SP7682EB_技术文档

SP7682/SP7682A

Backlight and Flash Driver in QFN 3mm x 3mm

FEATURES

Output current up to 500mA for Flash LED

Up to 94% efficiency in 1x mode

Triple mode 1x, 1.5x and 2x charge pump

Built-in current setting DAC

SP7682 - I²C serial interface

SP7682A – Single Line Programmable Serial Interface

2.4MHz switching frequency

Flash LED output current adjustable in 10mA steps to 500mA

Backlight LED output current adjustable in 0.5mA steps to 31.5mA

Power-saving shutdown mode of 1μA

Time Out function to protect the LED in Flash mode (2s)

Thermal shutdown protection

VOUT

SGND

LED 1

LED 2

VIN

PGND

EN

SCL (SETFL)

Built-in over-voltage and over-current protection

Automatic soft start limits in-rush current

Lead Free, RoHS Compliant Packaging:

Space saving 16-pin 3X3mm QFN package

DESCRIPTION

The SP7682 or SP7682A provides a complete LED backlight and flash solution that is designed to drive 4 low

current LEDs for backlighting and a single channel high current output for a LED flash. The SP7682 and SP7682A

have serial interfaces that can program the backlight LED current in steps of 0.5mA up to 31.5mA and flash LED

current in steps of 10mA up to 500mA. The SP7682A uses two single line serial interfaces for programming the

backlight current and flash current. The SP7682 uses an I²C serial interface which also allows programming active,

standby and shutdown states, selecting flash timeout periods and switching individual LEDs for the backlight. The

data is loaded into internal registers upon power up and stored while in shutdown. When the chip is enabled, the

stored values set the LED currents. The SP7682/SP7682A automatically detects 1x, 1.5x or 2x operation for

optimal efficiency.

TYPICAL APPLICATION CIRCUIT

C1 1uF

C2 1uF

VIN = 2.7V to 5.5V

VIN C1+ C1- C2+ C2-

VOUT

C_IN

4.7uF

C_OUT

2.2uF

SDA (SETBL)

SCL (SETFL)

SDA (SETBL)

SCL (SETFL)

Flash

FLASH

SP7682

(SP7682A)

LED1

LED2

LED3

LED4

EN

PGND SGND

Sept 27-07 rev G

SP7682: Backlight and Flash Driver

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1

ABSOLUTE MAXIMUM RATINGS

These are stress ratings only and functional operation of the

device at these ratings or any other above those indicated in the

operation sections of the specifications below is not implied.

Exposure to absolute maximum rating conditions for extended

periods of time may affect reliability.

V_CC, Enable, SCL, SDA, V_FLASH, V_LED..............-0.3V to 6.0V

Power Dissipation………………………….Internally limited¹

Storage Temperature..……..………………-65 °C to 150 °C

Junction Temperature................................-40°C to +125°C

ESD @ LED pins……………...…………………+/-4kV HBM

ESD all other pins………….…………………....+/-2kV HBM

ELECTRICAL SPECIFICATIONS

Unless otherwise specified: V_IN=3.6V, C_IN=4.7uF, C_OUT=2.2uF, C_FLY=1uF, T_A= -40°C to +85°C, Tj=-40°C to +125°C.

Bold values apply over the full operating temperature range (-40°C to 85°C).

PARAMETER

Operating VIN Range

MIN

2.7

TYP

MAX

5.5

UNITS

CONDITIONS

V

Operating Input Current

2

mA

Quiescent Current

25

Standby Mode

_EN= 0V (shutdown), Ta = 25°C

Measure LED1-LED4 and FLASH pins

Measure current into LED1-LED4

Measure current into FLASH

μA

mA

Shutdown Supply Current

ILED Voltage for DAC=000000

I_LEDfor DAC=000001

0.01

1

V

0

0.5

31.5

10

I_LEDfor DAC=111111

30.2

465

34.8

535

I_FLASHfor DAC=000001

I_FLASHfor DAC=110010

mA

500

Measure current into FLASH

Current DAC Resolution

Backlight Current DAC LSB

Flash Current DAC LSB

6

Bit

mA

0.5

10

DAC Current Accuracy

-7

7

%

5mA< I_LED<30mA, 80mA< I_FLASH<500mA

Switching Frequency

1.9

2.4

1.0

10

8

2.9

1.8

MHz

Ohm

V

Equivalent Resistance, 1x mode

Equivalent Resistance, 1.5x mode

Equivalent Resistance, 2x mode

LEDx Pin dropout voltage

FLASH Pin dropout voltage

Thermal Regulation

Iout=200mA

Iout=80mA

Iout=500mA

0.25

I_LED=20mA, measure mode switching

I_FLASH=200mA, measure mode switching

V

0.01

170

%/°C

Thermal Shutdown Die Temperature

Thermal Shutdown Hysteresis

Over-current Protection

150

160

20

Driver turns off

°C

A

Driver turns on again

Vout =0V

0.7

1.2

6.0

Over-voltage protection

5.4

V

Vout open

Settle time (T_S) after last count

SDA, SCL, SETB, SETFL input logic low

voltage

100

To 1x mode from STANDBY mode

μs

0.4

V

SDA, SCL, SETB, SETFL input logic

high voltage

Turn-off time (T_OFF) into shutdown

1.6

V

μs

s

50

EN pin high to low

TD0=TD1=0V, I_FLASH>I_THRESHOLD(defined by

bits TOUT0, TOUT1)

Time Duration before standby, SP7682

2

1

4

2

6

Time Duration before standby, SP7682A

Enable logic low voltage

3

s

V

I_FLASH>I_THRESHOLD= 230mA

0.4

Driver shutdown

Driver enabled

Enable logic high voltage

1.6

Sept 27-07 rev G

SP7682: Backlight and Flash Driver

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I²C SPECIFICATIONS

CONDITIONS

PARAMETER

SYMBOL

MIN

TYP MAX UNITS

Serial Clock Frequency

Bus Free Time Between a STOP and a

START

f_SCL

400

kHz

t_BUF

1.3

µs

Hold Time, Repeated START Condition

Repeated START Condition Setup Time

STOP Condition Setup Time

Data Hold Time

Input Data Hold Time

Data Setup Time

SCL Clock Low Period

SCL Clock High Period

Rise Time of Both SDA and SCL

Signals, receiving

Fall Time of Both SDA and SCL

Signals, Receiving

t _{HD_STA}

t _SU,STA

t_SU,STO

t_HD,DAT(OUT)

t_HD,DAT(IN)

t_SU,DAT

0.6

225

0

100

1.3

µs

ns

µs

900

t_LOW

t_HIGH

0.6

20+

0.1Cb

20+

0.1Cb

20+

0.1Cb

0

t_R

t_F

300

250

(Notes2, 3)

(Note2, 3)

ns

Fall Time of SDA Transmitting

t_F.TX

ns

(Note2, 3, 4)

Pulse Width of Spike Suppressed

Capacitive Load for Each Bus Line

I²C startup time after UVLO clears

t_SP

Cb

t_SRT

50

400

1

ns

pF

µs

(Note5)

(Note 2)

400

1

Note 1: All parameters tested at T_A=25 °C. Specifications over temperature are guaranteed by design.

Note 2: Guaranteed by design.

Note 3: Cb = total capacitance of one bus line in pF. t_Rand t_Fmeasured between 0.3 x VDD and 0.7 x VDD.

Note 4: I_SINK≤6mA. Cb =total capacitance of one bus line in pF. t_Rand t_Fmeasured between 0.3 x V_DDand 0.7 V_DD.

Note5: Input filters on the SDA and SCL inputs suppress noise spikes less than 50ns.

SP7682A: SINGLE LINE PROGRAMMABLE SERIAL INTERFACE SPECIFICATIONS

PARAMETER

SYMBOL MIN

TYP

0.4

MAX

UNITS

V

µs

CONDITIONS

SET_BL, SET_FL logic low threshold

SET_BL, SET_FL logic high threshold

SET_BL, SET_FL logic low time

SET_BL, SET_FL logic high time

SET_BL shutdown delay

V_IL

V_IH

t_LO

1.6

0.5

250

V_{SET_BL}< 0.4V

V_{SET_BL}> 1.6V

V_{SET_BL}< 0.4V

V_{SET_FL}< 0.4V

t_HI

0.5

500

t_SHDN

225

325

800

700

SET_FL shutdown delay

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SP7682: Backlight and Flash Driver

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PIN DESCRIPTION

NAME

PIN #

DESCRIPTION

1

2

V_IN

Power supply input. Place a 4.7uF decoupling capacitor next to this pin.

Power ground pin.

PGND

Enable/Shutdown (Logic high = enable, logic low = shutdown). Used to immediately

disable the driver and reset the output current level.

3

EN

SCL,SDA These pins connect to the I²C bus. Multiple functions can be programmed through his

(SP7682) interface.

4, 5

SETFL

4

5

Used to serially program the Flash LED current

(SP7682A)

SETBL

Used to serially program the Backlight LED’s output current

(SP7682A)

High current internal current source. Connect a high brightness LED between this pin and

V_OUT. The value of the current can be programmed via the I²C interface between 0mA

and 500mA with 10mA increments. During operation this pin is monitored for dropout.

6

FLASH

When dropout condition detected the charge pump increases operation mode from 1x to

1.5x to 2x. If the FLASH current is set to above the maximum threshold the time-out

protection circuit is activated. After the maximum time of constant operation, FLASH

current is reduced to zero.

Internal current source for LCD backlight. Connect an LED between each of these pins

and V_OUT. The value of the current can be programmed via the I²C interface between

0mA and 32mA with 0.5mA increments. During operation this pin is monitored for dropout.

When dropout condition detected the charge pump increases operation mode from 1x to

1.5x to 2x. If any of the LEDs are not used connect the corresponding pin to Vout.

7,8,9,

10

LED1-

LED4

11

12

SGND

VOUT

Signal ground pin.

Output voltage of the internal charge pump. Connect the LEDs between this pin and the

corresponding internal current source. Connect a 2.2uF capacitor between VOUT and

PGND.

13,14, C2+, C2-,

Connect external flying capacitors between these pins.

Connect thermal pad to PGND pin.

15,16

C1+, C1-

Thermal

Pad

-

Sept 27-07 rev G

SP7682: Backlight and Flash Driver

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FUNCTIONAL DIAGRAM

Sept 27-07 rev G

SP7682: Backlight and Flash Driver

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THEORY OF OPERATION

The SP7682 and SP7682A are charge pump based

backlight and flash LED drivers with I²C and serial single

wire interface (SWI) control respectively. The SP7682

family provides very accurate current drive capability for

up-to four backlight LED channels and a flash LED. The

backlight LED current can be set through a serial

interface controlled 6-bit current DAC with 0.5mA steps,

up to 31.5mA. Similarly, FLASH LED current is set thru a

serial interface controlled 6-bit current DAC with 10mA

steps, up to 500mA.

charge pump switches at a high frequency of 2.4MHz

which allows tiny 1uF external capacitors to be used as

flying capacitors.

When any of the LED outputs or the FLASH output

voltage drops below the "dropout" voltage (200mV

typical), the charge pump decides to switch up to a less

efficient mode, i.e. in 1x mode it switches to 1.5x mode,

in 1.5x mode it switches to 2x mode. This switching to a

less efficient mode guarantees the part to sustain LED

currents in regulation. For the decision to switch back to

a more efficient mode, the mode decision logic uses

battery voltage, output voltage and load current

information and relies on preset margins on the mode

switching comparator thresholds.

Backlight and Flash current loops make sure that the

corresponding output currents at each individual LED

output are regulated to their DAC set current values. The

inherent decision and control logic decides the operation

mode of the "gear-box" charge pump to maximize overall

efficiency. In order to decide on the most efficient

operation mode for the charge pump, the decision and

control logic observes the battery voltage, output

voltage, load current, dropout voltage, over-voltage,

over-current conditions and in-regulation feedback

signals and forces the charge pump to operate in one of

the 1x, 1.5x and 2x modes and dynamically switches

between modes to maximize overall efficiency.

The FLASH channel can be used in torch mode as well

as in Flash time-out mode. When used for a momentary

Flash output, it is recommended to activate the I²C

control for timeout. Once the I²C timeout is activated and

for as long as the Flash is active, the SP7682 charge

pump will operate in 2x mode in order to provide the

continuous voltage and high current needed for Flash.

For the SP7682A, which uses the single wire interface,

the Flash channel will be in 2x mode whenever the Flash

current is at least 230mA.

The charge pump used in the heart of the design is a

regulated charge pump and regulates the minimum of

the LEDx outputs and FLASH output to be 350mV

typical. Regulated output voltage depends on the

forward voltage drop of the external LEDs used. The

The SP7682 and SP7682A are furnished with under-

voltage lockout, current limit, thermal shutdown and over

voltage protection features.

Sept 27-07 rev G

SP7682: Backlight and Flash Driver

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6

TYPICAL PERFORMANCE CHARACTERISTICS

VIN = 3.6V, Typical Application Circuit, TA = 25°C unless otherwise noted.

OUT

Backlight & Flash V Efficiency

OUT

Backlight V Efficiency

100

95

90

85

80

75

70

65

60

55

50

100

95

90

85

80

75

70

65

60

55

50

4LEDs=20mA,Flash=0mA

4LEDs=20mA,Flash=100mA

4LEDs=20mA,Flash=200mA

4LEDs=15mA

4LEDs=20mA

4LEDs=25mA

3.0

3.3

3.6

Vin (V)

3.9

4.2

3.0

3.3

3.6

Vin (V)

3.9

4.2

IN

Backlight & Flash Output Current Vs V

IN

Backlight Output Current Vs V

300

250

200

150

100

50

110

100

90

4LEDs=20mA,Flash=0mA

4LEDs=20mA,Flash=100mA

4LEDs=20mA,Flash=200mA

80

4LEDs=15mA

4LEDs=20mA

4LEDs=25mA

70

60

50

3.0

3.3

3.6

Vin (V)

3.9

3.0

3.3

3.6

Vin (V)

3.9

4.2

Backlight LED Efficiency

Backlight & Flash LED Efficiency

100

95

90

85

80

75

70

65

60

55

50

100

95

90

85

80

75

70

65

60

55

50

4LEDs=15mA

4LEDs=20mA

4LEDs=25mA

4LEDs=20mA,Flash=0mA

4LEDs=20mA,Flash=100mA

4LEDs=20mA,Flash=200mA

3.0

3.3

3.6

Vin (V)

3.9

4.2

3.0

3.3

3.6

Vin (V)

3.9

Sept 27-07 rev G

SP7682: Backlight and Flash Driver

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TYPICAL PERFORMANCE CHARACTERISTICS

VIN = 3.6V, Typical Application Circuit, TA = 25°C unless otherwise noted.

I_OUT

IN

Vs V

Flash PWF4 2x Timeout Mode,

500

400

300

200

100

Vin(AC)

Vout(AC)

Flash=500mA2xTimeout Mode

Flash=400mA2xTimeout Mode

Flash=300mA2xTimeout Mode

Flash=200mAAuto Mode

3.0

3.3

3.6

Vin (V)

3.9

4.2

400mA 2x Timeout Mode Ripple

I_OUT

IN

Vs V

Flash PWF4 1.5x Mode Forced,

Flash=500mA1.5xForced Mode

Flash=400mA1.5xForced Mode

500

Flash=300mA1.5xForced Mode

Flash=200mA1.5xForced Mode

Vin(AC)

400

300

200

100

Vout(AC)

3.0

3.3

3.6

Vin (V)

3.9

4.2

400mA Forced 1.5x Mode Ripple

I

OUT

IN

Vs V

Flash PWF4 Auto Mode,

500

400

300

200

100

Vin(AC)

Vout(AC)

Flash=500mAAuto Mode

Flash=400mAAuto Mode

Flash=300mAAuto Mode

Flash=200mAAuto Mode

3.0

3.3

3.6

Vin (V)

3.9

4.2

400mA Auto Mode 1.5x to 2x Mode Ripple

Sept 27-07 rev G

SP7682: Backlight and Flash Driver

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TYPICAL PERFORMANCE CHARACTERISTICS

VIN = 3.6V, Typical Application Circuit, TA = 25°C unless otherwise noted.

Ch1=EN

Ch2=Vout

Ch4=Iin

0.2A/div

Ch4=Iin

0.2A/div

LEDs = 20mA 1x Startup from Shutdown

LEDs = 20mA 1.5x Startup from Shutdown

Ch1=EN

Ch2=Vout

Ch4=Iin

0.2A/div

Ch4=Iin

0.2A/div

Flash = 200mA 1x Startup from Shutdown

Flash = 200mA 1.5x Startup from Shutdown

Ch1=EN

Ch2=Vout

Ch4=Iin

0.2A/div

Ch4=Iin

0.2A/div

Flash = 300mA 2x Timeout Startup from SHDN

Flash = 400mA 2x Timeout Startup from SHDN

Sept 27-07 rev G

SP7682: Backlight and Flash Driver

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TYPICAL PERFORMANCE CHARACTERISTICS

VIN = 3.6V, Typical Application Circuit, TA = 25°C unless otherwise noted.

Ch1=SET_BL

Ch2=Vout

Ch4=Iin

0.2A/div

Ch4=Iin

0.2A/div

SP7682A SET_BL=41 Pulses LEDs=20mA 1x

SP7682A SET_BL=41 Pulses LEDs=20mA, 1.5x

Ch1=SET_FL

Ch2=Vout

Ch4=Iin

0.2A/div

Ch4=Iin

0.2A/div

SP7682A SET_FL=31 Pulses Flash=0.3A 1x

SP7682A SET_FL=31 Pulses Flash = 0.3A 2x

Ch1=SET_FL

Ch2=Vout

Ch4=Iin

0.2A/div

Ch4=Iin

0.2A/div

SP7682A SET_FL=31 Pulses Flash=0.3A 2s

SP7682 TD0=TD1=0V Flash=0.3A 4s

Sept 27-07 rev G

SP7682: Backlight and Flash Driver

Page 10

TYPICAL PERFORMANCE CHARACTERISTICS

VIN = 3.6V, Typical Application Circuit, TA = 25°C unless otherwise noted.

IN

20mABacklight Output Current Vs V

22

21

20

19

18

LED1

LED2

LED3

LED4

Ch1=Vin

Ch2=Vout

3.0

3.3

3.6

Vin (V)

3.9

4.2

20mA Backlight: 1.5x Mode Ripple

Ch1=EN

Ch2=LEDx

Ch2=FLASH

Ch4=Iin

0.5A/div

Ch4=Iin

0.2A/div

Turn-off time into SHDN LEDs=20mA

Turn-off time into SHDN Flash=0.3A

Ch1=SCL

Ch2=Vout

Ch4=Iin

0.2A/div

Ch4=Iin

0.5A/div

Settle last count Standby LEDs=20mA 1x

Settle last count Standby LEDs=20mA 1.5x

Sept 27-07 rev G

SP7682: Backlight and Flash Driver

Page 11

APPLICATIONS INFORMATION

I²C Specifications

device as the slave. The master will always initiate a

data transfer and will provide the serial clock for

synchronization.

The I²C protocol defines any device that sends data

to the bus as a transmitter and any device that reads

the data as a receiver. The device that controls the

data transfer is known as the master and the other

Data input format:

S

SP7682 Address

7-bit

A

Data for

Status1

8-bit

A

Data for

Status2

8-bit

A

Data

For

LED

8-bit

A

Data

for

Flash

8-bit

A

SP

^R/W

1/0

Stop

condition

Acknowledge,

sent by slave

Acknowledge, sent by slave when R/W =0

Or, sent by master when R/W =1

Start

Condition

SP7682 I²C Slave Address Map: (7-bit Default Address: 0x28)

Fuses Device Address

7-bit

address

Hex

R/W

1/0

Fuse1

Fuse0

A7

0

A6

1

A5

A4

1

A3

A2

0

A1

0

A0

0

A7-A1

0

1

0

1

0

1

0

1

0

0x28

0x20

0x38

0x30

0

1

0

1

0

1

0

Theory of Operation - I²C Serial Interface

Temperature OK, Voltage OK, and Flash time-out

expired conditions. After the Flash timeout has

expired the FTO bit will toggle on and then off for

intervals set by the TDO bits. The next two registers

are used to set the brightness levels of the backlight

LEDs and Flash LED.

The SP7682 has four data registers which can be

programmed serially via the I²C interface. The first

register is a status register which has two bits used

for shutdown/power up options, 4 bits used for

individual backlight LED ON/OFF control, and 2 bits

for charge pump mode.

The second STATUS

The register bits are as follows:

register contains settings of the FLASH time-out,

REGISTER

STATUS1

STATUS2

LEDS

B7

WZ

B6

WP

B5

PMP0

TD0

D3

B4

B3

LED0

TOK

D1

B2

LED1

VOK

D0

B1

LED2

FTO

dc

B0

LED3

dc

PMP1

TD1

D2

TOUT0

D5

TOUT1

D4

dc

FLASH

D5

D4

D3

D2

D1

D0

dc

Sept 27-07 rev G

SP7682: Backlight and Flash Driver

Page 12

APPLICATIONS INFORMATION

The following table defines the states for bits PMP0 and

PMP1. These bits can be used to set the operating

mode for the internal charge pump.

The following table defines the states for bits TOUT0 and

TOUT1. These bits can be used to adjust current

threshold for the time-out feature in Flash mode.

PMP0 PMP1

State

TOUT0 TOUT1

State

0

1

0

1

0

1

Automatic mode detection.

0

1

Time-out disabled

Timeout enabled for 110mA

and above

Timeout enabled for 160mA

and above

Timeout enabled for 230mA

and above

1x mode only. 1.5x and 2x

modes are prohibited

1.5x mode only. 1x and 2x

modes are prohibited.

1x or 1.5x mode auto detection.

2x mode is prohibited.

1

0

1

The following table defines the states for bits TD0 and TD1.

These bits can be used to adjust time-out delay for the

time-out feature in Flash mode.

The following table defines the states for bits LED0 to

LED3. These bits can be used to turn LEDs On or OFF.

TD0 TD1

State

4s

0

1

0

1

0

1

LED0 LED1 LED2 LED3

State

2s

LED0 OFF, other

LEDs ON.

1

0

1

0

1s

LED1 OFF, other

LEDs ON.

0.5s

LED2 OFF, other

LEDs ON.

0

1

0

1

Addressing and Writing Data to the SP7682

LED3 OFF, other

LEDs ON.

To write data to the SP7682 one of the following two

cycles must be obeyed:

Easy shutdown/startup sequence

The following table defines the states for bits WZ and

WP. These bits can be used to put the SP7682 into

shutdown, standby or active.

[Slave Address with write bit][Data for Status]

Full shutdown/startup sequence

WZ

WP

State

[Slave Address with write bit][Data for Status1][Data for

Status2][Data for LEDs][Data for FLASH]

Shutdown, data registers are reset

to 000000

0

Shutdown, data registers are

unchanged

Standby. Output current is zero, data

registers are unchanged.

Active. Output current corresponds

to the register contents

0

1

0

1

Addressing and Reading Data from the SP7682

To read data from the SP7682 the following data cycle

must be obeyed:

[Slave Address with read bit][Data for Status1][Data for

Status2][Data

for

LEDs][Data

for

FLASH]

Sept 27-07 rev G

SP7682: Backlight and Flash Driver

Page 13

APPLICATIONS INFORMATION

DAC table for Backlight LED intensity

DAC table for FLASH LED intensity

In the LED register bits B7, B6, B5, B4, B3 and B2

represent the DAC codes D5-D0 used to set the LED

current in the four LEDs. The following table lists the

DAC codes and the corresponding current for each

channel in mA:

In the FLASH register bits B7, B6, B5, B4, B3 and B2

represent the DAC codes D5-D0 used to set the LED

current in the four LEDs. The following table lists the

DAC codes and the corresponding current for each

channel in mA:

BL

B7-B2 (mA)

Flash

(mA)

Flash

B7-B2 (mA)

000000

000001

000010

000011

000100

000101

000110

000111

001000

001001

001010

001011

001100

001101

001110

001111

010000

010001

010010

010011

010100

010101

010110

010111

011000

011001

011010

011011

011100

011101

011110

011111

0

100000

100001

100010

100011

100100

100101

100110

100111

101000

101001

101010

101011

101100

101101

101110

101111

110000

110001

110010

110011

110100

110101

110110

110111

111000

111001

111010

111011

111100

111101

111110

111111

16.0

16.5

17.0

17.5

18.0

18.5

19.0

19.5

20.0

20.5

21.0

21.5

22.0

22.5

23.0

23.5

24.0

24.5

25.0

25.5

26.0

26.5

27.0

27.5

28.0

28.5

29.0

29.5

30.0

30.5

31.0

31.5

B7-B2

000000

000001

000010

000011

000100

000101

000110

000111

001000

001001

001010

001011

001100

001101

001110

001111

010000

010001

010010

010011

010100

010101

010110

010111

011000

011001

011010

011011

011100

011101

011110

011111

0.5

0

100000

100001

100010

100011

100100

100101

100110

100111

101000

101001

101010

101011

101100

101101

101110

101111

110000

110001

110010

110011

110100

110101

110110

110111

111000

111001

111010

111011

111100

111101

111110

111111

320

330

340

350

360

370

380

390

400

410

420

430

440

450

460

470

480

490

500

1.0

10

1.5

20

2.0

30

2.5

40

3.0

50

3.5

60

4.0

70

4.5

80

5.0

90

5.5

100

110

120

130

140

150

160

170

180

190

200

210

220

230

240

250

260

270

280

290

300

310

6.0

6.5

7.0

7.5

8.0

8.5

9.0

9.5

10.0

10.5

11.0

11.5

12.0

12.5

13.0

13.5

14.0

14.5

15.0

15.5

Sept 27-07 rev G

SP7682: Backlight and Flash Driver

Page 14

SP7682A APPLICATIONS INFORMATION

SP7682A Single Line Programmable Serial

Interface

Backlight Code Table (programmed via SETBL)

BL

code (mA) code (mA) code (mA)

SET_FL (or SET_BL) pin programming waveform

shown below:

1

2

0

0.5

1

22

23

24

25

26

27

28

29

30

31

32

33

34

35

36

37

38

39

40

41

42

10.5

11

43

44

45

46

47

48

49

50

51

52

53

54

55

56

57

58

59

60

61

62

63

64

21

21.5

22

EN

3

11.5

12

4

1.5

2

22.5

23

SET_FL

5

12.5

13

t_LO=0.5us to 0.25ms

t_SHDN=0.5ms

shutdown

t_HI=0.5us min

6

2.5

3

23.5

24

7

13.5

14

8

3.5

4

24.5

25

40mA

9

14.5

15

10mA

10

11

12

13

14

15

16

17

18

19

20

21

4.5

5

25.5

26

0mA

I_FLASH

15.5

16

5.5

6

26.5

27

In the above example code 5 is programmed as

there are five rising edges.

16.5

17

6.5

7

27.5

28

17.5

18

Serially Programmable Codes

7.5

8

28.5

29

18.5

19

Flash Code Table (programmed via SETFL)

8.5

9

29.5

30

Flash

code (mA) code

Flash

(mA)

Flash

code (mA)

19.5

20

9.5

10

30.5

31

1

2

0

18

19

20

21

22

23

24

25

26

27

28

29

30

31

32

33

34

170

180

190

200

210

220

230

240

250

260

270

280

290

300

310

320

330

35

36

37

38

39

40

41

42

43

44

45

46

47

48

49

50

51

340

350

360

370

380

390

400

410

420

430

440

450

460

470

480

490

500

20.5

10

31.5

3

20

4

30

5

40

6

50

7

60

8

70

9

80

10

11

12

13

14

15

16

17

90

100

110

120

130

140

150

160

Sept 27-07 rev G

SP7682: Backlight and Flash Driver

Page 15

APPLICATIONS INFORMATION

LED Selection

here for reference. The second case of LED

power efficiency is included to show the user the

true power delivered to the LEDs. As one can

see in the curves, the LED efficiency is greatest

when VIN is higher than the VF of the LEDs (and

higher than the voltage required on the constant

current-sink outputs of the LEDs) and that is

when the SP7682 is in the 1x mode. When VIN

is less than the VF (and less than the voltage

required on the constant current-sink outputs of

the LEDs) the SP7682 is in the 1.5x mode or 2x

mode and in these modes the input current is

1.5 times or 2 times the output current and

therefore the efficiency will be reduced.

The SP7682 is designed as a driver for backlight

white LEDs and Flash white LEDs, but is

capable of driving other LED types with forward

voltage specifications ranging from 2.0V to 3.8V.

LED applications may include LCD display

backlighting, camera photo-flash applications,

infrared (IR) diodes for remotes, and other loads

benefiting from a controlled output current

generated from a varying input voltage. Since

the D1 to D4 output current-sinks are matched

with negligible voltage dependence, the LED

brightness will be matched regardless of the

specific LED forward voltage (VF) levels. In flash

applications, it may be necessary to drive high-

VF type LEDs. The typical characteristic curves

illustrate low VF Flash LEDs using the Lumi-

LEDs PWF4 LED, but the low dropout current-

sinks in the SP7682 make it capable of driving

LEDs with forward voltages as high as 4.0V from

an input supply as low as 3.2V but at a reduced

output current.

VOUT efficiency = VOUT•IOUT/(VIN•IIN)•100%

LED efficiency =

(VOUT -VLED) •IOUt/(VIN•IIN)•100%

Refer to the Typical Characteristics section of

this document for measured plots of efficiency

versus input voltage and output load current

versus input voltage for given LED output

current options.

Device Switching Noise Performance

The SP7682 operates at a fixed frequency of

approximately 2.4MHz to control noise and

limit harmonics that can interfere with the RF

operation of cellular telephone handsets or other

communication devices. Back-injected noise

appearing on the input pin of the charge pump

can be much less than 100mV peak-to-peak,

typically less than inductor-based DC/DC boost

converter white LED backlight solutions. The

SP7682 soft-start feature helps prevent noise

transient effects associated with inrush currents

during startup of the charge pump circuit.

Capacitor Characteristics

Ceramic composition capacitors are highly

recommended over all other types of capacitors

for use with the SP7682. Ceramic capacitors

offer many advantages over their tantalum and

aluminum electrolytic counterparts. A ceramic

capacitor has very low ESR, is lower in cost, has

a smaller PCB footprint, and is non-polarized.

Low ESR ceramic capacitors help to maximize

charge pump transient response. Since ceramic

capacitors are non-polarized, they are not prone

to incorrect connection damage.

Power Efficiency

The charge pump efficiency shown in the typical

characteristic curves is shown for two cases.

The first case is called output efficiency which is

the power efficiency to the output as a ratio of

the output voltage power to the input voltage

power and expressed as a percentage. The

second case is called LED efficiency and is the

power efficiency to the LED outputs and is

expressed as a ratio of the power to the LEDs to

the input voltage power. These expressions are

shown at the end of this section in their

formulas. The first case is what is generally

shown in competitors’ datasheets and is shown

Equivalent Series Resistance (ESR)

ESR is an important characteristic to consider

when selecting a capacitor. ESR is a resistance

internal to a capacitor that is caused by the

leads, internal connections, size or area,

material composition, and ambient temperature.

Capacitor ESR is typically measured in

milliohms for ceramic capacitors and can range

to more than several Ohms for tantalum or

aluminum electrolytic capacitors.

Sept 27-07 rev G

SP7682: Backlight and Flash Driver

Page 16

APPLICATIONS INFORMATION

Ceramic Capacitor Materials

can be 1μF for most applications for backlight

and Flash, and for light output currents flying

capacitors of 0.47uF can be used. For

applications when the 4 backlight LED drivers

are drive 20mA or more and the Flash driver is

driven to 100mA or more, it is advisable to use a

4.7μF input capacitor in order to reduce the input

ripple as seen by the battery. If the LED current-

sinks are only programmed for low current

levels, or if the application is not very noise

sensitive, then a 2.2μF input capacitor may be

used. See table 1 for capacitor selection.

Capacitors with large output values are typically

composed of X7R, X5R, Z5U, or Y5V dielectric

materials, but Z5U and Y5V are not

recommended since they have a large change in

value with temperature. X5R and X7R

capacitors are recommended since they are

relatively low in cost and their output value

changes with temperature are relatively small.

Capacitor Selection

Careful selection of the four external capacitors

CIN, C1, C2, and COUT is important because

they will affect turn-on time, output ripple, and

transient performance. Optimum performance

will be obtained when low equivalent series

resistance (ESR) ceramic capacitors are used.

In general, low ESR may be defined as less than

100mΩ. A value of 4.7μF for the input and 2.2μF

for the output capacitor is sufficient for most

applications. The flying capacitors C1 and C2

Thermal Protection

The SP7682 has a thermal protection circuit that

will shut down the internal LDO and charge

pump if the die temperature rises above the

thermal limit, and will restart when the die

temperature drops about 20°C below the

thermal limit.

Table 1: SP7682/SP7682A Capacitor Selection

Manufacturers/ Website

Part Number

Capacitance/

Voltage

Capacitor

Size/Type/Thickness

ESR at

100kHz

TDK/www.tdk.com

C1005X5R0J474K

C1005X5R0J105K

C1608X5R0J225K

0.47uF/6.3V

1uF/6.3V

2.2uF/6.3V

4.7uF/6.3V

0.47uF/6.3V

1uF/6.3V

0402/X5R/0.55mm

0603/X5R/0.9mm

0402/X5R/0.55mm

0603/X5R/0.55mm

0603/X5R/0.8mm

0.05

0.03

0.02

0.05

0.03

0.02

TDK/www.tdk.com

C1608X5R0J475K

Murata/www.murata.com

GRM155R60J474KE19

GRM155R60J105KE19

GRM185R60J225KE26

GRM188R60J475KE19

2.2uF/6.3V

4.7uF/6.3V

FOOTPRINT: 3x3mm 16 pin QFN

Sept 27-07 rev G

SP7682: Backlight and Flash Driver

Page 17

PACKAGE: 3x3mm 16 pin QFN

Sept 27-07 rev G

SP7682: Backlight and Flash Driver

Page 18

ORDERING INFORMATION

Control

Interface Temp ºC Temp ºC

Min

Max

Theta JA

ºC/W

Part Number

RoHS

MSL Level

L3 @ 260ºC

L3 @ 260ºC Tape & Reel

Pack Type Quantity Package

3x3 16 Pin

I²C

SP7682ER1-L

-40

85

Yes

33.3

Canister

Any

QFN

3x3 16 Pin

QFN

SP7682ER1-L/TR

SP7682EB

-40

85

3000

I²C

Single

Wire

Single

Wire

Single

Wire

Not Applicable to Eval Board

Board

3x3 16 Pin

QFN

SP7682AER1-L

Yes

33.3

L3 @ 260ºC

Canister

Any

SP7682AER1-

L/TR

3x3 16 Pin

QFN

-40

85

L3 @ 260ºC Tape & Reel

3000

Not Applicable to Eval Board

SP7682AEB

Board

For further assistance:

Email:

Sipexsupport@sipex.com

WWW Support page:

Application Notes:

http://www.sipex.com/content.aspx?p=support

http://www.sipex.com/applicationNotes.aspx

EXAR Corporation reserves the right to make changes to the products contained in this publication in order to improve design, performance or

reliability. EXAR Corporation assumes no responsibility for the use of any circuits described herein, conveys no license under any patent or other right,

and makes no representation that the circuits are free of patent infringement. Charts and schedules contained here in are only for illustration purposes

and may vary depending upon a user’s specific application. While the information in this publication has been carefully checked; no responsibility,

however, is assumed for inaccuracies.

EXAR Corporation does not recommend the use of any of its products in life support applications where the failure or malfunction of the product can

reasonably be expected to cause failure of the life support system or to significantly affect its safety or effectiveness. Products are not authorized for

use in such applications unless EXAR Corporation receives, in writing, assurances to its satisfaction that: (a) the risk of injury or damage has been

minimized; (b) the user assumes all such risks; (c) potential liability of EXAR Corporation is adequately protected under the circumstances.

Sept 27-07 rev G

SP7682: Backlight and Flash Driver

Page 19


型号：	SP7682EB
厂家：	EXAR CORPORATION
描述：	Backlight and Flash Driver in QFN 3mm x 3mm 背光和闪光的QFN封装采用3mm x 3mm驱动程序驱动
文件：	总19页 (文件大小：513K)
中文：	中文翻译
下载：	下载PDF数据表文档文件

SP7682EB [EXAR]

相关型号：

SP7682ER1-L

SP7682ER1-L

SP7682ER1-L/TR

SP7682ER1-L/TR

SP7682ER1-TR

SP7683

SP7683ER

SP7683ER-L

SP7683ER-L

SP7683ER-L/TR

SP7683ER/TR

SP7683ER/TR-L