BB OPA628AU

®
OPA628
OPA
628
Low Distortion Wideband
OPERATIONAL AMPLIFIER
FEATURES
APPLICATIONS
● EXCELLENT DIFFERENTIAL GAIN: 0.015%
● EXCELLENT DIFFERENTIAL PHASE: 0.015°
● BROADCAST QUALITY VIDEO
● LOW DISTORTION: 90dB SFDR
● TWO-TONE THIRD-ORDER INTERCEPT:
60dBm
● LOW NOISE: 2.5nV/√Hz
● LOW NOISE FIGURE: 9dB
● MEDICAL IMAGING
● LOW NOISE PREAMPLIFIER
● PRECISION ADC/DAC BUFFER
● TELECOMMUNICATIONS
● ANALYTICAL INSTRUMENTS
● ACTIVE FILTERS
● DC RESTORATION CIRCUITS
● BANDWIDTH (Gain = +1): 160MHz
● 0.1dB GAIN FLATNESS: 30MHz
● LOW OFFSET VOLTAGE: 500µV
DESCRIPTION
The OPA628 is a low distortion, wideband operational
amplifier. It features low differential gain error of
0.015% and low differential phase error of 0.015° at
NTSC and PAL frequencies with a 150Ω load (a backterminated 75Ω cable). The 0.1dB gain flatness to
30MHz, and the excellent differential gain and phase
make the OPA628 ideal for broadcast quality video
applications. In addition, the spurious free dynamic
range of 90dB makes the OPA628 an excellent choice
to buffer the input of precision Analog-to-Digital converters. It can also be used to provide a buffer for the
output of precision high speed Digital-to-Analog converters. The two-tone third-order intercept of the
OPA628 is 60dBm.
The OPA628 is a unity gain stable, voltage feedback
operational amplifier. It has all of the benefits associated with voltage feedback amplifiers including
high input impedance, high common mode rejection,
and symmetrical differential input flexibility. The
unity gain bandwidth of the OPA628 is 160MHz. The
low noise of 2.5nV/√Hz and low noise figure of 9dB
(RS = 50Ω) make the OPA628 very useful in precision applications requiring wide dynamic range.
additionally enhanced by separating the power supplies to the input and output stages requiring four
power supply connections as shown in the block
diagram below. This separation of supplies eliminates
the effects of package and wire bond parasitic capacitance and inductance. The OPA628 is powered with
±5VDC supplies for low power dissipation. The
OPA628 is available in 8-pin SOIC package. The
temperature range is –40°C to +85°C.
+VCC, Input Stage
+VCC, Output Stage
8
7
Active
Load
Non-Inverting
Input
3
6
+1
Output
2
Inverting
Input
The superior distortion performance of the OPA628 is
achieved by its multistage architecture which provides
high open-loop gain. The distortion performance is
5
4
–VCC, Input Stage
–VCC, Output Stage
International Airport Industrial Park • Mailing Address: PO Box 11400, Tucson, AZ 85734 • Street Address: 6730 S. Tucson Blvd., Tucson, AZ 85706 • Tel: (520) 746-1111 • Twx: 910-952-1111
Internet: http://www.burr-brown.com/ • FAXLine: (800) 548-6133 (US/Canada Only) • Cable: BBRCORP • Telex: 066-6491 • FAX: (520) 889-1510 • Immediate Product Info: (800) 548-6132
®
©
1993 Burr-Brown Corporation
PDS-1204B
1
OPA628
Printed in U.S.A. March, 1998
SPECIFICATIONS
ELECTRICAL
At VCC = ±5VDC, RL=100Ω, G = +2, and TA = +25°C, unless otherwise noted.
OPA628AU
PARAMETER
CONDITIONS
INPUT NOISE
Voltage: RS = 0Ω
MIN
fO = 100Hz
fO = 1kHz
fO = 10kHz
fO = 100kHz
fO = 1MHz to 100MHz
fB = 100Hz to 10MHz
fO = 100kHz to 100MHz
RS = 50Ω, fO = 1MHz to 100MHz
Current
Noise Figure
OFFSET VOLTAGE
Input Offset Voltage
Average Drift
Supply Rejection (PSRR)
Over Specification Temperature
INPUT BIAS CURRENT
Input Bias Current
Over Specification Temperature
Input Offset Current
Over Specification Temperature
±VCC
OPEN-LOOP GAIN, DC
Open-Loop Voltage Gain
Over Specification Temperature
FREQUENCY RESPONSE
Closed-Loop Bandwidth
(–3dB)
Bandwidth 0.1dB Flat
Differential Gain
Differential Phase
Harmonic Distortion
3rd-Order Intercept
3rd-Order Intercept
Two-tone 3rd-Order Intercept
Full Power Response(1)
Slew Rate
Overshoot
Settling Time: 0.10%
0.01%
Overload Recovery Time(2)
Phase Margin
Rise Time
Small Signal
Large Signal
Output Resistance
Load Capacitance Stability
Short Circuit Current
Short Circuit Current
nV/√Hz
nv/√Hz
nV/√Hz
nV/√Hz
nV/√Hz
µVrms
pA/√Hz
dB
±1
mV
µV/°C
dB
dB
VCM = 0VDC
VCM = 0VDC, TA = TMIN to TMAX
VCM = 0VDC
TA = TMIN to TMAX
15
22
±0.3
±0.8
30
µA
µA
µA
µA
Open–Loop
30 || 2
10 || 6
kΩ || pF
MΩ || pF
±2.5
110
105
V
dB
dB
100
96
dB
dB
160
77
24
30
0.015
0.015
MHz
MHz
MHz
MHz
%
degrees
–91
–98
dBc
dBc
–90
–97
dBc
dBc
–83
–87
70
60
60
20
49
310
2
20
64
60
60
dBc
dBc
dBm
dBm
dBm
MHz
MHz
V/µs
%
ns
ns
ns
degrees
3
15
ns
ns
±3
±3
0.0005
20
+180
–130
V
V
V
Ω
pF
mA
mA
VCM
VCM = ±2.5V
= ±2.5V, TA = TMIN to TMAX
90
90
90
TA = TMIN to TMAX
Gain = +1V/V
Gain = +1V/V, 10% to 90%
VO = 100mVp-p
VO = 6Vp-p
fO = 1MHz, RL = 100Ω
fO = 1MHz, RL = 100Ω, TA = TMIN to TMAX
fO = 1MHz, RL = 50Ω
1MHz, Gain = +1V/V
Gain = +1V/V, VO = 2Vp-p
Continuous, Source
Continuous, Sink
®
OPA628
UNITS
±0.5
±6
105
100
Gain = +1V/V
Gain = +2V/V
Gain = +5V/V
Gain = +2V/V
3.58MHz, Gain = +2, VO = 1.4V Ramp
3.58MHz, Gain = +2, VO = 1.4V Ramp
RL = 100Ω, G = +1V/V, f = 5MHz, VO = 2Vp-p
Second Harmonic
Third Harmonic
RL = 500Ω, G = +2V/V, f = 5MHz, VO = 2Vp-p
Second Harmonic
Third Harmonic
RL = 500Ω, G = +2V/V, f = 10MHz, VO = 2Vp-p
Second Harmonic
Third Harmonic
fC = 5MHz, G = +2
fC = 10MHz, G = +2
fC = 5MHz, G = +2
VO = 5Vp-p, Gain = +1V/V
VO = 2Vp-p, Gain = +1V/V
2V Step, Gain = –1V/V
2V Step, Gain = –1V/V
2V Step, Gain = –1V/V
RATED OUTPUT
Voltage Output
Over Specification Temperature
MAX
8.3
3.5
2.6
2.5
2.5
8.1
2.2
9.3
VCM = 0VDC
TA = T MIN to TMAX
±VCC = ±4.5V to ±5.5V
= ±4.5V to ±5.5V, TA = TMIN to TMAX
INPUT IMPEDANCE
Differential
Common-Mode
INPUT VOLTAGE RANGE
Common-Mode Input Range
Common-Mode Rejection (CMRR)
Over Specification Temperature
TYP
2
±3
±2
SPECIFICATIONS (CONT)
ELECTRICAL
At VCC = ±5VDC, RL=100Ω, G = +2, and TA = +25°C, unless otherwise noted.
OPA628AU
PARAMETER
CONDITIONS
POWER SUPPLY
Rated Voltage
Derated Performance
Current, Quiescent
Current, Quiescent
MIN
±VCC
±VCC
IO = 0mADC
IO = 0mADC, TA = TMIN to TMAX
TEMPERATURE RANGE
Specification: AU
Storage:
AU
θ JA
AU
TYP
±5
±4.5
29
31
TMIN and TMAX
Ambient Temperature
Junction-to-Ambient
–40
–55
MAX
UNITS
±6
32
35
VDC
VDC
mA
mA
°C
°C
°C/W
+85
+125
100
NOTES: (1) Full power response = slew rate/(2πVpeak). (2) Time for output to resume linear operation after saturation.
PACKAGE/ORDERING INFORMATION
PIN CONFIGURATION
PRODUCT
PACKAGE
PACKAGE DRAWING
NUMBER(1)
OPA628AU
SO-8 Surface Mount
182
Top View
8-Pin Plastic SOIC
NOTE: (1) For detailed drawing and dimension table, please see end of data
sheet, or Appendix C of Burr-Brown IC Data Book.
ABSOLUTE MAXIMUM RATINGS
No Internal Connection
1
8
+VCC, Input Stage
Inverting Input
2
7
+VCC, Output Stage
OPA628
Supply .............................................................................................. ±7VDC
Internal Power Dissipation(1) ........................ See Applications Information
Differential Input Voltage ......................................................................... 5V
Input Voltage Range ..................................... See Applications Information
Storage Temperature Range: AP, AU ............................ –55°C to +125°C
Lead Temperature (soldering, SOIC 3s) ........................................ +260°C
Output Short Circuit to Ground (+25°C) ................. Continuous to Ground
Junction Temperature (TJ ) ............................................................. +175°C
Non-Inverting Input
3
6
Output
–VCC, Input Stage
4
5
–VCC, Output Stage
ELECTROSTATIC
DISCHARGE SENSITIVITY
NOTE: (1) Packages must be derated based on specified θJA. Maximum TJ
must be observed.
This integrated circuit can be damaged by ESD. Burr-Brown
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.
The information provided herein is believed to be reliable; however, BURR-BROWN assumes no responsibility for inaccuracies or omissions. BURR-BROWN assumes
no responsibility for the use of this information, and all use of such information shall be entirely at the user’s own risk. Prices and specifications are subject to change
without notice. No patent rights or licenses to any of the circuits described herein are implied or granted to any third party. BURR-BROWN does not authorize or warrant
any BURR-BROWN product for use in life support devices and/or systems.
®
3
OPA628
TYPICAL PERFORMANCE CURVES
At VCC = ±5VDC, RL=100Ω, G = +2, and TA = +25°C, unless otherwise noted.
A V = +1V/V CLOSED-LOOP
SMALL SIGNAL BANDWIDTH
OPEN-LOOP FREQUENCY RESPONSE
–45
Phase
40
–90
20
–135
0
–1
Bandwidth
= 160MHz
Open-Loop Phase
–2
–80
–3
–100
–4
–180
Phase
Margin
= 60°
–20
0
Gain (dB)
60
Gain
1
0
Gain
Phase Shift (°)
80
Gain (dB)
Phase Shift (°)
AOL
2
100
–120
Phase
Margin
= 60°
–5
–6
–140
–160
–180
10k
100k
1M
10M
100M
1G
1M
10M
A V = +2V/V CLOSED-LOOP
SMALL SIGNAL BANDWIDTH
Phase Shift (°)
A V = +5V/V CLOSED-LOOP
SMALL SIGNAL BANDWIDTH
Gain (dB)
6
5
Bandwidth
= 77MHz
Open-Loop Phase
4
–80
12
2
–120
10
–140
9
–160
8
0
–100
11
Open-Loop Phase
10M
100M
1M
10M
1G
G = +2V/V
VO = 2Vp-p
RL = 100Ω
–40
Harmonic Distortion (dBc)
Harmonic Distortion (dBc)
100M
HARMONIC DISTORTION vs FREQUENCY
–30
G = +1V/V
VO = 2Vp-p
RL = 100Ω
–50
–60
–160
Frequency (Hz)
HARMONIC DISTORTION vs FREQUENCY
–40
–140
–180
1G
Frequency (Hz)
–30
–120
Phase
Margin
= 84°
–180
1M
–80
13
–100
Phase
Margin
= 75°
Bandwidth = 24MHz
14
3
1
AOL
Gain
Gain (dB)
AOL
Gain
7
1G
Frequency (Hz)
Frequency (Hz)
8
100M
Phase Shift (°)
1k
100
2f
–70
3f
–80
–90
–50
2f
–60
–70
3f
–80
–90
–100
100k
1M
10M
–100
100k
100M
Frequency (Hz)
10M
Frequency (Hz)
®
OPA628
1M
4
100M
TYPICAL PERFORMANCE CURVES
(CONT)
At VCC = ±5VDC, RL=100Ω, G = +2, and TA = +25°C, unless otherwise noted.
5MHz HARMONIC DISTORTION vs LOAD RESISTANCE
5MHz HARMONIC DISTORTION vs OUTPUT SWING
–70
–70
G = +2V/V
–80
–85
2f
–90
–95
G = +2V/V
VO = 2Vp-p
–75
Harmonic Distortion (dBc)
Harmonic Distortion (dBc)
–75
–80
2f
–85
–90
–95
3f
3f
–100
–100
0
0.5
1.0
1.5
2.0
2.5
0
3.0
100 200 300 400 500 600 700 800 900 1000
Output Swing (Vp-p)
Load Resistance (Ω)
10MHz HARMONIC DISTORTION
vs LOAD RESISTANCE
FULL-POWER BANDWIDTH vs OUTPUT SWING
1G
G = +2V/V
VO = 2Vp-p
2f
–70
G = +1V/V
Bandwidth (Hz)
Harmonic Distortion (dBc)
–65
–75
–80
–85
–90
100M
Slew Rate Limit
G = +2V/V
3f
Slew Rate Limit
for G = +5V/V
G = +5V/V
10M
–95
0
100 200 300 400 500 600 700 800 900 1000
0
1
2
Load Resistance (Ω)
6
90
0.01%
80
80
70
70
Settling Time (ns)
Settling Time (ns)
5
100
90
60
40
4
SETTLING TIME vs OUTPUT VOLTAGE CHANGE
SETTLING TIME vs CLOSED-LOOP GAIN
100
50
3
Output Swing (Vp-p)
VO = 2V step
30
0.1%
20
60
50
30
20
10
0
0
–2
–3
Gain = –1V/V
40
10
–1
0.01%
–4
0.1%
0
–5
1
2
3
4
5
Output Voltage Change (Vp-p)
Closed-Loop Gain
®
5
OPA628
TYPICAL PERFORMANCE CURVES (CONT)
At VCC = ±5VDC, RL=100Ω, G = +2, and TA = +25°C, unless otherwise noted.
INPUT VOLTAGE NOISE SPECTRAL DENSITY
vs FREQUENCY
INPUT CURRENT NOISE SPECTRAL DENSITY
100
Input Current Noise (pA/√Hz)
Input Voltage Noise (nV/√Hz
100
10
1
10
1
10
100
1k
10k
100k
1M
10M
100M
10
100
1k
Frequency (Hz)
SMALL SIGNAL TRANSIENT RESPONSE
1M
10M
100M
G = +1V/V
RL = 100Ω
CL = 10pF
3
Output Voltage (V)
Output Voltage (mV)
100k
LARGE SIGNAL TRANSIENT RESPONSE
G = +1V/V
RL = 100Ω
CL = 10pF
60
40
20
0
–20
2
1
0
–1
–40
–2
–60
–3
Time (ns)
Time (ns)
COMMON-MODE REJECTION vs FREQUENCY
POWER SUPPLY REJECTION vs FREQUENCY
120
Power Supply Rejection (dB)
120
Common-Mode Rejection (dB)
10k
Frequency (Hz)
100
80
60
40
20
0
100
+PSR
80
60
40
–PSR
20
0
100
1k
10k
100k
1M
10M
100M
1G
100
Frequency (Hz)
10k
100k
1M
Frequency (Hz)
®
OPA628
1k
6
10M
100M
1G
TYPICAL PERFORMANCE CURVES (CONT)
At VCC = ±5VDC, RL=100Ω, G = +2, and TA = +25°C, unless otherwise noted.
BIAS AND OFFSET CURRENT
vs INPUT COMMON-MODE VOLTAGE
COMMON-MODE REJECTION
vs INPUT COMMON-MODE VOLTAGE
0.9
Bias Current (µA)
Bias Current
15
0.5
10
0.3
Common-Mode Rejection (dB)
0.7
20
120
Magnitude Offset Current (µA)
25
100
80
60
Offset Current
0.1
5
–4
–3
–2
–1
0
1
2
3
40
4
–4
–3
–2
Common-Mode Voltage (V)
–1
0
1
2
3
4
Common-Mode Voltage (V)
INPUT OFFSET VOLTAGE WARM-UP DRIFT
BIAS AND OFFSET CURRENT vs TEMPERATURE
125
25
2.5
Bias Current (µA)
50
25
0
–25
–50
2.0
15
1.5
10
1.0
Offset Current
5
–75
0.5
Offset Bias Current (µA)
Bias Current
20
75
–100
0
–125
0
20
40
60
80
100
120
140
160
180
0
–50
–25
0
Time (s)
25
50
75
100
125
Temperature (°C)
SUPPLY CURRENT vs TEMPERATURE
CMR, PSR, AND AOL vs TEMPERATURE
34
120
CMR
115
CMR, PSR, AOL (dB)
32
Supply Current (mA)
Offset Voltage Change (µV)
100
30
28
26
110
PSR
105
100
AOL
95
90
24
85
22
80
–50
–25
0
25
50
75
100
125
–50
Temperature (°C)
–25
0
25
50
75
100
125
Temperature (°C)
®
7
OPA628
TYPICAL PERFORMANCE CURVES
(CONT)
At VCC = ±5VDC, RL=100Ω, G = +2, and TA = +25°C, unless otherwise noted.
RANGE OF CHANGE IN VOS
vs TEMPERATURE RELATIVE TO VOS at 25°C
5MHz HARMONIC DISTORTION vs TEMPERATURE
–70
Harmonic Distortion (dBc)
Change In Offset Voltage (mV)
1.0
0.5
0
–0.5
–1.0
G = +2V/V
VO = 2Vp-p
RL = 100Ω
–75
–80
2f
–85
–90
3f
–95
–100
–50
–25
0
25
50
75
100
–50
125
Temperature (°C)
0
25
50
75
100
125
Temperature (°C)
DISCUSSION OF
PERFORMANCE
from the generator was a 0V to 1.4V modulated ramp with
sync pulse. With these conditions the test circuit shown in
Figure 1 delivered a 100IRE modulated ramp to the 75Ω
input of the video analyzer. The signal averaging feature of
the analyzer was used to establish a reference against which
the performance of the amplifier was measured. Signal
averaging was also used to measure the DG and DP of the
test signal in order to eliminate the generator’s contribution
to measured amplifier performance. Typical performance of
the OPA628 is 0.015% differential gain and 0.015° differential phase to both NTSC and PAL standards. Increasing the
closed-loop gain degrades the DP and DG.
The OPA628’s classical operational amplifier architecture
employs true differential and fully symmetrical inputs allowing optimal performance in either inverting or noninverting circuit applications. All traditional circuit configurations and op amp theory apply to the OPA628. The use of
low drift thin film resistors allows internal operating currents to be laser trimmed at wafer level to optimize AC
performance such as distortion, bandwidth and settling time,
as well as DC parameters such as input offset voltage. The
result is a wideband, high frequency monolithic operational
amplifier with a gain-bandwidth product of 150MHz, a
spurious free dynamic range (SFDR) of 90dB, and input
offset voltage of 500µV.
GAIN FLATNESS
Small signal ±0.1dB gain flatness can be achieved up to
30MHz in a non-inverting gain of +2V/V through careful
layout of the printed circuit board and frequency shaping of
the feedback network. Frequency shaping is achieved empirically by placing a small capacitor in parallel with either
the feedback resistor or the input resistor of the OPA628 to
compensate for printed circuit parasitic capacitance. A capacitor in the range of approximately 1pF to 20pF is suggested. Printed circuit board layout design will determine if
the capacitor should be placed across the feedback resistor
or the input resistor.
The layout considerations described in the “Printed Circuit
Board Guidelines” section must be followed to achieve the
best possible performance of the OPA628.
DIFFERENTIAL GAIN AND PHASE
Differential Gain (DG) and Differential Phase (DP) are
among the more important specifications for video applications. DG is defined as the percent change in closed-loop
gain over a specified change in output voltage level. DP is
defined as the change in degrees of the closed-loop phase
over the same output voltage change. Both DG and DP are
specified at the NTSC sub-carrier frequency of 3.58MHz
and the PAL subcarrier of 4.43MHz. All NTSC measurements were performed using a Tektronix model VM700A
Video Measurement Set. All PAL measurements were performed using a Rohde & Schwarz Video Analyzer UAF.
Small signal ±0.1dB gain flatness of greater than 30MHz
can be achieved at a gain of +1V/V. To eliminate the effects
of package lead inductance, a small value resistor should be
included in the feedback path. Maximizing gain flatness for
a particular layout requires optimization of the feedback
resistor; an approximate value is 50Ω to 75Ω.
DISTORTION
The OPA628’s Harmonic Distortion characteristics when
driving a 100Ω load are shown vs frequency and vs voltage
output in the Typical Performance Curves. Distortion can be
further optimized by decreasing output loading as also
DG and DP of the OPA628 were measured with the amplifier in a gain of +2V/V with 75Ω input impedance and the
output back-terminated in 75Ω. The input signal selected
®
OPA628
–25
8
510Ω
510Ω
0.1µF
1
8
DUT
2
3
Tektronix
TSG 130A
OPA628
0.1µF
6
VO
75Ω
+
7
4
75Ω
5
Tektronix
VM700A
75Ω
0.1µF
0.1µF
C = 10µF
75Ω
C = 10µF
–5V
+5V
FIGURE 1. Configuration For Testing Differential Gain/Phase.
shown in Typical Performance Curves. Include the contribution of the feedback resistance when calculating the effective load resistance at the amplifier output. A high performance spectrum analyzer such as the HP3585B should be
used to measure distortion.
tal shorts to common and eliminates the need for external
current-limiting circuitry. Although the device can withstand momentary shorts to either power supply, it is not
recommended.
Many demanding high-speed applications such as ADC/
DAC buffers require op amps with low wideband output
impedance. For example, low output impedance is essential
when driving the signal-dependent capacitances at the inputs
of flash A/D converters. As shown in Figure 2, the OPA628
maintains very low closed-loop output impedance over frequency. Closed-loop output impedance increases with frequency since loop gain is decreasing with frequency.
Two-tone, third-order intermodulation distortion (IM) is an
important parameter for many RF amplifier applications.
The specification table shows the OPA628’s two-tone, third
order IM intercept at 5MHz and 10MHz. For these measurements, tones were spaced 200kHz apart. This data is particularly useful for determining the magnitude of the third-order
IM products. The magnitude of the third-order IM products
can be easily calculated from the expression:
NOISE FIGURE
The OPA628’s voltage and current noise spectral densities
are specified in the Typical Performance Curves. For RF
applications, however, Noise Figure (NF) is often the preferred noise specification since it allows system noise performance to be more easily calculated. The OPA628’s Noise
Figure vs Source Resistance is shown in Figure 3 for
frequencies above 1MHz.
Third IM = 2(OPI3P – PO)
where
= third-order output intercept, dBm
PO = output level/tone, dBm/tone
Third IM = third-order intermodulation ratio
below each output tone, dB
OPI3P
As an example, with OPI3P = 60dBm, for PO = 10dBm, the
third order IM = 2(60 – 10) = 100dB below either 10dBm
tone. The OPA628’s low IM makes the device an excellent
choice for a variety of RF signal processing applications. In
order to obtain the full low distortion performance of the
OPA628, it is imperative to follow the recommendations
described in the “Printed Circuit Board Guidelines” section.
Small Signal Output Impedance (Ω)
10
OUTPUT DRIVE CAPABILITY
The OPA628 has been optimized for low distortion performance with back terminated 50Ω and 75Ω loads (RLOAD =
100Ω and 150Ω, respectively). However, it is capable of
driving 6Vpp into a 50Ω load with a sacrifice in distortion.
This high-output drive capability makes the OPA628 an
ideal choice for a wide range of RF, IF, and video applications. All transmission lines should be terminated with the
characteristic impedance of the transmission line.
1
100m
G = +5V/V
10m
G = +2V/V
1m
G = +1V/V
100µ
10µ
100
1k
10k
100k
1M
10M
100M
Frequency (Hz)
Internal current-limiting circuitry limits output current to
about 130mA at 25°C. This prevents damage from acciden-
FIGURE 2. Small Signal Output Impedance vs Frequency.
®
9
OPA628
In general, capacitive loads should be minimized for optimum high frequency performance. Coax lines can be driven
if the cable is properly terminated. The capacitance of coax
cable (29pF/ft for RG-58) will not load the amplifier when
the coaxial cable or transmission line is terminated in its
characteristic impedance.
NOISE FIGURE vs SOURCE RESISTANCE
25
NF (dB)
20
NFdB = 10log 1 +
en2 + (inRS)2
4kTRS
15
COMPENSATION
The OPA628 is internally compensated and is stable in unity
gain with a phase margin of approximately 60°. However,
the unity gain buffer is the most demanding circuit configuration for loop stability and oscillations are most likely to
occur in this gain. If possible, use the device in a noise gain
of two or greater to improve phase margin and reduce the
susceptibility to oscillation. (Note that, from a stability
standpoint, an inverting gain of –1V/V is equivalent to a
noise gain of 2V/V.) Gain and phase response for other gains
are shown in the Typical Performance Curves.
10
5
0
10k
1k
100
10
100k
Source Resistance (Ω)
FIGURE 3. Noise Figure vs Source Resistance.
SETTLING TIME
Settling time is defined as the total time required, from the
input signal step, for the output to settle to within the
specified error band around the final value. This error band
is expressed as a percentage of the value of the output
transition, a 2V step. Thus, settling time to 0.01% requires an
error band of ±200µV centered around the final value of 2V.
The high-frequency response of the OPA628 in a good
layout is very flat with frequency. However, some circuit
configurations, such as those where large feedback resistances are used, can produce high-frequency gain peaking.
This peaking can be minimized by connecting a small
capacitor in parallel with the feedback resistor. This capacitor compensates for the closed-loop, high frequency, transfer
function zero that results from the time constant formed by
the input capacitance of the amplifier (typically 2pF after PC
board mounting), and the input and feedback resistors. The
selected compensation capacitor may be a trimmer, a fixed
capacitor, or a planned PC board capacitance. The capacitance value is strongly dependent on circuit layout and
closed-loop gain. Using small resistor values will preserve
the phase margin and avoid peaking by keeping the break
frequency of this zero sufficiently high. When high closedloop gains are required, a three-resistor attenuator (tee network) is recommended to avoid using large value resistors
with large time constants.
Settling time, specified in an inverting gain of one, is only
64ns to 0.01% for a 2V step. Settling time increases with
closed-loop gain and output voltage change as described in
the Typical Performance Curves. Preserving settling time
requires critical attention to the details as mentioned under
“Printed Circuit Board Guidelines.” The amplifier also recovers quickly from input overloads. Overload recovery
time to linear operation from a 50% overload is typically
only 60ns. Settling time measurements for the OPA628 were
performed in the circuit configuration of Figure 5. A sampling oscilloscope was used with signal averaging.
CAPACITIVE LOADS
Capacitive loads will decrease the OPA628’s phase margin
which may cause high frequency peaking or oscillations.
Capacitive loads greater than 20pF should be buffered by
connecting a small resistance, usually 5Ω to 25Ω, in series
with the output as shown in Figure 4. This is particularly
important when driving high capacitance loads such as flash
A/D converters.
THERMAL CONSIDERATIONS
The OPA628 does not require a heat sink for operation in
most environments. The use of a heat sink, however, will
reduce the internal thermal rise and will result in cooler,
more reliable operation. At extreme temperatures and under
full load conditions a heat sink is necessary. See “Maximum
Power Dissipation” curve, Figure 6.
The internal power dissipation is given by the equation
PD = PDQ + PDL, where PDQ is the quiescent power dissipation and PDL is the power dissipation in the output stage due
to the load. (For ±VCC = ±5V, PDQ = 10V X 32mA =
320mW, max). For the case where the amplifier is driving a
grounded load (RL) with a DC voltage (VOUT) the maximum
valueofPDLoccurs at VOUT = VCC/2, and is equal to PDL,
max = (VCC)2/4RL. Note that it is the voltage across the
output transistor, and not the load, that determines the power
dissipated in the output stage.
(RS typically 5Ω to 25Ω )
RS
OPA628
RL
CL
When the output is shorted to common PDL = 5V X 180mA
= 900mW. Thus, PD, max = 320mW + 900mW ≈ 1.2W.
FIGURE 4. Driving Capacitive Loads.
®
OPA628
10
1 of settling response at b
n+1
R2
c
nR2
G = n+1
R3
50Ω
R1
50Ω
nR3
nR1
a
Tektronix11402
50Ω
R1
OPA628
OPA620
b
2V
1MΩ
15pF
G = –n
FIGURE 5. Settling Time Test Circuit.
INPUT PROTECTION
Static damage has been well recognized for MOSFET devices, but any semiconductor device deserves protection
from this potentially damaging source. The OPA628 incorporates on-chip ESD protection diodes as shown in Figure 8.
This eliminates the need for the user to add external protection diodes, which can add capacitance and degrade AC
performance.
Note that the short circuit condition represents the maximum
amount of internal power dissipation that can be generated.
Thus, the “Maximum Power Dissipation” curve starts at
1.2W and is derated based on a 175°C maximum junction
temperature and the junction-to-ambient thermal resistance,
θJA, of the package. The variation of short circuit current
with temperature is shown in Figure 7.
1.2
Internal Power Dissipation (W)
+VCC
1.0
0.8
External
Pin
0.6
–VCC
0.4
FIGURE 8. Internal ESD Protection.
0.2
0
0
+25
+50
+75
+100
+125
All pins on the OPA628 are internally protected from ESD
by means of a pair of back-to-back reverse-biased diodes to
either power supply as shown. These diodes will begin to
conduct when the input voltage exceeds either power supply
by about 0.7V. This situation can occur with loss of the
amplifier’s power supplies while a signal source is still
present. The diodes can typically withstand a continuous
current of 30mA without destruction. To insure long term
reliability, however, diode current should be externally limited to approximately 10mA whenever possible.
+150
Ambient Temperature (°C)
FIGURE 6. Maximum Power Dissipation.
200
Short Circuit Current (mA)
Internal
Circuitry
180
Source
160
140
OFFSET VOLTAGE ADJUSTMENT
The OPA628’s input offset voltage is laser-trimmed and will
require no further adjustment for most applications. However, if additional adjustment is needed, the circuit in Figure
9 can be used without degrading offset drift with temperature. Avoid external adjustment whenever possible since
extraneous noise, such as power supply noise, can be inadvertently coupled into the amplifier’s inverting input terminal. Remember that additional offset errors can be created by
Sink
120
100
–50
–25
0
25
50
75
100
125
Temperature (°C)
FIGURE 7. Short Circuit Current vs Temperature.
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11
OPA628
of the board. A 2-ounce copper ground plane is recommended. The input signal ground return, the load return,
and the power supply common should all be connected to
the same physical point to avoid ground loops which can
cause unwanted feedback.
the amplifier’s input bias currents. Whenever possible, match
the impedance seen by both inputs as is shown with R3. This
will reduce error due to the amplifier’s input bias current.
+VCC
R2
2. The entire physical circuit should be as small as practical.
All signal and power supply paths should be as short and
direct as possible to minimize stray capacitance and
inductance which are detrimental to high frequency performance. Minimize signal trace impedance by keeping
traces as wide and short as possible. Stray capacitance
should be minimized, especially at high impedance nodes
such as the amplifier's input terminals. In addition, stray
signal coupling from the output of the amplifier back to
the input should be minimized.
RTrim
20kΩ
470kΩ
OPA628
–VCC
R1
(1)R
3
= R1 || R 2
VIN or Ground
3. In general, the use of surface mount components improves
performance over through-hole components by minimizing parasitics. (However, it should be noted that use of
the DIP version of the OPA628 will not compromise
amplifier performance.) If circuit elements with leads are
used, the leads should be kept as short as possible (6mm)
to minimize lead inductance. Resistors used in feedback
networks should have values of a few hundred ohms for
best performance. Shunt capacitance problems limit the
acceptable resistance range to about 1,000Ω on the high
end and to a value that is within the amplifier's output
drive limits on the low end. Remember that output current must be provided by the amplifier to drive its own
feedback network as well as to drive its load.
Output Trim Range ≅ +V CC ( R 2 ) to –V CC ( R2 )
RTrim
RTrim
NOTE: (1) R3 is optional and can be used to reduce error due to input
bias currents.
FIGURE 9. Offset Voltage Trim.
SPICE MODELS
Computer simulation using SPICE is often useful when
analyzing the performance of analog circuits and systems.
This is particularly true for Video and RF amplifier circuits
where parasitic capacitance and inductance can have a
major effect on circuit performance. SPICE models are
available for the OPA628. Contact Burr-Brown Applications Department to receive a SPICE diskette.
4. As with any low distortion, wide bandwidth amplifier,
power supply bypassing is extremely critical and must
always be used. The system power supplies should be
well bypassed at the board level with a minimum of
2.2µF tantalum capacitors. In addition, all four power
supply leads should be locally bypassed to ground as
close as possible to the amplifier pins. Surface mount
0.1µF capacitors will provide the best performance for
local bypassing. Johanson 0.1µF capacitors (part number
250R18B104ZP4W) are used on the OPA628 demonstration board. All power supply bypass capacitors should be
low impedance designs and should be located on the
primary ground plane side of the PC board for the lowest
impedance connection to ground. Properly bypassed and
modulation free power supply lines allow optimum amplifier performance.
RELIABILITY DATA
Reliability reports are available upon request for each of the
package options offered.
PRINTED CIRCUIT BOARD GUIDELINES
The printed circuit board layout is critical to obtaining the
full performance of the OPA628, particularly optimum
distortion and gain flatness. The guidelines below should be
employed to design the OPA628 printed circuit board.
1. Establish the primary ground plane on the IC side of the
PC board. The primary ground plane is the lowest impedance ground plane, it should be as wide as possible with
minimal interruptions. Connect all unused space on both
sides of the board to the ground plane. The ground plane
should extend beneath the body of the IC on both sides
5. The OPA628 should be soldered directly into the PC
board for best performance.
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OPA628
12
APPLICATIONS
390Ω
390Ω
75Ω Transmission Line
75Ω
VOUT
OPA628
Video
Input
75Ω
75Ω
75Ω
VOUT
High output current drive capability (6Vp-p into 75Ω)
allows two back-terminated 75Ω transmission lines
to be simultaneously driven.
75Ω
FIGURE 10. Video Distribution Amplifier.
75Ω
Triax
Input
249Ω
ADC614
12-Bit,
10MHz A/D
Converter
150Ω
249Ω
75Ω
Signal
Input
OPA628
5Ω
Differential
Input
RS
OPA628
249Ω
SingleEnded
Output
249Ω
10Ω
46
Analog
Common
FIGURE 12. Low Distortion Unity Gain Difference Amplifier.
NOTE: The value of RS varies with the value of the input capacitance of
the A/D converter. RS is 0Ω for the ADC614 since the input capacitance
in only 5pF.
ADC INPUT CAPACITANCE
RS
CIN < 20pF
0Ω
CIN > 20pF
30Ω to 50Ω
FIGURE 11. Differential Input Buffer Amplifier (G = 2V/V).
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13
OPA628