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| EL4083C EL4083C Current Mode Four Quadrant Multiplier Features Novel current mode design Virtual ground current summing inputs Differential ground referenced current outputs High speed (both inputs) 200 MHz bandwidth 12 ns 1% settling time Low distortion THD k 0 03% 1 MHz THD k 0 1% 10 MHz Low noise (RL e 50X) 100 dB dynamic range 10 Hz to 20 kHz 73 dB dynamic range 10 Hz to 10 MHz Wide supply conditions g5 to g15V operation Programmable bias current 0 2 dB gain tolerance to 25 MHz General Description The 4083C 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 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 Connection Diagram EL4083 8-Pin SO P DIP Applications Four quadrant multiplication Gain control Controlled signal summing and multiplexing HDTV video fading and switching Mixing modulating demodulating (phase detection) Frequency doubling Division Squaring Square rooting RMS and power measurement Vector addition-RMS summing CRT focus and geometry correction Polynomial function generation AGC circuits 4083 - 1 Top View December 1995 Rev B Ordering Information Part No Temp Range Package Outline EL4083CN b 40 C to a 85 C 8-Pin P-DIP MDP0031 EL4083CS b 40 C to a 85 C 8-Pin SO MDP0027 Manufactured under U S Patent No 5 389 840 Note All information contained in this data sheet has been carefully checked and is believed to be accurate as of the date of publication however this data sheet cannot be a ``controlled document'' Current revisions if any to these specifications are maintained at the factory and are available upon your request We recommend checking the revision level before finalization of your design documentation 1993 Elantec Inc EL4083C Current Mode Four Quadrant Multiplier Absolute Maximum Ratings (TA e 25 C) VS IZ(BIAS) IX IY PD TA a 33V Voltage between VS a and VSb a 2 4 mA Z Bias Current g2 4 mA X Input Current g2 4 mA Y Input Current Maximum Power Dissipation See Curves Operating Temperature Range b 40 C to a 85 C EL4083 Operating Junction Temperature EL4083 150 C b 65 C to a 150 C TST Storage Temperature TJ Important Note All parameters having Min Max specifications are guaranteed The Test Level column indicates the specific device testing actually performed during production and Quality inspection Elantec performs most electrical tests using modern high-speed automatic test equipment specifically the LTX77 Series system Unless otherwise noted all tests are pulsed tests therefore TJ e TC e TA Test Level I II III IV V Test Procedure 100% production tested and QA sample tested per QA test plan QCX0002 100% production tested at TA e 25 C and QA sample tested at TA e 25 C TMAX and TMIN per QA test plan QCX0002 QA sample tested per QA test plan QCX0002 Parameter is guaranteed (but not tested) by Design and Characterization Data Parameter is typical value at TA e 25 C for information purposes only Electrical Characteristics (TA e 25 C Parameter Power Supplies Operating Supply Voltage Range ICC ICC IEE IEE Multiplier Performance Transfer Function (Note 5) K Value Total Error (Note 1) vs Temp Linearity (Note 2) Bandwidth (Note 3) X Feedthrough DC to IXY or IXY (Note 5) Y Feedthrough DC to IXY or IXY (Note 5) AC Feedthrough X to IXY or IXY (Note 4) VS e g5 IZ e 1 6 mA) unless otherwise specified Min Typ Max Test Level Units Conditions g4 5 g16 5 VS VS VS VS e e e e g15V IZ e 0 2 mA g5V IZ e 1 6 mA g15V IZ e 0 2 mA g5V IZ e 1 6 mA 72 42 0 95 45 85 44 0 10 0 47 95 45 12 48 I I I I I V mA mA mA mA (IXY -IXY) e K(IX c IY) IZ 0 92 b 2 mA k IX IY k 2 mA TMIN to TMAX b 3 dB (See Figure 2) IX e g2 mA IY e 0 (unnulled) IY e g2 mA IX e 0 (unnulled) IX e 4 mApp IY e nulled f e 3 58 MHz f e 100 MHz IX e 4 mApp IY e nulled 200 0 965 g0 5 g1 5 0 25 225 0 15 0 15 b 80 b 28 b 50 1 01 g2 g3 05 16 16 I I IV I III I I V V V V V V %FS %FS %FS MHz %FS %FS dB dB dB dB dB dB AC Feedthrough X to (IXY - IXY) (Note 4) AC Feedthrough Y to IXY or IXY (Note 4) AC Feedthrough Y to (IXY - IXY) (Note 4) b 50 2 TD is 3 7in DC k f k 1 GHz IY e 4 mApp IX e nulled f e 3 58 MHz f e 100 MHz IY e 4 mApp IX e nulled DC k f k 1 GHz b 64 b 26 EL4083C Current Mode Four Quadrant Multiplier Electrical Characteristics Parameter Inputs (IX IY) Full Scale Range Clipping Level ZIN (IX) ZIN (IY) Input Offset Voltages (VOSX VOSY) Input Offset Currents (Note 5) IXOS IYOS Nonlinearity IX IY Distortion IX (to IXY or IXY) FRS e 1 25 c IZ (Nominal) CL e 2 c IZ g2 (TA e 25 C VS e g5 IZ e 1 6 mA) unless otherwise specified Test Conditions Min Typ Max Units Level I I I I mA mA X X mV mV mA nA C %FS %FS dB dB dB dB dB dB dB dB % % % % deg deg deg deg mA mA V mA pA rootHz mA mV mV TD is 5 8in Contd at Input Pins IZ e 1 6 mA IZ e 0 2 mA RSX e RSY e 1K VX e VY e 0 TMIN to TMAX IY e 2 mA b 2 mA k IX k 2 mA IX e 2 mA b 2 mA k IY k 2 mA IY e 2 mA b 2 mA k IX k 2 mA f e 3 58 MHz f e 100 MHz IX e 2 mA b 2 mA k Iy k 2 mA f e 3 58 MHz f e 100 MHz IY e 2 mA b2 mA k IX k 2 mA f e 3 58 MHz f e 100 MHz IX e 2 mA b2 mA k IY k 2 mA f e 3 58 MHz f e 100 MHz 3 58 MHz IZ e 0 2 mA IY e 0 25 mA IZ e 0 2 mA IX e 0 25 mA IZ e 1 6 mA IY e 2 mA IZ e 1 6 mA IX e 2 mA 3 58 MHz IZ e 0 2 mA IY e 0 25 mA IZ e 0 2 mA IX e 0 25 mA IZ e 1 6 mA IY e 2 mA IZ e 1 6 mA IX e 2 mA IX e IY e 0 IX e IY e 0 (IXY -IXY) 2 85 30 30 b4 b 12 32 40 36 48 48 a4 a 12 g40 g10 g20 I V I I V V V V V V V V V V V V V V V V I I V I V 01 01 b 55 b 25 b 56 b 26 b 66 b 35 b 66 b 34 06 04 Distortion IY (to IXY or IXY) Distortion IX (to (IXY b IXY) Distortion IY (to (IXY b IXY) Diff Gain IX IY IX IY Diff Phase IX IY IX IY Outputs (IXY IYX) Output IOS (Note 5) Diff Output IOS (Note 5) Voltage Compliance Max Output Current Swing Noise Spectral Density 10 Hz k f k 10 MHz IZ (Bias) Current Range Input Voltage Input Voltage 02 0 17 01 0 05 05 05 0 05 0 05 b 15 g1 5 g2 85 g0 1 g2 0 g3 2 g120 g80 RL e 50X Tested IZ e 0 2 mA IZ e 1 6 mA 02 125 16 g25 g25 I I I Note 1 Error is defined as the maximum deviation from the ideal transfer function expressed as a percentage of the full scale output Note 2 Linearity is defined as the error remaining after compensating for scale factor (gain) variation and input and output referred offset errors Note 3 Bandwidth is guaranteed using the squaring mode test circuit of Figure 4 Note 4 Relative to full scale output with full scale sinewave on signal input and zero port input nulled Specification represents feedthrough of the fundamental Note 5 Specifications are provisional for the EL4083 3 EL4083C Current Mode Four Quadrant Multiplier EL4083 Block Diagram 4083 - 3 Figure 1 4 EL4083C Current Mode Four Quadrant Multiplier AC Test Fixture 4083 - 4 Figure 2 AC Bandwidth Test Fixture Burn-In Circuit Top View 4083 - 5 Figure 3 Burn-In Circuit P-DIP 5 EL4083C Current Mode Four Quadrant Multiplier 8-Pin Plastic DIP Maximum Power Dissipation vs Ambient Temperature 8-Lead SO Maximum Power Dissipation vs Ambient Temperature 4083 - 6 4083 - 7 Figure 4 Figure 5 4083 - 10 4083 - 11 Figure 6 (IX IY Bandwidth vs IZ) Figure 7 (IX IY 1% Settling Time vs IZ) 6 EL4083C Current Mode Four Quadrant Multiplier 4083 - 12 Figure 8 Output Noise Density vs IZ Bias Input Offset Trim(s) Output Offset Trim 4083 - 13 4083 - 14 RTI e (VS c 1 6 mA) (16 mA c IZ) RTO e (VS c 1 6 mA) (30 mA c IZ) Figure 9 Optional External Trim Networks 4083 - 15 4083 - 16 Figure 10 VZIN vs IZ (Typical) Figure 11 IZIN Bandwidth vs IZ 7 EL4083C Current Mode Four Quadrant Multiplier General Operating Information IZ Input (Bias Divisor) and Power Supplies The IZ pin is a low impedance ( k 20X) 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 c IY) IZ e (IXY - IXY) K E 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 (g4 5V b g16 5V) The E4083 has been designed to function well for IZ values in the range of 200 mA k IZ k 1 6 mA which corresponds to IX and IY signal bandwidths of about 50 MHz to over 200 MHz 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 50 mA 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 impeddance 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 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 c 2 while the full scale value has been chosen to be 1 25 c IZ to maintain excellent distortion and linearity performance Operating at higher full scale values will degrade these two pa- Table 1 Basic Design Equations and Relationships Positive Supply Current Negative Supply Current Power Dissipation (See Figures 4 and 5) Multipling Input(s) Impedance Multiplying Input(s) Clip Point Multiplying Input(s) Full Scale Value Multiplying Input Resistor Values (In Terms of Peak Input Signal) Full Scale Output (Single Ended) Full Scale Output (Differential) IZ (Bias) Input Voltage vs IZ IZ Signal Bandwidth vs IZ IX IY Signal Bandwidth vs IZ IX IY 1% Settling Time vs IZ IS a e 3 4 mA a IZ c 26 ISb e 4 5 mA a IZ c 27 PWR e ( a VS b (bVS)) c (4 mA a IZ c 26 5) RZX e RZY e (32X) c 1 6 mA IZ IX (clip) e IY (clip) e IZ c 2 IX (fs) e IY (fs) e IZ c 1 25 (nominal) RX e VX (peak) IX (fs) RY e VY (peak) IY (fs) IXY e IXY e IX (fs) c IY (fs) (IZ c 2) (IXY b IXY) e IX (fs) c IY (fs) IZ (See Figure 10) (See Figure 11) (See Figure 6) (See Figure 7) 8 EL4083C Current Mode Four Quadrant Multiplier General Operating Information Contd rameters 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 e 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 6 mA 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 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 50X terminated lines and reactive loads such as transformers baluns and LC tank and filter circuits directly 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 40 dB See EL2082 Data Sheet Receiver IF Amplifier (Figure 19) The EL2082 also has a current output 9 EL4083C Current Mode Four Quadrant Multiplier General Operating Information Contd 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 10 dB lower than the single-ended signals 10 EL4083C Current Mode Four Quadrant Multiplier General Operating Information Contd 4083 - 17 4083 - 18 Figure 12 Nulled IXY and IXY Frequency Response (Signal on XIN Gain Controlled by YIN) Figure 13 Nulled (IXY-IXY) Frequency Response (Signal on XIN Gain Controlled by YIN) 4083 - 19 4083 - 20 Figure 14 Nulled IXY and IXY Frequency Response (Signal on YIN Gain Controlled by XIN) Figure 15 Nulled (IXY -IXY) Frequency Response (Signal on YIN Gain Controlled by XIN) 4083 - 22 4083 - 21 Figure 16 (Full Level XIN THD vs Frequency) Figure 17 (Full Level YIN THD vs Frequency) 11 EL4083C Current Mode Four Quadrant Multiplier This has a maximum 3 dB bandwidth of 130 MHz and settles to 1% in 25 ns 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 b 3 dB bandwidth of this circuit is over 150 MHz using good layout techniques However to achieve this bandwidth one must restrict the output swing to little more than 1 Vpp to avoid running into the 500V ms minimum slew rate of the EL2075 Table 2 shows the input signal assignments for the applications listed above 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 voltagecontrolled 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 Table 2 Input Signal Assignments for Figures 18 and 19 Circuits Application Mixer Frequency Doubler Modulator Demodulator Gain Control VCA Multiplier Squarer VX Signal 1 Signal Modulating Signal Local Oscillator Gain Control Signal 1 Signal VY Signal 2 Signal Carrier Modulated Signal Signal Signal 2 Signal X means not connected if function is not used 12 EL4083C Current Mode Four Quadrant Multiplier Applications Contd IZ e VCC RZ RX e VX (MAX) (1 25 c IZ) RY e VY (MAX) (1 25 c IZ) 1 51X Resistors omitted when using EL2260 2 Optimum value of RF determined by supplies and amount or tolerable peaking g15V) (b3 dB BW E 90 MHz VS e g5V BW E 150 MHz 4083 - 27 Figure 18 Basic Schematic (Dual Diff Outs) IZ e VCC RZ RX e VX (MAX) (1 25 c IZ) RY e VY (MAX) (1 25 c IZ) Optimized for Wide Bandwidth 4083 - 28 Figure 19 Basic Schematic (Single Ended Converted) (150 MHz VCA) 13 EL4083C Current Mode Four Quadrant Multiplier 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 tween IZ and NS is IZ e 200 mA c 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 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 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 200 mA to 1 6 mA 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 be- Macromodel EL4083 Macromodel Revision A August 22 1994 Connection IZ(BIAS) l IX(in) l l IY(in) l l l VEE l l l l VCC l l l l l IXY l l l l l l IXY 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 lllllll subckt EL4083 ZIN XIN YIN VEE VCC IXY IYX MODEL M1MP5DIODE D TT e 60p IS e 1f CJO e 300f VJ e 600m XTI e 3 EG e 1 11 RS e 80m MODEL M2MDCAP D TT e 100n IS e 2e-17 CJO e 1p VJ e 800m RS e 300 MODEL M3MNPN1 NPN CJC e 1 3p TF e 120p IS e 1 04f BF e 120 CJS e 480f MODEL M4MPNP1 PNP CJC e 1 79p TF e 50 166666666667p IS e 1f BF e 90 CJS e 480f C1 N9 N7 9p C2 N7 0 350f C3 N19 N16 9p C4 N16 0 350f 14 EL4083C Current Mode Four Quadrant Multiplier Macromodel Contd Q4 0 N20 VNb VEE M3MNPN1 2 Q5 N46 VPb N39 VEE M4MPNP1 2 Q6 N47 VP a N39 VEE M4MPNP1 2 Q7 N46 VP a N38 VEE M4MPNP1 2 Q8 N47 VPb N38 VEE M4MPNP1 2 Q9 N47 VNb N36 VEE M3MNPN1 2 R1 N15 N7 60 TC e 824u 7 67u R10 N16 N17 450 TC e 0 0 R11 YIN N16 100 TC e 0 0 R12 0 SWIN 500 TC e 824u 7 67u R13 N56 N38 35 TC e 0 0 R14 N57 N39 35 TC e 0 0 R15 N37 N58 35 TC e 0 0 R16 N36 N59 35 TC e 0 0 R17 N46 IYX 100 TC e 0 0 R18 N47 IXY 100 TC e 0 0 R2 N11 IXC 6 25 TC e 0 0 R3 N9 IXC 4 5 TC e 0 0 R4 N7 IXA 1 5K TC e 0 0 R5 XIN N7 100 TC e 0 0 R6 N25 N16 156 TC e 824u 7 67u R7 N21 IYC 6 25 TC e 0 0 R8 ITC N19 45 TC e 0 0 R9 N17 IYA 45 TC e 0 0 RSU VEE 0 16K TC e 0 0 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 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 a VNb VFI20 500m FI21 VP a VPb 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 a VEE VFI8 1 FI9 VCC VP a 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 a VEE M4MPNP1 2 Q10 N46 VN a N36 VEE M3MNPN1 2 Q11 N47 VN a N37 VEE M3MNPN1 2 Q12 N46 VNb 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 VPb VEE M4MPNP1 2 Q3 0 N20 VN a VEE M3MNPN1 2 15 EL4083C EL4083C Current Mode Four Quadrant Multiplier General Disclaimer Specifications contained in this data sheet are in effect as of the publication date shown Elantec Inc reserves the right to make changes in the circuitry or specifications contained herein at any time without notice Elantec Inc assumes no responsibility for the use of any circuits described herein and makes no representations that they are free from patent infringement WARNING Life Support Policy December 1995 Rev B Elantec Inc 1996 Tarob Court Milpitas CA 95035 Telephone (408) 945-1323 (800) 333-6314 Fax (408) 945-9305 European Office 44-71-482-4596 16 Elantec Inc products are not authorized for and should not be used within Life Support Systems without the specific written consent of Elantec Inc Life Support systems are equipment intended to support or sustain life and whose failure to perform when properly used in accordance with instructions provided can be reasonably expected to result in significant personal injury or death Users contemplating application of Elantec Inc products in Life Support Systems are requested to contact Elantec Inc factory headquarters to establish suitable terms conditions for these applications Elantec Inc 's warranty is limited to replacement of defective components and does not cover injury to persons or property or other consequential damages Printed in U S A |
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