 VDD PTAT
PM1PM2 PM3PM4
VDD
PM2PM4 PM4 PM2
VDD IB
NM15 NM14 VDD PSRR
PM15 VDD Vc VDD
PTAT
3.8 Ileak 0
3.8 VDDX VXNM12
Y VY NM11 Z VZ
AMOLED
3.8 PM1 PM2 I1 I2
I1 I2 ΔIεS = ΔI/I I2/I1 = 1 + εS
εS 1 R1
2 1 1 1
V V V I ln N lnN
R R R 3.13
2 2
R lnN 3.14
poly
2 2 2 1 2( )[1 ( ) ( ) ]r r rR R T B T T B T T 3.15
3.15B1 B2 R2 B1 < 0B2 > 0
3.13.23.143.15
1 (
3
2
2
r
ref
q T T T
m = (R2/R1)lnN
N R1 M R2 R2
3.1 R2 m
34
ΔI“M”
3.10 AMOLED
2.5~4.5 V
3.11 3.11a Vref “M”
3.11bTT Corner 2.19 ppm/°C
V-V
Vref_H Vref_LVref
FS TC 1.95 ppm/°C FF TC
14.61 ppm/°C 3.12 PSRR
PSRR PSRR -80 dB
PSRR 3.8 NM12
PSRR PSRR
W12 = 2 μm -112 dB
AMOLED
-40 -20 0 20 40 60 80 100 120 1.1833
1.1834
1.1835
1.1836
1.1837
1.1838
0.29540
0.29545
0.29550
0.29555
0.29560
0.29565
0.29570
2.5110
2.5115
2.5120
2.5125
2.5130
2.5135
-60 -40 -20 0 20 40 60 80 100 120 140 1.170
1.175
1.180
1.185
1.190
1.195
1.200
V re
f( V
36
10-1 100 101 102 103 104 105 106 107 108 109 1010
-120
-110
-100
-90
-80
-70
-60
-50
-40
-30
-20
+ PSRR Enhancement
P S
R R
WNM12 = 1.5 m
WNM12 = 2 m
WNM12 = 2.5 m
WNM12 = 3m
B.
3 trimming
3.13 Sample1Sample2 Sample3 1.1 mV3.7 mV
8.9 mV 4.99 ppm/°C17.85 ppm/°C 46.85 ppm/°C
3.14 BGR PSRR
5 Hz 30 MHz PSRR -76.1
dB @ 10 Hz-69.8 dB @ 1 kHz-44.9 dB @ 10 MHz
1.2948
-40 -20 0 20 40 60 80 100 120 140
V re
f ( V
PSRR TC CSMC
0.25μm
PSRR
LDO
-40~130 °C
4.99 ppm/°C PSRR -80 dB
3.3 V 37 μA
3.4
38
BJT MOS
VREF=(αICTAT+βIPTAT)RO
BJT
4.2 VREF
1 1 2( ln / / )REF T EB OV V MN R V R R 4.2
MN Q2Q1 PM1PM2
MN R1R2 RO
a b
Vref
RO
PM
I
VDD
VSS
RO1
Vref
RO
PM
I
VDD
VSS
rQ
Q
4.3 1.2 V
μA BJT- 0.6 V
I VT 26 mV rQ kΩ
kΩ RORO1 PN
RO
[53][54][55]
[56]
4.4
VREG VDD VREF
VREF VOUT
4.6
io
1
_ 4 1 _ 4 _ 2 _ 2
o o o m NM
d s N M d s N M d s PM
v vv i g v
r r r 4.3
r r
_ 3 _ 2
/ / / / (1 )(1 )i
ds PM ds NMo O v ds PM ds NM
o m NM ds NM m PM ds PM
r rv R r r
i g r g r
I1 I2 _ 2ds PMr _ 2ds NMr
_ 4ds NMr _ 3 _ 3 1m PM ds PMg r
_ 4 _ 3 _ 3
R g g r
M4
_ 4 _ 31 m NM ds PMg r VDDVREG PSRR
_ 2 _ 2 _ 4 _ 3 _ 3
1 20lg 20lg 20lg
reg o V
dd o ds PM ds PM m NM m PM ds PM
v R PSRR
4.7
VREG
[62][61]
BJT - VBE
MOS - VGS
MOS
BJT
1 1 2 2( )REF PTAT PTAT CTAT OUTV N I N I N I R 4.8
IPTAT1
PTAT IPTAT1 NM1
NM2 - R1
1 1 1 1
R R 4.9
n 1~3 [58][59]
ln(10) (1 )S T
R R 4.11
( ) )/ ( ( ) 1
r r
T R
T k V ln T T T T
T q T T 4.13
2 3 0 1 2 3( )REF OUTV a a T a T a T R 4.14
a0a1a2 a3
0
R q R T q
4.16
2
C RT qR q
4.18
N2R2M2NRN1R1 M1 a1a2
Tr
R 5-bit trimmingtrimming MC
sigma 2~3 trimming 4.9b trimming
R
4.9 a trimming b trimming
4.9a trimming [57][58]
2 1 ~
2N2N-1…2 R 1
2N R MOS
MOS
4.9b 02 02
2 1
1 R R R
R MOS
4.3.2
SMIC 0.18-μm CMOS Cadence Spectre
4.10 1.2 V
1.3 V TC
1.3 V~2.5 V 1.5 V-35~105 ºC TC
0.96 ppm/ ºC
PSRR
PTAT
0.0 0.2 0.4 0.6 0.8 1.0 1.2 1.4 1.6 1.8 2.0 2.2 2.4 2.6
0.00
50.00
100.00
150.00
200.00
250.00
300.00
350.00
400.00
( pp
m /°
C )
1.3 1.4 1.5 1.6 1.7 1.8 1.9 2.0 2.1 2.2 2.3 2.4 2.5 121.60
121.80
122.00
122.20
122.40
122.60
122.80
123.00
123.20
123.40
123.60
0
2
4
6
8
10
12
14
16
18
20
-40 -20 0 20 40 60 80 100 120 122.004
122.006
122.008
122.010
122.012
122.014
122.016
122.018
122.020
122.022
122.024
100 101 102 103 104 105 106 107 108 109 -70
-60
-50
-40
-30
-20
-10
0
4.12 1.5 V
Monte Carlo trimming
TC PSRR
0 4 8 12 16 20 24 28 32 36 40 44 0
20
40
20
40
60
C ou
20
40
60
V ref
C ou
4.13b
PM3NM3 4.13b VDD
X VX PM1 Y VY NM2
Z VZ NM3 X VX-VY-
VZ-VX PSRR
PSRR
4.14 PSRR
PM1 PM2
-30
-25
-20
-15
-10
-5
0
5
10
121.60 121.80 122.00 122.20 122.40 122.60 122.80 123.00 123.20
123.40 123.60
0 2 4 6 8 10 12 14 16 18 20
121.80 121.84 121.88 121.92 121.96 122.00 122.04 122.08
122.12
0 4 8 12 16 20 24 28 32 36 40 44
1.3 1.4 1.5 1.6 1.7 1.8 1.9 2.0 2.1 2.2 2.3 2.4 2.5 120.94
120.96
120.98
121.00
121.02
121.04
121.06
121.08
121.10
VDD (V)
0 2 4 6 8 10 12 14 16 18 20 22 24
-80 -70 -60 -50 -40 -30 -20 -10
0
-100 -90 -80 -70 -60 -50 -40 -30 -20 -10
0 10
100 101 102 103 104 105 106 107 108 109
-120 -100
)
value(PSRR "V" 1.3) (dB) value(PSRR "V" 1.8) (dB) value(PSRR "V"
2.3) (dB) value(PSRR "V" 1.4) (dB) value(PSRR "V" 1.9) (dB)
value(PSRR "V" 2.4) (dB) value(PSRR "V" 1.5) (dB) value(PSRR "V"
2.0) (dB) value(PSRR "V" 2.5) (dB) value(PSRR "V" 1.6) (dB)
value(PSRR "V" 2.1) (dB) value(PSRR "V" 1.7) (dB) value(PSRR "V"
2.2) (dB)
freq (Hz)
1.3~2.5 V -35~105 ºC
1.5 V 13 μA PSRR -57.55 dB
-76.87 dB -77.15 dB 1.3 V -71.17 dB 1.4 V -
84.24 dB 2.1 V -112 dB
4.17
PTAT
1 2( )REF PTAT CTAT OUTV N I N I I R 4.19
PTAT Q1Q2 R1
1 1
R R 4.20
2 5 2
R 4.21
r r
T T 4.22
I V V nV
I 4.23
( ) ( ) ( ) THTH TH r V rV T V T B T T ln(10) (1 )S
OX
VREF- +
A
53
2 3 0 1 2 3( )REF OU TV a a T a T a T I R 4.24
2
N kT a V V T B T
R q
R q R T q
4.26
2
R qT C Iq
4.19
PM6 PM7 PM8 PM9
NM6 NM7 PM7 PTAT
54
β1β2 TL TL PM7
NM7 PM8 NM7
PM7 M7 PM8 PM8
PM8 M7 ΔI
PM9
PM7 NM7 NM7
PM8
PM7 NM7 ΔI
2 1
T T
β1β2 TL
β
4.4.2
4.20
4.20
0.0 0.2 0.4 0.6 0.8 1.0 1.2 1.4 1.6 1.8 2.0 2.2 2.4 2.6
0.00
100.00
200.00
300.00
400.00
500.00
600.00
700.00
800.00
1.1 1.2 1.3 1.4 1.5 1.6 1.7 1.8 1.9 2.0 2.1 2.2 2.3 2.4 2.5
154.00
155.00
156.00
157.00
158.00
159.00
148 152 156 160 164 0 4 8
12 16 20 24 28 32 36 40 44
V ref
C ou
C ou
4.22 1.5V MC
4.20 1.1~2.5 V
4.21b
1.5 V PSRR -50 dB 4.21a
PM8 -15~140 ºC
-50~140 ºC 5.13 ppm/ºC
-15 ºCPM8 4.22 1.5 V Monte
Carlo
TC
100 101 102 103 104 105 106 107 108 109 -55
-50
-45
-40
-35
-30
-25
-20
-15
-10
-5
0
-60 -40 -20 0 20 40 60 80 100 120 140
154.58
154.60
154.62
154.64
154.66
154.68
154.70
154.72
154.74
100 101 102 103 104 105 106 107 108 109
-80
-60
-40
-20
0
freq (Hz)
value(PSRR "V" 1.3) (dB) value(PSRR "V" 1.7) (dB) value(PSRR "V"
2.1) (dB) value(PSRR "V" 1.4) (dB) value(PSRR "V" 1.8) (dB)
value(PSRR "V" 2.2) (dB) value(PSRR "V" 1.5) (dB) value(PSRR "V"
1.9) (dB) value(PSRR "V" 2.3) (dB) value(PSRR "V" 1.6) (dB)
value(PSRR "V" 2.0) (dB) value(PSRR "V" 2.4) (dB) value(PSRR "V"
2.5) (dB)
4.23
1.5 V PSRR-48.58 dB-74.48
dB
-15~140 ºC -50~140 ºC 1.5 V
5.13 ppm/ºC 7.43 μA
58
R BJT
dummy BJT
1:8 3×3 4×3 OPA
triple ring latch-up
4.5.2
0.18-μm CMOS Mentor Graphics Calibre
Cadence Spectre
1.5V
122.39 122.40 122.41 122.42 122.43 122.44 122.45 122.46 122.47
122.48 122.49 122.50
-40 -20 0 20 40 60 80 100 121.600
121.605
121.610
121.615
121.620
121.625
121.630
121.635
1.8 ppm/ºC
100 101 102 103 104 105 106 107 108 109
-80
-70
-60
-50
-40
-30
-20
-10
0
-40 -20 0 20 40 60 80 100 120 140
154.50
154.55
154.60
154.65
154.70
154.75
4.1
0.13 0.18 0.18 0.18 0.18 0.18
V 1.2 4.4~5.6 0.6~1.2 0.9~2 1.3~2.5 1.3~2.5
µA 120 50 0.03 0.085 13 7.43
mV 735 2500 218.3 411.9 122 154.7
ºC -40~120 -60~150 -40~125 -40~125 -35~100 -50~140
TCppm/ºC 9.3 0.42 23.5 33.7 1.11 4.94
PSRRdB -30@
mm 2 0.063 0.075 0.11 0.021 0.014
100 101 102 103 104 105 106 107 108 109
-80
-70
-60
-50
-40
-30
-20
-10
0
AMLCD
IGZOAOS
IGZO TFT
AOS TFT TFT
OLED AMOLED
64
65
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