INTERSIL EL4452CN

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8
1-88
Wideband Variable-Gain Amplifier with
Gain of 10
The EL4452 is a complete variablegain circuit. It offers wide bandwidth
and excellent linearity, while including
a powerful output voltage amplifier, drawing modest current.
The higher gain and lower input noise makes the EL4452
ideal for use in AGC systems.
The EL4452 operates on ±5V to ±15V and has an analog
input range of ±0.5V. AC characteristics do not change
appreciably over the supply range.
The circuit has an operational temperature of -40°C to +85°C
and is packaged in 14-pin PDIP and SO-14.
EL4452
FN7170
Features
• Complete variable-gain amplifier complete with output
amplifier
• Compensated for Gain ≥ 10
• 50MHz signal bandwidth
• 50MHz gain-control bandwidth
• Low 29nV/√Hz input noise
• Operates on ±5V to ±15V supplies
• All inputs are differential
• > 70dB attenuation @ 5MHz
Applications
The EL4452 is fabricated with Elantec’s proprietary
complementary bipolar process which gives excellent signal
symmetry and is very rugged.
• AGC variable-gain amplifier
Pinout
• Transducer amplifier
• IF amplifier
Ordering Information
EL4452
(14-PIN PDIP, SO)
TOP VIEW
1
PART
NUMBER
TEMP. RANGE
PACKAGE
PKG. NO.
EL4452CN
-40°C to +85°C
14-Pin PDIP
MDP0031
EL4452CS
-40°C to +85°C
14-Pin SO
MDP0027
CAUTION: These devices are sensitive to electrostatic discharge; follow proper IC Handling Procedures.
1-888-INTERSIL or 321-724-7143 | Intersil (and design) is a registered trademark of Intersil Americas Inc.
Copyright © Intersil Americas Inc. 2003. All Rights Reserved. Elantec is a registered trademark of Elantec Semiconductor, Inc.
All other trademarks mentioned are the property of their respective owners.
EL4452
Absolute Maximum Ratings (TA = 25°C)
V+
VS
VIN
∆VIN
IIN
Positive Supply Voltage . . . . . . . . . . . . . . . . . . . . . . . . . 16.5V
V+ to V- Supply Voltage . . . . . . . . . . . . . . . . . . . . . . . . . .33V
Voltage at any Input or Feedback . . . . . . . . . . . . . . . V+ to VDifference between Pairs of Inputs or Feedback. . . . . . . . .6V
Current into any Input or Feedback Pin. . . . . . . . . . . . . . 4mA
IOUT
PD
TA
TS
Output Current . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 30mA
Maximum Power Dissipation . . . . . . . . . . . . . . . . See Curves
Operating Temperature Range . . . . . . . . . . . .-40°C to +85°C
Storage Temperature Range. . . . . . . . . . . . .-60°C to +150°C
CAUTION: Stresses above those listed in “Absolute Maximum Ratings” may cause permanent damage to the device. This is a stress only rating and operation of the
device at these or any other conditions above those indicated in the operational sections of this specification is not implied.
IMPORTANT NOTE: All parameters having Min/Max specifications are guaranteed. Typical values are for information purposes only. Unless otherwise noted, all tests
are at the specified temperature and are pulsed tests, therefore: TJ = TC = TA
Open-Loop DC Electrical Specifications
PARAMETER
VDIFF
Power supplies at ±5V, TA = 25°C, RF = 910Ω, RG = 100Ω, RL = 500Ω
DESCRIPTION
Signal Input Differential Input Voltage
Clipping
MIN
TYP
0.4
0.5
V
0.4
V
±2.0
±2.8
V
±12.0
±12.8
V
0.6% Nonlinearity
VCM
Common-Mode Range (All Inputs; VDIFF = 0) VS = ±5V
VS = ±15V
MAX
UNITS
VOS
Input Offset Voltage
10
mV
VOS, FB
Output Offset Voltage
10
mV
VG, 100%
Extrapolated Voltage for 100% Gain
VG, 0%
Extrapolated Voltage for 0% Gain
VG, 1V
1.8
2.1
2.2
V
-0.16
-0.06
0.04
V
Gain at VGAIN = 1 (RF = 910Ω, RG = 100Ω)
4.9
5.35
5.9
V/V
IB
Input Bias Current (All Inputs)
-20
-9
0
µA
IOS
Input Offset Current Between VIN+ and VIN-, VGAIN+ and VGAIN-
0.5
4
µA
FT
Signal Feedthrough, VG = -1V
-100
-70
dB
RIN, Signal
Input Resistance, Signal Input
25
60
kΩ
RIN, Gain
Input Resistance, Gain Input
50
120
kΩ
RIN, FB
Input Resistance, Feedback
25
60
kΩ
CMRR
Common-Mode Rejection Ratio, VIN
70
90
dB
PSRR
Power-Supply Rejection Ratio, VOS, FB; Supplies from ±5V to ±15V
65
83
dB
EG
Gain Error, Excluding Feedback Resistors, VGAIN = 2.5V
-7
NL
Nonlinearity, VIN from -0.25V to +0.25, VGAIN = 1V
VO
Output Voltage Swing (VIN = 0, VREF Varied) VS = ±5V
±2.5
±2.8
V
VS= ±15V
±12.5
±12.8
V
40
85
mA
ISC
Output Short-Circuit Current
IS
Supply Current, VS = ±15V
2
0.3
15.5
+7
%
0.6
%
18
mA
EL4452
Closed-Loop AC Electrical Specifications
PARAMETER
Power supplies at ±12V, TA = 25°C, RL = 500Ω, CL = 15pF
DESCRIPTION
MIN
TYP
MAX
UNITS
BW, -3dB
-3dB Small-Signal Bandwidth, Signal Input
50
MHz
BW, ±0.1dB
0.1dB Flatness Bandwidth, Signal Input
10
MHz
Peaking
Frequency Response Peaking
0.1
dB
BW, Gain
-3dB Small-Signal Bandwidth, Gain Input
50
MHz
SR
Slew Rate, VOUT between -2V and +2V
VN
Input-Referred Noise Voltage Density
350
Test Circuit
Note: For typical performance curves, RF = 910Ω, RG = 100Ω, VGAIN = 1V,
RL = 500Ω, and CL = 15pF unless otherwise noted.
3
400
29
550
V/µs
nV/rt√Hz
EL4452
Typical Performance Curves
Frequency Response for Various
Feedback Divider Ratios
Frequency Response for
Various Gains
Frequency Response for
Various RL, CL, VS = ±5V
Frequency Response for
Various RL, CL, VS = ±15V
-3dB Bandwidth vs. Supply Voltage
4
-3dB Bandwidth vs. Die
Temperature
EL4452
Typical Performance Curves
(Continued)
Gain and -3dB Bandwidth vs.
Load Resistance
Slew Rate vs. Supply Voltage
Input Voltage Noise vs. Frequency
5
Input Common-Mode Rejection
Ratio vs. Frequency
Slew Rate vs. Die Temperature
Nonlinearity vs. Input Signal
EL4452
Typical Performance Curves
(Continued)
Bias Current vs. Die Temperature
Gain vs. VGAIN
Change in VG, 100% and VG, 0% vs.
Die Temperature
VG, 0% and VG, 100% vs. Supply
Voltage
Common Mode Input
Range vs. Supply Voltage
Supply Current vs. Supply Voltage
6
EL4452
Typical Performance Curves
(Continued)
Supply Current vs. Die Temperature
Applications Information
The EL4452 is a complete two-quadrant multiplier/gain
control with 50MHz bandwidth. It has three sets of inputs; a
differential signal input VIN, a differential gain-controlling
input VGAIN, and another differential input which is used to
complete a feedback loop with the output. Here is a typical
connection:
The gain of the feedback divider is H. The transfer function of
the part is:
VOUT = AO × (((VIN+) - (VIN-)) × ((VGAIN+) - (VGAIN-)) +
(VREF - VFB)).
14-Pin Package Power Dissipation
vs. Ambient Temperature
It is important to keep the feedback divider’s impedance at
the FB terminal low so that stray capacitance does not
diminish the loop’s phase margin. The pole caused by the
parallel impedance of the feedback resistors and stray
capacitance should be at least 130MHz; typical strays of 3pF
thus require a feedback impedance of 400Ω or less.
Alternatively, a small capacitor across RF can be used to
create more of a frequency-compensated divider. The value
of the capacitor should scale with the parasitic capacitance
at the FB input. It is also practical to place small capacitors
across both the feedback and the gain resistors (whose
values maintain the desired gain) to swamp out parasitics.
For instance, a 3pF capacitor across RF and 27pF to ground
will dominate parasitic effects in a 1/10 divider and allow a
higher divider resistance.
The REF pin can be used as the output’s ground reference,
for DC offsetting of the output, or it can be used to sum in
another signal.
Gain-Control Characteristics
VOUT = (((VIN+) - (VIN-)) × 1/2 ((VGAIN+) - (VGAIN)) +
VREF)/H,
The quantity VGAIN in the above equations is bounded as
0 ≤ VGAIN ≤ 2, even though the externally applied voltages
exceed this range. Actually, the gain transfer function around
0 and 2V is “soft”; that is, the gain does not clip abruptly
below the 0%-VGAIN voltage nor above the 100%-VGAIN
level. An overdrive of 0.3V must be applied to VGAIN to
obtain truly 0% or 100%. Because the 0%- or 100%- VGAIN
levels cannot be precisely determined, they are extrapolated
from two points measured inside the slope of the gain
transfer curve. Generally, an applied VGAIN range of -0.5V to
+2.5V will assure the full numerical span of 0 ≤ VGAIN ≤ 2.
VOUT = (VIN × 1/2 VGAIN + VREF)/H
The gain control has a small-signal bandwidth equal to the
VIN channel bandwidth, and overload recovery resolves in
about 20nsec.
VFB is connected to VOUT through a feedback network, so
VFB = H × VOUT. AO is the open-loop gain of the amplifier,
and is approximately 3300. The large value of AO drives:
((VIN+) - (VIN-)) × 1/2 ((VGAIN+) - (VGAIN-)) + (VREF VFB) → 0.
Rearranging and substituting for VFB:
or
Thus the output is equal to the difference of the VIN’s times
the difference of VGAIN’s and offset by VREF, all gained up
by the feedback divider ratio. The EL4452 is stable for a
divider ratio of 1/10, and the divider may be set for higher
output gain, although with the traditional loss of bandwidth.
7
Input Connections
The input transistors can be driven from resistive and
capacitive sources, but are capable of oscillation when
presented with an inductive input. It takes about 80nH of
series inductance to make the inputs actually oscillate,
EL4452
equivalent to four inches of unshielded wiring or 6 of
unterminated input transmission line. The oscillation has a
characteristic frequency of 500MHz. Often placing one’s
finger (via a metal probe) or an oscilloscope probe on the
input will kill the oscillation. Normal high-frequency
construction obviates any such problems, where the input
source is reasonably close to the input. If this is not possible,
one can insert series resistors of around 51Ω to de-Q the
inputs.
For instance, the EL4452 draws a maximum of 18mA. With
light loading, RPAR →∞ and the dissipation with ±5V
supplies is 180mW. The maximum supply voltage that the
device can run on for a given PD and other parameters is:
VS, max=(PD+VO2/RPAR)/(2IS+VO/RPAR)
The maximum dissipation a package can offer is:
PD, max = (TJ, max-TA, max) / θJA
Where
Signal Amplitudes
Signal input common-mode voltage must be between (V-)
+2.5V and (V+)-2.5V to ensure linearity. Additionally, the
differential voltage on any input stage must be limited to ±6V
to prevent damage. The differential signal range is ±0.5V in
the EL4452. The input range is substantially constant with
temperature.
The Ground Pin
The ground pin draws only 6µA maximum DC current, and
may be biased anywhere between (V-)+2.5V and (V+)-3.5V.
The ground pin is connected to the IC’s substrate and
frequency compensation components. It serves as a shield
within the IC and enhances input stage CMRR and
feedthrough over frequency, and if connected to a potential
other than ground, it must be bypassed.
Power Supplies
The EL4452 operates with power supplies from ±3V to ±15V.
The supplies may be of different voltages as long as the
requirements of the ground pin are observed (see the
Ground Pin section). The supplies should be bypassed close
to the device with short leads. 4.7µF tantalum capacitors are
very good, and no smaller bypasses need be placed in
parallel. Capacitors as small as 0.01µF can be used if small
load currents flow.
Single-polarity supplies, such as +12V with +5V can be
used, where the ground pin is connected to +5V and V- to
ground. The inputs and outputs will have to have their levels
shifted above ground to accommodate the lack of negative
supply.
The power dissipation of the EL4452 increases with power
supply voltage, and this must be compatible with the
package chosen. This is a close estimate for the dissipation
of a circuit:
PD=2×VS×IS, max+(VS-VO)×VO/RPAR
where
IS, max is the maximum supply current
VS is the ± supply voltage (assumed equal)
VO is the output voltage
RPAR is the parallel of all resistors loading the output
8
TJ,max is the maximum die temperature, 150°C for
reliability, less to retain optimum electrical performance
TA,max is the ambient temperature, 70°C for commercial
and 85°C for industrial range
θJAis the thermal resistance of the mounted package,
obtained from data sheet dissipation curves
The more difficult case is the SO-14 package. With a
maximum die temperature of 150°C and a maximum
ambient temperature of 85°C, the 65°C temperature rise and
package thermal resistance of 120°C/W gives a dissipation
of 542mW at 85°C. This allows the full maximum operating
supply voltage unloaded, but reduced if loaded.
Output Loading
The output stage of the EL4452 is very powerful. It can
typically source 80mA and sink 120mA. Of course, this is too
much current to sustain and the part will eventually be
destroyed by excessive dissipation or by metal traces on the
die opening. The metal traces are completely reliable while
delivering the 30mA continuous output given in the Absolute
Maximum Ratings table in this data sheet, or higher purely
transient currents.
Gain changes only 0.2% from no load to a 100Ω load. Heavy
resistive loading will degrade frequency response and
distortion for loads < 100Ω.
Capacitive loads will cause peaking in the frequency
response. If capacitive loads must be driven, a small-valued
series resistor can be used to isolate it. 12Ω to 51Ω should
suffice. A 22Ω series resistor will limit peaking to 1dB with
even a 220pF load.
EL4452
AGC Circuits
The basic AGC (automatic gain control) loop is this:
the EL4452. Bias current-induced offsets could increase this
further.
Depending on the nature of the signal, different level
detector strategies will be employed. If the system goal is to
prevent overload of subsequent stages, peak detectors are
preferred. Other strategies use an RMS detector to maintain
constant output power. Here is a simple AGC using peak
detection (Figure 2).
FIGURE 1. BASIC AGC LOOP
A multiplier scales the input signal and provides necessary
gain and buffers the signal presented to the output load, a
level detector (shown schematically here as a diode)
converts some measure of the output signal amplitude to a
DC level, a low-pass filter attenuates any signal ripple
present on that DC level, and an amplifier compares that
level to a reference and amplifies the error to create a gaincontrol voltage for the multiplier. The circuitry is a servo that
attempts to keep the output amplitude constant by
continuously adjusting the multiplier’s gain control input.
Most AGC’s deal with repetitive input signals that are
capacitively coupled. It is generally desirable to keep DC
offsets from mixing with AC signals and fooling the level
detector into maintaining the DC output offset level constant,
rather than a smaller AC component. To that end, either the
level detector is AC-coupled, or the reference voltage must
be made greater than the maximum multiplier gain times the
input offset. For instance, if the level detector output equaled
the reference voltage at 1V of EL4452 output, the 8mV of
input offset would require a maximum gain of 125 through
The output of the EL4452 drives a diode detector which is
compared to VREF by an offset integrator. Its output feeds
the gain-control input of the EL4452. The integrator’s output
is attenuated by the 2kΩ and 2.7kΩ resistors to prevent the
op-amp from overloading the gain-control pin during zero
input conditions. The 510kΩ resistor provides a pull-down
current to the peak level storage capacitor C1 to allow it to
drift negative when output amplitude reduces. Thus the
detector is of fast attack and slow decay design, able to
reduce AGC gain rapidly when signal amplitude suddenly
increases, and increases gain slowly when the input drops
out momentarily. The value of C1 determines drop-out
reaction rates, and the value of CF affects overall loop time
constant as well as the amount of ripple on the gain-control
line. C2 can be used to reduce this ripple further, although it
contributes to loop overshoot when input amplitude changes
suddenly. The op-amp can be any inexpensive lowfrequency type.
The major problem with diode detectors is their large and
variable forward voltage. They require at least a 2VP-P peak
output signal to function reliably, and the forward voltage
should be compensated by including a negative VD added to
VREF. Even this is only moderately successful. At the
expense of bandwidth, op-amp circuits can greatly improve
diode rectifiers (see “An Improved Peak Detector”, an
FIGURE 2.
9
EL4452
FIGURE 3.
Elantec application note). Fortunately, the detector will see a
constant amplitude of signal if the AGC is operating correctly.
A better-calibrated method is to use a four-quadrant
multiplier as a square-law detector. Here is a circuit
employing the EL4450 (Figure 3).
beyond the 10 of the EL4452, current feedback devices
being the most flexible. The op-amp’s input should be
capacitor coupled to prevent gained-up offsets from
confusing the level detector during AGC control line
variations.
In this circuit, the EL4450 not only calculates the square of
the input, but also provides the offset integrator function. The
product of the two multiplier inputs adds to the -Reference
input and are passed to the output amplifier, which through
CF behaves as a pseudo-integrator. The “integrator” gain
does not pass through zero at high frequencies but has a
zero at 1/(2πCF × 1kΩ). This zero is cancelled by the pole
caused by the second capacitor of value CF connected at
the EL4452 -VGAIN input. The -Reference can be exchanged
for a positive reference by connecting it to the ground return
of the 1kΩ resistor at the FB terminal and grounding REF.
As a general consideration, the input signal applied to an
EL4452 should be kept below about 250mV peak for good
linearity. If the AGC were designed to produce a 1V peak
output, the input range would be 100mV–250mV peak when
the EL4452 has a feedback network that establishes a
maximum gain of 10. This is an input range of only 2.5:1 for
precise output regulation. Raising the maximum gain to 25
allows a 40mV–250mV input range with the output still
regulated, better than 6:1. Unfortunately, the bandwidth will
be reduced. Bandwidth can be maintained by adding a high
frequency op-amp cascaded with the output to make up gain
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reliable. However, no responsibility is assumed by Intersil or its subsidiaries for its use; nor for any infringements of patents or other rights of third parties which may result
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