NSC CLC428AJE

N
CLC428
Dual Wideband, Low-Noise, Voltage Feedback Op Amp
General Description
Features
The CLC428 is a very high-speed dual op amp that offers a traditional
voltage-feedback topology featuring unity-gain stability and slewenhanced circuitry. The CLC428’s ultra low noise and very low
harmonic distortion combine to form a very wide dynamic-range op
amp that operates from a single (5 to 12V) or dual (±5V) power supply.
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Each of the CLC428’s closely matched channels provides a 160MHz
unity-gain bandwidth with an ultra low input voltage noise density
(2nV/√Hz). Very low 2nd/3rd harmonic distortion (-62/-72dBc) as well
as high channel-to-channel isolation (-62dB) make the CLC428 a
perfect wide dynamic-range amplifier for matched I/Q channels.
With its fast and accurate settling (16ns to 0.1%), the CLC428 is also
a excellent choice for wide-dynamic range, anti-aliasing filters
to buffer the inputs of hi-resolution analog-to-digital converters.
Combining the CLC428’s two tightly-matched amplifiers in a single
eight-pin SOIC reduces cost and board space for many composite
amplifier applications such as active filters, differential line drivers/
receivers, fast peak detectors and instrumentation amplifiers.
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Wide unity-gain bandwidth: 160MHz
Ultra-low noise: 2.0nV/√Hz
Low distortion: -78dBc 2nd (2MHz)
-62/-72dBc (10MHz)
Settling time: 16ns to 0.1%
Supply voltage range: ±2.5 to ±5 or
single supply
High output current: ±80mA
Applications
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■
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General purpose dual op amp
Low noise integrators
Low noise active filters
Diff-in/diff-out instrumentation amp
Driver/receiver for transmission systems
High-speed detectors
I/Q channel amplifiers
To reduce design times and assist in board layout, the CLC428 is
supported by an evaluation board and a SPICE simulation model
available from National Semiconductor.
CLC428
Dual Wideband, Low-Noise, Voltage Feedback Op Amp
June 1999
Typical Application
5-Decade Integrator
Pinout
DIP & SOIC
Vout1
1
Vinv1
2
Vnon-inv1
-Vcc
 1999 National Semiconductor Corporation
Printed in the U.S.A.
3
-
8
+Vcc
7
Vout2
6
Vinv2
5
Vnon-inv2
+
+
4
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CLC428 Electrical Characteristics (V
CC
PARAMETERS
Ambient Temperature
CONDITIONS
CLC428
FREQUENCY DOMAIN RESPONSE
gain bandwidth product
Vout < 0.5Vpp
-3dB bandwidth, Av=+1
Vout < 0.5Vpp
Av=+2
Vout < 0.5Vpp
Vout < 5.0Vpp
gain flatness
Vout < 0.5Vpp
peaking
DC to 200MHz
rolloff
DC to 20MHz
linear phase deviation
DC to 20MHz
TIME DOMAIN RESPONSE
rise and fall time
1V step
settling time
2V step to 0.1%
overshoot
1V step
slew rate
5V step
DISTORTION AND NOISE RESPONSE
2nd harmonic distortion
1Vpp,10MHz
1Vpp,10MHz
3rd harmonic distortion
equivalent input noise
voltage
1MHz to 100MHz
current
1MHz to 100MHz
crosstalk
input referred, 10MHz
STATIC DC PERFORMANCE
open-loop gain
input offset voltage
average drift
input bias current
average drift
input offset current
average drift
power supply rejection ratio
common-mode rejection ratio
supply current
per channel, RL= ∞
MISCELLANEOUS PERFORMANCE
input resistance
common-mode
differential-mode
input capacitance
common-mode
differential-mode
output resistance
closed loop
output voltage range
RL= ∞
RL=100Ω
input voltage range
common mode
output current
Ω; Rg =100Ω
Ω; RL = 100Ω
Ω; unless noted;
= ±5V; AV = +2V/V; Rf =100Ω
TYP
+25°C
+25°C
MIN/MAX RATINGS
0 to +70°C -40 to +85°C
UNITS
135
160
80
40
100
120
50
25
80
90
40
22
70
80
35
20
MHz
MHz
MHz
MHz
0.0
0.05
0.2
0.6
0.5
1.0
0.8
0.7
1.5
1.0
0.7
1.5
dB
dB
°
5.5
16
1
500
7.5
20
5
300
9.0
24
10
275
10.0
24
10
250
ns
ns
%
V/µs
- 62
- 72
- 50
- 60
- 45
- 56
- 43
- 56
dBc
dBc
2.0
2.0
- 62
2.5
3.0
- 58
2.8
3.6
- 58
2.8
4.6
- 58
nV/√Hz
pA/√Hz
dB
60
1.0
5
1.5
150
0.3
5
66
63
11
56
2.0
--25
--3
--60
57
12
500
200
2.0
2.0
0.05
± 3.8
± 3.5
± 3.7
± 70
250
50
3.0
3.0
0.1
± 3.5
± 3.2
± 3.5
± 50
50
3.0
15
40
600
5
25
55
52
13
50
3.5
20
65
700
5
50
55
52
15
125
25
3.0
3.0
0.2
± 3.3
± 2.6
± 3.3
± 40
125
25
3.0
3.0
0.2
± 3.3
± 1.3
± 3.3
± 20
NOTES
dB
mV
µV/°C
µA
nA/°C
µA
nA/°C
dB
dB
mA
A
A
A
kΩ
kΩ
pF
pF
Ω
V
V
V
mA
Min/max ratings are based on product characterization and simulation. Individual parameters are tested as noted. Outgoing quality levels are
determined from tested parameters.
Ordering Information
Absolute Maximum Ratings
supply voltage
short circuit current
common-mode input voltage
differential input voltage
maximum junction temperature
storage temperature
lead temperature (soldering 10 sec)
±7V
(note 1)
±Vcc
±10V
+150°C
-65°C to+150°C
+300°C
Model
Notes
Reliability Information
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-40°C to +85°C
-40°C to +85°C
-55°C to +125°C
5962-94708
Description
8-pin PDIP
8-pin SOIC
8-pin CerDIP, MIL-STD-883
Package Thermal Resistance
A) J-level: spec is 100% tested at +25°C, sample tested at +85°C.
1) Output is short circuit protected to ground, however maximum
reliability is obtained if output current does not exceed 160mA.
Transistor count
Temperature Range
CLC428AJP
CLC428AJE
CLC428A8B
DESC SMD number:
Package
Plastic (AJP)
Surface Mount (AJE)
CerDIP
104
2
θjc
θjA
60°C/W
40°C/W
25°C/W
115°C/W
115°C/W
115°C/W
3
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Application Discussion
Low Noise Design
Ultimate low noise performance from circuit designs using
the CLC428 requires the proper selection of
external resistors. By selecting appropriate low-valued
resistors for Rf and Rg, amplifier circuits using the CLC428
can achieve output noise that is approximately the
equivalent voltage input noise of 2.0 nV/√Hz multiplied
by the desired gain (Av).
Output and Supply Considerations
With ±5V supplies, the CLC428 is capable of a typical
output swing of ±3.8V under a no-load condition.
Additional output swing is possible with slightly higher
supply voltages. For loads of less than 50Ω, the output
swing will be limited by the CLC428’s output current
capability, typically 80mA.
Output settling time when driving capacitive loads can be
improved by the use of a series output resistor. See the
plot labeled "Settling Time vs. Capacitive Load" in the
Typical Performance section.
Each amplifier in the CLC428 has an equivalent
input noise resistance which is optimum for matching
source impedances of approximately 1k. Using a
transformer, any source can be matched to achieve the
lowest noise design.
Layout
Proper power supply bypassing is critical to insure good high
frequency performance and low noise. De-coupling capacitors of 0.1µF should be place as close as possible to the
power supply pins. The use of surface mounted capacitors
is recommended due to their low series inductance.
For even lower noise performance than the CLC428,
consider the CLC425 or CLC426 at 1.05 and 1.6 nV/√Hz,
respectively.
DC Bias Currents and Offset Voltages
Cancellation of the output offset voltage due to input bias
currents is possible with the CLC428. This is done by
making the resistance seen from the inverting and noninverting inputs equal. Once done, the residual output
offset voltage will be the input offset voltage (Vos) multiplied by the desired gain (Av). Comlinear Application Note
OA-7 offers several solutions to further reduce the output
offset.
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A good high frequency layout will keep power supply and
ground traces away from the inverting input and output
pins. Parasitic capacitance from these nodes to ground
causes frequency response peaking and possible circuit
oscillation. See OA-15 for more information. National
suggests the CLC730038 (through-hole) or the CLC730036
(SOIC) dual op amp evaluation board as a guide for high
frequency layout and as an aid in device evaluation.
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Analog Delay Circuit (All-Pass Network)
The circuit in Figure 1 implements an all-pass network using
the CLC428. A wide bandwidth buffer (CLC111) drives the
circuit and provides a high input impedence for the source.
As shown in Figure 2, the circuit provides a
Figure 3
A1 (B1) and pass the signals from driver B1 (A1). The
output of the receiver amplifier will be:
Figure 1
Vout
e j
AB
=
1
2
Vin
F RI 1
G J
a f GH1 − R JK + 2 V
f
inB
A B
g
F RI
G J
a f GH1 + R JK
f
A
Eq. 3
g
Care must be given to layout and component placement to
maintain a high frequency common-mode rejection. The
plot of Figure 4 shows the simultaneous reception of
signals transmitted at 1MHz and 10MHz.
Figure 2
13.1ns delay (with R =40.2Ω, C=47pF). Rf and Rg should
be of equal and low value for parasitic insensitive operation. The circuit gain is +1 and the delay is determined by
the following equations.
c
τ delay = 2 2RC + Td
Td =
1 dφ
360 df
;
h
Figure 4
Eq. 1
Five Decade Integrator
A composite integrator, as shown in Figure 5, uses the
CLC428 dual op amp to increase the circuits' usable
frequency range of operation. The transfer function of this
circuit is:
1
Vo =
Vin dt
Eq. 4
RC
Eq. 2
z
where Td is the delay of the op amp at AV=+1. The CLC428
provides a typical delay of 2.8ns at its -3dB point.
Full Duplex Digital or Analog Transmission
Simultaneous transmission and reception of analog or
digital signals over a single coaxial cable or twisted-pair
line can reduce cabling requirements. The CLC428's wide
bandwidth and high common-mode rejection in a differential amplifier configuration allows full duplex transmission
of video, telephone, control and audio signals.
In the circuit shown in Figure 3, one of the CLC428's amps
is used as a "driver" and the other as a difference
"receiver" amplifier. The output impedance of the "driver"
is essentially zero. The two R's are chosen to match the
characteristic impedance of the transmission line. The
"driver" op amp gain can be selected for unity or greater.
Figure 5
A resistive divider made from the 143Ω and 60.4Ω
resistors was chosen to reduce the loop-gain and stabilize
the network. The CLC428 composite integrator provides
integration over five decades of operation. R and C set the
integrator's gain. Figure 6 shows the frequency and phase
response of the circuit in Figure 5 with R = 44.2Ω and
C = 360pF.
Receiver amplifier A2 (B2) is connected across R and
forms differential amplifier for the signals transmitted by
driver A1 (B1). If the coax cable is lossless and Rf equals
Rg, receiver A2 (B2) will then reject the signals from driver
5
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The maximum speed of detection is limited by the delay
of the op amps and the diodes. The use of Schottky diodes
will provide faster response.
Adjustable or Bandpass Equalizer
A "boost" equalizer can be made with the CLC428 by
summing a bandpass response with the input signal, as
shown in Figure 9.
Figure 6
Positive Peak Detector
The CLC428's dual amplifiers can be used to implement a
unity-gain peak detector circuit as shown in Figure 7.
Figure 9
The overall transfer function is shown in Eq. 5.
F
GH c
Rb
Vout
=
Vin
K Ra + Rb
Q1
I
h JK s
2
s2Qω o
−1
ω
+ s o + ω o2
Q
Eq. 5
To build a boost circuit, use the design equations Eq. 6 and
Eq. 7.
c
h
R 2C Q
1
=
, 2C Ra ||Rb =
2
Qω o
ωo
Eq. 6,7
Select R2 and C using Eq. 6. Use reasonable values for
high frequency circuits - R2 between 10Ω and 5kΩ, C
between 10pF and 2000pF. Use Eq. 7 to determine the
parallel combination of Ra and Rb. Select Ra and Rb by
either the 10Ω to 5kΩ criteria or by other requirements
based on the impedance Vin is capable of driving. Finish
the design by determining the value of K from Eq. 8.
Figure 7
The acquisition speed of this circuit is limited by the
dynamic resistance of the diode when charging Chold. A
plot of the of the circuit's performance is shown in Figure
8 with a 1MHz sinusoidal input.
Peak Gain =
Vout
Vin
R
cω h = 2KR
−1
2
o
Eq. 8
a
Figure 10 shows an example of the response of the circuit
of Figure 9, where fo is 2.3MHz. The component values
are as follows: Ra =2.1kΩ, Rb =68.5Ω, R2 =4.22kΩ, R
=500Ω, KR =50Ω, C =120pF.
Figure 8
A current source, built around Q1, provides the necessary
bias current for the second amplifier and prevents saturation when power is applied. The resistor, R, closes the loop
while diode D2 prevents negative saturation when Vin is
less than Vc. A MOS-type switch (not shown) can be used
to reset the capacitor's voltage.
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Figure 10
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CLC428
Dual Wideband, Low-Noise, Voltage Feedback Op Amp
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