INTERSIL EL4083CS

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EL4083
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conta -INTERSIL
1-888
December 1995, Rev. B
FN7157
Current Mode Four Quadrant Multiplier
Features
The EL4083 makes use of an Elantec
fully complimentary oxide isolated
bipolar process to produce a patent
pending current in, current out four quadrant multiplier. Input
and output signal summing and direct interface to other
current mode devices can be accomplished by simple
connection to reduce component count and preserve
bandwidth. The selection of an appropriate series resistor
value allows an input to accept a voltage signal of any size
and optimize dynamic range. The differential outputs offer
significant performance improvements which greatly extend
the usable gain control range at high frequencies. The bias
current is programmable to accommodate the voltage and
power dissipation constraints of the package and available
systems supplies.
• Novel current mode design
- Virtual ground current summing inputs
- Differential ground referenced current outputs
The devices can implement all the classic four quadrant
multiplier applications and are uniquely well suited to gain
control and signal summing of broadband signals.
Ordering Information
PART
NUMBER
• High speed (both inputs)
- 200MHz bandwidth
- 12ns 1% settling time
• Low distortion
- THD < 0.03% @ 1MHz
- THD < 0.1% @ 10MHz
• Low noise (RL = 50Ω)
- 100dB dynamic range
- 10Hz to 20kHz
- 73dB dynamic range
- 10Hz to 10MHz
• Wide supply conditions
- ±5 to ±15V operation
- Programmable bias current
• 0.2dB gain tolerance to 25MHz
TEMP.
RANGE
PACKAGE
PKG. NO.
EL4083CN
-40°C to +85°C
8-Pin PDIP
MDP0031
Features
EL4083CS
-40°C to +85°C
8-Pin SO
MDP0027
• Four quadrant multiplication
• Gain control
Pinout
• Controlled signal summing and multiplexing
EL4083
8-PIN PDIP, SO
TOP VIEW
• HDTV video fading and switching
• Mixing/modulating/demodulating (phase detection)
• Frequency doubling
• Division
• Squaring
• Square rooting
• RMS and power measurement
• Vector addition-RMS summing
Manufactured under U.S. Patent No. 5,389,840
• CRT focus and geometry correction
• Polynomial function generation
• AGC circuits
1
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.
EL4083
Absolute Maximum Ratings (TA = 25 °C)
VS
IZ(BIAS)
IX
IY
Voltage between VS+ and VS- . . . . . . . . . . . . . . .+33V
Z, Bias Current . . . . . . . . . . . . . . . . . . . . . . . . .+2.4mA
X Input Current . . . . . . . . . . . . . . . . . . . . . . . . .±2.4mA
Y Input Current . . . . . . . . . . . . . . . . . . . . . . . . .±2.4mA
Electrical Specifications
PD
TA
TJ
TST
Maximum Power Dissipation. . . . . . . . . . . . . . See Curves
Operating Temperature Range EL4083 . . -40°C to +85°C
Operating Junction Temperature EL4083 . . . . . . . . .150°C
Storage Temperature . . . . . . . . . . . . . . . -65°C to +150°C
TA = 25°C, VS = ±5, IZ = 1.6mA unless otherwise specified.
PARAMETER
CONDITIONS
MIN
TYP
MAX
UNITS
±16.5
V
POWER SUPPLIES
Operating Supply Voltage Range
±4.5
ICC
VS = ±15V, IZ = 0.2mA
7.2
8.5
9.5
mA
ICC
VS = ±5V, IZ = 1.6mA
42.0
44.0
45
mA
IEE
VS = ±15V, IZ = 0.2mA
9.5
10.0
12
mA
IEE
VS = ±5V, IZ = 1.6mA
45
47
48
mA
0.92
0.965
1.01
MULTIPLIER PERFORMANCE
(IXY-IXY) = K(IX × IY)/IZ
Transfer Function (Note 1)
K Value
Total Error (Note 2)
-2mA < IX, IY < 2mA
±0.5
±2
%FS
vs. Temp
TMIN to TMAX
±1.5
±3
%FS
0.25
0.5
%FS
Linearity (Note 3)
Bandwidth (Note 4)
-3dB (Figure 2)
200
225
MHz
X Feedthrough DC to IXY or IXY (Note 1)
IX = ±2mA, IY = 0 (unnulled)
0.15
1.6
%FS
Y Feedthrough DC to IXY or IXY (Note1)
IY = ±2mA, IX = 0 (unnulled)
0.15
1.6
%FS
AC Feedthrough, X to IXY or IXY (Note 5)
IX = 4mAPP, IY = nulled
f = 3.58MHz
-80
dB
f = 100MHz
-28
dB
AC Feedthrough, X to (IXY-IXY) (Note 5)
IX = 4mAPP, IY = nulled,
DC < f < 1 GHz
-50
dB
AC Feedthrough, Y to IXY or IXY (Note 5)
IY = 4mAPP, IX = nulled
f = 3.58MHz
-64
dB
f = 100MHz
-26
dB
IY = 4mAPP, IX = nulled
DC < f < 1 GHz
-50
dB
Full Scale Range
FRS = 1.25 × IZ (Nominal)
±2
mA
Clipping Level
CL = 2 × IZ
2.85
3.2
mA
ZIN (IX)
30
40
48
Ω
ZIN (IY)
30
36
48
Ω
AC Feedthrough, Y to (IXY-IXY)-(Note 5)
INPUTS (IX, IY)
Input Offset Voltages
at Input Pins, IZ = 1.6mA
-4
+4
mV
(VOSX,VOSY)
IZ = 0.2mA
-12
+12
mV
Input Offset Currents (Note 1)
RSX = RSY = 1K, VX = VY = 0
±10
±40
µA
IXOS, IYOS
TMIN to TMAX
±20
IX
IY = 2mA, - 2mA < IX < 2mA
0.1
0.6
%FS
IY
IX = 2mA, - 2mA < IY < 2mA
0.1
0.4
%FS
nA/°C
Nonlinearity
2
EL4083
Electrical Specifications
TA = 25°C, VS = ±5, IZ = 1.6mA unless otherwise specified. (Continued)
PARAMETER
CONDITIONS
Distortion, IX (to IXY or IXY)
MIN
TYP
MAX
UNITS
IY = 2mA, - 2mA < IX < 2mA
Distortion, IY (to IXY or IXY)
f = 3.58MHz
-55
dB
f = 100MHz
-25
dB
f = 3.58MHz
-56
dB
f = 100MHz
-26
dB
f = 3.58MHz
-66
dB
f = 100MHz
-35
dB
f = 3.58MHz
-66
dB
f = 100MHz
-34
dB
IX = 2mA, - 2mA < Iy < 2mA
Distortion, IX (to (IXY - IXY)
IY = 2mA, -2mA < IX < 2mA
Distortion, IY (to (IXY - IXY)
IX = 2mA, -2mA < IY < 2mA
Diff Gain
@ 3.58MHz
IX
IZ = 0.2mA, IY = 0.25mA
0.2
%
IY
IZ = 0.2mA, IX = 0.25mA
0.17
%
IX
IZ = 1.6mA, IY = 2mA
0.1
%
IY
IZ = 1.6mA, IX = 2mA
0.05
%
Diff Phase
@ 3.58MHz
IX
IZ = 0.2mA, IY = 0.25mA
0.5
deg °
IY
IZ = 0.2mA, IX = 0.25mA
0.5
deg °
IX
IZ = 1.6mA, IY = 2mA
0.05
deg °
IY
IZ = 1.6mA, IX = 2mA
0.05
deg °
Output IOS (Note 1)
IX = IY = 0
-15
±120
µA
Diff Output IOS (Note 1)
IX = IY = 0, (IXY-IXY)
±0.1
±80
µA
OUTPUTS (IXY, IYX)
Voltage Compliance
±1.5
±2.0
V
Max Output Current Swing
±2.85
±3.2
mA
125
pA/√Hz
Noise Spectral Density
RL = 50Ω
10Hz < f < 10MHz
IZ (BIAS)
Current Range
Tested
Input Voltage
Input Voltage
0.2
1.6
mA
IZ = 0.2mA
±25
mV
IZ = 1.6mA
±25
mV
NOTES:
1. Specifications are provisional for the EL4083.
2. Error is defined as the maximum deviation from the ideal transfer function expressed as a percentage of the full scale output.
3. Linearity is defined as the error remaining after compensating for scale factor (gain) variation and input and output referred offset errors.
4. Bandwidth is guaranteed using the squaring mode test circuit of Figure 4.
5. Relative to full scale output with full scale sinewave on signal input and zero port input nulled. Specification represents feedthrough of the
fundamental.
3
EL4083
EL4083 Block Diagram
FIGURE 1.
AC Test Fixture
FIGURE 2. AC BANDWIDTH TEST FIXTURE
Burn-In Circuit
FIGURE 3. BURN-IN CIRCUIT PDIP
4
EL4083
Typical Performance Curves
8-Pin SO
Maximum Power Dissipation
vs Ambient Temperature
8-Pin Plastic DIP
Maximum Power Dissipation
vs Ambient Temperature
FIGURE 4.
FIGURE 5.
FIGURE 6. (IX, IY BANDWIDTH VS IZ)
FIGURE 7. (IX, IY 1% SETTLING TIME VS IZ)
FIGURE 8. OUTPUT NOISE DENSITY VS IZ BIAS
5
EL4083
Typical Performance Curves
(Continued)
Input Offset Trim(s)
Output Offset Trim
RTI = (VS × 1.6mA)/(16µA × IZ)
RTO = (VS × 1.6mA)/(30µA × IZ)
FIGURE 9. OPTIONAL EXTERNAL TRIM NETWORKS
FIGURE 10. VZIN VS IZ (TYPICAL)
6
FIGURE 11. (IZIN BANDWIDTH VS IZ
EL4083
General Operating Information
IZ Input (Bias, Divisor) and Power Supplies
The IZ pin is a low impedance (< 20Ω) virtual ground current
input. It can accept positive current from a resistor
connected to a positive voltage source or the positive
supply. The instantaneous bias for the multiplier gain core is
proportional to this current value. Negative applied current
will put the multiplier portion of the circuit in a zero bias state
and the voltage at the pin will be clamped at a diode drop
below ground. The part will respond in a similar manner to
currents from a current source such as the output of a
transconductance amplifier or one of its own outputs. The
overall transfer equation for the EL4083 is:
K(IX × IY)/IZ = (IXY-IXY), K ~ 1
As can be seen from the equation, the Z input can serve as a
divisor input. However, it is different from the other two
inputs in that the value of its current determines the supply
current of the part and the bandwidth and compliance range
of the outputs and other two inputs. Table 1 gives the
equations describing these and other important
relationships. These dependencies can complicate and/or
limit the usefulness of this pin as a computational input. The
IZ dependence of the impedance of the multiplying inputs
can be particularly troublesome. See the IZ divider and the
RMS#2 circuit sections of the application note for some
ways of dealing with this.
The primary intended use for the Z input is as a
programming pin similar in function to those on
programmable op amps. This enables one to trade off power
consumption against bandwidth and settling time and allow
the part to function within its power dissipation rating over its
full operational supply range (±4.5V - ±16.5V). The E4083
has been designed to function well for IZ values in the range
of 200µA < IZ < 1.6mA which corresponds to IX and IY signal
bandwidths of about 50MHz to over 200MHz. Higher values
of IZ may cause problems at temperature extremes while
lower values down to zero will progressively degrade the
input referred D.C. offsets and reduce speed. Below about
50µA of bias current the internal servo amplifier loop which
maintains the IZ pin at ground will lose regulation and the
voltage at the pin will start to move negative (see Figure 10).
This is accompanied by a significant increase in input
impedance of the pin. Figure 11 shows the A.C. bandwidth
of the IZ input as a function of the D.C. value of IZ. Figures 6
and 7 show the bandwidth and 1% settling time of the
multiplying inputs, IX and IY, as functions of IZ.
TABLE 1. BASIC DESIGN EQUATIONS AND RELATIONSHIPS
Positive Supply Current
IS+ = 3.4mA + IZ × 26
Negative Supply Current
IS- = 4.5mA + IZ × 27
Power Dissipation (See Figures 4 and 5)
PWR = (+VS - (-VS)) × (4mA + IZ × 26.5)
Multiplying Input(s) Impedance
RZX = RZY = (32Ω) × 1.6mA/IZ
Multiplying Input(s) Clip Point
IX (clip) = IY (clip) = IZ × 2
Multiplying Input(s) Full Scale Value
IX (fs) = IY (fs)= IZ × 1.25 (nominal)
Multiplying Input Resistor Values
RX = VX (peak)/IX (fs)
(In Terms of Peak Input Signal)
RY = VY (peak)/IY (fs)
Full Scale Output (Single Ended)
IXY = IXY = IX (fs) × IY (fs)/(IZ×2)
Full Scale Output (Differential)
(IXY - IXY) = IX (fs) × IY (fs)/IZ
IZ (Bias) Input Voltage vs IZ
(See Figure 10)
IZ Signal Bandwidth vs IZ
(See Figure 11)
IX, IY Signal Bandwidth vs IZ
(See Figure 6)
IX, IY 1% Settling Time vs IZ
(See Figure 7)
7
EL4083
IX and IY (Multiplier) Inputs and Offset Trimming
The IX and IY pins are low impedance (IZ dependent) virtual
ground current inputs that accept bipolar signals. The input
referred clip value is equal to IZ × 2 while the full scale value
has been chosen to be 1.25 × IZ to maintain excellent distortion
and linearity performance. Operating at higher full scale values
will degrade these two parameters and, to some extent,
bandwidth while improving the signal to noise performance,
feedthrough and control range.
The EL4083 is fundamentally different from conventional
voltage mode multipliers in that the available input range can
be tailored to accommodate voltage sources of almost any size
by selecting appropriate input series resistor values. If desired,
one can interface with voltages that are much greater than the
supplies from which the part is powered. Current source signals
can be connected directly to the multiplier inputs. The parts’
dynamic range can also be tailored to a large extent for a
current signal by the appropriate selection of IZ. These inputs
act in the same manner as a virtual ground input of an
operational amplifier and thus can serve as a summing node for
any number of voltage and/or current signals. Outputs of
components such as current output DACs, transconductance
amplifiers and current conveyors can be directly connected to
the inputs.
Ideally, a multiplier should give zero output if either one of its
multiplying inputs is zero. A nonzero output under these
conditions is caused by a combination of input and output
referred offsets. An output referred offset can be thought of as
a fixed value added to the output and thus only affects D.C.
accuracy. An input referred offset at a multiplying input allows
signal to feedthrough from the other multiplying input to the
output(s). The EL4083 is trimmed during testing at Elantec for
X and Y input referred offset for IZ = 1.6 mA. The internal trim
networks provide a current to each input which nulls the
feedthrough caused by internal device mismatches. These
current values are ratioed to the value of IZ so that the input
referred nulls are largely maintained at different values of IZ.
However, there will be some mistracking in the trim networks so
that the input referred null point will deviate away from zero at
values of IZ lower than 1.6mA. Figure 9 shows optional external
input and output referred offset trim networks which can be
used as needed to improve performance.
As mentioned, the output referred offset only affects D.C.
accuracy which may not be an issue in A.C. applications. In
8
gain control applications one may only need to null feedthrough
with respect to the gain control input.
In gain control (VCA) applications the X input should be used
as the control input and the signal applied to the Y input since it
has slightly higher bandwidth and better linearity and distortion
performance.
Current Outputs (IXY, IXY), Feedthrough and
Distortion
Another unique feature of the EL4083 is the differential ground
referenced current output structure. These outputs can drive
50Ω terminated lines and reactive loads such as transformers,
baluns, and LC tank and filter circuits directly (See EL2082
Data Sheet_Receiver IF Amplifier (Figure 19). The EL2082 also
has a current output.). Unlike low impedance follower buffers,
these outputs do not interact with the load to produce ringing or
instability. If a high level low impedance output is required, the
outputs can be recovered differentially and converted to a
single ended output with a fast op amp such as the EL2075
(see Figure 19). The outputs can also drive current input
devices such as CMF amps, current conveyors and its own
inputs directly by simple connection.
Figures 12 and 14 show the nulled gain and feedthrough
characteristics of the IXY and IXY outputs which are virtually
identical and differ only in phase. Figure 12 is with the A.C.
signal applied to the X input with Y used as the gain control and
in Figure 14 these signals are reversed. Note that in both cases
the signal feedthrough rolls up and peaks near the cutoff
frequency. This is quite typical of the performance of all
previous four quadrant multipliers. Figures 13 and 15 show the
corresponding gain/feedthrough characteristics for the
differentially recovered output signal IXY-IXY. Note that in this
case the peak feedthrough at high frequencies is lower by more
than 40dB (See EL2082 Data Sheet - Receiver IF Amplifier
[Figure 19]. The EL2082 also has a current output).
General Operating Information
Figures 16 and 17 show the total harmonic distortion for the
single-ended and differential recovered outputs for a full scale
A.C. input signal on one input and a full scale D.C. control
signal on the other. Note that above about one megahertz to
the cutoff frequency the THD of the differentially recovered
signal is as much as 10dB lower than the single-ended signals.
EL4083
FIGURE 12. NULLED IXY AND IXY FREQUENCY
RESPONSE (SIGNAL ON XIN, GAIN
CONTROLLED BY YIN)
FIGURE 14. NULLED IXY AND IXY FREQUENCY
RESPONSE (SIGNAL ON YIN,
GAIN CONTROLLED BY XIN)
FIGURE 16. FULL LEVEL XIN THD VS
FREQUENCY
9
FIGURE 13. NULLED (IXY-IXY) FREQUENCY
RESPONSE (SIGNAL ON XIN,
GAIN CONTROLLED BY YIN)
FIGURE 15. NULLED (IXY--IXY) FREQUENCY
RESPONSE (SIGNAL ON YIN,
GAIN CONTROLLED BY XIN)
FIGURE 17. FULL LEVEL YIN THD VS
FREQUENCY
EL4083
Applications
Basic Product Functions
Figures 18 and 19 are the basic schematics for many of the
applications of the EL4083. These can perform signal
mixing, frequency doubling, modulation, demodulation, gain
control/voltage-controlled amplification, multiplication and
squaring. Figure 18 has resistively terminated differential
outputs and has the widest bandwidth. The figure also
shows the option of using the EL2260 dual CMF amplifier to
recover the outputs differentially at very low impedance.
This has a maximum 3dB bandwidth of 130MHz and settles
to 1% in 25ns. Figure 19 uses an EL2075 at the outputs as a
differential to single ended converter with gain to take
advantage of the performance enhancements of the
differentially recovered output mentioned above and to
provide a high level low impedance drive. The -3dB
bandwidth of this circuit is over 150MHz using good layout
techniques. However, to achieve this bandwidth one must
restrict the output swing to little more than 1VPP to avoid
running into the 500V/µs minimum slew rate of the EL2075.
Table 2 shows the input signal assignments for the
applications listed above.
TABLE 2. INPUT SIGNAL ASSIGNMENTS
FOR FIGURES 18 AND 19 CIRCUITS
APPLICATION
Mixer
Signal 1
Signal 2
Frequency Doubler
Signal
Signal
Modulator
Modulating Signal
Carrier
Demodulator
Local Oscillator
Modulated Signal
Gain Control/VCA
Gain Control
Signal
Multiplier
Signal 1
Signal 2
Squarer
Signal
Signal
*X means not connected if function is not used.
IZ = VCC/RZ
RX = VX (MAX) / (1.25 × IZ)
RY = VY (MAX) / (1.25 × IZ)
*1. 51Ω Resistors omitted when using EL2260
*2. Optimum value of RF determined by supplies and amount or tolerable peaking
(-3dB BW ~ 90MHz @ VS = ±5V, BW ~ 150MHz @ ±15V)
FIGURE 18. BASIC SCHEMATIC (DUAL DIFF OUTS)
10
VY
VX
EL4083
IZ = VCC/RZ
RX = VX (MAX) / (1.25 × IZ)
RY = VY (MAX) / (1.25 × IZ)
*Optimized for Wide Bandwidth
FIGURE 19. BASIC SCHEMATIC (SINGLE ENDED CONVERTED)-(150MHZ VCA)
Other Applications
Elantec has also published an applications note covering
other applications of the EL4083. These include dividers,
squaring and square rooting circuits, several RMS and
power measurement circuits, and a wideband AGC circuit.
Also presented are two polynomial computation examples
for video and some HDTV quality fader and summing
circuits. The EL4083 has been found flexible enough to
easily implement all of the classic four quadrant multiplier
applications and also offer interesting new applications
possibilities.
EL4083 Macromodel
This macromodel is compatible with PSPICE (copywritten by
Microsim Corporation). It has been designed to work
accurately for fixed values of IZ (bias) in the range of 200µA
to 1.6mA. The additional simulation burden imposed by
including provision for a time varying IZ was thought not
worthwhile. The value of IZ is specified to the model by the
parameter NS. The relation between IZ and NS is;
IZ = 200µA×NS. All other inputs can accept time varying
signals.
The model will provide good transient and frequency
response and settling time estimates as well as time domain
switching results. Input and output impedance and overload
responses are correctly modeled. The D.C. current drawn
from supplies for a given value of IZ is also correct.
Noise, PSRR and the temperature dependence of A.C.
parameters such as frequency response and settling time
11
are not modeled. Linearity and distortion results from the
model will be worse than the real part by about a factor of
three and do not show the correct frequency dependence.
The macromodel is constructed from simple controlled
sources, passive components and stripped transistor and
diode models. As such it should be usable, perhaps with
slight modification, on all but student or demonstration
simulators where the model’s size may be a problem.
EL4083
EL4083 Macromodel
(Continued)
*EL4083 Macromodel
*Revision A, August 22, 1994
*
*Connection:
IZ(BIAS)
*
|
IX(in)
*
|
|
IY(in)
*
|
|
|
VEE
*
|
|
|
|
VCC
*
|
|
|
|
|
IXY
*
|
|
|
|
|
|
/IXY
*
|
|
|
|
|
|
|
.subckt EL4083 ZIN XIN YIN VEE VCC IXY IYX
.MODEL M1MP5DIODE D TT=60p IS=1f CJO=300f VJ=600m XTI=3 EG=1.11 RS=80m
.MODEL M2MDCAP D TT=100n IS=2e-17 CJO=1p VJ=800m RS=300
.MODEL M3MNPN1 NPN CJC=1.3p TF=120p IS=1.04f BF=120 CJS=480f
.MODEL M4MPNP1 PNP CJC=1.79p TF=50.166666666667p IS=1f BF=90 CJS=480f
C1 N9 N7 9p
C2 N7 0 350f
C3 N19 N16 9p
C4 N16 0 350f
D1 0 N15 M2MDCAP 12
D10 0 N26 M1MP5DIODE 1
D11 N26 N27 M1MP5DIODE 1
D12 N29 N30 M1MP5DIODE 1
D13 0 N31 M1MP5DIODE 1
D14 VBP N34 M1MP5DIODE 2
D15 N34 VBP M1MP5DIODE 2
D16 0 N34 M2MDCAP 12.5
D17 N35 0 M2MDCAP 12.5
D18 N35 VBN M1MP5DIODE 2
D19 VBN N35 M1MP5DIODE 2
D2 N15 0 M2MDCAP 12
D20 N42 N10 M2MDCAP 4
D21 N10 0 M2MDCAP 4
D22 0 N20 M2MDCAP 4
D23 N20 N45 M2MDCAP 4
D3 0 N12 M1MP5DIODE 8
D4 N55 N13 M1MP5DIODE 8
D5 0 N25 M2MDCAP 6
D6 N25 0 M2MDECAP 6
D7 0 N22 M1MP5DIODE 8
D8 N54 N23 M1MP5DIODE 8
D9 0 N28 M1MP5DIODE 1
EV94 0 VBN 0 N45 1
EV95 VBP 0 N42 0 1
EV96 N54 0 N21 0 650m
EV97 N55 0 N11 0 650m
EV98 N27 0 N28 0 1
EV99 N29 0 SWIN 0 1
FI10 VN-VEE VFI10 1
FI11 VCC VP-VFI11 1
FI12 VCC N39 VFI12 1
FI13 N37 VEE VFI13 1
FI14 VCC N38 VFI14 1
FI15 N36 VEE VFI15 1
FI16 N45 VEE VFI16 1
FI17 VCC N42 VFI17 1
FI18 N37 N36 VFI18 500m
FI19 N38 N39 VFI19 500m
FI20 VN+ VN- VFI20 500m
12
EL4083
EL4083 Macromodel
(Continued)
FI21 VP+ VP- VFI21 500m
FI22 0 N21 VFI22 1
FI23 N21 0 VFI23 1
FI24 N24 0 VFI24 2
FI25 N14 0 VFI25 2
FI26 N11 0 VFI26 1
FI27 0 N11 VFI27 1
FI28 VCC VEE VFI28 21
FI 29 N28 ZB1 VFI29 1
FI5 N33 0 VFI5 1
FI6 0 N33 VFI6 1
FI7 N35 N34 VFI7 1
FI8 VN+ VEE VFI8 1
FI9 VCC VP+ VFI9 1
IIBGN 0 VEE 2.2m
IIBGP VCC 0 2.46m
IIISWB N32 VEE 629u
IIISWI SWIN VEE 555u
IIZSU N28 VEE 10u
L1 N7 IXA 71n
L2 XIN N7 4n
L3 N16 IYA 71n
L4 YIN N16 4n
L5 N46 IYX 4n
L6 N47 IXY 4n
Q10 N10 VP+[VEE] M4MPNP1 2
Q10 N46 VN+ N36[VEE] M3MNPN1 2
Q11 N47 VN+ N37 [VEE] M3MNPN1 2
Q12 N46 VN- N37 [VEE] M3MNPN1 2
Q13 0 N34 N56 [VEE] M4MPNP1 400m
Q14 0 N34 N57 [VEE] M4MPNP1 400m
Q15 0 N35 N58 [VEE] M3MNPN1 400m
Q16 0 N35 N59 [VEE] M3MNPN1 400m
Q2 0 N10 VP- [VEE] M4MPNP1 2
Q3 0 N20 VN+ [VEE] M3MNPN1 2
Q4 0 N20 VN- [VEE] M3MNPN1 2
Q5 N46 VP- N39 [VEE] M4MPNP1 2
Q6 N47 VP+ N39 [VEE] M4MPNP1 2
Q7 N46 VP+ N38 [VEE] M4MPNP1 2
Q8 N47 VP- N38 [VEE] M4MPNP1 2
Q9 N47 VN- N36 [VEE] M3MNPN1 2
R1 N15 N7 60 TC=824u 7.67u
R10 N16 N17 450 TC=0 0
R11 YIN N16 100 TC=0 0
R12 0 SWIN 500 TC=824u 7.67u
R13 N56 N38 35 TC=0 0
R14 N57 N39 35 TC=0 0
R15 N37 N58 35 TC=0 0
R16 N36 N59 35 TC=0 0
R17 N46 IYX 100 TC=0 0
R18 N47 IXY 100 TC=0 0
R2 N11 IXC 6.25 TC=0 0
R3 N9 IXC 4.5 TC=0 0
R4 N7 IXA 1.5K TC=0 0
R5 XIN N7 100 TC=0 0
R6 N25 N16 156 TC=824u 7.67u
R7 N21 IYC 6.25 TC=0 0
R8 ITC N19 45 TC=0 0
R9 N17 IYA 45 TC=0 0
RSU VEE 0 16K TC=0 0
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EL4083
EL4083 Macromodel
(Continued)
VFI10 N43 N44 0.0
VFI11 N40 N41 0.0
VFI12 ZB4 ZB5 0.0
VFI13 ZB5 ZB6 0.0
VFI14 ZB3 ZB4 0.0
VFI15 ZB6 ZB7 0.0
VFI16 N44 ZB9 0.0
VFI17 N41 ZB8 0.0
VFI18 IYB IYC 0.0
VFI19 IYA IYB 0.0
VFI20 IXB IXC 0.0
VFI21 IXA IXB 0.0
VFI22 N22 N24 0.0
VFI23 N23 N24 0.0
VFI24 ZB2 ZB3 0.0
VFI25 ZB1 ZB2 0.0
VFI26 N13 N14 0.0
VF127 N12 N14 0.0
VFI28 ZB9 VEE 0.0
VFI29 ZIN N26 0.0
VF15 N30 N32 0.0
VFI6 N31 N32 0.0
VFI7 N33 0 0.0
VFI8 ZB8 N43 0.0
VFI9 ZB7 N40 0.0
.ENDS
All Intersil U.S. products are manufactured, assembled and tested utilizing ISO9000 quality systems.
Intersil Corporation’s quality certifications can be viewed at www.intersil.com/design/quality
Intersil products are sold by description only. Intersil Corporation reserves the right to make changes in circuit design, software and/or specifications at any time without
notice. Accordingly, the reader is cautioned to verify that data sheets are current before placing orders. Information furnished by Intersil is believed to be accurate and
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
from its use. No license is granted by implication or otherwise under any patent or patent rights of Intersil or its subsidiaries.
For information regarding Intersil Corporation and its products, see www.intersil.com
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