RICOH RE5RL26AA-RR, RE5RL26AA-TZ, RE5RL26AC, RE5RL27AA-RF, RE5RL27AA-RR Datasheet

VOLTAGE REGULATOR

R×5RL SERIES

APPLICATION MANUAL

NO.EA-022-0006

VOLTAGE REGULATOR

R×5RL SERIES

1

OUTLINE

The R×5RL Series are voltage regulator ICs with high accuracy output voltage and ultra-low quiescent cur-

rent by CMOS process. Each of these ICs consists of a voltage reference unit, an error amplifier, a driver tran-

sistor, and resistors for setting output voltage. The output voltage is fixed with high accuracy.

Three types of packages, TO-92, SOT-89 (Mini-power Mold), SOT-23-5 (Mini-mold), are available.

• Ultra-low Quiescent Current

...........................

TYP. 1.1µA (R

×5RL30A, VIN=5.0V)

• Small Dropout Voltage

.....................................

TYP. 30mV (R

×5RL50A, IOUT=1mA)

• Low Temperature-Drift Coefficient of Output Voltage

...............

TYP. ±100 ppm/˚C

• Excellent Line Regulation

.................................

TYP. 0.1%/V

• Output Voltage

..................................................

Stepwise setting with a step of 0.1V in the range of 2.0V to 6.0V

is possible (refer to Selection Guide).

• High Accuracy Output Voltage

.........................

±2.5%

• Three Types of Packages

...................................

TO-92, SOT-89 (Mini-power Mold), SOT-23-5 (Mini-mold)

FEATURES

APPLICATIONS

• Power source for battery-powered equipment.

• Power source for cameras, video instruments such as camcorders, VCRs, and hand- held communication equipment.

• Precision voltage references.

BLOCK DIAGRAM

2

1

3

Vref

V

OUT

GND

V

IN

–

+

1

R×5RL

2

SELECTION GUIDE

The package type, the output voltage, the packing type, and the taping type of R×5RL Series can be

designated at the user's request by specifying the part number as follows:

For example, the product with Package Type SOT-89, Output Voltage 5.0V, Version A,and Taping Type T1 are

designated by Part Number RH5RL50AA-T1.

Code Contents

Designation of Package Type:

a

E: TO-92
H: SOT-89 (Mini-power Mold)
N: SOT-23-5 (Mini-mold)

b

Setting Output Voltage (V

OUT):

Stepwise setting with a step of 0.1V in the range of 2.0V to 6.0V is possible.

cA

Designation of Packing Type:

d A: Taping

C: Antistatic bag for TO-92 and samples

Designation of Taping Type:

Ex. TO-92 : RF, RR, TZ

e

SOT-89 : T1, T2
SOT-23-5 : TR, TL

(refer to Taping Specifications)

“TZ”, “T1”, and “TR” are prescribed as standard directions.

R×5RL×××× – ×× ← Part Number

↑↑↑↑↑

abcde

}

}

R×5RL

3

•

TO-92

PIN CONFIGURATION

•

SOT-89

•

SOT-23-5

PIN DESCRIPTION

• TO-92 • SOT-89 • SOT-23-5

Pin No. Symbol

1 GND

2VIN

3VOUT

4NC

5NC

Pin No. Symbol

1 GND

2VIN

3VOUT

Pin No. Symbol

1 GND

2VIN

3VOUT

12

3

(mark side)

12

3

(mark side)

12

3

(mark side)

5

4

R×5RL

4

ABSOLUTE MAXIMUM RATINGS

Symbol Item

VIN Input Voltage

VOUT Output Voltage

IOUT Output Current

PD1 Power Dissipation 1 (NOTE1)

PD2 Power Dissipation 2 (NOTE2)

Topt Operating Temperature

Tstg Storage Temperature

Tsolder Lead Temperature (Soldering)

Rating Unit

+12 V

–0.3 to VIN +0.3 V

150 mA

300 mW

150 mW

– 40 to +85 ˚C

– 55 to +125 ˚C

260˚C,10s

Topt=25˚C

Absolute Maximum ratings are threshold limit values that must not be exceeded even for an instant under any

conditions. Moreover, such values for any two items must not be reached simultaneously. Operation above

these absolute maximum ratings may cause degradation or permanent damage to the device. These are stress

ratings only and do not necessarily imply functional operation below these limits.

ABSOLUTE MAXIMUM RATINGS

(NOTE 1) applied to SOT-89 and TO-92
(NOTE 2) applied to SOT-23-5

R×5RL

5

ELECTRICAL CHARACTERISTICS

• R×5RL20A

Symbol Item

VOUT Output Voltage

IOUT Output Current

∆V

OUT

Load Regulation

∆IOUT

VDIF Dropout Voltage

ISS Quiescent Current

∆V

OUT

∆VIN

Line Regulation

VIN Input Voltage

∆V

OUT Output Voltage

∆Topt Temperature Coefficient

Conditions MIN. TYP. MAX. Unit

VIN=4.0V

1.950 2.000 2.050 V

10

µA

≤IOUT≤10mA

VIN=4.0V 25 35 mA

V

IN=4.0V

1mA≤IOUT≤35mA

30 45 mV

IOUT=1mA 60 90 mV

VIN=4.0V 1.0 3.0

µ

A

I

OUT=1mA

VOUT+0.5V≤VIN≤10V

0.05 0.2 %/V

10 V

I

OUT=10mA

±100 ppm/˚C

–40˚C≤Topt≤85˚C

Topt=25˚C

• R×5RL30A

Topt=25˚C

Symbol Item

VOUT Output Voltage

IOUT Output Current

∆V

OUT

Load Regulation

∆

I

OUT

VDIF Dropout Voltage

ISS Quiescent Current

∆V

OUT

∆

V

IN

Line Regulation

VIN Input Voltage

∆V

OUT Output Voltage

∆

Topt Temperature Coefficient

Conditions MIN. TYP. MAX. Unit

VIN=5.0V

2.925 3.000 3.075 V

10µA≤IOUT≤10mA

VIN=5.0V 35 50 mA

V

IN=5.0V

1mA≤IOUT≤50mA

40 60 mV

IOUT=1mA 40 60 mV

VIN=5.0V 1.1 3.3 µA

I

OUT=1mA

VOUT

+

0.5V≤V

IN≤10V

0.05 0.2 %/V

10 V

I

OUT=10mA

±100 ppm/˚C

–40˚C≤Topt≤85˚C

R×5RL

6

• R

×5RL50A

Topt=25˚C

• R×5RL40A

Topt=25˚C

Symbol Item

VOUT Output Voltage

IOUT Output Current

∆V

OUT

Load Regulation

∆IOUT

VDIF Dropout Voltage

ISS Quiescent Current

∆V

OUT

∆VIN

Line Regulation

VIN Input Voltage

∆V

OUT Output Voltage

∆Topt Temperature Coefficient

Conditions MIN. TYP. MAX. Unit

VIN=6.0V

3.900 4.000 4.100 V

10µA≤IOUT≤10mA

VIN=6.0V 45 65 mA

V

IN=6.0V

1mA≤IOUT≤65mA

50 75 mV

IOUT=1mA 25 38 mV

VIN=6.0V 1.2 3.6 µA

I

OUT=1mA

VOUT

+

0.5V≤V

IN≤10V

0.05 0.2 %/V

10 V

I

OUT=10mA

±100 ppm/˚C

–40˚C≤Topt≤85˚C

Symbol Item

VOUT Output Voltage

IOUT Output Current

∆V

OUT

Load Regulation

∆IOUT

VDIF Dropout Voltage

ISS Quiescent Current

∆V

OUT

∆VIN

Line Regulation

VIN Input Voltage

∆V

OUT Output Voltage

∆Topt Temperature Coefficient

Conditions MIN. TYP. MAX. Unit

VIN=7.0V

4.875 5.000 5.125 V

10µA≤IOUT≤10mA

VIN=7.0V 55 80 mA

V

IN=7.0V

1mA≤IOUT≤80mA

60 90 mV

IOUT=1mA 25 38 mV

VIN=7.0V 1.3 3.9 µA

I

OUT=1mA

VOUT

+

0.5V≤V

IN≤

10

V

0.05 0.2 %/V

10 V

I

OUT=10mA

±100 ppm/˚C

–40˚C≤Topt≤85˚C

R×5RL

7

• R

×5RL60A

Topt=25˚C

Symbol Item

VOUT Output Voltage

IOUT Output Current

∆V

OUT

Load Regulation

∆IOUT

VDIF Dropout Voltage

ISS Quiescent Current

∆V

OUT

∆VIN

Line Regulation

VIN Input Voltage

∆V

OUT Output Voltage

∆Topt Temperature Coefficient

Conditions MIN. TYP. MAX. Unit

VIN=8.0V

5.850 6.000 6.150 V

10µA≤IOUT

≤

10mA

VIN=8.0V 55 80 mA

V

IN=8.0V

1mA≤IOUT≤80mA

60 90 mV

IOUT=1mA 25 38 mV

VIN=8.0V 1.3 3.9 µA

I

OUT=1mA

VOUT

+

0.5V≤V

IN≤10V

0.05 0.2 %/V

10 V

I

OUT=10mA

±100 ppm/˚C

–40˚C≤T

OPt≤85˚C

R×5RL

8

ELECTRICAL CHARACTEISTICS BY OUTPUT VOLTAGE

VIN–

V

OUT

=2.0V

25 35 30 45

1mA≤

I

OUT

≤35mA

VIN–

V

OUT

=2.0V

35 50 40 60

1mA≤

I

OUT

≤50mA

VIN–

VOUT

=2.0V

45 65 50 70

1mA≤

I

OUT

≤65mA

VIN–

VOUT

=2.0V

55 80 60 90

1mA≤

I

OUT

≤80mA

R×5RL20A 1.950 2.000 2.050
R×5RL21A 2.048 2.100 2.152
R×5RL22A 2.145 2.200 2.255
R×5RL23A 2.243 2.300 2.357
R×5RL24A 2.340 2.400 2.460
R×5RL25A 2.438 2.500 2.562
R×5RL26A 2.535 2.600 2.665
R×5RL27A 2.633 2.700 2.767
R×5RL28A 2.730 2.800 2.870
R×5RL29A 2.828 2.900 2.972
R×5RL30A 2.925 3.000 3.075
R×5RL31A 3.023 3.100 3.177
R×5RL32A 3.120 3.200 3.280
R×5RL33A 3.218 3.300 3.382
R×5RL34A 3.315 3.400 3.485
R×5RL35A 3.413 3.500 3.587
R×5RL36A 3.510 3.600 3.690
R×5RL37A 3.608 3.700 3.792
R×5RL38A 3.705 3.800 3.895
R×5RL39A 3.803 3.900 3.997
R×5RL40A 3.900 4.000 4.100
R×5RL41A 3.998 4.100 4.202
R×5RL42A 4.095 4.200 4.305
R×5RL43A 4.193 4.300 4.407
R×5RL44A 4.290 4.400 4.510
R×5RL45A 4.388 4.500 4.612
R×5RL46A 4.485 4.600 4.715
R×5RL47A 4.583 4.700 4.817
R×5RL48A 4.680 4.800 4.920
R×5RL49A 4.778 4.900 5.022
R×5RL50A 4.875 5.000 5.125
R×5RL51A 4.973 5.100 5.227
R×5RL52A 5.070 5.200 5.330
R×5RL53A 5.168 5.300 5.432
R×5RL54A 5.265 5.400 5.535
R×5RL55A 5.363 5.500 5.637
R×5RL56A 5.460 5.600 5.740
R×5RL57A 5.558 5.700 5.842
R×5RL58A 5.655 5.800 5.945
R×5RL59A 5.753 5.900 6.047
R

×

5RL60A 5.850 6.000 6.150

Output Voltage OutputCurrent Load Regulation

Part Number

V

OUT(V) IOUT(mA) ∆VOUT(mV)

Conditions

MIN. TYP. MAX.

Conditions

MIN. TYP.

Conditions

TYP. MAX.

VIN–

VOUT

=2.0V

10µA≤

I

OUT

≤10mA

VIN–

V

OUT

=2.0V

60 90

50 75

40 60

35 53

30 45

I

OUT

=1mA

25 38

Dropout Voltage

V

DIF (mV)

Conditions

TYP. MAX.

R×5RL

9

1.0 3.0

1.1 3.3

I

OUT

=1mA IOUT

VIN =10mA

V

OUT 0.05 0.2 10 ±100

=2.0V

V

OUT+

–40˚C≤

0.5V≤ Topt

V

IN≤ 85˚C

1.2 3.6 ≤10V

1.3 3.9

Quiescent Current Line Regulation

Input VoltageOutput Voltage Tempco.

Iss(µA) ∆VOUT/∆VIN(%/V) VIN(V)

∆VOUT/∆T(ppm/˚C)

Conditions

TYP. MAX.

Conditions

TYP. MAX. MAX.

Conditions

TYP.

Topt=25˚C

R×5RL

10

OPERATION

Output Voltage VOUT divided at the node between

Registers R1 and R2 is compared with Reference Voltage

by Error Amplifier, so that a constant voltage is output.

TEST CIRCUITS

FIG. 2 Test Circuit

FIG. 3 Quiescent Current Test Circuit

FIG. 4 Line Transient Response Test Circuit

FIG. 1 Brock Diagram

GNDGND

V

IN

+

–

Error Amplifire

V

OUT

R2

R1

Vref

CI

1µF

Co
1µF

V

IN

GND

R×5RL

SERIES

VOUT

IOUT

VOUT

VIN

+ +

Ro

Co

0.1µF

P.G

GND

R×5RL
SERIES

VOUT

VOUT

VIN

+

ISS

CI

1µF

V

IN

GND

R×5RL
SERIES

VOUT

VIN

+

R×5RL

11

R

×5RL30A

TYPICAL CHARACTERISTICS

1) Output Voltage vs. Output Current
R

×5RL30A

R

×5RL40A

R

×5RL50A

2) Output Voltage vs. Input Voltage
R

×5RL30A

Output Voltage VOUT(V)

Output Current IOUT(mA)

2.7

2.8

2.9

3.1

3.0

V

IN=5.0V

0 20 40 60 80 100 120 140

Topt=−40˚C

85˚C

25˚C

Output Current IOUT(mA)

Output Voltage VOUT(V)

050

4.7

4.8

4.9

5.0

5.1

V

IN=7.0V

100 150 200

85˚C

25˚C

Topt=−40˚C

2.5 3.0 3.5

2.2

2.4

2.6

2.8

3.0

3.2

IOUT=1mA

Output Voltage VOUT(V)

Topt=25˚C

Input Voltage V

IN(V)

5mA

10mA

Output Current IOUT(mA)

Output Voltage VOUT(V)

0

3.7

3.8

3.9

4.1

4.0

VIN=6.0V

20 40 60 80

100 120 140 160 180

Topt=−40˚C

85˚C

25˚C

34 5678910

2.95

2.96

2.97

2.98

2.99

3.00

3.01

3.02

3.03

3.04

3.05

Input Voltage V

IN(V)

Output Voltage VOUT(V)

IOUT=1mA

Topt=25˚C

R×5RL

12

R

×5RL40A

R

×5RL50A R×5RL50A

R

×5RL30A

3) Dropout Voltage vs. Output Curret

R

×5RL40A

R

×5RL40A

3.5 4.0 4.5

3.2

3.4

3.6

3.8

4.0

4.2

IOUT=1mA

Output Voltage VOUT(V)

Topt=25˚C

5mA

10mA

Input Voltage VIN(V)

4.5 5.0 5.5

4.2

4.4

4.6

4.8

5.0

5.2

IOUT=1mA

Output Voltage VOUT(V)

Topt=25˚C

Input Voltage V

IN(V)

5mA

10mA

Output Current IOUT(mA)

Dropout Voltage VDIF(V)

0 1020304050

0.0

0.4

0.6

0.2

0.8

1.0

1.2

1.4

1.6

1.8

2.0

25˚C

85˚C

Topt=−40˚C

Input Voltage VIN(V)

45678910

3.95

3.96

3.97

3.98

3.99

4.00

4.01

4.02

4.03

4.04

4.05

Output Voltage VOUT(V)

IOUT=1mA

Topt=25˚C

5

6

78

9

10

4.95

4.96

4.97

4.98

4.99

5.00

5.01

5.02

5.03

5.04

5.05

Input Voltage V

IN(V)

Output Voltage VOUT(V)

IOUT=1mA

Topt=25˚C

Output Current IOUT(mA)

Dropout Voltage VDIF(V)

01020304050

0.0

0.4

0.6

0.2

0.8

1.0

1.2

1.4

1.6

1.8

2.0

85˚C

Topt=−40˚C

25˚C

13

R×5RL

R×5RL50A

R

×5RL30A

R

×5RL40A

R

×5RL50A

4) Output Voltage vs.Temperature

Output Current IOUT(mA)

Dropout Voltage VDIF(V)

0 10 20 30 40 50

0.0

0.4

0.6

0.2

0.8

1.0

1.2

1.4

1.6

1.8

2.0

Topt=−40℃

25℃

85℃

IOUT=10mA

V

IN=5.0V

–40 –20

Temperature Topt(˚C)

0 20 40 60 80 100

2.90

2.92

2.94

2.96

2.98

3.00

3.02

3.04

3.06

3.08

3.10

Output Voltage VOUT(V)

IOUT=10mA

V

IN=7.0V

–40 –20

Temperature Topt(˚C)

0 20 40 60 80 100

4.90

4.92

4.94

4.96

4.98

5.00

5.02

5.04

5.06

5.08

5.10

Output Voltage VOUT(V)

IOUT=10mA

V

IN=6.0V

–40 –20

Temperature Topt(˚C)

0 20 40 60 80 100

3.90

3.92

3.94

3.96

3.98

4.00

4.02

4.04

4.06

4.08

4.10

Output Voltage VOUT(V)

R×5RL

14

R

×5RL30C

5) Quiescent Current vs. Input Voltage

R

×5RL50A

R

×5RL40A

R

×5RL30A

R

×5RL40A

6) Quiescent Current vs. Temperature

345678910

0.5

0.6

0.7

0.8

0.9

1.0

1.1

1.2

1.3

1.4

1.5

Quiescent Current Iss(µA)

Topt=25˚C

Input Voltage V

IN(V)

45678 910

1.0

1.1

1.2

1.3

1.4

1.5

1.6

1.7

1.8

1.9

2.0

Quiescent Current Iss(µA)

Topt=25˚C

Input Voltage V

IN(V)

–40 –20

0.5

0.6

0.7

0.8

0.9

1.0

1.1

1.2

1.3

1.4

1.5

Quiescent Current Iss(µA)

Temperature Topt(˚C)

V

IN=5.0V

0 20 40 60 80 100

5678910

0.5

0.6

0.7

0.8

0.9

1.0

1.1

1.2

1.3

1.4

1.5

Quiescent Current Iss(µA)

Topt=25˚C

Input Voltage V

IN(V)

–40 –20

1.0

1.1

1.2

1.3

1.4

1.5

1.6

1.7

1.8

1.9

2.0

Quiescent Current Iss(µA)

Temperature Topt(˚C)

V

IN=6.0V

0 20 40 60 80 100

15

R×5RL

R×5RL50A

7) Dropout Voltage vs. Set Output Voltage

9) Line Transient Response (2)

8) Line Transient Response (1)

–40 –20

1.5

1.6

1.7

1.8

1.9

2.0

2.1

2.2

2.3

2.4

2.5

Quiescent Current Iss(µA)

Temperature Topt(˚C)

V

IN=7.0V

020

40 60

80

100

012345

6

0.0

0.2

0.1

0.3

0.4

0.5

0.6

0.7

Set Output Voltage Vreg(V)

Dropout Voltage VDIF(V)

5mA

1mA

IOUT=10mA

01234

4.0

5.0

4.5

5.5

6.0

6.5

7.0

7.5

8.0

Input Voltage/Output Voltage(V)

IOUT=1mA

Time t(ms)

Output Voltage

Input Voltage

01234

4.0

5.0

4.5

5.5

6.0

6.5

7.0

7.5

8.0

Input Voltage/Output Voltage(V)

IOUT=10mA

Time t(ms)

Input Voltage

Output Voltage

R×5RL

16

TYPICAL APPLICATION

In R×5RL Series, a constant voltage can be obtained

without using Capacitors C1 and C2. However, when the

wire connected to Vin is long, use Capacitor C1. Output

noise can be reduced by using Capacitor C2.

Insert Capacitors C1 and C2 with the capacitance of

0.1µF to 2.0µF between Input/Output Pins and GND Pin

with minimum wiring.

As shown in the circuit diagram, a dual power sup-

ply circuit can be constructed by using two R

×5RL

Series.

This circuit diagram shows a dual power supply

circuit with an output of 3V and an output of 5V.

When the minimum output current of IC2 is larger

than I

SS of IC1, Resistor R is unnecessary. Diode D is

a protection diode for the case where V

OUT2 becomes

larger than V

OUT1.

• VOLTAGE BOOST CIRCUIT

• DUAL POWER SUPPLY CIRCUIT

C2

C1

V

IN

GND

GND

GND

R

×5RL

SERIES

VOUT

VOUT

VIN

+

+

C2

C1

V

IN

GND

R

×5RL

SERIES

VOUT

VOUT

VIN

R1

R2

ISS

+

+

C1

C2

V

IN

GND

GND

GND

R

×5RL20A

R×5RL30A

VOUT

VOUT1

5V

V

OUT2

3V

V

IN

C3

GND

VOUT

VIN

R

I

SS

IC1

IC2

D

+

+

+

The output voltage can be obtained by the follow-

ing formula :

V

OUT=Vreg · (1+R2/R1) + ISS R · 2

Since the quiescent current of R

×5RE Series is so

small that the resistances of R1 and R2 can be set as

large as several hundreds kΩ and therefore the sup-

ply current of “Voltage Boost Circuit” itself can be

reduced.

Furthermore, since R

×5RL Series are operated by

a constant voltage, the supply current of “Voltage

Boost Circuit” is not substantially affected by the

input voltage.

*

1) Vreg : Set Output Voltage of R×5RL Series.

*

1

APPLICATION CIRCUITS

R×5RL

17

• CURRENT BOOST CIRCUIT

Output current of 60mA or more can be obtained by

the current boost circuit constructed as shown in this cir-

cuit diagram.

• CURRENT BOOST CIRCUIT WITH OVERCURRENT LIMIT CIRCUIT

A circuit for protecting Tr.1 from the destruction

caused by output short-circuit or overcurrent is shown in

this circuit diagram.

When the voltage reduction caused by the current ( aa

I

OUT) which flows through R2 reaches Vbe2 of Tr.2 by

additionally providing the current boost circuit with Tr.2

and R2, Tr.2 is turned ON and the base current of Tr.1 is

increased, so that the output current is limited.

Current limit of Overcurrent Limit Circuit is obtained

as follows :

I

OUT Vbe2/R2

• CURRENT SOURCE

A current source with the structure as shown in this

circuit diagram can be used. Output Current I

OUT is

obtained as follows :

I

OUT= Vreg /R + ISS

Take care that Output Current IOUT does not exceed

its allowable current.

C2

GND

GND

GND

R

×5RL

SERIES

VOUT

VOUT

C1

VIN

VIN

Tr.1

+

+

C2

GND

GND

GND

R×5RL

SERIES

VOUT

VOUT

C1

VIN

VIN

Tr.1

Tr.2

R1

R2

I

OUT

Vbe2

+

+

GND

R

×5RL

SERIES

C1

VIN

VIN

R

I

OUT

ISS

VOUT

+

*

1) Vreg : Set Output Voltage of R×5RL Series.

*

1