Fairchild Rc4194 User manual

www.fairchildsemi.com

Features

• Simultaneously adjustable outputs with one resistor

to ±42V

• Load current – ±200 mA with 0.04% load regulation

Description

The RC/RM4194 are dual polarity tracking regulators

designed to provide balanced or unbalanced positive and

negative output voltages at currents to 200 mA.

A single external resistor adjustment can be used to change

both outputs between the limits of ±50 mV and ±42V.

These devices are designed for local “on-card” regulation,

eliminating distribution problems associated with single-

point regulation. To simplify application the regulators

require a minimum number of external parts.

The device is available in three package types to accommo-

date various power requirements. The K (TO-66) power

package can dissipate up to 3W at TA= +25°C. The D

14-pin dual in-line will dissipate up to 1W and the N

14-pin dual in-line will dissipate up to 625 mW.

• Internal thermal shutdown at TJ= +175°C

• External balance for ±VOUT unbalancing

• 3W power dissipations

Block Diagram

Comp+

Bal

+VS

–VS

–VOUT

+VOUT

GND

RSET

65-4194-01

Thermal

Shutdown

100µA

Current

Source

Comp–

20K

4194

20K

3R R

RC4194

Dual Tracking Voltage Regulators

Rev. 1.0.0

PRODUCT SPECIFICATION RC4194

Absolute Maximum Ratings

(beyond which the device may be damaged)1

Note:

1. Functional operation under any of these conditions is NOT implied.

Parameter Min Typ Max Units

Supply Voltage RC4194 ±35 V

RM4194 ±45 V

Supply Input to Output Voltage Differential RC4194 ±35 V

RM4194 ±45 V

Load Current PDIP 100 mA

CerDIP 150 mA

TO-66 Metal Can 250 mA

PDTA< 50°C PDIP 468 mW

CerDIP 1042 mW

TO-66 Metal Can 2381 mW

Operating Temperature (Tj) RC4194 0 70 °C

RM4194 -55 125 °C

Storage Temperature -65 150 °C

Junction Temperature PDIP 125 °C

CerDIP 175 °C

TO-66 Metal Can 150 °C

Lead Soldering Temperature (60 seconds) 300 °C

For TA> 50°C Derate at TO-66 Metal Can 23.81 mW/°C

PDIP 6.25 mW/°C

CerDIP 8.38 mW/°C

Pin Assignments

65-4194-02

GND

-VOUT

Comp-

Bal

Comp+

+VOUT

-V (Case) S

SET

Comp+

Bal

Comp-

+VOUT

-V

GND

-VOUT

SET

65-4194-03

RC4194 PRODUCT SPECIFICATION

Operating Conditions

Electrical Characteristics

(±5 £VOUT £VMAX; –VIN £-8V; IL= ±1mA; RM4194: -55°C £Tj£+125°C; RC4194: 0°C £Tj£+70°C

unless otherwise speciﬁed)

Notes:

1. Measured as (mA)

2. Output voltage temperature drift guaranteed by design.

3. The current drain will increase by 50mA/VOUT on positive side and 100mA/VOUT on negative side.

4. The specifications above apply for the given junction temperatures since pulse test conditions are used.

Parameter Min Typ Max Units

qJC Thermal Resistance CerDIP 60 °C/W

TO-66 Metal Can 7 °C/W

qJA Thermal Resistance PDIP 160 °C/W

CerDIP 120 °C/W

TO-66 Metal Can 42 °C/W

Parameters Test Conditions Min Typ Max Units

Line Regulation DVS= 0.1 VIN 0.04 0.1 %VOUT

Load Regulation14194K: IL< 200 mA

4194D: IL< 100 mA

±VS= ±(VOUT + 5)V

0.002 0.004 %VOUT/IL

(mA)

Output Voltage Drift With

Temperature2

Positive Output VOUT = ±5V 0.002 0.015 %/°C

Negative Output VOUT = ±5V 0.003 0.015 %/°C

Supply Current3(Positive) VS= ±VMAX, VOUT = 0V,

IL= 0 mA +0.8 +2.5 mA

Supply Current4(Negative) VS= ±VMAX, VOUT = 0V,

IL= 0 mA -1.8 -4.0 mA

Supply Voltage RM4194 ±9.5 ±45 V

RC4194 ±9.5 ±35 V

Output Voltage Scale Factor RSET = 71.5 kW, Tj= +25°C,

VS= ±VMAX 2.38 2.5 2.62 kW/V

Output Voltage Range RM4194: RSET = 71.5 kW,

IL= 25 mA 0.05 ±42 V

RC4194: RSET = 71.5 kW,

IL= 25 mA 0.05 ±42 V

Output Voltage Tracking ±0.4 ±2.0 %

Ripple Rejection F = 120 Hz, Tj= +25°C70dB

Input-Output Voltage Differential IL= 50 mA, Tj= +25°C 3.0 V

Short Circuit Current VS= ±30V, Tj= +25°C 300 mA

Output Noise Voltage CL= 4.7 mF, VOUT = ±15V,

F = 10 Hz to 100 kHz 250 mVRMS

Internal Thermal Shutdown 175 °C

DVOUT

VOUT

------------------ 100%´

èø

æö

PRODUCT SPECIFICATION RC4194

Typical Performance Characteristics

Figure 1. Ripple Rejection vs. Frequency Figure 2. Load Regulation vs. Load Current

Figure 3. Output Voltage Tracking vs. Temperature

65-0201

Ripple Rejection (dB)

F (Hz)

150

130

110

100 100 1K 10K 100K

VOUT = ±15V

65-0202

Tj= +125¡C

Tj= +25¡C

0.06

0.05

0.04

0.03

0.02

0.01

-0.01 020 40 60 80 100 120 140 160 180 200

IL(mA)

Load Regulation (% VOUT/IL)

65-0203

0.8

0.6

0.4

0.2

-0.2

-0.4

-0.6

Tj(¡C)

Output Voltage Tracking (% VOUT)

-60 -40 -20 0 +20 +40 +60 +80+100+120+140

A = % Tracking of VOUT

B = T.C. for Positive Regulator

C = T.C. for Negative Regulator

RC4194 PRODUCT SPECIFICATION

Typical Applications

Figure 4. Unbalanced Output Voltage — Comparator Application

Figure 5. High Output Application

0.01µF

-VS

+V S

-VS

71.5K

0.01µF

RSET Comp- Gnd

RM4194

Comp+

R-V

Bal

+VOUT

OUT

4.7µF

4805

4.7µF**

+VOUTTo Additional

Comparators

(Typically 15 RC4805s)

-V = -5V

To Additional

Comparators

R (k½) = 2.5 (-V )

Adjust R for -V = -5V (12.5 k )

R = R = 20 k½(See Schematic)

+ V = -V

R = when +V -V

For +V = 5 when -V = -5V

R =

OUT

F1 F2

OUT OUT

AOUT OUT

BOUT OUT

OUT OUT

OUT

R R

F1 A

F2 B

65-0205

65-0206

-VS

0.1 F

-V

GND Comp+

-V

Comp-

60µF

-V

60µF**

2N2297 or equiv.

R *

0.1 F

4194

71.5K

2N914 or equiv.

2N2297 or equiv.

R *

2N4905 or equiv.

*R =

**Optional usage - Not as critical as -V bypass capacitors.

Note: Compensation and bypass capacitor connections should be close as posibe to the 4194

0.7

SC SC

SET

OUT

0OUT

+VOUT

Load regulation

10 mV @ 2.5A

R (k ) = 2.5 V

OWO

PRODUCT SPECIFICATION RC4194

Typical Applications (continued)

Figure 6. Balanced Output Voltage — Op Amp Application

Figure 7. Digitally Controlled Dual 200 mA Voltage Regulator

0.001µF

-VS

71.5K

0.001µF

RSET Comp- Gnd

4194

Comp+

R-V

+VOUT

OUT

R4.7µF

741

4.7µF**

+V = +15V

OUT To Additional

Op Amps

(Typically 180 741s)

-V = -15V

To Additional

Op Amps

OUT

65-0204

OUT

R (k½) = 2.5 V

65-1725

Optional Tracking

Adjustment

100K

-V

Bal

RC4194K

Binary Inputs

MSB LSB

5678910 11 12

Adjust R2 for -19.92V at -VOUT with all "1s" at binary inputs,

then optionally adjust R3 for +19.92V at +VOUT

2.49K

Ref-

Ref+ -V Comp +V

DAC-08

In Out

Gnd

REF-02

250

4.87K C

-VS

14 316

0.01µF

0.001

+V = +25V

Comp +V +V

6+V (0 to +19.92V)

10µF

-V (0 to -19.92V)

Comp-

-V Gnd

RC4194K

0.001

-V = -25V

9Case 4

V = 4 I R1

SET

OUT

3-VO

RC4194 PRODUCT SPECIFICATION

RC4194 Switchable Power Supply

The outputs of the RC4194 can be simultaneously switched

on or off under logic control as shown in Figure 8. In the

“off” state, the outputs will be forced to a minimum voltage,

or about ±20 mV, rather than becoming open-circuit. The

turn-on time, with the outputs programmed to ±12V, is

approximately 200 mS. This circuit works by forcing the R0

pin to ground with an analog switch.

Refer to the RC4194 internal schematic diagram. A refer-

ence voltage that regulates with respect to –VSis generated

at the RSET pin by the zener diode Q12 and the buffer cir-

cuit of Q11 and Q13. When the external 71.5k RSET resis-

tor is connected between the RSET pin and –VS, a precision

current of 100 mA is generated which then ﬂows into Q13’s

collector. Since Q13’s collector is tied to the R0 pin, the 100

mA current will develop a ground-referenced voltage drop

proportional to the value of R0, which is then ampliﬁed by

the internal error ampliﬁer. When the analog switch in Fig-

ure 8 turns on, it effectively shorts out R0 and causes 0V to

be applied to the error ampliﬁer. The output voltage in the

off state will be approxi-mately ±20 mV. If a higher value

(50 to 100 mV) is acceptable, then the DG201 analog switch

can be replaced with a low-cost small signal transistor, as

shown in the alternate switch conﬁguration.

Compensation

Formostapplications, thefollowing compensationtechnique

is sufﬁcient. The positive regulator section of the RC4194 is

compensated by a 0.001 mF ceramic disc capacitor from the

Comp+ terminal to ground. The negative regulator requires

compensation at two points. The ﬁrst is the Comp– pin,

which should have 0.001 mF to the –VSpin, or case. A

ceramic disc is ideal here. The second compen-sation point

for the negative side is the –VOUT terminal, which ideally

should be a 4.7 mF solid tantalum capacitor with enough

reserve voltage capacity to avoid the momentary shorting

and reforming which can occur with tantalum caps. For sys-

tems where the cost of a solid tantalum capacitor cannot be

justiﬁed, it is usually sufﬁcient to use an aluminum capacitor

with a 0.03 mF ceramic disc in parallel to bypass high fre-

quencies. In addition, if the rectiﬁer ﬁlter capacitors have

poor high frequency characteristics (like aluminum electro-

lytics) or if any impedance is in series with the +VSand –VS

terminals, it is necessary to bypass these two points with

0.01 mF ceramic disc capacitors. Just as with monolithic op

amps, some applications may not require these bypass caps,

but if in doubt, be sure to include them.

Figure 8. ±12V Switchable Power Supply

65-4083

Comp+

+VOUT

–VOUT

4.7 µF

0.001 µF

4.7 µF

+12V

-12V

30K

4194

RGnd

+VS

Comp–

–VS

RSET

71.5K

0.001 F

-V

Logic

–VS

+VS

Gnd

DG201

0* Alternate Switch Configuration

4194 R0

47K 30K

2N3904

*Quad SPST CMOS Analog Switch

PRODUCT SPECIFICATION RC4194

Figure 9. RC4194 Recommended Compensation

4194

0.001µF

Comp+

R0Comp-

R0RSET

RSET

0.01µF

0.001µF

4.7µF*

65-4201

+VS

–VS

+VS

–VS

+VOUT

–VOUT

+VOUT

–VOUT

Note:

All Capacitors are Ceramic Disc

Except * = Solid Tantalum

All compensation and bypass caps should have short leads,

solid grounds, and be located as close to the 4194 as possi-

ble. Refer to Figure 9 for recommended compensation cir-

cuitry.

Protection

In systems using monolithic voltage regulators, a number of

conditions can exist which, left uncorrected, will destroy the

regulator. Fortunately, regulators can easily be protected

against these potentially destructive conditions. Monolithic

regulators can be destroyed by any reversal of input or output

voltage polarity, or if the input voltage drops below the out-

put voltage in magnitude. These conditions can be caused by

inductive loads at the inputs or outputs of the regulator.

Other problems are caused by heavy loads at the unregulated

inputs to the regulator, which might cause the input voltage

to drop below the output voltage at turn-off. If any of the

preceding problem conditions are present in your system, it

is recommended that you protect the regulator using diodes.

These diodes should be high speed types capable of handling

large current surges. Figure 10 shows all six of the possible

protection diodes. The diodes at the inputs and outputs pre-

vent voltages at those points from becoming reversed.

Diodes from outputs to inputs prevent the output voltage

from exceeding the input voltage. Chances are that the sys-

tem under consideration will not require all six diodes, but if

in doubt, be sure to include them.

Brownout Protection

The RC4194 is one of the most easily applied and trouble-

free monolithic ICs available. When used within the data

sheet ratings (package power dissipation, maximum output

current, minimum and maximum input voltages) it provides

the most cost-effective source of regulated ±15V for power-

ing linear ICs.

Sometimes occasions arise in which the RC4194 ratings

must be exceeded. One example is the “brownout.” During

a brownout, line voltages may be reduced to as low as 75

VRMS, causing the input voltage to the RC4194 to drop

below the minimum dropout voltage. When this happens,

the negative output voltage can go to positive. The maximum

amount of current available is approximately 5 mA.

In general this is not enough current to damage most ICs

which the RC4194 might be supplying, but it is a potentially

destructive condition. Fortunately, it is easy to protect

against. As shown in the typical application circuit in Figure

11, a diode, D, can be connected to the negative output.

Figure 10. RC4194 Regulator Showing All Protective Diodes

4194

0.001µF

Comp+

+VS

-VSR0RSET Comp-

R0RSET

0.01µF

0.001 F

4.7µF*

-VOUT

+VOUT

-VOUT

65-4202

+VS

-VS

-V

OUT

Note:

All Capacitors are Ceramic Disc

Except * = Solid Tantalum

RC4194 PRODUCT SPECIFICATION

If a small signal silicon diode is used, it will clamp the nega-

tive output voltage at about +0.55V. A Schottky barrier or

germanium device would clamp the voltage at about +0.3V.

Another cure which will keep the negative output negative at

all times is the 1 mWresistor connected between the +15V

output and the Comp- terminal. This resistor will then sup-

ply drive to the negative output transistor, causing it to satu-

rate to -1V during the brownout.

Heatsinking

Voltage Regulators are power devices which are used in a

wide range of applications.

When operating these devices near their extremes of load

current, ambient temperature and input-output differential,

consideration of package dissipation becomes important to

avoid thermal shutdown at 175°C. The RC4194 has this fea-

ture to prevent damage to the device. It typically starts

affecting load regulation approximately 2°C below 175°C.

To avoid shutdown, some form of heatsinking should be used

or one of the above operating conditions would need to be

derated.*

The following is the basic equation for junction temperature:

Equation 1

where

TJ= junction temperature (°C)

TA= ambient air temperature (°C)

PD= power dissipated by device (W)

qJ-A = thermal resistance from junction to ambient

air (°C/W)

The power dissipated by the voltage regulator can be detailed

as follows:

Equation 2

where

VIN = input voltage

VOUT = regulated output voltage

IO= load current

IQ= quiescent current drain

TJTAPDqJA–

PDVIN VOUT

–()IOVIN IQ

´+´=

Let’s look at an application where a user is trying to deter-

mine whether the RC4194 in a high temperature environ-

ment will need a heatsink.

Given:

TJat thermal shutdown = 150°C

TA= 125°C

qJ-A = 41.6°C/W, K (TO-66) pkg.

VIN = 40V

VOUT = 30V

IQ= 1 mA + 75 mA/VOUT x 30V

= 3.25 mA*

Solve for IO,

= 60 mA – 13 mA ~ 47 mA

If this supply current does not provide at least a 10% margin

under worst case load conditions, heatsinking should be

employed. If reliability is of prime importance, the multiple

regulator approach should be considered.

In Equation 1, qJ-A can be broken into the following compo-

nents:

qJ-A = qJ-C + qC-S + qS-A

where

qJ-C = junction-to-case thermal resistance

qC-S = case-to-heatsink thermal resistance

qS-A = heatsink-to-ambient thermal resistance

qJA–TJTA

–

------------------=

PDTJTA

–

qJA–

------------------=

VIN VOUT

–()IOVIN IQ

´+´=

IOTJTA

–

qJA–VIN VOUT

–()

-------------------------------------------------VIN IQ

VIN VOUT

–()

-----------------------------------–=

IO150°C 125°C–

41.6°C/W 10V´

----------------------------------------- 40 3.25´10 3–

----------------------------------------–=

———————————————

*The current drain will increase by 50mA/VOUT on positive side and 100mA/VOUT on negative side

PRODUCT SPECIFICATION RC4194

Table 1. Commercial Heatsink Selection Guide

No attempt has been made to provide a complete list of all heatsink manufacturers.This list is only representative.

Staver Co., Inc.: 41-51 N Saxon Ave., Bay Shore, NY 11706

IERC: 135 W Magnolia Blvd., Burbank, CA 91502

Thermalloy: P.O. Box 34829, 2021 W Valley View Ln., Dallas, TX

Wakefield Engin Ind: Wakefield, MA 01880

* All values are typical as given by manufacturer or as determined from characteristic curves supplied by manufacturer.

qS-A1(°C/W) Manufacturer/Series or Part Number

TO-66 Package

0.31 – 1.0 Thermalloy — 6441, 6443, 6450, 6470, 6560, 6590, 6660, 6690

1.0 – 3.0 Wakefield — 641

Thermalloy — 6123, 6135, 6169, 6306, 6401, 6403, 6421, 6423, 6427, 6442, 6463, 6500

3.0 – 5.0 Wakefield — 621, 623

Thermalloy — 6606, 6129, 6141, 6303

IERC — HP

Staver — V3-3-2

5.0 – 7.0 Wakefield — 690

Thermalloy — 6002, 6003, 6004, 6005, 6052, 6053, 6054, 6176, 6301

IERC — LB

Staver— V3-5-2

7.0 – 10.0 Wakefield — 672

Thermalloy — 6001, 6016, 6051, 6105, 6601

IERC — LA, uP

Staver — V1-3, V1-5, V3-3, V3-5, V3-7

10.0 – 25.0 Thermalloy — 6-13, 6014, 6015, 6103, 6104, 6105, 6117

Dual In-line Package

20 Thermalloy — 6007

30 Thermalloy — 6010

32 Thermalloy — 6011

34 Thermalloy — 6012

45 IERC — LI

60 Wakefield — 650, 651

In the above example, let’s say that the user’s load current is

200 mA and he wants to calculate the combined qC-S and

qS-A he needs:

Given: IO= 200 mA,

= 11.75°C/W

Given qJ-C = 7.15°C/W for the 4194 in the K package,

qC-S + qS-A = 11.75°C/W – 7.15°C/W

= 4.6°C/W

When using heatsink compound with a metal-to-metal

interface, a typical qC-S = 0.5°C/W for the K package.

The remaining qS-A of approximately 4°C/W is a large

enough thermal resistance to be easily provided by a number

of heatsinks currently available. Table 1 is a brief selection

guide to heatsink manufacturers.

qJA–TJTA

–

VIN VOUT

–()IOVIN IQ

´+´

---------------------------------------------------------------------------=

50°C 125°C–

10V 200mA´40+ 3.25 10 3–

´´

----------------------------------------------------------------------------------=

RC4194 PRODUCT SPECIFICATION

Simpliﬁed Schematic Diagram

65-0198

Q28 Q30

Q29

Q33

Q34 Q37

Q36

Q35

Q38

Comp+

(7)

R18

10K

500 R5

25K

Q47

Q16

Q13

Q11

Q10

Q12

10 pF R6

30K

12K Q6

680

5000 R7

5000

(3)

R (2)

R11

3900 R10

1650

Q19

Q22

Q23 Q24

Q17 Q21

Q20

Q44 R8

5000

Q31

Q25

Q26

8 kW

200W

R14

3000

Q46

Q18 Q43

R15

1.1

Q27

(1)

-V

OUT

15K

Q45

(6)

(8)

(4)

-V

Bal

Gnd

OUT

RF1

RF2

R23

20K

R24

20K

Q32

Q36 Q42

Q40 Q41

R21

1.1

R19

3000

R20

200

-V

To Case (9)

Comp-

SET 0

(5)

+Vs

Note: Pin numbers are for K package.

PRODUCT SPECIFICATION RC4194

Mechanical Dimensions

9-Lead Metal Can IC Header Package

øb

øp

øD1

øD

Notes:

1. All leads—increase maximum limit by .003 (.08mm) when

lead finish is applied.

A .250 .340 6.35 8.64

Symbol Inches

Min. Max. Min. Max.

Millimeters Notes

øb .028 .034 .71 .86

øD — .620 — 15.75

øD1 .470 .500 11.94 12.70

.190 .210 4.83 5.33

.093 .107 2.36 2.72

F .050 .075 1.27 1.91

.360 — 9.14 —

.142 .152 3.61 3.86

.958 .962 24.33 24.43

øp

q— .350 — 8.89

r1 — .145 — 3.68

r2 .570 .590 14.48 14.99

RC4194 PRODUCT SPECIFICATION

Mechanical Dimensions (continued)

14-Lead Ceramic DIP Package

A — .200 — 5.08

Symbol Inches

Min. Max. Min. Max.

Millimeters Notes

b1 .014 .023 .36 .58

.065 1.65

b2 .045 1.14

c1 .008 .015 .20 .38

E .220 .310 5.59 7.87

e.100 BSC 2.54 BSC

L .125 .200 3.18 5.08

.015 .060 .38 1.52

.005 — .13 — 3

5, 9

eA .300 BSC 7.62 BSC 7

s1 90¡105¡90¡105¡

D — .785 — 19.94

Notes:

Index area: a notch or a pin one identification mark shall be located

adjacent to pin one. The manufacturer's identification shall not be

used as pin one identification mark.

The minimum limit for dimension "b2" may be .023 (.58mm) for leads

number 1, 7, 8 and 14 only.

Dimension "Q" shall be measured from the seating plane to the base

plane.

This dimension allows for off-center lid, meniscus and glass overrun.

The basic pin spacing is .100 (2.54mm) between centerlines. Each

pin centerline shall be located within ±.010 (.25mm) of its exact

longitudinal position relative to pins 1 and 14.

Applies to all four corners (leads number 1, 7, 8, and 14).

"eA" shall be measured at the center of the lead bends or at the

centerline of the leads when "a" is 90¡.

All leads – Increase maximum limit by .003 (.08mm) measured at the

center of the flat, when lead finish applied.

Twelve spaces.

NOTE 1

s1 814

PRODUCT SPECIFICATION RC4194

Mechanical Dimensions (continued)

14-Lead Plastic DIP Package

814

A — .210 — 5.33

Symbol Inches

Min. Max. Min. Max.

Millimeters Notes

A1 .015 — .38 —

.022 .56

B .014 .36

.195 4.95

A2 .115 2.93

B1 .045 .070 1.14 1.78

D .725 .795 18.42 20.19

.300 .325 7.62 8.26

eB — .430 — 10.92

.115 .200 2.92 5.08

e.100 BSC 2.54 BSC 2

L14 14 5

.240 .280 6.10 7.11

C .008 .015 .20 .38

D1 .005 — .13 —

Notes:

Dimensioning and tolerancing per ANSI Y14.5M-1982.

"D" and "E1" do not include mold flashing. Mold flash or protrusions

shall not exceed .010 inch (0.25mm).

Terminal numbers are shown for reference only.

"C" dimension does not include solder finish thickness.

Symbol "N" is the maximum number of terminals.

PRODUCT SPECIFICATION RC4194

5/20/98 0.0m 001

Stock#DS30004194

Ó1998 Fairchild Semiconductor Corporation

LIFE SUPPORT POLICY

FAIRCHILD’S PRODUCTS ARE NOT AUTHORIZED FOR USE AS CRITICAL COMPONENTS IN LIFE SUPPORT DEVICES

OR SYSTEMS WITHOUT THE EXPRESS WRITTEN APPROVAL OF THE PRESIDENT OF FAIRCHILD 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 (c) 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 of the

user.

2.A critical component in any component of a life support

device or system whose failure to perform can be

reasonablyexpected tocause thefailure ofthe lifesupport

device or system, or to affect its safety or effectiveness.

www.fairchildsemi.com

Ordering Information

Note:

1./883B suffix denotes MIL-STD-883, Par. 1.2.1 compliant device.

Product Number Temperature Range Screening Package SMD Number

RC4194N 0°to +70°CCommercial 14 pin Plastic DIP

RC4194D 0°to +70°CCommercial 14 pin Ceramic DIP

RC4194K 0°to +70°CCommercial 9 pin TO-66

RM4194D -55°C to +125°CCommercial 14 pin Ceramic DIP

RM4194D/883B -55°C to +125°CMilitary14 pin Ceramic DIP 7705401CA

RM4194K -55°C to +125°CCommercial 9 pin TO-66

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