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LM36923H

ZHCSEM6A –FEBRUARY 2016–REVISED FEBRUARY 2016

LM36923H 高效三串白色 LED 驱动器

1 特性

3 说明

1

•

整个过程、电压、温度范围内的灌电流匹配度为

1%

LM36923H 是一款专为 LCD 显示屏背光照明而设计的

超紧凑型、高效三串白色 LED 驱动器。该器件最多可

为 12 个串联 LED 供电，每条灯串的电流高达

25mA。该器件采用自适应电流调节方法，可在保持电

流稳定的同时为每个灯串提供不同的 LED 电压。

•

整个过程、电压、温度范围内的灌电流精度为 3%

11 位调光分辨率

解决方案效率最高可达 90%

在电压高达 38V、每条灯串的电流为 25mA 的条件

下，可驱动一至三条并行发光二极管 (LED) 灯串

LED 电流通过 I²C 接口或逻辑电平 PWM 输入进行调

节。PWM 占空比在内部进行感测并映射到一个 11 位

电流，从而提供宽 PWM 频率范围并在 50µA 至 25mA

范围内实现无噪声运行。

•

脉宽调制 (PWM) 调光输入

I²C 可编程

500kHz 和 1MHz 可选开关频率，可选频移为 -

12%

其他特性包括可根据负载电流自动更改频率的自动频

率模式，其作用是提升效率。

•

自动切换频率模式（250kHz、500kHz 和 1MHz）

四个可配置过压保护阈值（17V、24V、31V 和

38V）

该器件可在 2.5V 至 5.5V 输入电压范围内运行，其运

行温度范围为 -40°C 至 +85°C。

•

四个可配置过流保护阈值（750mA、1000mA、

1250mA 和

1500mA）

器件信息⁽¹⁾

器件型号

LM36923H

封装

封装尺寸（最大值）

•

热关断保护

通过 ASEL 输入在外部选择 I²C 地址选项

DSBGA (12)

1.756mm x 1.355mm

(1) 要了解所有可用封装，请参见数据表末尾的可订购产品附录。

2 应用

空格

空白

•

针对智能手机和平板电脑背光照明的电源

LED 最多可达 24 个的液晶显示屏 (LCD) 面板

简化电路原理图

灯串间匹配与 LED 电流间的典型关系

V_OUT(Up to 38V)

V_BATT

V_IO

SW

OVP

IN

LM36923H

HWEN

SDA

SCL

LED1

LED2

LED3

ASEL

PWM

GND

1

An IMPORTANT NOTICE at the end of this data sheet addresses availability, warranty, changes, use in safety-critical applications,

intellectual property matters and other important disclaimers. PRODUCTION DATA.

English Data Sheet: SNVSAF3

LM36923H

ZHCSEM6A –FEBRUARY 2016–REVISED FEBRUARY 2016

www.ti.com.cn

7.5 Programming........................................................... 24

7.6 Register Maps ........................................................ 25

Applications and Implementation ...................... 27

8.1 Application Information............................................ 27

8.2 Typical Application .................................................. 27

Power Supply Recommendations...................... 35

9.1 Input Supply Bypassing .......................................... 35

1

2

3

4

5

6

特性.......................................................................... 1

应用.......................................................................... 1

说明.......................................................................... 1

修订历史记录 ........................................................... 2

Pin Configuration and Functions......................... 3

Specifications......................................................... 4

6.1 Absolute Maximum Ratings ..................................... 4

6.2 ESD Ratings.............................................................. 4

6.3 Recommended Operating Conditions....................... 4

6.4 Thermal Information ................................................. 4

6.5 Electrical Characteristics........................................... 5

6.6 I²C Timing Requirements.......................................... 6

6.7 Typical Characteristics.............................................. 7

Detailed Description ............................................ 10

7.1 Overview ................................................................. 10

7.2 Functional Block Diagram ....................................... 10

7.3 Feature Description................................................. 11

7.4 Device Functional Modes........................................ 16

8

9

10 Layout................................................................... 35

10.1 Layout Guidelines ................................................. 35

10.2 Layout Example .................................................... 38

11 器件和文档支持 ..................................................... 39

11.1 器件支持................................................................ 39

11.2 商标....................................................................... 39

11.3 社区资源................................................................ 39

11.4 静电放电警告......................................................... 39

11.5 Glossary................................................................ 39

12 机械、封装和可订购信息....................................... 39

7

4 修订历史记录

注：之前版本的页码可能与当前版本有所不同。

Changes from Original (February 2016) to Revision A

Page

•

已更改器件状态“产品预览”至“量产数据” ................................................................................................................................ 1

2

LM36923H

www.ti.com.cn

ZHCSEM6A –FEBRUARY 2016–REVISED FEBRUARY 2016

5 Pin Configuration and Functions

YFF Package

12-Pin DSBGA

Top View

LED1

ASEL

SDA

SCL

GND

SW

A

B

C

D

LED2

LED3

VOUT

PWM

HWEN

IN

1

2

3

Pin Functions

I/O

DESCRIPTION

NUMBER

NAME

Input to current sink 1. The boost converter regulates the minimum voltage between LED1,

LED2, LED3 to VHR.

ASEL is a logic input which selects between two I²C address options. This pin is read on

power up (V_INgoing above 1.8 V, and HWEN going above a logic high voltage). GND =

address 0x36, logic high = address 0x37.

A1

LED1

Input

A2

ASEL

A3

B1

B2

B3

GND

LED2

SDA

SW

Input

I/O

Ground

Input pin to current sink 2. The boost converter regulates the minimum voltage between LED1,

LED2 ,LED3 to VHR.

Data I/O for I²C-Compatible Interface.

Drain connection for internal low side NFET, and anode connection for external Schottky

diode.

Output

Input pin to current sink 3. The boost converter regulates the minimum voltage between LED1,

LED2, LED3 to VHR.

Clock input for I²C-compatible interface.

C1

C2

C3

D1

D2

D3

LED3

SCL

Input

OUT serves as the sense point for overvoltage protection. Connect OUT to the positive pin of

the output capacitor.

OUT

PWM

HWEN

IN

Logic level input for PWM current control.

Hardware enable input. Drive HWEN high to bring the device out of shutdown and allow I²C

writes or PWM control.

Input voltage connection. Bypass IN to GND with a minimum 2.2-µF ceramic capacitor.

3

LM36923H

ZHCSEM6A –FEBRUARY 2016–REVISED FEBRUARY 2016

www.ti.com.cn

6 Specifications

6.1 Absolute Maximum Ratings

over operating free-air temperature range (unless otherwise noted)⁽¹⁾

MIN

–0.3

MAX

6

UNIT

IN

Input voltage

V

OUT

Output overvoltage sense input

Inductor connection

40

30

SW

LED1, LED2, LED3

LED string cathode connection

HWEN, PWM, SDA,

SCL, ASEL

Logic I/Os

–0.3

6

V

Maximum junction temperature, T_{J_MAX}

Storage temperature, T_stg

150

°C

–65

(1) Stresses beyond those listed under Absolute Maximum Ratings may cause permanent damage to the device. These are stress ratings

only, which do not imply functional operation of the device at these or any other conditions beyond those indicated under Recommended

Operating Conditions. Exposure to absolute-maximum-rated conditions for extended periods may affect device reliability.

6.2 ESD Ratings

VALUE

±2000

±500

UNIT

Human-body model (HBM), per ANSI/ESDA/JEDEC JS-001⁽¹⁾

Charged-device model (CDM), per JEDEC specification JESD22-C101⁽²⁾

Electrostatic

discharge

V_(ESD)

V

(1) JEDEC document JEP155 states that 500-V HBM allows safe manufacturing with a standard ESD control process. Pins listed as ±2000

V may actually have higher performance.

(2) JEDEC document JEP157 states that 250-V CDM allows safe manufacturing with a standard ESD control process. Pins listed as ±500 V

may actually have higher performance.

6.3 Recommended Operating Conditions

over operating free-air temperature range (unless otherwise noted)

MIN

2.5

0

MAX

5.5

UNIT

IN

Input voltage

V

OUT

Overvoltage sense input

Inductor connection

38

SW

0

38

LED1, LED2, LED3

LED string cathode connection

0

29.5

HWEN, PWM, SDA,

SCL, ASEL

Logic I/Os

0

5.5

V

6.4 Thermal Information

LM36923H

YFQ (DSBGA)

12 PINS

88.9

THERMAL METRIC⁽¹⁾

UNIT

R_θJA

Junction-to-ambient thermal resistance

°C/W

R_θJC(top)

R_θJB

Junction-to-case (top) thermal resistance

Junction-to-board thermal resistance

0.7

43.9

Ψ_θJT

Junction-to-top characterization parameter

Junction-to-board characterization parameter

2.9

Ψ_θJB

43.7

(1) For more information about traditional and new thermal metrics, see the Semiconductor and IC Package Thermal Metrics application

report, SPRA953.

4

LM36923H

www.ti.com.cn

ZHCSEM6A –FEBRUARY 2016–REVISED FEBRUARY 2016

6.5 Electrical Characteristics

Minimum and maximum limits apply over the full operating ambient temperature range (−40°C ≤ T_A≤ 85°C), typical values

are at T_A= 25°C, and V_IN= 3.6 V (unless otherwise noted).

PARAMETER

TEST CONDITIONS

MIN

–1%

–3%

TYP

MAX

1%

UNIT

BOOST

LED current matching I_LED150 µA ≤ I_LED≤ 25 mA, 2.7 V ≤ V_IN≤ 5 V (linear

to I_LED2to I_LED3

0.1%

(1)

I_MATCH

or exponential mode)

Absolute accuracy (I_LED1

,

50 µA ≤ I_LED≤ 25 mA, 2.7 V ≤ V_IN≤ 5 V (linear

or exponential mode)

Accuracy

I_{LED_MIN}

0.1%

3%

I_LED2, I_LED3

)

Minimum LED current (per

string)

50

25

µA

PWM or I²C current control (linear or

exponential mode)

I_{LED_MAX}

Maximum LED current (per

string)

mA

1/3

(0.3%)

R_DNL

IDAC ratio-metric DNL

exponential mode only

LSB

mV

I_LED= 25 mA

I_LED= 5 mA

210

100

Regulated current sink

headroom voltage

V_HR

Current sink minimum

headroom voltage

V_{HR_MIN}

I_LED= 95% of nominal, I_LED= 5 mA

V_IN= 3.7 V, I_LED= 5 mA/string, Typical

35

50

Efficiency

R_NMOS

Typical efficiency

87%

Application circuit (3x7 LEDs), (P_OUT/P_IN

)

NMOS switch on resistance I_SW= 250 mA

0.29

750

1000

1250

1500

17

Ω

OCP = 00

OCP = 01

OCP = 10

OCP = 11

OVP = 00

OVP = 01

OVP = 10

OVP = 11

575

860

1100

1350

16

875

1110

1400

1650

17.5

25

I_CL

NMOS switch current limit

2.7 V ≤ V_IN≤ 5 V

mA

23

24

Output overvoltage

protection

V_OVP

ON threshold, 2.7 V ≤ V_IN≤ 5 V

V

30

31

32

37

38

39

OVP

Hysteresis

0.5

Boost

frequency

select = 0

475

950

500

525

2.7 V ≤ V_IN≤ 5 V, boost

frequency

shift = 0

ƒ_SW

Switching frequency

kHz

Boost

frequency

select = 1

1000

1050

D_MAX

I_SHDN

Maximum boost duty cycle

Shutdown current

92%

94%

1.2

Chip enable bit = 0, SDA = SCL = IN or GND,

2.7 V ≤ V_IN≤ 5 V

5

µA

°C

Thermal shutdown

Hysteresis

135

15

T_SD

PWM INPUT

Min ƒ_PWM

50

Hz

Max ƒ_PWM

Sample rate = 24 MHz

Sample rate = 4 MHz

Sample rate = 800 kHz

Sample rate = 24 MHz

Sample rate = 4 MHz

Sample rate = 800 kHz

50

kHz

183.3

1100

5500

183.3

1100

5500

t_{MIN_ON}

Minimum pulse ON time

Minimum pulse OFF time

ns

t_{MIN_OFF}

(1) LED Current Matching between strings is given as the worst case matching between any two strings. Matching is calculated as ((I_LEDX

I_LEDY)/(I_LEDX+ I_LEDY)) × 100.

–

5

LM36923H

ZHCSEM6A –FEBRUARY 2016–REVISED FEBRUARY 2016

www.ti.com.cn

Electrical Characteristics (continued)

Minimum and maximum limits apply over the full operating ambient temperature range (−40°C ≤ T_A≤ 85°C), typical values

are at T_A= 25°C, and V_IN= 3.6 V (unless otherwise noted).

PARAMETER

TEST CONDITIONS

MIN

TYP

MAX

UNIT

PWM input active, PWM = logic high,HWEN

input from low to high, ƒ_PWM= 10 kHz (50% duty

cycle)

Turnon delay from

shutdown to backlight on

t_START-UP

3.5

5

ms

1.6 kHz ≤ ƒ_PWM≤ 12 kHz, PWM hysteresis = 00,

PWM sample rate = 11

PWM_RES

PWM input resolution

11

bits

V

V_IH

V_IL

Input logic high

Input logic low

HWEN, ASEL, SCL, SDA, PWM inputs

PWM pulse filter = 00

1.25

0

V_IN

0.4

0

100

150

200

0.6

3

15

PWM pulse filter = 01

60

90

140

210

280

0.66

3.3

t_GLITCH

PWM input glitch rejection

PWM shutdown period

ns

PWM pulse filter = 10

PWM pulse filter = 11

120

0.54

2.7

Sample rate = 24 MHz

t_{PWM_STBY}

Sample rate = 4 MHz

ms

Sample rate = 800 kHz

22.5

25

27.5

6.6 I²C Timing Requirements

See Figure 1

MIN

2.5

100

0

MAX

UNIT

t1

t2

t3

t4

t5

SCL clock period

µs

ns

Data in setup time to SCL high

Data out stable after SCL low

SDA low Setup Time to SCL low (start)

SDA high hold time after SCL high (stop)

100

t₁

SCL

t₅

t₄

SDA_IN

SDA_OUT

t₂

t₃

Figure 1. I2C Timing

6

LM36923H

www.ti.com.cn

ZHCSEM6A –FEBRUARY 2016–REVISED FEBRUARY 2016

6.7 Typical Characteristics

0.53

0.525

0.52

17.3

17.2

17.1

17.0

16.9

16.8

16.7

16.6

16.5

16.4

16.3

MAX -40 degC

MAX 30 degC

MAX 85 degC

MAX 125 degC

MIN -40 degC

MIN 30 degC

MIN 85 degC

MIN 125 degC

0.515

0.51

-40 degC

30 degC

85 degC

125 degC

0.505

VIN (V)

C001

Figure 3. 17-V OVP Threshold

Figure 2. OVP Hysteresis

24.3

24.2

24.1

24.0

23.9

23.8

23.7

23.6

23.5

23.4

23.3

MAX -40 degC

MAX 30 degC

MAX 85 degC

MAX 125 degC

MIN -40 degC

MIN 30 degC

MIN 85 degC

MIN 125 degC

MAX -40 degC

MAX 30 degC

MAX 85 degC

MAX 125 degC

MIN -40 degC

MIN 30 degC

MIN 85 degC

MIN 125 degC

31.3

31.1

30.9

30.7

30.5

30.3

VIN (V)

C001

Figure 4. 24-V OVP Threshold

Figure 5. 31-V OVP Threshold

38.6

38.4

38.2

38.0

37.8

37.6

37.4

37.2

0.45

0.4

MAX -40 degC

MAX 30 degC

MAX 85 degC

MAX 125 degC

MIN -40 degC

MIN 30 degC

MIN 85 degC

MIN 125 degC

0.35

0.3

0.25

0.2

0.15

0.1

125 degC

85 degC

30 degC

-40 degC

0.05

0

VIN (V)

C001

Figure 6. 38-V OVP Threshold

Figure 7. RDSON

7

LM36923H

ZHCSEM6A –FEBRUARY 2016–REVISED FEBRUARY 2016

www.ti.com.cn

Typical Characteristics (continued)

3.5

3

2.5

2

125 degC

85 degC

30 degC

3

-40 degC

2.5

2

1.5

1

1.5

1

125 degC

85 degC

30 degC

-40 degC

0.5

0

0.5

0

VIN (V)

C001

HWEN = GND

f_SW= 1 Mhz

No Load

Figure 8. Shutdown Current

Figure 9. I_QCurrent (Switching)

50

875

825

775

725

675

625

575

45

40

35

125 degC

-40 degC

30

25

20

30 degC

85 degC

125 degC

85 degC

30 degC

-40 degC

VIN (V)

C001

Open Loop

I_LED= 5 mA

Figure 11. 750-mA OCP Current

Figure 10. VHR MIN

1,110

1,060

1,010

960

1,400

1,350

1,300

1,250

1,200

1,150

1,100

-40 degC

30 degC

85 degC

125 degC

-40 degC

30 degC

85 degC

125 degC

910

860

VIN (V)

C001

Open Loop

Figure 13. 1250-mA OCP Current

Figure 12. 1000-mA OCP Current

8

LM36923H

www.ti.com.cn

ZHCSEM6A –FEBRUARY 2016–REVISED FEBRUARY 2016

Typical Characteristics (continued)

1,650

1,600

1,550

1,500

1,450

1,400

1,350

-40 degC

30 degC

85 degC

125 degC

VIN (V)

C001

Open Loop

Figure 14. 1500-mA OCP Current

9

LM36923H

ZHCSEM6A –FEBRUARY 2016–REVISED FEBRUARY 2016

www.ti.com.cn

7 Detailed Description

7.1 Overview

The LM36923H is an inductive boost plus three current sinks white-LED driver designed for powering from one to

three strings of white LEDs used in display backlighting. The device operates over the 2.5-V to 5.5-V input

voltage range. The 11-bit LED current is set via an I²C interface, via a logic level PWM input, or a combination of

both.

7.2 Functional Block Diagram

SW

Overvoltage

OVP

Protection

17V

IN

24V

32V

38V

HWEN

OVP

0.29 Ω

Boost Control

Fault Detection

Overvoltage

LED String Short

LED String Open

Current Limit

Thermal

Shutdown

135^oC

TSD

Boost Switching

Frequency

1MHz

Thermal Shutdown

800kHz

500kHz

400kHz

250kHz

200kHz

LED

Fault

OCP

Auto

Frequency

Mode

ASEL

I2C Address

Select

Boost Current

Limit

750mA

1000mA

1250mA

1500mA

SDA

SCL

I2C Interface

Min Headroom

Select

Adaptive

Headroom

Current Sinks

LED1

PWM Sample Rate

800kHz

11 Bit

Brightness

Code

LED2

LED3

LED Current

4MHz

24MHz

Mapping

Exponential

Linear

LED Current Ramping

No ramp

0.125ms/step

0.25ms/step

0.5ms/step

1ms/step

PWM

PWM Sampler

LED String

Enables

2ms/step

4ms/step

8ms/step

16ms/step

GND

10

LM36923H

www.ti.com.cn

ZHCSEM6A –FEBRUARY 2016–REVISED FEBRUARY 2016

7.3 Feature Description

7.3.1 Enabling the LM36923H

The LM36923H has a logic level input HWEN which serves as the master enable/disable for the device. When

HWEN is low the device is disabled, the registers are reset to their default state, the I²C bus is inactive, and the

device is placed in a low-power shutdown mode. When HWEN is forced high the device is enabled, and I²C

writes are allowed to the device.

7.3.1.1 Current Sink Enable

Each current sink in the device has a separate enable input. This allows for a 1-string, 2-string, or 3-string

application. The default is with three strings enabled. Once the correct LED string configuration is programmed,

the device can be enabled by writing the chip enable bit high (register 0x10 bit[0]), and then either enabling PWM

and driving PWM high, or writing a non-zero code to the brightness registers.

The default setting for the device is with the chip enable bit set to 1, PWM input enabled, and the device in linear

mapped mode. Therefore, on power up once HWEN is driven high, the device enters the standby state and

actively monitors the PWM input. After a non-zero PWM duty cycle is detected the LM36923H converts the duty

cycle information to the linearly weighted 11-bit brightness code. This allows for operation of the device in a

stand-alone configuration without the need for any I²C writes. Figure 15 and Figure 16 describe the start-up

timing for operation with both PWM controlled current and with I²C controlled current.

VIN

HWEN

PWM

ILED

t_{HWEN_PWM}

t_{PWM_DAC}

t_{DAC_LED}

t_{DD_LED}

t_{PWM_STBY}

Figure 15. Enabling the LM36923H via PWM

VIN

HWEN

I2C

I2C Registers In

Reset

I2C Brightness

Data Sent

I2C Data Valid

ILED

t_{HWEN_I2C}

t_{BRT_DAC}

t_{DAC_LED}

Figure 16. Enabling the LM36923H via I²C

11

LM36923H

ZHCSEM6A –FEBRUARY 2016–REVISED FEBRUARY 2016

www.ti.com.cn

Feature Description (continued)

7.3.2 LM36923H Start-Up

The LM36923H can be enabled or disabled in various ways. When disabled, the device is considered shutdown,

and the quiescent current drops to I_SHDN. When the device is in standby, it returns to the I_SHDNcurrent level

retaining all programmed register values. Table 1 describes the different operating states for the LM36923H.

Table 1. LM36923H Operating Modes

I²C BRIGHTNESS

LED CURRENT

LED STRING

ENABLES

0x10 bits[3:1]

BRIGHTNESS

MODE

DEVICE

ENABLE

0x10 bit[0]

REGISTERS

0x18 bits[2:0]

0x19 bits[7:0]

PWM INPUT

(EXP MAPPING)

0x11 bit[7] = 1

(LIN MAPPING)

0x11 bit[7] = 0

0x11 bits[6:5]

XXX

0

X

XXX

0

XX

00

0

1

Off, device disabled

Off, device standby

At least one

enabled

Off, device in standby

At least one

enabled

X

Code > 000

00

1

I_LED= 50 µA ×

1.003040572^Code

See⁽¹⁾

LED = 37.806 µA + 12.195

µA × Code

See⁽¹⁾

At least one

enabled

0

XXX

01

1

Off, device in standby

At least one

enabled

PWM Signal

I_LED= 50 µA ×

1.003040572^CodeSee⁽¹⁾

LED = 37.806 µA + 12.195

µA × Code

See⁽¹⁾

At least one

enabled

0

X

XXX

0

10 or 11

1

Off, device in standby

At least one

enabled

Off, device in standby

At least one

enabled

PWM Signal

Code > 000

I_LED= 50 µA ×

1.003040572^CodeSee⁽¹⁾

LED = 37.806 µA + 12.195

µA × Code

See⁽¹⁾

(1) Code is the 11-bit code output from the ramper (see Figure 21, Figure 23, Figure 25, Figure 27). This can be the I²C brightness code,

the converted PWM duty cycle or the 11-bit product of both.

7.3.3 Brightness Mapping

There are two different ways to map the brightness code (or PWM duty cycle) to the LED current: linear and

exponential mapping.

7.3.3.1 Linear Mapping

For linear mapped mode the LED current increases proportionally to the 11-bit brightness code and follows the

relationship:

+_.'&=37.806ä# +12.195ä#×%K@A

(1)

This is valid from codes 1 to 2047. Code 0 programs 0 current. Code is an 11-bit code that can be the I²C

brightness code, the digitized PWM duty cycle, or the product of the two.

7.3.3.2 Exponential Mapping

In exponential mapped mode the LED current follows the relationship:

+

_.'&= 50J# × 1.003040572^%K@A

(2)

This results in an LED current step size of approximately 0.304% per code. This is valid for codes from 1 to

2047. Code 0 programs 0 current. Code is an 11-bit code that can be the I²C brightness code, the digitized PWM

duty cycle, or the product of the two. Figure 17 details the LED current exponential response.

The 11-bit (0.304%) per code step is small enough such that the transition from one code to the next in terms of

LED brightness is not distinguishable to the eye. This therefore gives a perfectly smooth brightness increase

between adjacent codes.

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25

2.5

0.25

0.025

0

256

512

768

1024

1280

1536

1792

2048

C006

11 Bit Brightness Code

Figure 17. LED Current vs Brightness Code (Exponential Mapping)

7.3.4 PWM Input

The PWM input is a sampled input which converts the input duty cycle information into an 11-bit brightness code.

The use of a sampled input eliminates any noise and current ripple that traditional PWM controlled LED drivers

are susceptible to.

The PWM input uses logic level thresholds with V_{IH_MIN}= 1.25 V and V_{IL_MAX}= 0.4 V. Because this is a sampled

input, there are limits on the max PWM input frequency as well as the resolution that can be achieved.

7.3.4.1 PWM Sample Frequency

There are four selectable sample rates for the PWM input. The choice of sample rate depends on three factors:

1. Required PWM Resolution (input duty cycle to brightness code, with 11 bits max)

2. PWM Input Frequency

3. Efficiency

7.3.4.1.1 PWM Resolution and Input Frequency Range

The PWM input frequency range is 50 Hz to 50 kHz. To achieve the full 11-bit maximum resolution of PWM duty

cycle to the LED brightness code (BRT), the input PWM duty cycle must be ≥ 11 bits, and the PWM sample

period (1/ƒ_SAMPLE) must be smaller than the minimum PWM input pulse width. Figure 18 shows the possible

brightness code resolutions based on the input PWM frequency. The minimum PWM frequency for each PWM

sample rate is described in PWM Timeout.

12

24MHz

4MHz

800kHz

11

10

9

8

7

6

0.1kHz

1.0kHz

10.0kHz

Input PWM Frequency

C001

Figure 18. PWM Sample Rate, Resolution, and PWM Input Frequency

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7.3.4.1.2 PWM Sample Rate and Efficiency

Efficiency is maximized when the lowest ƒ_SAMPLEis chosen as this lowers the quiescent operating current of the

device. Table 2 describes the typical efficiency tradeoffs for the different sample clock settings.

Table 2. PWM Sample Rate Trade-Offs

PWM SAMPLE RATE

(ƒ_SAMPLE

TYPICAL INPUT CURRENT, DEVICE ENABLED

I_LED= 10 mA/string, 2 × 7 LEDs

TYPICAL EFFICIENCY

)

(0x12 Bits[7:6])

ƒ_SW= 1 MHz

1.03 mA

V_IN= 3.7 V

89.7%

0

1

1.05 mA

89.6%

1X

1.35 mA

89.4%

7.3.4.1.2.1 PWM Sample Rate Example

The number of bits of resolution on the PWM input varies according to the PWM Sample rate and PWM input

frequency.

Table 3. PWM Resolution vs PWM Sample Rate

PWM

FREQUENCY

(kHz)

RESOLUTION

(PWM SAMPLE RATE = 800 kHz)

RESOLUTION

(PWM SAMPLE RATE = 4 MHz)

RESOLUTION

(PWM SAMPLE RATE = 24 MHz)

0.4

2

11

8.6

6.1

11

12

8.4

7.3.4.2 PWM Hysteresis

To prevent jitter at the input PWM signal from feeding through the PWM path and causing oscillations in the LED

current, the LM36923H offers seven selectable hysteresis settings. The hysteresis works by forcing a specific

number of 11-bit LSB code transitions to occur in the input duty cycle before the LED current changes. Table 4

describes the hysteresis. The hysteresis only applies during the change in direction of brightness currents. Once

the change in direction has taken place, the PWM input must over come the required LSB(s) of the hysteresis

setting before the brightness change takes effect. Once the initial hysteresis has been overcome and the

direction in brightness change remains the same, the PWM to current response changes with no hysteresis.

Table 4. PWM Input Hysteresis

MIN CHANGE IN PWM

MIN (ΔI_LED), INCREASE FOR INITIAL CODE

PULSE WIDTH (Δt)

DUTY CYCLE (ΔD)

CHANGE

HYSTERESIS SETTING REQUIRED TO CHANGE REQUIRED TO CHANGE

(0x12 Bits[4:2])

LED CURRENT, AFTER

DIRECTION CHANGE

(for ƒ_PWM< 11.7 kHz)

LED CURRENT AFTER

DIRECTION CHANGE

EXPONENTIAL MODE

LINEAR MODE

000 (0 LSB)

001 (1 LSB)

010 (2 LSBs)

011 (3 LSBs)

100 (4 LSBs)

101 (5 LSBs)

110 (6 LSBs)

1/(ƒ_PWM× 2047)

1/(ƒ_PWM× 1023)

1/(ƒ_PWM× 511)

1/(ƒ_PWM× 255)

1/(ƒ_PWM× 127)

1/(ƒ_PWM× 63)

1/(ƒ_PWM× 31)

0.05%

0.10%

0.20%

0.39%

0.78%

1.56%

3.12%

0.30%

0.61%

1.21%

2.40%

4.74%

9.26%

17.66%

0.05%

0.10%

0.20%

0.39%

0.78%

1.56%

3.12%

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t_JITTER

D/f_PWM

1/f_PWM

ñ

D is t_JITTERx f_PWMor equal to #LSB‘s = ∆D x 2048 codes.

For 11-bit resolution, #LSBs is equal to a hysteresis setting of LN(#LSB‘s)/LN(2).

For example, with a t_JITTERof 1 µs and a f_PWMof 5 kHz, the hysteresis setting should be:

LN(1 µ s x 5 kHz x 2048)/LN(2) = 3.35 (4 LSBs).

Figure 19. PWM Hysteresis Example

7.3.4.3 PWM Step Response

The LED current response due to a step change in the PWM input is approximately 2 ms to go from minimum

LED current to maximum LED current.

7.3.4.4 PWM Timeout

The LM36923H PWM timeout feature turns off the boost output when the PWM is enabled and there is no PWM

pulse detected. The timeout duration changes based on the PWM Sample Rate selected which results in a

minimum supported PWM input frequency. The sample rate, timeout, and minimum supported PWM frequency

are summarized in Table 5.

Table 5. PWM Timeout and Minimum Supported PWM Frequency vs PWM Sample Rate

MINIMUM SUPPORTED PWM

SAMPLE RATE

TIMEOUT

FREQUENCY

0.8 MHz

4 MHz

25 msec

3 msec

48 Hz

400 Hz

24 MHz

0.6 msec

2000 Hz

7.3.5 LED Current Ramping

There are 8 programmable ramp rates available in the LM36923H. These ramp rates are programmable as a

time per step. Therefore, the ramp time from one current set-point to the next, depends on the number of code

steps between currents and the programmed time per step. This ramp time to change from one brightness set-

point (Code A) to the next brightness set-point (Code B) is given by:

:

;

¿P = 4=IL_N=PA× %K@A$F%K@A#F1

(3)

For example, assume the ramp is enabled and set to 1 ms per step. Additionally, the brightness code is set to

0x444 (1092d). Then the brightness code is adjusted to 0x7FF (2047d). The time the current takes to ramp from

the initial set-point to max brightness is:

1IO

OPAL

: ;

× 0T7(( F 0T444 F 1 = 954IO

¿P =

(4)

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7.3.6 Regulated Headroom Voltage

In order to optimize efficiency, current accuracy, and string-to-string matching the LED current sink regulated

headroom voltage (VHR) varies with the target LED current. Figure 20 details the typical variation of VHR with

LED current. This allows for increased solution efficiency as the dropout voltage of the LED driver changes.

Furthermore, in order to ensure that both current sinks remain in regulation whenever there is a mismatch in

string voltages, the minimum headroom voltage between VLED1, VLED2, VLED3 becomes the regulation point

for the boost converter. For example, if the LEDs connected to LED1 require 12 V, the LEDs connected to LED2

require 12.5 V , and the LEDs connected to LED3 require 13 V at the programmed current, then the voltage at

LED1 is VHR + 1 V, the voltage at LED2 is VHR + 0.5 V, and the voltage at LED3 is regulated at VHR. In other

words, the boost makes the cathode of the highest voltage LED string the regulation point.

240

220

200

180

160

140

120

100

80

LED Current (mA)

C001

Figure 20. LM36923H Typical Exponential Regulated Headroom Voltage vs Programmed LED Current

7.4 Device Functional Modes

7.4.1 Brightness Control Modes

The LM36923H has four brightness control modes:

1. I²C Only (brightness mode 00)

2. PWM Only (brightness mode 01)

3. I²C × PWM with ramping only between I²C codes (brightness mode 10)

4. I²C × PWM with ramping between I²C × PWM changes (brightness mode 11)

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Device Functional Modes (continued)

7.4.1.1 I²C Only (Brightness Mode 00)

In brightness control mode 00 the I²C Brightness registers are in control of the LED current, and the PWM input

is disabled. The brightness data (BRT) is the concatenation of the two brightness registers (3 LSBs) and (8

MSBs) (registers 0x18 and 0x19, respectively). The LED current only changes when the MSBs are written,

meaning that to do a full 11-bit current change via I²C, first the 3 LSBs are written and then the 8 MSBs are

written. In this mode the ramper only controls the time from one I²C brightness set-point to the next (see

Figure 21).

V_OUT

Boost

Digital Domain

Analog Domain

Min V_HR

RAMP_RATE Bits

I_LED3

I_LED1

I_LED2

Driver_1

BRT Code = I2C

Code

DAC_i

Driver_2

Driver_3

Ramper

Mapper

DAC

I2C Brightness Reg

MAP_MODE

RAMP_EN

Figure 21. Brightness Control 00 (I²C Only)

ILED_t1

Ramp Rate

t_RAMP

ILED_t0

t0

t1

1. At time t0 the I²C Brightness Code is changed from 0x444 (1092d) to 0x7FF (2047d)

2. Ramp Rate programmed to 1ms/step

3. Mapping Mode set to Linear

4. ILED_t0 = 1092 × 12.213 µA = 13.337 mA

5. ILED_t1 = 2047 × 12.213 µA = 25 mA

6. t_RAMP= (t1 – t0) = 1ms/step × (2047 – 1092 – 1) = 954 ms

Figure 22. I²C Brightness Mode 00 Example (Ramp Between I²C Code Changes)

7.4.1.2 PWM Only (Brightness Mode 01)

In brightness mode 01, only the PWM input sets the brightness. The I²C code is ignored. The LM36923 samples

the PWM input and determines the duty cycle; this measured duty cycle is translated into an 11-bit digital code.

The resultant code is then applied to the internal ramper (see Figure 23).

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Device Functional Modes (continued)

V_OUT

Boost

Digital Domain

Analog Domain

Min V_HR

I_LED3

I_LED1

I_LED2

RAMP_RATE Bits

Driver_1

Driver_2

Driver_3

BRT Code =

2047 × Duty Cycle

DAC_i

PWM Input

Ramper

Mapper

DAC

PWM Detector

MAP_MODE

RAMP_EN

Figure 23. Brightness Control 01 (PWM Only)

ILED_t1

Ramp Rate

t_RAMP

ILED_t0

t0

t1

1. At time t0 the PWM duty cycle changed from 25% to 100%

2. Ramp Rate programmed to 1 ms/step

3. Mapping Mode set to Linear

4. ILED_t0 = 25 mA × 0.25 = 6.25 mA

5. ILED_t1 = 25 mA × 1 = 25 mA

6. t_RAMP= (t1 – t0) = 1 ms/step × (2047 × 1 – 2047 × 0.25 – 1) = 1534 ms

Figure 24. Brightness Control Mode 01 Example (Ramp Between Duty Cycle Changes)

7.4.1.3 I²C + PWM Brightness Control (Multiply Then Ramp) Brightness Mode 10

In brightness control mode 10 the I²C Brightness register and the PWM input are both in control of the LED

current. In this case the I²C brightness code is multiplied with the PWM duty cycle to produce an 11-bit code

which is then sent to the ramper. In this mode ramping is achieved between I²C and PWM currents (see

Figure 25).

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Device Functional Modes (continued)

V_OUT

Boost

Digital Domain

Analog Domain

Min V_HR

RAMP_RATE Bits

I_LED3

I_LED1

I_LED2

Driver_1

Driver_2

Driver_3

BRT Code =

I2C × Duty Cycle

DAC_i

I2C Brightness Reg

Ramper

Mapper

DAC

MAP_MODE

RAMP_EN

PWM

Detector

PWM Input

Figure 25. Brightness Control 10 (I²C + PWM)

ILED_t1

Ramp Rate

t_RAMP

ILED_t0

t0

t1

1. At time t0 the I²C Brightness code changed from 0x444 (1092d) to 0x7FF (2047d)

2. At time t0 the PWM duty cycle changed from 50% to 75%

3. Ramp Rate programmed to 1ms/step

4. Mapping Mode set to Linear

5. ILED_t0 = 1092 × 12.213 µA × 0.5 = 6.668 mA

6. ILED_t1 = 2047 × 12.213 µA × 0.75 = 18.75 mA

7. t_RAMP= (t1 – t0) = 1 ms/step × (2047 × 0.75 – 1092 × 0.5 – 1) = 988 ms

Figure 26. Brightness Control Mode 10 Example (Multiply Duty Cycle then Ramp)

7.4.1.4 I²C + PWM Brightness Control (Ramp Then Multiply) Brightness Mode 11

In brightness control mode 11 both the I²C brightness code and the PWM duty cycle control the LED current. In

this case the ramper only changes the time from one I²C brightness code to the next. The PWM duty cycle is

multiplied with the I²C brightness code at the output of the ramper (see Figure 27).

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Device Functional Modes (continued)

V_OUT

Boost

Digital Domain

Analog Domain

Min V_HR

RAMP_RATE Bits

I_LED3

I_LED1

I_LED2

Driver_1

Driver_2

Driver_3

BRT Code =

I2C × Duty Cycle

DAC_i

I2C Brightness Reg

Ramper

Mapper

DAC

MAP_MODE

RAMP_EN

PWM Input

PWM Detector

Figure 27. Brightness Control 11 (I²C + PWM)

ILED_t1

ILED_t0+

Ramp

Rate

ILED_t0-

t_RAMP

t0

t1

1. At time t0 the I²C Brightness code changed from 0x444 (1092d) to 0x7FF (2047d)

2. At time t0 the PWM duty cycle changed from 50% to 75%

3. Ramp Rate programmed to 1 ms/step

4. Mapping Mode set to Linear

5. ILED_t0– = 1092 × 12.213 µA × 0.5 = 6.668 mA

6. ILED_t0+ = 1092 × 12.213 µA × 0.75 = 10.002 mA

7. t_RAMP= (t1 – t0) = 1 ms/step × (2047 – 1092 – 1) = 954 ms

Figure 28. Brightness Control Mode 11 Example (Ramp Current Then Multiply Duty Cycle)

7.4.2 Boost Switching Frequency

The LM36923H has two programmable switching frequencies: 500 kHz and 1 MHz. These are set via the Boost

Control 1 register 0x13 bit [5]. Once the switching frequency is set, this nominal value can be shifted down by

12% via the boost switching frequency shift bit (register 0x13 bit[6]). Operation at 500 kHz is better suited for

configurations which use a 10-µH inductor or use the auto-frequency mode and switch over to 500 kHz at lighter

loads. Operation at 1 MHz is primarily beneficial at higher output currents, where the average inductor current is

much larger than the inductor current ripple. For maximum efficiency across the entire load current range the

device incorporates an automatic frequency shift mode (see Auto-Switching Frequency).

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Device Functional Modes (continued)

7.4.2.1 Minimum Inductor Select

The LM36923H can use inductors in the range of 4.7 µH to 10 µH. In order to optimize the converter response to

changes in V_INand load, the Min Inductor Select bit (register 0x13 bit[4]) should be selected depending on which

value of inductance is chosen. For 10-µH inductors this bit should be set to 1. For less than 10 µH, this bit should

be set to 0.

7.4.3 Auto-Switching Frequency

To take advantage of frequency vs load dependent losses, the LM36923H has the ability to automatically change

the boost switching frequency based on the magnitude of the load current. In addition to the register

programmable switching frequencies of 500 kHz and 1 MHz, the auto-frequency mode also incorporates a low

frequency selection of 250 kHz. It is important to note that the 250-kHz frequency is only accessible in auto-

frequency mode and has a maximum boost duty cycle (D_MAX) of 50%.

Auto-frequency mode operates by using 2 programmable registers (Auto Frequency High Threshold (register

0x15) and Auto Frequency Low Threshold (0x16)). The high threshold determines the switchover from 1 MHz to

500 kHz. The low threshold determines the switchover from 500 kHz to 250 kHz. Both the High and Low

Threshold registers take an 8-bit code which is compared against the 8 MSB of the brightness register (register

0x19). Table 6 details the boundaries for this mode.

Table 6. Auto-Switching Frequency Operation

BRIGHTNESS CODE MSBs (Register 0x19 bits[7:0])

BOOST SWITCHING FREQUENCY

< Auto Frequency Low Threshold (register 15 Bits[7:0])

250 kHz (D_MAX= 50%)

> Auto Frequency Low Threshold (Register 15 Bits[7:0]) or < Auto

Frequency High Threshold (Register 14 Bits[7:0])

500 kHz

1 MHz

≥ Auto Frequency High Threshold (register 14 Bits[7:0])

Automatic-frequency mode is enabled whenever there is a non-zero code in either the Auto-Frequency High or

Auto-Frequency Low registers. To disable the auto-frequency shift mode, set both registers to 0x00. When

automatic-frequency select mode is disabled, the switching frequency operates at the programmed frequency

(Register 0x13 bit[5]) across the entire LED current range. Table 7 provides a guideline for selecting the auto-

frequency 250-kHz threshold setting; the actual setting needs to be verified in the application.

Table 7. Auto Frequency 250-kHz Threshold Settings

RECOMMENDED AUTO FREQUENCY

LOW THRESHOLD MAXIMUM VALUE

(NO SHIFT)

OUTPUT POWER AT AUTO

FREQUENCY SWITCHOVER

(W)

CONDITION

(V_ƒ= 3.2 V, I_LED= 25 mA)

INDUCTOR (µH)

3 × 4 LEDs

3 × 5 LEDs

3 × 6 LEDs

3 × 7 LEDs

3 × 8 LEDs

10

0x17

0x15

0x13

0x11

0x0f

0.079

0.089

0.097

0.101

0.102

7.4.4 I²C Address Select (ASEL)

The LM36923H provides two I²C slave address options. When ASEL = GND the slave address is set to 0x36.

When ASEL = VIN the slave address is set to 0x37. This static input pin is read on power up (VIN > 1.8 V and

HWEN > VIH) and must not be changed after power up.

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7.4.5 Fault Protection/Detection

7.4.5.1 Overvoltage Protection (OVP)

The LM36923H provides four OVP thresholds (17 V, 24 V, 32 V, and 38 V). The OVP circuitry monitors the boost

output voltage (V_OUT) and protects OUT and SW from exceeding safe operating voltages in case of open load

conditions or in the event the LED string voltage requires more voltage than the programmed OVP setting. The

OVP thresholds are programmed in register 13 bits[3:2]. The operation of OVP differentiates between two

overvoltage conditions (see Case 1 OVP Fault Only (OVP Threshold Hit and All Enabled Current Sink Inputs >

40 mV) , Case 1 OVP Fault Only (OVP Threshold Hit and All Enabled Current Sink Inputs > 40 mV) , and Case

2b OVP Fault and Open LED String Fault (OVP Threshold Duration and Any Enabled Current Sink Input ≤ 40

mV) ).

7.4.5.1.1 Case 1 OVP Fault Only (OVP Threshold Hit and All Enabled Current Sink Inputs > 40 mV)

In steady-state operation with V_OUTnear the OVP threshold a rapid change in V_INor brightness code can result in

a momentary transient excursion of V_OUTabove the OVP threshold. In this case the boost circuitry is disabled

until V_OUTdrops below OVP – hysteresis (1 V). Once this happens the boost is re-enabled and steady state

regulation continues. If V_OUTremains above the OVP threshold for > 1 ms the OVP Flag is set (register 0x1F

bit[0]).

7.4.5.1.2 Case 2a OVP Fault and Open LED String Fault (OVP Threshold Occurrence and Any Enabled Current Sink

Input ≤ 40 mV)

When any of the enabled LED strings is open the boost converter tries to drive V_OUTabove OVP and at the same

time the open string(s) current sink headroom voltage(s) (LED1, LED2, LED3) drop to 0. When the LM36923H

detects three occurrences of V_OUT> OVP and any enabled current sink input (V_LED1or V_LED2, V_LED3) ≤ 40 mV,

the OVP Fault flag is set (register 0x1F bit[0]), and the LED Open Fault flag is set (register 0x1F bit[4]).

7.4.5.1.3 Case 2b OVP Fault and Open LED String Fault (OVP Threshold Duration and Any Enabled Current Sink

Input ≤ 40 mV)

When any of the enabled LED strings is open the boost converter tries to drive V_OUTabove OVP and at the same

time the open string(s) current sink headroom voltage(s) (LED1, LED2, LED3) drop to 0. When the LM36923H

detects V_OUT> OVP for > 1 msec and any enabled current sink input (V_LED1or V_LED2, V_LED3) ≤ 40 mV, the OVP

Fault flag is set (register 0x1F bit[0]), and the LED Open Fault flag is set (register 0x1F bit[4]).

7.4.5.1.4 OVP/LED Open Fault Shutdown

The LM36923H has the option of shutting down the device when the OVP flag is set. This option can be enabled

or disabled via register 0x1E bit[0]. When the shutdown option is disabled the fault flag is a report only. When the

device is shut down due to an OVP/LED String Open fault, the fault flags register must be read back before the

LM36923H can be re-enabled.

7.4.5.1.5 Testing for LED String Open

The procedure for detecting an open in a LED string is:

•

Apply power the the LM36923H.

Enable all LED strings (Register 0x10 = 0x0F).

Set maximum brightness (Register 0x18 = 0x07 and Register 0x19 = 0xFF).

Set the brightness control (Register 0x11 = 0x00).

Open LED1 string.

Wait 4 msec.

Read LED open fault (Register 0x1F).

If bit[4] = 1, then a LED open fault condition has been detected.

Connect LED1 string.

Repeat the procedure for the other LED strings.

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7.4.5.2 Voltage Limitations on LED1, LED2, and LED3

The inputs to current sinks LED1, LED2 , and LED3 are rated for 30 V (absolute maximum voltage). This is lower

than the boost output capability as set by the OVP threshold (maximum specification) of 39 V. To ensure that the

current sink inputs remain below their absolute maximum rating, the LED configuration between LED1 or LED2

or LED3 must not have a voltage difference between strings so that VLED1/2/3 have a voltage greater than 30 V.

7.4.5.3 LED String Short Fault

The LM36923H can detect an LED string short fault. This happens when the voltage between V_INand any

enabled current sink input has dropped below (1.5 V). This test can only be performed on one LED string at a

time. Performing this test with more than one LED string enabled can result in a faulty reading. The procedure for

detecting a short in a LED string is:

•

Apply power the LM36923H.

Enable only LED1 string (Register 0x10 = 0x03).

Enable short fault (Register 0x1E = 0x01.

Set maximum brightness (Register 0x18 = 0x07 and Register 0x19 = 0xFF).

Set the brightness control (Register 0x11 = 0x00).

Wait 4 msec.

Read LED short fault (Register 0x1F).

If bit[3] = 1, then a LED short fault condition has been detected.

Set chip enable and LED string enable low (Register 0x10 = 0x00).

Repeat the procedure for the other LED strings.

7.4.5.4 Overcurrent Protection (OCP)

The LM36923H has four selectable OCP thresholds (750 mA, 1000 mA, 1250 mA, and 1500 mA). These are

programmable in register 0x13 bits[1:0]. The OCP threshold is a cycle-by-cycle current limit and is detected in

the internal low-side NFET. Once the threshold is hit the NFET turns off for the remainder of the switching period.

7.4.5.4.1 OCP Fault

If enough overcurrent threshold events occur, the OCP Flag (register 0x1F bit[1]) is set. To avoid transient

conditions from inadvertently setting the OCP Flag, a pulse density counter monitors OCP threshold events over

a 128-µs period. If 8 consecutive 128-µs periods occur where the pulse density count has found two or more

OCP events,then the OCP Flag is set.

During device start-up and during brightness code changes, there is a 4-ms blank time where OCP events are

ignored. As a result, if the device starts up in an overcurrent condition there is an approximate 5-ms delay before

the OCP Flag is set.

7.4.5.4.2 OCP Shutdown

The LM36923H has the option of shutting down the device when the OCP flag is set. This option can be enabled

or disabled via register 0x1E bit[1]. When the shutdown option is disabled, the fault flag is a report only. When

the device is shut down due to an OCP fault, the fault flags register must be read back before the LM36923H can

be re-enabled.

7.4.5.5 Device Overtemperature

Thermal shutdown (TSD) is triggered when the device die temperature reaches 135˚C. When this happens the

boost stops switching, and the TSD Flag (register 0x1F bit[2]) is set. The boost automatically starts up again

when the die temperature cools down to 120°C.

7.4.5.5.1 Overtemperature Shutdown

The LM36923H has the option of shutting down the device when the TSD flag is set. This option can be enabled

or disabled via register 0x1E bit[2]. When the shutdown option is disabled the fault flag is a report only. When the

device is shutdown due to a TSD fault, the Fault Flags register must be read back before the LM36923H can be

re-enabled.

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ZHCSEM6A –FEBRUARY 2016–REVISED FEBRUARY 2016

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7.5 Programming

7.5.1 I²C Interface

7.5.1.1 Start and Stop Conditions

The LM36923H is configured via an I²C interface. START (S) and STOP (P) conditions classify the beginning

and the end of the I²C session Figure 29. A START condition is defined as SDA transitioning from HIGH to LOW

while SCL is HIGH. A STOP condition is defined as SDA transitioning from LOW to HIGH while SCL is HIGH.

The I²C master always generates the START and STOP conditions. The I²C bus is considered busy after a

START condition and free after a STOP condition. During the data transmission the I²C master can generate

repeated START conditions. A START and a repeated START conditions are equivalent function-wise. The data

on SDA must be stable during the HIGH period of the clock signal (SCL). In other words, the state of SDA can

only be changed when SCL is LOW.

{5!

{/[

{

ꢀ

{tart /ondition

{top /ondition

Figure 29. I²C Start and Stop Conditions

7.5.1.2 I²C Address

The 7-bit chip address for the LM36923 is 0x36 with ASEL connected to GND and 0x37 with ASEL connected to

a logic high voltage. After the START condition the I²C master sends the 7-bit chip address followed by an eighth

bit read or write (R/W). R/W = 0 indicates a WRITE, and R/W = 1 indicates a READ. The second byte following

the chip address selects the register address to which the data is written. The third byte contains the data for the

selected register.

7.5.1.3 Transferring Data

Every byte on the SDA line must be eight bits long with the most significant bit (MSB) transferred first. Each byte

of data must be followed by an acknowledge bit (ACK). The acknowledge related clock pulse, (9th clock pulse),

is generated by the master. The master then releases SDA (HIGH) during the 9th clock pulse. The LM36923H

pulls down SDA during the 9th clock pulse, signifying an acknowledge. An acknowledge is generated after each

byte has been received.

7.5.1.4 Register Programming

For glitch free operation, the following bits and/or registers should only be programmed while the LED Enable

bits are 0 (Register 0x10, Bit [3:1] = 0) and Device Enable bit is 1 (Register 0x10, Bit[0] = 1) :

1. Register 0x11 Bit[7] (Mapping Mode)

2. Register 0x11 Bits[6:5] (Brightness Mode)

3. Register 0x11 Bit[4] (Ramp Enable)

4. Register 0x11 Bit[3:1] (Ramp Rate)

5. Register 0x12 Bits[7:6] (PWM Sample Rate)

6. Register 0x12 Bits[5] (PWM Polarity)

7. Register 0x12 Bit[3:2] (PWM Hysteresis)

8. Register 0x12 Bit[3:2] (PWM Pulse Filter)

9. Register 0x15 (auto frequency high threshold)

10. Register 0x16 (auto frequency low threshold)

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LM36923H

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ZHCSEM6A –FEBRUARY 2016–REVISED FEBRUARY 2016

7.6 Register Maps

Note: Read of reserved (R) or write-only register returns 0.

Table 8. Revision (0x00)

Bits [7:4]

Bits [3:0]

R

Revision Code

Table 9. Software Reset (0x01)

Software Reset

Bit [0]

Bits [7:1]

R

0 = Normal Operation

1 = Device Reset (automatically resets back to 0)

Table 10. Enable (0x10)

LED2

Enable

Bit [2]

LED1

Enable

Bit [1]

Device

Enable

Bit [0]

LED3 Enable

Bit [3]

Bits [7:4]

R

0 = Disabled

1 = Enabled

(Default)

0 =

Disabled

0 =

Disabled

0 =

Disabled

1 = Enabled 1 = Enabled 1 = Enabled

(Default)

Table 11. Brightness Control (0x11)

Brightness

Mapping Mode

Mode

Bits [6:5]

Ramp Enable

Bits [4]

Ramp Rate

Bit [3:1]

Bit [7]

Bits [0]

0 = Linear (default)

1 = Exponential

00 = Brightness

Register Only

01 = PWM Duty

Cycle Only

10 = Multiply

Then Ramp

(Brightness

Register ×

0 = Ramp Disabled (default)

1 = Ramp Enabled

000 = 0.125

ms/step

(default)

001 = 0.250

ms/step

010 = 0.5

ms/step

011 = 1

R

PWM)

ms/step

100 = 2

ms/step

101 = 4

ms/step

110 = 8

11 = Ramp

Then Multiply

(Brightness

Register ×

PWM) (default)

ms/step

111 = 16

ms/step

Table 12. PWM Control (0x12)

PWM Input

PWM Sample Rate

Bit [7:6]

Polarity

Bit [5]

PWM Hysteresis

PWM Pulse Filter

Bit [1:0]

Bits [4:2]

00 = 800 kHz

01 = 4 MHz

1X = 24 MHz (default)

0 = Active Low

1 = Active High

(default)

000 = None

001 = 1 LSB

00 = No Filter

01 = 100 ns

10 = 150 ns

010 = 2 LSBs

011 = 3 LSBs

100 = 4 LSBs (default)

101 = 5 LSBs

110 = 6 LSBs

111 = N/A

11 = 200 ns (default)

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LM36923H

ZHCSEM6A –FEBRUARY 2016–REVISED FEBRUARY 2016

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Table 13. Boost Control 1 (0x13)

Minimum

Inductor

Select

Overvoltage

Protection

(OVP)

Boost Switching

Frequency Shift

Bit [6]

Boost Switching Frequency

Current Limit

(OCP)

Bits [1:0]

Reserved

Bit [7]

Select

Bit [5]

Bit [4]

Bits [3:2]

N/A

0 = –12% Shift

1 =No Shift (default)

0 = 500 kHz

1 = 1 MHz (default)

0 = 4.7 µH

(default)

1 = 10 µH

00 = 17 V

01 = 24 V

10 = 31 V

11 = 38 V

(default)

00 = 750 mA

01 = 1000 mA

10 = 1250 mA

11 = 1500 mA

(default)

Table 14. Auto Frequency High Threshold (0x15)

Auto Frequency High Threshold (500 kHz to 1000 kHz)

Bits [7:0]

Compared against the 8 MSBs of 11-bit brightness code (default = 00000000).

Table 15. Auto Frequency Low Threshold (0x16)

Auto Frequency High Threshold (250 kHz to 500 kHz)

Bits [7:0]

Compared against the 8 MSBs of 11-bit brightness code (default = 00000000).

Table 16. Brightness Register LSBs (0x18)

I²C Brightness Code (LSB)

Bits [2:0]

Bits [7:3]

R

This is the lower 3 bits of the 11-bit brightness code (default = 111).

Table 17. Brightness Register MSBs (0x19)

I2C Brightness Code (MSB)

Bits [7:0]

This is the upper 8 bits of the 11-bit brightness code (default = 11111111).

Table 18. Fault Control (0x1E)

OVP/LED

Open

OCP

LED Short

Fault Enable

Bit [3]

Shutdown

Disable

Bit [1]

Shutdown

Disable

Bit [0]

Reserved

Bits [7:4]

TSD Shutdown Disable

Bit [2]

R

0 = LED Short 0 = When the TSD Flag is set, 0 = When the

0 = When

the OVP

Fault Detection

is disabled

the device is forced into

shutdown.

OCP Flag is

set, the device Flag is set,

(default).

1 = No shutdown (default)

is forced into

shutdown.

1 = No

shutdown

(default)

the device

is forced

into

shutdown.

1 = No

1 = LED Short

Fault Detection

is enabled

shutdown

(default)

Table 19. Fault Flags (0x1F)

LED Open

Fault

Bit [4]

LED Short

Fault

Bit [3]

OVP

Fault

Bit [0]

Reserved

Bits [7:5]

TSD Fault

Bit [2]

OCP Fault

Bit [1]

R

1 = LED

String Open

Fault

1 = LED

Short Fault

1 = Thermal Shutdown

Fault

1 = Current Limit

Fault

1 =

Output

Overvolta

ge Fault

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LM36923H

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ZHCSEM6A –FEBRUARY 2016–REVISED FEBRUARY 2016

8 Applications and Implementation

NOTE

Information in the following applications sections is not part of the TI component

specification, and TI does not warrant its accuracy or completeness. TI’s customers are

responsible for determining suitability of components for their purposes. Customers should

validate and test their design implementation to confirm system functionality.

8.1 Application Information

The LM36923H provides a complete high-performance LED lighting solution for mobile handsets. The LM36923H

is highly configurable and can support multiple LED configurations.

8.2 Typical Application

Figure 30. LM36923H Typical Application

8.2.1 Design Requirements

DESIGN PARAMETER

EXAMPLE VALUE

Minimum input voltage (V_IN

)

2.7 V

3 × 5

3.2 V

82%

LED parallel/series configuration

LED maximum forward voltage (V_ƒ)

Efficiency

The number of LED strings, number of series LEDs, and minimum input voltage are needed in order to calculate

the peak input current. This information guides the designer to make the appropriate inductor selection for the

application. The LM36923H boost converter output voltage (V_OUT) is calculated: number of series LEDs × V_ƒ+

0.23 V. The LM36923H boost converter output current (I_OUT) is calculated: number of parallel LED strings × 25

mA. The LM36923H peak input current is calculated using Equation 5.

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LM36923H

ZHCSEM6A –FEBRUARY 2016–REVISED FEBRUARY 2016

www.ti.com.cn

8.2.2 Detailed Design Procedure

Table 20. Typical Application Component List

CONFIGURATION

L1

D1

C_OUT

VLF504012MT-100M

VLF504012MT-150M

3p7s, 3p8s

NSR0530P2T5G

C2012X7R1H105K085AC

3p6s

3p5s

3p4s

VLF504012MT-220M

VLF403210MT-100M

VLF302510MT-100M

NSR0530P2T5G

C2012X7R1H105K085AC

8.2.2.1 Component Selection

8.2.2.1.1 Inductor

The LM36923H requires a typical inductance in the range of 4.7 µH to 10 µH. When selecting the inductor,

ensure that the saturation rating for the inductor is high enough to accommodate the peak inductor current of the

application (I_PEAK) given in the inductor datasheet. The peak inductor current occurs at the maximum load

current, the maximum output voltage, the minimum input voltage, and the minimum switching frequency setting.

Also, the peak current requirement increases with decreasing efficiency. I_PEAKcan be estimated using

Equation 5:

8₁₇₆× +₁₇₆

8

8 × h

8

176

+0

+

=

+

× l1 +

p

2'#-

8 ×

h

2 × B × .

+0

59

(5)

Also, the peak current calculated above is different from the peak inductor current setting (I_SAT). The NMOS

switch current limit setting (I_{CL_MIN}) must be greater than I_PEAKfrom Equation 5 above.

8.2.2.1.2 Output Capacitor

The LM36923H requires a ceramic capacitor with a minimum of 0.4 µF of capacitance at the output, specified

over the entire range of operation. This ensures that the device remains stable and oscillation free. The 0.4 µF of

capacitance is the minimum amount of capacitance, which is different than the value of capacitor. Capacitance

would take into account tolerance, temperature, and DC voltage shift.

Table 21 lists possible output capacitors that can be used with the LM36923H. Figure 31 shows the DC bias of

the four TDK capacitors. The useful voltage range is determined from the effective output voltage range for a

given capacitor as determined by Equation 6:

0.38µ(

&% 8KHP=CA &AN=PEJC R

:

;

:

;

1 F 6KH × 1 F 6AIL_?K

(6)

Table 21. Recommended Output Capacitors

RECOMMENDED MAX

OUTPUT VOLTAGE

(FOR SINGLE

NOMINAL

CAPACITANCE

(µF)

CASE

SIZE

VOLTAGE

RATING (V)

TEMPERATURE

COEFFICIENT (%)

PART NUMBER

MANUFACTURER

TOLERANCE (%)

CAPACITOR)

C2012X5R1H105K085AB

C2012X5R1H225K085AB

C1608X5R1V225K080AC

C1608X5R1H105K080AB

TDK

0805

0603

50

35

50

1

±10

±15

22

24

12

15

2.2

1

For example, with a 10% tolerance, and a 15% temperature coefficient, the DC voltage derating must be ≥ 0.38 /

(0.9 × 0.85) = 0.5 µF. For the C1608X5R1H225K080AB (0603, 50-V) device, the useful voltage range occurs up

to the point where the DC bias derating falls below 0.523 µF, or around 12 V. For configurations where V_OUTis >

15 V, two of these capacitors can be paralleled, or a larger capacitor such as the C2012X5R1H105K085AB must

be used.

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LM36923H

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ZHCSEM6A –FEBRUARY 2016–REVISED FEBRUARY 2016

2

1.9

1.8

1.7

1.6

1.5

1.4

1.3

1.2

1.1

1

C2012X5R1H105K085AB

C2012X5R1H225K085AB

C1608X5R1V225K080AC

C1608X5R1H105K080AB

0.9

0.8

0.7

0.6

0.5

0.4

0.3

0.2

0.1

0

2

4

6

8

10 12 14 16 18 20 22 24 26 28

C006

DC Bias

Figure 31. DC Bias Derating for 0805 Case Size and

0603 Case Size 35-V and 50-V Ceramic Capacitors

8.2.2.1.3 Input Capacitor

The input capacitor in a boost is not as critical as the output capacitor. The input capacitor primary function is to

filter the switching supply currents at the device input and to filter the inductor current ripple at the input of the

inductor. The recommended input capacitor is a 2.2-µF ceramic (0402, 10-V device) or equivalent.

29

LM36923H

ZHCSEM6A –FEBRUARY 2016–REVISED FEBRUARY 2016

www.ti.com.cn

8.2.3 Application Curves

L1 = 4.7 µH (VLF504012-4R7M) or 10 µH (VLF504015-100M) as noted in graphs, D1 = NSR240P2T5G, LEDs are Samsung

SPMWHT325AD5YBTMS0, temperature = 25°C, V_IN= 3.7 V, unless otherwise noted.

Two String, AF Enabled -12%, 10 uH, 3.7V

Three String, AF Enabled, 10 uH, 3.7V

95%

90%

85%

80%

75%

70%

65%

60%

95%

90%

85%

80%

75%

70%

65%

60%

2p4s

3p4s

2p6s

3p6s

2p8s

3p8s

2p10s

2p12s

3p10s

3p12s

LED CURRENT (mA)

C001

Figure 32. Boost Efficiency vs Series LEDs

Figure 33. Boost Efficiency vs Series LEDs

Two String, AF Enabled, 10 uH, 3.7V

95%

Three String, AF Enabled -12%, 10 uH, 3.7V

95%

90%

85%

80%

90%

85%

80%

75%

2p4s

3p4s

2p6s

3p6s

70%

65%

60%

70%

65%

60%

2p8s

3p8s

2p10s

2p12s

3p10s

3p12s

LED CURRENT (mA)

C001

Figure 34. Boost Efficiency vs Series LEDs

Figure 35. Boost Efficiency vs Series LEDs

Two String, 443kHz, 10 uH, 3.7V

90%

Three String, 443kHz, 10 uH, 3.7V

90%

85%

80%

85%

80%

75%

70%

75%

70%

2p4s

2p6s

3p4s

3p6s

2p8s

3p8s

65%

2p10s

3p10s

2p12s

3p12s

60%

LED CURRENT (mA)

C001

LED CURRENT (mA)

C001

Figure 37. Boost Efficiency vs Series LEDs

Figure 36. Boost Efficiency vs Series LEDs

30

LM36923H

www.ti.com.cn

ZHCSEM6A –FEBRUARY 2016–REVISED FEBRUARY 2016

L1 = 4.7 µH (VLF504012-4R7M) or 10 µH (VLF504015-100M) as noted in graphs, D1 = NSR240P2T5G, LEDs are Samsung

SPMWHT325AD5YBTMS0, temperature = 25°C, V_IN= 3.7 V, unless otherwise noted.

Two String, 500kHz, 10 uH, 3.7V

Three String, 500kHz, 10 uH, 3.7V

90%

85%

80%

75%

70%

65%

60%

90%

85%

80%

75%

70%

65%

60%

2p4s

3p4s

2p6s

3p6s

2p8s

3p8s

2p10s

2p12s

3p10s

3p12s

LED CURRENT (mA)

C001

LED CURRENT (mA)

C001

Figure 39. Boost Efficiency vs Series LEDs

Figure 38. Boost Efficiency vs Series LEDs

Two String, 887kHz, 10 uH, 3.7V

95%

Three String, 887kHz, 10 uH, 3.7V

95%

90%

85%

80%

90%

85%

80%

75%

70%

75%

70%

2p4s

2p6s

3p4s

3p6s

2p8s

3p8s

65%

60%

2p10s

2p12s

65%

60%

3p10s

3p12s

LED CURRENT (mA)

C001

LED CURRENT (mA)

C001

Figure 41. Boost Efficiency vs Series LEDs

Figure 40. Boost Efficiency vs Series LEDs

Two String, 1Mhz, 10 uH, 3.7V

95%

Three String, 1Mhz, 10 uH, 3.7V

95%

90%

85%

80%

90%

85%

80%

75%

70%

75%

70%

2p4s

2p6s

3p4s

3p6s

2p8s

3p8s

65%

60%

2p10s

2p12s

65%

60%

3p10s

3p12s

LED CURRENT (mA)

C001

LED CURRENT (mA)

C001

Figure 43. Boost Efficiency vs Series LEDs

Figure 42. Boost Efficiency vs Series LEDs

31

LM36923H

ZHCSEM6A –FEBRUARY 2016–REVISED FEBRUARY 2016

www.ti.com.cn

L1 = 4.7 µH (VLF504012-4R7M) or 10 µH (VLF504015-100M) as noted in graphs, D1 = NSR240P2T5G, LEDs are Samsung

SPMWHT325AD5YBTMS0, temperature = 25°C, V_IN= 3.7 V, unless otherwise noted.

Three String, 443kHz, 4.7 uH, 3.7V

Two String, 443kHz, 4.7 uH, 3.7V

90%

85%

80%

75%

70%

65%

90%

85%

80%

75%

70%

65%

2p12s

3p8s

2p10s

2p8s

2p6s

2p4s

3p6s

3p4s

LED CURRENT (mA)

C001

Figure 45. Boost Efficiency vs Series LEDs

Figure 44. Boost Efficiency vs Series LEDs

Three String, 500kHz, 4.7 uH, 3.7V

90%

Two String, 500kHz, 4.7 uH, 3.7V

90%

85%

80%

85%

80%

75%

70%

65%

2p12s

2p10s

2p8s

3p8s

3p6s

3p4s

70%

65%

2p6s

2p4s

LED CURRENT (mA)

C001

Figure 46. Boost Efficiency vs Series LEDs

Figure 47. Boost Efficiency vs Series LEDs

Three String, 887kHz, 4.7 uH, 3.7V

90%

Two String, 887kHz, 4.7 uH, 3.7V

90%

85%

80%

85%

80%

75%

2p12s

3p10s

2p10s

3p8s

2p8s

2p6s

2p4s

70%

65%

70%

3p6s

3p4s

65%

LED CURRENT (mA)

C001

Figure 49. Boost Efficiency vs Series LEDs

Figure 48. Boost Efficiency vs Series LEDs

32

LM36923H

www.ti.com.cn

ZHCSEM6A –FEBRUARY 2016–REVISED FEBRUARY 2016

L1 = 4.7 µH (VLF504012-4R7M) or 10 µH (VLF504015-100M) as noted in graphs, D1 = NSR240P2T5G, LEDs are Samsung

SPMWHT325AD5YBTMS0, temperature = 25°C, V_IN= 3.7 V, unless otherwise noted.

Three String, 1Mhz, 4.7 uH, 3.7V

Two String, 1Mhz, 4.7 uH, 3.7V

90%

85%

80%

75%

70%

65%

90%

85%

80%

75%

70%

65%

2p12s

3p10s

2p10s

2p8s

2p6s

2p4s

3p8s

3p6s

3p4s

LED CURRENT (mA)

C001

LED CURRENT (mA)

C001

Figure 50. Boost Efficiency vs Series LEDs

Figure 51. Boost Efficiency vs Series LEDs

100

25

Exponential

23

20

18

15

13

10

8

Linear

10

1

0.1

5

3

0

0.01

BRIGHTNESS CODE

C001

Figure 53. LED Current vs Brightness Code

Figure 52. LED Current vs Brightness Code (Exponential

Mapping)

0.80

Matching(1-2)

Matching(1-3)

Matching (2-3)

Matching(1-3)

Matching (2-3)

0.60

0.40

0.60

0.40

0.20

0.00

-0.20

-0.40

-0.60

-0.80

-0.20

-0.40

-0.60

-0.80

BRIGHTNESS CODE

C001

Figure 54. LED Matching (Exponential Mapping)

Figure 55. LED Matching (Linear Mapping)

33

LM36923H

ZHCSEM6A –FEBRUARY 2016–REVISED FEBRUARY 2016

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L1 = 4.7 µH (VLF504012-4R7M) or 10 µH (VLF504015-100M) as noted in graphs, D1 = NSR240P2T5G, LEDs are Samsung

SPMWHT325AD5YBTMS0, temperature = 25°C, V_IN= 3.7 V, unless otherwise noted.

Exponential Mapping, 25C, 3.7V

Linear Mapping, 25C, 3.7V

2.00

1.80

1.60

1.40

1.20

1.00

0.80

0.60

0.40

0.20

0.00

1.80

1.60

1.40

1.20

1.00

0.80

0.60

0.40

0.20

0.00

Accuracy I1

Accuracy I2

Accuracy I3

Accuracy I2

Accuracy I3

BRIGHTNESS CODE

C001

Figure 56. LED Current Accuracy

Figure 57. LED Current Accuracy

Exponential Mapping, 25C, 3.7V

Linear Mapping, 25C, 3.7V

0.35

0.30

0.25

0.20

0.15

0.10

0.05

0.00

0.35

0.30

0.25

0.20

0.15

0.10

0.05

0.00

VH1

VH2

VH3

VH1

VH2

VH3

BRIGHTNESS CODE

C001

Figure 58. LED Headroom Voltage (Mis-Matched Strings)

Figure 59. LED Headroom Voltage (Mis-Matched Strings)

1.6

24Mhz

4Mhz

0.8Mhz

1.4

1.2

1.0

0.8

0.6

0.4

VIN (V)

C001

Figure 60. Current vs PWM Sample Frequency

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LM36923H

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ZHCSEM6A –FEBRUARY 2016–REVISED FEBRUARY 2016

9 Power Supply Recommendations

9.1 Input Supply Bypassing

The LM36923H is designed to operate from an input supply range of 2.5 V to 5.5 V. This input supply should be

well regulated and be able to provide the peak current required by the LED configuration and inductor selected

without voltage drop under load transients (start-up or rapid brightness change). The resistance of the input

supply rail should be low enough such that the input current transient does not cause the LM36923H supply

voltage to droop more than 5%. Additional bulk decoupling located close to the input capacitor (C_IN) may be

required to minimize the impact of the input supply rail resistance.

10 Layout

10.1 Layout Guidelines

The inductive boost converter of the LM36923H device detects a high switched voltage (up to V_OVP) at the SW

pin, and a step current (up to I_CL) through the Schottky diode and output capacitor each switching cycle. The high

switching voltage can create interference into nearby nodes due to electric field coupling (I = CdV/dt). The large

step current through the diode and the output capacitor can cause a large voltage spike at the SW pin and the

OUT pin due to parasitic inductance in the step current conducting path (V = Ldi/dt). Board layout guidelines are

geared towards minimizing this electric field coupling and conducted noise. Figure 61 highlights these two noise-

generating components.

Voltage Spike

V_OUT+ V_FSchottky

Pulsed voltage at SW

I_PEAK

Current through

Schottky and

COUT

I_AVE= I_IN

Current through

Inductor

Parasitic

Circuit Board

Inductances

Affected Node

due to Capacitive Coupling

LCD Display

Cp1

L

Lp1

D1

Lp2

Up to 38V

2.5 V to 5.5 V

C_OUT

SW

IN

Lp3

C_IN

LM36923H

OUT

LED1

LED2

LED3

GND

Figure 61. SW Pin Voltage (High Dv/Dt) and Current Through Schottky Diode and COUT (High Di/Dt)

35

LM36923H

ZHCSEM6A –FEBRUARY 2016–REVISED FEBRUARY 2016

www.ti.com.cn

Layout Guidelines (continued)

The following list details the main (layout sensitive) areas of the inductive boost converter of the LM36923 device

in order of decreasing importance:

•

Output Capacitor

–

Schottky Cathode to COUT+

COUT– to GND

•

Schottky Diode

–

SW pin to Schottky Anode

Schottky Cathode to COUT+

•

Inductor

–

SW Node PCB capacitance to other traces

Input Capacitor

–

CIN+ to IN pin

10.1.1 Boost Output Capacitor Placement

Because the output capacitor is in the path of the inductor current discharge path it detects a high-current step

from 0 to I_PEAKeach time the switch turns off and the Schottky diode turns on. Any inductance along this series

path from the cathode of the diode through C_OUTand back into the GND pin of the LM36923H device GND pin

contributes to voltage spikes (V_SPIKE= L_{P_}× di/dt) at SW and OUT. These spikes can potentially over-voltage the

SW pin, or feed through to GND. To avoid this, COUT+ must be connected as close to the cathode of the

Schottky diode as possible, and COUT− must be connected as close to the GND pin of the device as possible.

The best placement for COUT is on the same layer as the LM36923H in order to avoid any vias that can add

excessive series inductance.

10.1.2 Schottky Diode Placement

In the boost circuit of the LM36923H device the Schottky diode is in the path of the inductor current discharge.

As a result the Schottky diode sees a high-current step from 0 to I_PEAKeach time the switch turns off and the

diode turns on. Any inductance in series with the diode causes a voltage spike (V_SPIKE= L_{P_}× di/dt) at SW and

OUT. This can potentially over-voltage the SW pin, or feed through to V_OUTand through the output capacitor and

into GND. Connecting the anode of the diode as close to the SW pin as possibleand the cathode of the diode as

close to C_OUTas possible reduces the inductance (L_{P_}) and minimize these voltage spikes.

10.1.3 Inductor Placement

The node where the inductor connects to the LM36923H device SW pin has 2 issues. First, a large switched

voltage (0 to V_OUT+ V_{F_SCHOTTKY}) appears on this node every switching cycle. This switched voltage can be

capacitively coupled into nearby nodes. Second, there is a relatively large current (input current) on the traces

connecting the input supply to the inductor and connecting the inductor to the SW bump. Any resistance in this

path can cause voltage drops that can negatively affect efficiency and reduce the input operating voltage range.

To reduce the capacitive coupling of the signal on SW into nearby traces, the SW bump-to-inductor connection

must be minimized in area. This limits the PCB capacitance from SW to other traces. Additionally, high

impedance nodes that are more susceptible to electric field coupling must be routed away from SW and not

directly adjacent or beneath. This is especially true for traces such as SCL, SDA, HWEN, ASEL, and PWM. A

GND plane placed directly below SW dramatically reduces the capacitance from SW into nearby traces.

Lastly, limit the trace resistance of the V_INto inductor connection and from the inductor to SW connection by use

of short, wide traces.

10.1.4 Boost Input Capacitor Placement

For the LM36923H boost converter, the input capacitor filters the inductor current ripple and the internal

MOSFET driver currents during turnon of the internal power switch. The driver current requirement can range

from 50 mA at 2.7 V to over 200 mA at 5.5 V with fast durations of approximately 10 ns to 20 ns. This appears

as high di/dt current pulses coming from the input capacitor each time the switch turns on. Close placement of

the input capacitor to the IN pin and to the GND pin is critical because any series inductance between IN and

CIN+ or CIN− and GND can create voltage spikes that could appear on the VIN supply line and in the GND

36

LM36923H

www.ti.com.cn

ZHCSEM6A –FEBRUARY 2016–REVISED FEBRUARY 2016

Layout Guidelines (continued)

plane. Close placement of the input bypass capacitor at the input side of the inductor is also critical. The source

impedance (inductance and resistance) from the input supply, along with the input capacitor of the LM36923H,

form a series RLC circuit. If the output resistance from the source (R_S) is low enough the circuit is underdamped

and has a resonant frequency (typically the case). Depending on the size of L_Sthe resonant frequency could

occur below, close to, or above the LM36923H switching frequency. This can cause the supply current ripple to

be:

1. Approximately equal to the inductor current ripple when the resonant frequency occurs well above the

LM36923H switching frequency;

2. Greater than the inductor current ripple when the resonant frequency occurs near the switching frequency; or

3. Less than the inductor current ripple when the resonant frequency occurs well below the switching frequency.

Figure 62 shows the series RLC circuit formed from the output impedance of the supply and the input capacitor.

The circuit is redrawn for the AC case where the V_INsupply is replaced with a short to GND, and the LM36923H

+ Inductor is replaced with a current source (ΔI_L). Equation 1 is the criteria for an underdamped response.

Equation 2 is the resonant frequency. Equation 3 is the approximated supply current ripple as a function of L_S,

R_S, and C_IN. As an example, consider a 3.6-V supply with 0.1 Ω of series resistance connected to C_INthrough 50

nH of connecting traces. This results in an underdamped input-filter circuit with a resonant frequency of 712 kHz.

Because both the 1-MHz and 500-kHz switching frequency options lie close to the resonant frequency of the

input filter, the supply current ripple is probably larger than the inductor current ripple. In this case, using

equation 3, the supply current ripple can be approximated as 1.68 times the inductor current ripple (using a 500-

kHz switching frequency) and 0.86 times the inductor current ripple using a 1-MHz switching frequency.

Increasing the series inductance (LS) to 500 nH causes the resonant frequency to move to around 225 kHz, and

the supply current ripple to be approximately 0.25 times the inductor current ripple (500-kHz switching frequency)

and 0.053 times for a 1-MHz switching frequency.

I

SUPPLY

DI

L

LM36923H

R

L

S

SW

IN

V

IN

Supply

C_IN

I

SUPPLY

L

R

S

DI

L

C

IN

2

R_S

1

>

1.

2

L_Sx C_IN

4x L_S

1

f_RESONANT

=

2.

2p L_Sx C_IN

1

2p x 500 kHz x C_IN

3. I_SUPPLYRIPPLEö DI_Lx

2

≈

’

2

1

∆

÷

◊

R_S+ 2p x 500 kHz x L_S-

∆

2p x 500 kHz xC_IN

«

Figure 62. Input RLC Network

37

LM36923H

ZHCSEM6A –FEBRUARY 2016–REVISED FEBRUARY 2016

www.ti.com.cn

10.2 Layout Example

VIA

Inner or

Top Layer

Bottom Layer

Input Cap

Diode

ASEL

Inductor

Output Cap

6.5 mm

Figure 63. LM36923H Layout Example

38

LM36923H

www.ti.com.cn

ZHCSEM6A –FEBRUARY 2016–REVISED FEBRUARY 2016

11 器件和文档支持

11.1 器件支持

11.1.1 Third-Party Products Disclaimer

TI'S PUBLICATION OF INFORMATION REGARDING THIRD-PARTY PRODUCTS OR SERVICES DOES NOT

CONSTITUTE AN ENDORSEMENT REGARDING THE SUITABILITY OF SUCH PRODUCTS OR SERVICES

OR A WARRANTY, REPRESENTATION OR ENDORSEMENT OF SUCH PRODUCTS OR SERVICES, EITHER

ALONE OR IN COMBINATION WITH ANY TI PRODUCT OR SERVICE.

11.2 商标

E2E is a trademark of Texas Instruments.

All other trademarks are the property of their respective owners.

11.3 社区资源

The following links connect to TI community resources. Linked contents are provided "AS IS" by the respective

contributors. They do not constitute TI specifications and do not necessarily reflect TI's views; see TI's Terms of

Use.

TI E2E™ Online Community TI's Engineer-to-Engineer (E2E) Community. Created to foster collaboration

among engineers. At e2e.ti.com, you can ask questions, share knowledge, explore ideas and help

solve problems with fellow engineers.

Design Support TI's Design Support Quickly find helpful E2E forums along with design support tools and

contact information for technical support.

11.4 静电放电警告

ESD 可能会损坏该集成电路。德州仪器 (TI) 建议通过适当的预防措施处理所有集成电路。如果不遵守正确的处理措施和安装程序 , 可

能会损坏集成电路。

ESD 的损坏小至导致微小的性能降级 , 大至整个器件故障。精密的集成电路可能更容易受到损坏 , 这是因为非常细微的参数更改都可

能会导致器件与其发布的规格不相符。

11.5 Glossary

SLYZ022 — TI Glossary.

This glossary lists and explains terms, acronyms, and definitions.

12 机械、封装和可订购信息

以下页中包括机械、封装和可订购信息。这些信息是针对指定器件可提供的最新数据。这些数据会在无通知且不对

本文档进行修订的情况下发生改变。欲获得该数据表的浏览器版本，请查阅左侧的导航栏。

39

PACKAGE MATERIALS INFORMATION

www.ti.com

25-Feb-2016

TAPE AND REEL INFORMATION

*All dimensions are nominal

Device

Package Package Pins

Type Drawing

SPQ

Reel

A0

B0

K0

P1

W

Pin1

Diameter Width (mm) (mm) (mm) (mm) (mm) Quadrant

(mm) W1 (mm)

LM36923HYFFR

DSBGA

YFF

12

3000

180.0

8.4

1.5

1.99

0.75

4.0

8.0

Q1

Pack Materials-Page 1

PACKAGE MATERIALS INFORMATION

www.ti.com

25-Feb-2016

*All dimensions are nominal

Device

Package Type Package Drawing Pins

DSBGA YFF 12

SPQ

Length (mm) Width (mm) Height (mm)

210.0 185.0 35.0

LM36923HYFFR

3000

Pack Materials-Page 2

PACKAGE OUTLINE

YFF0012

DSBGA - 0.625 mm max height

SCALE 8.000

DIE SIZE BALL GRID ARRAY

A

B

E

BALL A1

CORNER

D

0.625 MAX

C

SEATING PLANE

0.05 C

BALL TYP

0.30

0.12

0.8 TYP

0.4 TYP

D

C

B

SYMM

1.2

TYP

D: Max = 1.756 mm, Min =1.695 mm

E: Max = 1.355 mm, Min =1.295 mm

A

0.4 TYP

1

2

3

0.3

12X

0.015

0.2

SYMM

C A

B

4222191/A 07/2015

NOTES:

1. All linear dimensions are in millimeters. Any dimensions in parenthesis are for reference only. Dimensioning and tolerancing

per ASME Y14.5M.

2. This drawing is subject to change without notice.

www.ti.com

EXAMPLE BOARD LAYOUT

YFF0012

DSBGA - 0.625 mm max height

DIE SIZE BALL GRID ARRAY

(0.4) TYP

3

12X ( 0.23)

(0.4) TYP

1

2

A

B

C

SYMM

D

SYMM

LAND PATTERN EXAMPLE

SCALE:30X

0.05 MAX

0.05 MIN

METAL UNDER

SOLDER MASK

(

0.23)

METAL

(

0.23)

SOLDER MASK

OPENING

SOLDER MASK

OPENING

NON-SOLDER MASK

SOLDER MASK

DEFINED

(PREFERRED)

SOLDER MASK DETAILS

NOT TO SCALE

4222191/A 07/2015

NOTES: (continued)

3. Final dimensions may vary due to manufacturing tolerance considerations and also routing constraints. For more information,

see Texas Instruments literature number SNVA009 (www.ti.com/lit/snva009).

www.ti.com

EXAMPLE STENCIL DESIGN

YFF0012

DSBGA - 0.625 mm max height

DIE SIZE BALL GRID ARRAY

(0.4) TYP

(R0.05) TYP

12X ( 0.25)

1

2

3

A

(0.4) TYP

B

SYMM

METAL

TYP

C

D

SYMM

SOLDER PASTE EXAMPLE

BASED ON 0.1 mm THICK STENCIL

SCALE:30X

4222191/A 07/2015

NOTES: (continued)

4. Laser cutting apertures with trapezoidal walls and rounded corners may offer better paste release.

www.ti.com

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TI“按原样”提供技术和可靠性数据（包括数据表）、设计资源（包括参考设计）、应用或其他设计建议、网络工具、安全信息和其他资源，

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TI 反对并拒绝您可能提出的任何其他或不同的条款。IMPORTANT NOTICE

邮寄地址：Texas Instruments, Post Office Box 655303, Dallas, Texas 75265


型号：	LM36923HYFFR
厂家：	TEXAS INSTRUMENTS
描述：	高效三灯串白光 LED 驱动器 \| YFF \| 12 \| -40 to 85 驱动驱动器
文件：	总46页 (文件大小：2308K)
中文：	中文翻译
下载：	下载PDF数据表文档文件

LM36923HYFFR [TI]

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