NSC CLC5523IN Low-power, variable gain amplifier Datasheet

CLC5523
Low-Power, Variable Gain Amplifier
General Descriptions
Features
The CLC5523 is a low power, wideband, DC-coupled, voltagecontrolled gain amplifier. It provides a voltage-controlled gain
block coupled with a current feedback output amplifier. High
impedance inputs and minimum dependence of bandwidth on
gain make the CLC5523 easy to use in a wide range of
applications. This amplifier is suitable as a continuous gain
control element in a variety of electronic systems which benefit
from a wide bandwidth of 250MHz and high slew rate of
1800V/ms, with only 135mW of power dissipation.
■
■
■
■
■
■
Applications
■
■
Input impedances in the megaohm range on both the signal
and gain control inputs simplify driving the CLC5523 in any
application. The CLC5523 can be configured to use pin 3 as a
low impedance input making it an ideal interface for current
inputs. By using the CLC5523’s inverting configuration in which
RG is driven directly, inputs which exceed the device’s input
voltage range may be used.
■
■
■
Frequency Response with Changes in Vg
Magnitude (10dB/div)
20
The extremely high slew rate of 1800V/ms and wide bandwidth
provides high speed rise and fall times of 2.0ns, with settling time
for a 2 volt step of only 22ns to 0.2%. In time domain applications
where linear phase is important with gain adjust, the internal current mode circuitry maintains low deviation of delay over a wide
gain adjust range.
Variable Gain Amplifier
Circuit
0
-10
-20
-30
-40
-50
1M
10M
100M
Frequency (Hz)
Pinout
DIP & SOIC
+5V
1
2
3
8
+
VG
6
CLC5523
7
-
5
4
Rg
25W
Printed in the U.S.A.
10
VG
Typical Application
© 2000 National Semiconductor Corporation
Automatic gain control
Voltage controlled filters
Automatic signal leveling for A/D
Amplitude modulation
Variable gain transimpedance
30
The gain control input (VG), with a 0 to 2V input range, and a
linear-in-dB gain control, simplifies the implementation of AGC
circuits. The gain control circuit can adjust the gain as fast as
4dB/ns. Maximum gains from 2 to 100 are accurately and simply
set by two external resistors while attenuation of up to 80dB from
this gain can be achieved.
Vin
Low power: 135mW
250MHz, -3dB bandwidth
Slew rate 1800V/ms
Gain flatness 0.2dB @ 75MHz
Rise & fall times 2.0ns
Low input voltage noise 4nV/ÖHz
CLC5523
Low-Power, Variable Gain Amplifier
March 2000
Rf
Vo
RL
VIN
Rg
+VCC
I-
X1
-
VO
+
-5V
GND
-VCC
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CLC5523 Electrical Characteristics (VCC = ±5V, Rf = 1k, Rg = 100W, RL = 100W, VG = 2V; unless specified)
PARAMETERS
Ambient Temperature
CONDITIONS
CLC5523I
TYP
+25˚C
MIN/MAX RATINGS
25˚C
-40 to 85˚C
UNITS
FREQUENCY DOMAIN RESPONSE
-3dB bandwidth
Vo < 0.5Vpp
Vo < 4.0Vpp
peaking
DC to 200MHz (Vo = 0.5Vpp)
rolloff
DC to 75MHz (Vo = 0.5Vpp)
linear phase deviation
DC to 75MHz (Vo = 0.5Vpp)
gain control bandwidth
Vin = 0.2VDC, Vg = 1VDC
250
100
0
0.2
0.6
95
150
45
0.8
1.0
1.5
70
125
35
2.0
1.2
3.0
60
MHz
MHz
dB
dB
deg
MHz
TIME DOMAIN RESPONSE
rise and fall time
overshoot
settling time to 0.2%
non-inverting slew rate
inverting slew rate
gain control response rate
2.0
6.0
22
700
1800
4
2.8
15
30
450
1000
3.0
20
60
400
700
ns
%
ns
V/ms
V/ms
dB/nS
-65
-80
-57
-75
5
4
36
–
–
-52
-58
6
5.5
50
–
–
-40
-54
7
5.5
60
dBc
dBc
dBc
dBc
nV/ÖHz
nV/ÖHz
pA/ÖHz
50
120
150
mV
±3.8
3.0
3.0
1.0
7.0
7.0
0.04
0.3
±3.6
8.0
1.0
1.5
5.0
5.0
0.1
0.5
±3.3
16
0.8
1.7
4.0
2.5
0.2
0.9
V
mA
MW
pF
mA
mA
%
dB
0.5
10
1.0
40
57
13.5
±3.4
±3.0
0.1
80
146
2.0
2.0
1.5
55
50
15
±3.0
±2.5
0.15
65
4.0
2.0
1.5
65
46
16
±2.3
±2.3
0.15
50
mA
MW
pF
mA
dB
mA
V
V
W
mA
0.5V step
0.5V step
2V step
4V step
4V step
DISTORTION AND NOISE RESPONSE
2nd harmonic distortion
1Vpp, 5MHz
3rd harmonic distortion
1Vpp, 5MHz
2nd harmonic distortion
1Vpp, 10MHz
3rd harmonic distortion
1Vpp, 10MHz
input referred total noise
Vg = 2V
input referred voltage noise
Rg referred current noise
STATIC DC PERFORMANCE
output offset voltage
Vin signal input
input voltage range
Rg open
input bias current
input resistance
input capacitance
IRgmax
0° to 70°C
IRgmax
-40° to 85°C
signal ch. non-linearity SGNL Vo = 2Vpp
gain accuracy*
Vg gain input
input bias current
input resistance
input capacitance
ground pin current
power supply rejection ratio
input-referred
supply current
RL= ¥
output voltage range
no load
output voltage range
RL = 100W
output impedance
output current
transistor count
NOTES
1
A
A
A
A
*maximum gain is defined as Rf/Rg
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
Notes
A) I-level: spec is 100% tested at +25˚C.
1) See plot “Gain Control Settling Time”.
Model
Absolute Maximum Ratings
supply voltage
output current
maximum junction temperature
storage temperature range
lead temperature (soldering 10 sec)
ESD rating (human body model)
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Temp Range
Description
CLC5523IN
-40°C to +85°C
8-pin DIP
CLC5523IM
-40°C to +85°C
8-pin Small outline
CLC5523IMX
-40°C to +85°C
8-pin Small outline tape and reel
Contact the factory for other packages.
±7V
±80mA
+150˚C
-65˚C to +150˚C
+300˚C
TBD
Package Thermal Resistance
Package
DIP (IN)
Small Outline (IM)
2
qJC
qJA
65°C/W
55°C/W
115°C/W
135°C/W
CLC5523 Typical Performance (VG = +2V, Rf = 1kW, Rg = 100W, RL = 100W, Vo = 0.5Vpp;
Frequency Response (Avmax = 100)
Frequency Response (Avmax = 2)
10
5
0
-5
-10
-15
-20
Magnitude (5dB/div)
10
5
0
Magnitude (5dB/div)
-5
-10
-15
-20
-25
-30
-35
-25
-30
10
100
30
25
20
15
10
5
0
-5
-10
-40
-45
1
45
40
35
1
10
1
100
10
100
Frequency (MHz)
Frequency (MHz)
Frequency (MHz)
Frequency Response vs. RL
Frequency Response vs. Rg
Frequency Response vs. Rf
Magnitude (1dB/div)
RL = 1k
Magnitude
180
Phase
0
-180
RL = 50W
RL = 100W
Rf = 689W
Rg = 500W
Phase (deg)
Magnitude (1dB/div)
360
Rf = 1k
Magnitude (1dB/div)
Magnitude (5dB/div)
Frequency Response (Avmax =10)
25
20
15
unless specified)
Rg = 10W
Rg = 33W
Rf = 2k
Rf = 5k
Rg = 100W
-360
-450
1
10
1
100
10
1
100
0.1
Magnitude (0.1dB/div)
30
Gain (dB)
1.0
Rout (W)
40
Vo = 2Vpp
Avmax = 10
20
10
Gain Flatness & Linear Phase Deviation
0
-20
-40
-60
Rout
1
10
1
100
10
100
0
Large Signal Frequency Response
Equivalent Input Noise
Input Voltage Noise (nVÖHz)
Magnitude (1dB/div)
Vout = 2Vpp
Vout = 4Vpp
Non-Inverting
Vout = 1Vpp
Vout = 2Vpp
Vout = 4Vpp
10
100
100
Voltage Noise
Current Noise
Frequency (MHz)
1
12
10
8
6
4
0
Amplitude (0.5V/div)
Gain (dB)
5.0
4.0
-10
25¡C
-20
-30
-40¡C
3.0
-40
2.0
1.0
-50
0
-60
0
0.4
0.8
1.2
Vg Voltage (V)
1.6
2.0
0.5
0.4
Large
1.5
0.3
0.2
Small
0.5
0.1
0
-0.5
-0.1
-0.2
-1.5
-0.3
Amplitude (0.1V/div)
6.0
300
Large & Small Signal Pulse Response
0
85¡C
200
2.5
85¡C
25¡C
100
RG (W)
Gain (dB) vs. Vg
7.0
500
14
10
8.0
400
16
10
20
-40¡C
9.0
Gain (V/V)
0.1
18
Frequency (MHz)
Gain (V/V) vs. Vg
10
0.01
75
2
10
0.001
60
Input Referred Total Noise
10
1
0.0001
45
20
1000
Input Current Noise (pAÖHz)
Inverting
30
Frequency (MHz)
100
Vout = 1Vpp
1
15
Frequency (MHz)
Frequency (MHz)
Input Voltage Noise (nVÖHz)
0.10
Phase
-80
0.01
20
Gain
Phase (0.5¡C/div)
50
100
Avmax = 100
40
PSRR
0.01
10
Frequency (MHz)
Feed-Through Isolation (VG = 0, 2)
PSRR & Rout
60
Magnitude (dB)
100
Frequency (MHz)
Frequency (MHz)
-0.4
-2.5
0
0.4
0.8
1.2
1.6
2.0
-0.5
Time (5ns/div)
Vg Voltage (V)
3
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CLC5523 Typical Performance
(VG = +2V, Rf = 1kW, Rg = 100W, Avmax = 10; unless specified)
2nd Harmonic Distortion vs. Frequency
-50
Vo = 1Vpp
2nd RL = 100W
-60
-70
-80
2nd RL = 1k
-60
-70
-80
3rd RL = 100W
3rd RL = 1k
-90
-90
-100
Distortion (dBc)
-50
3rd = 10MHz
-90
3rd = 1MHz
0
10
Frequency (MHz)
0.5
Input Harmonic Distortion (Av = 2)
Harmonic Distortion vs. Gain
1
1.5
0.05
Vo = 100mVpp
0.05
VG = 1.04V
Rg = 250W
2nd = 1MHz
-90
Gain (%)
Distortion (dBc)
3rd = 10MHz
0
Phase
50
VG = 0.94V
Rg = 100W
40
-0.05
0
Gain
-0.1
-0.15
-0.05
30
-0.2
3rd = 1MHz
20
-110
0.1
1
-0.25
-0.1
0
10
0.5
1.0
1.5
2.0
-1.6
-0.8
Input Voltage (V)
Gain (Av)
Short Term Settling Time
Gain Control Settling Time
0.15
Vo = 2Vstep
Vo = 2Vstep
0
-0.1
Vo
Amplitude (0.5V/div)
Vo (% Output Step)
Vo (% Output Step)
0.1
0.1
0.05
0
-0.05
-0.1
Vg
-0.15
-0.2
1
100
-0.2
0.001
10000
0.01
0.1
Time (ns)
1.0
10
DC Offset vs. Temperature
2nd Tone, 3rd Order Intermod Intercept
50
2.5
2.0
80
1.5
60
1.0
40
0.5
45
Intercept (dBm)
Input Bias Current
100
Input Bias Current (mA)
Output Offset (mV)
Time (10ns/div)
100
Time (ms)
120
40
35
30
25
Output Offset Voltage
20
20
0
-60
-20
20
60
100
140
10
Temperature (¡C)
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20
30
40
50
60
Frequency (MHz)
4
0.8
DC Output Voltage
Long Term Settling Time
0.2
0
70
80
1.6
Phase (deg)
2nd = 10MHz
2.5
Differential Gain & Phase (NTSC)
60
-50
2
Output Voltage (Vpp)
Frequency (MHz)
-30
-70
2nd = 1MHz
-80
-110
1
10
RL = 100
-70
-100
-100
1
2nd = 10MHz
-60
-50
Distortion (dBc)
Distortion (dBc)
RL = 100
Vo = 1Vpp
-40
Distortion (dBc)
Harmonic Distortion vs. Output Voltage
3rd Harmonic Distortion vs. Frequency
-40
-30
CLC5523 Operation
The key features of the CLC5523 are:
■
■
■
■
■
■
Using the CLC5523 in AGC Applications
In AGC applications, the control loop forces the CLC5523
to have a fixed output amplitude. The input amplitude will
vary over a wide range and this can be the issue that
limits dynamic range. At high input amplitudes, the
distortion due to the input buffer driving Rg may exceed
that which is produced by the output amplifier driving the
load. In the plot, Harmonic Distortion vs. Gain, second
and third harmonic distortion are plotted over a gain
range of nearly 40dB for a fixed output amplitude
of 100mVpp in the specified configuration, Rf = 1k,
Rg = 100W. When the gain is adjusted to 0.1 (i.e. 40dB
down from Avmax), the input amplitude would be 1Vpp and
we can see the distortion is at its worst at this gain. If the
output amplitude of the AGC were to be raised above
100mV, the input amplitudes for gains 40dB down from
Avmax would be even higher and the distortion would
degrade further. It is for this reason that we recommend
lower output amplitudes if wide gain ranges are desired.
Using a post-amp like the CLC404 or CLC409 would be
the best way to preserve dynamic range and yield output
amplitudes much higher than 100mVpp.
Low Power
Broad voltage controlled gain and attenuation
range
Bandwidth independent, resistor programmable
gain range
Broad signal and gain control bandwidths
Frequency response may be adjusted with Rf
High Impedance signal and gain control Inputs
The CLC5523 combines a closed loop input buffer, a voltage controlled variable gain cell and an output amplifier.
The input buffer is a transconductance stage whose gain
is set by the gain setting resistor, Rg. The output amplifier is a current feedback op amp and is configured as a
transimpedance stage whose gain is set by, and equal to,
the feedback resistor, Rf. The maximum gain, Avmax, of
the CLC5523 is defined by the ratio; Rf / Rg. As the
gain control input (VG) is adjusted over its 0 to 2V range,
the gain is adjusted over a range of 80dB relative to the
maximum set gain.
Setting the CLC5523 Maximum Gain
A vmax
Another way of addressing distortion performance and
its limitations on dynamic range, would be to raise the
value of Rg. Just like any other high-speed amplifier, by
increasing the load resistance, and therefore decreasing
the demanded load current, the distortion performance
will be improved in most cases. With an increased Rg, Rf
will also have to be increased to keep the same Avmax
and this will decrease the overall bandwidth.
R
= f
Rg
Although the CLC5523 is specified at Avmax = 10, the
recommended Avmax varies between 2 and 100. Higher
gains are possible but usually impractical due to
output offsets, noise and distortion. When varying Avmax
several tradeoffs are made:
Gain Partitioning
If high levels of gain are needed, gain partitioning should
be considered.
Rg: determines the input voltage range
Rf: determines overall bandwidth
The amount of current which the input buffer can source
into Rg is limited and is specified in the IRgmax spec. This
sets the maximum input voltage:
VG
Vin
+
CLC425
Vin (max) = IR gmax × R g
25Wž
Rc
-
3
R2
The effects of maximum input range on harmonic distortion
are illustrated in the Input Harmonic Distortion plot.
Variations in Rg will also have an effect on the small
signal bandwidth due to its loading of the input buffer and
can be seen in Frequency Response vs. Rg. Changes in
Rf will have a more dramatic effect on the small signal
bandwidth. The output amplifier of the CLC5523 is a
current feedback amplifier(CFA) and its bandwidth is
determined by Rf. As with any CFA, doubling the feedback resistor will roughly cut the bandwidth of the device
in half (refer to the plot Frequency Response vs. Rf). For
more
information
covering
CFA’s,
there
is
a basic tutorial, OA-20, Current Feedback Myths
Debunked or a more rigorous analysis, OA-13, Current
Feedback Amplifier Loop Gain Analysis and Performance
Enhancements.
1
2
CLC5523
7
4
R1
Rg
6
Vo
Rf
25W
Figure 1: Gain Partitioning
The maximum gain range for this circuit is given by the
following equation:
æ R ö æR ö
maximum gain = ç1 + 2 ÷ × ç f ÷
R1 ø è R g ø
è
5
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other methods of limiting the input voltage should be
implemented. One simple solution is to place a 2:1
resistive divider on the VG input. If the device driving this
divider is operating off of ±5V supplies as well, its output
will not exceed 5V and through the divider VG can not
exceed 2.5V.
The CLC425 is a low noise wideband voltage feedback
amplifier. Setting R2 at 909W and R1 at 100W produces
a gain of 20dB. Setting Rf at 1000W as recommended
and Rg at 50W, produces a gain of 26dB in the CLC5523.
The total gain of this circuit is therefore approximately
46dB. It is important to understand that when partitioning
to obtain high levels of gain, very small signal levels will
drive the amplifiers to full scale output. For example, with
46dB of gain, a 20mV signal at the input will drive the output of the CLC425 to 200mV, the output of the CLC5523
to 4V. Accordingly, the designer must carefully consider
the contributions of each stage to the overall characteristics. Through gain partitioning the designer is provided
with an opportunity to optimize the frequency response,
noise, distortion, settling time, and loading effects
of each amplifier to achieve improved overall
performance.
Improving the CLC5523 Large Signal Performance
Figure 2 illustrates an inverting gain scheme for the
CLC5523.
VG
25W
Vin
3
6
CLC5523
Vo
7
Rg
Rf
4
25W
CLC5523 Gain Control Range and Minimum Gain
Before discussing Gain Control Range, it is important to
understand the issues which limit it. The minimum gain of
the CLC5523, theoretically, is zero, but in practical circuits
is limited by the amount of feedthrough, here defined as
the difference in output levels when VG = 2V and when
VG = 0V. Capacitive coupling through the board and
package as well as coupling through the supplies will
determine the amount of feedthrough. Even at DC, the
input signal will not be completely rejected. At high frequencies feedthrough will get worse because of its capacitive nature. At low frequencies, the feedthrough will be
80dB below the maximum gain, and therefore it can be said
that the CLC5523 has an 80dB Gain Control Range.
Figure 2: Inverting the CLC5523
The input signal is applied through the Rg resistor. The
Vin pin should be grounded through a 25W resistor. The
maximum gain range of this configuration is given in the
following equation:
æR ö
A vmax = - ç f ÷
è Rg ø
The inverting slew rate of the CLC5523 is much higher
than that of the non-inverting slew rate. This 2.5X
performance improvement comes about because in the
non-inverting configuration, the slew rate of the overall
amplifier is limited by the input buffer. In the inverting
circuit, the input buffer remains at a fixed voltage and
does not affect slew rate.
CLC5523 Gain Control Function
In the two plots, Gain vs. VG, we can see the gain as a
function of the control voltage. The first plot, sometimes
referred to as the S-curve, is the linear (V/V ) gain. This
is a hyperbolic tangent relationship. The second gain
curve plots the gain in dB and is linear over a wide range
of gains. Because of this, the CLC5523 gain control is
referred to as “linear-in-dB.”
Transmission Line Matching
One method for matching the characteristic impedance of
a transmission line is to place the appropriate resistor at
the input or output of the amplifier. Figure 3 shows a typical circuit configuration for matching transmission lines.
For applications where the CLC5523 will be used at the
heart of a closed loop AGC circuit, the S-curve control
characteristic provides a broad linear (in dB) control
range with soft limiting at the highest gains where large
changes in control voltage result in small changes in
gain. For applications, requiring a fully linear (in dB)
control characteristic, use the CLC5523 at half gain and
below (VG ² 1V).
VG
Zo
Signal
Input
+
-
Rs
Ri
3
Co
1
2
Ro
7
4
Zo
6
CLC5523
Rg
Rf
Output
RT
25W
Avoiding Overdrive of the CLC5523
Gain Control Input
There is an additional requirement for the CLC5523 Gain
Control Input (VG): VG must not exceed +2.5V. The gain
control circuitry may saturate and the gain may actually
be reduced. In applications where VG is being driven
from a DAC, this can easily be addressed in the software.
If there is a linear loop driving VG, such as an AGC loop,
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1
2
Figure 3: Transmission Line Matching
The resistors Rs, Ri, Ro, and RT are equal to the
characteristic impedance, Zo, of the transmission line or
cable. Use Co to match the output transmission line over
a greater frequency range. It compensates for the
increase of the op amp’s output impedance with frequency.
6
Minimizing Parasitic Effects on
Small Signal Bandwidth
The best way to minimize parasitic effects is to use the
small outline package and surface mount components.
For designs utilizing through-hole components,
specifically axial resistors, resistor self-capacitance
should be considered. Example: the average magnitude
of parasitic capacitance of RN55D 1% metal film
resistors is about 0.15pF with variations of as much as
0.1pF between lots. Given the CLC5523’s extended
bandwidth, these small parasitic reactance variations can
cause measurable frequency response variations in the
highest octave. We therefore recommend the use
of surface mount resistors to minimize these parasitic
reactance effects. If an axial component is preferred, we
recommend PRP8351 resistors which are available from
Precision Resistive Products, Inc., Highway 61 South,
Mediapolis, Iowa.
■
■
■
Adjusting Offsets and DC Level Shifting
Offsets can be broken into two parts: an input-referred term
and an output-referred term. These errors can be trimmed
using the circuit in Figure 4. First set VG to 0V and adjust
the trim pot R4 to null the offset voltage at the output. This
will eliminate the output stage offsets. Next set VG to 2V
and adjust the trim pot R1 to null the offset voltage at the
output. This will eliminate the input stage offsets.
Small Signal Response at Low Avmax
When the maximum gain, as set by Rg and Rf, is greater
than or equal to Avmax = 10, little or no peaking should be
observed in the amplifier response. When the gain range
is set to less than Avmax = 10, some peaking may
be observed at higher frequencies. At gain ranges of
2 ² Avmax ² 10 peaking can be minimized by increasing
Rf. At gain ranges of Avmax < 2 peaking reaches
approximately 6dB in the upper octave.
VG
Vin
If peaking is observed with the recommended Rf resistor,
and a small increase in the Rf resistor does not solve the
problem, then investigate the possible causes and
remedies listed below.
■
■
■
Long traces between CLC5523 and 0.1mF
bypass capacitors
■ Keep these traces less than 0.2 inches (5mm)
■ For the devices in the PDIP package, an
additional 1000pF monolithic capacitor should be
placed less than 0.1” (3mm) from the pin
Extra capacitance between the Rg pin and
ground (CG)
■ See the Printed Circuit Board Layout sub-section
below for suggestions on reducing CG
■ Increase Rf if peaking is still observed after
reducing CG
Non-inverting input pin connected directly to
ground
■ Place a 50 to 200W resistor between the noninverting pin and ground
3
+5V
R1
10k
Capacitance across Rf
■ Do not place a capacitor across Rf
■ Keep traces connecting Rf separated and as
short as possible
Capacitive Loads
■ Place a small resistor (20-50W) between the
output and CL
Long traces and/or lead lengths between Rf
and the CLC5523
■ Keep these traces as short as possible
-5V
R2
10k
0.1mF
Rg
1
2
6
CLC5523
7
4
25W
Vo
Rf
R3
10k
0.1mF
+5V
R4
10k
-5V
Figure 4: Offset Adjust Circuit
7
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Printed Circuit Board Layout
High frequency op amp performance is strongly
dependent on proper layout, proper resistive termination
and adequate power supply decoupling. The most important layout points to follow are:
■
■
■
Use a ground plane
Bypass each power supply pin with these capacitors:
■ a high-quality 0.1mF ceramic capacitor placed
less than 0.2” (5mm) from the pin
■ a 6.8mF tantalum capacitor less than 2” (50mm)
from the pin
■ for the plastic DIP package, a high-quality
1000pF ceramic capacitor placed less than 0.1”
(3mm) from the pin
■
■
Minimize trace and lead lengths for components
between the inverting and output pins
■ Remove ground plane 0.1” (3mm) from all
input/output pads
■ For prototyping, use flush-mount printed circuit
board pins; never use high profile DIP sockets
To minimize high frequency distortion, other layout issues
need be addressed:
Capacitively bypassing power pins to a good ground plane
with a minimum of trace length (inductance) is necessary
for any high speed device, but it is particularly important for
the CLC5523.
■
Minimize or eliminate sources of capacitance
between the Rf pin and the output pin. Avoid
adjacent feedthrough vias between the Rf and
output leads since such a geometry may give rise
to a significant source of capacitance.
■
■
Short, equal length, low impedance power supply
return paths from the load to the supplies
avoid returning output ground currents near the
input stage.
Establish wide, low impedance, power supply traces
For the plastic DIP package, a 25W resistor should
be connected from pin 4 to ground with a minimum
length trace
Evaluation Boards
Evaluation boards are available for both the 8-pin DIP
and small outline package types. Evaluation kits that
contain an evaluation board and CLC5523 samples can
be obtained by calling National Semiconductor’s
Customer Service Center at 1-800-272-9959. The 8-pin
DIP evaluation kit part number is CLC730065. The 8-pin
small outline evaluation kit part number is CLC730066.
The DIP evaluation kit has been designed to utilize axial
lead components. The small outline evaluation kit has
been designed to utilize surface mount components.
The circuit diagram shown in Figure 5, applies to both the
DIP and the small outline evaluation boards.
5V
Input
Signal
Gain
Control
RX
50W
6.8mF
VG
+VCC
Vin
I-
GND
Rf
1kWž
X1
Vo
Rg
Rin
50W
+
Rg
100W
0.1mF
-VCC
Ro
0.1mF
*
25W
Output
50Wž
6.8mF
-5V
* 25W series resistor is not required on the
small outline device and does not appear on
the small outline board
Figure 5: Evaluation Board Schematic
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8
Comlinear Layer2
3255CLC
DRAOB LAVE
Comlinear Layer1
Figure 6: DIP Evaluation Board (Top Layer)
Figure 7: DIP Evaluation Board (Bottom Layer)
Comlinear Layer1 Silk
Comlinear Layer2 Silk
3C
4C
5J
oR
DRAOB LAVE 3255CLC
Figure 8: Small Outline Evaluation Board
(Top Layer)
Figure 9: Small Outline Evaluation Board
(Bottom Layer)
(Not drawn to scale)
9
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CLC5523 Applications
Digital Gain Control
Digitally variable gain control can be easily realized
by driving the CLC5523’s gain control input with a
digital-to-analog converter (DAC). Figure 10 illustrates
such an application. This circuit employs National
Semiconductor’s eight-bit DAC0830, the LM351 JFET
input op-amp, and the CLC5523 VGA. With Vref set to 2V,
the circuit provides up to 80dB of gain control in
512 steps with up to 0.05% full scale resolution. The
maximum gain of this circuit is 20dB.
Signal frequencies must not reach the gain control port of
the CLC5523, or the output signal will be distorted
(modulated by itself). A fast settling AGC needs
additional filtering beyond the integrator stage to
block signal frequencies. This is provided in Figure 11
by a simple R-C filter (R10 and C3); better distortion
performance can be achieved with a more complex filter.
These filters should be scaled with the input signal
frequency. Loops with slower response time (longer
integration time constants) may not need the R10 –
C3 filter.
Digital
Input
Checking the loop stability can be done by monitoring the
Vg voltage while applying a step change in input signal
amplitude. Changing the input signal amplitude can be
easily done with either an arbitrary waveform generator
or a fast multiplexer such as the CLC532.
Rfb
Io1
Vref
-
DAC0830
LM351
+
Io2
Vin
1
2
3
7
Rf
4
RG
100W
Automatic Gain Control (AGC) #2
Figure 12 on the following page, illustrates an automatic
gain control circuit that employs two CLC5523’s. In this
circuit, U1 receives the input signal and produces an
output signal of constant amplitude. U2 is configured
to provide negative feedback. U2 generates a rectified
gain control signal that works against an adjustable
bias level which may be set by the potentiometer and
Rb. Ci integrates the bias and negative feedback. The
resultant gain control signal is applied to the U1 gain
control input Vg. The bias adjustment allows the U1
output to be set at an arbitrary level less than the
maximum output specification of the amplifier.
Rectification is accomplished in U2 by driving both
the amplifier input and the gain control input with the
U1 output signal. The voltage divider that is formed
by R1, R2 and the Vg input (pin 1) resistance, sets the
rectifier gain.
Vo
6
CLC5523
1k
25W
Figure 10: Digital Gain Control
Automatic Gain Control (AGC) #1
Fast Response AGC Loop
The AGC circuit shown in Figure 11 will correct a 6dB
input amplitude step in 100ns. The circuit includes a two
op-amp precision rectifier amplitude detector (U1 and
U2), and an integrator (U3) to provide high loop gain at
low frequencies. The output amplitude is set by R9.
Some notes on building fast AGC loops:
Precision rectifiers work best with large output signals.
Accuracy is improved by blocking DC offsets, as shown in
Figure 11.
Includes scope
probe capacitance
C3
40pF
Vin
R10
500W
2
3
Rg
100W
C2
680pF
R8
-
U3
CLC426
+
500W
R9
4.22k
1
+
6
CLC5523
7
-
C1
1.0mF
Rf
4
+
U2
CLC404
-
R5
R3
25W
500W
R6
R4
500W
500W
R7
500W
-5V
1N5712
Schottky
10
-
U1
CLC404
Figure 11: Automatic Gain Control Circuit #1
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R1
20W
+
R2
25W
Output
20MHz,
0.1Vpp
Rc
+5V
100W
2k Rb
Level Adj.
100W
150W
Ci
100pF
-5V
Signal
Input
2
3
Rg1
100W
R1
100W
1
U1
CLC5523
4
6
50W
7
2.2mF
Rf1
1k
25W
2
Rg2
3
100W
1
U2
CLC5523
4
6
7
Rf2
1k
Output
Figure 12: Automatic Gain Control Circuit #2
11
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CLC5523
Low-Power, Variable Gain Amplifier
LIFE SUPPORT POLICY
NATIONAL’S PRODUCTS ARE NOT AUTHORIZED FOR USE AS CRITICAL COMPONENTS IN LIFE SUPPORT DEVICES
OR SYSTEMS WITHOUT THE EXPRESS WRITTEN APPROVAL OF THE PRESIDENT AND GENERAL COUNSEL OF
NATIONAL SEMICONDUCTOR CORPORATION. As used herein:
1. Life support devices or systems are devices or systems which, a) are intended for surgical implant into the body, or b)
support or sustain life, and whose failure to perform, when properly used in accordance with instructions for use provided
in the labeling, can be reasonably expected to result in a significant injury to the user.
2. A critical component is any component of a life support device or system whose failure to perform can be reasonably
expected to cause the failure of the life support device or system, or to affect its safety or effectiveness.
National Semiconductor
Corporation
Americas
Tel: 1(800) 272-9959
Fax: 1(800) 737-7018
Email: [email protected]
National Semiconductor
Europe
Fax: +49 (0) 1 80-530 85 86
E-mail: europe.support.nsc.com
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Francais Tel: +49 (0) 1 80-532 93 58
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Asia Pacific Customer
Response Group
Tel: 65-25-2544466
Fax: 65-2504466
Email: [email protected]
National Semiconductor
Japan Ltd.
Tel: 81-3-5639-7560
Fax: 81-3-5639-7507
National does not assume any responsibility for use of any circuitry described, no circuit patent licenses are implied and National reserves the right at any time without notice to change said circuitry and specifications.
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12
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