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RC4200

Analog Multiplier

Fairchild Semiconductor 

PRODUCT SPECIFICATION

RC4200

Voltage Multiplier/Divider

R1

8

VX

I1

7

R4

5

VZ

I4

RC4200

VY

R2

1

I2

4

2

3

I3

6

RO VO

VXVY = VOVZ

–VS

R1R2 ROR4

65-4200-04

Figure 3. Voltage Multiplier/Divider

Solving for V0

=

V-----X----V----Y------------R----0---R----4-

VZ

R1R2

For a multiplier circuit VZ = VR = cons tan t

Therefore: V0

=

VXVYK where K

=

-----R----0---R----4-----

VRR1R2

For a divider circuit VY = VR = cons tan t

Therefore: V0

=

V-----X-- K

VZ

where K

=

V-----R----R----0---R----4-

R1R2

Extended Range

The input and output voltage ranges can be extended to

include 0 and negative voltage signals by adding bias

currents. The RSCS filter circuits are eliminated when the

input and biasing resistors are selected to limit the respective

currents to 50 µA min. and 250 µA max.

Extended Range Multiplier

VX

(Input)

VY

(Input)

RA

R1

R2

RB

RC

8

5

I1

I4

7

RC4200

1

I2

2

3

4

I3

6

RC4

–VS

+VREF

RD

VO

RO (Output)

+VS

RCX

–VS

65-4200-05

Figure 4. Extended Range Multiplier

Resistors Ra and Rb extend the range of the VX and VY

inputs by picking values such that:

I 1 ( min. )

=

V-----X----(--m-----i--n---.--) + V-----R----E---F-

R1

Ra

=

50 µA,

and I1(max.)

=

V-----X----(--m-----a--x---.--) + -V----R----E---F-

R1

Ra

=

250 µA,

also I2(min.)

=

V-----Y----(--m-----i-n---.--) + V-----R----E---F-

R2

Rb

=

50 µA,

and I2(max.)

=

V-----Y----(--m-----a--x---.--) + -V----R----E---F-

R2

Rb

=

250 µA.

Resistor RC supplies bias current for I3 which allows the

output to go negative.

Resistors RCX and RCY permit equation (6) to balance, ie.:







V-----X---

R1

+

V-----RR-----Ea----F- 







V-----Y---

R2

+

V-----RR----b-E----F- 

=







V-----0-

R0

+

-V----R-----E----F-

RC

+

---V----X-----

RCX

+

R---V--C--Y--Y---







V----R-R----D-E----F- 

V-----Y-----V----X--- + V-----X-----V----R-----E----F-- + V-----Y-----V----R-----E----F-- + V-----R-----E----F- =

R1R2 R1Rb

R2Ra RaRb

V-----0----V----R-----E----F- + -V----X-----V----R-----E----F-- + V-----Y-----V----R-----E----F-- + V-----R-----E----F--2

R0Rd

RcxRd RCYRd RcRd

Cross-Product Cancellation

Cross-products are a result of ths VXVR and VYVR terms.

To the extend that R1Rb = RCXRD, and R2Ra = RCYRd

cross-product cancellation will occur.

Arithmetic Offset Cancellation

The offset caused by the VREF2 term will cancel to the

extent that RaRb = R0Rd, and the result is:

V-----Y----V----X--

R1R2

=

-V----0---V----R----E---F-

R0Rd

or

V0

=

VXVYK

where K = --------R----0---R----d--------

VREFR1R2

Resistor Values

Inputs:

VX(min.) ≤ VX ≤ VX(max.)

∆VX = VX(max.) – VX(min.)

VY(min.) ≤ VY ≤ VY(max.)

∆VY = VY(max.) = VY(min.)

VREF = Constant (+7V to +18V)

K = -----V-----0----- (Design Requirements)

VXVY

REV. 1.2.1 6/14/01

5

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