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TPS54540B-Q1

ZHCSG12 –FEBRUARY 2017

具有 Eco-mode™ 的 TPS54540B-Q1 4.5V 至 42V 输入、5A 降压直流/直

流转换器

1 特性

•

12V、24V 和 48V 工业、汽车及通信用电源系统

1

•

符合汽车应用应用认证

具有符合 AEC-Q100 标准的下列结果：

3 说明

TPS54540B-Q1 是一款具有集成型高侧 MOSFET 的

42V、5A 降压稳压器。按照 ISO 7637 标准，此器件

能够耐受高达 65V 的负载突降脉冲。电流模式控制提

供简单的外部补偿和灵活的组件选择。低纹波脉冲跳跃

模式可将无负载电源电流减小至 146μA。当使能引脚

被拉至低电平时，关断电源电流将降至 2μA。

–

器件温度 1 级：-40°C 至 125°C 的环境运行温

度范围

器件人体放电模式 (HBM) 静电放电 (ESD) 分类

等级 H1C

器件组件充电模式 (CDM) ESD 分类等级 C3B

•

可在轻负载条件下使用脉冲跳跃 Eco-mode™ 实现

高效率 Eco-mode™

欠压闭锁在内部设定为 4.3V，但可用一个使能引脚上

的外部电阻分压器将之提高。该器件可在内部控制输出

电压启动斜坡，从而控制启动过程并消除过冲。

92mΩ 高侧金属氧化物半导体场效应晶体管

(MOSFET)

•

146μA 静态运行电流和 2μA 关断电流

100kHz 至 2.5MHz 可调开关频率

同步至外部时钟

宽开关频率范围可实现对效率或者外部组件尺寸进行的

优化。输出电流是受限的逐周期电流。频率折返和热关

断功能在过载情况下保护内部和外部组件不受损坏。

可在轻负载条件下使用集成型引导 (BOOT) 再充电

场效应晶体管 (FET) 实现低压降

TPS54540B-Q1 采用 8 引脚热增强型 HSOP

PowerPAD 封装。

•

可调欠压闭锁 (UVLO) 电压和迟滞

0.8V 1% 内部电压基准

器件信息⁽¹⁾

8 引脚 HSOP PowerPAD™的封装

-40°C 至 150°C T_J运行范围

由 WEBENCH^®软件工具支持

器件型号

封装

HSOP (8)

封装尺寸（标称值）

TPS54540B-Q1

4.89mm × 3.90mm

(1) 如需了解所有可用封装，请参阅产品说明书末尾的可订购产品

附录。

2 应用

•

车辆附件：全球卫星定位 (GPS)（请参见

SLVA412），娱乐系统，高级驾驶员辅助系统

(ADAS)，紧急呼叫系统 (eCall)

•

USB 专用充电端口和电池充电器（请参阅

SLVA464）

工业自动化和电机控制

sp

简化原理图

效率与负载电流间的关系

100

90

80

70

60

50

40

30

V_IN

VIN

BOOT

TPS54540B-Q1

EN

V_OUT

SW

COMP

20

10

0

V

= 12 V

= 36 V

Series1

IN

RT/CLK

FB

V

Series2

IN

V

= 60 V

Series4

IN

GND

0

0.5

1

1.5

2

2.5

3

3.5

4

4.5

5

5.5

C024

I_O- Output Current (A)

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: SLVSDX6

TPS54540B-Q1

ZHCSG12 –FEBRUARY 2017

www.ti.com.cn

7.4 Device Functional Modes........................................ 22

Application and Implementation ........................ 23

8.1 Application Information............................................ 23

8.2 Typical Applications ................................................ 23

Power Supply Recommendations...................... 36

1

2

3

4

5

6

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

8

9

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 Timing Requirements................................................ 5

6.7 Switching Characteristics.......................................... 6

6.8 Typical Characteristics.............................................. 7

Detailed Description ............................................ 11

7.1 Overview ................................................................. 11

7.2 Functional Block Diagram ....................................... 12

7.3 Feature Description................................................. 12

10 Layout................................................................... 36

10.1 Layout Guidelines ................................................. 36

10.2 Layout Example .................................................... 36

10.3 Estimated Circuit Area .......................................... 37

11 器件和文档支持 ..................................................... 37

11.1 器件支持................................................................ 37

11.2 文档支持................................................................ 37

11.3 社区资源................................................................ 37

11.4 商标....................................................................... 37

11.5 静电放电警告......................................................... 37

11.6 Glossary................................................................ 37

12 机械、封装和可订购信息....................................... 38

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。

日期

修订版本

注释

2017 年2 月

*

初始发行版。

2

TPS54540B-Q1

www.ti.com.cn

ZHCSG12 –FEBRUARY 2017

5 Pin Configuration and Functions

DDA Package

8-Pin HSOP With PowerPAD

Top View

BOOT

VIN

1

2

3

4

8

7

6

5

SW

GND

COMP

FB

PowerPAD

9

EN

RT/CLK

Pin Functions

I/O

DESCRIPTION

NAME

NO.

A bootstrap capacitor is required between BOOT and SW. If the voltage on this capacitor is below the

minimum required to operate the high side MOSFET, the MOSFET stops switching until the capacitor is

refreshed.

BOOT

1

I

Error amplifier output and input to the output switch current (PWM) comparator. Connect frequency

compensation components to this pin.

COMP

EN

6

3

I

Enable pin, with internal pullup current source. Pull below 1.2 V to disable. Float to enable. Adjust the input

undervoltage lockout with two resistors. See the Enable and Adjusting Undervoltage Lockout section.

FB

5

7

I

Inverting input of the transconductance (gm) error amplifier.

Ground

GND

—

Resistor Timing and External Clock. An internal amplifier holds this pin at a fixed voltage when using an

external resistor to ground to set the switching frequency. If the pin is pulled above the PLL upper threshold,

a mode change occurs and the pin becomes a synchronization input. The internal amplifier is disabled and

the pin is a high impedance clock input to the internal PLL. If clocking edges stop, the internal amplifier is

reenabled and the operating mode returns to resistor frequency programming.

RT/CLK

4

I

SW

VIN

8

2

9

O

I

The source of the internal high-side power MOSFET and switching node of the converter.

Input supply voltage is connected to this pin with a 4.5-V to 42-V operating range.

PowerPAD

—

GND pin must be electrically connected to the exposed pad on the printed-circuit-board for proper operation.

3

TPS54540B-Q1

ZHCSG12 –FEBRUARY 2017

www.ti.com.cn

6 Specifications

6.1 Absolute Maximum Ratings

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

MIN

–0.3

–0.6

–2

MAX

65

8.4

3

UNIT

VIN

EN

FB

COMP

3

Voltage

V

RT/CLK

3.6

8

BOOT-SW

SW

SW, 10-ns Transient

65

150

Operating junction temperature

Storage temperature, T_stg

–40

–65

°C

(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

±750

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.

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

6.3 Recommended Operating Conditions

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

MIN

V_O+ V_do

0.8

NOM

MAX

60

UNIT

V

V_IN

V_O

I_O

Input supply voltage⁽¹⁾

Output voltage

58.8

5

V

Output current

0

A

T_J

Junction Temperature

–40

150

°C

(1) See Equation 1 in the Feature Description section.

6.4 Thermal Information

TPS54540B-Q1

THERMAL METRIC⁽¹⁾

DDA (HSOP)

8 PINS

41.7

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

52.7

22.6

ψ_JT

Junction-to-top characterization parameter

Junction-to-board characterization parameter

Junction-to-case (bottom) thermal resistance

7.9

ψ_JB

22.5

R_θJC(bot)

2.6

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

report, SPRA953.

4

TPS54540B-Q1

www.ti.com.cn

ZHCSG12 –FEBRUARY 2017

6.5 Electrical Characteristics

T_J= –40°C to 150°C, VIN = 4.5 V to 42 V (unless otherwise noted)

PARAMETER

TEST CONDITIONS

MIN

TYP

MAX

UNIT

SUPPLY VOLTAGE (VIN PIN)

Operating input voltage

4.5

4.1

42

V

Internal undervoltage lockout threshold

Internal undervoltage lockout threshold hysteresis

Shutdown supply current

Rising

4.3

325

2.25

146

4.48

mV

EN = 0 V, 25°C, 4.5 V ≤ VIN ≤ 42 V

4.5

μA

Operating: nonswitching supply current

ENABLE AND UVLO (EN PIN)

Enable threshold voltage

FB = 0.9 V, T_A= 25°C

175

No voltage hysteresis, rising and falling

Enable threshold 50 mV

1.1

1.2

–4.6

–1.2

–3.4

1.3

V

Input current

μA

Enable threshold –50 mV

–0.58

–2.2

–1.8

–4.5

Hysteresis current

INTERNAL SOFT-START TIME

Soft-start time

f_SW= 500 kHz, 10% to 90%

f_SW= 2.5 MHz, 10% to 90%

2.1

ms

Soft-start time

0.42

VOLTAGE REFERENCE

Voltage reference

0.792

0.8

92

0.808

190

V

HIGH-SIDE MOSFET

On-resistance

V_IN= 12 V, BOOT-SW = 6 V

mΩ

ERROR AMPLIFIER

Input current

50

350

nA

μS

Error amplifier transconductance (g_M)

Error amplifier transconductance (g_M) during soft-start

Error amplifier DC gain

Minimum unity gain bandwidth

Error amplifier source and sink

COMP to SW current transconductance

CURRENT LIMIT

–2 μA < I_COMP< 2 μA, V_COMP= 1 V

–2 μA < I_COMP< 2 μA, V_COMP= 1 V, V_FB= 0.4 V

V_FB= 0.8 V

77

μS

10000

2500

±30

V/V

kHz

μA

V_(COMP)= 1 V, 100-mV overdrive

17

A/V

All VIN and temperatures, Open Loop

All temperatures, VIN = 12 V, Open Loop

V_IN= 12 V, T_A= 25°C, Open Loop⁽¹⁾

6.3

7.0

7.9

9.5

8.8

Current limit threshold

A

THERMAL SHUTDOWN

Thermal shutdown

176

12

°C

Thermal shutdown hysteresis

ERROR AMPLIFIER

Enable to COMP active

V_IN= 12 V, T_A= 25°C

346

µs

(1) Open-loop current limit measured directly at the SW pin and is independent of the inductor value and slope compensation.

6.6 Timing Requirements

T_J= –40°C to 150°C, V_IN= 4.5 V to 42 V (unless otherwise noted)

MIN

NOM

MAX

UNIT

RT/CLK

Minimum CLK input pulse width

15

ns

5

TPS54540B-Q1

ZHCSG12 –FEBRUARY 2017

www.ti.com.cn

6.7 Switching Characteristics

T_J= –40°C to 150°C, V_IN= 4.5 V to 42 V (unless otherwise noted)

PARAMETER

TEST CONDITIONS

MIN

TYP

MAX

UNIT

CURRENT LIMIT

Current limit threshold delay

60

ns

RT/CLK

Switching frequency range using RT

mode

100

450

160

2500

550

2300

2

kHz

f_SW

Switching frequency

R_T= 200 kΩ

500

Switching frequency range using

CLK mode

RT/CLK high threshold

RT/CLK low threshold

1.55

1.2

V

0.5

RT/CLK falling edge to SW rising

edge delay

Measured at 500 kHz with RT

resistor in series

55

78

ns

PLL lock in time

Measured at 500 kHz

μs

6

TPS54540B-Q1

www.ti.com.cn

ZHCSG12 –FEBRUARY 2017

6.8 Typical Characteristics

0.25

0.2

0.15

0.1

0.05

0

0.814

0.809

0.804

0.799

0.794

0.789

0.784

BOOT-SW = 3 V

BOOT-SW = 6 V

œ50

œ25

0

25

50

75

100

125

150

œ50

œ25

0

25

50

75

100

125

150

C025

C026

T_J- Junction Temperature (°C)

Figure 1. ON-Resistance vs Junction Temperature

Figure 2. Voltage Reference vs Junction Temperature

9.5

9

4.5

12

60

8.5

8

8.5

8

7.5

7

7.5

7

-40 èC

25 èC

150 èC

6.5

6

6.5

6

-40

-10

20

50

80

110

140

170

0

10

20

30

40

50

60

Temperature Junction (Tj)

Input Voltage (V)

D001

D002

Figure 3. High-side Switch Current Limit vs Junction

Temperature

Figure 4. High-side Switch Current Limit vs Input Voltage

550

500

450

400

350

300

250

200

150

100

50

540

530

520

510

500

490

480

470

460

450

0

œ50

œ25

0

25

50

75

100

125

150

200

300

400

500

600

700

800

900 1000

C029

C030

T_J- Junction Temperature (°C)

RT/CLK - Resistance (kꢀ)

Figure 5. Switching Frequency vs Junction Temperature

Figure 6. Switching Frequency vs RT/CLK Resistance Low-

Frequency Range

7

TPS54540B-Q1

ZHCSG12 –FEBRUARY 2017

www.ti.com.cn

Typical Characteristics (continued)

2500

2300

2100

1900

1700

1500

1300

1100

900

500

450

400

350

300

250

200

700

500

0

50

100

150

200

œ50

œ25

0

25

50

75

100

125

150

C031

C032

RT/CLK - Resistance (kꢀ)

T_J- Junction Temperature (°C)

Figure 7. Switching Frequency vs RT/CLK Resistance

High-Frequency Range

Figure 8. EA Transconductance vs Junction Temperature

120

110

100

90

1.3

1.29

1.28

1.27

1.26

1.25

1.24

1.23

1.22

1.21

1.2

1.19

1.18

1.17

1.16

1.15

80

70

60

50

40

30

20

œ50

œ25

0

25

50

75

100

125

150

œ50

œ25

0

25

50

75

100

125

150

C033

C034

T_J- Junction Temperature (°C)

Figure 9. EA Transconductance During Soft-Start vs

Junction Temperature

Figure 10. EN Pin Voltage vs Junction Temperature

œ3.5

œ0.5

œ3.7

œ3.9

œ4.1

œ4.3

œ4.5

œ4.7

œ4.9

œ5.1

œ5.3

œ5.5

œ0.7

œ0.9

œ1.1

œ1.3

œ1.5

œ1.7

œ1.9

œ2.1

œ2.3

œ2.5

œ50

œ25

0

25

50

75

100

125

150

œ50

œ25

0

25

50

75

100

125

150

C035

C036

T_J- Junction Temperature (°C)

Figure 11. EN Pin Current vs Junction Temperature

Figure 12. EN Pin Current vs Junction Temperature

8

TPS54540B-Q1

www.ti.com.cn

ZHCSG12 –FEBRUARY 2017

Typical Characteristics (continued)

œ2.5

œ2.7

œ2.9

œ3.1

œ3.3

œ3.5

œ3.7

œ3.9

œ4.1

œ4.3

œ4.5

100

75

50

25

0

V_SS_ENe_Sr_EieFsa2lling

Rising

V

_SS_ENe_Sr_Eies4

0.0

0.1

0.2

0.3

0.4

0.5

0.6

0.7

0.8

œ50

œ25

0

25

50

75

100

125

150

C038

C037

T_J- Junction Temperature (°C)

V_SENSE(V)

Figure 13. EN Pin Current Hysteresis vs Junction

Temperature

Figure 14. Switching Frequency vs V_SENSE

3

2.5

2

T_JS=er2ie5s°2C

2.5

2

1.5

1

1.5

1

0.5

0

0.5

0

œ50

œ25

0

25

50

75

100

125

150

0

5

10

15

20

25

30

35

40

45

C039

C040

T_J- Junction Temperature (°C)

V_IN- Input Voltage (V)

Figure 15. Shutdown Supply Current vs Junction

Temperature

Figure 16. Shutdown Supply Current vs Input Voltage (V_IN)

210

T_JS=er2ie5s°C2

190

170

150

130

110

90

190

170

150

130

110

90

70

œ50

œ25

0

25

50

75

100

125

150

0

5

10

15

20

25

30

35

40

45

C041

C042

T_J- Junction Temperature (°C)

V_IN- Input Voltage (V)

Figure 17. V_INSupply Current vs Junction Temperature

Figure 18. V_INSupply Current vs Input Voltage

9

TPS54540B-Q1

ZHCSG12 –FEBRUARY 2017

www.ti.com.cn

Typical Characteristics (continued)

2.6

4.5

4.4

4.3

4.2

4.1

4.0

3.9

3.8

3.7

BOOT-PH UVLO Falling

UVLO Start Switching

UVLO Stop Switching

BOOT-PH UVLO Rising

2.5

2.4

2.3

2.2

2.1

2.0

1.9

1.8

œ50

œ25

0

25

50

75

100

125

150

œ50

œ25

0

25

50

75

100

125

150

C043

C044

T_J- Junction Temperature (°C)

Figure 19. BOOT-SW UVLO vs Junction Temperature

Figure 20. Input Voltage UVLO vs Junction Temperature

10

9

8

7

6

5

4

3

2

1

0

C045

Switching Frequency (kHz)

Figure 21. Soft-Start Time vs Switching Frequency

10

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www.ti.com.cn

ZHCSG12 –FEBRUARY 2017

7 Detailed Description

7.1 Overview

The TPS54540-Q1 device is a 42-V, 5-A, step-down (buck) regulator with an integrated high-side N-channel

MOSFET. The device implements constant frequency, current mode control that reduces output capacitance and

simplifies external frequency compensation. The wide switching frequency range of 100 kHz to 2500 kHz allows

either efficiency or size optimization when selecting the output filter components. The switching frequency is

adjusted using a resistor to ground connected to the RT/CLK pin. The device has an internal phase-locked loop

(PLL) connected to the RT/CLK pin that will synchronize the power switch turnon to a falling edge of an external

clock signal.

The TPS54540-Q1 device has a default input start-up voltage of approximately 4.3 V. The EN pin can be used to

adjust the input voltage undervoltage lockout (UVLO) threshold with two external resistors. An internal pullup

current source enables operation when the EN pin is floating. The operating current is 146 μA under no load

condition (not switching). When the device is disabled, the supply current is 2 μA.

The integrated 92-mΩ high-side MOSFET supports high-efficiency power supply designs capable of delivering

5 A of continuous current to a load. The gate drive bias voltage for the integrated high-side MOSFET is supplied

by a bootstrap capacitor connected from the BOOT to SW pins. The TPS54540-Q1 device reduces the external

component count by integrating the bootstrap recharge diode. The BOOT pin capacitor voltage is monitored by a

UVLO circuit which turns off the high-side MOSFET when the BOOT to SW voltage falls below a preset

threshold. An automatic BOOT capacitor recharge circuit allows the TPS54540-Q1 device to operate at high duty

cycles approaching 100%. Therefore, the maximum output voltage is near the minimum input supply voltage of

the application. The minimum output voltage is the internal 0.8-V feedback reference.

Output overvoltage transients are minimized by an Overvoltage Protection (OVP) comparator. When the OVP

comparator is activated, the high-side MOSFET is turned off and remains off until the output voltage is less than

106% of the desired output voltage.

The TPS54540-Q1 device includes an internal soft-start circuit that slows the output rise time during start-up to

reduce in-rush current and output voltage overshoot. Output overload conditions reset the soft-start timer. When

the overload condition is removed, the soft-start circuit controls the recovery from the fault output level to the

nominal regulation voltage. A frequency foldback circuit reduces the switching frequency during start-up and

overcurrent fault conditions to help maintain control of the inductor current.

11

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ZHCSG12 –FEBRUARY 2017

www.ti.com.cn

7.2 Functional Block Diagram

EN

VIN

Thermal

Shutdown

UVLO

Enable

OV

Comparator

Shutdown

Logic

Enable

Threshold

Boot

Charge

Voltage

Reference

Boot

UVLO

Minimum

Clamp

Pulse

Current

Sense

Skip

Error

Amplifier

PWM

FB

Comparator

BOOT

Logic

Shutdown

Slope

Compensation

S

SW

COMP

Frequency

Foldback

Reference

DAC for

Soft-Start

Maximum

Clamp

Oscillator

with PLL

8/8/ 2012A 0192789

RT/CLK

GND

POWERPAD

7.3 Feature Description

7.3.1 Fixed Frequency PWM Control

The TPS54540-Q1 device uses fixed frequency, peak current mode control with adjustable switching frequency.

The output voltage is compared through external resistors connected to the FB pin to an internal voltage

reference by an error amplifier. An internal oscillator initiates the turnon of the high-side power switch. The error

amplifier output at the COMP pin controls the high-side power switch current. When the high-side MOSFET

switch current reaches the threshold level set by the COMP voltage, the power switch is turned off. The COMP

pin voltage will increase and decrease as the output current increases and decreases. The device implements

current limiting by clamping the COMP pin voltage to a maximum level. The pulse skipping Eco-mode is

implemented with a minimum voltage clamp on the COMP pin.

7.3.2 Slope Compensation Output Current

The TPS54540-Q1 device adds a compensating ramp to the MOSFET switch current sense signal. This slope

compensation prevents sub-harmonic oscillations at duty cycles greater than 50%. The peak current limit of the

high-side switch is not affected by the slope compensation and remains constant over the full duty cycle range.

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Feature Description (continued)

7.3.3 Pulse-Skip Eco-mode

The TPS54540-Q1 device operates in a pulse-skipping Eco-mode at light load currents to improve efficiency by

reducing switching and gate drive losses. If the output voltage is within regulation and the peak switch current at

the end of any switching cycle is below the pulse skipping current threshold, the device enters Eco-mode. The

pulse skipping current threshold is the peak switch current level corresponding to a nominal COMP voltage of

600 mV.

When in Eco-mode, the COMP pin voltage is clamped at 600 mV and the high-side MOSFET is inhibited.

Because the device is not switching, the output voltage begins to decay. The voltage control loop responds to the

falling output voltage by increasing the COMP pin voltage. The high-side MOSFET is enabled and switching

resumes when the error amplifier lifts COMP above the pulse skipping threshold. The output voltage recovers to

the regulated value, and COMP eventually falls below the Eco-mode pulse skipping threshold at which time the

device again enters Eco-mode. The internal PLL remains operational when in Eco-mode. When operating at light

load currents in Eco-mode, the switching transitions occur synchronously with the external clock signal.

During Eco-mode operation, the TPS54540-Q1 device senses and controls peak switch current, not the average

load current. Therefore the load current at which the device enters Eco-mode is dependent on the output inductor

value. As the load current approaches zero, the device enters a pulse-skip mode during which it draws only

152 µA of input quiescent current. The circuit in Figure 33 enters Eco-mode at about 18-mA output current, and

with no external load has an average input current of 240 µA.

7.3.4 Low Dropout Operation and Bootstrap Voltage (BOOT)

The TPS54540-Q1 device provides an integrated bootstrap voltage regulator. A small capacitor between the

BOOT and SW pins provides the gate drive voltage for the high-side MOSFET. The BOOT capacitor is refreshed

when the high-side MOSFET is off and the external low-side diode conducts. The recommended value of the

BOOT capacitor is 0.1 μF. For stable performance over temperature and voltage, TI recommends a ceramic

capacitor with an X7R or X5R grade dielectric with a voltage rating of 10 V or higher.

When operating with a low voltage difference from input to output, the high-side MOSFET of the TPS54540-Q1

device will operate at 100% duty cycle as long as the BOOT to SW pin voltage is greater than 2.1 V. When the

voltage from BOOT to SW drops to less than 2.1 V, the high-side MOSFET is turned off and an integrated low-

side MOSFET pulls SW low to recharge the BOOT capacitor. To reduce the losses of the small low-side

MOSFET at high-output voltages, it is disabled at 24-V output and reenabled when the output reaches 21.5 V.

Because the gate drive current sourced from the BOOT capacitor is small, the high-side MOSFET can remain on

for many switching cycles before the MOSFET is turned off to refresh the capacitor. Thus, the effective duty

cycle of the switching regulator can be high, approaching 100%. The effective duty cycle of the converter during

dropout is mainly influenced by the voltage drops across the power MOSFET, the inductor resistance, the low-

side diode voltage and the printed-circuit-board resistance.

Equation 1 calculates the minimum input voltage required to regulate the output voltage and ensure proper

operation of the device. This calculation must include tolerance of the component specifications and the variation

of these specifications at their maximum operating temperature in the application.

V_OUT+ V_F+ R_dc´I_OUT

V min =

_IN( )

+ R_DSon ´I

( )

- V_F

OUT

D

where

•

V_F= Schottky diode forward voltage

R_dc= DC resistance of inductor

R_DS(on)= High-side MOSFET resistance

D = Effective duty cycle of 99%

(1)

During high duty cycle (low dropout) conditions, inductor current ripple increases when the BOOT capacitor is

being recharged resulting in an increase in output voltage ripple. Increased ripple occurs when the off time

required to recharge the BOOT capacitor is longer than the high-side off time associated with cycle-by-cycle

PWM control.

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Feature Description (continued)

At heavy loads, the minimum input voltage must be increased to insure a monotonic start-up. Equation 2 can be

used to calculate the minimum input voltage for this condition.

V_Omax = Dmax × (V_VINmin – I_Omax × R_DS(on)+ V_F) – V_F– I_Omax × R_dc

where

•

Dmax ≥ 0.9

R_DS(on)= 1 / (–0.3 × VB2SW²+ 3.577 × VB2SW – 4.246)

VB2SW = VBOOT + V_F

VBOOT = (1.41 × V_VIN– 0.554 – V_F× ƒ_SW– 1.847 × 10³× IB2SW) / (1.41 + ƒ_SW

IB2SW = 100 × 10^–6A

)

(2)

7.3.5 Error Amplifier

The TPS54540-Q1 voltage regulation loop is controlled by a transconductance error amplifier. The error amplifier

compares the FB pin voltage to the lower of the internal soft-start voltage or the internal 0.8-V voltage reference.

The transconductance (gm) of the error amplifier is 350 μA/V during normal operation. During soft-start operation,

the transconductance is reduced to 78 μA/V and the error amplifier is referenced to the internal soft-start voltage.

The frequency compensation components (capacitor, series resistor and capacitor) are connected between the

error amplifier output COMP pin and GND pin.

7.3.6 Adjusting the Output Voltage

The internal voltage reference produces a precise 0.8 V ±1% voltage reference over the operating temperature

and voltage range by scaling the output of a bandgap reference circuit. The output voltage is set by a resistor

divider from the output node to the FB pin. TI recommends using 1% tolerance or better divider resistors. Select

the low-side resistor R_LSfor the desired divider current and use Equation 3 to calculate R_HS. To improve

efficiency at light loads consider using larger value resistors. However, if the values are too high, the regulator

will be more susceptible to noise and voltage errors from the FB input current may become noticeable.

Vout - 0.8V

æ

ö

R_HS= R_LS

´

ç

÷

0.8 V

è

ø

(3)

7.3.7 Enable and Adjusting Undervoltage Lockout

The TPS54540-Q1 device is enabled when the VIN pin voltage is greater than 4.3 V and the EN pin voltage

exceeds the enable threshold of 1.2 V. The TPS54540-Q1 device is disabled when the VIN pin voltage falls less

than 4 V or when the EN pin voltage is less than 1.2 V. The EN pin has an internal pullup current source, I1, of

1.2 μA that enables operation of the TPS54540-Q1 device when the EN pin floats.

If an application requires a higher undervoltage lockout (UVLO) threshold, use the circuit shown in Figure 22 to

adjust the input voltage UVLO with two external resistors. When the EN pin voltage exceeds 1.2 V, an additional

3.4 μA of hysteresis current, I_HYS, is sourced out of the EN pin. When the EN pin is pulled to less than 1.2 V, the

3.4-μA Ihys current is removed. This additional current facilitates adjustable input voltage UVLO hysteresis. Use

Equation 4 to calculate R_UVLO1for the desired UVLO hysteresis voltage. Use Equation 5 to calculate R_UVLO2for

the desired VIN start voltage.

In applications designed to start at relatively low input voltages (that is, from 4.5 V to 9 V) and withstand high

input voltages (for example, 40 V), the EN pin may experience a voltage greater than the absolute maximum

voltage of 8.4 V during the high input voltage condition. To avoid exceeding this voltage when using the EN

resistors, the EN pin is clamped internally with a 5.8 V Zener diode that will sink up to 150 μA.

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Feature Description (continued)

VIN

TPS54540B-Q1

i1 ihys

VIN

R_UVLO1

R

UVLO1

10 kW

EN

Node

5.8 V

V_EN

R_UVLO2

R

UVLO2

Figure 22. Adjustable Undervoltage Lockout

(UVLO)

Figure 23. Internal EN Clamp

V

- V

STOP

START

R

=

UVLO1

I

HYS

(4)

(5)

V

ENA

R

=

UVLO2

V

- V

ENA

START

+ I

1

R

UVLO1

7.3.8 Internal Soft Start

The TPS54540-Q1 device has an internal digital soft start that ramps the reference voltage from zero volts to its

final value in 1024 switching cycles. The internal soft-start time (10% to 90%) is calculated using Equation 6.

1024

t

(ms) =

SS

f

(kHz)

SW

(6)

If the EN pin is pulled below the stop threshold of 1.2 V, switching stops and the internal soft start resets. The

soft start also resets in thermal shutdown.

7.3.9 Constant Switching Frequency and Timing Resistor (RT/CLK) Pin)

The switching frequency of the TPS54540-Q1 device is adjustable over a wide range from 100 kHz to 2500 kHz

by placing a resistor between the RT/CLK pin and GND pin. The RT/CLK pin voltage is typically 0.5 V, and must

have a resistor to ground to set the switching frequency. To determine the timing resistance for a given switching

frequency, use Equation 7 or Equation 8 or the curves in Figure 5 and Figure 6. To reduce the solution size one

would typically set the switching frequency as high as possible, but tradeoffs of the conversion efficiency,

maximum input voltage and minimum controllable on time should be considered. The minimum controllable on

time is typically 135 ns, which limits the maximum operating frequency in applications with high input to output

step down ratios. The maximum switching frequency is also limited by the frequency foldback circuit. See

Accurate Current Limit for a more detailed discussion of the maximum switching frequency.

101756

f sw (kHz)^1.008

R_T(kW) =

(7)

92417

RT (kW)^0.991

f sw (kHz) =

(8)

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Feature Description (continued)

7.3.10 Synchronization to RT/CLK Pin

The RT/CLK pin can receive a frequency synchronization signal from an external system clock. To implement

this synchronization feature connect a square wave to the RT/CLK pin through either circuit network shown in

Figure 24. The square wave applied to the RT/CLK pin must switch lower than 0.5 V and higher than 1.7 V and

have a pulse-width greater than 15 ns. The synchronization frequency range is from 160 kHz to 2300 kHz. The

rising edge of the SW will be synchronized to the falling edge of RT/CLK pin signal. The external synchronization

circuit should be designed such that the default frequency set resistor is connected from the RT/CLK pin to

ground when the synchronization signal is off. When using a low impedance signal source, the frequency set

resistor is connected in parallel with an ac coupling capacitor to a termination resistor (for example, 50 Ω) as

shown in Figure 24. The two resistors in series provide the default frequency setting resistance when the signal

source is turned off. The sum of the resistance should set the switching frequency close to the external CLK

frequency. TI recommends ac-coupling the synchronization signal through a 10-pF ceramic capacitor to RT/CLK

pin.

The first time the RT/CLK is pulled above the PLL threshold, the TPS54540-Q1 device switches from the RT

resistor free-running frequency mode to the PLL synchronized mode. The internal 0.5-V voltage source is

removed, and the RT/CLK pin becomes high impedance as the PLL starts to lock onto the external signal. The

switching frequency can be higher or lower than the frequency set with the RT/CLK resistor. The device

transitions from the resistor mode to the PLL mode, and locks onto the external clock frequency within 78 µs.

During the transition from the PLL mode to the resistor programmed mode, the switching frequency will fall to

150 kHz and then increase or decrease to the resistor programmed frequency when the 0.5-V bias voltage is

reapplied to the RT/CLK resistor.

The switching frequency is divided by 8, 4, 2, and 1 as the FB pin voltage ramps from 0 V to 0.8 V. The device

implements a digital frequency foldback to enable synchronizing to an external clock during normal start-up and

fault conditions. Figure 25, Figure 26, and Figure 27 show the device synchronized to an external system clock in

continuous conduction mode (CCM), discontinuous conduction (DCM), and pulse skip mode (Eco-mode).

SPACER

TPS54540B-Q1

PLL

TPS54540B-Q1

PLL

RT/CLK

RT

RT/CLK

RT

Hi-Z

Clock

Source

Clock

Source

Figure 24. Synchronizing to a System Clock

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Feature Description (continued)

SW

EXT

IL

Figure 25. Plot of Synchronizing in CCM

Figure 26. Plot of Synchronizing in DCM

SW

EXT

IL

Figure 27. Plot of Synchronizing in Eco-mode™

7.3.11 Maximum Switching Frequency

To protect the converter in overload conditions at higher switching frequencies and input voltages, the

TPS54540-Q1 device implements a frequency foldback. The oscillator frequency is divided by 1, 2, 4, and 8 as

the FB pin voltage falls from 0.8 V to 0 V. The TPS54540-Q1 device uses a digital frequency foldback to enable

synchronization to an external clock during normal start-up and fault conditions. During short circuit events, the

inductor current can exceed the peak current limit because of the high input voltage and the minimum

controllable on time. When the output voltage is forced low by the shorted load, the inductor current decreases

slowly during the switch off time. The frequency foldback effectively increases the off time by increasing the

period of the switching cycle providing more time for the inductor current to ramp down.

With a maximum frequency foldback ratio of 8, there is a maximum frequency at which the inductor current can

be controlled by frequency foldback protection. Equation 10 calculates the maximum switching frequency at

which the inductor current will remain under control when V_OUTis forced to V_OUT(SC). The selected operating

frequency should not exceed the calculated value.

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Feature Description (continued)

Equation 9 calculates the maximum switching frequency limitation set by the minimum controllable on time and

the input to output step down ratio. Setting the switching frequency above this value will cause the regulator to

skip switching pulses to achieve the low duty cycle required at maximum input voltage.

æ

ç

ö

÷

I_O´R_dc+ V_OUT+ V_d

1

f_{SW maxskip}

=

´

(

)

ç

÷

t_ON

V_IN-I_O´R_{DS on}+ V_d

( )

è

ø

(9)

æ

ö

÷

I_CL´R_dc+ V_{OUT sc}+ V_d

f_DIV

( )

ç

f_SW(shift)

=

´

ç

÷

t_ON

V_IN-I_CL´R_{DS on}+ V_d

( )

è

ø

where

•

I_O= Output current

I_CL= Current limit

Rdc = inductor resistance

V_IN= maximum input voltage

V_OUT= output voltage

V_OUTSC= output voltage during short

Vd = diode voltage drop

R_DS(on)= switch on resistance

t_ON= controllable on time

ƒ_DIV= frequency divide equals (1, 2, 4, or 8)

(10)

7.3.12 Accurate Current Limit

The TPS54540-Q1 device implements peak current mode control in which the COMP pin voltage controls the

peak current of the high-side MOSFET. A signal proportional to the high-side switch current and the COMP pin

voltage are compared each cycle. When the peak switch current intersects the COMP control voltage, the high-

side switch is turned off. During overcurrent conditions that pull the output voltage low, the error amplifier

increases switch current by driving the COMP pin high. The error amplifier output is clamped internally at a level

which sets the peak switch current limit. The TPS54540-Q1 device provides an accurate current limit threshold

with a typical current limit delay of 60 ns. With smaller inductor values, the delay will result in a higher peak

inductor current. The relationship between the inductor value and the peak inductor current is shown in

Figure 28.

Peak Inductor Current

Δ_CLPeak

Open Loop Current Limit

Δ_CLPeak= V /L x t_CLdelay

IN

t_CLdelay

t_ON

Figure 28. Current Limit Delay

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Feature Description (continued)

7.3.13 Overvoltage Protection

The TPS54540-Q1 device incorporates an output overvoltage protection (OVP) circuit to minimize voltage

overshoot when recovering from output fault conditions or strong unload transients in designs with low-output

capacitance. For example, when the power supply output is overloaded the error amplifier compares the actual

output voltage to the internal reference voltage. If the FB pin voltage is lower than the internal reference voltage

for a considerable time, the output of the error amplifier will increase to a maximum voltage corresponding to the

peak current limit threshold. When the overload condition is removed, the regulator output rises and the error

amplifier output transitions to the normal operating level. In some applications, the power supply output voltage

can increase faster than the response of the error amplifier output resulting in an output overshoot.

The OVP feature minimizes output overshoot when using a low value output capacitor by comparing the FB pin

voltage to the rising OVP threshold which is nominally 109% of the internal voltage reference. If the FB pin

voltage is greater than the rising OVP threshold, the high-side MOSFET is immediately disabled to minimize

output overshoot. When the FB voltage drops below the falling OVP threshold which is nominally 106% of the

internal voltage reference, the high-side MOSFET resumes normal operation.

7.3.14 Thermal Shutdown

The TPS54540-Q1 device provides an internal thermal shutdown to protect the device when the junction

temperature exceeds 176°C. The high-side MOSFET stops switching when the junction temperature exceeds the

thermal trip threshold. Once the die temperature falls to less than 164°C, the device reinitiates the power-up

sequence controlled by the internal soft-start circuitry.

7.3.15 Small Signal Model for Loop Response

Figure 29 shows an equivalent model for the TPS54540-Q1 device control loop, which can be simulated to check

the frequency response and dynamic load response. The error amplifier is a transconductance amplifier with a

gm_EAof 350 μA/V. The error amplifier can be modeled using an ideal voltage controlled current source. The

resistor R_oand capacitor C_omodel the open loop gain and frequency response of the amplifier. The 1-mV AC

voltage source between the nodes a and b effectively breaks the control loop for the frequency response

measurements. Plotting c/a provides the small signal response of the frequency compensation. Plotting a/b

provides the small signal response of the overall loop. The dynamic loop response can be evaluated by replacing

R_Lwith a current source with the appropriate load step amplitude and step rate in a time domain analysis. This

equivalent model is only valid for continuous conduction mode (CCM) operation.

SW

V

O

Power Stage

gm 17 A/V

ps

a

b

R

R1

ESR

R

COMP

L

c

FB

C

OUT

0.8 V

CO

RO

R3

C1

gm

ea

C2

R2

350 mA/V

Figure 29. Small Signal Model for Loop Response

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Feature Description (continued)

7.3.16 Simple Small Signal Model for Peak Current Mode Control

Figure 30 describes a simple small signal model that can be used to design the frequency compensation. The

TPS54540-Q1 power stage can be approximated by a voltage-controlled current source (duty cycle modulator)

supplying current to the output capacitor and load resistor. The control to output transfer function is shown in

Equation 11 and consists of a DC gain, one dominant pole, and one ESR zero. The quotient of the change in

switch current and the change in COMP pin voltage (node c in Figure 29) is the power stage transconductance,

gm_PS. The gm_PSfor the TPS54540-Q1 device is 17 A/V. The low-frequency gain of the power stage is the

product of the transconductance and the load resistance as shown in Equation 12.

As the load current increases and decreases, the low-frequency gain decreases and increases, respectively. This

variation with the load may seem problematic at first glance, but fortunately the dominant pole moves with the

load current (see Equation 13). The combined effect is highlighted by the dashed line in the right half of

Figure 30. As the load current decreases, the gain increases and the pole frequency lowers, keeping the 0-dB

crossover frequency the same with varying load conditions. The type of output capacitor chosen determines

whether the ESR zero has a profound effect on the frequency compensation design. Using high ESR aluminum

electrolytic capacitors may reduce the number frequency compensation components needed to stabilize the

overall loop because the phase margin is increased by the ESR zero of the output capacitor (see Equation 14).

V

O

Adc

VC

R

ESR

fp

R

L

gm

ps

C

OUT

fz

Figure 30. Simple Small Signal Model and Frequency Response for Peak Current Mode Control

æ

ç

è

ö

÷

ø

s

1+

2p´ f_Z

V_OUT

= Adc ´

V_C

æ

ç

è

ö

÷

ø

s

2p´ f_P

(11)

(12)

Adc = gm_ps´ R_L

1

f

=

P

C

´R ´ 2p

L

OUT

(13)

(14)

1

f

=

Z

C

´R

´ 2p

OUT

ESR

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Feature Description (continued)

7.3.17 Small Signal Model for Frequency Compensation

The TPS54540-Q1 uses a transconductance amplifier for the error amplifier and supports three of the commonly-

used frequency compensation circuits. Compensation circuits Type 2A, Type 2B, and Type 1 are shown in

Figure 31. Type 2 circuits are typically implemented in high bandwidth power-supply designs using low ESR

output capacitors. The Type 1 circuit is used with power-supply designs with high-ESR aluminum electrolytic or

tantalum capacitors. Equation 15 and Equation 16 relate the frequency response of the amplifier to the small

signal model in Figure 31. The open-loop gain and bandwidth are modeled using the R_Oand C_Oshown in

Figure 31. See the Typical Applications section for a design example using a Type 2A network with a low ESR

output capacitor.

Equation 15 through Equation 24 are provided as a reference. An alternative is to use WEBENCH software tools

to create a design based on the power supply requirements.

V

O

R1

FB

Type 2A

Type 2B

Type 1

gm

ea

R

COMP

Vref

C2

R3

C1

R3

R2

C2

C

O

C1

Figure 31. Types of Frequency Compensation

Aol

A0

P1

Z1

P2

A1

BW

Figure 32. Frequency Response of the Type 2A and Type 2B Frequency Compensation

Aol(V/V)

Ro =

gm_ea

2p ´ BW (Hz)

(15)

(16)

C_O

=

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Feature Description (continued)

æ

ç

è

ö

÷

ø

s

1+

2p´ f_Z1

EA = A0´

æ

ç

è

ö æ

ö

÷

ø

s

1+

´ 1+

÷ ç

2p´ f_P1

2p´ f_P2

ø è

(17)

(18)

(19)

R2

A0 = gm_ea´ Ro ´

R1 + R2

R2

R1 + R2

A1 = gm_ea´ Ro| | R3 ´

1

P1=

2p´Ro´ C1

(20)

1

Z1=

2p´R3´ C1

(21)

(22)

1

P2 =

type 2a

2p ´ R3 | | R_O´ (C2 + C_O)

1

P2 =

type 2b

2p ´ R3 | | R_O´ C_O

(23)

(24)

1

P2 =

type 1

2p ´ R_O´ (C2 + C_O

)

7.4 Device Functional Modes

The TPS54540-Q1 device is designed to operate with input voltages greater than 4.5 V. When the VIN voltage is

greater than the 4.3 V typical rising UVLO threshold and the EN voltage is above the 1.2 V typical threshold the

device is active. If the VIN voltage falls below the typical 4-V UVLO turnoff threshold, the device stops switching.

If the EN voltage falls below the 1.2-V threshold the device stops switching and enters a shutdown mode with low

supply current of 2 μA typical.

The TPS54540-Q1 device operates in CCM when the output current is enough to keep the inductor current

greater than 0 A at the end of each switching period. As a nonsynchronous converter, it will enter DCM at low-

output currents when the inductor current falls to 0 A before the end of a switching period. At very low-output

current the COMP voltage will drop to the pulse-skipping threshold and the device operates in a pulse-skipping

Eco-mode. In this mode, the high-side MOSFET does not switch every switching period. This operating mode

reduces power loss while keeping the output voltage regulated. For more information on Eco-mode, see the

Pulse-Skip Eco-mode section.

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8 Application 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 TPS54540-Q1 device is a 42-V, 5-A, step-down regulator with an integrated high-side MOSFET. This device

is typically used to convert a higher DC voltage to a lower DC voltage with a maximum available output current of

5 A. Example applications are: 12-V and 24-V industrial, automotive, and communications power systems. Use

the following design procedure to select component values for the TPS54540-Q1 device. This procedure

illustrates the design of a high-frequency switching regulator using ceramic output capacitors. Calculations can

be done with the excel spreadsheet (SLVC452) located on the product page. Alternately, use the WEBENCH

software to generate a complete design. The WEBENCH software uses an iterative design procedure and

accesses a comprehensive database of components when generating a design. This section presents a

simplified discussion of the design process.

8.2 Typical Applications

8.2.1 Buck Converter With 6-V to 42-V Input and 3.3-V at 5-A Output

L1

5.5 μH

VOUT

0.1 μF

C4

3.3V, 5A

C6

C7

U1

TPS54540B-Q1

D1

100 μF

B560 C

8

7

6

5

1

2

3

4

R5

31.6 kΩ

BOOT

SW

GND

COMP

FB

VIN

6V to 42V

C1

VIN

EN

C10

C3

C2

R1

FB

RT/CLK

365 kΩ

4.7 μF

R4

16.9 kΩ

9

C8

R6

10.2 kΩ

R2

R3

47pF

88.7 kΩ

243 kΩ

C5

4700 pF

Figure 33. 3.3-V Output TPS54540 Design Example

8.2.1.1 Design Requirements

This guide illustrates the design of a high-frequency switching regulator using ceramic output capacitors. A few

parameters must be known to start the design process. These requirements are typically determined at the

system level. This example in Figure 33 is designed with the known parameters listed in Table 1.

Table 1. Design Parameters

DESIGN PARAMETERS

EXAMPLE VALUE

Output Voltage

3.3 V

Transient Response 1.25-A to

3.75-A load step

ΔV_OUT= 4 %

Maximum Output Current

Input Voltage

5 A

12 V nom. 6 V to 42 V

0.5% of V_OUT

Output Voltage Ripple

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Table 1. Design Parameters (continued)

DESIGN PARAMETERS

Start Input Voltage (rising VIN)

Stop Input Voltage (falling VIN)

EXAMPLE VALUE

5.75 V

4.5 V

8.2.1.2 Detailed Design Procedure

8.2.1.2.1 Selecting the Switching Frequency

The first step is to choose a switching frequency for the regulator. Typically, the designer uses the highest

switching frequency possible because this produces the smallest solution size. High switching frequency allows

for lower value inductors and smaller output capacitors compared to a power supply that switches at a lower

frequency. The switching frequency that can be selected is limited by the minimum on-time of the internal power

switch, the input voltage, the output voltage and the frequency foldback protection.

Equation 9 and Equation 10 should be used to calculate the upper limit of the switching frequency for the

regulator (see Equation 25 and Equation 26). Choose the lower value result from the two equations. Switching

frequencies higher than these values results in pulse skipping or the lack of overcurrent protection during a short

circuit.

The typical minimum on time, t_onmin, is 135 ns for the TPS54540-Q1 device. Equation 9 and Equation 10 should

be used to calculate the upper limit of the switching for the regulator (see Equation 25 and Equation 26). For this

example, the output voltage is 3.3 V and the maximum input voltage is 42 V. Assuming a diode voltage of 0.52

V, inductor DC resistance of 10.3 mΩ, typical switch resistance of 92-mΩ and 5-A load, from Equation 9 the

maximum switch frequency to avoid pulse skipping is 680 kHz. To ensure overcurrent runaway is not a concern

during short circuits use Equation 10 to determine the maximum switching frequency for frequency fold-back

protection. With a current limit value of 6.3 A and short circuit output voltage of 0.1 V, the maximum switching

frequency is 960 kHz.

For this design, a lower switching frequency of 400 kHz is chosen to operate comfortably below the calculated

maximums. To determine the timing resistance for a given switching frequency, use Equation 7 or the curve in

Equation 7. The switching frequency is set by resistor R₃shown in Figure 33. For 400-kHz operation, the closest

standard value resistor is 243 kΩ (see Equation 27).

1

5 A x 10.3 mW + 3.3 V + 0.52 V

42 V - 5 A x 92 mW + 0.52 V

æ

ö

f_SW(maxskip)

=

´

= 680 kHz

ç

÷

135ns

è

ø

(25)

(26)

(27)

8

6.3 A x 10.3 mW + 0.1 V + 0.52 V

42 V - 6.3 A x 92 mW + 0.52 V

æ

ö

f_SW(shift)

=

´

= 960 kHz

ç

÷

135 ns

è

ø

101756

400 (kHz)^1.008

RT (kW) =

= 242 kW

8.2.1.2.2 Output Inductor Selection (L_O)

To calculate the minimum value of the output inductor, use Equation 28.

K_INDis a ratio that represents the amount of inductor ripple current relative to the maximum output current. The

inductor ripple current is filtered by the output capacitor. Therefore, choosing high inductor ripple currents

impacts the selection of the output capacitor because the output capacitor must have a ripple current rating equal

to or greater than the inductor ripple current. In general, the inductor ripple value is at the discretion of the

designer, however, the following guidelines may be used.

For designs using low ESR output capacitors such as ceramics, a value as high as K_IND= 0.3 may be desirable.

When using higher ESR output capacitors, K_IND= 0.2 yields better results. Because the inductor ripple current is

part of the current mode PWM control system, the inductor ripple current should always be greater than 150 mA

for stable PWM operation. In a wide input voltage regulator, it is best to choose relatively large inductor ripple

current. This provides sufficient ripple current with the input voltage at the minimum.

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For this design example, K_IND= 0.3 and the inductor value is calculated to be 5.1 μH. It is important that the RMS

current and saturation current ratings of the inductor not be exceeded. The RMS and peak inductor current can

be found from Equation 30 and Equation 31 (using Equation 29). For this design, the RMS inductor current is 5 A

and the peak inductor current is 5.79 A. The chosen inductor is a WE 744325550, which has a saturation current

rating of 12 A and an RMS current rating of 10 A. This inductor also has a typical inductance of 5.5 µH at no load

and 4.8 µH at a 5-A load. Lastly, the chosen inductor has a DCR of 10.3 mΩ.

As the equation set demonstrates, lower ripple currents will reduce the output voltage ripple of the regulator but

will require a larger value of inductance. Selecting higher ripple currents will increase the output voltage ripple of

the regulator but allow for a lower inductance value.

The current flowing through the inductor is the inductor ripple current plus the output current. During power-up,

faults or transient load conditions, the inductor current can increase above the peak inductor current level

calculated previously. In transient conditions, the inductor current can increase up to the switch current limit of

the device. For this reason, the most conservative design approach is to choose an inductor with a saturation

current rating equal to or greater than the switch current limit of the TPS54540 device, which is nominally 7.5 A.

V

- V_OUT

IN max

(

V_OUT

)

42 V - 3.3 V

5 A x 0.3

3.3 V

L_{O min}

=

´

=

´

= 5.1 mH

(

)

I_OUT´K_IND

V

´ f_SW

42 V ´ 400 kHz

IN max

(

)

(28)

(29)

spacer

I_RIPPLE

V

_OUT´(V

- V_OUT)

IN max

(

)

3.3 V x (42 V - 3.3 V)

=

= 1.58 A

V

´L_O´ f_SW

42 V x 4.8 mH x 400 kHz

IN max

(

)

spacer

2

æ

ö

2

V

´ V

- V

OUT

(

OUT

)

æ

ç

è

ö

÷

ø

IN max

(

3.3 V ´ 42 V - 3.3 V

)

(

)

1

ç

÷

1

2

I

=

I

(

+

´

=

5 A

+

´

= 5 A

)

( )

OUT

÷

L rms

(

)

12

V

´L ´ f

12

42 V ´ 4.8 mH ´ 400 kHz

O

SW

IN max

(

)

ç

÷

è

ø

(30)

spacer

I_{L peak}= I_OUT

I_RIPPLE

1.58 A

2

+

= 5 A +

= 5.79 A

(

)

2

(31)

8.2.1.2.3 Output Capacitor

There are three primary considerations for selecting the value of the output capacitor. The output capacitor

determines the modulator pole, the output voltage ripple, and how the regulator responds to a large change in

load current. The output capacitance must be selected based on the most stringent of these three criteria.

The desired response to a large change in the load current is the first criteria. The output capacitor needs to

supply the increased load current until the regulator responds to the load step. A regulator does not respond

immediately to a large, fast increase in the load current such as transitioning from no load to a full load. The

regulator usually needs two or more clock cycles for the control loop to sense the change in output voltage and

adjust the peak switch current in response to the higher load. The output capacitance must be large enough to

supply the difference in current for 2 clock cycles to maintain the output voltage within the specified range.

Equation 32 shows the minimum output capacitance necessary, where ΔI_OUTis the change in output current, ƒsw

is the regulators switching frequency and ΔV_OUTis the allowable change in the output voltage. For this example,

the transient load response is specified as a 4% change in V_OUTfor a load step from 1.25 A to 3.75 A. Therefore,

ΔI_OUTis 3.75 A – 1.25 A = 2.5 A and ΔV_OUT= 0.04 × 3.3 V = 0.13 V. Using these numbers gives a minimum

capacitance of 95 μF. This value does not take the ESR of the output capacitor into account in the output voltage

change. For ceramic capacitors, the ESR is usually small enough to be ignored. Aluminum electrolytic and

tantalum capacitors have higher ESR that must be included in load step calculations.

The output capacitor must also be sized to absorb energy stored in the inductor when transitioning from a high to

low load current. The catch diode of the regulator can not sink current so energy stored in the inductor can

produce an output voltage overshoot when the load current rapidly decreases. A typical load step response is

shown in Figure 38. The excess energy absorbed in the output capacitor will increase the voltage on the

capacitor. The capacitor must be sized to maintain the desired output voltage during these transient periods.

25

TPS54540B-Q1

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Equation 33 calculates the minimum capacitance required to keep the output voltage overshoot to a desired

value, where L_Ois the value of the inductor, I_OHis the output current under heavy load, I_OLis the output under

light load, V_fis the peak output voltage, and Vi is the initial voltage. For this example, the worst case load step

will be from 3.75 A to 1.25 A. The output voltage increases during this load transition and the stated maximum in

our specification is 4 % of the output voltage. This makes V_f= 1.04 × 3.3 V = 3.43 V. Vi is the initial capacitor

voltage that is the nominal output voltage of 3.3 V. Using these numbers in Equation 33 yields a minimum

capacitance of 68 μF.

Equation 34 calculates the minimum output capacitance needed to meet the output voltage ripple specification,

where ƒsw is the switching frequency, V_ORIPPLEis the maximum allowable output voltage ripple, and I_RIPPLEis the

inductor ripple current. Equation 34 yields 30 μF.

Equation 35 calculates the maximum ESR an output capacitor must meet the output voltage ripple specification.

Equation 35 indicates the equivalent ESR should be less than 10 mΩ.

The most stringent criteria for the output capacitor is 95 μF required to maintain the output voltage within

regulation tolerance during a load transient.

Capacitance deratings for aging, temperature and Eco-mode bias increases this minimum value. For this

example, 2 × 100-μF, 6.3-V type X5R ceramic capacitors with 2 mΩ of ESR will be used. The derated

capacitance is 130 µF, well above the minimum required capacitance of 95 µF.

Capacitors are generally rated for a maximum ripple current that can be filtered without degrading capacitor

reliability, especially non ceramic capacitors. Some capacitor data sheets specify the root mean square (RMS)

value of the maximum ripple current. Equation 36 can be used to calculate the RMS ripple current that the output

capacitor must support. For this example, Equation 36 yields 460 mA.

2´ DI

2 ´ 2.5 A

OUT

C

>

=

= 95 mF

OUT

f

´ DV

400 kHz x 0.13 V

SW

OUT

(32)

2

(_OH) (_OL)

2

3.75 A²-1.25 A²

I

-

I

(

)

(

)

= 68 mF

)

C_OUT> L_O

x

= 4.8 mH x

2

3.43 V²- 3.3 V²

V

-

V

I

( ) ( )

(

f

(

)

(33)

1

C

>

´

=

x

= 30 mF

OUT

8´ f

8 x 400 kHz

16 mV

1.58 A

æ

ç

è

ö

÷

ø

æ

ö

V

SW

ORIPPLE

ç

è

÷

ø

I

RIPPLE

16 mV

1.58 A

(34)

(35)

V

ORIPPLE

R

<

=

= 10 mW

ESR

I

RIPPLE

V

´ V

(

IN max

(

- V

OUT

)

=

IN max

(

3.3 V ´ 42 V - 3.3 V

)

(

)

12 ´ 42 V ´ 4.8 mH ´ 400 kHz

I

=

= 460 mA

COUT(rms)

12 ´ V

´L ´ f

O

SW

)

(36)

8.2.1.2.4 Catch Diode

The TPS54540 device requires an external catch diode between the SW pin and GND. The selected diode must

have a reverse voltage rating equal to or greater than V_IN(max). The peak current rating of the diode must be

greater than the maximum inductor current. Schottky diodes are typically a good choice for the catch diode due

to their low forward voltage. The lower the forward voltage of the diode, the higher the efficiency of the regulator.

Typically, diodes with higher voltage and current ratings have higher forward voltages. A diode with a minimum of

42-V reverse voltage is preferred to allow input voltage transients up to the rated voltage of the TPS54540-Q1

device.

For the example design, the PDS760-13 Schottky diode is selected for its lower forward voltage and good

thermal characteristics compared to smaller devices. The typical forward voltage of the PDS760-13 is 0.52 V at

5 A and 25°C.

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The diode must also be selected with an appropriate power rating. The diode conducts the output current during

the off-time of the internal power switch. The off-time of the internal switch is a function of the maximum input

voltage, the output voltage, and the switching frequency. The output current during the off-time is multiplied by

the forward voltage of the diode to calculate the instantaneous conduction losses of the diode. At higher

switching frequencies, the AC losses of the diode must be taken into account. The AC losses of the diode are

due to the charging and discharging of the junction capacitance and reverse recovery charge. Equation 37 is

used to calculate the total power dissipation, including conduction losses and AC losses of the diode.

The PDS760-13 diode has a junction capacitance of 300 pF. Using Equation 37, the total loss in the diode at the

nominal input voltage is 1.9 W.

If the power supply spends a significant amount of time at light load currents or in sleep mode, consider using a

diode, which has a low leakage current and slightly higher forward voltage drop.

2

)

V

(

- V_OUT´ I_OUT´ Vf d

)

C_j´ f_SW´ V + Vf d

IN max

(

)

IN

P_D=

+

=

V

2

IN

300 pF x 400 kHz x (12 V + 0.52 V)²

12 V - 3.3 V ´ 5 A x 0.52 V

(

)

12 V

+

= 1.9 W

2

(37)

8.2.1.2.5 Input Capacitor

The TPS54540-Q1 device requires a high quality ceramic type X5R or X7R input decoupling capacitor with at

least 3 μF of effective capacitance. Some applications will benefit from additional bulk capacitance. The effective

capacitance includes any loss of capacitance due to DC bias effects. The voltage rating of the input capacitor

must be greater than the maximum input voltage. The capacitor must also have a ripple current rating greater

than the maximum input current ripple of the TPS54540-Q1 device. The input ripple current can be calculated

using Equation 38.

The value of a ceramic capacitor varies significantly with temperature and the Eco-mode bias applied to the

capacitor. The capacitance variations due to temperature can be minimized by selecting a dielectric material that

is more stable over temperature. X5R and X7R ceramic dielectrics are usually selected for switching regulator

capacitors because they have a high capacitance to volume ratio and are fairly stable over temperature. The

input capacitor must also be selected with consideration for the DC bias. The effective value of a capacitor

decreases as the DC bias across a capacitor increases.

For this example design, a ceramic capacitor with at least a 42-V voltage rating is required to support transients

up to the maximum input voltage. Common standard ceramic capacitor voltage ratings include 4 V, 6.3 V, 10 V,

16 V, 25 V, 50 V or 100 V. For this example, four 4.7-μF, 50-V capacitors in parallel are used. Table 2 lists

several choices of high voltage capacitors.

The input capacitance value determines the input ripple voltage of the regulator. The maximum input voltage

ripple occurs at 50% duty cycle and can be calculated using Equation 39. Using the design example values,

I_OUT= 5 A, C_IN= 18.8 μF, ƒsw = 400 kHz, yields an input voltage ripple of 170 mV and a rms input ripple current

of 2.5 A.

V

- V

OUT

)

= 5 A

(

IN min

(

6 V - 3.3 V

)

V

(

)

3.3 V

6 V

OUT

I

= I

x

´

= 2.5 A

OUT

CI rms

(

)

V

6 V

IN min

(

IN min

(

)

(38)

(39)

I

´ 0.25

5 A ´ 0.25

18.8 mF ´ 400 kHz

OUT

DV

=

= 170 mV

IN

C

´ f

IN

SW

27

TPS54540B-Q1

ZHCSG12 –FEBRUARY 2017

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Table 2. Capacitor Types

VENDOR

VALUE (μF)

1 to 2.2

1 to 4.7

1

EIA SIZE

VOLTAGE

100 V

50 V

DIALECTRIC

COMMENTS

1210

GRM32 series

GRM31 series

Murata

100 V

50 V

1206

2220

2225

1812

1210

1812

1 to 2.2

1 to 1.8

1 to 1.2

1 to 3.9

1 to 1.8

1 to 2.2

1.5 to 6.8

1 to 2.2

1 to 3.3

1 to 4.7

1

50 V

100 V

50 V

Vishay

TDK

VJ X7R series

100 V

50 V

X7R

C series C4532

C series C3225

100 V

50 V

100 V

50 V

AVX

X7R dielectric series

1 to 4.7

1 to 2.2

100 V

8.2.1.2.6 Bootstrap Capacitor Selection

A 0.1-μF ceramic capacitor must be connected between the BOOT and SW pins for proper operation. A ceramic

capacitor with X5R or better grade dielectric is recommended. The capacitor should have a 10-V or higher

voltage rating.

8.2.1.2.7 Undervoltage Lockout Set Point

The undervoltage lockout (UVLO) can be adjusted using an external voltage divider on the EN pin of the

TPS54540-Q1device. The UVLO has two thresholds, one for power-up when the input voltage is rising and one

for power-down or brown outs when the input voltage is falling. For the example design, the supply should turn

on and start switching once the input voltage is greater than 5.75 V (UVLO start). After the regulator starts

switching, it should continue to do so until the input voltage falls below 4.5 V (UVLO stop).

Programmable UVLO threshold voltages are set using the resistor divider of R_UVLO1and R_UVLO2between V_INand

ground connected to the EN pin. Equation 4 and Equation 5 calculate the resistance values necessary. For the

example application, a 365 kΩ between V_INand EN (R_UVLO1) and a 88.7 kΩ between EN and ground (R_UVLO2) are

required to produce the 5.75-V and 4.5-V start and stop voltages.

V

- V

STOP

5.75 V - 4.5 V

START

R

=

= 368 kW

UVLO1

I

3.4 mA

HYS

(40)

(41)

V

1.2 V

5.75 V - 1.2 V

ENA

R

=

= 88.7 kW

UVLO2

V

- V

ENA

START

+1.2 mA

+ I

1

365 kW

R

UVLO1

8.2.1.2.8 Output Voltage and Feedback Resistors Selection

The voltage divider of R5 and R6 sets the output voltage. For the example design, 10.2 kΩ was selected for R6.

Using Equation 3, R5 is calculated as 31.9 kΩ. The nearest standard 1% resistor is 31.6 kΩ. Due to the input

current of the FB pin, the current flowing through the feedback network should be greater than 1 μA to maintain

the output voltage accuracy. This requirement is satisfied if the value of R6 is less than 800 kΩ. Choosing higher

resistor values decreases quiescent current and improves efficiency at low-output currents but may also

introduce noise immunity problems. For more details about adjusting the output voltage, see Equation 42.

V_OUT- 0.8 V

3.3 V - 0.8 V

æ

ö

R_HS= R_LS

x

= 10.2 kW x

= 31.9 kW

ç

÷

0.8 V

è

ø

(42)

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TPS54540B-Q1

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ZHCSG12 –FEBRUARY 2017

8.2.1.2.9 Minimum V_IN

To ensure proper operation of the device and to keep the output voltage in regulation, the input voltage at the

device must be above the value calculated with Equation 43 . Using the typical values for the R_DS(on), R_dcand V_F

in this application example, the minimum input voltage is 3.99 V. The BOOT-SW = 3 V curve in Figure 1 was

used for R_DS(on)= 0.12 Ω because the device will be operating with low drop out. When operating with low

dropout, the BOOT-SW voltage is regulated at a lower voltage because the BOOT-SW capacitor is not refreshed

every switching cycle. In the final application, the values of R_DS(on), R_dcand V_Fused in this equation must include

tolerance of the component specifications and the variation of these specifications at their maximum operating

temperature in the application.

In this application example the calculated minimum input voltage is near the input voltage UVLO for the

TPS54540B-Q1 so the device may turn off before going into drop out.

V_OUT+ V_F+ R_dcìI_OUT

V

min =

+ R_DSon ìI

- V_F

(

)

(

)

IN

OUT

0.99

3.3V + 0.5V + 0.0103Wì5A

0.99

V

min =

+ 0.12Wì5A - 0.5V = 3.99V

)

IN

(43)

8.2.1.2.10 Compensation

There are several methods to design compensation for DC-DC regulators. The method presented here is easy to

calculate and ignores the effects of the slope compensation that is internal to the device. Because the slope

compensation is ignored, the actual crossover frequency will be lower than the crossover frequency used in the

calculations. This method assumes the crossover frequency is between the modulator pole and the ESR zero

and the ESR zero is at least 10 times greater the modulator pole.

To get started, the modulator pole, ƒ_p(mod), and the ESR zero, ƒ_z1must be calculated using Equation 44 and

Equation 45. For C_OUT, use a derated value of 130 μF. Use equations Equation 46 and Equation 47 to estimate a

starting point for the crossover frequency, ƒco. For the example design, ƒ_p(mod)is 1850 Hz and ƒ_z(mod)is 610 kHz.

Equation 45 is the geometric mean of the modulator pole and the ESR zero and Equation 47 is the mean of

modulator pole and half of the switching frequency. Equation 46 yields 34 kHz and Equation 47 gives 19 kHz.

Use the geometric mean value of Equation 46 and Equation 47 for an initial crossover frequency. For this

example, after lab measurement, the crossover frequency target was increased to 30 kHz for an improved

transient response.

Next, the compensation components are calculated. A resistor in series with a capacitor is used to create a

compensating zero. A capacitor in parallel to these two components forms the compensating pole.

I_{OUT max}

(

)

5 A

f_{P mod}

=

2´ p´ V_OUT´ C_OUT2 ´ p ´ 3.3 V ´ 130 mF

= 1850 Hz

= 610 kHz

(

)

(44)

1

f

=

Z mod

(

)

2´ p´R

´ C

2 ´ p ´ 1 mW ´ 130 mF

ESR

OUT

(45)

(46)

f

=

f

=

1850 Hz x 610 kHz = 34 kHz

co1

p(mod) x z(mod)

f

400 kHz

SW

f

=

f

=

1850 Hz x

= 19 kHz

co2

p(mod) x

2

(47)

To determine the compensation resistor, R4, use Equation 48. The typical power stage transconductance, gmps,

is 17 A/V. The output voltage, V_O, reference voltage, V_REF, and amplifier transconductance, gmea, are 3.3 V,

0.8 V and 350 μA/V, respectively. R4 is calculated to be 17 kΩ and a standard value of 16.9 kΩ is selected. Use

Equation 49 to set the compensation zero to the modulator pole frequency. Equation 49 yields 5100 pF for

compensating capacitor C5. 4700 pF is used for this design.

æ

ç

è

ö

÷

ø

æ 2´ p´ f ´ C

ö

÷

ø

V

OUT

æ

ç

è

ö

÷

ø

2´ p´ 30 kHz ´ 130 mF

17 A / V

3.3V

æ

ö

co

OUT

R4 =

x

=

x

= 17 kW

ç

÷

gmps

V

x gmea

0.8 V x 350 mA / V

è

ø

è

REF

(48)

1

C5 =

=

= 5100 pF

2´ p´R4 x f

2´ p´16.9 kW x 1850 Hz

p(mod)

(49)

29

TPS54540B-Q1

ZHCSG12 –FEBRUARY 2017

www.ti.com.cn

A compensation pole can be implemented if desired by adding capacitor C8 in parallel with the series

combination of R4 and C5. Use the larger value calculated from Equation 50 and Equation 51 for C8 to set the

compensation pole. The selected value of C8 is 47 pF for this design example.

C

x R

ESR

130 mF x 1 mW

OUT

C8 =

=

= 15 pF

R4

16.9 k

W

(50)

(51)

1

C8 =

=

= 47 pF

R4 x f sw x p

16.9 kW x 400 kHz x p

8.2.1.2.11 Power Dissipation Estimate

The formulas in Equation 52 and Equation 58 show how to estimate the TPS54540-Q1 power dissipation under

continuous conduction mode (CCM) operation. These equations should not be used if the device is operating in

discontinuous conduction mode (DCM).

The power dissipation of the IC includes conduction loss (P_COND), switching loss (P_SW), gate drive loss (P_GD) and

supply current (P_Q). Example calculations are shown with the 12-V typical input voltage of the design example.

æ

ç

è

ö

÷

ø

V

5 V

2

OUT

P

= I

´R

´

= 5 A ´ 92 mW ´

= 0.958 W

(

)

COND

OUT

DS on

( )

V

12 V

IN

(52)

(53)

(54)

spacer

P

= V ´ f

´I

´ t

= 12 V ´ 400 kHz ´ 5 A ´ 4.9 ns = 0.118 W

rise

SW

IN

SW

OUT

spacer

P

= V ´ Q ´ f

= 12 V ´ 3nC´ 400 kHz = 0.014 W

SW

GD

IN

G

spacer

P

= V ´ I = 12 V ´ 146 mA = 0.0018 W

IN Q

Q

where

•

I_OUTis the output current (A)

R_DS(on)is the on-resistance of the high-side MOSFET (Ω)

V_OUTis the output voltage (V)

V_INis the input voltage (V)

fsw is the switching frequency (Hz)

trise is the SW pin voltage rise time and can be estimated by trise = V_IN× 0.16 ns/V + 3 ns

Q_Gis the total gate charge of the internal MOSFET

I_Qis the operating nonswitching supply current

(55)

(56)

(57)

Therefore,

P

= P

+ P

+ P + P = 0.958 W + 0.118 W + 0.014 W + 0.0018 W = 1.092 W

TOT

COND

SW GD Q

For given T_A,

T = T + R ´P

TOT

J

A

TH

For given T_JMAX= 150°C

T_{A max}= T_{J max}- R_TH´P_TOT

(

)

(

)

where

•

Ptot is the total device power dissipation (W)

T_Ais the ambient temperature (°C)

T_Jis the junction temperature (°C)

R_THis the thermal resistance of the package (°C/W)

T_JMAXis maximum junction temperature (°C)

T_AMAXis maximum ambient temperature (°C)

(58)

30

TPS54540B-Q1

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There will be additional power losses in the regulator circuit due to the inductor AC and Eco-mode losses, the

catch diode and PCB trace resistance impacting the overall efficiency of the regulator.

8.2.1.2.12 Safe Operating Area

The safe operating area (SOA) of the device is shown in Figure 34, through Figure 37 for 3.3-V, 5-V, and 12-V

outputs and varying amounts of forced air flow. The temperature derating curves represent the conditions at

which the TPS54540-Q1 device is at or below the maximum operating temperature. The device is soldered

directly to the EVM, which is a 4-layer double-sided PCB with 2-oz. copper. Careful attention must be paid to the

other components chosen for the design, especially the catch diode.

90

80

70

60

50

40

30

20

90

80

70

60

50

40

30

20

8 V

6 V

12 V

24 V

36 V

12 V

24 V

36 V

0.0 0.5 1.0 1.5 2.0 2.5 3.0 3.5 4.0 4.5 5.0

C047

C048

I_OUT(Amps)

Figure 34. 3.3-V Outputs

Figure 35. 5-V Outputs

90

80

70

60

50

40

30

20

90

80

70

60

50

40

30

20

400 LFM

200 LFM

100 LFM

Nat Conv

18 V

24 V

36 V

0.0 0.5 1.0 1.5 2.0 2.5 3.0 3.5 4.0 4.5 5.0

C048

I_OUT(Amps)

Figure 36. 12-V Outputs

Figure 37. Air Flow Conditions

V_IN= 36 V, V_O= 12 V

8.2.1.2.13 Discontinuous Conduction Mode and Eco-mode Boundary

With an input voltage of 12 V, the power supply enters discontinuous conduction mode when the output current

is less than 560 mA. The power supply enters Eco-mode when the output current is lower than 18 mA. The input

current draw is 240 μA with no load.

31

TPS54540B-Q1

ZHCSG12 –FEBRUARY 2017

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8.2.1.3 Application Curves

Measurements are taken with standard EVM using a 12-V input, 3.3-V output, and 5-A load unless otherwise noted.

IOUT

VIN

VOUT œ3.3V offset

Time = 4 ms/div

Time = 100 ms/div

Figure 39. Line Transient (8 V to 40 V)

Figure 38. Load Transient

VIN

EN

VOUT

Time = 20 ms/div

Time = 2 ms/div

Figure 40. Start-Up With VIN

Figure 41. Start-Up With EN

SW

IL

VOUT œ AC Coupled

I

= 100 mA

OUT

Time = 4 ms/div

Figure 43. Output Ripple DCM

Figure 42. Output Ripple CCM

32

TPS54540B-Q1

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Measurements are taken with standard EVM using a 12-V input, 3.3-V output, and 5-A load unless otherwise noted.

SW

IL

VOUT œ AC Coupled

No Load

VIN œ AC Coupled

Time = 1 ms/div

Time = 4 ms/div

Figure 44. Output Ripple PSM

Figure 45. Input Ripple CCM

SW

IL

SW

IL

VOUT = 5 V

VIN œ AC Coupled

No Load

EN Floating

I

= 100 mA

OUT

V

= 5.5 V

IN

Time = 4 ms/div

Time = 40 ms/div

Figure 46. Input Ripple DCM

Figure 47. Low Dropout Operation

100

90

80

70

60

50

40

30

20

10

0

100

95

90

85

80

75

70

65

60

IN=6V

V_IN= 7 V

V

= 12 V

IN=12V

IN

V_OUT= 5 V, fsw = 400 kHz

IN=24V

V_IN= 24 V

SVeri=es74V

1V2V= 12 V

IN

VIN=24V

V_IN= 36 V

V_OUT= 5 V, fsw = 400 kHz

V

= 24 V

24V

IN

3V6V= 36 V

IN

0.001

0.01

0.1

1

0

0.5

1

1.5

2

2.5

3

3.5

4

4.5

5

C024

I_O- Output Current (A)

C024

I_O- Output Current (A)

Figure 49. Light Load Efficiency

Figure 48. Efficiency vs Load Current

33

TPS54540B-Q1

ZHCSG12 –FEBRUARY 2017

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Measurements are taken with standard EVM using a 12-V input, 3.3-V output, and 5-A load unless otherwise noted.

100

95

90

85

80

75

70

65

60

100

90

80

70

60

50

40

30

20

10

0

VVIN==66VV

IN

V

= 12 V

V

= 12 V

VIN = 12 V

IN

V

= 24 V

V

= 24 V

VIN = 24 V

IN

ë_hÜÇ= 3.3 ë, fsw = 400 kIz

V

= 36 V

V

= 36 V

VIN = 36 V

IN

0

0.5

1

1.5

2

2.5

3

3.5

4

4.5

5

0.001

0.01

0.1

1

C050

C051

Load Current (A)

Figure 50. Efficiency vs Load Current

Figure 51. Light Load Efficiency

60

180

150

120

90

100

95

90

85

80

75

70

65

60

50

40

30

20

60

10

30

0

œ10

œ20

œ30

œ40

œ50

œ60

œ30

œ60

œ90

V

= 18 V

18in

IN

Gain

œ120

œ150

œ180

Series1

V_IN= 24 V

ë_Lb= 12 ë, ë_hÜÇ= 3.3 ë, L_hÜÇ= 5 !

Phase

100k 1M

V_OUT= 12 V, fsw = 800 kHz

Series3

V_IN= 36 V

10

100

1k

10k

0

0.5

1

1.5

2

2.5

3

3.5

4

4.5

5

C053

Frequency (Hz)

C024

I_O- Output Current (A)

Figure 52. Efficiency vs Output Current

Figure 53. Overall Loop Frequency Response

0.5

0.4

0.3

0.2

0.1

0

0.20

0.15

ë_Lb= 12 ë, L_hÜÇ= 5 !, fsw = 400 kIz

0.10

0.05

0.00

œ0.05

œ0.10

œ0.15

œ0.20

-0.1

-0.2

-0.3

-0.4

ë_Lb= 12 ë, ë_hÜÇ= 3.3 ë, fsw = 400 kIz

0

0.5

1

1.5

2

2.5

3

3.5

4

4.5

5

0

5

10

15

20

25

30

35

40

45

C054

C055

Output Current (A)

Input Voltage (V)

Figure 54. Regulation vs Load Current

Figure 55. Regulation vs Input Voltage

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8.2.2 Inverting Buck-Boost Topology for Positive Input to Negative Output

The TPS54540-Q1 device can be used to convert a positive input voltage to a split-rail positive and negative

output voltage by using a coupled inductor. Example applications are amplifiers requiring a split-rail positive and

negative voltage power supply. For a more detailed example, see SLVA317.

VIN

+

C_IN

C_BOOT

SW

L_O

GND

BOOT

VIN

C_D

R1

R2

+

GND

C_O

VOUT

FB

TPS54540B-Q1

EN

COMP

R_COMP

RT/CLK

RT

C_ZERO

C_POLE

Figure 56. TPS54540-Q1 Inverting Power Supply from SLVA317 Application Note

8.2.3 Split-Rail Power Supply

The TPS54540-Q1 device can be used to convert a positive input voltage to a split-rail positive and negative

output voltage by using a coupled inductor. Example applications are amplifiers requiring a split-rail positive and

negative voltage power supply. For a more detailed example, see SLVA369.

VOPOS

+

C_OPOS

VIN

+

C_IN

C_BOOT

GND

SW

BOOT

VIN

Lo

C_D

R1

R2

+

GND

C_ONEG

TPS54540B-Q1

FB

VONEG

EN

COMP

R_COMP

C_POLE

RT /CLK

RT

C_ZERO

Figure 57. TPS54540-Q1 Split Rail Power Supply Based on the SLVA369 Application Note

35

TPS54540B-Q1

ZHCSG12 –FEBRUARY 2017

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9 Power Supply Recommendations

The device is designed to operate from an input voltage supply range from 4.5 V to 42 V. This input supply must

remain within this range. If the input supply is located more than a few inches from the TPS54540-Q1 converter,

additional bulk capacitance may be required in addition to the ceramic bypass capacitors. An electrolytic

capacitor with a value of 100 μF is a typical choice.

10 Layout

10.1 Layout Guidelines

Layout is a critical portion of good power supply design. There are several signal paths that conduct fast

changing currents or voltages that can interact with stray inductance or parasitic capacitance to generate noise

or degrade performance. To reduce parasitic effects, the VIN pin should be bypassed to ground with a low-ESR

ceramic bypass capacitor with X5R or X7R dielectric. Take care to minimize the loop area formed by the bypass

capacitor connections, the VIN pin, and the anode of the catch diode. See Figure 58 for a PCB layout example.

The GND pin should be tied directly to the power pad under the IC and the power pad.

The power pad must be connected to internal PCB ground planes using multiple vias directly under the IC. The

SW pin should be routed to the cathode of the catch diode and to the output inductor. Because the SW

connection is the switching node, the catch diode and output inductor must be located close to the SW pins, and

the area of the PCB conductor minimized to prevent excessive capacitive coupling. For operation at full rated

load, the top side ground area must provide adequate heat dissipating area. The RT/CLK pin is sensitive to noise

so the RT resistor should be located as close as possible to the IC and routed with minimal lengths of trace. The

additional external components can be placed approximately as shown. It may be possible to obtain acceptable

performance with alternate PCB layouts; however, this layout has been shown to produce good results and is

meant as a guideline.

10.2 Layout Example

Vout

Output

Capacitor

Output

Inductor

Topside

Ground

Route Boot Capacitor

Catch

Area

Trace on another layer to

provide wide path for

topside ground

Diode

Input

Bypass

Capacitor

BOOT

VIN

SW

GND

COMP

FB

Vin

EN

UVLO

RT/CLK

Compensation

Network

Adjust

Resistor

Divider

Resistors

Frequency

Thermal VIA

Signal VIA

Set Resistor

Figure 58. PCB Layout Example

36

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ZHCSG12 –FEBRUARY 2017

10.3 Estimated Circuit Area

Boxing in the components in the design of Figure 33 the estimated printed-circuit-board area is 1.025 in²

(661 mm²). This area does not include test points or connectors. If the area needs to be reduced, this can be

done by using a two sided assembly and replacing the 0603 sized passives with a smaller sized equivalent.

11 器件和文档支持

11.1 器件支持

11.1.1 开发支持

有关 TPS54360 和 TPS54361 系列设计 Excel 工具，请参阅以下资料：

•

设计计算器 zip 文件 (SLVC452)

11.1.2 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 文档支持

11.2.1 相关文档

请参阅如下相关文档：

•

《利用 TPS54260 创建 GSM 电源》(SLVA412)

《利用 TPS54240 和 TPS2511 创建供 USB 设备使用的通用车载充电器》(SLVA464)

《利用降压稳压器创建反向电源》(SLVA317)

《使用宽输入电压降压稳压器创建分裂轨电源》(SLVA369)

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 商标

Eco-mode, PowerPAD, E2E are trademarks of Texas Instruments.

WEBENCH is a registered trademark of Texas Instruments.

All other trademarks are the property of their respective owners.

11.5 静电放电警告

这些装置包含有限的内置 ESD 保护。存储或装卸时，应将导线一起截短或将装置放置于导电泡棉中，以防止 MOS 门极遭受静电损

伤。

11.6 Glossary

SLYZ022 — TI Glossary.

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

37

TPS54540B-Q1

ZHCSG12 –FEBRUARY 2017

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12 机械、封装和可订购信息

以下页面包括机械、封装和可订购信息。这些信息是指定器件的最新可用数据。这些数据发生变化时，我们可能不

会另行通知或修订此文档。如欲获取此产品说明书的浏览器版本，请参见左侧的导航栏。

38

GENERIC PACKAGE VIEW

DDA 8

PowerPAD^TMSOIC - 1.7 mm max height

PLASTIC SMALL OUTLINE

Images above are just a representation of the package family, actual package may vary.

Refer to the product data sheet for package details.

4202561/G

重要声明和免责声明

TI 均以“原样”提供技术性及可靠性数据（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

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所述资源可供专业开发人员应用TI 产品进行设计使用。您将对以下行为独自承担全部责任：(1) 针对您的应用选择合适的TI 产品；(2) 设计、

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邮寄地址：上海市浦东新区世纪大道 1568 号中建大厦 32 楼，邮政编码：200122


型号：	TPS54540BQDDARQ1
厂家：	TEXAS INSTRUMENTS
描述：	具有 Eco-Mode™ 的 4.5V 至 42V 输入、5A、降压直流/直流转换器 \| DDA \| 8 \| -40 to 125 开关光电二极管输出元件转换器
文件：	总45页 (文件大小：2838K)
中文：	中文翻译
下载：	下载PDF数据表文档文件

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