RICOH RN5RK212A-TL, RN5RK212A-TR, RN5RK221A-TL, RN5RK221A-TR, RN5RK221B-TL Datasheet

62705608#9)0#67(3083#'&2'&

&219(57(5

5185.

$33/,&$7,21#0$18$/

××

4$2

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NO. EA-045-0006

SOT-23-5 VFM STEP-UP DC/DC CONVERTER

5185.××

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OUTLINE

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UHQW#DQG#KLJK#RXWSXW#YROWDJH#DFFXUDF\#E\#&026#SURFHVV1

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UHVLVWDQFH#+/[#VZLWFK,/#D#UHIHUHQFH#YROWDJH#XQLW/#D#KLJK#VSHHG#FRPSDUDWRU/#UHVLVWRUV#IRU#YROWDJH#GHWHFWLRQ/#DQ#/[#VZLWFK

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7KH#5185.××5$#XVHV#WKH#VDPH#FKLS#DV#ZKDW#LV#HPSOR\HG#LQ#WKH#5185.××4$24%#,&#DQG#KDV#D#GULYH#SLQ#+(;7,#IRU

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FEATURES

6PDOO#1XPEHU#RI#([WHUQDO#&RPSRQHQWV 111111111111111111111111111 2QO\#DQ#LQGXFWRU/#D#GLRGH#DQG#D#FDSDFLWRU

•

+5185.××4$2××4%,

8OWUD#/RZ#,QSXW#&XUUHQW#RQ#6WDQGE\ 11111111111111111111111111111111 7<31#3—$

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+LJK#2XWSXW#9R O W D J H #$FFXUDF\ 111111111111111111111111111111111111111111 “518(

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/RZ#5LSSOH#DQG#/RZ#1RLVH

•

/RZ#6WDUW0XS#9RO W D J H 1111111111111111111111111111111111111111111111111111111111 0$;1#31<9

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+LJK#(IILFLHQF\ 1111111111111111111111111111111111111111111111111111111111111111111 7<31#;3(

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,QFOXGLQJ#D#'ULYHU#7UDQVLVWRU#ZLWK#/RZ#21#5HVLVWDQFH

•

7Z R #.LQGV#RI#'XW\#5DWLR1111111111111111111111111111111111111111111111111111 ::(#+

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2XWSXW#9R O W D J H 11111111111111111111111111111111111111111111111111111111111111111111 6WHSZLVH#VHWWLQJ#ZLWK#D#VWHS#RI#3149#LQ#WKH#UDQJH#RI#5139#WR

•

8189#LV#SRVVLEOH#+UHIHU#WR#6HOHFWLRQ#*XLGH,

/RZ#7HPSHUDWXUH0'ULIW#&RHIILFLHQW#RI#2XWSXW#9R O W D J H 11111 7<31#“433SSP2ƒ&

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6PDOO#3DFNDJHV 1111111111111111111111111111111111111111111111111111111111111111111 62705608#+0LQL00ROG,

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APPLICATIONS

3RZHU#VRXUFH#IRU#EDWWHU\0SRZHUHG#HTXLSPHQW1

•

3RZHU#VRXUFH#IRU#FDPHUDV/#FDPFRUGHUV/#9&5V/##DQG#KDQG0KHOG#FRPPXQLFDWLRQ#HTXLSPHQW1

•

3RZHU#VRXUFH#IRU#WKRVH#DSSOLDQFHV#ZKLFK#UHTXLUH#KLJKHU#FHOO#YROWDJH#WKDQ#WKDW#RI#EDWWHULHV1

•

1

RN5RK××1A/××1B/××2A

BLOCK DIAGRAM

*) LX pin: only for RN5RK

Lx*

EXT*

4$2××4%

××

Vref

5

5

VLX Limiter

Buffer

VFM Control

OSC 100kHz

Chip Enable

1

-

+

CE

2

4

OUT

V

GND

SELECTION GUIDE

7KH#RXWSXW#YROWDJH/#WKH#GULYHU#W\SH/#WKH#GXW\#F\FOH#DQG#WKH#WDSLQJ#W\SH#IRU#WKH#,&V#FDQ#EH#VHOHFWHG#DW#WKH#XVHU*V#UH0

TXHVW1

7KH#VHOHFWLRQ#FDQ#EH#PDGH#E\#GHVLJQDWLQJ#WKH#SDUW#QXPEHU#DV#VKRZQ#EHORZ=

5185.#

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↑↑↑ ↑

DEF G

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Code Contents

287

D

6WHSZLVH#VHWWLQJ#ZLWK#D#VWHS#RI#3149#LQ#WKH#UDQJH#RI#5139#WR#8189#LV#SRVVLEOH1

6HWWLQJ#2XWSXW#9R O W D J H #+9

,#=

'HVLJQDWLRQ#RI#'ULYHU

E

4=#,QWHUQDO#/[#7U1#'ULYHU

5=#([WHUQDO#7U1#'ULYHU

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F

$=#::(

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'HVLJQDWLRQ#RI#7DSLQJ#W\SH

G

([1#75/#7/#+UHIHU#WR#7DSLQJ#6SHFLILFDWLRQV/#75#W\SH#LV#SUHVFULEHG#DV#D#VWDQGDUG1,

2

PIN CONFIGURATION

RN5RK××1A/××1B/××2A

SOT-23-5

54

(mark side)

PIN DESCRIPTION

Pin No. Symbol Pin description

4 &( &KLS#(QDEOH#3LQ

5 9

6 1& 1R#&RQQHFWLRQ

7 *1' *URXQG#3LQ

8 /

Pin No. Symbol Pin description

4 &( &KLS#(QDEOH#3LQ

5 9

6 1& 1R#&RQQHFWLRQ

7 *1' *URXQG#3LQ

287

;

287

12

3

6WHS0XS#2XWSXW#0RQLWRULQJ#3LQ/#3RZHU#6XSSO\#+IRU#GHYLFH#LWVHOI,

6ZLWFKLQJ#3LQ#+1FK#2SHQ#'UDLQ,

6WHS0XS#2XWSXW#0RQLWRULQJ#3LQ/#3RZHU#6XSSO\#+IRU#GHYLFH#LWVHOI,

8 (;7 ([WHUQDO#7U1#'ULYH#3LQ#+&026#2XWSXW,

3

RN5RK××1A/××1B/××2A

ABSOLUTE MAXIMUM RATINGS

Symbol Item Rating Unit

287

9

/;

9

6WHS0XS#2XWSXW#3LQ#9R O W D J H < 9

/;#3LQ#9R O W D J H < 9

(;7

9

&(

9

/;

,

(;7

,

'

3

(;7#3LQ#9R O W D J H ² 316#WR#9

&(#3LQ#9RO W D J H ² 316#WR#9

/[#3LQ#2XWSXW#&XUUHQW 833 P$

(;7#3LQ#2XWSXW#&XUUHQW “63 P$

3RZHU#'LVVLSDWLRQ 583 P:

287#

.316 9

287#

.316 9

7RSW 2SHUDWLQJ#7HPSHUDWXUH#5DQJH ²73#WR#.;8 ƒ&

7V W J 6W R U D J H #7HPSHUDWXUH#5DQJH ²88#WR#.458 ƒ&

ABSOLUTE MAXIMUM RATINGS

$EVROXWH#0D[LPXP#UDWLQJV#DUH#WKUHVKROG#OLPLW##YDOXHV#WKDW#PXVW#QRW#EH#H[FHHGHG#HYHQ#IRU#DQ#LQVWDQW#XQGHU#DQ\#FRQ0

GLWLRQV1#0RUHRYHU/#VXFK#YDOXHV#IRU#DQ\#WZR#LWHPV#PXVW#QRW#EH#UHDFKHG#VLPXOWDQHRXVO\1#2SHUDWLRQ#DERYH#WKHVH#DEVR0

OXWH#PD[LPXP#UDWLQJV#PD\#FDXVH#GHJUDGDWLRQ#RU#SHUPDQHQW#GDPDJH#WR#WKH#GHYLFH1#7KHVH#DUH#VWUHVV#UDWLQJV#RQO\#DQG

GR#QRW#QHFHVVDULO\#LPSO\#IXQFWLRQDO#RSHUDWLRQ#EHORZ#WKHVH#OLPLWV1

4

RN5RK××1A/××1B/××2A

ELECTRICAL CHARACTERISTICS

•

RN5RK 1A/ 1B

Symbol Item Conditions MIN. TYP. MAX. Unit

7R S W 58ƒ&

287

9

,1

9

287

2∆7R S W

9

∆

2XWSXW#9R O W D J H 9,1 VHW#9

,QSXW#9R O W D J H ; 9

2XWSXW#9R O W D J H #7HPSHUDWXUH

&RHIILFLHQW

073ƒ&≤7R S W≤;8ƒ& “433 SSP2ƒ&

9VWDUW 6WDUW08S#9R O W D J H 9,1 39→59

9VWDUW2∆7R S W

∆

6WDUW08S#9R O W D J H #7H P S H U D 0

WXUH#&RHIILFLHQW

073ƒ&≤7R S W≤;8ƒ&

,1

39→59-

9

9KROG +ROG0RQ#9RO W D J H #+××4$, 9,1 59→39-

9KROG +ROG0RQ#9RO W D J H #+××4%, 9,1 59→39-

''5

,

6XSSO\#&XUUHQW5 9

,VWDQE\ 6WDQGE\#&XUUHQW 9

/;OHDN

,

/[#/HDNDJH#&XUUHQW 9

0D[LPXP#2VFLOODWRU#)UH0

I

RVF

287 9&(

287

287 9/;

287 9&(

9

TXHQF\

)UHTXHQF\#7HPSHUDWXUH#&R0

I

RVF2

∆

HIILFLHQW

Topt

∆

073ƒ&≤7R S W≤;8ƒ& 3174

287

VHW#9

×

-4

4

4

4

287

319/#,

4P$

31<:8

×

×

31:8 31< 9

0419 P92ƒ&

31: 9

31< 9

287

.3189 58—$

41358 9

99/#9&( 39 318 —$

;9 4 —$

VHW#9

287

×

31<9

;3

433 453 N+]

N+]2

ƒ&

'XW\ 2VFLOODWRU#'XW\#&\FOH#+××4$,

'XW\ 2VFLOODWRU#'XW\#&\FOH#+××4%,

O[OLP

9

&(+

9

&(/

9

&(+

,

&(/

,

''4

,

''4

,

9/[#9R O W DJ H #/LPLW

&(#´+µ#,QSXW#9R O W D J H

&(#´/µ#,QSXW#9R O W D J H

&(#´+µ#,QSXW#&XUUHQW 9

&(#´/µ#,QSXW#&XUUHQW 9

6XSSO\#&XUUHQW4#

6XSSO\#&XUUHQW4#

-5

-5

287 9&(

9

+9/

287 9&(

9

+9/

287 9&(

9

VHW#9

;#

´/µ#VLGH,

VHW#9

;#

´/µ#VLGH,

41<89/#/[#6ZLWFK

21

287 9&(

9

VHW#9

-XGJPHQW#LV#PDGH#E\#WKH#/[

287

287

287

31<9/#21

×

31<9/#21

×

31<9/

×

:3 :: ;8 (

7: 88 96 (

317 319 31; 9

31< 9

ZDYHIRUP

287 9&(

9

VHW#9

-XGJPHQW#LV#PDGH#E\#WKH#/[

287

31<9/

×

316 9

ZDYHIRUP

287

9139/#9&( 9139 0318 3 318 —$

287

9139/#9&( 3139 0318 3 318 —$

5139≤9

5189≤9

287

5179 58 83 —$

≤

287

51<9 63 88 —$

≤

5

RN5RK××1A/××1B/××2A

Symbol Item Conditions MIN. TYP. MAX. Unit

,

,

,

,

,

''4

''4

''4

''4

''4

6XSSO\#&XUUHQW4#

6XSSO\#&XUUHQW4#

6XSSO\#&XUUHQW4#-

6XSSO\#&XUUHQW4#-

6XSSO\#&XUUHQW4#-

-5

-5

5

5

5

6139≤9

6189≤9

7139≤9

7189≤9

8139≤9

287

6179 68 93 —$

≤

287

61<9 73 98 —$

≤

287

7179 78 :8 —$

≤

287

71<9 83 ;3 —$

≤

287

8189 93 <3 —$

≤

;

,/

,/

,/

,/

,/

,/

,/

;

;

;

;

;

;

/[#6ZLWFKLQJ#&XUUHQW 5139≤9

/[#6ZLWFKLQJ#&XUUHQW 5189≤9

/[#6ZLWFKLQJ#&XUUHQW 6139≤9

/[#6ZLWFKLQJ#&XUUHQW 6189≤9

/[#6ZLWFKLQJ#&XUUHQW 7139≤9

/[#6ZLWFKLQJ#&XUUHQW 7189≤9

/[#6ZLWFKLQJ#&XUUHQW 8139≤9

*1) Condition: An Output load resistor RL is connected between V

287

287

287

287

287

287

287

5179/#9/

≤

51<9/#9/

≤

6179/#9/

≤

61<9/#9/

≤

7179/#9/

≤

71<9/#9/

≤

8189/#9/

≤

;

3179 ;3 P$

;

3179 433 P$

;

3179 453 P$

;

3179 473 P$

;

3179 493 P$

;

3179 4;3 P$

;

3179 533 P$

OUT

and GND.

Note that the resistor RL has a resistance which makes an output current 1mA after step-up operation.

*2) The Supply Current 1 (I

DD1

) for IC itself is measured when the internal oscillator works continuously.
If the oscillator works intermittently, the supply current becomes smaller than the value which is written
on the above table.
Measurement condition: V

OUT=VCE

=Setting Output Voltage ×0.96

6

RN5RK××1A/××1B/××2A

RN5RK

•

××

××

××××

2A

7R S W 58ƒ&

Symbol Item Conditions MIN. TYP. MAX. Unit

287

9

,1

9

2

V

OUT

∆

∆

2XWSXW#9R O W D J H 9,1 VHW#9

,QSXW#9R O W D J H ; 9

Output Voltage Temperature

Topt

073ƒ&≤7R S W≤;8ƒ& “433 SSP2ƒ&

287

319/#,

×

287

4P$

31<:8

×

41358 9

×

Coefficient

9VWDUW 6WDUW08S#9R O W D J H 9,1 39→59

Vstart/∆Topt

∆

''5

,

Coefficient

6XSSO\#&XUUHQW5 9

,VWDQE\ 6WDQGE\#&XUUHQW 9

0D[LPXP#2VFLOODWRU#)UH0

)

Start-Up Voltage Temperature

RVF

TXHQF\

-40°C≤Topt≤85°C
=0V→2V*

V

IN

287 9&(

287

287 9&(

9

99/#9&( 39 318 —$

-4

1

VHW#9

VHW#9

31: 31; 9

0419 P92ƒ&

287

.3189 58—$

287

31<9 ;3 433 453 N+]

×

)UHTXHQF\#7HPSHUDWXUH#&R0

I

RVF2

∆

HIILFLHQW

Topt

∆

073ƒ&≤7R S W≤;8ƒ& 3174 N+]2ƒ&

'XW\ 2VFLOODWRU#'XW\#&\FOH

&(+

9

9

,

,

,

,

,

,

(;7+

,

&(/

&(+

&(/

''4

''4

''4

''4

&(#´+µ#,QSXW#9R O W D J H

&(#´/µ#,QSXW#9R O W D J H

&(#´+µ#,QSXW#&XUUHQW 9

&(#´/µ#,QSXW#&XUUHQW 9

6XSSO\#&XUUHQW4 5139≤9

6XSSO\#&XUUHQW4 6139≤9

6XSSO\#&XUUHQW4 7139≤9

6XSSO\#&XUUHQW4 8139≤9

(;7#´+µ#2XWSXW#9RO W D J H

287 9&(

9

21#+9

287 9&(

9

VHW#9

(;7#

´+µ#VLGH,

VHW#9

-XGJPHQW#LV#PDGH#E\#WKH#(;7

287

287

31<9/

×

31<9/

×

:3 :: ;8 (

31< 9

ZDYHIRUP

287 9&(

9

VHW#9

-XGJPHQW#LV#PDGH#E\#WKH#(;7

287

×

31<9

316 9

ZDYHIRUP

287

9139/#9&( 9139 0318 3 318 —$

287

9139/#9&( 3139 0318 3 318 —$

5

5

5

5

53 73 —$

58 83 —$

63 93 —$

68 :3 —$

0413

5139≤9

(;7 9287

9

287

51<9/#(;7#QR#ORDG-

≤

287

61<9/#(;7#QR#ORDG-

≤

287

71<9/#(;7#QR#ORDG-

≤

287

8189/#(;7#QR#ORDG-

≤

287

51<9/

≤

03179

P$

(;7+

,

(;7#´+µ#2XWSXW#9RO W D J H

6139≤9

(;7 9287

9

287

61<9/

≤

03179

0418 P$

7

RN5RK××1A/××1B/××2A

Symbol Item Conditions MIN. TYP. MAX. Unit

287

(;7+

,

(;7#´+µ#2XWSXW#9RO W D J H

7139≤9

(;7 9287

9

8189/

≤

03179

0513 P$

(;7+

,

(;7+

,

(;7+

,

(;7#´/µ#2XWSXW#9R O W D J H 5139≤9

(;7#´/µ#2XWSXW#9R O W D J H 6139≤9

(;7#´/µ#2XWSXW#9R O W D J H 7139≤9

*1) Condition: An Output load resistor RL is connected between V

287

287

287

51<9/#9

≤

61<9/#9

≤

8189/#9

≤

(;7

3179 413 P$

(;7

3179 418 P$

(;7

3179 513 P$

OUT

and GND.

Note that the resistor RL has a resistance which makes an output current 1mA after step-up operation.

*2) The Supply Current 1 (I

DD1

) for IC itself is measured when the internal oscillator works continuously.
If the oscillator works intermittently, the supply current becomes smaller than the value which is written
on the above table. Measurement condition: V

OUT=VCE

=Setting Output Voltage ×0.96

8

TEST CIRCUITS

SBD

1KΩ

Lx

RN5RK××1A/××1B/××2A

OUT

V

L

V

IN

Osilloscope

*) When V

Lx

GND

OUT

V

CE

V

R

C

L

L

GND

CE

T est Circuit 1 T est Circuit 2

Lx

V

OUT

C

GND

CE

L

T est Circuit 3

LX

lim and ILX are measured, the 5Ωresistor is used. Otherwise 1kΩis used.

A

C

L

&RPSRQHQWV#,QGXFWRU +/, =#433—+/#553—+#+6XPLGD#(OHFWULF#&R1/#/WG>#&'087,

'LRGH +6%',=#0$:54#+0DWVXVKLWD#(OHFWURQLFV#&RUSRUDWLRQ>#6FKRWWN\#7\ S H ,

/

&DSDFLWRU +&

, =#7:—)#+7DQWDOXP#7\ S H ,

8VLQJ#WKHVH#WHVW#FLUFXLWV#FKDUDFWHULVWLFV#GDWD#KDV#EHHQ#REWDLQHG#DV#VKRZQ#RQ#WKH#IROORZLQJ#SDJHV1

7H V W #&LUFXLW#4 =#7<3,&$/#&+$5$&7(5,67,&6#+4,0+:,

7H V W #&LUFXLW#5 =#7<3,&$/#&+$5$&7(5,67,&6#+<,0+44,

7H V W #&LUFXLW#6 =#7<3,&$/#&+$5$&7(5,67,&6#+;,/#+45,0+49,

9

RN5RK××1A/××1B/××2A

SBD

L

Tr

Rb

EXT

V

OUT

V

L

IN

V

Cb

GND

CE

C

T est Circuit 1 T est Circuit 2

EXT

V

OUT

Osilloscope

C

GND

CE

L

T est Circuit 3 T est Circuit 4

&RPSRQHQWV#,QGXFWRU +/, =#5:—+#+6XPLGD#(OHFWULF#&R1/#/WG>#&'0437,

'LRGH +6%',=#5%444&#+52+0#&R1/#/WG>#6FKRWWN\#7\ S H ,

/

&DSDFLWRU +&

, =#7:—)×5+7DQWDOXPH#7\ S H ,

7UDQVLVWRU +7U ,=#56'495;*

%DVH#5HVLVWRU +5E, =#633Ω%DVH#&DSDFLWRU#+&E,=#3134—)

EXT

GND

100Ω

Osilloscope

V

EXT

GND

OUT

CE

A

C

L

OUT

V

C

CE

L

8VLQJ#WKHVH#WHVW#FLUFXLWV#FKDUDFWHULVWLFV#GDWD#KDV#EHHQ#REWDLQHG#DV#VKRZQ#RQ#WKH#IROORZLQJ#SDJHV1

7H V W #&LUFXLW#4 =#7<3,&$/#&+$5$&7(5,67,&6#+4,0+8,

7H V W #&LUFXLW#5 =#7<3,&$/#&+$5$&7(5,67,&6#+;,0+43,

7H V W #&LUFXLW#6 =#7<3,&$/#&+$5$&7(5,67,&6#+44,0+47,

7H V W #&LUFXLW#7 =#7<3,&$/#&+$5$&7(5,67,&6#+9,/#+:,

10

TYPICAL CHARACTERISTICS

RN5RK××1A/××1B/××2A

RN5RK

•

××

××

××××

1A/B

1) Output Voltage vs. Output Current (Topt=25°C)

RN5RK301A RN5RK301A

3.5

3.0

(V)

2.5

OUT

2.0
VIN=0.9V

1.5

1.0

Output V oltage V

0.5

0.0

0 204060 16014080 100 120

1.0V

1.3V

Output Current I

OUT

L=100µH

2.0V

1.5V

(mA)

RN5RK301B RN5RK301B

L=100µH

2.0V

(V)

OUT

3.5

3.0

2.5

2.0

1.5

VIN=1.0V

1.3V

1.5V

3.5

3.0

(V)

2.5

OUT

Output V oltage V

2.0

1.5

1.0

0.5

0.0

1.0V 1.5V 2.0V

VIN=0.9V

0 204060 16014080 100 120

1.3V

Output Current I

3.5

(V)

OUT

3.0

2.5

2.0

1.5

1.3V

VIN=1.0V

1.5V

OUT

L=220µH

(mA)

L=220µH

2.0V

1.0

Output V oltage V

0.5

0.0
0 102030 5040

Output Current IOUT(mA)

RN5RK501A RN5RK501A

6

5

(V)

OUT

4

VIN=0.9V

3

2

Output V oltage V

1

0

0 50 100 150 200

2.0V

1.5V

Output Current I

OUT

(mA)

L=100µH

4.0V

3.0V

1.0

Output V oltage V

0.5

0.0
0 102030 5040

Output Current I

6

5

(V)

OUT

4

VIN=0.9V

3

2

Output V oltage V

1

0

0 50 100 150 200

1.5V 2.0V 3.0V

Output Current I

OUT

OUT

(mA)

(mA)

L=220µH

4.0V

11

RN5RK××1A/××1B/××2A

RN5RK501B RN5RK501B

6

5

(V)

OUT

4

2.0V

3

IN

=1.5V

V

2

L=100µH

2.5V 3.0V

4.0V

(V)

OUT

6

5

2.0V

4

IN

=1.5V

V

3

2

2.5V

L=220µH

4.0V

3.0V

Output V oltage V

1

0

0 50 100 150 200

Output Current I

OUT

(mA)

2) Efficiency vs. Output Current (Topt=25°C)

RN5RK301A RN5RK301A

100

90

80

70

60

Efficiency η(%)

50

VIN=0.9V

40

0 204060 16014080 100 120

1.0V

Output Current I

1.5V

1.3V

OUT

L=100µH

(mA)

2.0V

Output V oltage V

1

0

0 50 100 150 200

Output Current I

100

90

80

70

60

Efficiency η(%)

50

40

1.0V

VIN=0.9V

0 204060 16014080 100 120

1.3V

Output Current I

1.5V

OUT

OUT

(mA)

(mA)

L=220µH

2.0V

12

RN5RK301B RN5RK301B

100

90

80

VIN=1.0V

70

60

Efficiency η(%)

50

40

0 102030 5040

Output Current I

1.3V

1.5V

OUT

(mA)

L=100µH

2.0V

100

90

80

70

Efficiency η(%)

VIN=1.0V

60

50

0 102030 5040

Output Current I

OUT

L=220µH

2.0V1.5V1.3V

(mA)

100

RN5RK××1A/××1B/××2A

RN5RK501A RN5RK501A

L=100µH

100

L=220µH

90

80

2.0V

70

VIN=0.9V

60

Efficiency η(%)

50

40

0 50 100 150 200

1.5V

Output Current I

OUT

(mA)

RN5RK501B RN5RK501B

100

90

2.0V

2.5V

VIN=1.5V

Efficiency η(%)

80

70

60

4.0V

3.0V

L=100µH

4.0V

3.0V

90

80

70

Efficiency η(%)

Efficiency η(%)

60

50

40

100

90

80

70

60

1.5V

VIN=0.9V

2.0V

0 50 100 150 200

Output Current I

2.0V

2.5V

VIN=1.5V

OUT

(mA)

4.0V

3.0V

L=220µH

4.0V

3.0V

50

40

0 50 100 150 200

Output Current I

OUT

(mA)

3) Ripple Voltage vs. Output Current (Topt=25°C)

RN5RK301A RN5RK301A

140
120
100

80
60
40

Ripple V oltage Vr(mVp-p)

20

0

0 204060 16014080 100 120

1.3V

1.0V

VIN=0.9V

Output Current I

1.5V

OUT

L=100 µH

2.0V

(mA)

50

40

0 50 100 150 200

Output Current I

160
140
120
100

1.3V

80
60
40

Ripple V oltage Vr(mVp-p)

20

0

04020 8060 100 160140120

1.0V

VIN=0.9V

Output Current I

1.5V

OUT

OUT

(mA)

(mA)

L=220µH

2.0V

13

RN5RK××1A/××1B/××2A

RN5RK301B RN5RK301B

45
40
35
30
25
20
15
10

Ripple V oltage Vr(mVp-p)

5
0

0 102030 5040

200

1.3V

VIN=1.0V

Output Current I

RN5RK501A RN5RK501A

1.5V

L=100µH

OUT

(mA)

L=100µH

2.0V

45
40
35
30
25
20
15
10

Ripple V oltage Vr(mVp-p)

5
0

1.3V1.0V

1.5V

0 102030 5040

Output Current I

200

L=220µH

OUT

(mA)

L=220µH

2.0V

150

100

2.0V

50

Ripple V oltage Vr(mVp-p)

0

0 50 100 150 200

1.5V

VIN=0.9V

Output Current I

OUT

RN5RK501B RN5RK501B

140
120
100

80
60

2.0V

40

Ripple V oltage Vr(mVp-p)

20

VIN=1.5V

0

0 50 100 150 200

2.5V

Output Current I

OUT

3.0V

4.0V

(mA)

L=100µH

3.0V

4.0V

(mA)

150

2.0V

100

50

Ripple V oltage Vr(mVp-p)

0

0 50 100 150 200

1.5V

VIN=0.9V

Output Current I

140
120
100

80
60
40

Ripple V oltage Vr(mVp-p)

20

0

VIN=1.5V

0 50 100 150 200

Output Current I

2.5V

OUT

3.0V

OUT

3.0V

(mA)

(mA)

4.0V

L=220µH

4.0V

14

4) Start-up/Hold-on Voltage vs. Output Current (Topt=25°C)

RN5RK301A RN5RK501A

1.4

L=100µH

1.4

RN5RK××1A/××1B/××2A

L=100µH

1.2

1.0
Vstart

0.8

0.6

Vstart/Vhold(V)

0.4

Start-up/Hold-on Voltage

0.2

0.0

015105

2.0

1.8

1.6

1.4

1.2

1.0

0.8

0.6

Vstart/Vhold(V)

0.4

Start-up/Hold-on Voltage

0.2

0.0
015105

1.2

1.0

Vstart

0.8

0.6
Vhold

015105

Output Current I

Vhold

Output Current I

OUT

(mA)

Vstart/Vhold(V)

0.4

Start-up/Hold-on Voltage

0.2

0.0

RN5RK301B RN5RK501B

Vstart

Vhold

Output Current I

OUT

L=100µH

(mA)

2.0

1.8

1.6

1.4

1.2

Vstart

1.0

0.8

0.6

Vstart/Vhold(V)

0.4

Start-up/Hold-on Voltage

0.2

0.0

015105

Vhold

Output Current I

OUT

OUT

(mA)

L=100µH

(mA)

5) Output Voltage vs. Temperature

RN5RK301A RN5RK501A

3.10

(V)

3.05

OUT

3.00

2.95

Output V oltage V

2.90

I

OUT=0m

OUT

I

OUT

A

=10mA

=30mA

I

-50 -25 1007502550

Temperature Topt( )

VIN=1.5V,L=100µH

5.10

(V)

5.05

OUT

5.00

4.95

Output V oltage V

4.90

-50 -25 1007502550

IOUT=30mA

IOUT=0mA

IOUT=10mA

Temperature Topt( )

VIN=3.0V,L=100µH

15

RN5RK××1A/××1B/××2A

6) Start-up Voltage vs. Temperature

RN5RK501A RN5RK501B

1

L=100 µH

1

L=100µH

0.8

0.6

0.4

0.2

Start-up Voltage Vstart(V)

0

-50 -25 1007502550

Temperature Topt( )

7) Hold-on Voltage vs. Temperature

RN5RK501A RN5RK501B

1

0.8

0.6

0.4

L=100µH

0.8

0.6

0.4

0.2

Start-up Voltage Vstart(V)

0

-50 -25 1007502550

Temperature Topt( )

1

0.8

0.6

0.4

L=100µH

0.2

Hold-on V oltage Vhold(V)

0

-50 -25 1007502550

Temperature Topt( )

8) Lx Switching Current vs. Temperature

RN5RK301A RN5RK501A

500

400

300

200

100

LxSwitching Current ILx(mA)

0

-50 -25 1007502550

Temperature Topt( )

0.2

Hold-on V oltage Vhold(V)

0

-50 -25 1007502550

Temperature Topt( )

500

400

300

200

100

LxSwitching Current ILx(mA)

0

-50 -25 1007502550

Temperature Topt( )

16

9) Supply Current 1 vs. Temperature

RN5RK301A RN5RK501A

50

RN5RK××1A/××1B/××2A

80

(µA)

40

DD1

30

20

Supply Current1 I

10

-50 -25 1007502550

Temperature Topt( )

70

(µA)

DD1

60

50

40

Supply Current1 I

30

-50 -25 1007502550

Temperature Topt( )

10) Supply Current 2 vs. Temperature 11) Standby Current 3 vs. Temperature

RN5RK301A RN5RK301A

(µA)

DD2

5

4

3

2

1

0.8

0.6

0.4

1

Supply Current2 I

0

-50 -25 1007502550

Temperature Topt( )

12) Oscillator Duty Cycle vs. Temperature

RN5RK301A RN5RK301B

85

80

75

Oscullator Duty Cycle Maxduty(%)

70

-50 -25 1007502550

Temperature Topt( )

0.2

Supply Current3 Istandby(µA)

0

-50 -25 1007502550

Temperature Topt( )

60

58

56

54

52

Oscullator Duty Cycle Maxduty(%)

50

-50 -25 1007502550

Temperature Topt( )

17

RN5RK××1A/××1B/××2A

13) CE “H” Input Voltage vs. Temperature 14) CE “L” Input Voltage vs. Temperature

RN5RK301A RN5RK301A

(V)

CEH

1

0.8

(V)

CEL

1

0.8

0.6

0.4

0.2

CE H Input Voltage V

0

-50 -25 1007502550

Temperature Topt( )

0.6

0.4

0.2

CE L Input Voltage V

0

-50 -25 1007502550

Temperature Topt( )

15) Maximum Oscillator Frequency vs. Temperature 16) VLX Voltage Limit vs. Temperature

RN5RK301A RN5RK301A

0.8

120

(kHz)

OSC

110
100

90
80
70
60
50

-50 -25 1007502550

Maximum Oscillator Frequency f

Temperature Topt( )

(V)

0.7

Lx

0.6

Voltage Limit V

0.5

Lx

V

0.4

-50 -25 1007502550

Temperature Topt( )

18

RN5RK××1A/××1B/××2A

RN5RK

•

××

××

××××

2A

1) Output Voltage vs. Output Current (Topt=25°C)

RN5RK302A RN5RK502A

1.5V

OUT

L=27µH

2.0V

(mA)

3.5

3.0

(V)

2.5

OUT

2.0

1.5

1.0

Output V oltage V

VIN=0.9V

0.5
0

0 200 400 600 800

1.3V

1.0V

Output Current I

2) Efficiency vs. Output Current (Topt=25°C)

RN5RK302A RN5RK502A

L=27µH

2.0V

Efficiency η(%)

100

90

80

70

60

50

V

IN

=0.9V

1.5V

1.3V

1.0V

6.0

5.0

(V)

OUT

4.0

IN

=1.0V

V

3.0

2.0

Output V oltage V

1.0

0.0
0 200 400 600 800

Output Current I

100

90
80
70

VIN=1.0V

60

Efficiency η(%)

50
40

1.5V

1.5V

2.0V

OUT

2.0V

(mA)

L=27µH

3.0V

L=27µH

3.0V

40

0 200 400 600 800

Output Current I

OUT

(mA)

3) Ripple Voltage vs. Output Current (Topt=25°C)

RN5RK302A RN5RK502A

OUT

L=27µH

2.0V

(mA)

250

1.3V

200

1.0V

150

100

50

Ripple V oltage Vr(mVp-p)

VIN=0.9V

0

0 200 400 600 800

1.5V

Output Current I

30

0 200 400 600 800

Output Current I

300

250

200

150

100

50

Ripple V oltage Vr(mVp-p)

0

0 200 400 600 800

1.5V

VIN=1.0V

Output Current I

OUT

2.0V

OUT

(mA)

(mA)

L=27µH

3.0V

19

RN5RK××1A/××1B/××2A

4) Start-up/Hold-on Voltage vs. Output Current (Topt=25°C)

RN5RK302A RN5RK502A

2.0

1.8

1.6

1.4

1.2

V

start

1.0

0.8

0.6

Vstart/Vhold(V)

0.4

Start-up/Hold-on Voltage

0.2

0.0

hold

V

0 20015010050

Output Current I

5) Output Voltage vs. Temperature

RN5RK302A RN5RK502A

3.10

OUT

VIN=1.2V,L=27µH

L=27µH

(mA)

2.4

2.2

2.0

1.8

1.6

Vstart,Vhold

1.4

1.2

1.0

0.8

Vstart/Vhold(V)

0.6

0.4

Start-up/Hold-on Voltage

0.2

0.0
0 20015010050

5.10

Output Current I

L=27µH

OUT

(mA)

VIN=3.0V,L=27µH

3.05

(V)

OUT

3.00

I

OUT=0m

A

2.95
I

OUT

=50mA

Output V oltage V

2.90

2.85

I

OUT

=100mA

2.80

-50 -25 1007502550

Temperature Topt( )

6) EXT “H” Output Current vs. Temperature

RN5RK302A RN5RK502A

10

9

(mA)

8

EXTH

7
6
5
4
3
2
1

EXT H Output Current I

0

-50 -25 1007502550

Temperature Topt( )

(V)

5.05

OUT

5.00

4.95

I

OUT

=100mA

Output V oltage V

4.90

-50 -25 1007502550

Temperature Topt( )

10

9

(mA)

8

EXTH

7
6
5
4
3
2
1

EXT H Output Current I

0

-50 -25 1007502550

Temperature Topt( )

I

OUT=0m

I

OUT

A

=50mA

20

7) EXT “L” Output Current vs. Temperature

RN5RK302A RN5RK502A

20
18

(mA)

16

EXTL

14
12
10

8
6
4
2

EXT L Output Current I

0

-50 -25 1007502550

Temperature Topt( )

8) Supply Current 1 vs. Temperature

RN5RK302A RN5RK502A

50

RN5RK××1A/××1B/××2A

20
18

(mA)

16

EXTL

14
12
10

8
6
4
2

EXT L Output Current I

0

-50 -25 1007502550

Temperature Topt( )

50

40

(µA)

DD1

30

20

10

Supply Current1 I

0

-50 -25 1007502550

Temperature Topt( )

40

(µA)

DD1

30

20

10

Supply Current1 I

0

-50 -25 1007502550

Temperature Topt( )

9) Supply Current 2 vs. Temperature 10) Standby Current vs. Temperature

RN5RK302A RN5RK302A

1

0.8

0.6

0.4

(µA)

DD2

5

4

3

2

1

Supply Current2 I

0

-50 -25 1007502550

Temperature Topt( )

0.2

Supply Current3 Istandby(µA)

0

-50 -25 1007502550

Temperature Topt( )

21

RN5RK××1A/××1B/××2A

11) Oscillator Duty Cycle vs. Temperature 12) Maximum Oscillator Frequency vs. Temperature

RN5RK302A RN5RK302A

85

120
110

80

100

90

(kHz)

80

OSC

75

Oscullator Duty Cycle Maxduty(%)

70

-50 -25 1007502550

Temperature Topt( )

f

70
60

Maximum Oscillator Frequency

50

-50 -25 1007502550

Temperature Topt( )

13) CE “H” Input Voltage vs. Temperature 14) CE “L” Input Voltage vs. Temperature

RN5RK302A RN5RK302A

1

(V)

0.8

CEH

0.6

0.4

0.2

CE H Input Voltage V

0

-50 -25 1007502550

Temperature Topt( )

1

(V)

0.8

CEL

0.6

0.4

0.2

CE L Input Voltage V

0

-50 -25 1007502550

Temperature Topt( )

22