THS4552
SBOS831B – DECEMBER 2016 – REVISED JUNE 2021
THS4552
Dual-Channel, Low-Noise, Precision, 150-MHz, Fully Differential Amplifier
1 Features
3 Description
•
•
•
•
The THS4552 fully differential amplifier offers an
easy interface from single-ended sources to the
differential output required by high-precision analogto-digital converters (ADCs). Designed for exceptional
dc accuracy, low noise, and robust capacitive load
driving, this device is well suited for data acquisition
systems where high precision is required along with
the best signal-to-noise ratio (SNR) and spurious-free
dynamic range (SFDR) through the amplifier and ADC
combination.
•
•
•
•
•
•
•
•
•
•
Bandwidth: 150 MHz (G = 1 V/V)
Differential output slew rate: 220 V/µs
Gain bandwidth product: 135 MHz
Negative rail input (NRI),
rail-to-rail output (RRO)
Wide output common-mode control range
Single-supply operating range: 2.7 V to 5.4 V
Trimmed-supply current:
1.37 mA per channel at 5 V
25°C input offset: ±175 µV (maximum)
Input offset voltage drift: ±2.0 µV/°C (maximum)
Differential input voltage noise: 3.3 nV/√ Hz
HD2: –128 dBc at 2 VPP, 100 kHz
HD3: –139 dBc at 2 VPP, 100 kHz
< 50 ns settling time: 4 V Step to 0.01%
18-bit settling time: 4 V Step, < 500 ns
The THS4552 features the negative rail input required
when interfacing a dc-coupled, ground-centered,
source signal to a single-supply differential input ADC.
Very low dc error and drift terms support the emerging
16- to 20-bit successive-approximation register (SAR)
input requirements. A wide-range output commonmode control supports the ADC running from 1.8
V to 5 V supplies with ADC common-mode input
requirements from 0.7 V to greater than 3.0 V.
2 Applications
24-Bit, delta-sigma (ΔΣ) ADC drivers
16- to 20-Bit, differential, high-speed SAR drivers
Differential active filters
Differential transimpedance amplifiers
Pin-compatible upgrade to the THS4522
(TSSOP-16 only)
The THS4552 device is characterized for operation
over the wide temperature range of –40°C to +125°C,
and is available in 16-pin TSSOP and 24-pin VQFN
packages.
Low-Power ADCs Supported by the THS4552(1)
PART
NUMBER
ADC TYPE
RESOLUTION, SPEED
ADS1278
Delta sigma
Octal, 24 bits, 0.512 MSPS
ADS8694
SAR
Quad, 18 bits, 0.5 MSPS
ADC3221
Pipeline
Dual, 12 bits, 25 MSPS
ADC3241
Pipeline
Dual, 14 bits, 25 MSPS
(1)
For all available packages, see the orderable addendum at
the end of the datasheet.
1.2 k
270 pF
470 pF
1.2 k
330
1 nF
VOCM
1.2 k
+
±
3V
5
+
±
•
•
•
•
•
THS4552
330
10
AINN
22 nF
ADS127L01
AINP
5
10
270 pF
1.2 k
Copyright © 2016, Texas Instruments Incorporated
Simplified Schematic: Gain of 1-V/V, Single-Ended Input to Differential Output, 500-kHz, Multiple
Feedback Filter Interface to the ADS127L01 (1 of 2 Channels)
An IMPORTANT NOTICE at the end of this data sheet addresses availability, warranty, changes, use in safety-critical applications,
intellectual property matters and other important disclaimers. PRODUCTION DATA.
THS4552
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SBOS831B – DECEMBER 2016 – REVISED JUNE 2021
Table of Contents
1 Features............................................................................1
2 Applications..................................................................... 1
3 Description.......................................................................1
4 Revision History.............................................................. 2
5 Pin Configuration and Functions...................................4
6 Specifications.................................................................. 5
6.1 Absolute Maximum Ratings........................................ 5
6.2 ESD Ratings............................................................... 5
6.3 Recommended Operating Conditions.........................5
6.4 Thermal Information....................................................6
6.5 Electrical Characteristics: (VS+) – (VS–) = 5 V.............6
6.6 Electrical Characteristics: (VS+) – (VS–) = 3 V.............9
6.7 Typical Characteristics: (VS+) – (VS–) = 5 V.............. 12
6.8 Typical Characteristics: (VS+) – (VS–) = 3 V.............. 15
6.9 Typical Characteristics: 3 V to 5 V Supply Range.....18
7 Parameter Measurement Information.......................... 22
7.1 Example Characterization Circuits............................22
7.2 Output Interface Circuit for DC-Coupled
Differential Testing.......................................................24
7.3 Output Common-Mode Measurements.....................24
7.4 Differential Amplifier Noise Measurements...............25
7.5 Balanced Split-Supply Versus Single-Supply
Characterization.......................................................... 25
7.6 Simulated Characterization Curves.......................... 25
7.7 Terminology and Application Assumptions............... 26
8 Detailed Description......................................................27
8.1 Overview................................................................... 27
8.2 Functional Block Diagram......................................... 27
8.3 Feature Description...................................................28
8.4 Device Functional Modes..........................................36
9 Application and Implementation.................................. 41
9.1 Application Information............................................. 41
9.2 Typical Applications.................................................. 50
10 Power Supply Recommendations..............................56
10.1 Thermal Analysis.................................................... 56
11 Layout........................................................................... 57
11.1 Layout Guidelines................................................... 57
11.2 Layout Example...................................................... 58
11.3 EVM Board..............................................................59
12 Device and Documentation Support..........................60
12.1 Device Support....................................................... 60
12.2 Documentation Support.......................................... 62
12.3 Receiving Notification of Documentation Updates..63
12.4 Support Resources................................................. 63
12.5 Trademarks............................................................. 63
12.6 Electrostatic Discharge Caution..............................63
12.7 Glossary..................................................................63
13 Mechanical, Packaging, and Orderable
Information.................................................................... 63
4 Revision History
NOTE: Page numbers for previous revisions may differ from page numbers in the current version.
Changes from Revision A (July 2017) to Revision B (June 2021)
Page
• Updated the numbering format for tables, figures, and cross-references throughout the document..................1
• Removed the IIB input bias current (positive current out-of-node) minumum limits in the Electrical
Characteristics: (VS+) – (VS–) = 5 V section........................................................................................................6
• Removed the IIB input bias current (positive current out-of-node) minumum limits in the Electrical
Characteristics: (VS+) – (VS–) = 3 V section........................................................................................................9
Changes from Revision * (December 2016) to Revision A (July 2017)
Page
• Changed 47k Ohms, 1.3 pF to 150k Ohms, 7 pF in Section 6.5 table............................................................... 1
2
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Device Family Comparison (Dual-Channel, Precision FDAs)
DEVICE
BW, G = 1 (MHz)
IQ, 5 V
(mA/Ch)
INPUT NOISE
(nV/√ Hz)
THD (dBc) 2 VPP
AT 10 kHz
RAIL-TO-RAIL
SINGLE
VERSIONS
THS4552
150
1.37
3.3
–138
Negative in, out
THS4551
THS4522
145
1.14
5.6
–120
Negative in, out
THS4521
THS4532
36
0.25
10
–118
Negative in, out
THS4531A
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SBOS831B – DECEMBER 2016 – REVISED JUNE 2021
±IN1
1
+FB1
2
+IN1
±FB1
±VS1
±VS1
PD1
±OUT1
5 Pin Configuration and Functions
24
23
22
21
20
19
18
+OUT1
17
PD1
1
16
VS±
VIN1+
2
15
VOUT1±
VIN1±
3
14
VOUT1+
VOCM1
4
13
VS1+
PD2
5
12
VS±
VIN2+
6
11
VOUT2±
VIN2±
7
10
VOUT2+
VOCM2
8
9
VS2+
+
+VS1
+VS1
3
16
4
15
VOCM1
±VS2
±VS2
±FB2
5
14
PD2
+IN2
6
13
±OUT2
±
+
7
8
9
10
11
12
±IN2
+FB2
+VS2
+VS2
VOCM2
+OUT2
±
Figure 5-1. RTW Package 24-Pin VQFN With
Exposed Thermal Pad Top View
Figure 5-2. PW Package 16-Pin VSSOP Top View
Table 5-1. Pin Functions
PIN
NAME
I/O
DESCRIPTION
PW
FB1–
23
—
O
Channel 1, inverting (negative) output feedback
FB2–
5
—
O
Channel 2, inverting (negative) output feedback
FB1+
2
—
O
Channel 1, noninverting (positive) output feedback
FB2+
8
—
O
Channel 2, noninverting (positive) output feedback
IN1–
1
3
I
Channel 1, inverting (negative) amplifier input
IN2–
7
7
I
Channel 2, inverting (negative) amplifier input
IN1+
24
2
I
Channel 1, noninverting (positive) amplifier input
IN2+
6
6
I
Channel 2, noninverting (positive) amplifier input
OUT1–
19
15
O
Channel 1, inverting (negative) amplifier output
OUT2–
13
11
O
Channel 2, inverting (negative) amplifier output
OUT1+
18
14
O
Channel 1, noninverting (positive) amplifier output
OUT2+
12
10
O
Channel 2, noninverting (positive) amplifier output
PD1
20
1
I
Channel 1, power-down.
PD = logic low = power off mode; PD = logic high = normal operation.
PD2
14
5
I
Channel 2, power-down.
PD = logic low = power off mode; PD = logic high = normal operation.
VOCM1
17
4
I
Channel 1, common-mode voltage input
VOCM2
11
8
I
Channel 2, common-mode voltage input
VS1–
21, 22
16
I
Channel 1, negative power-supply input
VS2–
15.16
12
I
Channel 2, negative power-supply input
VS1+
3,4
13
I
Channel 1, positive power-supply input
VS2+
9.10
9
I
Channel 2, positive power-supply input
(1)
4
NO.
RTW(1)
Solder the exposed thermal pad (RTW package) to a heat-spreading power or ground plane. This pad is electrically isolated from the
die, but must be connected to a power or ground plane and not floated.
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6 Specifications
6.1 Absolute Maximum Ratings
over operating free-air temperature range (unless otherwise noted)(1)
MIN
MAX
UNIT
5.5
V
Supply voltage, (VS+) – (VS–)
Supply turn-on, turn-off maximum
Voltage
dV/dT(2)
1
V/µs
(VS+) + 0.5
V
Differential input voltage
±1
V
Continuous input current
±10
Continuous output current(3)
±20
Input/output voltage range
Current
(VS–) – 0.5
See Section 6.4 and
Section 10.1
Continuous power dissipation
Maximum junction
Temperature
(1)
(2)
(3)
mA
150
Operating free-air, TA
–40
125
Storage, Tstg
–65
150
°C
Stresses beyond those listed under Absolute Maximum Ratings may cause permanent damage to the device. These are stress
ratings only, which do not imply functional operation of the device at these or any other conditions beyond those indicated under
Recommended Operating Conditions. Exposure to absolute-maximum-rated conditions for extended periods may affect device
reliability.
Staying below this ± supply turn-on edge rate ensures that the edge-triggered ESD absorption device across the supply pins remains
off.
Long-term continuous current for electro-migration limits.
6.2 ESD Ratings
VALUE
UNIT
A. THS4552 in PW Pacakges
V(ESD)
Electrostatic discharge
Human body model (HBM), per ANSI/ESDA/JEDEC JS-001(1)
±2500
Charged device model (CDM), per JEDEC specification JESD22-C101(2)
±1250
Human body model (HBM), per ANSI/ESDA/JEDEC JS-001(1) (3)
±1000
V
B. THS4552 in RTW Package
V(ESD)
(1)
(2)
(3)
Electrostatic discharge
Charged device model (CDM), per JEDEC specification
JESD22-C101(2)
V
±1250
JEDEC document JEP155 states that 500-V HBM allows safe manufacturing with a standard ESD control process.
JEDEC document JEP157 states that 250-V CDM allows safe manufacturing with a standard ESD control process.
ESD limit of ±1000 V for any pin to thermal pad. Pin-to-pin HBM ESD specifications are rated at ±2500 V.
6.3 Recommended Operating Conditions
over operating free-air temperature range (unless otherwise noted)
MIN
NOM
MAX
VS+
Single-supply positive voltage
2.7
5
5.4
UNIT
V
TA
Ambient temperature
–40
25
125
°C
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6.4 Thermal Information
THS4552
THERMAL METRIC(1)
RTW(2)
(VQFN)
PW
(TSSOP)
UNIT
24 PINS
16 PINS
RθJA
Junction-to-ambient thermal resistance
46.0
117.2
°C/W
RθJC(top)
Junction-to-case (top) thermal resistance
34.6
48.8
°C/W
RθJB
Junction-to-board thermal resistance
19.7
70.2
°C/W
ψJT
Junction-to-top characterization parameter
10.0
21.1
°C/W
ψJB
Junction-to-board characterization parameter
19.7
69.8
°C/W
RθJC(bot)
Junction-to-case (bottom) thermal resistance
12.9
N/A
°C/W
(1)
(2)
For more information about traditional and new thermal metrics, see the Semiconductor and IC Package Thermal Metrics application
report.
Thermal impedance for RTW reported with backside thermal pad soldered to heat spreading plane.
6.5 Electrical Characteristics: (VS+) – (VS–) = 5 V
at TA ≈ 25°C, VOCM pin = open, RF = 1 kΩ, RL = 1 kΩ, VOUT = 2 VPP, 50 Ω input match, G = 1 V/V, PD = VS+, single-ended
input, differential output, and input and output referenced to default midsupply for ac-coupled tests (unless otherwise noted);
specifications are per channel; see Figure 7-1 for a gain of 1-V/V test circuit
PARAMETER
TEST CONDITIONS
MIN
TYP
MAX
UNIT
TEST
LEVEL(1)
AC PERFORMANCE
VOUT = 20 mVPP, G = 1, peaking (< 1.0 dB)
SSBW
Small-signal bandwidth
150
C
MHz
VOUT = 20 mVPP, G = 2
75
VOUT = 20 mVPP, G = 10
15
C
135
MHz
C
C
GBP
Gain-bandwidth product
VOUT = 20 mVPP, G = 100
LSBW
Large-signal bandwidth
VOUT = 2 VPP, G = 1
37
MHz
C
Bandwidth for 0.1-dB flatness
VOUT = 2 VPP, G = 1
15
MHz
C
SR
Slew rate(2)
VOUT = 4 VPP, full-power bandwidth (FPBW),
RL = 1 kΩ
220
V/µs
C
tR, tF
Rise and fall time
VOUT = 0.5 V step, G = 1, input tR = 2 ns
ns
C
tSETTLE
Settling time
Overshoot and undershoot
HD2
HD3
Second-order harmonic distortion
Third-order harmonic distortion
6
To 0.1%, VOUT = 0.5 V step, input tR = 2 ns, G = 1
30
To 0.01%,VOUT = 0.5 V step, input tR = 2 ns, G = 1
50
VOUT = 0.5 V step G = 1, input tR = 2 ns
ns
8%
f = 100 kHz, VOUT = 2 VPP, G = 1, RL = 1 kΩ
–128
f = 100 kHz, VOUT = 8 VPP, G = 1, RL = 1 kΩ
–124
f = 100 kHz, VOUT = 2 VPP, G = 1, RL = 1 kΩ
–139
f = 100 kHz, VOUT = 8 VPP, G = 1, RL = 1 kΩ
–131
C
C
C
dBc
dBc
C
C
C
C
Input voltage noise
f > 500 Hz, 1/f < 150 Hz
3.3
nV/√ Hz
C
Input current noise
f > 20 kHz, 1/f 90 dB CMRR at input
range limits
TA = 25°C
(VS–) – 0.2 (VS–) – 0.1
TA = –40°C to +125°C
(VS–) – 0.1
Common-mode input, high
> 90-dB CMRR at input
range limits
TA = 25°C
(VS+) – 1.2 (VS+) – 1.1
TA = –40°C to +125°C
(VS+) – 1.3 (VS+) – 1.2
Common-mode rejection ratio
Input pins at [(VS+) – (VS–)] / 2
DC PERFORMANCE (continued)
IOS
Input offset current
A
nA
B
B
B
INPUT
CMRR
93
Input impedance differential mode Input pins at [(VS+) – (VS–)] / 2
VS–
V
V
110
100 || 1.2
A
B
A
B
dB
A
kΩ || pF
C
OUTPUT
TA = 25°C
(VS–) + 0.2
Output voltage, low
TA = –40°C to +125°C
Output voltage, high
TA = –40°C to +125°C
Linear output current
(VS–) +
0.22
(VS+) –
(VS+) – 0.2
0.23
TA = 25°C
Continuous output current
(VS–) + 0.2
(VS–) +
0.23
±60
TA = –40°C to +125°C, ±2.1 V, RL= 40 Ω,
VOCM offset < ±20 mV
±50
TA = 25°C, ±2.1 V, RL= 50 Ω, AOL > 80 dB
±40
B
A
V
(VS+) –
(VS+) – 0.2
0.22
TA = 25°C, ±2.5 V, RL= 40 Ω,
VOCM offset < ±20 mV
A
V
B
±65
A
mA
B
±45
A
mA
TA = –40°C to +125°C, ±1.6 V, RL= 50 Ω,
AOL > 80 dB
±30
2.7
5
5.4
TA ≈ 25°C(6), VS+ = 5 V
1.28
1.37
1.44
TA = –40°C to +125°C, VS+ = 5 V
0.97
Supply current at maximum
operating supply per channel
TA = 25°C, VS+ = 5.4 V
1.33
1.36
1.46
mA
D
Quiescent current temperature
coefficient per channel
VS+ = 5 V
2.4
3.9
5.4
µA/°C
B
Either supply pin to differential VOUT
93
110
dB
A
V
A
V
A
B
POWER SUPPLY
Specified operating voltage
IQ
dIQ/dT
Quiescent operating current per
channel
±PSRR Power-supply rejection ratio
1.92
V
mA
B
A
B
POWER-DOWN
Enable voltage threshold
Specified on above (VS–) + 1.15 V
Disable voltage threshold
Specified off below (VS–) + 0.55 V
(VS–) + 1.15
(VS–) + 0.55
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6.5 Electrical Characteristics: (VS+) – (VS–) = 5 V (continued)
at TA ≈ 25°C, VOCM pin = open, RF = 1 kΩ, RL = 1 kΩ, VOUT = 2 VPP, 50 Ω input match, G = 1 V/V, PD = VS+, single-ended
input, differential output, and input and output referenced to default midsupply for ac-coupled tests (unless otherwise noted);
specifications are per channel; see Figure 7-1 for a gain of 1-V/V test circuit
MIN
TYP
MAX
UNIT
TEST
LEVEL(1)
–100
±10
100
nA
A
Disable logic at (VS–) + 0.55 V
–2
1
5
Disable logic at (VS–)
–2
1
5
PARAMETER
TEST CONDITIONS
Disable pin bias current
PD = VS– → VS+
Power-down quiescent current
µA
A
A
tON
Turn-on time delay
Time from PD = low to VOUT = 90% of final value
700
ns
C
tOFF
Turn-off time delay
Time from PD = low to VOUT = 10% of final value
100
ns
C
40
MHz
C
OUTPUT COMMON-MODE VOLTAGE (VOCM) CONTROL(4) (see Figure 7-5)
SSBW
Small-signal bandwidth
VOCM = 100 mVPP at the control pin
LSBW
Large-signal bandwidth
VOCM = 1 VPP at the control pin
8
MHz
C
SR
Slew rate(2)
From 1-VPP LSBW
18
V/µs
C
Output common-mode noise
(≥ 2 kHz)
VOCM pin driven from low impedance
15
nV/√ Hz
C
Gain
VOCM control pin input to output average voltage
(see Figure 7-5)
Input bias current
DC output balance (differential
mode to common-mode output)
SSBW
Output balance
LSBW
0.997
0.999
1.001
V/V
A
–100
±10
100
nA
A
dB
C
VOUT = ±1 V
85
VOUT = 100 mVPP (output balance drops –3 dB from
the 85-dB dc level)
300
VOUT = 2 VPP (output balance drops –3 dB from the
85-dB dc level)
300
Input impedance
(VOCM pin input)
VOCM pin open
Default voltage offset drift from
[(VS+) – (VS–)] / 2
TA = –40°C to +125°C
TA = 25°C
VOCM pin driven to [(VS+)
– (VS–)] / 2
Common-mode offset voltage
drift(3)
TA = –40°C to +125°C
Common-mode headroom to
negative supply –PSRR test
(supply to VOD)
–PSRR > 80 dB
TA = 0°C to +70°C
Common-mode headroom to
positive supply +PSRR test
(supply to VOD)
(1)
(2)
(3)
8
mV
A
15
35
55
µA/°C
B
–5.0
±1
5.0
TA = –40°C to +85°C
–5.7
5.6
TA = –40°C to +125°C
–5.7
6.0
–10
±2
10
< ±15 mV shift from midsupply CM VOS
0.6
0.65
TA = –40°C to +125°C
0.7
+PSRR > 80 dB
1.2
TA = 0°C to 70°C
A
mV
TA = –40°C to +85°C
1.3
TA = –40°C to +125°C
1.3
B
µV/°C
B
V
D
A
V
B
B
B
V
1.2
1.25
B
B
0.55
TA = –40°C to +85°C
TA = 25°C
Common-mode loop supply
headroom to positive supply
15
0.55
< ±15 mV shift from
midsupply CM VOS
C
±2
5.5
TA = 0°C to +70°C
kΩ || pF
–15
–5.25
TA = 25°C
Common-mode loop supply
headroom to negative supply
C
150 || 7
Default voltage offset from
[(VS+) – (VS–)] / 2
CM VOS Common-mode offset voltage
C
kHz
D
A
V
B
B
B
Test levels (all values set by characterization and simulation): (A) 100% tested at TA ≈ 25°C. (B) Not tested in production; limits set by
characterization and simulation. (C) Typical value only for information.
This slew rate is the average of the rising and falling time estimated from the sinusoidal large-signal bandwidth as: (VP / √ 2) × 2π ×
f–3dB.
Input offset voltage drift, input bias current drift, and input offset current drift are the mean ±1-sigma values calculated by taking
measurements at the maximum-range ambient temperature end points, computing the difference, and dividing by the temperature
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(4)
(5)
(6)
SBOS831B – DECEMBER 2016 – REVISED JUNE 2021
range. Maximum drift specifications are set by mean ±4 σ on the device distributions tested over a –40°̊C to +125°̊C ambient
temperature range. Drift is not specified by final ATE testing or QA sample test.
Specifications are from the input VOCM pin to the differential output average voltage.
Currents out of pin are treated as a positive polarity (with the exception of the power-supply pins).
TA = 25°C and ICC ≈ 1.37 mA. The test limit is expanded for the ATE ambient range of 22°C to 32°C with a 4 µA/°C ICC temperature
coefficient considered; see Figure 10-1.
6.6 Electrical Characteristics: (VS+) – (VS–) = 3 V
at TA ≈ 25°C, VOCM pin = open, RF = 1 kΩ, RL = 1 kΩ, VOUT = 2 VPP, 50 Ω input match, G = 1 V/V, PD = VS+, single-ended
input, differential output, and input and output referenced to default midsupply for ac-coupled tests (unless otherwise noted);
specifications are per channel; see Figure 7-1 for a gain of 1-V/V test circuit
PARAMETER
TEST CONDITIONS
MIN
TYP
MAX
UNIT
TEST
LEVEL(1)
AC PERFORMANCE
VOUT = 20 mVPP, G = 1, peaking (< 1.0 dB)
150
Small-signal bandwidth
VOUT = 20 mVPP, G = 10
14
GPB
Gain-bandwidth product
VOUT = 20 mVPP, G = 100
130
MHz
C
LSBW
Large-signal bandwidth
VOUT = 1 VPP, G = 1
45
MHz
C
Bandwidth for 0.1-dB flatness
VOUT = 1 VPP, G = 1
14
MHz
C
SR
Slew rate(2)
VOUT = 1 VPP, FPBW, G = 1
110
V/µs
C
tR, tF
Rise and fall time
VOUT = 0.5 V step, G = 1, input tR = 4 ns
7.0
ns
C
To 0.1%, VOUT = 0.5 V step, input tR = 4 ns, G = 1
35
To 0.01%, VOUT = 0.5 V step, input tR = 4 ns, G = 1
55
tSETTLE
Settling time
Overshoot and undershoot
HD2
HD3
Second-order harmonic distortion
Third-order harmonic distortion
VOUT = 20 mVPP, G = 2
C
SSBW
80
VOUT = 0.5 V step, G = 1, input tR = 4 ns
MHz
C
ns
7%
f = 100 kHz, VOUT = 2 VPP, G = 1, RL = 1 kΩ
–128
f = 100 kHz, VOUT = 4 VPP, G = 1, RL = 1 kΩ
–127
f = 100 kHz, VOUT = 2 VPP, G = 1, RL = 1 kΩ
–139
f = 100 kHz, VOUT = 4 VPP, G = 1, RL = 1 kΩ
–125
C
C
C
C
dBc
dBc
C
C
C
C
Input voltage noise
f > 500 Hz, 1/f < 150 Hz
3.4
nV/√ Hz
C
Input current noise
f > 20 kHz, 1/f < 10 kHz
0.5
pA/√ Hz
C
Overdrive recovery time
G = 2, 2X output overdrive, dc coupled
100
ns
C
Closed-loop output impedance
f = 100 kHz (differential), G = 1
0.02
Ω
C
Channel-to-channel crosstalk
2-VPP output on one channel, 1 MHz
–80
dBc
C
dB
A
DC PERFORMANCE(5)
AOL
VIO
Open-loop voltage gain
100
120
TA = 25°C
–175
±40
TA = 0°C to +70°C
–225
265
TA = –40°C to +85°C
–295
295
TA = –40°C to +125°C
–295
375
Input offset voltage drift(3)
TA = –40°C to +125°C (PW package)
–2.0
Channel-to-channel input offset
voltage mismatch
TA = 25°C (PW package)
–250
Input offset voltage drift mismatch
TA = –40°C to +125°C (PW package)
–2.6
Input-referred offset voltage
±2 V differential to 1 kΩ differential load
TA = 25°C
IIB
Input bias current
(positive current out-of-node)
Input bias current
drift(3)
±0.45
1.0
175
B
B
B
250
µV
A
2.6
µV/°C
B
1.5
TA = –40°C to +85°C
1.80
TA = –40°C to +125°C
2.0
3.3
B
µV/°C
1.73
2
µV
2.0
TA = 0°C to +70°C
TA = –40°C to +125°C
A
5.5
A
µA
B
B
B
nA/°C
B
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SBOS831B – DECEMBER 2016 – REVISED JUNE 2021
6.6 Electrical Characteristics: (VS+) – (VS–) = 3 V (continued)
at TA ≈ 25°C, VOCM pin = open, RF = 1 kΩ, RL = 1 kΩ, VOUT = 2 VPP, 50 Ω input match, G = 1 V/V, PD = VS+, single-ended
input, differential output, and input and output referenced to default midsupply for ac-coupled tests (unless otherwise noted);
specifications are per channel; see Figure 7-1 for a gain of 1-V/V test circuit
PARAMETER
TEST CONDITIONS
UNIT
TEST
LEVEL(1)
MIN
TYP
MAX
TA = 25°C
–50
±10
50
TA = 0°C to +70°C
–57
63
TA = –40°C to +85°C
–68
67
TA = –40°C to +125°C
–68
78
input offset current mismatch
TA = 25°C
–65
65
nA
D
Input offset current drift(3)
TA = –40°C to +125°C (PW package)
–240
±20
240
pA/°C
B
Offset current drift mismatch
TA = –40°C to +125°C (PW package)
–260
±20
260
pA/°C
B
Common-mode input, low
> 87 dB CMRR at input
range limits
TA = 25°C
(VS–) – 0.2 (VS–) – 0.1
TA = –40°C to +125°C
(VS–) – 0.1
Common-mode input, high
> 87 dB CMRR at input
range limits
TA = 25°C
(VS+) – 1.2
(VS+) –1.1
TA = –40°C to +125°C
(VS+) – 1.3
(VS+) –1.2
Common-mode rejection ratio
Input pins at [(VS+) – (VS–)] / 2
90
110
DC PERFORMANCE (continued)
IOS
Input offset current
A
nA
B
B
B
INPUT
CMRR
Input impedance differential mode Input pins at [(VS+) – (VS–)] / 2
VS–
V
V
100 || 1.2
A
B
A
B
dB
A
kΩ || pF
C
OUTPUT
TA = 25°C
VOL
(VS–) + 0.2
Output voltage, low
TA = –40°C to +125°C
(VS–) + 0.2
Output voltage, high
Linear output current
±1.5 V, RL = 40 Ω,
VOCM offset < ±20 mV
TA = 25°C
±1.3 V, RL = 40 Ω,
VOCM offset < ±20 mV
TA = –40°C to +125°C
±30
±1.5 V, RL = 50 Ω,
AOL > 80 dB
TA = 25°C
±28
±1.1 V, RL = 50 Ω,
AOL > 80 dB
TA = –40°C to +125°C
±35
A
V
B
A
V
(VS+) –
(VS+) – 0.2
0.22
TA = –40°C to +125°C
Continuous output current
(VS–) +
0.22
(VS+) –
(VS+) – 0.2
0.21
TA = 25°C
VOH
(VS–) +
0.21
B
±40
A
mA
B
±35
A
mA
±20
B
POWER SUPPLY
Specified operating voltage
IQ
dIQ/dT
2.7
3
5.4
TA ≈ 25°C(6), VS+ = 3 V
1.24
1.31
1.40
TA = –40°C to +125°C, VS+ = 3 V
0.96
Supply current at minimum
operating supply per channel
TA = 25°C, VS+ = 2.7 V
1.24
1.28
1.38
mA
D
Quiescent current temperature
coefficient per channel
VS+ = 3 V
2.0
3.4
5.0
µA/°C
B
Either supply pin to differential VOUT
90
105
dB
A
V
A
Quiescent operating current per
channel
±PSRR Power-supply rejection ratio
1.84
V
mA
B
A
B
POWER-DOWN
Enable voltage threshold
Specified on above (VS–) + 1.15 V
Disable voltage threshold
Specified off below (VS–) + 0.55 V
Disable pin bias current
PD = VS– → VS+
(VS–) + 1.15
(VS–) + 0.55
V
A
–100
±10
100
nA
A
–2
1
5
µA
A
IQ(PD)
Power-down quiescent current
tON
Turn-on time delay
Time from PD = low to VOUT = 90% of final value
750
ns
C
tOFF
Turn-off time delay
Time from PD = low to VOUT = 10% of final value
150
ns
C
10
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SBOS831B – DECEMBER 2016 – REVISED JUNE 2021
6.6 Electrical Characteristics: (VS+) – (VS–) = 3 V (continued)
at TA ≈ 25°C, VOCM pin = open, RF = 1 kΩ, RL = 1 kΩ, VOUT = 2 VPP, 50 Ω input match, G = 1 V/V, PD = VS+, single-ended
input, differential output, and input and output referenced to default midsupply for ac-coupled tests (unless otherwise noted);
specifications are per channel; see Figure 7-1 for a gain of 1-V/V test circuit
PARAMETER
TEST CONDITIONS
MIN
UNIT
TEST
LEVEL(1)
40
MHz
C
8
MHz
C
C
TYP
MAX
OUTPUT COMMON-MODE VOLTAGE (VOCM) CONTROL(4) (see Figure 7-5)
SSBW
Small-signal bandwidth
VOCM = 100 mVPP at the control pin
LSBW
Large-signal bandwidth
VOCM = 1 VPP at the control pin
SR
Slew rate(2)
From 1-VPP LSBW
12
V/µs
Output common-mode noise
VOCM pin driven from low impedance, f ≥ 2 kHz
15
nV/√ Hz
Gain
VOCM control pin input to output average voltage
(see Figure 7-5)
DC output balance (differential
mode to common-mode output)
VOUT = ±1 V
SSBW
Output balance
LSBW
0.997
300
TA = –40°C to +125°C
TA = 25°C
VOCM input driven to [(VS+) TA = 0°C to +70°C
– (VS–)] / 2
TA = –40°C to +85°C
TA = –40°C to +125°C
Common-mode offset voltage
drift(3)
VOCM input driven to [(VS+) – (VS–)] / 2
Common-mode headroom to
negative supply –PSRR test
(supply to VOD)
–PSRR > 80 dB
< ±15 mV shift from midsupply CM VOS
TA = 0°C to +70°C
(2)
(3)
(4)
(5)
(6)
100
< ±15 mV shift from midsupply CM VOS
A
kΩ || pF
C
±2
15
mV
A
15
35
55
µA/°C
B
–5.0
±1
5.0
–5.25
5.5
–5.7
5.6
–5.7
6.0
–10
±2
10
A
mV
0.6
0.7
0.55
TA = –40°C to +85°C
1.3
TA = –40°C to +125°C
1.3
B
µV/°C
B
V
C
A
V
B
B
B
V
1.2
1.25
B
B
0.55
TA = –40°C to +125°C
TA = 0°C to +70°C
nA
–15
0.65
TA = 25°C
(1)
±10
TA = –40°C to +85°C
+PSRR > 80 dB
C
C
0.55
TA = 25°C
A
C
150 || 7
Default voltage offset drift from
[(VS+) – (VS–)] / 2
V/V
kHz
–100
VOCM pin open
Common-mode loop supply
headroom to positive supply
dB
VOUT = 1 VPP (output balance drops –3 dB from the
85 dB dc level)
Default voltage offset from
[(VS+) – (VS–)] / 2
Common-mode headroom to
positive supply +PSRR test
(supply to VOD)
85
300
Input impedance
Common-mode loop supply
headroom to negative supply
1.001
VOUT = 100 mVPP (output balance drops –3 dB from
the 85 dB dc level)
Input bias current
CM VOS Common-mode offset voltage
0.999
C
A
V
B
B
B
Test levels (all values set by characterization and simulation): (A) 100% tested at TA ≈ 25°C. (B) Not tested in production; limits set by
characterization and simulation. (C) Typical value only for information.
This slew rate is the average of the rising and falling time estimated from the large-signal bandwidth as: (VPP / √ 2) × 2π × f–3dB.
Input offset voltage drift, input bias current drift, and input offset current drift are the mean ±1-sigma values calculated by taking
measurements at the maximum-range ambient temperature end points, computing the difference, and dividing by the temperature
range. Maximum drift specifications are set by mean ±4 σ on the device distributions tested over a –40°̊C to +125°̊C ambient
temperature range. Drift is not specified by final ATE testing or QA sample test.
Specifications are from input VOCM pin to differential output average voltage.
Currents out of pin are treated as a positive polarity.
TA = 25°C and ICC ≈ 1.31 mA. The test limit is expanded for the ATE ambient range of 22°C to 32°C with a 4 µA/°C ICC temperature
coefficient considered; see Figure 10-1.
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SBOS831B – DECEMBER 2016 – REVISED JUNE 2021
6.7 Typical Characteristics: (VS+) – (VS–) = 5 V
at TA ≈ 25°C, VOCM pin = open, RF = 1 kΩ, RL = 1 kΩ, VOUT = 2 VPP, 50 Ω input match, G = 1 V/V, PD = VS+, single-ended
input, differential output, and input and output referenced to default midsupply for ac-coupled tests (unless otherwise noted);
see Figure 7-1 for a gain of 1 V/V test circuit
9
3
1
3
-1
0
Gain (dB)
Normalized Gain (dB)
2
6
0
-3
-6
-9
100k
-3
-4
VOUT = 20 mVpp
VOUT = 200 mVpp
VOUT = 1 Vpp
VOUT = 2 Vpp
VOUT = 4 Vpp
VOUT = 8 Vpp
-5
G = 0.1 V/V
G = 1 V/V
G = 2 V/V
G = 5 V/V
G = 10 V/V
1M
-2
-6
-7
-8
10M
Frequency (Hz)
-9
100k
100M
1M
D001
VOUT = 20 mVPP, see Figure 7-1 and Table 8-1 for resistor
values
10M
Frequency (Hz)
100M
D002
See Figure 7-1
Figure 6-2. Frequency Response vs VOUT
Figure 6-1. Small-Signal Frequency Response vs Gain
6
3
2
1
3
0
0
Gain (dB)
Gain (dB)
-1
-2
-3
-4
-5
-6
-7
-8
-9
100k
VOCM = 0.8 V
VOCM = 1 V
VOCM = 1.5 V
VOCM = 2 V
VOCM = 3 V
VOCM = 3.5 V
1M
-3
-6
RL = 50 :
RL = 100 :
RL = 200 :
RL = 500 :
RL = 1000 :
-9
10M
Frequency (Hz)
-12
100k
100M
D003
VOUT = 20 mVPP , see Figure 7-1 with VOCM adjusted
Figure 6-3. Small-Signal Frequency Response vs VOCM
1M
10M
Frequency (Hz)
100M
D004
VOUT = 20 mVPP, see Figure 7-1 with load resistance (RL)
adjusted
Figure 6-4. Small-Signal Frequency Response vs RL
3
100
2
90
-1
-2
-3
-4
-5
-6
-7
-8
-9
100k
G = 1 V/V
G = 2 V/V
G = 5 V/V
G = 10 V/V
80
0
RO in each output (:)
Normalized Gain (dB)
1
CL = 10 pF, RO = 97.6 :
CL = 47 pF, RO = 49.9 :
CL = 100 pF, R O = 32.4 :
CL = 470 pF, R O = 10.0 :
CL = 1000 pF, R O = 4.7 :
70
60
50
40
30
20
10
0
1M
10M
Frequency (Hz)
1
100M
D005
VOUT = 20 mVPP at load, G = 1, two series RO added at output
before capacitive load (CL)
1000
D006
Output resistance (RO) is two series output resistors to a
differential CL in parallel with a 1 kΩ load resistance
Figure 6-5. Small-Signal Frequency Response vs CL
12
10
100
Differential CL (pF)
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Figure 6-6. Recommended RO vs CL
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SBOS831B – DECEMBER 2016 – REVISED JUNE 2021
6.7 Typical Characteristics: (VS+) – (VS–) = 5 V (continued)
at TA ≈ 25°C, VOCM pin = open, RF = 1 kΩ, RL = 1 kΩ, VOUT = 2 VPP, 50 Ω input match, G = 1 V/V, PD = VS+, single-ended
input, differential output, and input and output referenced to default midsupply for ac-coupled tests (unless otherwise noted);
see Figure 7-1 for a gain of 1 V/V test circuit
1.2
0.5
1
0.4
RO = 0 :
RO = 75 :
0.3
0.6
Differential Output (V)
Differential Output (V)
0.8
0.4
0.2
0
-0.2
-0.4
-0.6
0.2-V step, tR = 1 ns
0.5-V step, tR = 2 ns
1-V step, tR = 4 ns
2-V step, tR = 8 ns
-0.8
-1
0.2
0.1
0
-0.1
-0.2
-0.3
-0.4
-1.2
-0.5
0
20
40
60
80
100 120
Time (ns)
140
160
180
200
0
20
40
60
80
D007
G = 1 V/V, 5 MHz input, single-ended to differential output
100 120
Time (ns)
140
180
200
D008
G = 1 V/V, VOUT = 500 mV step into 22 pF CL, see Figure 7-4
Figure 6-7. Small- and Large-Signal Step Response
Figure 6-8. Step Response Into Capacitive Load
0.5
1.5
RO = 0 :
RO = 46.4 :
0.4
1
0.3
Differential Output (V)
Differential Output (V)
160
0.5
0
-0.5
0.2-V step, tR = 1 ns
0.5-V step, tR = 1 ns
1-V step, tR = 2 ns
2-V step, tR = 5 ns
-1
0.2
0.1
0
-0.1
-0.2
-0.3
-0.4
-1.5
-0.5
0
20
40
60
80
100 120
Time (ns)
140
160
180
200
0
20
40
60
D009
G = 2 V/V, 5 MHz input, single-ended input to differential
output
80
100 120
Time (ns)
140
160
180
200
D010
G = 2 V/V, VOUT = 500 mV step into 22 pF CL, see Figure 7-4
Figure 6-10. Step Response Into Capacitive Load
Figure 6-9. Small- and Large-Signal Step Response
10
0.2-V step, tR = 1 ns
1-V step, tR = 4 ns
2-V step, tR = 8 ns
0.15
Error to Final Value (%)
Input and Differential Output Voltage (V)
0.2
0.1
0.05
0
-0.05
-0.1
-0.15
Input
Output
8
6
4
2
0
-2
-4
-6
-8
-10
-0.2
0
10
20
30
40
50
Time ' from 50% of Input Edge (ns)
60
70
0
D011
Simulated with G = 1 V/V
0.1
0.2
0.3
0.4 0.5 0.6
Time (Ps)
0.7
0.8
0.9
1
D012
Single-ended to differential gain of 2, 2X input overdrive
Figure 6-11. Small- and Large-Signal Step Settling Time
Figure 6-12. Overdrive Recovery Performance
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SBOS831B – DECEMBER 2016 – REVISED JUNE 2021
6.7 Typical Characteristics: (VS+) – (VS–) = 5 V (continued)
at TA ≈ 25°C, VOCM pin = open, RF = 1 kΩ, RL = 1 kΩ, VOUT = 2 VPP, 50 Ω input match, G = 1 V/V, PD = VS+, single-ended
input, differential output, and input and output referenced to default midsupply for ac-coupled tests (unless otherwise noted);
see Figure 7-1 for a gain of 1 V/V test circuit
-70
-50
HD2
HD3
-60
HD2, 100 kHz
HD3, 100 kHz
HD2, 1 MHz
HD3, 1 MHz
-80
-70
Distortion (dBc)
Distortion (dBc)
-90
-80
-90
-100
-110
-100
-110
-120
-120
-130
-130
-140
-140
-150
10k
100k
1M
Frequency (Hz)
-150
0.1
10M
D013
G = 1 V/V, VOUT = 2 VPP
1
Differential Output Voltage (Vpp)
D014
G = 1 V/V
Figure 6-13. Harmonic Distortion vs Frequency
Figure 6-14. Harmonic Distortion vs Output Swing
-40
-60
Max IMD3
Max IMD2
-45
HD2, 100 kHz
HD3, 100 kHz
HD2, 1 MHz
HD3, 1 MHz
-70
-50
-80
-55
Distortion (dBc)
Spurious Level (dBc)
10
-60
-65
-70
-90
-100
-110
-75
-120
-80
-130
-85
-90
1M
-140
50
10M
Frequency (Hz)
D015
-20
-105
HD2, 10 kHz
HD2, 100 kHz
HD2, 1 MHz
HD3, 10 kHz
HD3, 100 kHz
HD3, 1 MHz
-60
HD2, 100 kHz
HD3, 100 kHz
-110
-115
Distortion (dBc)
-40
Distortion (dBc)
D016
Figure 6-16. Harmonic Distortion vs RL
Figure 6-15. Intermodulation Distortion (IMD2 and IMD3) vs
Frequency
-80
-100
-120
-120
-125
-130
-135
-140
-140
-145
1.5
2.5
VOCM - (VS-) (V)
3.5
4.5
1
Figure 6-17. Harmonic Distortion vs VOCM
10
Gain (V/V)
D017
G = 1 V/V, VOUT = 2 VPP, with VOCM adjusted
14
1000
G = 1 V/V, VOUT = 2 VPP, with RL adjusted
G = 1 V/V, VOUT = 1 VPP each tone
-160
0.5
100
Differential Load Resistance (:)
D018
VOUT = 2 VPP, see Table 8-1 for gain setting
Figure 6-18. Harmonic Distortion vs Gain
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SBOS831B – DECEMBER 2016 – REVISED JUNE 2021
6.8 Typical Characteristics: (VS+) – (VS–) = 3 V
at TA ≈ 25°C, VOCM pin = open, RF = 1 kΩ, RL = 1 kΩ, VOUT = 2 VPP, 50 Ω input match, G = 1 V/V, PD = VS+, single-ended
input, differential output, and input and output referenced to default midsupply for ac-coupled tests (unless otherwise noted);
see Figure 7-1 for a gain of 1 V/V test circuit
3
9
1
3
-1
0
Gain (dB)
Normalized Gain (dB)
2
6
0
-3
-6
-9
100k
-3
-4
-5
G = 0.1 V/V
G = 1 V/V
G = 2 V/V
G = 5 V/V
G = 10 V/V
1M
-2
VOUT = 20 mVpp
VOUT = 200 mVpp
VOUT = 1 Vpp
VOUT = 2 Vpp
VOUT = 4 Vpp
-6
-7
-8
10M
Frequency (Hz)
-9
100k
100M
D019
1M
VOUT = 20 mVPP, see Figure 7-1 and Table 8-1 for resistor
values
10M
Frequency (Hz)
100M
D020
See Figure 7-1
Figure 6-20. Frequency Response vs VOUT
Figure 6-19. Small-Signal Frequency Response vs Gain
6
3
2
1
3
0
0
Gain (dB)
Gain (dB)
-1
-2
-3
-4
-5
-3
-6
RL = 50 :
RL = 100 :
RL = 200 :
RL = 500 :
RL = 1000 :
-6
-7
-8
-9
100k
VOCM = 0.8 V
VOCM = 1 V
VOCM = 1.5 V
1M
-9
10M
Frequency (Hz)
-12
100k
100M
D021
D003
VOUT = 20 mVPP, see Figure 7-1 with VOCM adjusted
110
1
100
0
90
RO in each output (:)
Normalized Gain (dB)
120
2
-1
-2
-3
-4
-7
-8
-9
100k
100M
D022
Figure 6-22. Small-Signal Frequency Response vs RL
3
-6
10M
Frequency (Hz)
VOUT = 20 mVPP, see Figure 7-1 with RL adjusted
Figure 6-21. Small-Signal Frequency Response vs VOCM
-5
1M
CL = 10 pF, RO = 113 :
CL = 47 pF, RO = 54.9 :
CL = 100 pF, R O = 34.0 :
CL = 470 pF, R O = 10.5 :
CL = 1000 pF, R O = 5.1 :
G = 1 V/V
G = 2 V/V
G = 5 V/V
G = 10 V/V
80
70
60
50
40
30
20
10
0
1M
10M
Frequency (Hz)
1
100M
10
100
Differential CL (pF)
D023
VOUT = 20 mVPP, G = 1 V/V, two series RO added at output
before CL
Figure 6-23. Small-Signal Frequency Response vs CL
1000
D024
Two RO at output to differential CL in parallel with a 1 kΩ load
resistance
Figure 6-24. Recommended RO vs CL
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6.8 Typical Characteristics: (VS+) – (VS–) = 3 V (continued)
at TA ≈ 25°C, VOCM pin = open, RF = 1 kΩ, RL = 1 kΩ, VOUT = 2 VPP, 50 Ω input match, G = 1 V/V, PD = VS+, single-ended
input, differential output, and input and output referenced to default midsupply for ac-coupled tests (unless otherwise noted);
see Figure 7-1 for a gain of 1 V/V test circuit
0.5
1.5
RO = 0 :
RO = 82.5 :
0.4
0.3
Differential Output (V)
Differential Output (V)
1
0.5
0
-0.5
0.2-V step, tR = 2 ns
0.5-V step, tR = 4 ns
1-V step, tR = 8 ns
2-V step, tR = 12ns
-1
0.2
0.1
0
-0.1
-0.2
-0.3
-0.4
-1.5
-0.5
0
20
40
60
80
100 120
Time (ns)
140
160
180
200
0
20
40
60
80
D025
G = 1 V/V, 5 MHz input, single-ended input to differential
output
100 120
Time (ns)
140
160
180
200
D026
G = 1 V/V, VOUT = 500 mV step into 22 pF CL, see Figure 7-4
Figure 6-26. Step Response Into Capacitive Load
Figure 6-25. Small- and Large-Signal Step Response
0.5
1.5
0.4
0.3
Differential Output (V)
Differential Output (V)
1
0.5
0
-0.5
0.2-V step, tR = 2 ns
0.5-V step, tR = 2 ns
1-V step, tR = 6 ns
2-V step, tR = 12 ns
-1
0.2
0.1
0
-0.1
-0.2
-0.3
RO = 0 :
RO = 51.1 :
-0.4
-1.5
-0.5
0
20
40
60
80
100 120
Time (ns)
140
160
180
200
0
20
40
60
D027
G = 2 V/V, 5 MHz input, single-ended input to differential
output
80
100 120
Time (ns)
140
160
180
200
D028
G = 2 V/V, VOUT = 500-mV step into 22-pF CL, see Figure 7-4
Figure 6-28. Step Response Into Capacitive Load
Figure 6-27. Small- and Large-Signal Step Response
6
0.2-V step, tR = 2 ns
1-V step, tR = 8 ns
2-V step, tR = 12 ns
0.15
Error to Final Value (%)
Input and Differential Output Voltage (V)
0.2
0.1
0.05
0
-0.05
-0.1
-0.15
2
0
-2
-4
-6
-0.2
0
10
20
30
40
50
Time ' from 50% of Input Edge (ns)
60
70
0
D029
Simulated with G = 1 V/V
0.1
0.2
0.3
0.4 0.5 0.6
Time (Ps)
0.7
0.8
0.9
1
D030
Single-ended to differential gain of 2, 2X input overdrive
Figure 6-29. Small- and Large-Signal Step Settling Time
16
Input
Output
4
Figure 6-30. Overdrive Recovery Performance
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6.8 Typical Characteristics: (VS+) – (VS–) = 3 V (continued)
at TA ≈ 25°C, VOCM pin = open, RF = 1 kΩ, RL = 1 kΩ, VOUT = 2 VPP, 50 Ω input match, G = 1 V/V, PD = VS+, single-ended
input, differential output, and input and output referenced to default midsupply for ac-coupled tests (unless otherwise noted);
see Figure 7-1 for a gain of 1 V/V test circuit
-70
-40
-50
HD2
HD3
HD2, 100 kHz
HD3, 100 kHz
HD2, 1 MHz
HD3, 1 MHz
-80
-60
-90
Distortion (dBc)
Distortion (dBc)
-70
-80
-90
-100
-110
-120
-100
-110
-120
-130
-130
-140
-140
-150
10k
100k
1M
Frequency (Hz)
-150
0.1
10M
D031
G = 1 V/V, VOUT = 2 VPP
D032
Figure 6-32. Harmonic Distortion vs Output Swing
-40
-60
Max IMD3
Max IMD2
HD2, 100 kHz
HD3, 100 kHz
HD2, 1 MHz
HD3, 1 MHz
-70
-50
-80
-55
Distortion (dBc)
Spurious Level (dBc)
4
G = 1 V/V
Figure 6-31. Harmonic Distortion vs Frequency
-45
1
Differential Output Voltage (Vpp)
-60
-65
-70
-90
-100
-110
-75
-120
-80
-130
-85
-90
1M
-140
50
10M
Frequency (Hz)
D033
HD2, 10 kHz
HD2, 100 kHz
HD2, 1 MHz
HD3, 10 kHz
HD3, 100 kHz
HD3, 1 MHz
HD2, 100 kHz
HD3, 100 kHz
-115
Distortion (dBc)
Distortion (dBc)
-110
-90
-110
-130
-150
0.8
D034
Figure 6-34. Harmonic Distortion vs RL
Figure 6-33. IMD2 and IMD3 vs Frequency
-30
-70
1000
G = 1 V/V, VOUT = 2-VPP output, with RL adjusted
G = 1 V/V, 1 VPP each tone
-50
100
Differential Load Resistance (:)
-120
-125
-130
-135
-140
1
1.2
1.4
1.6
VOCM - (VS-) (V)
1.8
2
1
VOUT = 2-VPP output, with VOCM adjusted
10
Gain (V/V)
D035
D036
VOUT = 2-VPP output, see Table 8-1 for gain setting
Figure 6-35. Harmonic Distortion vs VOCM
Figure 6-36. Harmonic Distortion vs Gain
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6.9 Typical Characteristics: 3 V to 5 V Supply Range
at TA ≈ 25°C, VOCM pin = open, RF = 1 kΩ, RL = 1 kΩ, VOUT = 2 VPP, 50 Ω input match, G = 1 V/V, PD = VS+, single-ended
input, differential output, and input and output referenced to default midsupply for ac-coupled tests (unless otherwise noted);
see Figure 7-1 for a gain of 1 V/V test circuit
Open-Loop Gain (dB)
100
70
-100
40
-150
10
-200
-20
10
100
1k
10k
100k
1M
Frequency (Hz)
10M
100M
100
50
Output Impedance (:)
0
+5 V, Gain
+5 V, Phase
+3 V, Gain
-50
+3 V, Phase
Open-Loop Phase (deg)
130
20
10
5
2
1
0.5
0.2
0.1
0.05
0.02
0.01
0.005
0.002
0.001
10k
-250
1G
+5 V, G = 1 V/V
+5 V, G = 2 V/V
+5 V, G = 5 V/V
+3 V, G = 1 V/V
+3 V, G = 2 V/V
+3 V, G = 5 V/V
100k
1M
Frequency (Hz)
D037
Simulated with a 1 kΩ differential load and 0.6 pF internal
feedback capacitors removed
10M
100M
D038
Simulated closed-loop differential output impedance
Figure 6-38. Closed-Loop Output Impedance vs Frequency
Figure 6-37. Main Amplifier Differential Open-Loop Gain and
Phase vs Frequency
90
85
10
80
Output Balance (dB)
Input Spot Voltage (nV/—Hz) and
Current (pA/—Hz) Noise
20
1
+5 V, En
+5 V, In
+3 V, En
+3 V, In
0.1
10
100
75
70
65
60
55
50
45
1k
10k
Frequency (Hz)
100k
+5 V, SSOB
+5 V, 2-VPP OB
+3 V, SSOB
+3 V, 2-VPP OB
40
10k
1M
100k
.
1M
10M
Frequency (Hz)
D039
D040
Differential mode output to common-mode output, simulated
with G = 1 V/V Note: SSOB is equal to a 20 mVPP output
balance (OB).
Figure 6-39. Input Spot Noise vs Frequency
Figure 6-40. Output Balance vs Frequency
120
120
+5 V
+3 V
115
110
100
105
PSRR (dB)
CMRR (dB)
110
100
95
90
80
90
70
85
80
1k
10k
100k
Frequency (Hz)
1M
10M
D041
Common-mode input to differential output, simulated with G =
1 V/V
Figure 6-41. CMRR vs Frequency
18
60
1k
+5 V, VS+
+5 V, VS+3 V, VS+
+3 V, VS10k
100k
Frequency (Hz)
1M
10M
D042
Single-ended to differential gain of 1, PSRR simulated to
differential output
Figure 6-42. Power-Supply Rejection Ratio vs Frequency
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6.9 Typical Characteristics: 3 V to 5 V Supply Range (continued)
at TA ≈ 25°C, VOCM pin = open, RF = 1 kΩ, RL = 1 kΩ, VOUT = 2 VPP, 50 Ω input match, G = 1 V/V, PD = VS+, single-ended
input, differential output, and input and output referenced to default midsupply for ac-coupled tests (unless otherwise noted);
see Figure 7-1 for a gain of 1 V/V test circuit
0.6
3
Output Common Mode Voltage (V)
2
1
0
Gain (dB)
-1
-2
-3
-4
-5
-6
+5 V, 100 mVpp
+5 V, 1 Vpp
+3 V, 100 mVpp
+3 V, 1 Vpp
-7
-8
0.4
0.2
0
-0.2
+5 V, 0.2-V step
+5 V, 1-V step
+3 V, 0.2-V step
+3 V, 1-V step
-0.4
-0.6
-9
100k
1M
10M
0
100M
Frequency (Hz)
0.1
0.2
D043
.
0.5 0.6
Time(Ps)
0.7
0.8
0.9
1
D044
Figure 6-44. Common-Mode Voltage, Small- and Large-Step
Response (VOCM Pin Driven)
1000
3
+3 V, VOCM Pin Driven
+5 V, VOCM Pin Driven
+3 V, VOCM Pin Floating
+5 V, VOCM Pin Floating
Output CM Voltage Offset (mV)
Output Spot Common Mode Noise (nV/—Hz)
0.4
.
Figure 6-43. Common-Mode Voltage, Small- and Large-Signal
Response (VOCM Pin Driven)
100
10
100
0.3
+3 V
+5 V
2
1
0
-1
1k
10k
100k
Frequency (Hz)
1M
10M
0
0.5
1
D045
The VOCM pin is either driven to mid-supply by lowimpedance source or allowed to float and default to midsupply
1.5
2
2.5
VOCM - (VS-) (V)
3
3.5
4
D046
Average VOCM output offset of 39 units, standard deviation < 2
mV
Figure 6-46. VOCM Offset vs VOCM Setting
Figure 6-45. Output Common-Mode Noise vs Frequency
120
120
+5 V
+3 V
110
105
100
95
90
110
105
100
95
90
85
85
80
80
0
1
2
3
VOCM - (VS-) (V)
4
+5 V
+3 V
115
Positive Supply PSRR (dB)
Negative Supply PSRR (dB)
115
5
0
D047
Simulated with single-ended to differential gain of 1, PSRR for
negative supply to differential output
Figure 6-47. –PSRR vs VOCM Approaching VS–
1
2
3
VOCM - (VS-) (V)
4
5
D048
Simulated with single-ended to differential gain of 1, PSRR for
positive supply to differential output
Figure 6-48. +PSRR vs VOCM Approaching VS+
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6.9 Typical Characteristics: 3 V to 5 V Supply Range (continued)
at TA ≈ 25°C, VOCM pin = open, RF = 1 kΩ, RL = 1 kΩ, VOUT = 2 VPP, 50 Ω input match, G = 1 V/V, PD = VS+, single-ended
input, differential output, and input and output referenced to default midsupply for ac-coupled tests (unless otherwise noted);
see Figure 7-1 for a gain of 1 V/V test circuit
400
375
350
325
300
275
250
225
200
175
150
125
100
75
50
25
0
No. of Units in 5 nA Bins
5V
3V
Input Offset Voltage (PV)
Input Offset Current (nA)
D049
D050
Total of 561 PW units trimmed at a 5 V supply
Total of 561 PW units trimmed at a 5 V supply
Figure 6-49. Input Offset Voltage (VIO)
Figure 6-50. Input Offset Current (IOS)
40
120
100
30
Delta from 25°C I OS (nA)
Delta from 25°C V IO (µV)
80
60
40
20
0
-20
-40
-60
-80
-20
0
20
40
60
80
Ambient Temperature (°C)
100
10
0
-10
-20
-40
-40
120
D051
5 V and 3 V delta from 25°C VIO, 52 PW units
20
40
60
80
Ambient Temperature (°C)
100
120
D052
6
5
4
3
2
1
-2
-1.8
-1.6
-1.4
-1.2
-1
-0.8
-0.6
-0.4
-0.2
0
0.2
0.4
0.6
0.8
1
1.2
1.4
1.6
1.8
2
0
D053
–40°C to +125°C endpoint drift, total of 52 PW units
Figure 6-53. Input Offset Voltage Drift Histogram
30
28
26
24
22
20
18
16
14
12
10
8
6
4
2
0
+5 V
+3 V
-300
-275
-250
-225
-200
-175
-150
-125
-100
-75
-50
-25
0
25
50
75
100
125
150
175
200
225
250
275
300
No. of Units in Each 25 pA/°C Bin
+5 V
+3 V
Input Offset Voltage Drift (PV/qC)
0
Figure 6-52. Input Offset Current vs Temperature
8
7
-20
5 V and 3 V delta from 25°C IOS, 52 PW units
Figure 6-51. Input Offset Voltage vs Temperature
No. of Units in Each 0.2 PV/qC Bin
20
-30
-100
-120
-40
20
5V
3V
-50
-45
-40
-35
-30
-25
-20
-15
-10
-5
0
5
10
15
20
25
30
35
40
45
50
-180
-160
-140
-120
-100
-80
-60
-40
-20
0
20
40
60
80
100
120
140
160
180
No. of units in 20 PV Bins
350
325
300
275
250
225
200
175
150
125
100
75
50
25
0
Input Offset Current Drift (pA/qC)
D054
–40°C to +125°C endpoint drift, total of 52 PW units
Figure 6-54. Input Offset Current Drift Histogram
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6.9 Typical Characteristics: 3 V to 5 V Supply Range (continued)
at TA ≈ 25°C, VOCM pin = open, RF = 1 kΩ, RL = 1 kΩ, VOUT = 2 VPP, 50 Ω input match, G = 1 V/V, PD = VS+, single-ended
input, differential output, and input and output referenced to default midsupply for ac-coupled tests (unless otherwise noted);
see Figure 7-1 for a gain of 1 V/V test circuit
2.5
1.6
2
1.4
1.5
0.5
r1.5 V, Pos
r1.5 V, Neg
r2.5 V, Pos
r2.5 V, Neg
0
-0.5
1.2
Supply Current (mA)
Maximum VOUT (V)
1
-1
1
0.8
0.6
0.4
-1.5
0.2
-2
-2.5
50
+3 V
+5 V
0
100
Differential Load Resistance (:)
1000
0
1
D055
2
3
Disable Pin Voltage (V)
Maximum differential output swing, VOCM at mid-supply
+5 V
+3 V
No. of Units in 0.5 mV Bins
No. of Units in 2 mV Bins
140
120
100
80
60
40
20
D057
+3 V, PD
+3 V, VOUT
5
4
3
2
1
0
-1
-2
0
0.2
0.4
0.6
0.8
1
1.2
Time (Ps)
1.4
1.6
1.8
Figure 6-58. Common-Mode Output Offset from Driven VOCM
Histogram
Disable and Differential Output Voltage (V)
Disable and Differential Output Voltage (V)
7
+5 V, PD
+5 V, VOUT
D058
Common Mode Offset Voltage (mV)
VOCM input driven to mid-supply, total of 240 units
Figure 6-57. Common-Mode Output Offset from VS+ / 2 Default
Value Histogram
6
+5 V
+3 V
-4.5
-4
-3.5
-3
-2.5
-2
-1.5
-1
-0.5
0
0.5
1
1.5
2
2.5
3
3.5
4
4.5
Common Mode Offset Voltage (mV)
70
65
60
55
50
45
40
35
30
25
20
15
10
5
0
16
14
12
8
10
6
4
2
0
-2
-4
-6
-8
-10
-12
-14
-16
0
VOCM input floating, total of 240 units
D056
Figure 6-56. Supply Current vs PD Voltage
200
160
5
.
Figure 6-55. ±Maximum VOUT vs Differential Load Resistance
180
4
2
7
+5 V, PD
+5 V, VOUT
+3 V, PD
+3 V, VOUT
6
5
4
3
2
1
0
-1
-2
0
D059
5 MHz, 2 VPP input, G = 1 V/V, see Figure 7-1
0.2
0.4
0.6
0.8
1
1.2
Time (Ps)
1.4
1.6
1.8
2
D060
5 MHz, 2 VPP input, G = 1 V/V, see Figure 7-1
Figure 6-59. PD Turn-On Waveform
Figure 6-60. PD Turn-Off Waveform
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7 Parameter Measurement Information
7.1 Example Characterization Circuits
The THS4552 offers the advantages of a fully differential amplifier (FDA) design with the trimmed input offset
voltage and very low drift of a precision op amp. The FDA is an extremely flexible device where the main aim
is to provide a purely differential output signal centered on a user-configurable common-mode voltage usually
matched to the input common-mode voltage required by an analog-to-digital converter (ADC) following this
stage. The primary options revolve around the choices of single-ended or differential inputs, ac-coupled or dccoupled signal paths, gain targets, and resistor value selections. The characterizations described in this section
focus on single-ended input to differential output designs as the more challenging application requirement.
Differential sources can certainly be supported and are often simpler to both implement and analyze.
The characterization circuits are typically operated with a single-ended, matched, 50 Ω, input termination to a
differential output at the FDA output pins because most lab equipment is single-ended. The FDA differential
output is then translated back to single-ended through a variety of baluns (or transformers), depending on the
test and frequency range. DC-coupled step response testing used two 50 Ω scope inputs with trace math.
Single-supply operation is most common in end equipment designs. However, using split balanced supplies
allows simple ground referenced testing without adding further blocking capacitors in the signal path beyond
those capacitors already within the test equipment. The starting point for any single-ended input to differential
output measurements (such as any of the frequency response curves) is shown in Figure 7-1 (available as a
TINA-TI™ simulation file).
50- Input Match,
Gain of 1 V/V from RT,
Single-Ended Source to
Differential Output
THS4552 Wideband,
Fully Differential Amplifier
RF1
1k
RO1
487
VS+
RG1
1k
Network
Analyzer,
50- Source
Impedance
ADTL1-4-75+
±
RT1
52.3
VOCM
FDA
RG2
1k
Termination
RS1
50
RT2
52.3
N1
+
VOPP
±
+
50-
31.8-dB
Insertion Loss
from VOPP to a
50- Load
PD
VS-
VS+
RF2
1k
RO2
487
1-k
Differential
Load
RM
52.3
N2
50Single-Ended
Source
Network
Analyzer,
50- Load
Copyright © 2016, Texas Instruments Incorporated
Figure 7-1. Single-Ended Source to a Differential Gain of a 1 V/V Test Circuit
Most characterization plots fix the RF (RF1 = RF2) value at 1 kΩ, as shown in Figure 7-1. This element value is
completely flexible in application, but 1 kΩ provides a good compromise for the parasitic issues linked to this
value, specifically:
•
•
•
22
Added output loading: the FDA functions similarly to an inverting op amp design with both feedback resistors
appearing as an added load across the outputs (the approximate total differential load in Figure 7-1 is 1 kΩ ||
2 kΩ = 667 Ω). The 1 kΩ value also reduces the power dissipated in the feedback networks.
Noise contributions resulting from resistor values: these contributions are both the 4kTRF terms and the
current noise times the RF value to the output (see Section 9.1.1).
Parasitic feedback pole at the input summing nodes: this pole is created by the feedback resistor (RF) value
and the 1.2 pF differential input capacitance (as well as any board layout parasitic) and introduces a zero in
the noise gain, thus decreasing the phase margin in most situations. This effect must be managed for best
frequency response flatness or step response overshoot. Internal 0.6-pF feedback capacitors on each side
combine with these external feedback resistors to introduce a zero in the noise gain, thereby reducing the
effect of the feedback pole to the differential input capacitance.
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The frequency domain characterization curves start with the selections of Figure 7-1. Some of the features in this
test circuit include:
•
•
•
The elements on the non-signal input side exactly match the signal-side input resistors. This feature has the
effect of more closely matching the divider networks on each side of the FDA. The three resistors on the
non-signal input side can be replaced by a single resistor to ground using a standard E96 value of 1.02 kΩ
with some loss in gain balancing between the two sides; see Section 8.3.4).
Translating from a 1 kΩ differential load to a 50-Ω environment introduces considerable insertion loss in
the measurements (–31.8 dB in Figure 7-1). The measurement path insertion loss is normalized out when
reporting the frequency response curves to show the gain response to the FDA output pins.
In the pass band for the output balun, the network analyzer 50 Ω load reflects to be in parallel with the
52.3 Ω shunt termination. These elements combine to show a differential 1 kΩ load at the output pins of the
THS4552. The source impedance presented to the balun is a differential 50 Ω source. Figure 7-2 and Figure
7-3 show the TINA-TI™ model (available as a TINA-TI™ simulation file) and resulting response flatness for
this relatively low-frequency balun providing 0.1 dB flatness through 100 MHz.
L1's Inductance : 198.94 uH
L2's Inductance : 198.94 uH
Mutual Inductance : 198.92972 uH
ADTL1-4-75 Model 198.94u
R3 50
+
N1
R1 25
VG1
N2
R2 25
+
V
VM1
Figure 7-2. Output Measurement Balun Simulation Circuit in TINA-TI™
10
8
-6.02
6
-6.03
4
-6.04
2
-6.05
0
-6.06
-2
-6.07
-4
-6.08
-6.09
-6.1
1k
Phase (deg)
Gain (dB)
-6
-6.01
-6
Gain (dB)
Phase (deg)
10k
-8
100k
1M
Frequency (Hz)
10M
-10
100M
D061
Figure 7-3. Output Measurement Balun Flatness Test
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Starting from the test circuit of Figure 7-1, various elements are modified to show the effect of these elements
over a range of design targets, specifically:
•
•
•
•
The gain setting is changed by adjusting the RT and the two RG elements to provide a 50 Ω input match and
setting the feedback resistors to 1 kΩ.
Output loading of both resistive and capacitive load testing. Changing to lower resistive loads is
accomplished by adding parallel resistors across the output pins in Figure 7-1. Changing to capacitive loads
adds series output resistors to a differential capacitance before the 1 kΩ sense path of Figure 7-1.
Power-supply settings. Most often, a single 5 V test uses a ±2.5 V supply and a 3 V test uses ±1.5 V supplies
with the VOCM input control at ground.
The disable control pin (PD) is tied to the positive supply (VS+) for any active channel test.
7.2 Output Interface Circuit for DC-Coupled Differential Testing
The pulse response plots were taken using the output circuit of Figure 7-4. The two sides of this circuit present
a 500 Ω load to ground (for a differential 1 kΩ load) with a 50 Ω source to the two scope inputs. Trace math is
used to combine the two sides into the pulse response plots of Figure 6-7 to Figure 6-8 and Figure 6-9 to Figure
6-10. Using balanced bipolar supplies for this test ensures that the THS4552 outputs deliver a ground-centered
differential swing. This setup produces no dc load currents using the circuit of Figure 7-4.
RO1
475
RM1
56.2
THS4552
Output
RM1
56.2
RO2
475
50Scope
Input
50Scope
Input
Copyright © 2016, Texas Instruments Incorporated
Figure 7-4. Output Interface for DC-Coupled Differential Outputs
7.3 Output Common-Mode Measurements
The circuit of Figure 7-5 is a typical setup for common-mode measurements.
THS4552 Wideband,
Fully Differential Amplifier
RG1
1k
RF1
1k
VS+
Signal
Source
100
RS
49.9
VOCM
Input
±
FDA
RT
49.9
+
±
+
RT
1k
50Measurement
Equipment
PD
VS-
VS+
100
RF2
1k
Copyright © 2016, Texas Instruments Incorporated
Figure 7-5. Output Common-Mode Measurements
24
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In Figure 7-5, the differential path is simply terminated back to ground on the two 1 kΩ input resistors and
the VOCM control input is driven from a 50 Ω matched source for the frequency response and step response
curves of Figure 6-43 and Figure 6-44. The outputs are summed to a center point (to obtain the average, or
common-mode, output) through two 100 Ω resistors. These 100 Ω resistors form an equivalent 50 Ω source
to the common-mode output for measurements. This common-mode test circuit is available as a TINA-TI™
simulation file. Figure 6-45 illustrates the common-mode output noise measurements with either a ground on the
VOCM input pin or with the VOCM input pin floating. The higher noise in Figure 6-45 for a floated input can be
reduced by including a capacitor to ground at the VOCM control input pin.
7.4 Differential Amplifier Noise Measurements
To extract out the input-referred noise terms from the total output noise, a measurement of the differential output
noise is required under two external conditions to emphasize the different noise terms. A high-gain, low resistor
value condition is used to emphasize the differential input voltage noise and a higher RF at low gains is used
to emphasize the two input current noise terms. The differential output noise must be converted to single-ended
with added gain before being measured by a spectrum analyzer. At low frequencies, a zero 1/f noise, high-gain,
differential to single-ended instrumentation amplifier (such as the INA188) is used. At higher frequencies, a
differential to single-ended balun is used to drive into a high-gain, low-noise, op amp (such as the LMH6629).
In this case, the THS4552 outputs drive 25 Ω resistors into a 1:1 balun where the balun output is terminated
single-endedly at the LMH6629 input with 50 Ω. This termination provides a modest 6 dB insertion loss for the
THS4552 differential output noise that is then followed by a 40 dB gain setting in the very wideband LMH6629.
7.5 Balanced Split-Supply Versus Single-Supply Characterization
Although most end applications use a single-supply implementation, most characterizations are done on a split
balanced supply. Using a split balanced supply keeps the I/O common-mode inputs near midsupply and provides
the most output swing with no dc bias currents for level shifting. These characterizations include the frequency
response, harmonic distortion, and noise plots. The time domain plots are in some cases done through the
single-supply characterization to obtain the correct movement of the input common-mode voltage.
7.6 Simulated Characterization Curves
In some cases, a characteristic curve can only be generated through simulation. A good example of this scenario
is the output balance plot of Figure 6-40. This plot shows the best-case output balance (output differential
signal versus output common-mode signal) using exact matching on the external resistors in simulation using a
single-ended input to differential output configuration. The actual output balance is set by resistor mismatch at
low frequencies but intersects and follows the high-frequency portion of Figure 6-40.
The remaining simulated plots include:
•
•
•
•
•
AOL gain and phase, see Figure 6-37.
Large and small-signal settling times, see Figure 6-11 and Figure 6-25.
Closed-loop output impedance versus frequency, see Figure 6-38.
CMRR versus frequency, see Figure 6-41.
PSRR versus frequency and output common-mode voltage, see Figure 6-42, Figure 6-47, and Figure 6-48.
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7.7 Terminology and Application Assumptions
Numerous common terms that are unique to this type of device exist. This section identifies and explains these
terms.
•
•
•
•
Fully differential amplifier (FDA). This term is restricted to devices offering what appears similar to a
differential inverting op amp design element that requires an input resistor (not a high-impedance input)
and includes a second internal control loop that sets the output average voltage (VOCM) to a default or set
point. This second common-mode control loop interacts with the differential loop in certain configurations.
The desired output signal at the two output pins is a differential signal that swings symmetrically around a
common-mode voltage, which is the average voltage for the two outputs.
Single-ended to differential. The output must always be used differentially in an FDA; however, the source
signal can be either a single-ended or a differential source with a variety of implementation details for either
source. For an FDA operating in single-ended to differential, only one of the two input signals is applied to
one of the input resistors.
The common-mode control has limited bandwidth from the input VOCM pin to the common-mode output
voltage. The internal loop bandwidth beyond the input VOCM buffer is a much wider bandwidth than the
reported VOCM bandwidth, but is not directly discernable. A very wide bandwidth in the internal VOCM loop is
required to perform an effective and low-distortion single-ended to differential conversion.
Several features in the application of the THS4552 are not explicitly stated, but are necessary for correct
operation. These features are:
•
•
•
•
•
26
Good power-supply decoupling is required. Often a larger capacitor (2.2 µF, typical) is used along with a
high-frequency, 0.1 µF supply decoupling capacitor at the device supply pins. For single-supply operation,
only the positive supply has these capacitors. Where a split supply is used, connect these capacitors to
ground on both sides with the larger capacitor placed some distance from the package and shared among
multiple channels of the THS4552, if used. A separate 0.1 µF capacitor must be provided to each device at
the device power pins. With cascaded or multiple parallel channels, including ferrite beads from the larger
capacitor to the local high-frequency decoupling capacitor is often useful.
Although often not stated, the power disable pin (PD) is tied to the positive supply when only an enabled
channel is desired.
Virtually all ac characterization equipment expects a 50 Ω termination from the 50 Ω source and a 50 Ω,
single-ended source impedance from the device outputs to the 50 Ω sensing termination. This condition is
achieved in all characterizations (often with some insertion loss) but is not necessary for most applications.
Matching impedance is most often required when transmitting over longer distances. Tight layouts from a
source, through the THS4552, and to an ADC input do not require doubly-terminated lines or filter designs.
The only exception is if the source requires a defined termination impedance for correct operation (for
example, mixer outputs).
The amplifier signal path is flexible for use as single or split-supply operation. Most applications are intended
to be single supply, but any split-supply design can be used as long as the total supply voltage across the
TH4552 is less than 5.5 V and the required input, output, and common-mode pin headrooms to each supply
are taken into account. When left open, the VOCM pin defaults to near midsupply for any combination of
split or single supplies used. The disable pin ( PD) is referenced to the negative rail. Using a negative supply
requires that PD be pulled down to within 0.55 V of the negative supply to disable the amplifier.
External element values are normally assumed to be accurate and matched. In an FDA, this assumption
translates to equal feedback resistor values and a matched impedance from each input summing junction
to either a signal source or a dc bias reference on each side of the inputs. Unbalancing these values
introduces non-idealities in the signal path. For the signal path, imbalanced resistor ratios on the two sides
creates a common-mode to differential conversion. Furthermore, mismatched RF values and feedback ratios
create additional differential output error terms from any common-mode dc or ac signal or noise terms.
Using standard 1% resistor values is a typical approach and generally leads to some nominal feedback ratio
mismatch. Modestly mismatched resistors or ratios do not by themselves degrade harmonic distortion. Where
there is a meaningful common-mode noise or distortion coming in that gets converted to differential via an
element or ratio mismatch. For the best dc precision, use 0.1% accuracy resistors that are readily available in
E96 values (1% steps).
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8 Detailed Description
8.1 Overview
In addition to the core differential I/O voltage feedback gain block, there are two 5.2 kΩ resistors internally
across the outputs to sense the average voltage at the outputs. These resistors feed the average voltage back
into a VCM error amplifier where the voltage is compared to either a default voltage divider across the supplies
or an externally set VOCM target voltage. When the amplifier is disabled, the default mid-supply bias string is
disabled to save power.
To achieve the very-low noise at the low power provided by the THS4552, the input stage transistors
are relatively large, thus resulting in a higher differential input capacitance (1.2 pF in Section 8.2). As a
default compensation for the 1.2 pF differential input capacitance and the 1 kΩ feedback resistors used in
characterization, internal 0.6 pF capacitors are placed between the two output and input pins. Adjust any desired
external feedback capacitor value to account for these 0.6 pF internal elements. When using the 24-pin VQFN
package and the internal feedback traces to the input side of the package, include the nominal trace impedance
of 3.3 Ω in the design. These elements are not included in the TINA-TI™ model and must be added externally to
a design intending to use the RTW package.
8.2 Functional Block Diagram
VS+
3.3
(RTW Package)
FB+
0.6 pF
OUT+
IN±
±
5.2 k
High-AOL +
Differential I/O
Amplifier ±
1.2 pF
IN+
5.2 k
+
OUT±
0.6 pF
VS+
3.3
(RTW Package) FB±
300 k
VS±
±
VCM
Error
Amplifier
+
PD
VOCM
CMOS
Buffer
300 k
VS±
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8.3 Feature Description
8.3.1 Differential Open-Loop Gain and Output Impedance
The most important elements to the closed-loop performance are the open-loop gain and open-loop output
impedance. Figure 8-1 and Figure 8-2 show the simulated differential open-loop gain and phase from the
differential inputs to the differential outputs with no load and with a 100 Ω load. Operating with no load removes
any effect introduced by the open-loop output impedance to a finite load. This AOL simulation removes the
0.6 pF internal feedback capacitors to isolate the forward path gain and phase (see Figure 12-1). The 0.6
pF capacitance becomes part of the feedback network that sets the noise gain and phase combined with the
external elements. The simulated differential open-loop output impedance is shown in Figure 8-3.
-90
80
100 : Load
No Load
70
-100
-110
Open-Loop Phase (deg)
Open-Loop Gain (dB)
60
50
40
30
20
10
-120
-130
-140
-150
-160
-170
-180
0
-190
-10
-200
-20
100k
1M
10M
Frequency (Hz)
100M
No Load
100 : Load
-210
100k
1G
D063
Figure 8-1. No-Load and 100 Ω Loaded AOL Gain
1M
10M
Frequency (Hz)
100M
1G
D064
Figure 8-2. No-Load and 100 Ω AOL Phase
Differential Output Impedance (:)
10000
1000
100
10
1
10
100
1k
10k
100k
1M
Frequency (Hz)
10M
100M
1G
D062
Figure 8-3. Differential Open-Loop Output Impedance
This impedance combines with the load to shift the apparent open-loop gain and phase to the output pins when
the load changes. The rail-to-rail output stage shows a very high impedance at low frequencies that reduces with
frequency to a lower midrange value and then peaks again at higher frequencies. The maximum value at low
frequencies is set by the common-mode sensing resistors to be a 10.5 kΩ dc value (see Section 8.2). This high
impedance at a low frequency is significantly reduced in closed-loop operation by the loop gain, as shown in the
closed-loop output impedance of Figure 6-38. Figure 8-1 compares the no load AOL gain to the AOL gain driving
a 100 Ω load that shows the effect of the output impedance. The heavier loads pull the AOL gain down faster to
lower crossovers with more phase shift at the lower frequencies.
The much faster phase roll-off for the 100 Ω differential load explains the greater peaked response illustrated in
Figure 6-4 and Figure 6-22 when the load decreases. This same effect happens for the RC loads common with
converter interface designs. Use the TINA-TI™ model to verify loop phase margin in any design.
28
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8.3.2 Setting Resistor Values Versus Gain
The THS4552 offers considerable flexibility in the configuration and selection of resistor values. The design
starts with the selection of the feedback resistor value. The 1 kΩ feedback resistor value used for the
characterization curves is a good compromise between power, noise, and phase margin considerations. With
the feedback resistor values selected (and set equal on each side) the input resistors are set to obtain the
desired gain with input impedance also set with these input resistors. Differential I/O designs provide an input
impedance that is the sum of the two input resistors. Single-ended input to differential output designs present a
more complicated input impedance. Most characteristic curves implement the single-ended to differential design
as the more challenging requirement over differential-to-differential I/O.
For single-ended, matched, input impedance designs, Table 8-1 illustrates the suggested standard resistors set
to approximately a 1 kΩ feedback. This table assumes a 50 Ω source and a 50 Ω input match and uses a
single resistor on the non-signal input side for gain matching. Better matching is possible using the same three
resistors on the non-signal input side as on the input side. Figure 8-4 shows the element values and naming
convention for the gain of 1 V/V configuration where the gain is defined from the matched input at RT to the
differential output.
50- Input Match,
Gain of 1 V/V from RT,
Single-Ended Source to
Differential Output
50Source
Impedance
THS4552 Wideband,
Fully Differential Amplifier
RF1
1k
VS+
RG1
1k
RS1
50
VOPP
±
RT
52.3
VOCM
FDA
+
+
RG2
1.02 k
RL
1k
±
PD
VS-
VS+
RF2
1k
Copyright © 2016, Texas Instruments Incorporated
Figure 8-4. Single-Ended to Differential Gain of 1 V/V with Input Matching Using Standard Resistor
Values
Starting from a target feedback resistor value, the desired input matching impedance, and the target gain (AV),
the required input RT value is given by solving the quadratic of Equation 1.
RT 2
RS
§
·
2RS ¨ 2RF
A V2 ¸
2
©
¹
RT
2RF 2 A V
RS A V (4 A V )
2RF 2
2RFRS2 A V
AV
RS A V (4
0
AV )
(1)
When this value is derived, the required input side gain resistor is given by Equation 2 and then the single value
for RG2 on the non-signal input side is given by Equation 3:
2
RG1
RF
AV
1
RS
RS
RT
(2)
RF
AV
RS
1
RT
2
RG2
(3)
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Using these expressions to generate a swept gain table of values results in Table 8-1, where the best standard
1% resistor values are shown to minimize input impedance and gain error to target.
Table 8-1. Swept Gain 50 Ω Input Match with RF = 1 kΩ (±1 Standard Values)
GAIN (V/V)
RF (Ω)
RG1 (Ω)
RT (Ω)
RG2 (Ω)
ZIN (Ω)
AV (V/V)
0.1
1000
10000
49.9
10000
49.66
0.09965
1
1000
976
51.1
1000
49.2
1.0096
2
1020
499
52.3
523
48.9
1.988
5
1000
187
59
215
50.2
5.057
10
1020
88.7
69.8
118
50.6
10.09
Where an input impedance match is not required, simply set the input resistor to obtain the desired gain without
an additional resistor to ground (remove RT in Figure 8-4). This scenario is common when coming from the
output of another single-ended op amp (such as the OPA192). This single-ended to differential stage shows a
higher input impedance than the physical RG as given by the expression for ZA (active input impedance) shown
as Equation 4.
ZA
RG1
§
¨1
©
RG1 ·§
RF ·
¸¨ 1
¸
RG2 ¹©
RG1 ¹
RF
2
RG2
(4)
Using Equation 4 for the gain of 1 V/V with all resistors equal to 1 kΩ shows an input impedance of 1.33 kΩ.
The increased input impedance comes from the common-mode input voltage at the amplifier pins moving in
the same direction as the input signal. The common-mode input voltage must move to create the current in the
non-signal input RG resistor to produce the inverted output. The current flow into the signal-side input resistor
is impeded because the common-mode input voltage moves with the input signal, thus increasing the apparent
input impedance in the signal input path.
8.3.3 I/O Headroom Considerations
The starting point for most designs is to assign an output common-mode voltage for the THS4552. For accoupled signal paths, this voltage is often the default midsupply voltage to retain the most available output swing
around the voltage centered at the VOCM voltage. For dc-coupled designs, set this voltage with consideration
to the required minimum headroom to the supplies as described in the table specifications of Electrical
Characteristics for the VOCM control. For precision ADC drivers, this output VOCM becomes the input VCM to
the ADC. Often, VCM is set to VREF / 2 to center the differential input on the available input when precision ADCs
are being driven.
From the target output VOCM, the next step is to verify that the desired output differential peak-to-peak voltage
(VOPP) stays within the supplies. For any desired differential VOPP, make sure that the absolute maximum
voltage at the output pins swings with Equation 5 and Equation 6 and confirm that these expressions are within
the supply rails minus the output headroom required for the RRO device.
30
VOmax
VOCM
VOPP
4
(5)
VOmin
VOCM
VOPP
4
(6)
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For instance, when the THS4552 drives the ADC3223 with a 0.95 VCM control using a single 3.0 V supply,
the negative-going signal sets the maximum output swing from 0.95 VCM to 0.2 V above ground. This 0.75 V,
single-sided swing becomes an available 4 × 0.75 V = 3 VPP differential around the nominal 0.95 VCM output
common-mode voltage. On the high side, the maximum output is equal to 1.7 V (0.95 V + 0.75 V), which is well
within the allowed maximum range of 2.8 V (3.0 V – 0.2 V). This available 3 VPP maximum differential output is
also well beyond the maximum value required for the 2 VPP input ADS3223.
With the output headrooms confirmed, the input junctions must also stay within the operating range. The input
range limitations only appear when approaching the positive supply where a maximum 1.3 V headroom is
required over the full temperature range because the input range extends to the negative supply voltage over the
full temperature range.
The input pins operate at voltages set by the external circuit design, the required output VOCM, and the input
signal characteristics. For differential-to-differential designs where there is no signal-related movement in the
input VICM voltages, ac-coupled differential input designs have a VICM equal to the output VOCM. Going towards
the positive supply, the output common-mode can be set to within 1.2 V of the supply. AC-coupled input designs
violate the required 1.3 V headroom on the input pins in this case. Going towards the negative supply on the
VOCM setting requires a minimum of 0.55 V above the supply. This extreme is always in range for the input pins
that require a minimum 0 V headroom to the negative supply.
DC-coupled differential input designs must check the voltage divider from the source common-mode input
voltage to the THS4552 VOCM setting. This result must be equal to an input VICM within the specified range. If the
source VCM can vary over some voltage range, validate this result over that range before proceeding.
For single-ended input to differential output designs, the VICM is nominally at a voltage set by the external
configuration with a small swing around the nominal value because of the common-mode loop. An ac-coupled,
single-ended input to differential output design places an average input VICM equal to the output VOCM for the
FDA with an ac-coupled swing around the VOCM voltage following the input voltage. A dc-coupled, single-ended
input to differential design gets a nominal input VICM set by the source signal common-mode level and the VOCM
output voltage with a small signal-related swing around the nominal VICM voltage.
One approach to deriving the VICM voltage range for any single-ended input to differential output design is to
observe the output voltage swing on the non-signal input side of the FDA outputs and simply take the voltage
division on the input pin to ground or to the dc reference used on that side. An example analysis is shown in
Figure 8-5 using a Thevenized version of the gain of 2 values listed in Table 8-1 for a 50 Ω matched impedance,
ac-coupled design.
In this example, a single 3.3 V supply is used with the VOCM defaulted to midsupply or 1.65 V as a commonmode output voltage. This value is also the common-mode voltage on the input pins for the ac-coupled input
to the FDA. Targeting a 4 VPP differential output swing means each output pin swings ±1 V around this 1.65
V common-mode voltage. This output swing is in range because the full swing is 0.65 V to 2.65 V relative to
ground, which is well within the 0.2 V output headroom requirements on a single 3.3 V supply.
THS4552 Wideband,
Fully Differential Amplifier
VS+
Thevinized
Source
VS-
RS1
25.6
1 µF
RF1
1.02 k
VS+
RG1
499
VOUT = 4-VPP
Differential
RL
1k
±
+
±
3.3 V
+
±
VOCM
0V
FDA
VIN = ±1.022 V
1 µF
+
±
+
1 µF
PD
VSRG2
523
VS+
RF2
1.02 k
Copyright © 2016, Texas Instruments Incorporated
Figure 8-5. Input Swing Analysis Circuit with AC-Coupled, Single-Ended to Differential Signal Path
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The output on the lower side of this design ranges from 0.65 V to 2.65 V. This 2 VPP swing (on just one side,
the other output is an inverted version and gives the 4 VPP differential maximum) is divided back by the RF2
and RG2 divider to the input pins to form a common-mode input swing on top of the 1.65-V input common-mode
voltage. This divider is 0.339 × 2 VPP = 0.678 VPP or ±0.34 V around the 1.65 V input common-mode voltage.
The 1.31 V to 1.99 V common-mode input swing for this design is in range for the 0 V to 2.2 V available input
range (the maximum headroom is 3.3 V – 1.1 V, which is equal to 2.2 V). These voltage swings can be directly
observed using the SBOC460 TINA-TI™ simulation file. Shifting the VOCM down slightly (if allowed by the design
requirements) is a good way to improve the positive-swinging input headroom for this low-voltage design.
Taking a more complex example by using the THS4552 to attenuate a large bipolar input signal in a dc-coupled
design for an ADC is shown in Figure 8-6. To remove the peaking for this low-noise gain design, the two CF
elements and an input capacitor are added to shape the noise gain at high frequencies to a capacitive divider, as
described in Section 9.1.8. In this example (including the 1.2 pF internal differential capacitor at the inputs and
the 0.6 pF internal feedback capacitors), the high-frequency noise gain is 3 V/V and a flat frequency response
with approximately 45 MHz of –3 dB BW is delivered.
3.1 pF
10 k
VOCM
4.096 V
+
THS4552 Wideband,
Fully Differential Amplifier
RF1
1k
VOUT = 7.2 VPP
Differential
1 µF
10 k
±
Gain of 0.2 V/V,
DC-Coupled,
Single-Ended Source to
Differential Output
VS+
RG1
4.99 k
±
VS+
5V
+
±
VS0V
VOCM
VS = ±18 V
2.6 pF
+
FDA
+
RL
1k
±
+
PD
VS-
VS+
For Attenuator Design:
NG1 = 1.2
NG2 = 3
GBP = 135 MHz
Zo = 14.3 MHz
±
RG2
4.99 k
A 1-k load is very
important to include because
of high-frequency resonance;
no load may oscillate.
RF2
1k
3.1 pF
Copyright © 2016, Texas Instruments Incorporated
Figure 8-6. DC-Coupled, Single-Ended to Differential Attenuator Design
In this example, the output VOCM is 4.096 V / 2, which equals 2.048 V and the source signal VCM is 0 V. These
values set the nominal input pin VICM to 2.048 V × 4.99 kΩ / (4.99 kΩ + 1 kΩ) = 1.71 V. Applying a ±18 V input
at the 4.99 kΩ input resistor produces a 7.2 VPP differential output. That is, a ±1.8 V swing on the lower output
side around the 2.048 V common-mode voltage. This 0.248 V to 3.84 V relative-to-ground swing at the output
is well within the 0.2 V output headrooms to the 0 V to 5 V supplies used in the example in Figure 8-6 (with the
same swing inverted on the other output side). That output swing on the lower side produces an attenuated input
common mode swing of (±1.8 V × (4.99 kΩ / (4.99 kΩ + 1 kΩ)) = ±1.5 V around the midscale input bias of 1.71
V. This 0.2-V to 3.2 V input common-mode swing is well within the available 0 V to 3.8 V input range. This ±18
V bipolar input signal is delivered to a SAR ADC with a 7.2 VPP differential output with all I/O nodes operating in
range using a single 5 V supply design. The source must sink the 2.048 V / 5.99 kΩ = 0.34 mA common-mode
level-shifting current to take the input 0 V common-mode voltage up to the midscale 1.71 V VICM operating
voltage. Using the single-ended input impedance of Equation 4, the source must also drive an apparent input
load of 5.44 kΩ.
Most designs do not run into an input range limit. However, using the approach shown in this section can
allow a quick assessment of the input VICM range under the intended full-scale output condition. The TINA-TI™
simulation file for Figure 8-6 can be used to plot the input voltages under the intended swings and application
circuit to verify that there is no limiting from this effect. Driving the I/O nodes out of range in the TINA-TI™ model
results in convergence problems. Increasing the positive and negative supplies slightly in simulation is an easy
way to discover the simulated swings that might be going out of range.
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As a third example of arriving at the input pin voltage swings, use the design of Figure 9-20 (the ADC3241
design). Thevenize the source to just one input resistor to get an expression for the input VICM in terms of
the input voltage to be derived. Figure 8-7 shows the gain of 5 V/V, dc-coupled, matched input impedance,
single-ended to differential circuit of Figure 9-20 with both sides reduced to a single input resistor. In Figure 9-20,
the design operates on a single 3.3 V supply with an output VOCM equal to 0.95 V to directly connect to TI’s line
of low-power ADC3xxx series of 12- and 14-bit ADCs. This family accepts a 2 VPP maximum differential voltage,
which (at the input-terminating resistor of Figure 9-20) is a ±0.2 V swing. Going back to the source through
the matching resistor is then a ±0.4 V source swing. Thevenizing that source with the RT element provides the
±0.217 V shown in Figure 8-7 and the total R2 as the sum of RG1 and 50 Ω || 59 Ω.
THS4552 Wideband,
Fully Differential Amplifier
RF1
1k
VOUT
VS+
3.3 V
+
±
VOCM
VS0V
+
±
Thevinized
Source
VS+
R2
215
±1-V Differential Output
Centered on 0.95 VCM
±
0.95 V
+
±
VOCM
VTHEV
±0.217 V
FDA
+
+
R2
215
RL
1k
±
PD
VS-
VS+
RF2
1k
Copyright © 2016, Texas Instruments Incorporated
Figure 8-7. Input VICM Analysis Circuit From the Design of Figure 9-20
For an input signal (VTHEV) that swings around ground as ±VTHEV, the input pins are within a range given by
Equation 7, which is a superposition of the output VOCM divided back to the input nodes and half of the input
±VTHEV signal.
VICM
VOCM
RG
V
RF
r THEV u
RG RF
2
RF RG
(7)
Using the values from the design of Figure 8-7, the computed input range for the THS4552 input pins is VICM =
0.168 V ± 0.89 mV or 0.079 V to 0.257 V at the input pins. These values are well within range for the negative
rail input available in the THS4552.
A simpler approach to arriving at the input common mode range for this DC coupled single supply design would
be to take the output voltage swing range on the lower side (non – signal input side) and simply divide it back
through its resistor divider to ground on that side.
The output pin voltage swing is 0.95 V ± 0.5 V or 0.45 V to 1.45 V. This swing is divided back to the input VICM
by a 215 / (215 + 1000) = 0.177 ratio. This ratio computes the input pin range as 79 mV to 0.256 V, matching
the input source swing results in Equation 7. The TINA-TI™ model for Figure 8-7 (available as SBOC472) also
provides these input swings as shown in the simplified circuit of Figure 8-8. The large centered swing is the
differential output voltage at the THS4552 output pins (which is actually the two outputs swinging ±0.5 V around
a 0.95 VCM), the small centered bipolar swing is the input swing for the thevenized source of Figure 8-8, and the
smallest VPP swing on a dc offset is the input VICM voltage at the non-signal side input for the circuit of Figure
8-8.
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1.2
1
0.8
0.6
Output (V)
0.4
0.2
0
-0.2
-0.4
-0.6
VIN+
VOUT
VS
-0.8
-1
-1.2
0
100
200
300
400 500 600
Time (ns)
700
800
900 1000
D069
Figure 8-8. I/O Swing Simulation Using the TINA-TI™ Model
8.3.4 Output DC Error and Drift Calculations and the Effect of Resistor Imbalances
The THS4552 offers a trimmed input offset voltage and extremely low offset drift over the full –40°C to +125°C
operating range. This offset voltage combines with several other error contribution terms to produce an initial
25°C output offset error band and then a drift over temperature. For each error term, a gain must be assigned
to that term. For this analysis, only dc-coupled signal paths are considered. One new source of output error
(versus the typical op amp analysis) arises from the effect mismatched resistor values and ratios can have on
the two sides of the FDA. Any common-mode error or drift creates a differential output error through the slight
mismatches arising from the external feedback and gain setting resistor tolerances or standard value constraints.
The error terms (25°C and drift), along with the gain to the output differential voltage, include input offset voltage
and input offset current. Input offset voltage has a gain equal to the noise gain or 1 + RF / RG, where RG is
the total dc impedance from the input pins back to the source or a dc reference (typically ground). Input offset
current has a gain to the differential output through the average feedback resistor value.
The remaining terms arise from an assumed range on both the absolute feedback resistor mismatch and the
mismatch in the divider ratio on each side of the FDA. The first of these resistor mismatch terms is the input bias
current that creates a differential output offset via RF mismatch. For simplicity, the upper RF and RG values are
termed RF1 and RG1 with a ratio of RF1 / RG1 ≡ G1. The lower elements are defined as RF2 and RG2 with a ratio
of RF2 / RG2 ≡ G2. To compute worst-case contributions, a maximum variation in the design resistor tolerance is
used in the absolute and ratio mismatches.
For instance, ±1% tolerance resistors are assumed, giving a worst-case G1 that is 2% higher than nominal
and a G2 that is 2% lower than nominal with a worst-case RF value mismatch of 2% as well. Using a 0.1%
precision resistor reduces the gain for the input bias current, but because these precision resistors are usually
only available in 1% value steps, a gain mismatch term may still need to be considered. For matched impedance
designs with RT and RG1 on a single-ended to differential stage, the standard value constraint imposes a fixed
mismatch in the initial feedback ratios with the tolerance of the resistors around the ratio if the non-signal input
side uses a single resistor for RG2.
Define the selected external resistor tolerance as ±T (so for 1% tolerance resistors, T = 0.01). Input bias current
times the feedback resistor mismatch gain is ±2 × T × RFnom.
Anything that generates an output common-mode level or shift over temperature also generates an output
differential error term if the two feedback ratios, G1 and G2, are not equal. An error trying to produce a shift in
the output common-mode voltage is overridden by the common-mode control loop where the error becomes a
balanced differential error around the output VOCM.
The terms that create a differential error from a common-mode term and feedback ratio mismatch include the
desired VOCM voltage, any source common-mode voltage, any drift on the reference bias to the VOCM control pin,
any internal offset and drift in the VOCM control path, and the input average bias current and drift.
34
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Considering just the output common-mode control and the source common-mode voltage, the conversion to
output differential offsets is through Equation 8.
VOD
VOCM G1 G2
VICM G1 G2
G1 G2
1
2
(8)
Neglecting any G1 and G2 mismatch because of standard values constraint, the conversion gain for these two
terms can be recast in terms of the nominal RF / RG ≡ G and the tolerance T, as shown in Equation 9. When G
increases, this conversion gain approaches 4T.
VOD
VOCM
G
4T
‡
(1 G) (1 T 2 )
(9)
This conversion gain to differential output error is applied to two error terms: VOCM and the input bias current
and drift. (The source common-mode voltage is assumed to be 0 V. If not, apply this gain to the source
common-mode voltage and any resulting shift in application.)
The output error is applied to VOCM, assuming that the input control pin is driven and not floating. The input bias
current and drift are multiplied by the average RF value then by the conversion gain to differential output error to
create an added output differential error.
As an example of using these terms to estimate the worst-case output 25°C error band and then the worst-case
drift (by adding all error terms together independently), use the gain of 1 V/V configuration with RF = 1 kΩ and
assume a ±1% tolerance on the resistors with the standard values used in Figure 8-9.
50- Input Match,
Gain of 1 V/V from RT,
Single-Ended Source to
Differential Output
50Source
Impedance
VS+
+
±
VS-
5V
+
±
VOCM
0V
+
±
THS4552 Wideband,
Fully Differential Amplifier
RF1
1k
VS+
RG1
1k
RS1
50
VOPP
±
2.5 V
RT1
52.3
VOCM
FDA
+
+
RG2
1.02 k
RL
1k
±
PD
VS-
VS+
RF2
1k
Copyright © 2016, Texas Instruments Incorporated
Figure 8-9. DC-Coupled Gain of 1 with RF = 1 kΩ and Single-to-Differential Matched Input 50 Ω
Impedance
The standard value constraint on the non-signal input side actually produces more gain mismatch than the
resistor tolerances. For Figure 8-9, G2 = 1000 / 1020 = 0.9804 and G1 = 1000 / 1025.6 = 0.9751 nominally, then
with a ±2% tolerance around the initial gain mismatch resulting from the standard values available if 1% resistors
are used.
Using the maximum 25°C error terms and a nominal 2.5 V input to the VOCM control pin gives Table 8-2, gains
to the output differential error (VOD), and then the summed output error band at 25°C. The output error is clearly
dominated by the VOCM voltage and the effect of the feedback dividers being slightly mismatched. This analysis
does not completely include resistor tolerances but the approach is the same with the wider error bands on the
gain terms. For the lowest output error, this analysis shows that an exact match on the feedback dividers with
precision resistors is preferred. However, doing so would require duplicating the exact network on the non-signal
input side and the signal input side. Where input impedance matching is not required, the two RG resistors are
simply single equal resistors and the gain mismatch is just from the tolerance of the resistors.
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Table 8-2. Worst-Case Output VOD Error Band
ERROR TERM
25°C MAX VALUE
GAIN TO VOD
OUTPUT ERROR
(mV)
GAIN COMMENT
Input VIO
±0.175 mV
1.9777
±0.346
Average noise gain
Input IOS
±50 nA
1000
±0.05
Feedback resistor
Input IBCM
1.5 µA
20 Ω
±0.03
Feedback resistor mismatch
Input IBCM
1.5 µA
1 kΩ × 0.00268
±0.004
Converted to differential by gain mismatch
VOCM input
2.5 V
0.00268
±12.5
VOCM to differential by gain mismatch
Total
±12.93
The 0.00268 conversion gain for the gain ratio mismatch is the worst-case ratio starting from the initially higher
G1 value resulting from the standard value constraint and using a ±1% tolerance on the RF and RG elements of
the ratio. Mismatch is not symmetric but is shown that way in the analysis.
Normally, the expected drift in the output VOD is of more interest than an initial error band. Table 8-3 shows these
terms for the RTW package and the summed results by adding all terms independently to obtain a worst-case
drift.
Table 8-3. Worst-Case Output VOD Drift Band
ERROR TERM
MAX VALUE
GAIN TO VOD
OUTPUT ERROR
(µV/°C)
GAIN COMMENT
Input VIO
±1.8 µV/°C
1.9777
±3.56
Average noise gain
Input IOS
±120 pA/°C
1000
±0.12
Feedback resistor
Input IBCM
5.0 nA/°C
20 Ω
±0.10
Feedback resistor mismatch
Input IBCM
5.0 nA/°C
1 kΩ × 0.00268
±0.014
Converted to differential by gain mismatch
VOCM input
±10 µV/°C
0.00268
±0.027
VOCM to differential by gain mismatch
Total
±3.82
In Table 8-3, the input offset voltage drift dominates the output drift. For the last term, the drift for the VOCM
path is just for the internal offset drift of the common-mode path with a driven input. Any added external drift on
the source of the VOCM input must also be considered. This type of calculation can be repeated for the exact
application circuit considering each of these terms in the context of a specific design.
The absolute accuracy and drift for the THS4552 are exceptionally good. Mismatched resistor feedback ratios
combined with a high drift in the VOCM control input can actually dominate the output VOD drift. Where the output
differential precision is more important than the input matching accuracy, consider matching the networks on the
two sides of the input to obtain improved nominal G1 to G2 match. The gains for the input bias current error
terms are relatively low when using the 1 kΩ feedback values. Higher R F values provide the input-current-related
drift terms more gain.
8.4 Device Functional Modes
The wideband FDA requires external resistors for correct signal-path operation. When configured for the desired
input impedance and gain setting with these external resistors, the amplifier can be either on with the PD pin
asserted to a voltage greater than (VS–) + 1.15 V, or turned off by asserting PD low (within 0.55 V of the negative
supply). Disabling the amplifier shuts off the quiescent current and stops correct amplifier operation. The signal
path is still present for the source signal through the external resistors, which provides poor signal isolation from
the input to output in power-down mode.
Internal protection diodes remain present across the input pins in both operating and shutdown mode. Large
input signals during disable can turn on the input differential protection diodes, thus producing a load current in
the supply even in shutdown.
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The VOCM control pin sets the output average voltage. Left open, VOCM defaults to an internal midsupply
value. Driving this high-impedance input with a voltage reference within the valid range sets a target for the
internal VCM error amplifier. If floated to obtain a default midsupply reference for VOCM, an external decoupling
capacitor is recommended to be added on the VOCM pin to reduce the otherwise high output noise for the
internal high-impedance bias (see Figure 6-45).
8.4.1 Operation from Single-Ended Sources to Differential Outputs
One of the most useful features supported by the FDA device is an easy conversion from a single-ended input
to a differential output centered on a user-controlled, common-mode level. Although the output side is relatively
straightforward, the device input pins move in a common-mode manner with the input signal. The common-mode
voltage at the input pins, which moves with the input signal, increases the apparent input impedance to be
greater than the RG value. The input active impedance issue applies to both ac- and dc-coupled designs, and
requires somewhat more complex solutions for the resistors to account for this active impedance, as discussed
in Section 8.3.2.
8.4.1.1 AC-Coupled Signal Path Considerations for Single-Ended Input to Differential Output
Conversions
When the signal path can be ac-coupled, the dc biasing for the THS4552 becomes a relatively simple task. In
all designs, start by defining the output common-mode voltage. The ac-coupling issue can be separated for the
input and output sides of an FDA design. The input can be ac-coupled and the output dc-coupled, or the output
can be ac-coupled and the input dc-coupled, or both can be ac-coupled. One situation where the output can be
dc-coupled (for an ac-coupled input), is when driving directly into an ADC where the VOCM control voltage uses
the ADC common-mode reference to directly bias the FDA output common-mode voltage to the required ADC
input common-mode voltage. In any case, the design starts by setting the desired VOCM. When an ac-coupled
path follows the output pins, the best linearity is achieved by operating VOCM at mid-supply, which can be easily
delivered by floating the VOCM pin. The VOCM voltage must be within the linear range for the common-mode
loop, as specified in the headroom specifications (approximately 0.7 V greater than the negative supply and
1.3 V less than the positive supply for the full –40°C to +125°C operation). If the output path is also ac-coupled,
simply letting the VOCM control pin float is usually preferred in order to obtain a midsupply default VOCM bias
with minimal elements. To limit noise, place a 0.1 µF decoupling capacitor on the VOCM control pin to ground.
After VOCM is defined, check the target output voltage swing to ensure that the VOCM plus the positive and
negative output swing on each side does not clip into the supplies. If the desired output differential swing is
defined as VOPP, divide by 4 to obtain the ±VP (peak voltage) swing around VOCM at each of the two output pins
(each pin operates 180° out of phase with the other). Check that VOCM ±VP does not exceed the absolute supply
rails for the rail-to-rail output (RRO) device. Common-mode current does not flow from the common-mode output
voltage set by the VOCM pin towards the device input pins side, because both the source and balancing resistor
on the non-signal input side are dc blocked (see Figure 8-5). The ac-coupled input path sets the input pin
common-mode voltage equal to the output common-mode voltage. The input pin positive headroom requirement
(1.2 V) is less than the VOCM positive headroom (1.3 V). If the VOCM is in range, the input pins are also in range
for the ac-coupled input configuration. This headroom requirement functions similarly for when the output VOCM
voltage approaches the negative supply. The approximate minimum headroom of 0.6 V to the negative supply on
the VOCM voltage is greater than the input pin voltage headroom of approximately 0 V for the negative rail input
design. The input common-mode voltage is also in range if the output common-mode voltage is in range and
above 0.6 V from the negative supply because the input common-mode voltage follows the output VOCM setting
for ac-coupled input designs.
The input pin voltages move in a common-mode manner with the input signal, as described in Section 8.3.3.
Confirm that the VOCM voltage plus the input VPP common-mode swing also stays in range for the input pins.
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8.4.1.2 DC-Coupled Input Signal Path Considerations for Single-Ended to Differential Conversions
The output considerations remain the same as for the ac-coupled design. Again, the input can be dc-coupled
when the output is ac coupled. A dc-coupled input with an ac-coupled output can have some advantages to
move the input VICM down by adjusting the VOCM down if the source is ground referenced. When the source
is dc-coupled into the THS4552 (see Figure 8-4), both sides of the input circuit must be dc-coupled to retain
differential balance. Normally, the non-signal input side has an RG element biased to whatever the source
midrange is expected to be, provided that this midscale reference gives a balanced differential swing around
VOCM at the outputs. Often, RG2 is simply grounded for dc-coupled, bipolar-input applications. This configuration
provides a balanced differential output if the source swings around ground. If the source swings from ground
to some positive voltage, grounding RG2 gives a unipolar output differential swing from both outputs at VOCM
(when the input is at ground) to one polarity of the swing. Biasing RG2 to an expected midpoint for the input
signal creates a differential output swing around VOCM.
One significant consideration for a dc-coupled input is that VOCM sets up a common-mode bias current from the
output back through RF and RG to the source on both sides of the feedback. Without input balancing networks,
the source must sink or source this dc current. After the input signal range and biasing on the other RG element
is set, check that the voltage divider from VOCM to VIN through RF and RG (and possibly RS) establishes an
input VICM at the device input pins that is in range. If the average source is at ground, the negative rail input
stage for the THS4552 is in range for applications using a single positive supply and a positive output VOCM
setting because this dc common-mode current lifts the average FDA input summing junctions up off of ground to
a positive voltage (the average of the V+ and V– input pin voltages on the FDA). TINA-TI™ simulations of the
intended circuit offer a good check for input and output pin voltage swings (see Figure 8-7).
8.4.2 Operation from a Differential Input to a Differential Output
In many ways, this method is a much simpler way to operate the FDA from a design equations perspective.
Again, assuming that the two sides of the circuit are balanced with equal RF and RG elements, the differential
input impedance is now just the sum of the two RG elements to a differential inverting summing junction. In these
designs, the input common-mode voltage at the summing junctions does not move with the signal but must be
dc biased in the design range for the input pins and must take into account the voltage headroom required to
each supply. Slightly different considerations apply to ac- or dc-coupled differential input to differential output
designs, as described in the following sections.
8.4.2.1 AC-Coupled, Differential-Input to Differential-Output Design Issues
The most common way to use the THS4552 with an ac-coupled differential source is to simply couple the input
into the RG resistors through the blocking capacitors. Figure 8-10 shows a typical blocking capacitor approach
to a differential input. An optional input differential termination resistor (RM) is included in this design. The RM
element allows the input RG resistors to be scaled up and still delivers lower differential input impedance to
the source. In this example, the RG elements sum to show a 1 kΩ differential impedance and the RM element
combines in parallel to provide a net 500 Ω ac differential impedance to the source. Again, the design ideally
proceeds by selecting the RF element values, then the RG to set the differential gain, and then an RM element (if
needed) to achieve a target input impedance. Alternatively, the RM element can be eliminated, with the 2 × RG
elements set to the desired input impedance and RF set to obtain the differential gain (equal to RF / RG).
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THS4552 Wideband,
Fully Differential Amplifier
VS+
VS-
+
+
Differential I/O
with AC-Coupled
Input
10 nF
VS+
RG1
499
VOUT
±
VOCM
±
3.3 V
±
RF1
1.02 k
0V
VIN
RF1
1.02 k
1 µF
10 nF
FDA
RL
1k
±
+
PD
VSRG2
499
+
VS+
RF2
1.02 k
Copyright © 2016, Texas Instruments Incorporated
Figure 8-10. Example AC-Coupled Differential Input Design
The dc biasing for an ac-coupled differential input design is very simple. The output VOCM is set by the input
control voltage and, because there is no dc current path for the output common-mode voltage (as long as RM
is only differential and not split and connected to ground for instance), the dc bias also sets the common-mode
operating points for the input pins. For a purely differential input, the voltages on the input pins remain fixed
at the output VOCM setting and do not move with the input signal (unlike the single-ended input configurations
where the input pin common-mode voltages do move with the input signal). The SLOC341 TINA-TI™ simulation
file is available for Figure 8-10.
8.4.2.2 DC-Coupled, Differential-Input to Differential-Output Design Issues
Operating the THS4552 with a dc-coupled differential input source is very simple and only requires that the input
pins stay in range for the dc common-mode operating voltage. The example in Figure 8-11 takes the output
of a dual precision op amp (such as the OPA2192) where a high differential input signal is attenuated by the
THS4552 down into the range of an 18-bit SAR ADC such as the 2-MSPS ADS9110. The input stage provides a
differential gain of 21 V/V with a common-mode gain of 1 V/V. This example amplifies a small differential signal
on top of a very-wide range common-mode voltage. The input common-mode voltage appears at the outputs of
the OPA2192. The input common-mode voltage is level shifted by the FDA common-mode control to be at the
required output common-mode voltage to drive the ADS9110 SAR ADC (with a 4.096 V reference, as shown in
Figure 8-11); the FDA output common-mode voltage must be at the 2.048 V shown in Figure 8-11. This design
offers a very high CMRR using the common-mode control loop of the FDA to reset the output common-mode
voltage from that delivered to the inputs of the OPA2192. The actual CMRR from the OPA2192 inputs to the
FDA outputs is dominated by the resistor mismatches in the FDA. The feedback and differential input capacitors
are included to shape the noise gain as described in Section 9.1.8. This full example circuit is available as a
TINA-TI™ simulation file.
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Gain of 0.2 V/V,
DC-Coupled,
Differential Input to
Differential Output
2k
VOCM
4.096 V
+
10 k
±
22 pF
VCC
2.048 V
10 k
THS4552 Wideband,
Fully Differential Amplifier
1 µF
RG1
4.99 k
±
VIN1
RF1
1k
10
+
ADS9110
Inputs
VS+
VEE
200
VS+
VS-
VCC
VEE
±
OPA2192
49 pF
2k
VOCM
FDA
+
5V
+
±
0V
+
±
15 V
+
±
-15 V
+
12 nF
±
+
PD
VCC
±
VS-
±
VS+
10
VIN2
+
VEE
RG2
4.99 k
RF2
1k
22 pF
Copyright © 2016, Texas Instruments Incorporated
Figure 8-11. Example DC-Coupled Differential I/O Design from a Precision Dual Op Amp to an 18-Bit SAR
8.4.3 Input Overdrive Performance
Figure 6-30 illustrates a 2X overdrive triangle waveform for the THS4552. The input resistor is driven with a ±9
V swing for the gain of 2 V/V configuration in the test circuit of Figure 7-1 using a single 5 V supply. When the
output maximum swing is reached at approximately the supply values, the increasing input voltage turns on the
internal protection diodes across the two input pins. The internal protection diodes are two diodes in series in
both polarities. This feature clamps the maximum differential voltage across the inputs to approximately 1.5 V
when the output is limited at the supplies but the input exceeds the available range. The input resistors on both
sides limit the current flow in the internal diodes under these conditions.
40
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9 Application and Implementation
Note
Information in the following applications sections is not part of the TI component specification,
and TI does not warrant its accuracy or completeness. TI’s customers are responsible for
determining suitability of components for their purposes, as well as validating and testing their design
implementation to confirm system functionality.
9.1 Application Information
Most applications for the THS4552 strive to deliver the best dynamic range in a design that delivers the desired
signal processing along with adequate phase margin for the amplifier itself. The following sections detail some of
the design issues with analysis and guidelines for improved performance.
9.1.1 Noise Analysis
The first step in the output noise analysis is to reduce the application circuit to the simplest form with equal
feedback and gain setting elements to ground. Figure 9-1 shows the simplest analysis circuit with the FDA and
resistor noise terms to be considered.
enRg2
enRf2
RG
RF
r
r
In+2
+
In±2
eno2
±
eni2
enRg2
enRf2
RG
RF
r
r
Figure 9-1. FDA Noise Analysis Circuit
The noise powers are shown in Figure 9-1 for each term. When the RF and RG (or RI) terms are matched on
each side, the total differential output noise is the root sum squared (RSS) of these separate terms. Using NG ≡
1 + RF / RG, the total output noise is given by Equation 10. Each resistor noise term is a 4kT × R power (4kT =
1.6E-20J at 290K).
eo
eniNG
2
2 iNRF
2
2 4kTRFNG
(10)
The first term is simply the differential input spot noise times the noise gain, the second term is the input current
noise terms times the feedback resistor (and because there are two uncorrelated current noise terms, the power
is two times one of them), and the last term is the output noise resulting from both the RF and RG resistors, at
again twice the value for the output noise power of each side added together. Running a wide sweep of gains
when holding RF close to 1 kΩ and setting the input up for a 50 Ω match gives the standard values and resulting
noise listed in Table 9-1.
Note that when the gain increases, the input-referred noise approaches only the gain of the FDA input voltage
noise term at 3.3 nV/√ Hz.
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Table 9-1. Swept Gain of the Output- and Input-Referred Spot Noise Calculations
GAIN (V/V)
RF (Ω)
RG1 (Ω)
RT (Ω)
RG2 (Ω)
ZIN (Ω)
AV (V/V)
EO (nV/√ Hz)
EI (nV/√ Hz)
0.1
1000
10000
49.9
10000
49.66
0.09965
7
70
1
1000
976
51.1
1000
49.2
1.0096
10.4
10.4
2
1020
499
52.3
523
48.9
1.988
13.9
6.95
5
1000
187
59
215
50.2
5.057
23
4.6
10
1020
88.7
69.8
118
50.6
10.09
36.4
3.64
9.1.2 Factors Influencing Harmonic Distortion
As illustrated in the swept frequency harmonic distortion plots (Figure 6-13 and Figure 6-31), the THS4552
provides extremely low distortion at lower frequencies. In general, an FDA output harmonic distortion mainly
relates to the open-loop linearity in the output stage corrected by the loop gain at the fundamental frequency.
When the total load impedance decreases, including the effect of the feedback resistor elements in parallel for
loading purposes, the output stage open-loop linearity degrades, thus increasing the harmonic distortion; see
Figure 6-16 and Figure 6-34. When the output voltage swings increase, very fine scale open-loop output stage
nonlinearities increase that also degrade the harmonic distortion; see Figure 6-14 and Figure 6-13. Conversely,
decreasing the target output voltage swings drops the distortion terms rapidly. A nominal swing of 2 VPP is used
for harmonic distortion testing where Figure 6-14 illustrates the effect of going up to an 8 VPP differential input
that is more common with SAR converters.
Increasing the noise gain functions to decrease the loop gain resulting in the increasing harmonic distortion
terms; see Figure 6-18 and Figure 6-36. One advantage to the capacitive compensation for the attenuator
designs is that the noise gain is shaped up with frequency to achieve a crossover at an acceptable phase margin
at higher frequencies. This technique (see Section 9.1.8) holds the loop gain high at frequencies lower than the
noise gain zero, thus improving distortion at lower frequencies.
The THS4552 holds nearly constant distortion when the VOCM operating point is moved in the allowed range;
see Figure 6-17 and Fgiure 6-31. Clipping into the supplies with any combination of VOCM and VOPP rapidly
degrades distortion performance.
The THS4552 does an exceptional job of converting from single-ended inputs to differential outputs with very
low harmonic distortions. External resistors of 1% tolerance are used in characterization with good results.
Unbalancing the feedback divider ratios does not degrade distortion directly. Imbalanced feedback ratios convert
common-mode inputs to a differential mode at the outputs with the gain described in Section 8.3.4.
9.1.3 Driving Capacitive Loads
The capacitive load of an ADC or some other next-stage device is commonly required to be driven. Directly
connecting a capacitive load to the output pins of a closed-loop amplifier such as the THS4552 can lead to an
unstable response; see the step response plots into a capacitive load (Figure 6-8, Figure 6-10, Figure 6-26, and
Figure 6-28). One typical remedy to this instability is to add two small series resistors (RO) at the outputs of the
THS4552 before the capacitive load. Figure 6-6 and Figure 6-24 illustrate parametric plots of recommended RO
values versus differential capacitor load values and gains. Operating at higher noise gains requires lower RO
values to obtain a ±0.5 dB flat response for the same capacitive load. Some direct parasitic loading is acceptable
without a series RO that increases with gain setting (see Fgiure 6-8, Figure 6-10, Figure 6-26, and Figure 6-28
where the RO value is 0 Ω). Even when these plots suggest that a series RO is not required, good practice is
to leave a place for the RO elements in a board layout (a 0 Ω value initially) for later adjustment in case the
response appears unacceptable.
The rail-to-rail output stage of the THS4552 has an inductive characteristic in the open-loop output impedance
at higher frequencies; see Figure 6-68. This inductive open-loop output impedance introduces added phase shift
at the output pins for direct capacitive loads and feedback capacitors. Larger values of feedback capacitors
(greater than 100 pF) can risk a low phase margin. Including a 10 Ω to 15 Ω series resistor with a feedback
capacitor can be used to reduce this effect.
The TINA-TI™ simulation model does a good job of predicting these issues and illustrating the effect for different
choices of capacitive load isolating resistors (RO) and different feedback capacitor configurations.
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9.1.4 Interfacing to High-Performance Precision ADCs
The THS4552 provides a simple interface to a wide variety of precision SAR and delta-sigma (ΔΣ) ADCs. To
deliver the exceptional distortion at the output pins, considerably wider bandwidth than what is typically required
in the signal path to the ADC inputs is provided by the THS4552. This wide amplifier bandwidth provides the
low broadband, closed-loop output impedance to supply the sampling glitches and to recover quickly for the best
SFDR. A particularly challenging task is to drive the high-frequency modulator sample rates for a precision ΔΣ
converter where the modulator frequency can be far higher than the final output data rate. Figure 9-2 shows a
tested example circuit using the THS4552 in a 500 kHz, active multiple feedback (MFB) filter driving the 24-bit
ADS127L01. This filter is designed for FO = 500 kHz and Q = 0.63 to give a linear phase response with the –3
dB frequency at 443 kHz. This example circuit is available as a TINA-TI™ simulation file.
1.2 k
270 pF
VOCM
330
1 nF
470 pF
1.2 k
+
±
3V
5
+
±
1.2 k
THS4552
10
AINN
ADS127L01
22 nF
AINP
330
5
10
270 pF
1.2 k
Copyright © 2016, Texas Instruments Incorporated
Figure 9-2. 500-kHz Low-Pass Active Filter
This 3 V supply example provides a low-power interface to the very low-power ADC. This circuit is available on
the ADS127L01EVM board.
The 5 Ω resistors inside the loop at the output pins and the 1 nF differential capacitor across the FDA input
pins are not part of the filter design. These elements function to improve the loop-phase margin with minimal
interaction with the active filter operation To observe the loop gain and phase margin, use the SBOC461
TINA-TI™ simulation file. Tested performance with the ADS127L01 at a 4 kHz input shows the exceptional THD
and SNR of –114 dBc and 106 dB, respectively. Figure 9-3 uses the ADS127L01 at a modulator frequency of 16
MHz.
0
-20
-40
Amplitude (dB)
-60
-80
-100
-120
-140
-160
-180
-200
0
20
40
60
80
Frequency (kHz)
100
120
D066
Figure 9-3. 4 kHz FFT Test for the Gain of 1 V/V Interface in Figure 9-2
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9.1.5 Operating the Power Shutdown Feature
The CMOS input pin must be asserted to the desired voltage for operation. An internal pullup resistor is not
provided on the PD pin so that off-state quiescent current can be minimized. For applications simply requiring
the device to be powered on when the supplies are present, tie the PD pin to the positive supply voltage.
The disable operation is referenced from the negative supply, normally ground. For split-supply operation, with
the negative supply below ground, a disable control voltage below ground is required to turn the THS4552 off.
To assure an off state condition, the disable control pin must be below a voltage within 0.55 V of the negative
supply.
For single-supply operation, a minimum of 1.15 V above the negative supply (ground in this case) is required
to assure on operation. This logic threshold range allows direct operation from a 1.8 V supply logic when the
THS4552 operates with a single positive supply and ground.
9.1.6 Channel-to-Channel Crosstalk
Multichannel amplifiers are often used to save space and cost. Proper printed circuit board (PCB) layout
techniques can improve the crosstalk performance of multichannel amplifiers. The major cause of crosstalk is
the capacitive coupling of the signal from one channel to the other. Following are some considerations to be
taken into account to minimize the channel-to-channel crosstalk for a dual-channel THS4552:
•
•
•
•
•
•
Use 0.1 μF or 0.01 μF SMT ceramic bypass capacitors as close as possible to the power-supply pins on each
channel
Use a very large ground plane on the PCB and power-supply plane for each supply voltage, if possible
Keep input pin traces to a minimum length; longer traces result in more stray capacitance
If the design allows, put guard traces around the input pins of the amplifier; connect these guard traces to the
ground plane for high isolation
Keep the ground return path of the load routed away from the amplifier input traces
Isolate the traces for each amplifier from the other amplifiers as much as possible
Figure 9-4 shows the channel-to-channel crosstalk measurement for the THS4552 with a 2 VPP, single-ended
sinusoidal input applied on one channel and crosstalk measured on other channel with G = 1 V/V on both
channels.
-85
-90
+3 V
+5 V
Crosstalk (dBc)
-95
-100
-105
-110
-115
-120
-125
100k
1M
Frequency (Hz)
10M
D083
Figure 9-4. THS4552PW Crosstalk vs Frequency
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9.1.7 Channel-to-Channel Mismatch
Channel-to-channel dc error mismatch can be used for computing the channel-to-channel mismatch for highprecision applications. Figure 9-5 shows the channel-to-channel input offset voltage mismatch histogram and
Figure 9-6 shows the input offset current mismatch histogram.
180
200
5V
3V
No. of Units in 5 nA Bins
160
140
120
100
80
60
40
140
120
100
80
60
40
20
20
0
0
Input Offset Voltage mismatch (PV)
5V
3V
160
-50
-45
-40
-35
-30
-25
-20
-15
-10
-5
0
5
10
15
20
25
30
35
40
45
50
-200
-180
-160
-140
-120
-100
-80
-60
-40
-20
0
20
40
60
80
100
120
140
160
180
200
No. of units in 20 PV Bins
180
Input Offset Current mismatch (nA)
D080
Figure 9-5. THS4552PW Input Offset Voltage
Mismatch Histogram
D081
Figure 9-6. THS4552PW Input Offset Current
Mismatch Histogram
9.1.8 Designing Attenuators
Operating the THS4552 at a low-noise gain (or with higher feedback resistors) can cause a lower phase margin
to exist, thus giving the response peaking illustrated in Fgiure 6-1 for the gain of a 0.1 (a 1/10 attenuator)
condition. Although operating the THS4552 as an attenuator is often useful, taking a large input range to a
controlled output common-mode voltage with a purely differential signal around the VOCM voltage, the response
peaking illustrated in Figure 6-1 is usually undesirable. Several approaches can be used to reduce or eliminate
this peaking, usually at the cost of higher output noise. DC attenuation at the input usually increases the output
noise broadband, whereas using an ac noise gain shaping technique that peaks the noise gain only at higher
frequencies is more desirable. This peaking output noise can then be filtered off with the typical passive RC
filters often used after this stage. Figure 9-7 shows a simplified schematic for the gain of 0.1 V/V test from Figure
6-1.
Gain of 0.1 V/V,
DC-Coupled,
Single-Ended Source to
Differential Output
VS+
RG1
10 k
VS+
2.5 V
+
±
-2.5 V
VOUT
±
VS+
THS4552 Wideband,
Fully Differential Amplifier
RF1
1k
VOCM
VIN
FDA
+
+
±
RL
1k
±
PD
VS-
VS+
RF2
1k
RG2
10 k
Copyright © 2016, Texas Instruments Incorporated
Figure 9-7. Divide-by-10 Attenuator Application for the THS4552
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A 5 dB peaked response (see Figure 9-9) results from the configuration of Figure 9-7, which results from a
nominal 32° phase margin. This peaking can be eliminated by placing two feedback capacitors across the RF
elements and a differential input capacitor. Adding these capacitors provides a transition from a resistively set
noise gain (NG1 = 1.1 in Figure 9-7) to a capacitive divider at high frequency, and flattening out to a higher
noise gain (NG2). The key for this approach is to target a ZO where the noise gain begins to peak up. Using
only the following terms, and targeting a closed-loop flat (Butterworth) response, gives this solution sequence
(from Equation 11 to Equation 13) for ZO and then the capacitor values. See Wideband, Ultra-Low Noise,
Voltage-Feedback Operational Amplifier with Shutdown (page 12) for a discussion of this inverting noise gain
shaping technique.
•
•
•
•
Gain bandwidth product in Hz (135 MHz for the THS4552)
Low-frequency noise gain, NG1 (equal to 1.1 in the attenuator gain of a 0.1 V/V design)
The target high-frequency noise gain is selected to be higher than NG1 (NG2 = 5 V/V) in this example
Feedback resistor value, RF (is assumed balanced for this differential design = 1 kΩ)
From these elements, for any voltage feedback op amp or FDA, solve for ZO as shown in Equation 11:
ZO
GBP §
¨1
NG12 ¨©
NG1
NG2
1 2
NG1 ·
¸
NG2 ¸¹
(11)
From this target zero frequency in the noise gain, the feedback capacitors can be solved as Equation 12:
CF
1
2S ‡ RF ‡ ZO ‡ NG2
(12)
The next step is to resolve the input capacitance on the summing junction. Equation 13 is for a single-ended
op amp where the capacitor goes to ground. To use the capacitance (CS) resulting from Equation 13 for a
voltage-feedback FDA, cut the target value in half and place the resulting CS across the two inputs (reducing the
external value by the specified internal differential capacitance).
CS
NG2
1 CF
(13)
Using the computed capacitor values allows for an estimate of the resulting flat response bandwidth f–3dB
frequency, as shown in Equation 14:
f
3dB
|
GBP ‡ ZO
(14)
Running through these steps for the THS4552 in the attenuator circuit of Figure 9-7 provides the proposed
compensation of Figure 9-8, where Equation 14 estimates a bandwidth of 22 MHz (the ZO target is 3.5 MHz).
The solutions for CF gives 9 pF, where this value is reduced to 8.4 pF to account for the internal 0.6 pF feedback.
The single-ended solution for CS gives 36 pF, which is reduced to 18 pF to be differential, and is then further
reduced to 16.8 pF to account for the internal 1.2 pF differential input capacitance of the THS4552.
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CF1
8.4 pF
Gain of 0.1 V/V,
DC-Coupled,
Single-Ended Source to
Differential Output
VS+
VS+
RG1
10 k
VS-
2.5 V
±
-2.5 V
VOUT
±
VOCM
+
THS4552 Wideband,
Fully Differential Amplifier
RF1
1k
+
Vin
±
CS
16.8 pF
FDA
+
RL
1k
±
+
PD
VS-
VS+
RF2
1k
RG2
10 k
CF2
8.4 pF
Copyright © 2016, Texas Instruments Incorporated
Figure 9-8. Compensated Attenuator Circuit Using the THS4552
The 16.8 pF across the inputs is really a total of 36 pF for a single-ended design from Equation 13 reduced by
half and then the 1.2 pF internal capacitance is removed.
These two designs (with and without the compensation capacitors) were both bench tested and simulated using
the THS4552 TINA-TI™ model, which resulted in Figure 9-9. The TINA-TI™ simulation files used for Figure 9-9
are available both without the compensation capacitors and with the capacitors in place.
-12
-14
-16
Gain (dB)
-18
-20
-22
-24
-26
-28
-30
1M
Bench, wo Capacitors
Bench, with Capacitors
TINA-TI•, wo Capacitors
TINA-TI•, with Capacitors
10M
Frequency (Hz)
100M
D067
Figure 9-9. Attenuator Response Shapes With and Without External Capacitors
This approach does a good job of flattening the response for what starts out as a low phase margin attenuator
application. The simulation model does a very good job of predicting the peaking and showing the same
improvement with the external capacitors (both give a flat, approximately 24 MHz, closed-loop bandwidth for the
gain of 0.1 V/V design). The output noise starts to peak up (because of the noise gain shaping of the capacitors)
above 3.5 MHz in this example. These stages normally drive the RC filter at the input of a SAR ADC that filters
off the noise peaking above 3.5 MHz.
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9.1.9 The Effect of Adding a Feedback Capacitor
Adding a feedback capacitor to band-limit the signal path is very common in lower frequency designs. This
approach is very effective for the signal path gain but does create the potential for high-frequency peaking and
oscillation for a wideband device such as the THS4552. The feedback capacitor by itself takes the noise gain
to 1 V/V at high frequencies. Depending on the frequency where the noise gain goes to 1 V/V, and what added
phase margin reduction may already be in place resulting from the load RC, the feedback capacitors can cause
instability.
Figure 9-10 shows the starting point for a typical band-limited design. At lower frequencies, this example delivers
a gain of 10 V/V with an intentional band limit in the feedback RC at 320 kHz. This single 5 V design targets a
mid-supply output common-mode voltage with only a noise reduction capacitor on the VOCM input control.
CF1
250 pF
High-Gain, Single-Ended
to Differential Output Stage
with Feedback Pole
VS+
VS+
RG1
200
VS-
+
±
0V
10
±
VOCM
5V
THS4552 Wideband,
Fully Differential Amplifier
RF1
2k
+
VIN
10 nF
±
FDA
+
10 nF
±
+
SAR ADC
Input
PD
VS-
VS+
10
RF2
2k
RG2
200
CF2
250 pF
Copyright © 2016, Texas Instruments Incorporated
Figure 9-10. Single-Ended to Differential Stage with a Feedback Pole
The response shape must be probed at the FDA output pins before the added RC pole to the SAR input.
Running a wideband sweep with the THS4552 TINA-TI™ model using the SBOC475 simulation file shows a
resonance at 50 MHz in Figure 9-11 resulting from the feedback capacitor.
200
Gain (dB)
Phase (deg) 175
Gain (dB)
15
10
150
5
125
0
100
-5
75
-10
50
-15
25
-20
0
-25
-25
-30
100k
Phase (deg)
20
-50
1M
10M
Frequency (Hz)
100M
D070
Figure 9-11. Gain and Phase Plot with a Feedback Pole
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One approach to increasing the phase margin when there is a feedback capacitor is to include a differential
input capacitor. This approach increases the noise gain at higher frequencies, thus creating a lower-frequency
loop gain equal to a 0 dB crossover with more phase margin. Figure 9-12 shows a differential input capacitor
equal to the feedback capacitor in the test circuit. This approach increases the noise gain from 1 V/V at higher
frequencies (with only a feedback capacitor) to a noise gain of 3 V/V at higher frequencies.
CF1
250 pF
High-Gain, Single-Ended
to Differential Output Stage
with Feedback Pole
VS+
RF1
2k
VS+
RG1
200
VS-
+
±
0V
10
±
VOCM
5V
THS4552 Wideband,
Fully Differential Amplifier
+
VIN
250 pF
±
10 nF
FDA
+
10 nF
±
+
SAR ADC
Input
PD
VS-
VS+
10
RF2
2k
RG2
200
CF2
250 pF
Copyright © 2016, Texas Instruments Incorporated
Figure 9-12. Single-Ended to Differential Stage with a Feedback Pole and Differential Input Capacitor
Gain (dB)
20
10
200
Gain (dB)
Phase (deg) 160
0
120
-10
80
-20
40
-30
0
-40
-40
-50
-80
-60
100k
Phase (deg)
Re-running the wideband response (using the SBOC474 TINA-TI™ simulation file) simulation illustrates in
Figure 9-13 that the resonance is greatly reduced with the higher noise gain at the loop gain equal to a 0 dB
crossover at a lower frequency. Although this example is only modestly peaking, good design practice is to
include a place for a differential input capacitor (even if not used) for any design using a feedback capacitor
across the feedback resistors. This recommendation applies to this simple example and to multiple feedback
active filter designs.
-120
1M
10M
Frequency (Hz)
100M
D071
Figure 9-13. Gain and Phase Plot with a Differential Input Capacitor
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9.2 Typical Applications
9.2.1 An MFB Filter Driving an ADC Application
One common application for the THS4552 is to take a single-ended, high VPP voltage swing (from a high-voltage
precision amplifier such as the OPA192) and deliver that swing to precision SAR ADC as a single-ended to
differential conversion with output common-mode control and implement an active 2nd-order multiple feedback
(MFB) filter design. Designing for a 40 VPP maximum input down to an 8 VPP differential swing requires a gain
of 0.2 V/V. Targeting a 100 kHz Butterworth response with the RC elements tilted towards low noise gives the
example design of Figure 9-14. Note that the VCM control is set to half of a 4.096 V reference, which is typical for
5 V differential SAR applications.
OPA192 Output
VS+
5V
+
2.96 k
VS0V
±
RG1
1.57 k
910 pF
100 pF
VS+
+
±
10
20
VIN
±
1.5 nF
100 fF
VOCM
FDA
+
VS+
±
10
20
2.96 k
RG2
1.57 k
RF2
592
8-VPP Differential
SAR ADC Input
PD
VS-
+
2.2 nF
±
+
VOCM
2.048 V
THS4552 Wideband,
Fully Differential Amplifier
RF1
592
100 pF
910 pF
Copyright © 2016, Texas Instruments Incorporated
Figure 9-14. Example 100 kHz Butterworth Filter
9.2.1.1 Design Requirements
The requirements for this application are:
•
•
•
•
•
Single-ended to differential conversion
Attenuation by 0.2 V/V gain
Active filter set to a Butterworth, 100 kHz response shape
Output RC elements set by SAR input requirements (not part of the filter design)
Filter element resistors and capacitors are set to limit added noise over the THS4552 and noise peaking
9.2.1.2 Detailed Design Procedure
The design proceeds using the techniques and tools suggested in the Design Methodology for MFB Filters in
ADC Interface Applications. The process includes:
•
•
•
•
•
•
50
Scale the resistor values to not meaningfully contribute to the output noise produced by the THS4552 by itself
Select the RC ratios to hit the filter targets when reducing the noise gain peaking within the filter design
Set the output resistor to 10 Ω into a 2.2 nF differential capacitor
Add 100 pF common-mode capacitors to the load capacitor to improve common noise filtering
Inside the loop, add 20 Ω output resistors after the filter feedback capacitor to increase the isolation to the
load capacitor
Include a place for a differential input capacitor (illustrated as 100 fF in Figure 9-14)
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9.2.1.3 Application Curves
Probing the response to the output pins by using the THS4552 SBOC471 TINA-TI™ simulation model (before
the RC filter to the SAR ADC) illustrates the expected response plus some peaking at higher frequencies. Any
signal or noise peaking that appears at the output because of this peaking is rolled off by the RC filter between
the FDA and SAR inputs. A place for a differential input capacitor is illustrated in Figure 9-14 (as 0.1 pF) but
is not used for this simulation. This slight peaking is a combination of low phase margin and feedthrough via
the feedback capacitor to the increasing open-loop output impedance of Figure 8-3. The loop gain and phase
response are available as a TINA-TI™ simulation file.
Obtaining the SNR to the ADC input pins, and assuming an 8 VPP full scale (2.83 VRMS), gives the result of
Figure 9-16. The 113 dB SNR shown in Figure 9-16 does not limit the performance for any SAR application.
-40
150
-60
0
-80
-150
-100
-300
-120
-450
T
Signal to Noise [dB]
-20
450
Gain (dB)
Phase (deg) 300
Phase (deg)
Gain (dB)
0
150.00
140.00
130.00
120.00
110.00
-140
10k
100k
1M
Frequency (Hz)
10M
-600
100M
10k
100k
1MEG
10MEG
Frequency (Hz)
100MEG
Figure 9-16. Signal-to-Noise Ratio Plot
D072
Figure 9-15. Gain and Phase Plot for a 100 kHz
Butterworth Filter
9.2.2 Differential Transimpedance Output to a High-Grade Audio PCM DAC Application
The highest-grade audio digital-to-analog converters (DACs) are a differential current-mode output. These
devices normally suggest a two-amplifier transimpedance stage to hold the DAC output voltages fixed when
the amplifiers produce a differential voltage swing at the outputs. Often, the differential voltage swing is
then converted to single-ended in a differencing amplifier stage to drive headphone loads (see Figure 35
in the OPA161x SoundPlus™ High-Performance, Bipolar-Input Audio Operational Amplifiers). The emerging
high-power class D audio amplifiers often require differential inputs. Applying the THS4552 as a differential
transimpedance stage offers a simple solution for very low-distortion, differential-output audio channels.
Starting with the output specifications for a very high-performance PCM1792A audio DAC, the requirements for
the THS4552 interface can be extracted. The DAC is a current-sourcing device that requires its outputs to be
held at ground when using a transimpedance amplifier. Using the DAC 3.3 V supply and the LM27762 low-noise,
low-dropout (LDO) regulator and inverter provides a ±2.5 V supply to the THS4552. Operating the THS4552 on
±2.5 V supplies places all nodes in range for an input VCM equal to GND (and the DAC output voltages as well)
and an FDA output VOCM also equal to GND.
The center current in Table 9-2 is a fixed 6.2 mA dc current coming out of the DAC outputs regardless of the
DAC code. This dc common-mode current can be absorbed by the –2.5 V supply at the input pins to hold the
DAC compliance voltage and FDA input pins at ground. The FDA controls the output common-mode voltage,
set to ground in this case, whereas the input pin voltage (which does not move with the DAC output differential
current) is controlled with a resistor to the negative supply.
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Table 9-2. PCM1792A Analog Output Specification
ANALOG OUTPUT
TEST CONDITION
MIN
TYP
MAX
–6
±2
6
% of FSR
–3
±0.5
3
% of FSR
–2
±0.5
2
% of FSR
Gain error
Gain mismatch, channel-to-channel
Bipolar zero (BPZ) error
At BPZ
Output current
Full-scale (0 dB)
Center current
At BPZ
UNIT
7.8
mAPP
–6.2
mA
This bias is provided by the 402 Ω resistors to –2.5 V, as illustrated in Figure 9-17. This design takes the
differential 7.8 mAPP from the DAC and produces a ±1.46 V swing on each output of the THS4552. This
configuration gives a full-scale differential 5.85 VPP available on the ±2.5 V supply design centered at ground
at both the inputs and outputs. Although the LM27762 provides a very-low noise, –2.5 V supply, using 0.1%
resistors in the current sink path to the –2.5 V supply as well as the feedback resistors limits any common-mode
noise on the –2.5 V supply to differential mode conversion at the FDA outputs.
CF1
2.4 nF
VS+
4.4
VS-
THS4552 Wideband,
Fully Differential Amplifier
VS2.5 V
+
±
-2.5 V
+
LM27762
Supplies
RF1
750
6.2 mA
±
402
VS+
±
VOCM
PCM1792A
Complementary Current
Output DAC
FDA
±
+
20 nF
PD
VS-
6.2 mA
+
VS+
RF2
750
402
VS-
CF2
2.4 nF
4.4
Copyright © 2016, Texas Instruments Incorporated
Figure 9-17. PCM1792A DAC Output Driver
9.2.2.1 Design Requirements
To implement a differential transimpedance output interface to the PCM1792A DAC, the following requirements
must be met:
•
•
•
•
•
52
The center current of the DAC must be considered to hold the DAC output voltage at ground. Using an FDA
controls the output side common-mode voltage, but the input common-mode voltage must also be controlled
to ground.
A direct means of sinking the center current is to add a pulldown resistor at the DAC outputs to a negative
supply. Generating a ±2.5 V supply for this current sink requirement and the THS4552 is accomplished with
the LM27762.
The transimpedance gain can be set using the feedback resistors of the THS4552 FDA. These resistors are
very flexible, but when set, the bandwidth in this stage is set to 88 kHz using a feedback capacitor in parallel
with the resistive gain element.
When the feedback capacitor is set, a differential input capacitor is added to increase the high-frequency
noise gain for the overall loop gain stability.
These frequency response control capacitors interact with the inductive open-loop output impedance to form
a high-frequency resonance. Adding a small series resistor to the feedback capacitor paths reduces this
effect.
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9.2.2.2 Detailed Design Procedure
Proceed with this design using the techniques described in the Design for Wideband Differential
Transimpedance DAC Output:
•
•
•
•
•
•
•
Generate the bipolar balanced supplies using the LM27662.
Set the THS4552 output common-mode voltage at midsupply by grounding the VOCM pin.
Control the input pin operating voltage by sinking the center current out of the DAC to the –2.5 V supply with
precision 402 Ω resistors.
Set the gain for the complementary current output signal from the DAC by selecting the feedback resistor to
be 750 Ω. Set this resistor to keep the resulting output swing to be less than the available 9 VPP differential
swing.
Control the bandwidth in this differential transimpedance stage to 88 kHz using the 2.4 nF feedback capacitor
on each side.
Increase the high-frequency noise gain to 17.7 V/V by adding a differential input capacitor of 20 nF.
Isolate these feedback capacitors with a series 4.4 Ω resistor in series with the feedback capacitors.
9.2.2.3 Application Curves
Gain (dB)
70
65
240
Gain (dB)
Phase (deg) 200
60
160
55
120
50
80
45
40
40
0
35
-40
30
-80
25
-120
20
1k
10k
100k
1M
Frequency (Hz)
10M
Phase (deg)
The bandwidth is controlled to 88 kHz by using the 2.4 nF feedback capacitors. Amplifier stability is controlled
by the 20 nF differential capacitor across the DAC outputs. The added 4.4 Ω in series with the feedback 2.2
nF capacitor isolates this capacitance from the inductive open-loop output impedance. To observe the effect
of adding these small resistors in series with the feedback capacitors, use the TINA-TI™ loop gain simulation
circuit. Include the DAC source capacitance in any final design analysis. Running the frequency response for
this circuit (available as a TINA-TI™ simulation file) provides this result. The 63.5 dBΩ gain is the 1.5 kΩ
transimpedance gain provided in this design.
-160
100M
D074
Figure 9-18. Gain and Phase Plot of DAC Output Driver
Running a full-scale sine wave at 1 kHz with ±1.95 mA on each output from the DAC at 180° out of phase,
and probing each THS4552 output pin separately results in the expected ±1.46 V on each output pin, as shown
in Figure 9-19. More output swing is available for the RRO device using the ±2.5 V supplies provided by the
LM27762 by simply increasing the feedback resistor values.
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2.5
VOUTVOUT+
2
Output Voltage (V)
1.5
1
0.5
0
-0.5
-1
-1.5
-2
-2.5
0
0.2
0.4
0.6
0.8
1
1.2
Time (ms)
1.4
1.6
1.8
2
D075
Figure 9-19. Output Waveform of the DAC Output Driver
Although this example is on the audio signal generation side, the THS4552 can also be used to convert a
single-ended line input to a differential driver into an audio ADC.
9.2.3 ADC3k Driver with a 2nd-Order RLC Interstage Filter Application
The THS4552 is well suited to low-power, dc-coupled requirements driving low-power pipeline ADCs (such as
the ADC3241 25-MSPS, 14-bit, dual device). Figure 9-20 shows an example design taking a bipolar input to a
–1 dBFS swing at the ADC input of 1.8 VPP. In this case, a 50 Ω source and input matching is assumed with a
gain of 5 V/V to the output pins with a 2nd-order interstage filter adding a –1 dB insertion loss. Full-scale voltage
at the input of RT and RG1 is then ±0.2 V. The 0.95 V output common-mode voltage is provided by the ADC. The
output filter provides a noise-power bandwidth limit with a low overshoot step response with no common-mode
level shift from the 0.95 V voltage provided by the ADC.
3.3 V
VS+
VS-
+
+
0V
±
ADC Output
Common-Mode
Voltage
50- Input Match,
Gain of 5 V/V from RT,
Single-Ended Source to
Differential Output
RF1
1k
50- Source
Impedance
±
10-MHz,
Second-Order
Bessel Filter
VS+
RG1
187
RS1
50
40.2
390 nH
5.6
VOUT
±
VOCM
VIN
950 mV
THS4552 Wideband,
Fully Differential Amplifier
+
RT1
59
VOCM
FDA
+
+
±
RG2
215
360 pF
±
ADC3241
Inputs
732
PD
VS-
VS+
40.2
390 nH
5.6
RF2
1k
Copyright © 2016, Texas Instruments Incorporated
Figure 9-20. ADC3k Driver with a 2nd-Order RLC Interstage Filter
9.2.3.1 Design Requirements
For this design example, the requirements include:
•
•
•
•
•
54
Provide a wideband, 50 Ω input impedance match for a single-ended source centered on ground.
From the input termination, provide a gain of 5 V/V to the FDA output pins as a differential signal.
Set the output common-mode operating point using the ADC common-mode output voltage as the VOCM
input to the THS4552 FDA.
Implement a low-overshoot, noise-band-limiting filter between the FDA and the ADC. Use only differential
shunt elements in the filter to pass the FDA output common-mode voltage to the ADC with no level shifting.
Design the filter as a –1 dB insertion loss filter with a low series resistor to limit the common-mode level shift
resulting from the ADC input sample-rate-dependent common-mode current.
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9.2.3.2 Detailed Design Procedure
The design proceeds as follows:
•
•
•
•
•
•
•
Select the feedback resistor to be 1 kΩ and use the values from Table 8-1 at a gain of 5 V/V to implement a
50 Ω input match with a gain of 5 V/V.
Use a 3.3 V power supply and apply the ADC output common-mode voltage to the VOCM input pin of the
THS4552.
Design a –1 dB insertion loss, 2nd-order RLC filter using the approach described in the RLC Filter Design for
ADC Interface Applications.
Adjust the total resistive load target in the filter design to hit the standard value for the filter inductors.
Convert the filter design to differential with only differential shunt elements. These elements must not be split
and connected to a center-point ground. This technique passes the output common-mode voltage from the
FDA to the ADC with no level shift error.
Add a small series resistor at the ADC inputs. This resistor is not part of the filter design but spreads out the
sampling glitch energy to provide improved SFDR.
Check the common-mode level shift from the FDA outputs to the ADC resulting from the clock-ratedependent common-mode current. This common-mode current into the ADC shifts the common-mode
voltage slightly, but can easily stay in range with a low series resistor in the filter design.
9.2.3.3 Application Curve
Driving a 2 MHz ±0.2 V square wave into this circuit (using a TINA-TI™ simulation file for the circuit of Figure
9-20) gives the response shown in Figure 9-21 at the ADC. The red trace is a –1 dBFS, 1.8 VPP square wave
at the ADC input pins. The gray trace is the input signal at the RT termination resistor. The black trace is the
common-mode voltage at the FDA input pins. Note that the input pin voltage swing stays above ground and in
range for this bipolar input, single, 3.3 V supply design.
1.5
1
Voltage (V)
0.5
0
-0.5
VIN+
VOUT
VIN
-1
-1.5
0
100
200
300
400 500 600
Time (ns)
700
800
900 1000
D076
Figure 9-21. Time-Domain Waveform
Unbuffered pipeline ADCs draw a clock-rate-dependent input common-mode current. For the ADC3241, this
input current is specified as 1.5 µA per MSPS. Operating at 25 MSPS, the common-mode current drops the
common-mode voltage from 0.95 V at the THS4552 outputs by 37.5 µA × 45.8 Ω = 1.7 mV to 0.9483 V. This
value is well within the allowed ±25 mV common-mode deviation from the ADC VCM output. Consider this effect
carefully when using higher resistor values in the interface at the ADC.
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10 Power Supply Recommendations
The THS4552 is principally intended to operate with a nominal single-supply voltage of 3 V to 5 V. Supply
voltage tolerances are supported with the specified operating range of 2.7 V (10% low on a 3 V nominal supply)
and 5.4 V (8% high on a 5 V nominal supply). Supply decoupling is required, as described in Section 7.7. Split
(or bipolar) supplies can be used with the THS4552, as long as the total value across the device remains less
than 5.5 V (absolute maximum). The thermal pad on the RTW package is electrically isolated form the die;
connect the thermal pad (RTW package only) to any power or ground plane for reduced thermal impedance to
the junction temperature. This pad must be connected to some power or ground plane and not floated.
For the best input offset voltage drift, the THS4552 uses a proportional to absolute temperature (PTAT)
quiescent current biasing scheme. This approach gives a positive over temperature variation in supply current.
Figure 10-1 shows the 5 V supply current over a wide TJ range for a number of tested units. The tables in
Section 6.5 report the typical and range on this supply current temperature coefficient for both 5 V and 3 V
supply operation.
1.8
Supply Current (mA)
1.7
1.6
1.5
1.4
1.3
1.2
1.1
1
-45 -30 -15
0
15 30 45 60 75 90 105 120 135
Junction Temperature (qC)
D068
Figure 10-1. Linear Temperature Coefficient for Supply Current
Using a negative supply to deliver a true swing to ground output when driving SAR ADCs can be desired.
Although the THS4552 quotes a rail-to-rail output, linear operation requires approximately 200 mV headroom
to the supply rails. One easy option for extending the linear output swing to ground is to provide the small
negative supply voltage required using the LM7705 fixed –230 mV, negative-supply generator. This low-cost,
fixed, negative-supply generator can accept the 3 V to 5 V positive supply input used by the THS4552 and
provides a fixed –230 mV supply for the negative power supply. Using the LM7705 provides an effective solution,
as discussed in the Extending Rail-to-Rail Output Range for Fully Differential Amplifiers to Include True Zero
Volts.
10.1 Thermal Analysis
The very low internal quiescent power dissipation for the THS4552, combined with the excellent thermal
impedance of the 24-pin VQFN package (RTW), limits the possibility of excessively high internal junction
temperatures.
To estimate the internal TJ, an estimate of the maximum internal power dissipation is first required. There are
two pieces to the internal power dissipation: quiescent current power and the power used in the output stage
to deliver load current. To simplify the latter, the worst-case output stage power drives a dc differential voltage
across a load using half the total supply voltage. Also assume a maximum ambient temperature of 125°C, giving
the maximum quiescent current as shown in Figure 10-1. As an example:
•
•
56
Assume a maximum operating supply voltage of 5.4 V. This 5.4 V supply with a maximum ICC of 1.46 mA/
channel gives a quiescent power term of 2 × 1.46 mA × 5.4 V = 15.77 mW.
Assume a 200 Ω differential load with a static 2.7 V differential voltage established across the load for both
channels. The 1.35 mA of dc load current generates a maximum output stage power of (5.4 V – 2.7 V) × 1.35
mA = 3.65 mW/channel and a total power dissipation of 7.3 mW for both channels.
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•
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From the worst-case total internal PD of 23.07 mW, multiplying the internal PD with a 46°C/W thermal
impedance for the 24-pin VQFN package results in a 1.06°C rise from ambient.
Even for this extreme condition and the maximum-rated ambient of 125°C, the junction temperature is a
maximum of 126°C, which is less than the rated absolute maximum of 150°C. Follow this same calculation
sequence for the exact application and package selected to predict the maximum TJ.
11 Layout
11.1 Layout Guidelines
11.1.1 Board Layout Recommendations
Similar to all high-speed devices, best system performance is achieved with close attention to board layout. The
THS4552PW Evaluation Module shows a good example of high-frequency layout techniques as a reference.
This EVM includes numerous extra elements and features for characterization purposes that may not apply to
some applications. General high-speed signal path layout suggestions include:
•
•
•
•
•
Continuous ground planes are preferred for signal routing with matched impedance traces for longer runs;
however, both ground and power planes must be opened up around the capacitive sensitive input and output
device pins. When the signal goes to a resistor, parasitic capacitance becomes more of a band-limiting issue
and less of a stability issue.
Good high-frequency decoupling capacitors (0.1 µF) are required to a ground plane at the device power
pins. Additional higher-value capacitors (2.2 µF) are also required but can be placed further from the device
power pins and shared among devices. For best high-frequency decoupling, consider X2Y supply decoupling
capacitors that offer a much higher self-resonance frequency over standard capacitors.
Differential signal routing over any appreciable distance must use microstrip layout techniques with matched
impedance traces.
Higher-speed FDAs such as the THS4552 include a duplicate of the output pins on the input feedback side of
the larger 24-pin VQFN (RTW) package. This feature is intended to allow the external feedback resistors to
be connected with virtually no trace length on the input side of the package. This internal feedback trace also
provides a second feedback path for connecting a feedback capacitor on the input pin sides for band-limited
or multiple feedback filter designs. This internal trace shows an approximate 3.3 Ω series resistance that
must be considered in any design using that path. The TINA-TI™ model does not include that element (to be
generally applicable to all package styles) and must be added externally if the RTW package is used. Use
this layout approach without extra trace length on the critical feedback path.
The input summing junctions are very sensitive to parasitic capacitance. Any RG elements must connect into
the summing junction with minimal trace length to the device pin side of the resistor. The other side of the RG
elements can have more trace length if needed to the source or to GND.
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11.2 Layout Example
Figure 11-1. Example Layout
58
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11.3 EVM Board
Figure 11-2 and Figure 11-3 show the layout of the top and bottom layers of the THS4552PWEVM evaluation
module, respectively.
Figure 11-2. THS4552PWEVM Top Layer
Figure 11-3. THS4552PWEVM Bottom Layer
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12 Device and Documentation Support
12.1 Device Support
12.1.1 TINA-TI™ Simulation Model Features
The device model is available in the product folder under www.ti.com in a typical application circuit file. The
model includes numerous features intended to speed designer progress over a wide range of application
requirements. The following list shows the performance parameters included in the model:
•
•
•
•
For the small-signal response shape with any external circuit:
– Differential open-loop gain and phase
– Parasitic input capacitance
– Open-loop differential output impedance
For noise simulations:
– Input differential spot voltage noise and a 100 Hz 1/f corner
– Input current noise on each input with a 6 kHz 1/f corner
For time-domain, step-response simulations:
– Differential slew rate
– I/O headroom models to predict clipping
– Input stage diodes to predict overdrive limiting
Fine-scale, dc precision terms:
– PSRR
– CMRR
Section 6.9 provides more detail than the macromodels can provide; some of the unmodeled features include:
•
•
•
•
Harmonic distortion
Temperature drift in dc error terms (VIO and IOS)
Overdrive recovery time
Turn-on and turn-off times using the power-down feature
Some unique simulation considerations come with the THS4552 TINA-TI™ model. This device (and model)
include 0.6-pF internal feedback capacitors. These capacitors are intended to improve phase margin when using
higher external feedback resistor values. Higher feedback resistors generate an in-band pole in the feedback
signal with the differential input capacitance, and the internal 0.6 pF capacitors add a zero to the feedback
response shape to shape the noise gain flat at the loop-gain crossover.
In order to generate an accurate open-loop gain and phase simulation, these components must be removed
because they are feedback elements, not forward path elements. Figure 12-1 illustrates a typical AOL gain
and phase simulation (available as a TINA-TI™ software file) where external –0.6-pF capacitors cancel out the
internal capacitors in the model (TINA-TI™ supports negative value elements). The inductors inside the loop
close the loop for the dc operating point and open the loop immediately for an ac sweep. The input-coupling
capacitors are open at dc, then couple in the differential input immediately on an ac sweep. The somewhat odd
values help reduce numerical chatter in the simulation. When using the internal feedback traces from the outputs
to the inputs on the RTW package, be sure to add the 3.3-Ω trace impedance to any simulation. This impedance
is not included in the core model.
60
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VS±
C2 -600 fF
C3 9.97 kF
V
VIN+
-
VM1
VOCM
VIN+
VCVS1 1
+
+
-
-
R4
10 M:
C4 9.97 kF
VG1
R5
10 M:
+
VOCM
+
L2 999 H
+
U1 THS4552
VIN-
-
VS±
+
R3 100 k:
V2 -2.5
VS+
V1 2.5
+
-
VS+
V4 0
L1 999 H
VS+
VOCM
R1 10 m:
C1 -600 fF
VINR2 10 m:
Copyright © 2016, Texas Instruments Incorporated
Figure 12-1. Open-Loop Gain and Phase TINA-TI™ Simulation Setup
This test is set up with a very light load to isolate the no load AOL curve. Adding a load brings in the open-loop
ZOL response to the overall response of the output pins. Running this simulation gives the gain and phase of
Figure 12-2 that closely matches the plot of Figure 6-37.
Gain (dB)
T 200.00
100.00
0.00
-100.00
Phase [deg]
0.00
-100.00
-200.00
-300.00
-400.00
10.00
100.00
1.00k
10.00k
100.00k
1.00MEG
10.00MEG
100.00MEG 1.00G
Frequency (Hz)
Figure 12-2. Open-Loop Gain and Phase Simulation Result
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12.2 Documentation Support
12.2.1 Related Documentation
See the following for related documentation:
• Texas Instruments, 24-Bit, 192-kHz Sampling, Advanced Segment, Audio Stereo Digital-to-Analog Converter
data sheet
• Texas Instruments, ADC322x Dual-Channel, 12-Bit, 25-MSPS to 125-MSPS, Analog-to-Digital Converters
data sheet
• Texas Instruments, ADC324x Dual-Channel, 14-Bit, 25-MSPS to 125-MSPS, Analog-to-Digital Converters
data sheet
• Texas Instruments, ADS127L01 24-Bit, High-Speed, Wide-Bandwidth Analog-to-Digital Converter data sheet
• Texas Instruments, ADS127L01 Evaluation Module User's Guide
• Texas Instruments, ADS9110 18-Bit, 2-MSPS, 15-mW, SAR ADC with multiSPI™ Interface data sheet
• Texas Instruments, Design Methodology for MFB Filters in ADC Interface Applications application notes
• Texas Instruments, Design for Wideband Differential Transimpedance DAC Output application reports
• Texas Instruments, Extending Rail-to-Rail Output Range for Fully Differential Amplifiers to Include True Zero
Volts reference guide
• Texas Instruments, INA188 Precision, Zero-Drift, Rail-to-Rail Out, High-Voltage Instrumentation Amplifier data
sheet
• Texas Instruments, LM27762 Low-Noise Regulated Switched-Capacitor Voltage Inverter data sheet
• Texas Instruments, LM7705 Low-Noise Negative Bias Generator data heet
• Texas Instruments, LMH6629 Ultra-Low Noise, High-Speed Operational Amplifier with Shutdown data sheet
• Texas Instruments, OPAx192 36-V, Precision, Rail-to-Rail Input/Output, Low Offset Voltage, Low Input Bias
Current Op Amp with e-trim™ data sheet
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62
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Copyright © 2021 Texas Instruments Incorporated
Product Folder Links: THS4552
THS4552
www.ti.com
SBOS831B – DECEMBER 2016 – REVISED JUNE 2021
12.3 Receiving Notification of Documentation Updates
To receive notification of documentation updates, navigate to the device product folder on ti.com. Click on
Subscribe to updates to register and receive a weekly digest of any product information that has changed. For
change details, review the revision history included in any revised document.
12.4 Support Resources
TI E2E™ support forums are an engineer's go-to source for fast, verified answers and design help — straight
from the experts. Search existing answers or ask your own question to get the quick design help you need.
Linked content is provided "AS IS" by the respective contributors. They do not constitute TI specifications and do
not necessarily reflect TI's views; see TI's Terms of Use.
12.5 Trademarks
TINA-TI™ are trademarks of Texas Instruments.
SoundPlus™ is a trademark of Texas Instruments, Inc.
TI E2E™ is a trademark of Texas Instruments.
All trademarks are the property of their respective owners.
12.6 Electrostatic Discharge Caution
This integrated circuit can be damaged by ESD. Texas Instruments recommends that all integrated circuits be handled
with appropriate precautions. Failure to observe proper handling and installation procedures can cause damage.
ESD damage can range from subtle performance degradation to complete device failure. Precision integrated circuits may
be more susceptible to damage because very small parametric changes could cause the device not to meet its published
specifications.
12.7 Glossary
TI Glossary
This glossary lists and explains terms, acronyms, and definitions.
13 Mechanical, Packaging, and Orderable Information
The following pages include mechanical, packaging, and orderable information. This information is the most
current data available for the designated devices. This data is subject to change without notice and revision of
this document. For browser-based versions of this data sheet, refer to the left-hand navigation.
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Product Folder Links: THS4552
63
PACKAGE OPTION ADDENDUM
www.ti.com
28-Sep-2021
PACKAGING INFORMATION
Orderable Device
Status
(1)
Package Type Package Pins Package
Drawing
Qty
Eco Plan
(2)
Lead finish/
Ball material
MSL Peak Temp
Op Temp (°C)
Device Marking
(3)
(4/5)
(6)
THS4552IPWR
ACTIVE
TSSOP
PW
16
2500
RoHS & Green
NIPDAU
Level-2-260C-1 YEAR
-40 to 125
THS4552
THS4552IPWT
ACTIVE
TSSOP
PW
16
250
RoHS & Green
NIPDAU
Level-2-260C-1 YEAR
-40 to 125
THS4552
THS4552IRTWR
ACTIVE
WQFN
RTW
24
3000
RoHS & Green
NIPDAU
Level-1-260C-UNLIM
-40 to 125
THS4552
IRTW
THS4552IRTWT
ACTIVE
WQFN
RTW
24
250
RoHS & Green
NIPDAU
Level-1-260C-UNLIM
-40 to 125
THS4552
IRTW
(1)
The marketing status values are defined as follows:
ACTIVE: Product device recommended for new designs.
LIFEBUY: TI has announced that the device will be discontinued, and a lifetime-buy period is in effect.
NRND: Not recommended for new designs. Device is in production to support existing customers, but TI does not recommend using this part in a new design.
PREVIEW: Device has been announced but is not in production. Samples may or may not be available.
OBSOLETE: TI has discontinued the production of the device.
(2)
RoHS: TI defines "RoHS" to mean semiconductor products that are compliant with the current EU RoHS requirements for all 10 RoHS substances, including the requirement that RoHS substance
do not exceed 0.1% by weight in homogeneous materials. Where designed to be soldered at high temperatures, "RoHS" products are suitable for use in specified lead-free processes. TI may
reference these types of products as "Pb-Free".
RoHS Exempt: TI defines "RoHS Exempt" to mean products that contain lead but are compliant with EU RoHS pursuant to a specific EU RoHS exemption.
Green: TI defines "Green" to mean the content of Chlorine (Cl) and Bromine (Br) based flame retardants meet JS709B low halogen requirements of