REF197GBC_技术文档

Precision Micropower, Low Dropout

Voltage References

REF19x Series

PIN CONFIGURATIONS

8-Lead Narrow-Body SOIC and TSSOP

(S Suffix and RU Suffix)

FEATURES

Initial Accuracy: ؎2 mV Max

Temperature Coefficient: 5 ppm/؇C Max

Low Supply Current: 45 ␮A Max

Sleep Mode: 15 ␮A Max

Low Dropout Voltage

Load Regulation: 4 ppm/mA

Line Regulation: 4 ppm/V

High Output Current: 30 mA

Short Circuit Protection

1

2

3

4

NC

TP

8

7

6

5

REF19x

SERIES

TOP VIEW

(Not to Scale)

NC

V

S

OUTPUT

SLEEP

GND

TP

NC = NO CONNECT

TP PINS ARE FACTORY TEST POINTS,

NO USER CONNECTION

APPLICATIONS

Portable Instrumentation

A-to-D and D-to-A Converters

Smart Sensors

8-Lead Epoxy DIP (P Suffix)

Solar Powered Applications

Loop Current Powered Instrumentations

NC

1

2

TP

8

7

6

5

REF19x

SERIES

NC

V

S

GENERAL DESCRIPTION

TOP VIEW

(Not to Scale)

OUTPUT

TP

3

4

SLEEP

REF19x series precision band gap voltage references use a pat-

ented temperature drift curvature correction circuit and laser

trimming of highly stable thin film resistors to achieve a very low

temperature coefficient and a high initial accuracy.

GND

NC = NO CONNECT

TP PINS ARE FACTORY TEST POINTS,

NO USER CONNECTION

The REF19x series is made up of micropower, Low Dropout

Voltage (LDV) devices providing a stable output voltage from

supplies as low as 100 mV above the output voltage and consum-

ing less than 45 µA of supply current. In sleep mode, which is

enabled by applying a low TTL or CMOS level to the sleep pin,

the output is turned off and supply current is further reduced to

less than 15 µA.

Table I.

Part

Number

Nominal Output

Voltage (V)

REF191

REF192

REF193

REF194

REF195

REF196

REF198

2.048

2.50

3.00

4.50

5.00

3.30

4.096

The REF19x series references are specified over the extended

industrial temperature range (–40°C to +85°C) with typical

performance specifications over –40°C to +125°C for applications

such as automotive.

All electrical grades are available in 8-lead SOIC; the PDIP and

TSSOP are only available in the lowest electrical grade. Products

are also available in die form.

ORDERING GUIDE

Test Pins (TP)

Temperature

Range

Package

Description

Package

Option¹

The test pins, Pin 1 and Pin 5, are reserved for in-package

Zener-zap. To achieve the highest level of accuracy at the output,

the Zener-zapping technique is used to trim the output voltage.

Since each unit may require a different amount of adjustment, the

resistance value at the test pins will vary widely from pin to pin as

well as from part to part. The user should not make any physical

nor electrical connections to Pin 1 and Pin 5.

Model

REF19xGP

REF19xES³

REF19xFS³

REF19xGS

–40°C to +85°C 8-Lead Plastic DIP²N-8

–40°C to +85°C 8-Lead SOIC

SOIC-8

RU-8

REF19xGRU⁴–40°C to +85°C 8-Lead TSSOP

REF19xGBC 25°C

DICE

NOTES

¹N = Plastic DIP, SOIC = Small Outline, RU = Thin Shrink Small Outline.

²8-lead plastic DIP is only available in “G” grade.

REV. E

³REF193 and REF196 are only available in “G” grade.

⁴Available for REF192, REF195, and REF198 only.

Information furnished by Analog Devices is believed to be accurate and

reliable. However, no responsibility is assumed by Analog Devices for its

use, norforanyinfringementsofpatentsorotherrightsofthirdpartiesthat

may result from its use. No license is granted by implication or otherwise

under any patent or patent rights of Analog Devices. Trademarks and

registered trademarks are the property of their respective companies.

One Technology Way, P.O. Box 9106, Norwood, MA 02062-9106, U.S.A.

Tel: 781/329-4700

Fax: 781/326-8703

www.analog.com

REF19x Series

REF191–SPECIFICATIONS

ELECTRICAL CHARACTERISTICS (@ V_S= 3.3 V, T_A= 25؇C, unless otherwise noted.)

Parameter

Symbol

Condition

Min

Typ

Max

Unit

INITIAL ACCURACY¹

E Grade

F Grade

V_O

I_OUT= 0 mA

2.046

2.043

2.038

2.048

2.050

2.053

2.058

V

G Grade

LINE REGULATION²

E Grade

F and G Grades

LOAD REGULATION²

E Grade

F and G Grades

⌬V_O/⌬V_IN

3.0 V ≤ V_S≤ 15 V, I_OUT= 0 mA

V_S= 5.0 V, 0 mA ≤ I_OUT≤ 30 mA

2

4

8

ppm/V

⌬V_O/⌬V_LOAD

V_S– V_O

4

6

10

15

ppm/mA

DROPOUT VOLTAGE

V_S= 3.15 V, I_LOAD= 2 mA

V_S= 3.3 V, I_LOAD= 10 mA

V_S= 3.6 V, I_LOAD= 30 mA

0.95

1.25

1.55

V

LONG-TERM STABILITY³

DV_O

e_N

1000 Hours @ 125°C

1.2

20

mV

NOISE VOLTAGE

0.1 Hz to 10 Hz

µV p-p

NOTES

¹Initial accuracy includes temperature hysteresis effect.

²Line and load regulation specifications include the effect of self-heating.

³Long-term drift is guaranteed by 1000 hours life test performed on three independent wafer lots at 125°C, with an LTPD of 1.3.

Specifications subject to change without notice.

(@ V = 3.3 V, –40؇C ≤ T ≤ +85؇C, unless otherwise noted.)

ELECTRICAL CHARACTERISTICS

S

A

Parameter

Symbol

Condition

Min

Typ

Max

Unit

TEMPERATURE COEFFICIENT^{1, 2}

E” Grade

F Grade

G Grade³

TCV_O/°C

I_OUT= 0 mA

2

5

10

5

10

25

ppm/°C

LINE REGULATION⁴

E Grade

F and G Grades

LOAD REGULATION⁴

E Grade

F and G Grades

⌬V_O/⌬V_IN

3.0 V ≤ V_S≤ 15 V, I_OUT= 0 mA

V_S= 5.0 V, 0 mA ≤ I_OUT≤ 25 C

5

10

20

ppm/V

⌬V_O/⌬V_LOAD

V_S– V_O

5

10

15

20

ppm/mA

DROPOUT VOLTAGE

V_S= 3.15 V, I_LOAD= 2 mA

V_S= 3.3 V, I_LOAD= 10 mA

V_S= 3.6 V, I_LOAD= 25 mA

0.95

1.25

1.55

V

SLEEP PIN

Logic High Input Voltage

Logic High Input Current

Logic Low Input Voltage

Logic Low Input Current

V_H

I_H

V_L

I_L

2.4

V

µA

V

–8

0.8

–8

µA

SUPPLY CURRENT

Sleep Mode

No Load

45

15

µA

NOTES

¹For proper operation, a 1 µF capacitor is required between the output pin and the GND pin of the device.

²TCV_Ois defined as the ratio of output change with temperature variation to the specified temperature range expressed in ppm/ °C.

TCV_O= (V_MAX– V_MIN)/ V_O(T_MAX– T_MIN).

³Guaranteed by characterization.

⁴Line and load regulation specifications include the effect of self-heating.

Specifications subject to change without notice.

–2–

REV. E

REF19x Series

REF191–SPECIFICATIONS

ELECTRICAL CHARACTERISTICS ^{(@ V}_S^{= 3.3 V, –40؇C ≤ T}_A^{≤ +125؇C, unless otherwise noted.)}

Parameter

Symbol

Condition

Min

Typ

Max

Unit

TEMPERATURE COEFFICIENT^{1, 2}

E Grade

F Grade

G Grade³

TCV_O/°C

I_OUT= 0 mA

2

5

10

ppm/°C

LINE REGULATION⁴

E Grade

F and G Grades

LOAD REGULATION⁴

E Grade

F and G Grades

⌬V_O/⌬V_IN

3.0 V ≤ V_S≤ 15 V, I_OUT= 0 mA

V_S= 5.0 V, 0 mA ≤ I_OUT≤ 20 mA

10

20

ppm/V

⌬V_O/⌬V_LOAD

V_S– V_O

10

20

ppm/mA

DROPOUT VOLTAGE

V_S= 3.3 V, I_LOAD= 10 mA

V_S= 3.6 V, I_LOAD= 20 mA

1.25

1.55

V

NOTES

¹For proper operation, a 1 µF capacitor is required between the output pin and the GND pin of the device.

²TCV_Ois defined as the ratio of output change with temperature variation to the specified temperature range expressed in ppm/ °C.

TCV_O= (V_MAX– V_MIN)/ V_O(T_MAX– T_MIN).

³Guaranteed by characterization.

⁴Line and load regulation specifications include the effect of self-heating.

Specifications subject to change without notice.

REV. E

–3–

REF19x Series

REF192–SPECIFICATIONS

(@ V = 3.3 V, T = 25؇C, unless otherwise noted.)

ELECTRICAL CHARACTERISTICS

S

A

Parameter

Symbol

Condition

Min

Typ

Max

Unit

INITIAL ACCURACY¹

E Grade

F Grade

V_O

I_OUT= 0 mA

2.498

2.495

2.490

2.500

2.502

2.505

2.510

V

G Grade

LINE REGULATION²

E Grade

F and G Grades

LOAD REGULATION²

E Grade

F and G Grades

⌬V_O/⌬V_IN

3.0 V ≤ V_S≤ 15 V, I_OUT= 0 mA

V_S= 5.0 V, 0 mA ≤ I_OUT≤ 30 mA

2

4

8

ppm/V

⌬V_O/⌬V_LOAD

V_S– V_O

4

6

10

15

ppm/mA

DROPOUT VOLTAGE

V_S= 3.5 V, I_LOAD= 10 mA

V_S= 3.9 V, I_LOAD= 30 mA

1.00

1.40

V

LONG-TERM STABILITY³

DV_O

e_N

1000 Hours @ 125°C

1.2

25

mV

NOISE VOLTAGE

0.1 Hz to 10 Hz

µV p-p

NOTES

¹Initial accuracy includes temperature hysteresis effect.

²Line and load regulation specifications include the effect of self-heating.

³Long-term drift is guaranteed by 1000 hours life test performed on three independent wafer lots at 125°C, with an LTPD of 1.3.

Specifications subject to change without notice.

(@ V = 3.3 V, T = –40؇C ≤ T ≤ +85؇C, unless otherwise noted.)

ELECTRICAL CHARACTERISTICS

S

A

Parameter

Symbol

Condition

Min

Typ

Max

Unit

TEMPERATURE COEFFICIENT^{1, 2}

E Grade

F Grade

G Grade³

TCV_O/°C

I_OUT= 0 mA

2

5

10

5

10

25

ppm/°C

LINE REGULATION⁴

E Grade

F and G Grades

LOAD REGULATION⁴

E Grade

F and G Grades

⌬V_O/⌬V_IN

3.0 V ≤ V_S≤ 15 V, I_OUT= 0 mA

V_S= 5.0 V, 0 mA ≤ I_OUT≤ 25 mA

5

10

20

ppm/V

⌬V_O/⌬V_LOAD

V_S– V_O

5

10

15

20

ppm/mA

DROPOUT VOLTAGE

V_S= 3.5 V, I_LOAD= 10 mA

V_S= 4.0 V, I_LOAD= 25 mA

1.00

1.50

V

SLEEP PIN

Logic High Input Voltage

Logic High Input Current

Logic Low Input Voltage

Logic Low Input Current

V_H

I_H

V_L

I_L

2.4

V

µA

V

–8

0.8

–8

µA

SUPPLY CURRENT

Sleep Mode

No Load

45

15

µA

NOTES

¹For proper operation, a 1 µF capacitor is required between the output pin and the GND pin of the device.

²TCV_Ois defined as the ratio of output change with temperature variation to the specified temperature range expressed in ppm/ °C.

TCV_O= (V_MAX– V_MIN)/ V_O(T_MAX– T_MIN).

³Guaranteed by characterization.

⁴Line and load regulation specifications include the effect of self-heating.

Specifications subject to change without notice.

REV. E

–4–

REF19x Series

REF192–SPECIFICATIONS

ELECTRICAL CHARACTERISTICS

(@ V_S= 3.3 V, –40؇C ≤ T_A≤ +125؇C, unless otherwise noted.)

Parameter

Symbol

Condition

Min

Typ

Max

Unit

TEMPERATURE COEFFICIENT^{1, 2}

E Grade

F Grade

G Grade³

TCV_O/°C

I_OUT= 0 mA

2

5

10

ppm/°C

LINE REGULATION⁴

E Grade

F and G Grades

LOAD REGULATION⁴

E Grade

F and G Grades

⌬V_O/⌬V_IN

3.0 V ≤ V_S≤ 15 V, I_OUT= 0 mA

V_S= 5.0 V, 0 mA ≤ I_OUT≤ 20 mA

10

20

ppm/V

⌬V_O/⌬V_LOAD

V_S– V_O

10

20

ppm/mA

DROPOUT VOLTAGE

V_S= 3.5 V, I_LOAD= 10 mA

V_S= 4.0 V, I_LOAD= 20 mA

1.00

1.50

V

NOTES

¹For proper operation, a 1 µF capacitor is required between the output pin and the GND pin of the device.

²TCV_Ois defined as the ratio of output change with temperature variation to the specified temperature range expressed in ppm/ °C.

TCV_O= (V_MAX– V_MIN)/ V_O(T_MAX– T_MIN).

³Guaranteed by characterization.

⁴Line and load regulation specifications include the effect of self-heating.

Specifications subject to change without notice.

REF193–SPECIFICATIONS

ELECTRICAL CHARACTERISTICS ^{(@ V}_S^{= 3.3 V, T}_A^{= 25؇C, unless otherwise noted.)}

Parameter

INITIAL ACCURACY¹

G Grade

LINE REGULATION²

G Grades

LOAD REGULATION²

G Grade

Symbol

Condition

Min

Typ

3.0

4

Max

3.010

8

Unit

V_O

I_OUT= 0 mA

2.990

V

⌬V_O/⌬V_IN

3.3 V, ≤ V_S≤ 15 V, I_OUT= 0 mA

V_S= 5.0 V, 0 mA ≤ I_OUT≤ 30 mA

ppm/V

⌬V_O/⌬V_LOAD

V_S– V_O

6

15

ppm/mA

DROPOUT VOLTAGE

V_S= 3.8 V, I_LOAD= 10 mA

V_S= 4.0 V, I_LOAD= 30 mA

0.80

1.00

V

LONG-TERM STABILITY ³

DV_O

e_N

1000 Hours @ 125°C

1.2

30

mV

NOISE VOLTAGE

0.1 Hz to 10 Hz

µV p-p

NOTES

¹Initial accuracy includes temperature hysteresis effect.

²Line and load regulation specifications include the effect of self-heating.

³Long-term drift is guaranteed by 1000 hours life test performed on three independent wafer lots at 125°C, with an LTPD of 1.3.

Specifications subject to change without notice.

REV. E

–5–

REF19x Series

REF193–SPECIFICATIONS

ELECTRICAL CHARACTERISTICS

(@ V_S= 3.3 V, T_A= –40؇C ≤ T_A≤ +85؇C, unless otherwise noted.)

Parameter

Symbol

Condition

Min

Typ

Max

25

Unit

TEMPERATURE COEFFICIENT^{1, 2}

G Grade³

TCV_O/°C

⌬V_O/⌬V_IN

I_OUT= 0 mA

10

ppm/°C

ppm/V

ppm/mA

LINE REGULATION⁴

G Grade

LOAD REGULATION⁴

G Grade

3.3 V ≤ V_S≤ 15 V, I_OUT= 0 mA

V_S= 5.0 V, 0 mA ≤ I_OUT≤ 25 mA

10

20

⌬V_O/⌬V_LOAD

V_S– V_O

10

20

DROPOUT VOLTAGE

V_S= 3.8 V, I_LOAD= 10 mA

V_S= 4.1 V, I_LOAD= 30 mA

0.80

1.10

V

SLEEP PIN

Logic High Input Voltage

Logic High Input Current

Logic Low Input Voltage

Logic Low Input Current

V_H

I_H

V_L

I_L

2.4

V

µA

V

–8

0.8

–8

µA

SUPPLY CURRENT

Sleep Mode

No Load

45

15

µA

NOTES

¹For proper operation, a 1 µF capacitor is required between the output pin and the GND pin of the device.

²TCV_Ois defined as the ratio of output change with temperature variation to the specified temperature range expressed in ppm/ °C.

TCV_O= (V_MAX– V_MIN)/ V_O(T_MAX– T_MIN).

³Guaranteed by characterization.

⁴Line and load regulation specifications include the effect of self-heating.

Specifications subject to change without notice.

(@ V = 3.3 V, –40؇C ≤ T ≤ +125؇C, unless otherwise noted.)

ELECTRICAL CHARACTERISTICS

S

A

Parameter

Symbol

Condition

Min

Typ

Max

Unit

TEMPERATURE COEFFICIENT^{1, 2}

G Grade³

TCV_O/°C

⌬V_O/⌬V_IN

I_OUT= 0 mA

10

ppm/°C

ppm/V

ppm/mA

LINE REGULATION⁴

G Grade

LOAD REGULATION⁴

G Grade

3.3 V ≤ V_S≤ 15 V, I_OUT= 0 mA

V_S= 5.0 V, 0 mA ≤ I_OUT≤ 20 mA

20

⌬V_O/⌬V_LOAD

V_S– V_O

10

DROPOUT VOLTAGE

V_S= 3.8 V, I_LOAD= 10 mA

V_S= 4.1 V, I_LOAD= 20 mA

0.80

1.10

V

NOTES

¹For proper operation, a 1 µF capacitor is required between the output pin and the GND pin of the device.

²TCV_Ois defined as the ratio of output change with temperature variation to the specified temperature range expressed in ppm/ °C.

TCV_O= (V_MAX– V_MIN)/ V_O(T_MAX– T_MIN).

³Guaranteed by characterization.

⁴Line and load regulation specifications include the effect of self-heating.

Specifications subject to change without notice.

REV. E

–6–

REF19x Series

REF194–SPECIFICATIONS

(@ V = 5.0 V, T = 25؇C, unless otherwise noted.)

ELECTRICAL CHARACTERISTICS

S

A

Parameter

Symbol

Condition

Min

Typ

Max

Unit

INITIAL ACCURACY¹

E Grade

F Grade

V_O

I_OUT= 0 mA

4.498

4.495

4.490

4.5

4.502

4.505

4.510

V

G Grade

LINE REGULATION²

E Grade

F and G Grades

LOAD REGULATION²

E Grade

F and G Grades

⌬V_O/⌬V_IN

4.75 V ≤ V_S≤ 15 V, I_OUT= 0 mA

V_S= 5.8 V, 0 mA ≤ I_OUT≤ 30 mA

2

4

8

ppm/V

⌬V_O/⌬V_LOAD

V_S– V_O

2

4

8

ppm/mA

DROPOUT VOLTAGE

V_S= 5.00 V, I_LOAD= 10 mA

V_S= 5.8 V, I_LOAD= 30 mA

0.50

1.30

V

LONG-TERM STABILITY³

DV_O

e_N

1000 Hours @ 125°C

2

mV

NOISE VOLTAGE

0.1 Hz to 10 Hz

45

µV p-p

NOTES

¹Initial accuracy includes temperature hysteresis effect.

²Line and load regulation specifications include the effect of self-heating.

³Long-term drift is guaranteed by 1000 hours life test performed on three independent wafer lots at 125°C, with an LTPD of 1.3.

Specifications subject to change without notice.

ELECTRICAL CHARACTERISTICS ^{(@ V}_S^{= 5.0 V, T}_A^{= –40؇C ≤ T}_A^{≤ +85؇C, unless otherwise noted.)}

Parameter

Symbol

Condition

Min

Typ

Max

Unit

TEMPERATURE COEFFICIENT^{1, 2}

E Grade

F Grade

G Grade³

TCV_O/°C

I_OUT= 0 mA

2

5

10

5

10

25

ppm/°C

LINE REGULATION⁴

E Grade

F and G Grades

LOAD REGULATION⁴

E Grade

F and G Grades

⌬V_O/⌬V_IN

4.75 V ≤ V_S≤ 15 V, I_OUT= 0 mA

V_S= 5.80 V, 0 mA ≤ I_OUT≤ 25 mA

5

10

20

ppm/V

⌬V_O/⌬V_LOAD

V_S– V_O

5

10

15

20

ppm/mA

DROPOUT VOLTAGE

V_S= 5.00 V, I_LOAD= 10 mA

V_S= 5.80 V, I_LOAD= 25 mA

0.5

1.30

V

SLEEP PIN

Logic High Input Voltage

Logic High Input Current

Logic Low Input Voltage

Logic Low Input Current

V_H

I_H

V_L

I_L

2.4

V

µA

V

–8

0.8

–8

µA

SUPPLY CURRENT

Sleep Mode

No Load

45

15

µA

NOTES

¹For proper operation, a 1 µF capacitor is required between the output pin and the GND pin of the device.

²TCV_Ois defined as the ratio of output change with temperature variation to the specified temperature range expressed in ppm/ °C.

TCV_O= (V_MAX– V_MIN)/ V_O(T_MAX– T_MIN).

³Guaranteed by characterization.

⁴Line and load regulation specifications include the effect of self-heating.

Specifications subject to change without notice.

REV. E

–7–

REF19x Series

REF194–SPECIFICATIONS

(@ V = 5.0 V, –40؇C ≤ T ≤ +125؇C, unless otherwise noted.)

ELECTRICAL CHARACTERISTICS

S

A

Parameter

Symbol

Condition

Min

Typ

Max

Unit

TEMPERATURE COEFFICIENT^{1, 2}

E Grade

F Grade

G Grade³

TCV_O/°C

I_OUT= 0 mA

2

5

10

ppm/°C

LINE REGULATION⁴

E Grade

F and G Grades

LOAD REGULATION⁴

E Grade

F and G Grades

⌬V_O/⌬V_IN

4.75 V ≤ V_S≤ 15 V, I_OUT= 0 mA

V_S= 5.80 V, mA 0 ≤ I_OUT≤ 20 mA

5

10

ppm/V

⌬V_O/⌬V_LOAD

V_S– V_O

5

10

ppm/mA

DROPOUT VOLTAGE

V_S= 5.10 V, I_LOAD= 10 mA

V_S= 5.95 V, I_LOAD= 20 mA

0.60

1.45

V

NOTES

¹For proper operation, a 1 µF capacitor is required between the output pin and the GND pin of the device.

²TCV_Ois defined as the ratio of output change with temperature variation to the specified temperature range expressed in ppm/ °C.

TCV_O= (V_MAX– V_MIN)/ V_O(T_MAX– T_MIN).

³Guaranteed by characterization.

⁴Line and load regulation specifications include the effect of self-heating.

Specifications subject to change without notice.

REV. E

–8–

REF19x Series

REF195–SPECIFICATIONS

ELECTRICAL CHARACTERISTICS ^{(@ V}_S^{= 5.10 V, T}_A^{= 25؇C, unless otherwise noted.)}

Parameter

Symbol

Condition

Min

Typ

Max

Unit

INITIAL ACCURACY¹

E Grade

F Grade

V_O

I_OUT= 0 mA

4.998

4.995

4.990

5.0

5.002

5.005

5.010

V

G Grade

LINE REGULATION²

E Grade

F and G Grades

LOAD REGULATION²

E Grade

F and G Grades

⌬V_O/⌬V_IN

5.10 V ≤ V_S≤ 15 V, I_OUT= 0 mA

V_S= 6.30 V, 0 mA ≤ I_OUT≤ 30 mA

2

4

8

ppm/V

⌬V_O/⌬V_LOAD

V_S– V_O

2

4

8

ppm/mA

DROPOUT VOLTAGE

V_S= 5.50 V, I_LOAD= 10 mA

V_S= 6.30 V, I_LOAD= 30 mA

0.50

1.30

V

LONG-TERM STABILITY³

DV_O

e_N

1000 Hours @ 125°C

1.2

50

mV

NOISE VOLTAGE

0.1 Hz to 10 Hz

µV p-p

NOTES

¹Initial accuracy includes temperature hysteresis effect.

²Line and load regulation specifications include the effect of self-heating.

³Long-term drift is guaranteed by 1000 hours life test performed on three independent wafer lots at 125°C, with an LTPD of 1.3.

Specifications subject to change without notice.

(@ V_S= 5.15 V, T_A= –40؇C ≤ T_A≤ +85؇C, unless otherwise noted.)

ELECTRICAL CHARACTERISTICS

Parameter

Symbol

Condition

Min

Typ

Max

Unit

TEMPERATURE COEFFICIENT^{1, 2}

E Grade

F Grade

G Grade³

TCV_O/°C

I_OUT= 0 mA

2

5

10

5

10

25

ppm/°C

LINE REGULATION⁴

E Grade

F and G Grades

LOAD REGULATION⁴

E Grade

F and G Grades

⌬V_O/⌬V_IN

5.15 V ≤ V_S≤ 15 V, I_OUT= 0 mA

V_S= 6.30 V, 0 mA ≤ I_OUT≤ 25 mA

5

10

20

ppm/V

⌬V_O/⌬V_LOAD

V_S– V_O

5

10

20

ppm/mA

DROPOUT VOLTAGE

V_S= 5.50 V, I_LOAD= 10 mA

V_S= 6.30 V, I_LOAD= 25 mA

0.50

1.30

V

SLEEP PIN

Logic High Input Voltage

Logic High Input Current

Logic Low Input Voltage

Logic Low Input Current

V_H

I_H

V_L

I_L

2.4

V

µA

V

–8

0.8

–8

µA

SUPPLY CURRENT

Sleep Mode

No Load

45

15

µA

NOTES

¹For proper operation, a 1 µF capacitor is required between the output pin and the GND pin of the device.

²TCV_Ois defined as the ratio of output change with temperature variation to the specified temperature range expressed in ppm/ °C.

TCV_O= (V_MAX– V_MIN)/ V_O(T_MAX– T_MIN).

³Guaranteed by characterization.

⁴Line and load regulation specifications include the effect of self-heating.

Specifications subject to change without notice.

REV. E

–9–

REF19x Series

REF195–SPECIFICATIONS

ELECTRICAL CHARACTERISTICS

(@ V_S= 5.20 V, –40؇C ≤ T_A≤ +125؇C, unless otherwise noted.)

Parameter

Symbol

Condition

Min

Typ

Max

Unit

TEMPERATURE COEFFICIENT^{1, 2}

E Grade

F Grade

G Grade³

TCV_O/°C

I_OUT= 0 mA

2

5

10

ppm/°C

LINE REGULATION⁴

E Grade

F and G Grades

LOAD REGULATION⁴

E Grade

F and G Grades

⌬V_O/⌬V_IN

5.20 V ≤ V_S≤ 15 V, I_OUT= 0 mA

V_S= 6.45 V, 0 mA ≤ I_OUT≤ 20 mA

5

10

ppm/V

⌬V_O/⌬V_LOAD

V_S– V_O

5

10

ppm/mA

DROPOUT VOLTAGE

V_S= 5.60 V, I_LOAD= 10 mA

V_S= 6.45 V, I_LOAD= 20 mA

0.60

1.45

V

NOTES

¹For proper operation, a 1 µF capacitor is required between the output pin and the GND pin of the device.

²TCV_Ois defined as the ratio of output change with temperature variation to the specified temperature range expressed in ppm/ °C.

TCV_O= (V_MAX– V_MIN)/ V_O(T_MAX– T_MIN).

³Guaranteed by characterization.

⁴Line and load regulation specifications include the effect of self-heating.

Specifications subject to change without notice.

REF196–SPECIFICATIONS

(@ V = 3.5 V, T = 25؇C, unless otherwise noted.)

ELECTRICAL CHARACTERISTICS

S

A

Parameter

Symbol

Condition

Min

Typ

3.3

4

Max

3.310

8

Unit

INITIAL ACCURACY¹

G Grade

LINE REGULATION²

G Grades

LOAD REGULATION²

G Grade

V_O

I_OUT= 0 mA

3.290

V

⌬V_O/⌬V_IN

3.50 V ≤ V_S≤ 15 V, I_OUT= 0 mA

V_S= 5.0 V, 0 mA ≤ I_OUT≤ 30 mA

ppm/V

ppm/mA

⌬V_O/⌬V_LOAD

V_S– V_O

6

15

DROPOUT VOLTAGE

V_S= 4.1 V, I_LOAD= 10 mA

V_S= 4.3 V, I_LOAD= 30 mA

0.80

1.00

V

LONG-TERM STABILITY³

DV_O

e_N

1000 Hours @ 125°C

1.2

33

mV

NOISE VOLTAGE

0.1 Hz to 10 Hz

µV p-p

NOTES

¹Initial accuracy includes temperature hysteresis effect.

²Line and load regulation specifications include the effect of self-heating.

³Long-term drift is guaranteed by 1000 hours life test performed on three independent wafer lots at 125°C, with an LTPD of 1.3.

Specifications subject to change without notice.

REV. E

–10–

REF19x Series

REF196–SPECIFICATIONS

(@ V_S= 3.5 V, T_A= –40؇C ≤ T_A≤ +85؇C, unless otherwise noted.)

ELECTRICAL CHARACTERISTICS

Parameter

Symbol

Condition

Min

Typ

Max

25

Unit

TEMPERATURE COEFFICIENT^{1, 2}

G Grade³

TCV_O/°C

⌬V_O/⌬V_IN

I_OUT= 0 mA

10

ppm/°C

ppm/V

ppm/mA

LINE REGULATION⁴

G Grade

LOAD REGULATION⁴

G Grade

3.5 V ≤ V_S≤ 15 V, I_OUT= 0 mA

V_S= 5.0 V, 0 mA ≤ I_OUT≤ 25 mA

10

20

⌬V_O/⌬V_LOAD

V_S– V_O

10

20

DROPOUT VOLTAGE

V_S= 4.1 V, I_LOAD= 10 mA

V_S= 4.3 V, I_LOAD= 25 mA

0.80

1.00

V

SLEEP PIN

Logic High Input Voltage

Logic High Input Current

Logic Low Input Voltage

Logic Low Input Current

V_H

I_H

V_L

I_L

2.4

V

µA

V

–8

0.8

–8

µA

SUPPLY CURRENT

Sleep Mode

No Load

45

15

µA

NOTES

¹For proper operation, a 1 µF capacitor is required between the output pin and the GND pin of the device.

²TCV_Ois defined as the ratio of output change with temperature variation to the specified temperature range expressed in ppm/ °C.

TCV_O= (V_MAX– V_MIN)/ V_O(T_MAX– T_MIN).

³Guaranteed by characterization.

⁴Line and load regulation specifications include the effect of self-heating.

Specifications subject to change without notice.

(@ V_S= 3.50 V, –40؇C ≤ T_A≤ +125؇C, unless otherwise noted.)

ELECTRICAL CHARACTERISTICS

Parameter

Symbol

Condition

Min

Typ

Max

Unit

TEMPERATURE COEFFICIENT^{1, 2}

G Grade³

TCV_O/°C

⌬V_O/⌬V_IN

I_OUT= 0 mA

10

ppm/°C

ppm/V

ppm/mA

LINE REGULATION⁴

G Grade

LOAD REGULATION⁴

G Grade

3.50 V ≤ V_S≤ 15 V, I_OUT= 0 mA

V_S= 5.0 V, 0 mA ≤ I_OUT≤ 20 mA

20

⌬V_O/⌬V_LOAD

V_S– V_O

20

DROPOUT VOLTAGE

V_S= 4.1 V, I_LOAD= 10 mA

V_S= 4.4 V, I_LOAD= 20 mA

0.80

1.10

V

NOTES

¹For proper operation, a 1 µF capacitor is required between the output pin and the GND pin of the device.

²TCV_Ois defined as the ratio of output change with temperature variation to the specified temperature range expressed in ppm/ °C.

TCV_O= (V_MAX– V_MIN)/ V_O(T_MAX– T_MIN).

³Guaranteed by characterization.

⁴Line and load regulation specifications include the effect of self-heating.

Specifications subject to change without notice.

REV. E

–11–

REF19x Series

REF198–SPECIFICATIONS

ELECTRICAL CHARACTERISTICS ^{(@ V}_S^{= 5.0 V, T}_A^{= 25؇C, unless otherwise noted.)}

Parameter

Symbol

Condition

Min

Typ

Max

Unit

INITIAL ACCURACY¹

E Grade

F Grade

V_O

I_OUT= 0 mA

4.094

4.091

4.086

4.096

4.098

4.101

4.106

V

G Grade

LINE REGULATION²

E Grade

F and G Grades

LOAD REGULATION²

E Grade

F and G Grades

⌬V_O/⌬V_IN

4.5 V ≤ V_S≤ 15 V, I_OUT= 0 mA

V_S= 5.4 V, 0 mA ≤ I_OUT≤ 30 mA

2

4

8

ppm/V

⌬V_O/⌬V_LOAD

V_S– V_O

2

4

8

ppm/mA

DROPOUT VOLTAGE

V_S= 4.6 V, I_LOAD= 10 mA

V_S= 5.4 V, I_LOAD= 30 mA

0.50

1.30

V

LONG-TERM STABILITY³

DV_O

e_N

1000 Hours @ 125°C

1.2

40

mV

NOISE VOLTAGE

0.1 Hz to 10 Hz

µV p-p

NOTES

¹Initial accuracy includes temperature hysteresis effect.

²Line and load regulation specifications include the effect of self-heating.

³Long-term drift is guaranteed by 1000 hours life test performed on three independent wafer lots at 125°C, with an LTPD of 1.3.

Specifications subject to change without notice.

(@ V_S= 5.0 V, –40؇C ≤ T_A≤ +85؇C, unless otherwise noted.)

ELECTRICAL CHARACTERISTICS

Parameter

Symbol

Condition

Min

Typ

Max

Unit

TEMPERATURE COEFFICIENT^{1, 2}

E Grade

F Grade

G Grade³

TCV_O/°C

I_OUT= 0 mA

2

5

10

5

10

25

ppm/°C

LINE REGULATION⁴

E Grade

F and G Grades

LOAD REGULATION⁴

E Grade

F and G Grades

⌬V_O/⌬V_IN

4.5 V ≤ V_S≤ 15 V, I_OUT= 0 mA

V_S= 5.4 V, 0 mA ≤ I_OUT≤ 25 mA

5

10

20

ppm/V

⌬V_O/⌬V_LOAD

V_S– V_O

5

10

20

ppm/mA

DROPOUT VOLTAGE

V_S= 4.6 V, I_LOAD= 10 mA

V_S= 5.4 V, I_LOAD= 25 mA

0.50

1.30

V

SLEEP PIN

Logic High Input Voltage

Logic High Input Current

Logic Low Input Voltage

Logic Low Input Current

V_H

I_H

V_L

I_L

2.4

V

µA

V

–8

0.8

–8

µA

SUPPLY CURRENT

Sleep Mode

No Load

45

15

µA

NOTES

¹For proper operation, a 1 µF capacitor is required between the output pin and the GND pin of the device.

²TCV_Ois defined as the ratio of output change with temperature variation to the specified temperature range expressed in ppm/ °C.

TCV_O= (V_MAX– V_MIN)/ V_O(T_MAX– T_MIN).

³Guaranteed by characterization.

⁴Line and load regulation specifications include the effect of self-heating.

Specifications subject to change without notice.

REV. E

–12–

REF19x Series

REF198–SPECIFICATIONS

ELECTRICAL CHARACTERISTICS ^{(@ V}_S^{= 5.0 V, –40؇C ≤ T}_A^{≤ +125؇C, unless otherwise noted.)}

Parameter

Symbol

Condition

Min

Typ

Max

Unit

TEMPERATURE COEFFICIENT^{1, 2}

E Grade

F Grade

G Grade³

TCV_O/°C

I_OUT= 0 mA

2

5

10

ppm/°C

LINE REGULATION⁴

E Grade

F and G Grades

LOAD REGULATION⁴

E Grade

F and G Grades

⌬V_O/⌬V_IN

4.5 V ≤ V_S≤ 15 V, I_OUT= 0 mA

V_S= 5.6 V, 0 mA ≤ I_OUT≤ 20 mA

5

10

ppm/V

⌬V_O/⌬V_LOAD

V_S– V_O

5

10

ppm/mA

DROPOUT VOLTAGE

V_S= 4.7 V, I_LOAD= 10 mA

V_S= 5.6 V, I_LOAD= 20 mA

0.60

1.50

V

NOTES

¹For proper operation, a 1 µF capacitor is required between the output pin and the GND pin of the device.

²TCV_Ois defined as the ratio of output change with temperature variation to the specified temperature range expressed in ppm °C.

TCV_O= (V_MAX– V_MIN)/ V_O(T_MAX– T_MIN).

³Guaranteed by characterization.

⁴Line and load regulation specifications include the effect of self-heating.

Specifications subject to change without notice.

REV. E

–13–

REF19x Series

(@ I_LOAD= 0 mA, T_A= 25؇C, unless otherwise noted.)

WAFER TEST LIMITS

Parameter

Symbol

Condition

Limit

Unit

INITIAL ACCURACY

REF191

REF192

REF193

REF194

REF195

REF196

REF198

V_O

2.043/2.053

2.495/2.505

2.990/3.010

4.495/4.505

4.995/5.005

3.290/3.310

4.091/4.101

V

LINE REGULATION

LOAD REGULATION

DROPOUT VOLTAGE

⌬V_O/⌬V_IN

(V_O+ 0.5 V) < V_IN< 15 V, I_OUT= 0 mA

0 mA < I_LOAD< 30 mA, V_IN= (V_O+ 1.3 V)

15

ppm/V

⌬V_O/⌬I_LOAD

ppm/mA

V

_O– V+

I_LOAD= 10 mA

I_LOAD= 30 mA

1.25

1.55

V

SLEEP MODE INPUT

Logic Input High

Logic Input Low

V_IH

V_IL

2.4

0.8

V

SUPPLY CURRENT

Sleep Mode

V

_IN= 15 V

No Load

45

15

µA

For proper operation, a 1 µF capacitor is required between the output pins and the GND pin of the REF19x. Electrical tests and wafer probe to the limits shown.

Due to variations in assembly methods and normal yield loss, yield after packaging is not guaranteed for standard product dice. Consult factory to negotiate specifications

based on dice lot qualifications through sample lot assembly and testing.

ABSOLUTE MAXIMUM RATINGS¹

DICE CHARACTERISTICS

Supply Voltage . . . . . . . . . . . . . . . . . . . . . . . . . . –0.3 V, +18 V

Output to GND . . . . . . . . . . . . . . . . . . . . . –0.3 V, V_S+ 0.3 V

Output to GND Short-Circuit Duration . . . . . . . . . Indefinite

Storage Temperature Range

OUTPUT

6

OUTPUT

6

P, S Package . . . . . . . . . . . . . . . . . . . . . . . –65°C to +150°C

Operating Temperature Range

REF19x . . . . . . . . . . . . . . . . . . . . . . . . . . . –40°C to +85°C

Junction Temperature Range

P, S Package . . . . . . . . . . . . . . . . . . . . . . . –65°C to +150°C

Lead Temperature Range (Soldering 60 sec) . . . . . . . . . 300°C

2

Package Type

␪

JA

␪

JC

Unit

8-Lead PDIP (P)

8-Lead SOIC (S)

8-Lead TSSOP (RU)

103

158

240

43

°C/W

2

3

4

V؉

GND

SLEEP

NOTES

¹Absolute maximum rating applies to both DICE and packaged parts, unless

otherwise noted.

REF19x Die Size 0.041” ϫ 0.057”, 2,337 Square Mils

Substrate Is Connected to V+, Number of Transistors:

Bipolar 25, MOSFET4. Process: CBCMOS1

²θ_JAis specified for worst case conditions, i.e., θ_JAis specified for device in socket for

PDIP, and θ_JAis specified for device soldered in circuit board for SOIC package.

CAUTION

ESD (electrostatic discharge) sensitive device. Electrostatic charges as high as 4000 V readily

accumulate on the human body and test equipment and can discharge without detection. Although the

REF19x features proprietary ESD protection circuitry, permanent damage may occur on devices

subjected to high energy electrostatic discharges. Therefore, proper ESD precautions are recommended

to avoid performance degradation or loss of functionality.

–14–

REV. E

Typical Performance Characteristics–REF19x Series

50

5.004

5.003

5.002

5.001

5.000

4.999

4.998

4.997

3 TYPICAL PARTS

5.15V < V < 15V

–40؇C

T

+85؇C

45

40

35

30

25

20

15

10

5

BASED ON 600

UNITS, 4 RUNS

A

IN

0

4.996

–20

–15

–10

–5

0

5

10

15

20

–50

–25

0

25

50

75

100

T

– V – ppm/؇C

TEMPERATURE – ؇C

C

OUT

TPC 1. REF195 Output Voltage vs. Temperature

TPC 4. T_C– V_OUTDistribution

32

28

40

35

30

25

20

15

10

5

NORMAL MODE

5.15V

V

15V

S

24

20

16

12

8

–40؇C

+25؇C

+85؇C

SLEEP MODE

4

0

–50

0

5

10

15

– mA

20

25

30

–25

0

25

50

75

100

I

LOAD

TEMPERATURE – ؇C

TPC 2. REF195 Load Regulation vs. I_LOAD

TPC 5. Quiescent Current vs. Temperature

20

16

12

8

–6

0mA Յ I

< 25mA

OUT

+85؇C

–5

–4

–3

–2

–1

0

+25؇C

–40؇C

V

L

4

H

0

4

6

8

10

– V

12

14

16

–50

–25

0

25

50

75

100

V

IN

TEMPERATURE –

؇C

TPC 3. REF195 Line Regulation vs. V_IN

TPC 6. SLEEP Pin Current vs. Temperature

REV. E

–15–

REF19x Series

2

4

6

V

= 15V

IN

REF19x

0

10mA

1␮F

0

–20

–40

–60

–80

TPC 9b. Load Transient Response Measurement Circuit

2V

–100

–120

100

90

10

100

1k

10k

100k

1M

FREQUENCY – Hz

1mA

LOAD

TPC 7a. Ripple Rejection vs. Frequency

30mA

LOAD

10

0%

2V

100␮s

10␮F

TPC 10a. Power ON Response Time

10␮F

1␮F 1k⍀

1k⍀

2

6

OUTPUT

REF19x

V

= +15V

IN

10␮F

4

2

4

6

REF

REF19x

V

= 7V

1␮F

IN

TPC 7b. Ripple Rejection vs. Frequency

Measurement Circuit

TPC 10b. Power ON Response Time Measurement Circuit

V

= 7V

2

IN

200V

Z

6

REF19x

V

= 2V p-p

= 4V

G

4

5V

1␮F

V

100

ON

S

90

OFF

4

3

2

I

= 1mA

L

V

OUT

I

= 10mA

L

10

0%

1

0

2ms

1V

10

100

1k

10k

100k

1M

10M

FREQUENCY – Hz

TPC 11a. SLEEP Response Time

TPC 8. Output Impedance vs. Frequency

V

= 15V

IN

2

3

V

OUT

6

REF19x

4

5V

OFF

1␮F

100

90

ON

TPC 11b. SLEEP Response Time Measurement Circuit

10

0%

20mV

100␮s

TPC 9a. Load Transient Response

–16–

REV. E

REF19x Series

35

30

25

20

15

10

5

5V

100

90

10

0%

0

0.1

0.2

0.3

0.4

0.5

0.6

0.7

0.8

0.9

200mV

200␮s

REF195 DROPOUT VOLTAGE – V

TPC 13. Dropout Voltage vs. Load Current

TPC 12. Line Transient Response

+V

Output Voltage Bypassing

For stable operation, low dropout voltage regulators and refer-

ences generally require a bypass capacitor connected from their

V_OUTpins to their GND pins. Although the REF19x family of

references is capable of stable operation with capacitive loads

exceeding 100 µF, a 1 µF capacitor is sufficient to guarantee rated

performance. The addition of a 0.1 µF ceramic capacitor in parallel

with the bypass capacitor will improve load current transient

performance. For best line voltage transient performance, it is

recommended that the voltage inputs of these devices be bypassed

with a 10 µF electrolytic capacitor in parallel with a 0.1 µF

ceramic capacitor.

V

OUT

SLEEP (SHUTDOWN)

GND

Sleep Mode Operation

All REF19x devices include a sleep capability that is TTL/CMOS

level compatible. Internally, a pull-up current source to V_INis

connected at the SLEEP pin. This permits the SLEEP pin to be

driven from an open collector/drain driver. A logic LOW or a 0 V

condition on the SLEEP pin is required to turn the output stage

OFF. During sleep, the output of the references becomes a high

impedance state where its potential would then be determined

by external circuitry. If the sleep feature is not used, it is recom-

mended that the SLEEP pin be connected to V_IN(Pin 2).

Figure 1. Simplified Schematic

APPLICATIONS SECTION

Output Short Circuit Behavior

The REF19x family of devices is totally protected from damage

due to accidental output shorts to GND or to V+. In the event

of an accidental short circuit condition, the reference device will

shut down and limit its supply current to 40 mA.

Device Power Dissipation Considerations

Basic Voltage Reference Connections

The REF19x family of references is capable of delivering load

currents to 30 mA with an input voltage that ranges from 3.3 V

to 15 V. When these devices are used in applications with large

input voltages, care should be exercised to avoid exceeding

these devices’ maximum internal power dissipation. Exceeding

the published specifications for maximum power dissipation or

junction temperature could result in premature device failure.

The following formula should be used to calculate a device’s

maximum junction temperature or dissipation:

The circuit in Figure 2 illustrates the basic configuration for the

REF19x family of references. Note the 10 µF/0.1 µF bypass net-

work on the input and the 1 µF/0.1 µF bypass network on the

output. It is recommended that no connections be made to Pins 1,

5, 7, and 8. If the sleep feature is not required, Pin 3 should be

connected to V_IN.

NC

1

2

3

4

8

7

6

5

V

IN

T_J– T_A

P_D

=

REF19x

OUTPUT

10␮F

0.1␮F

θ_JA

SLEEP

1␮F

TANT

0.1␮F

In this equation, T_Jand T_Aare the junction and ambient tempera-

tures, respectively, P_Dis the device power dissipation, and θ_JAis

the device package thermal resistance.

NC

NC = NO CONNECT

Figure 2. Basic Voltage Reference Configuration

REV. E

–17–

REF19x Series

Membrane Switch Controlled Power Supply

clamps drive to Q1 at about 300 mA of load current with values

as shown. With this separation of control and power functions,

dc stability is optimum, allowing best advantage use of premium

grade REF19x devices for U1. Of course, load management

should still be exercised. A short, heavy, low DCR (dc resistance)

conductor should be used from U1–6 to the V_OUTsense point

“S,” where the collector of Q1 connects to the load, point “F.”

With output load currents in the tens of mA, the REF19x family

of references can operate as a low dropout power supply in hand-

held instrument applications. In the circuit shown in Figure 3,

a membrane ON/OFF switch is used to control the operation of

the reference. During an initial power-on condition, the SLEEP

pin is held to GND by the 10 kΩ resistor. Recall that this condition

disables (read: three-state) the REF19x output. When the mem-

brane ON switch is pressed, the SLEEP pin is momentarily pulled to

V_IN, enabling the REF19x output. At this point, current through

the 10 kΩ is reduced and the internal current source connected

to the SLEEP pin takes control. Pin 3 assumes and remains at the

same potential as V_IN. When the membrane OFF switch is pressed,

the SLEEP pin is momentarily connected to GND, which once

again disables the REF19x output.

Because of the current limiting configuration, the dropout voltage

circuit is raised about 1.1 V over that of the REF19x devices, due

to the V_BEof Q1 and the drop across current sense resistor R4.

However, overall dropout is typically still low enough to allow

operation of a 5 V to 3.3 V regulator/reference using the REF196

for U1 as noted, with a V_Sas low as 4.5 V and a load current

of 150 mA.

The requirement for a heat sink on Q1 depends on the maximum

input voltage and short circuit current. With V_S= 5 V and a

300 mA current limit, the worst case dissipation of Q1 is 1.5 W,

less than the TO-220 package 2 W limit. However, if smaller

TO-39 or TO-5 packaged devices such as the 2N4033 are used,

the current limit should be reduced to keep maximum dissi-

pation below the package rating. This is accomplished by simply

raising R4.

8

7

6

5

NC

1

2

3

4

V

IN

REF19x

OUTPUT

1k⍀

5%

1␮F

TANT

NC

ON

10k⍀

OFF

A tantalum output capacitor is used at C1 for its low ESR

(Equivalent Series Resistance), and the higher value is required

for stability. Capacitor C2 provides input bypassing and can be

an ordinary electrolytic.

NC = NO CONNECT

Figure 3. Membrane Switch Controlled Power Supply

Current-Boosted References with Current Limiting

Shutdown control of the booster stage is shown as an option,

and when used some cautions are in order. Because of the addi-

tional active devices in the V_Sline to U1, direct drive to Pin 3

does not work as with an unbuffered REF19x device. To enable

shutdown control, the connection to U1-2 is broken at the “X,”

and diode D1 then allows a CMOS control source V_Cto drive

U1-3 for ON-OFF operation. Startup from shutdown is not as

clean under heavy load as it is in basic REF19x series and can

require several milliseconds under load. Nevertheless, it is still

effective and can fully control 150 mA loads. When shutdown

control is used, heavy capacitive loads should be minimized.

While the 30 mA rated output current of the REF19x series is

higher than typical of other reference ICs, it can be boosted to

higher levels if desired with the addition of a simple external

PNP transistor, as shown in Figure 4. Full time current limiting

is used for protection of the pass transistor against shorts.

Q1

R4

2⍀

TIP32A

(SEE TEXT)

OUTPUT TABLE

+V = 6V TO 9V

S

(SEE TEXT)

R1

V

(V)

U1

OUT

1k⍀

Q2

REF192

REF193

REF196

REF194

REF195

2.5

3.0

3.3

4.5

5.0

2N3906

R2

1.5k⍀

A Negative Precision Reference without Precision Resistors

In many current-output CMOS DAC applications where the

output signal voltage must be of the same polarity as the reference

voltage, it is often required to reconfigure a current-switching DAC

into a voltage-switching DAC through the use of a 1.25 V reference,

an op amp, and a pair of resistors. Using a current-switching

DAC directly requires an additional operational amplifier at the

output to reinvert the signal. A negative voltage reference is then

desirable from the point that an additional operational amplifier

is not required for either reinversion (current-switching mode) or

amplification (voltage switching mode) of the DAC output voltage.

In general, any positive voltage reference can be converted into

a negative voltage reference through the use of an operational

amplifier and a pair of matched resistors in an inverting configura-

tion. The disadvantage to that approach is that the largest single

source of error in the circuit is the relative matching of the

resistors used.

C2

100␮F/25V

C3

F

0.1␮F

D1

U1

REF196

+V

3.3V

@ 150mA

S

OUT

V

C

(SEE TABLE)

1N4148

(SEE TEXT

ON SLEEP)

C1

10␮F/25V

(TANTALUM)

R3

1.82k⍀

R1

S

F

V

S

COMMON

V

OUT

COMMON

Figure 4. A Boosted 3.3 V Reference with Current Limiting

In this circuit, the power supply current of reference U1 flowing

through R1–R2 develops a base drive for Q1, whose collector

provides the bulk of the output current. With a typical gain of

100 in Q1 for 100 mA to 200 mA loads, U1 is never required to

furnish more than a few mA, so this factor minimizes temperature

related drift. Short circuit protection is provided by Q2, which

–18–

REV. E

REF19x Series

The circuit illustrated in Figure 5 avoids the need for tightly

matched resistors with the use of an active integrator circuit. In

this circuit, the output of the voltage reference provides the input

drive for the integrator. The integrator, to maintain circuit equi-

librium, adjusts its output to establish the proper relationship

between the reference’s V_OUTand GND. Thus, any desired

negative output voltage can be chosen by simply substituting for

the appropriate reference IC. The sleep feature is maintained in

the circuit with the simple addition of a PNP transistor and a

10 kΩ resistor. One caveat with this approach should be men-

tioned: although rail-to-rail output amplifiers work best in the

application, these operational amplifiers require a finite amount

(mV) of headroom when required to provide any load current.

The choice for the circuit’s negative supply should take this issue

into account.

V_OUT2is the sum of this voltage and the terminal voltage of U2.

U1 and U2 are simply chosen for the two voltages that supply

the required outputs (see Table I). If, for example, both U1 and

U2 are REF192s, the two outputs are 2.5 V and 5.0 V.

While this concept is simple, some cautions are in order. Since

the lower reference circuit must sink a small bias current from

U2 (50 µA to 100 µA), plus the base current from the series PNP

output transistor in U2, either the external load of U1 or R1

must provide a path for this current. If the U1 minimum load is

not well defined, resistor R1 should be used, set to a value that

will conservatively pass 600 µA of current with the applicable

V_OUT1across it. Note that the two U1 and U2 reference circuits

are locally treated as macrocells, each having its own bypasses at

input and output for best stability. Both U1 and U2 in this circuit

can source dc currents up to their full rating. The minimum

input voltage, V_S, is determined by the sum of the outputs, V_OUT2

plus the dropout voltage of U2.

,

V

IN

A related variation on stacking two three-terminal references

is shown in Figure 6, where U1, a REF192, is stacked with a

two-terminal reference diode such as the AD589. Like the three-

terminal stacked reference above, this circuit provides two outputs,

10k⍀

SLEEP

TTL/CMOS

2N3906

2

V

1␮F

+5V

IN

1k⍀

1␮F

6

3

SLEEP V

OUT

V

_OUT1and V_OUT2, which are the individual terminal voltages of

REF19x

D1 and U1 respectively. Here this is 1.235 and 2.5, which pro-

vides a V_OUT2of 3.735 V. When using two-terminal reference

diodes such as D1, the rated minimum and maximum device

currents must be observed and the maximum load current from

GND

4

100⍀

A1

–V

REF

10k⍀

100k⍀

–5V

A1 = 1/2 OP295,

1/2 OP291

V_OUT1can be no greater than the current set up by R1 and V_O(U1)

.

In the case with V_O(U1)equal to 2.5 V, R1 provides a 500 µA

bias to D1, so the maximum load current available at V_OUT1is

450 µA or less.

Figure 5. A Negative Precision Voltage Reference

Uses No Precision Resistors

Stacking Reference ICs for Arbitrary Outputs

+V

S

Some applications may require two reference voltage sources that

are a combined sum of standard outputs. The circuit of Figure 6

shows how this “stacked output” reference can be implemented.

V

S

> V

+0.15V

OUT2

U1

+V

3.735V

OUT2

REF192

C1

0.1␮F

R1

C2

V

(U1)

(D1)

4.99k⍀

O

1␮F

(SEE TEXT)

OUTPUT TABLE

U1/U2

V

(V)

V

(V)

OUT1

OUT2

+V

OUT1

REF192/REF192

REF192/REF194

REF192/REF195

2.5

5.0

7.0

7.5

1.235V

C3

1␮F

D1

AD589

V

O

+V

S

V

S

> V

+0.15V

OUT2

C1

V

OUT

IN

U2

0.1␮F

COMMON

+V

REF19x

OUT2

(SEE TABLE)

C2

V

(U2)

(U1)

O

1␮F

Figure 7. Stacking Voltage References with the REF19x

A Precision Current Source

Many times, in low power applications, the need arises for a

precision current source that can operate on low supply voltages.

As shown in Figure 8, any one of the devices in the REF19x

family of references can be configured as a precision current

source. The circuit configuration illustrated is a floating current

source with a grounded load. The reference’s output voltage is

bootstrapped across R_SET, which sets the output current into the

load. With this configuration, circuit precision is maintained for

load currents in the range from the reference’s supply current

(typically, 30 µA) to approximately 30 mA. The low dropout

voltage of these devices maximizes the current source’s output

voltage compliance without excess headroom.

C3

0.1␮F

U1

+V

OUT1

REF19x

R1

3.9k⍀

(SEE TEXT)

(SEE TABLE)

C4

1␮F

O

V

IN

OUT

COMMON

Figure 6. Stacking Voltage References with the REF19x

Two reference ICs are used, fed from a common unregulated

input, V_S. The outputs of the individual ICs are simply con-

nected in series as shown, which provides two output voltages,

V_OUT1and V_OUT2. V_OUT1is the terminal voltage of U1, while

REV. E

–19–

REF19x Series

V

IN

OUTPUT TABLE

U1/U2

V

*

V

(V)

OUT

C

REF195/

REF196

REF194/

REF195

HI

5.0

LO 3.3

V

IN

HI

LO 5.0

4.5

+V = 6V

S

REF19x

V

SLEEP

REF

*CMOS LOGIC LEVELS

U1

2

3

1

4

GND

R1

P1

V

C

REF19x

1␮F

R

SET

(SEE TABLE)

I

SY

U3A

U3B

ADJUST

74HC04 74HC04

I

+V

OUT

V

I

؋

R (MAX) + V (MIN)

L SY

IN

OUT

V

R

L

OUT

I

=

+ I (REF19x)

SY

OUT

U2

SET

C2

1␮F

REF19x

V

R

E.G. REF195 : V

= 5mA

= 5V

OUT

(SEE TABLE)

>> I

SY

I

OUT

SET

R1 = 953⍀

P1 = 100⍀, 10-TURN

C1

0.1␮F

V

IN

OUT

COMMON

Figure 8. A Low Dropout, Precision Current Source

The circuit’s governing equations are:

Figure 9. Switched Output Reference

V_IN= I_OUT× R_L(max)+V_SY(min, REF19x)

Using dissimilar REF19x series devices with this configuration

allows logic selection between the U1/U2 specified terminal

voltages. For example, with U1 (a REF195) and U2 (a REF196),

as noted in the table, changing the CMOS compatible V_Clogic

control voltage from HI to LO selects between a nominal output

of 5.000 V and 3.300 V and vice versa. Other REF19x family

units can also be used for U1/U2, with similar operation in a

logic sense, but with outputs as per the individual paired devices

(see table, again). Of course, the exact output voltage tolerance,

drift, and overall quality of the reference voltage will be consistent

with the grade of individual U1 and U2 devices.

V_OUT

R_SET

I_OUT

=

+ I_SY(REF19x)

V

R_SET

^OUT〉〉I_SY(REF19x)

Switched Output 5 V/3.3 V Reference

Applications often require digital control of reference voltages,

selecting between one stable voltage and a second. With the

sleep feature inherent to the REF19x series, switched output

reference configurations are easily implemented with relatively

little additional hardware.

Because of the nature of the wire–OR, there is one application

caveat that should be understood about this circuit. Since U1

and U2 can only source current effectively, negative going output

voltage changes, which require the sinking of current, will neces-

sarily take longer than positive going changes. In practice, this

means that the circuit is quite fast when undergoing a transition

from 3.3 V to 5 V, but the transition from 5 V to 3.3 V will take

longer. Exactly how much longer will be a function of the load

resistance, R_L, seen at the output and the typical 1 µF value of

C2. In general, a conservative transition time here will be on the

order of several milliseconds for load resistances in the range of

100 Ω to 1 kΩ. Note that for highest accuracy at the new output

voltage, several time constants should be allowed (>7.6 time

constants for <1/2 LSB error @ 10 bits, for example).

The circuit of Figure 9 illustrates the general technique, which

takes advantage of the output “wire-OR” capability of the REF19x

device family. When OFF, a REF19x device is effectively an

open circuit at the output node with respect to the power supply.

When ON, a REF19x device can source current up to its current

rating, but sink only a few µA (essentially just the relatively low

current of the internal output scaling divider). As a result, for

two devices wired together at their common outputs, the output

voltage is simply that of the ON device. The OFF state device

will draw a small standby current of 15 µA (max), but otherwise

will not interfere with operation of the ON device, which can

operate to its full current rating. Note that the two devices in

the circuit conveniently share both input and output capacitors,

and with CMOS logic drive, it is power efficient.

–20–

REV. E

REF19x Series

Kelvin Connections

A Fail-Safe 5 V Reference

In many portable instrumentation applications where PC board

cost and area go hand-in-hand, circuit interconnects are very

often of dimensionally minimum width. These narrow lines

can cause large voltage drops if the voltage reference is required

to provide load currents to various functions. In fact, a cir-

cuit’s interconnects can exhibit a typical line resistance of

0.45 mΩ/square (1 oz. Cu, for example). In those applications

where these devices are configured as low dropout voltage regu-

lators, these wiring voltage drops can become a large source of

error. To circumvent this problem, force and sense connections

can be made to the reference through the use of an operational

amplifier, as shown in Figure 10. This method provides a means

by which the effects of wiring resistance voltage drops can be

eliminated. Load currents flowing through wiring resistance

produce an I-R error (I_LOADϫ R_WIRE) at the load. However, the

Kelvin connection overcomes the problem by including the

wiring resistance within the forcing loop of the op amp. Since the

op amp senses the load voltage, op amp loop control forces the

output to compensate for the wiring error and to produce the

correct voltage at the load. Depending on the reference device

chosen, operational amplifiers that can be used in this application

are the OP295, the OP291, and the OP183/OP283.

Some critical applications require a reference voltage to be main-

tained constant, even with a loss of primary power. The low standby

power of the REF19x series and the switched output capability

allow a “fail-safe” reference configuration to be implemented

rather easily. This reference maintains a tight output voltage

tolerance for either a primary power source (ac line derived) or

a standby (battery derived) power source, automatically switching

between the two as the power conditions change.

The circuit in Figure 11 illustrates the concept, which borrows

from the switched output idea of Figure 8, again using the REF19x

device family output “wire-OR” capability. In this case, since a

constant 5 V reference voltage is desired for all conditions, two

REF195 devices are used for U1 and U2, with their ON/OFF

switching controlled by the presence or absence of the primary

dc supply source, V_S. V_BATis a 6 V battery backup source that sup-

plies power to the load only when V_Sfails. For normal (V_Spresent)

power conditions, V_BATsees only the 15 µA (max) standby current

drain of U1 in its OFF state.

In operation, it is assumed that for all conditions either U1 or U2

is ON and a 5 V reference output is available. With this voltage

constant, a scaled down version is applied to the comparator IC

U3, providing a fixed 0.5 V input to the (–) input for all power

conditions. The R1–R2 divider provides a signal to the U3 (+)

input proportional to V_S, which switches U3 and U1/U2 dependent

upon the absolute level of V_S. Op amp U3 is configured here as

a comparator with hysteresis, which provides for clean, noise free

output switching. This hysteresis is important to eliminate rapid

switching at the threshold due to V_Sripple. Further, the device

chosen is the AD820, a rail-to-rail output device that provides

HI and LO output states within a few mV of V_Sand ground for

accurate thresholds and compatible drive for U2 for all V_Scondi-

tions. R3 provides positive feedback for circuit hysteresis, changing

the threshold at the (+) input as a function of U3’s output.

V

IN

R

LW

+V

OUT

SENSE

V

IN

2

3

R

LW

1

+V

OUT

REF19x

A1

FORCE

V

SLEEP

OUT

R

L

GND

1␮F

100k⍀

A1 = 1/2 OP295

1/2 OP292

1/2 OP283

Figure 10. A Low Dropout, Kelvin Connected

Voltage Reference

+V

BAT

C2

0.1␮F

+V

S

U1

R1

REF195

5.000V

R3

10M⍀

R6

1.1M⍀

100⍀

Q1

2N3904

C1

0.1␮F

3

2

7

6

U3

C3

1␮F

4

AD820

U2

REF195

R2

100k⍀

R4

900k⍀

C4

0.1␮F

R5

100k⍀

V , V

BAT

V

S

OUT

COMMON

Figure 11. A Fail-Safe 5 V Reference

REV. E

–21–

REF19x Series

100⍀

For V_Slevels lower than the LOWER threshold, U3’s output is

low, thus U2 and Q1 are OFF, while U1 is ON. For V_Slevels

higher than the UPPER threshold, the situation reverses, with

U1 OFF and both U2 and Q1 ON. In the interest of battery

power conservation, all of the comparison switching circuitry

is powered from V_Sand is arranged so that when V_Sfails, the

default output comes from U1.

10␮F

REF195

1␮F

10␮F

57k⍀

1%

0.1␮F

For the R1–R3 values as shown, the LOWER/UPPER V_Sswitching

thresholds are approximately 5.5 V and 6 V, respectively. These

can obviously be changed to suit other V_Ssupplies, as can the

REF19x devices used for U1 and U2, over a range of 2.5 V to

5 V of output. U3 can operate down to a V_Sof 3.3 V, which is

generally compatible with all family devices.

1/4

OP492

10k⍀

1%

2N2222

0.1␮F

500⍀

0.1%

A Low Power, Strain Gage Circuit

As shown in Figure 12, the REF19x family of references can be

used in conjunction with low supply voltage operational amplifi-

ers, such as the OP492 and the OP283, in a self-contained strain

gage circuit. In this circuit, the REF195 was used as the core of

this low power, strain gage circuit. Other references can be easily

accommodated by changing circuit element values. The references

play a dual role as the voltage regulator to provide the supply

voltage requirements of the strain gage and the operational

amplifiers as well as a precision voltage reference for the current

source used to stimulate the bridge. A distinct feature of the

circuit is that it can be remotely controlled ON or OFF by digital

means via the SLEEP pin.

0.01␮F

10k⍀

1%

20k⍀

1%

20k⍀

1%

1/4

OP492

1/4

OUTPUT

OP492

10k⍀

1%

2.21k⍀

20k⍀

1%

1/4

OP492

20k⍀

1%

Figure 12. A Low Power, Strain Gage Circuit

–22–

REV. E

REF19x Series

OUTLINE DIMENSIONS

8-Lead Plastic DIP (P Suffix)

(N-8)

Dimensions shown in inches and (millimeters)

0.430 (10.92)

0.348 (8.84)

8

5

0.280 (7.11)

0.240 (6.10)

1

4

0.325 (8.25)

0.300 (7.62)

0.060 (1.52)

0.015 (0.38)

PIN 1

0.195 (4.95)

0.115 (2.93)

0.210 (5.33)

MAX

0.130

(3.30)

MIN

SEATING

PLANE

0.160 (4.06)

0.115 (2.93)

0.015 (0.381)

0.008 (0.204)

0.022 (0.558) 0.100 0.070 (1.77)

(2.54)

0.014 (0.356)

0.045 (1.15)

BSC

CONTROLLING DIMENSIONS ARE IN MILLIMETERS; INCH DIMENSIONS

ARE ROUNDED-OFF MILLIMETER EQUIVALENTS FOR REFERENCE

ONLY AND ARE NOT APPROPRIATE FOR USE IN DESIGN

8-Lead Narrow Body SOIC (S Suffix)

(SOIC-8)

Dimensions shown in inches and (millimeters)

0.1968 (5.00)

0.1890 (4.80)

8

1

5

4

0.1574 (4.00)

0.1497 (3.80)

0.2440 (6.20)

0.2284 (5.80)

PIN 1

0.0688 (1.75)

0.0532 (1.35)

0.0196 (0.50)

0.0099 (0.25)

x 45

0.0098 (0.25)

0.0040 (0.10)

8

0

0.0500

(1.27)

BSC

0.0192 (0.49)

0.0138 (0.35)

SEATING

PLANE

0.0098 (0.25)

0.0075 (0.19)

0.0500 (1.27)

0.0160 (0.41)

CONTROLLING DIMENSIONS ARE IN MILLIMETERS; INCH DIMENSIONS

ARE ROUNDED-OFF MILLIMETER EQUIVALENTS FOR REFERENCE

ONLY AND ARE NOT APPROPRIATE FOR USE IN DESIGN

8-Lead TSSOP (RU Suffix)

(RU-8)

Dimensions shown in inches and (millimeters)

0.122 (3.10)

0.114 (2.90)

8

5

1

4

PIN 1

0.0256 (0.65)

BSC

0.006 (0.15)

0.002 (0.05)

0.0433

(1.10)

MAX

0.028 (0.70)

0.020 (0.50)

8

0

0.0118 (0.30)

0.0075 (0.19)

SEATING

PLANE

0.0079 (0.20)

0.0035 (0.090)

CONTROLLING DIMENSIONS ARE IN MILLIMETERS; INCH DIMENSIONS

ARE ROUNDED-OFF MILLIMETER EQUIVALENTS FOR REFERENCE

ONLY AND ARE NOT APPROPRIATE FOR USE IN DESIGN

REV. E

–23–

REF19x Series

Revision History

Location

Page

1/03—Data Sheet changed from REV. D to REV. E.

Changes to TPCs 2 and 3 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 15

Changes to Output Short Circuit Behavior . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 17

Changes to Figure 1 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 17

Changes to Figure 5 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 19

Updated OUTLINE DIMENSIONS . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 23

–24–

REV. E


型号：	REF197GBC
厂家：	ETC
描述：	REF19x Series: Precision Micropower. Low Dropout. Low Voltage References Data Sheet (Rev. E. 1/03) REF19x系列：精密微功耗。低压差。低电压参考的数据表（版本E. 1/03 ）\n
文件：	总24页 (文件大小：611K)
中文：	中文翻译
下载：	下载PDF数据表文档文件

REF197GBC [ETC]

相关型号：

SI9130DB

SI9135LG-T1

SI9135LG-T1-E3

SI9135_11

SI9136_11

SI9130CG-T1-E3

SI9130LG-T1-E3

SI9130_11

SI9137

SI9137DB

SI9137LG

SI9122E