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TPS2549

ZHCSFL0 –SEPTEMBER 2016

TPS2549 具有电缆补偿功能的 USB 充电端口控制器和电源开关

1 特性

充电电流过大也依然有效。这对于 USB 电缆较长的系

统而言至关重要，因为该系统在对便携式设备进行快速

充电的过程中会产生大幅压降。

1

•

4.5V 至 6.5V 的工作范围

•

47mΩ（典型值）高侧金属氧化物半导体场效应晶

体管 (MOSFET)

TP2549 47mΩ 电源开关具有两个可选的可编程电流限

值，可通过在相邻端口承载高负载时提供较低电流限值

来支持端口电源管理。这对于具有多个端口并且上行电

源无法同时为所有端口提供满载电流的系统而言至关重

要。

•

最大连续开关电流达 3A

用于电缆补偿的 ±5% 电流感测 (CS) 输出

充电下行端口 (CDP) 模式符合 USB 电池充电规范

1.2

•

自动专用充电端口 (DCP) 模式选择：

–

短路模式符合 BC1.2 和 YD/T 1591-2009

2.7V 分压器 3 模式

DCP_Auto 方案通过检测并选择合适的 D+ 和 D– 设定

与所连设备进行通信，以便在满载电流条件下完成快速

充电。集成的 CDP 检测支持针对多数采用同步数据通

信的便携式设备进行快速充电，充电电流高达 1.5A。

1.2V 模式

•

面向系统更新的 D+ 和 D– 客户端模式

D+ 和 D– V_BUS短路保护

独特的客户端模式功能允许将软件更新为客户端设备，

同时在保持数据线连接的情况下通过关闭内部电源开关

来避免电源冲突。

D+ 和 D– ±8kV 接触放电和 ±15kV 空气放电 ESD

额定值 (IEC 61000-4-2)

•

UL 认证和 CB 认证正在审理中

此外，TPS2549 器件集成了针对 D+ 和 D- 的 V_BUS短

路保护功能，可避免在 D+ 和/或 D- 与 V_BUS之间意外

短路时造成损坏。为了节省应用空间，TPS2549 器件

还集成了 ESD 保护功能，无需在 D+ 和 D- 上应用外

部电路即可符合 IEC61000-4-2 标准。

运行结温范围：-40°C 至 125°C

16 引脚 3mm x 3mm 四方扁平无引线 (QFN) 封装

2 应用

•

USB 端口（主机和集线器）

壁式充电适配器

器件信息⁽¹⁾

汽车售后加装充电器

器件型号

TPS2549

封装

WQFN (16)

封装尺寸（标称值）

3.00mm x 3.00mm

3 说明

(1) 要了解所有可用封装，请见数据表末尾的可订购产品附录。

TPS2549 器件是一款 USB 充电端口控制器和电源开

关，其带有可控制上行电源的电流感测输出。该器件可

使 USB 端口电压维持在 5V 水平，即使

简化电路原理图

R_(CABLE1)

4.5 V to 6.5 V

0.1 µF

V_(BAT)

5 V

IN

OUT

Voltage

Regulator

R_(STATUS)

C_(OUT)

C_(COMP)

R_(FAULT)

TPS2549

R_(FA)

LMR14030

LM53603

LM25117

TPS54340

DM_IN

DP_IN

R_(CABLE2)

FAULT

R_(FB)

STATUS

GND

STATUS

CS

FB

ILIM_LO

ILIM_HI

EN

Power Switch EN

Mode Select I/O

R_(G)

CTL1

R_HI

R_LO

DM_OUT

DP_OUT

To Host

Controller

GND

CTL2

CTL3

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: SLUSCP2

TPS2549

ZHCSFL0 –SEPTEMBER 2016

www.ti.com.cn

8.3 Feature Description................................................. 17

8.4 Device Functional Modes........................................ 24

Application and Implementation ........................ 28

9.1 Application Information............................................ 28

9.2 Typical Application ................................................. 28

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.................................................. 5

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

6.6 Switching Characteristics.......................................... 8

6.7 Typical Characteristics.............................................. 8

Parameter Measurement Information ................ 14

Detailed Description ............................................ 15

8.1 Overview ................................................................. 15

8.2 Functional Block Diagram ....................................... 16

9

10 Power Supply Recommendations ..................... 33

11 Layout................................................................... 33

11.1 Layout Guidelines ................................................. 33

11.2 Layout Example .................................................... 34

12 器件和文档支持 ..................................................... 35

12.1 文档支持................................................................ 35

12.2 接收文档更新通知 ................................................. 35

12.3 社区资源................................................................ 35

12.4 商标....................................................................... 35

12.5 静电放电警告......................................................... 35

12.6 Glossary................................................................ 35

13 机械、封装和可订购信息....................................... 36

7

8

4 修订历史记录

日期

修订版本

注释

2016 年 9 月

*

最初发布版本。

2

TPS2549

www.ti.com.cn

ZHCSFL0 –SEPTEMBER 2016

5 Pin Configuration and Functions

RTE Package

16-Pin WQFN

Top View

IN

DM_OUT

DP_OUT

CS

1

2

3

4

12

11

10

9

OUT

DM_IN

DP_IN

STATUS

Thermal

Pad

Pin Functions

TYPE⁽¹⁾

DESCRIPTION

NAME

NO.

Provide sink current proportional to output current. For cable compensation, connect to the

feedback divider of the up-stream voltage regulator.

CS

4

O

CTL1

6

7

I

Logic-level control inputs for controlling the charging mode and the signal switches; (see

Table 2). These pins tie directly to IN or GND without a pullup or pulldown resistor.

CTL2

I

CTL3

8

I

DM_IN

DM_OUT

DP_IN

DP_OUT

11

2

I/O

D– data line to downstream connector

D– data line to upstream USB host controller

D+ data line to downstream connector

D+ data line to upstream USB host controller

10

3

Logic-level control input for turning the power switch and the signal switches on/off. When

EN is low, the device is disabled, the signal and power switches are OFF.

EN

5

I

Active-low open-drain output, asserted during overtemperature, overcurrent, and DP_IN and

DM_IN overvoltage conditions. See Table 1.

FAULT

13

O

GND

14

16

—

I

Ground connection; should be connected externally to the thermal pad.

Connect external resistor to ground to set the high current-limit threshold.

ILIM_HI

Connect external resistor to ground to set the low current-limit threshold and the load-

detection current threshold.

ILIM_LO

IN

15

1

I

Input supply voltage; connect a 0.1 µF or greater ceramic capacitor from IN to GND as close

to the IC as possible.

PWR

OUT

12

9

PWR

O

Power-switch output

STATUS

Active-low open-drain output, asserted when the load exceeds the load-detection threshold

Thermal pad on bottom of package. The thermal pad is internally connected to GND and is

used to heat-sink the device to the circuit board. Connect the thermal pad to the GND plane.

Thermal pad

—

(1) I = Input, O = Output, I/O = Input and output, PWR = Power

3

TPS2549

ZHCSFL0 –SEPTEMBER 2016

www.ti.com.cn

6 Specifications

6.1 Absolute Maximum Ratings

Voltages are with respect to GND unless otherwise noted⁽¹⁾

MIN

MAX

UNIT

CS, CTL1, CTL2, CTL3, EN, FAULT, ILIM_HI,

–0.3

7

V

ILIM_LO, IN, OUT, STATUS

DM_IN, DM_OUT, DP_IN, DP_OUT

IN to OUT

Voltage range

–0.3

–7

5.7

7

V

Continuous current in SDP,

CDP or client mode

DP_IN to DP_OUT or DM_IN to DM_OUT

–100

–35

100

35

mA

Continuous current in BC1.2

DCP mode

DP_IN to DM_IN

OUT

mA

A

Continuous output current

Internally limited

Continuous output source

current

I_(SRC)

ILIM_HI, ILIM_LO

A

FAULT, STATUS

CS

25

mA

A

I_(SNK)Continuous output sink current

Internally limited

T_J

Operating junction temperature

Storage temperature

–40 Internally limited

–65 150

°C

T_stg

(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

±2,000

±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

IEC61000-4-2 contact discharge, DP_IN and DM_IN

IEC⁽³⁾

±8,000

±15,000

IEC61000-4-2 air discharge, DP_IN and DM_IN

(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.

(3) Surges per IEC61000-4-2, 1999 applied between DP_IN/DM_IN and output ground of the TPS2549Q1EVM-729 (SLVUAK6) evaluation

module.

6.3 Recommended Operating Conditions

Voltages are with respect to GND unless otherwise noted.

MIN

4.5

0

NOM

MAX

6.5

3.6

3

UNIT

V_(IN)

Supply voltage

IN

V

A

CTL1, CTL2, CTL3, EN

DM_IN, DM_OUT, DP_IN, DP_OUT

OUT (–40°C ≤ T_A≤ 85°C)

Input voltage

0

I_(OUT)

Output continuous current

Continuous current in SDP, CDP or

client mode

DP_IN to DP_OUT or DM_IN to DM_OUT

–30

–15

30

15

mA

Continuous current in BC1.2 DCP

mode

DP_IN to DM_IN

FAULT, STATUS

Continuous output sink current

10

1000

125

mA

kΩ

°C

R_{(ILIM_xx)}Current limit-set resistors

T_JOperating junction temperature

15.4

–40

4

TPS2549

www.ti.com.cn

ZHCSFL0 –SEPTEMBER 2016

6.4 Thermal Information

TPS2549

THERMAL METRIC⁽¹⁾

RTE (WQFN)

UNIT

16 PINS

44.9

53.3

17.6

1

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

ψ_JT

Junction-to-top characterization parameter

Junction-to-board characterization parameter

Junction-to-case (bottom) thermal resistance

ψ_JB

17.6

4.1

R_θJC(bot)

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

report, SPRA953.

6.5 Electrical Characteristics

Unless otherwise noted, –40°C ≤ T_J≤ 125°C and 4.5 V ≤ V_(IN)≤ 6.5 V, V_(EN)= V_(IN), V_(CTL1)= V_(CTL2)= V_(CTL3)= V_(IN). R_(FAULT)

R_(STATUS)= 10 kΩ, R_{(ILIM_HI)}= 19.1 kΩ, R_{(ILIM_LO)}= 80.6 kΩ. Positive currents are into pins. Typical values are at 25°C. All

voltages are with respect to GND.

=

PARAMETER

OUT – POWER SWITCH

TEST CONDITIONS

MIN

TYP

MAX UNIT

T_J= 25°C

47

57

r_DS(on)

On-resistance⁽¹⁾

–40°C ≤ T_J≤ 85°C

–40°C ≤T_J≤ 125°C

72 mΩ

80

Reverse leakage current on V_OUT= 6.5 V, V_IN= V_EN= 0 V, –40°C ≤ T_J≤ 85°C,

I_lkg(OUT)

2

µA

OUT pin

measure I_(OUT)

OUT - DISCHARGE

R_(DCHG)

OUT discharge resistance

400

500

630

Ω

EN, CTL1, CTL2, CTL3 INPUTS

Input pin rising logic

1

1.35

2

V

threshold voltage

Input pin falling logic

threshold voltage

Hysteresis⁽²⁾

0.85

1.15

200

1.65

mV

µA

Input current

Pin voltage = 0 V or 6.5 V

–1

1

CURRENT LIMIT

R_{(ILIM_LO)}= 210 kΩ

R_{(ILIM_LO)}= 80.6 kΩ

R_{(ILIM_LO)}= 23.2 kΩ

R_{(ILIM_HI)}= 20 kΩ

205

600

255

660

305

720

2145

2500

2620

3255

5500

2300

2670

2800

3470

7000

2455

2840

2975

3685

8000

OUT short-circuit current

limit

I_OS

mA

R_{(ILIM_HI)}= 19.1 kΩ

R_{(ILIM_HI)}= 15.4 kΩ

R_{(ILIM_HI)}shorted to GND

SUPPLY CURRENT

I_{(IN_OFF)}

Disabled IN supply current V_(EN)= 0 V, V_(OUT)= 0 V, –40°C ≤ T_J≤ 85°C

0.1

220

226

150

115

5

300

220

190

µA

V_(CTL)1= V_(CTL2)= V_(CTL3)= V_(IN)

V_(CTL1)= V_(CTL2)= 0 V, V_(CTL3)= V_(IN)

Enabled IN supply current

I_{(IN_ON)}

V_(CTL2)= V_(IN), V_(CTL1)= V_(CTL3)= 0 V

V_(CTL1)= V_(IN), V_(CTL2)= V_(CTL3)= 0 V

(1) Pulse-testing techniques maintain junction temperature close to ambient temperature. Thermal effects must be taken into account

separately.

(2) These parameters are provided for reference only and do not constitute part of TI's published device specifications for purposes of TI's

product warranty.

5

TPS2549

ZHCSFL0 –SEPTEMBER 2016

www.ti.com.cn

Electrical Characteristics (continued)

Unless otherwise noted, –40°C ≤ T_J≤ 125°C and 4.5 V ≤ V_(IN)≤ 6.5 V, V_(EN)= V_(IN), V_(CTL1)= V_(CTL2)= V_(CTL3)= V_(IN). R_(FAULT)

R_(STATUS)= 10 kΩ, R_{(ILIM_HI)}= 19.1 kΩ, R_{(ILIM_LO)}= 80.6 kΩ. Positive currents are into pins. Typical values are at 25°C. All

voltages are with respect to GND.

=

PARAMETER

TEST CONDITIONS

MIN

TYP

MAX UNIT

UNDERVOLTAGE LOCKOUT, IN

IN rising UVLO threshold

voltage

V_(UVLO)

3.9

4.1

4.3

V

Hysteresis⁽³⁾

T_J= 25°C

100

mV

FAULT

Output low voltage

Off-state leakage

I_(FAULT)= 1 mA

V_(FAULT)= 6.5 V

100

2

mV

µA

STATUS

Output low voltage

Off-state leakage

I_(STATUS)= 1 mA

V_(STATUS)= 6.5 V

100

2

mV

µA

THERMAL SHUTDOWN

Thermal shutdown

T_(OTSD2)

155

135

°C

threshold

Thermal shutdown

threshold in current-limit

T_(OTSD1)

°C

Hysteresis⁽³⁾

20

LOAD DETECT (V_CTL1= V_CTL2= V_CTL3= V_IN

)

I_OUTload detection

threshold

Hysteresis⁽³⁾

I_(LD)

R_{(ILIM_LO)}= 80.6 kΩ, rising load current

630

700

50

770

mA

DP_IN AND DM_IN SHORT-TO-V_BUSPROTECTION

Overvoltage protection trip

threshold

Hysteresis⁽³⁾

V_(OV)

DP_IN and DM_IN rising

3.7

3.9

100

210

4.15

240

V

mV

kΩ

Discharge resistance after

OVP

R_{(DCHG_Data)}

V_{(DP_IN)}= V_{(DM_IN)}= 5 V

160

CABLE COMPENSATION

Load = 3 A, 2.5 V ≤ V_(CS)≤ 6.5 V

Load = 2.4 A, 2.5 V ≤ V_(CS)≤ 6.5 V

Load = 2.1 A, 2.5 V ≤ V_(CS)≤ 6.5 V

Load = 1 A, 2.5 V ≤ V_(CS)≤ 6.5 V

214

171

149

70

225

180

158

75

236

189

166

80

I_(CS)

Sink current

µA

(3) These parameters are provided for reference only and do not constitute part of TI's published device specifications for purposes of TI's

product warranty.

6

TPS2549

www.ti.com.cn

ZHCSFL0 –SEPTEMBER 2016

Electrical Characteristics (continued)

Unless otherwise noted, –40°C ≤ T_J≤ 125°C and 4.5 V ≤ V_(IN)≤ 6.5 V, V_(EN)= V_(IN), V_(CTL1)= V_(CTL2)= V_(CTL3)= V_(IN). R_(FAULT)

=

R_(STATUS)= 10 kΩ, R_{(ILIM_HI)}= 19.1 kΩ, R_{(ILIM_LO)}= 80.6 kΩ. Positive currents are into pins. Typical values are at 25°C. All

voltages are with respect to GND.

PARAMETER

TEST CONDITIONS

MIN

TYP

MAX UNIT

HIGH-BANDWIDTH ANALOG SWITCH

V_{(DP_OUT)}= V_{(DM_OUT)}= 0 V, I_{(DP_IN)}= I_{(DM_IN)}

30 mA

=

2

2.9

4

DP and DM switch on-

resistance

R_{(HS_ON)}

Ω

V_{(DP_OUT)}= V_{(DM_OUT)}= 2.4 V, I_{(DP_IN)}= I_{(DM_IN)}

–15 mA

=

6

V_{(DP_OUT)}= V_{(DM_OUT)}= 0 V, I_{(DP_IN)}= I_{(DM_IN)}

30 mA

=

0.05

6.7

0.15

Ω

Switch resistance mismatch

between DP and DM

channels

|ΔR_{(HS_ON)}

|

V_{(DP_OUT)}= V_{(DM_OUT)}= 2.4 V, I_{(DP_IN)}= I_{(DM_IN)}

–15 mA

0.15

DP/DM switch off-state

capacitance⁽⁴⁾

V_EN= 0 V, V_{(DP_IN)}= V_{(DM_IN)}= 0.3 V,

Vac = 0.03 V_PP, f = 1 MHz

C_{(IO_OFF)}

C_{(IO_ON)}

pF

DP/DM switch on-state

capacitance⁽⁴⁾

Off-state isolation⁽⁴⁾

V_{(DP_IN)}= V_{(DM_IN)}= 0.3 V,

Vac = 0.03 V_PP, f = 1 MHz

10

27

23

pF

dB

V_EN= 0 V, f = 250 MHz

On-state cross-channel

isolation⁽⁴⁾

f = 250 MHz

Off-state leakage current,

DP_OUT and DM_OUT

Bandwidth (–3 dB)⁽⁴⁾

V_EN= 0 V, V_{(DP_IN)}= V _{(DM_IN)}= 3.6 V, V_{(DP_OUT)}

= V_{(DM_OUT)}= 0 V

I_lkg(OFF)

BW

0.1

1.5

µA

R_(L)= 50 Ω

925

MHz

CHARGING DOWNSTREAM PORT DETECT

V_{(DM_SRC)}

DM_IN CDP output voltage V_{(DP_IN)}= 0.6 V, –250 µA < I_{(DM_IN)}< 0 µA

0.5

0.6

50

0.7

0.4

V

DP_IN rising lower window

threshold for V_{DM_SRC}

activation

Hysteresis⁽⁴⁾

V_{(DAT_REF)}

0.36

mV

V

DP_IN rising upper window

threshold for VDM_SRC

de-activation

Hysteresis⁽⁴⁾

V_{(LGC_SRC)}

0.8

40

0.88

V_{(LGC_SRC_HYS)}

I_{(DP_SINK)}

100

75

mV

µA

DP_IN sink current

V_{(DP_IN)}= 0.6 V

100

200

BC1.2 DCP MODE

DP_IN and DM_IN shorting

resistance

R_{(DPM_SHORT)}

125

Ω

DIVIDER3 MODE

V_{(DP_DIV3)}

DP_IN output voltage

DM_IN output voltage

DP_IN output impedance

DM_IN output impedance

2.57

24

2.7

30

2.84

36

V

V_{(DM_DIV3)}

R_{(DP_DIV3)}

I_{(DP_IN)}= –5 µA

I_{(DM_IN)}= –5 µA

kΩ

R_{(DM_DIV3)}

1.2-V MODE

V_{(DP_1.2V)}

24

30

36

DP_IN output voltage

DM_IN output voltage

DP_IN output impedance

DM_IN output impedance

1.12

84

1.2

1.26

126

V

V_{(DM_1.2V)}

R_{(DP_1.2V)}

I_{(DP_IN)}= –5 µA

I_{(DM_IN}= –5 µA

100

kΩ

R_{(DM_1.2V)}

84

(4) These parameters are provided for reference only and do not constitute part of TI's published device specifications for purposes of TI's

product warranty.

7

TPS2549

ZHCSFL0 –SEPTEMBER 2016

www.ti.com.cn

6.6 Switching Characteristics

Unless otherwise noted –40°C ≤ T_J≤ 125°C and 4.5 V ≤ V_(IN)≤ 6.5 V, V_(EN)= V_(IN), V_(CTL1)= V_(CTL2)= V_(CTL3)= V_(IN). R_(FAULT)

=

R(_STATUS)= 10 kΩ, R_{(ILIM_HI)}= 19.1 kΩ, R_{(ILIM_LO)}= 80.6 kΩ. Positive current is into pins. Typical value is at 25°C. All voltages

are with respect to GND.

PARAMETER

TEST CONDITIONS

MIN

0.7

TYP

1.14

0.35

4.15

1.8

MAX UNIT

t_r

OUT voltage rise time

OUT voltage fall time

OUT voltage turnon time

OUT voltage turnoff time

2

0.6

6

ms

V_(IN)= 5 V, C_(L)= 1 µF, R_(L)= 100 Ω (see

Figure 32 and Figure 33)

t_f

0.2

t_on

t_off

V_(IN)= 5 V, C_(L)= 1 µF, R_(L)= 100 Ω (see

Figure 32 andFigure 35)

3

Long OUT discharge hold

time (SDP, CDP, or client

mode to DCP_Auto)

t_{(DCHG_L)}

Time V_(OUT)< 0.7 V (see Figure 34)

1.1

2

2.9

s

Short OUT discharge hold

time (DCP_Auto to SDP,

CDP, or client mode)

t_{(DCHG_S)}

Time V_(OUT)< 0.7 V (see Figure 34)

186

320

450

ms

OUT short-circuit response

time⁽¹⁾

t_(IOS)

V_(IN)= 5 V, R_(SHORT)= 50 mΩ (see Figure 25)

2

8

µs

ms

ns

Bidirectional deglitch applicable to current limit

condition only (no deglitch assertion for OTSD)

t_{(OC_OUT_FAULT)}

t_pd

OUT FAULT deglitch time

5.5

11.5

Analog switch propagation

V_(IN)= 5 V

0.14

(1)

delay

Analog switch skew

between opposite

t_(SK)

V_(IN)= 5 V

0.02

ns

transitions of the same port

(1)

(t_PHL– t_PLH

)

t_{(LD_SET)}

Load-detect set time

Load-detect reset time

DP_IN and DM_IN over-

V_(IN)= 5 V (See Figure 27)

V_(IN)= 5 V (See Figure 28)

120

1.8

210

3

280

4.2

ms

s

t_{(LD_RESET)}

t_{(OV_D)}

voltage protection response V_(OUT)= 5 V (See Figure 29)

time

2

µs

DP_IN and DM_IN FAULT

V_(OUT)= 5 V (See Figure 30)

degltich time

t_{(OV_D_FAULT)}

11

16

23

ms

(1) These parameters are provided for reference only and do not constitute part of TI's published device specifications for purposes of TI's

product warranty.

6.7 Typical Characteristics

70

65

60

55

50

45

40

35

30

0.6

0.5

0.4

0.3

0.2

0.1

0

-0.1

-40 -25 -10

5

20 35 50 65 80 95 110 125

Junction Temperature (ºC)

-40 -25 -10

5

20 35 50 65 80 95 110 125

Junction Temperature (ºC)

D001

D002

V_IN= 5 V

Figure 1. Power Switch On-Resistance vs Temperature

V_IN= 5 V

Figure 2. Reverse Leakage Current vs Temperature

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Typical Characteristics (continued)

550

4000

3500

3000

2500

2000

1500

1000

500

V_(IN)= 4.5 V

V_(IN)= 5 V

V_(IN)= 6.5 V

540

530

520

510

500

490

480

470

R_{(ILIM_LO)}= 210 kW

R_{(ILIM_LO)}= 80.6 kW

R_{(ILIM_HI)}= 20 kW

R_{(ILIM_HI)}= 19.1 kW

R_{(ILIM_HI)}= 15.4 kW

0

-40 -25 -10

5

20 35 50 65 80 95 110 125

Junction Temperature (ºC)

-40 -25 -10

5

20 35 50 65 80 95 110 125

Junction Temperature (ºC)

D003

D004

A

V_IN= 5 V

Figure 3. OUT Discharge Resistance vs Temperature

Figure 4. OUT Short-Circuit Current Limit vs Temperature

280

14

12

10

8

V_(IN)= 4.5 V

V_(IN)= 5 V

V_(IN)= 6.5 V

V_(IN)= 4.5 V

V_(IN)= 5 V

V_(IN)= 6.5 V

260

240

220

200

180

6

4

2

0

-2

-40 -25 -10

5

20 35 50 65 80 95 110 125

Junction Temperature (ºC)

-40 -25 -10

5

20 35 50 65 80 95 110 125

Junction Temperature (ºC)

D005

D006

CTL1 = 1

CTL2 = 1

CTL3 = 1

CTL1 = 1

CTL2 = 1

CTL3 = 1

Figure 5. Disabled IN Supply Current vs Temperature

Figure 6. Enabled IN Supply Current – CDP (111) vs

Temperature

290

220

200

180

160

140

120

V_(IN)= 4.5 V

V_(IN)= 5 V

V_(IN)= 6.5 V

V_(IN)= 4.5 V

V_(IN)= 5 V

V_(IN)= 6.5 V

270

250

230

210

190

-40 -25 -10

5

20 35 50 65 80 95 110 125

Junction Temperature (ºC)

-40 -25 -10

5

20 35 50 65 80 95 110 125

Junction Temperature (ºC)

D007

D008

CTL1 = 0

CTL2 = 0

CTL3 = 1

CTL1 = 0

CTL2 = 1

CTL3 = 0

Figure 7. Enabled IN Supply Current – DCP_Auto (001) vs

Temperature

Figure 8. Enabled IN Supply Current – SDP (010) vs

Temperature

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Typical Characteristics (continued)

180

720

710

700

690

680

670

660

650

640

V_(IN)= 4.5 V

V_(IN)= 5 V

V_(IN)= 6.5 V

160

140

120

100

80

I_(LD), OUT Rising Load-Detect Threshold

I_OS, OUT Short-Circuit Current

-40 -25 -10

5

20 35 50 65 80 95 110 125

Junction Temperature (ºC)

-40 -25 -10

5

20 35 50 65 80 95 110 125

Junction Temperature (ºC)

D009

D010

CTL1 = 1

CTL2 = 0

CTL3 = 0

R_{(ILIM_LO)}= 80.6 kΩ

Figure 9. Enabled IN Supply Current – Client Mode (100) vs

Temperature

Figure 10. I_OUTRising Load-Detect Threshold and OUT

Short-Circuit Current Limit vs Temperature

4.2

4.1

4

4.2

4.1

4

3.9

3.8

3.7

3.6

3.9

3.8

3.7

3.6

-40 -25 -10

5

20 35 50 65 80 95 110 125

Junction Temperature (ºC)

-40 -25 -10

5

20 35 50 65 80 95 110 125

Junction Temperature (ºC)

D011

D012

V_IN= 5 V

Figure 11. DP_IN Overvoltage Protection Threshold vs

Temperature

Figure 12. DM_IN Overvoltage Protection Threshold vs

Temperature

250

200

150

100

50

200

150

100

50

I_(OUT)= 1 A

I_(OUT)= 2.1 A

I_(OUT)= 2.4 A

I_(OUT)= 3 A

I_(OUT) = 1 A

I_(OUT)= 2.1 A

I_(OUT)= 2.4 A

I_(OUT)= 3 A

0

-40 -25 -10

5

20 35 50 65 80 95 110 125

Junction Temperature (ºC)

2.5

3

3.5

4

4.5

5

5.5

6

6.5

CS Voltage (V)

D013

D014

V_IN= 5 V

V_CS= 2. 5 V

V_IN= 6.5 V

Figure 13. I_CSvs Temperature

Figure 14. I_CSvs V_CSVoltage

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Typical Characteristics (continued)

Figure 16. Off-State Data-Switch Isolation vs Frequency

Figure 15. Data Transmission Characteristics vs Frequency

Figure 17. On-State Cross-Channel Isolation vs Frequency

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Typical Characteristics (continued)

Forcing a page break between ImageMatrices

Figure 18. Eye Diagram Using USB Compliance Test

Pattern, Bypassing the TPS2549 Data Switch

Figure 19. Eye Diagram Using USB Compliance Test

Pattern, Through the TPS2549 Data Switch

V_(EN)

5 V/div

V_(OUT)

2.5 V/div

I_(IN)

0.5 A/div

R_(LOAD)= 5 Ω

C_(LOAD)= 150 µF

t = 1 ms/div

R_(LOAD)= 5 Ω

C_(LOAD)= 150 µF

t = 1 ms/div

Figure 20. Turnon Response

Figure 21. Turnoff Response

V_(EN)

5 V/div

V_(FAULT)

5 V/div

V_(FAULT)

5 V/div

I_(IN)

0.5 A/div

1 A/div

R_{(ILIM_HI)}= 80.6 kΩ

t = 2 ms/div

R_{(ILIM_HI)}= 19.1 kΩ

t = 4 ms/div

Figure 22. Enable Into Short

Figure 23. Enable Into Short – Thermal Cycling

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Typical Characteristics (continued)

V_(FAULT)

5 V/div

V_(OUT)

2.5 V/div

V_(OUT)

2.5 V/div

I_(IN)

I_(OUT)

2 A/div

10 A/div

R_(SHORT)= 50 mΩ

t = 1 µs/div

R_{(ILIM_HI)}= 19.1 kΩ

t = 4 ms/div

Figure 25. Hot-Short Response Time

Figure 24. Short-Circuit to Full-Load Recovery

V_(EN)

V_(OUT)

2.5 V/div

V_(STATUS)

5 V/div

I_(OUT)

0.5 A/div

2 A/div

R_{(ILIM_LO)}= 80.6 kΩ

t = 100 ms/div

R_{(ILIM_HI)}= 19.1 kΩ

R_(SHORT)= 50 mΩ

t = 1 ms/div

Figure 27. Load-Detection Set Time

Figure 26. Hot Short

V_(STATUS)

5 V/div

V_{(DM_IN)}

V_(OUT)

2.5 V/div

V_{(DM_OUT)}

2.5 V/div

I_(OUT)

0.5 A/div

R_{(ILIM_LO)}= 80.6 kΩ

t = 1 s/div

R_{(DM_OUT)}= 15 kΩ

t = 1 µs/div

Figure 28. Load Detection Reset Time

Figure 29. DM_IN Short to V_BUSResponse Time

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Typical Characteristics (continued)

V_(FAULT)

5 V/div

V_(FAULT)

5 V/div

V_{(DM_IN)}

2.5 V/div

V_{(DM_IN)}

2.5 V/div

V_{(DM_OUT)}

2.5 V/div

V_{(DM_OUT)}

2.5 V/div

R_{(DM_OUT)}= 15 kΩ

t = 4 ms/div

R_{(DM_OUT)}= 15 kΩ

t = 1 µs/div

Figure 30. DM_IN Short to V_BUS

Figure 31. DM_IN Short-to-V_BUSRecovery

7 Parameter Measurement Information

OUT

90%

R_(L)

C_(L)

t_r

t_f

V_(OUT)

10%

Figure 33. Power-On and -Off Timing

Figure 32. OUT Rise-Fall Test Load Figure

V_(EN)

50%

5 V

t_on

t_off

t_(DCHG)

V_(OUT)

90%

V_(OUT)

10%

Figure 35. Enable Timing, Active-High Enable

0 V

Figure 34. OUT Discharge During Mode Change

I_OS

I_(OUT)

t_(IOS)

Figure 36. Output Short-Circuit Parameters

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8 Detailed Description

8.1 Overview

The TPS2549 device is a USB charging controller and power switch which integrates D+ and D– short to V_BUS

protection, cable compensation and IEC ESD protection, and is suitable for USB charging and USB port-

protection applications.

The TPS2549 device integrates a current-limited, power-distribution switch using N-channel MOSFETs for

applications where short circuits or heavy capacitive loads can be encountered. The device allows the user to

program the current-limit threshold via an external resistor. The device enters constant-current mode when the

load exceeds the current limit threshold.

The TPS2549 device also integrates CDP mode, defined in the BC1.2 specification, to enable up to 1.5-A fast

charging of most of portable devices, meanwhile supporting data communication. In addition, the device

integrates the DCP-auto feature to enable fast-charging of most portable devices including pads, tablets, and

smart phones.

The TPS2549 device integrates a cable compensation (CS) feature to compensate the voltage drop in long

cables and keep the remote USB port output voltage constant.

Additionally, the device integrates an IEC ESD cell to provide ESD protection up to ±8 kV (contact discharge)

and ±15 kV (air discharge) per IEC 61000-4-2 on DP_IN and DM_IN, and integrates short-to-V_BUSovervoltage

protection on DP_IN and DM_IN to protect the upstream USB transceiver.

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8.2 Functional Block Diagram

Current

Sense

CS

OUT

IN

Disable + UVLO

+ Discharge

ILIM_HI

Current

Limit

Charge

Pump

8-ms

Deglitch

ILIM_LO

EN

GND

OC

Driver

FAULT

UVLO

Thermal

Sense

I_(CS)= I_(OUT)× 75 µA/A

CS

16-ms

Deglitch

OTSD

OVP2

OVP1

DM_OUT

DP_OUT

DM_IN

DP_IN

CDP

Detection

CTL1

CTL2

DCP

(Auto-Detection)

STATUS

Logic

Control

CTL3

Discharge

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8.3 Feature Description

8.3.1 FAULT Response

The device features an active-low, open-drain fault output. FAULT goes low when there is a fault condition. Fault

detection includes overtemperature, overcurrent, or DP_IN, DM_IN overvoltage. Connect a 10-kΩ pullup resistor

from FAULT to IN.

Table 1 summarizes the conditions that generate a fault and actions taken by the device.

Table 1. Fault Conditions

EVENT

CONDITION

ACTION

The device regulates switch current at I_OSuntil thermal

cycling occurs. The fault indicator asserts and de-asserts

with an 8-ms deglitch (The device does not assert FAULT on

overcurrent in SDP1 and DCP1 modes).

Overcurrent on V_(OUT)

I_(OUT)> I_OS

The device immediately shuts off the USB data switches.

The fault indicator asserts with a 16-ms deglitch, and de-

asserts without deglitch.

Overvoltage on the data lines DP_IN or DM_IN > 3.9 V

The device immediately shuts off the internal power switch

and the USB data switches. The fault indicator asserts

immediately when the junction temperature exceeds OTSD2

or OTSD1 while in a current-limiting condition. The device

has a thermal hysteresis of 20°C.

T_J> OTSD2 in non-current-limited or

T_J> OTSD1 in current-limited mode.

Overtemperature

8.3.2 Cable Compensation

When a load draws current through a long or thin wire, there is an IR drop that reduces the voltage delivered to

the load. In the vehicle from the voltage regulator 5-V output to the VPD_IN (input voltage of portable device), the

total resistance of power switch r_DS(on)and cable resistance causes an IR drop at the PD input.. So the charging

current of most portable devices is less than their expected maximum charging current.

V_(OUT)With Compensation

5.x

V_BUSWith Compensation

V_(DROP)

V_BUSWithout Compensation

0

I_(OUT)(A)

0.5

1

1.5

2

2.5

3

Figure 37. Voltage Drop

TPS2549 device detects the load current and generates a proportional sink current that can be used to adjust

output voltage of the upstream regulator to compensate the IR drop in the charging path. The gain G_(CS)of the

sink current proportional to load current is 75 µA/A.

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r_DS(on)

V_(OUT)

To Regulator OUT

C_(COMP)

To Load

V_BUS

IN

OUT

R1

R2

R_(WIRE)

R_(LOAD)

R_(FA)

C_(OUT)

R_(FB)

FB

To Regulator

Resistor Divider

CS

R_(G)

Figure 38. Cable Compensation Equivalent Circuit

8.3.2.1 Design Procedure

To start the procedure, the total resistance, including power switch r_DS(on)and wire resistance R_(WIRE), must to be

known.

1. Choose R_(G)following the voltage-regulator feedback resistor-divider design guideline.

2. Calculate R_(FA)according to Equation 1.

R_FA= (r_DS(on)+ R_(WIRE)) / G_(CS)

(1)

3. Calculate R_(FB)according to Equation 2.

V

(OUT)

R_(FB)

=

- R_(G)- R_(FA)

V

/ R_(G)

(FB)

(2)

4. C_(COMP)in parallel with R_(FA)is needed to stablilize V_(OUT)when C_(OUT)is large. Start with C_(COMP)≥ 3 × G_(CS)

× C_(OUT), then adjust C_(COMP)to optimize the load transient of the voltage regulator output. V_(OUT)stability

should always be verified in the end application circuit.

8.3.3 D+ and D– Protection

D+ and D– protection consists of ESD and OVP (overvoltage protection). The DP_IN and DM_IN pins integrate

an IEC ESD cell to provide ESD protection up to ±15 kV air discharge and ±8 kV contact discharge per IEC

61000-4-2 (See the ESD Ratings section for test conditions). Overvoltage protection (OVP) is provided for short-

to-V_BUSconditions in the vehicle harness to prevent damaging the upstream USB transceiver. Short-to-GND

protection for D+ and D– is provided by the upstream USB transceiver.

The ESD stress seen at DP_IN and DM_IN is impacted by many external factors like the parasitic resistance and

inductance between ESD test points and the DP_IN and DM_IN pins. For air discharge, the temperature and

humidity of the environment can cause some difference, so the IEC performance should always be verified in the

end-application circuit.

8.3.4 Output and D+ or D– Discharge

To allow a charging port to renegotiate current with a portable device, the TPS2549 device uses the OUT

discharge function. This function turns off the power switch while discharging OUT with a 500-Ω resistance, then

turns the power switches to back on reassert the OUT voltage.

For DP_IN and DM_IN, when OVP is triggered, the device turns on an internal discharge path with 210-Ω

resistance. On removal of OVP, this path can discharge the remnant charges to automatically turn on analog

switch and turn off this discharge path, thus back into normal mode.

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8.3.5 Port Power Management (PPM)

PPM is the intelligent and dynamic allocation of power. PPM is for systems that have multiple charging ports but

cannot power them all simultaneously.

8.3.5.1 Benefits of PPM

The benefits of PPM include the following:

•

Delivers better user experience

Prevents overloading of system power supply

Allows for dynamic power limits based on system state

Allows every port to potentially be a high-power charging port

Allows for smaller power-supply capacity because loading is controlled

8.3.5.2 PPM Details

All ports are allowed to broadcast high-current charging. The current-limit is based on ILIM_HI. The system

monitors the STATUS pin to see when high-current loads are present. Once the allowed number of ports asserts

STATUS, the remaining ports are toggled to a non-charging port. The non-charging port current-limit is based on

the ILIM_LO setting. The non-charging ports are automatically toggled back to charging ports when a charging

port de-asserts STATUS.

STATUS asserts in a charging port when the load current is above ILIM_LO + 40 mA for 210 ms (typical).

STATUS de-asserts in a charging-port when the load current is below ILIM_LO – 10 mA for 3 seconds (typical).

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8.3.5.3 Implementing PPM in a System With Two Charging Ports (CDP and SDP1)

Figure 39 shows the implementation of the two charging ports with data communication, each with a TPS2549

device and configured in CDP mode. In this example, the 5-V power supply for the two charging ports is rated at

less than 3.5 A. Both TPS2549 devices have ILIM_LO of 1 A and ILIM_HI of 2.4 A. In this implementation, the

system can support only one of the two ports at 2.4-A charging current, whereas the other port is set to SDP1

mode and I_(LIMIT)corresponds to 1 A. In SDP1 mode, FAULT does not assert for overcurrent.

TPS2549 Port 1

USB Charging

Port 1

5 V

IN

OUT

DM_IN

DP_IN

EN1

EN

FAULT1

FAULT

STATUS

ILIM _LO

ILIM_HI

CTL1

CTL2

R_HI

R_LO

GND

100 kW

CTL3

TPS2549 Port 2

USB Charging

Port 2

IN

OUT

DM_IN

DP_IN

EN2

EN

FAULT2

FAULT

STATUS

ILIM _LO

ILIM_HI

CTL1

CTL2

R_HI

R_LO

GND

100 kW

CTL3

Figure 39. PPM With CDP and SDP1

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8.3.5.4 Implementing PPM in a System With Two Charging Ports (DCP and DCP1)

Figure 40 shows the implementation of the two charging-only ports, each with a TPS2549 device and configured

in DCP mode. In this example, the 5-V power supply for the two charging ports is rated at less than 3.5 A. Both

TPS2549 devices have ILIM_LO of 1 A and ILIM_HI of 2.4 A. In this implementation, the system can support

only one of the two ports at 2.4-A charging current, whereas the other port is set to DCP1 mode and I_(LIMIT)

corresponds to 1 A. In DCP1 mode, FAULT does not assert for overcurrent.

TPS2549 Port 1

USB Charging

Port 1

5 V

IN

OUT

DM_IN

DP_IN

EN1

EN

FAULT1

FAULT

STATUS

ILIM _LO

ILIM_HI

CTL1

CTL2

R_HI

R_LO

GND

100 kW

CTL3

TPS2549 Port 2

USB Charging

Port 2

IN

OUT

DM_IN

DP_IN

EN2

EN

FAULT2

FAULT

STATUS

ILIM _LO

ILIM_HI

CTL1

CTL2

R_HI

R_LO

GND

100 kW

CTL3

Figure 40. PPM With DCP and DCP1

8.3.6 CDP and SDP Auto Switch

The TPS2549 device is equipped with a CDP and SDP auto-switch feature to support some popular phones in

the market. These popular phones do not comply with the BC1.2 specification because they fail to establish a

data connection in CDP mode. These phones use primary detection (used to distinguish between an SDP and

different types of charging ports) to only identify ports as SDP (data, no charge) or DCP (no data, charge). These

phones do not recognize CDP (data, charge) ports. When connected to a CDP port, these phones classify the

port as a DCP and only charge the battery. Because the charging ports are configured as CDP, users do not

receive the expected data connection.

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Device never signals

connection and enumerates.

Data connection is lost.

Primary Detection

D+

D–

V_BUS

V_BUSCurrent

Figure 41. CDP and SDP Auto-Switch

To remedy this problem, the TPS2549 device employs a CDP and SDP auto-switch scheme to ensure these

BC1.2 noncompliant phones establish data connection using the following steps.

1. The TPS2549 device determines when a noncompliant phone has wrongly classified a CDP port as a DCP

port and has not made a data connection.

2. The TPS2549 device automatically completes an OUT (V_BUS) discharge and reconfigures the port as an

SDP.

3. When reconfigured as an SDP, the phone detects a connection to an SDP and establishes a data

connection.

4. The TPS2549 device then switches automatically back to a CDP without doing an OUT (V_BUS) discharge.

5. The phone continues to operate as if connected to an SDP because OUT (V_BUS) was not interrupted. The

port is now ready in CDP if a new device is attached.

8.3.7 Overcurrent Protection

When an overcurrent condition is detected, the device maintains a constant output current and reduces the

output voltage accordingly. Two possible overload conditions can occur. In the first condition, the output is

shorted before the device enables or before the application of V_(IN). The TPS2549 device senses the short and

immediately switches into a constant-current output. In the second condition, a short or an overload occurs while

the device is enabled. At the instant the overload occurs, high currents flow for 2 μs (typical) before the current-

limit circuit reacts. The device operates in constant-current mode after the current-limit circuit has responded.

Complete shutdown occurs only if the fault is presented long enough to activate overtemperature protection. The

device remains off until the junction temperature cools to approximately 20°C and then restarts. The device

continues to cycle on and off until the overcurrent condition is removed.

8.3.8 Undervoltage Lockout

The undervoltage-lockout (UVLO) circuit disables the device until the input voltage reaches the UVLO turnon

threshold. Built-in hysteresis prevents unwanted oscillations on the output due to input voltage drop from large

current surges.

8.3.9 Thermal Sensing

Two independent thermal-sensing circuits protect the TPS2549 device if the temperature exceeds recommended

operating conditions. These circuits monitor the operating temperature of the power-distribution switch and

disable operation. The device operates in constant-current mode during an overcurrent condition, which

increases the voltage drop across power switch. The power dissipation in the package is proportional to the

voltage drop across the power switch, so the junction temperature rises during an overcurrent condition. When

the device is in a current-limiting condition, the first thermal sensor turns off the power switch when the die

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temperature exceeds OTSD1. If the device is not in a current-limiting condition, the second thermal sensor turns

off the power switch when the die temperature exceeds OTSD2. Hysteresis is built into both thermal sensors,

and the switch turns on after the device has cooled by approximately 20°C. The switch continues to cycle off and

then on until the fault is removed. The open-drain false-reporting output, FAULT, is asserted (low) during an

overtemperature shutdown condition.

8.3.10 Current Limit Setting

The TPS2549 has two independent current-limit settings that are each programmed externally with a resistor.

The ILIM_HI setting is programmed with R_{(ILIM_HI)}connected between ILIM_HI and GND. The ILIM_LO setting is

programmed with R_{(ILIM_LO)}connected between ILIM_LO and GND. Consult the device truth table (Table 2) to

see when each current limit is used. Both settings have the same relation between the current limit and the

programming resistor.

R_{(ILIM_LO)}is optional and the ILIM_LO pin may be left unconnected if the following conditions are met:

•

The TPS2549 device is configured as DCP(001) or CDP(111).

Load detection is not used.

The following equation calculates the value of resistor for programming the typical current limit:

53762 (V)

I_(OSnom)(mA) =

R_{(ILIM_ xx)}^1.0021(kW)

(3)

R_{(ILIM_xx)}corresponds to either R_{(ILIM_HI)}or R_{(ILIM_LO)}, as appropriate.

Many applications require that the current limit meet specific tolerance limits. When designing to these tolerance

limits, both the tolerance of the TPS2549 current limit and the tolerance of the external programming resistor

must be taken into account. The following equations approximate the TPS2549 minimum and maximum current

limits to within a few milliamperes and are appropriate for design purposes. The equations do not constitute part

of TI’s published device specifications for purposes of TI’s product warranty. These equations assume an

ideal—no variation—external programming resistor. To take resistor tolerance into account, first determine the

minimum and maximum resistor values based on its tolerance specifications and use these values in the

equations. Because of the inverse relation between the current limit and the programming resistor, use the

maximum resistor value in the I_{(OS_min)}equation and the minimum resistor value in the I_{(OS_max)}equation.

50409 (V)

R_{(ILIM_ xx)}^0.9982(kW)

I_(OSmin)(mA) =

- 35

(4)

(5)

57813 (V)

R_{(ILIM_ xx)}^1.0107(kW)

I_(OSmax)(mA) =

+ 41

4000

3500

3000

2500

2000

1500

1000

500

700

600

500

400

300

200

100

0

I_(OSmin)

I_(OStyp)

I_(OSmax)

I_(OSmin)

I_(OStyp)

I_(OSmax)

0

10

20

30

40

50

60

70

80

90

100

100 200 300 400 500 600 700 800 900 1000

Current Limit Resistor (kW)

D019

D020

Figure 42. Current Limit Setting vs Programming

Resistor I

Figure 43. Current Limit Setting vs Programming

Resistor II

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The routing of the traces to the R_{(ILIM_xx)}resistors should have a sufficiently low resistance so as to not affect the

current-limit accuracy. The ground connection for the R_{(ILIM_xx)}resistors is also very important. The resistors must

reference back to the TPS2549 GND pin. Follow normal board layout practices to ensure that current flow from

other parts of the board does not impact the ground potential between the resistors and the TPS2549 GND pin.

8.4 Device Functional Modes

8.4.1 Device Truth Table (TT)

The device truth table (Table 2) lists all valid combinations for the three control pins (CTL1 through CTL3), and

the corresponding charging mode of each pin combination. The TPS2549 device monitors the CTL inputs and

transitions to whichever charging mode it is commanded to go to. For example, if the USB port is a charging-only

port, then the user must set the CTL pins of the TPS2549 device to correspond to the DCP-auto charging mode.

However, when the USB port requires data communication, then the user must set control pins to correspond to

the SDP or CDP mode, and so on.

Table 2. Truth Table

STATUS

OUTPUT

(ACTIVE-

LOW)

FAULT

OUTPUT

(ACTIVE-

LOW)

CURRENT

LIMIT

SETTING

CS FOR CABLE

COMPENSATION

CTL1

CTL2

CTL3

MODE

NOTES

0

Lo

Hi

DCP1⁽¹⁾

OFF

ON⁽²⁾

ON

DCP includes divider 3,

1.2-V mode, and

BC1.2 mode

0

1

DCP⁽¹⁾

ON

DCP includes divider 3,

1.2-V mode, and

BC1.2 mode

0

1

0

X

Lo

SDP

OFF

ON

Standard SDP port

NA

Client mode

OFF

No current limit, power

switch disabled, data

switch bypassed

1

0

1

Lo

Hi

SDP1⁽³⁾

CDP⁽³⁾

OFF

ON

ON⁽²⁾

ON

Standard SDP port

CDP-SDP auto switch

mode

(1) No OUT discharge when changing between 000 and 001

(2) FAULT not asserted on overcurrent

(3) No OUT discharge when changing between 110 and 111

8.4.2 USB Specification Overview

The following overview references various industry standards. TI recommends consulting the most up-to-date

standards to ensure the most recent and accurate information. Rechargeable portable equipment requires an

external power source to charge batteries. USB ports are a convenient location for charging because of an

available 5-V power source. Universally accepted standards are required to ensure host and client-side devices

operate together in a system to ensure power-management requirements are met. Traditionally, host ports

following the USB-2.0 specification must provide at least 500 mA to downstream client-side devices. Because

multiple USB devices can be attached to a single USB port through a bus-powered hub, the client-side device

sets the power allotment from the host to ensure the total current draw does not exceed 500 mA. In general,

each USB device is granted 100 mA and can request more current in 100-mA unit steps up to 500 mA. The host

grants or denies additional current based on the available current. A USB-3.0 host port not only provides higher

data rate than a USB-2.0 port but also raises the unit load from 100 mA to 150 mA. Providing a minimum current

of 900 mA to downstream client-side devices is required.

Additionally, the success of USB has made the micro-USB and mini-USB connectors a popular choice for wall-

adapter cables. A micro-USB or mini-USB allows a portable device to charge from both a wall adapter and USB

port with only one connector. As USB charging has gained popularity, the 500-mA minimum defined by USB 2.0,

or 900 mA for USB 3.0, has become insufficient for many handset and personal media players, which require a

higher charging rate. Wall adapters provide much more current than 500 or 900 mA. Several new standards have

been introduced defining protocol handshaking methods that allow host and client devices to acknowledge and

draw additional current beyond the 500-mA and 900-mA minimum defined by USB 2.0 and USB 3.0,

respectively, while still using a single micro-USB or mini-USB input connector.

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The TPS2549 device supports four of the most-common USB-charging schemes found in popular hand-held

media and cellular devices.

•

USB Battery Charging Specification BC1.2

Chinese Telecommunications Industry Standard YD/T 1591-2009

Divider 3 mode

1.2-V mode

The BC1.2 specification includes three different port types:

•

Standard downstream port (SDP)

Charging downstream port (CDP)

Dedicated charging port (DCP)

BC1.2 defines a charging port as a downstream-facing USB port that provides power for charging portable

equipment. Under this definition, CDP and DCP are defined as charging ports.

Table 3 lists the difference between these port types.

Table 3. Operating Modes Table

PORT TYPE

SUPPORTS USB2.0 COMMUNICATION

MAXIMUM ALLOWABLE CURRENT

DRAWN BY PORTABLE EQUIPMENT (A)

SDP (USB 2.0)

SDP (USB 3.0)

CDP

YES

NO

0.5

0.9

1.5

DCP

8.4.3 Standard Downstream Port (SDP) Mode — USB 2.0 and USB 3.0

An SDP is a traditional USB port that follows USB 2.0 or USB 3.0 protocol. A USB 2.0 SDP supplies a minimum

of 500 mA per port and supports USB 2.0 communications. A USB 3.0 SDP supplies a minimum of 900 mA per

port and supports USB 3.0 communications. For both types, the host controller must be active to allow charging.

8.4.4 Charging Downstream Port (CDP) Mode

A CDP is a USB port that follows USB BC1.2 and supplies a minimum of 1.5 A per port. A CDP provides power

and meets the USB 2.0 requirements for device enumeration. USB-2.0 communication is supported, and the host

controller must be active to allow charging. The difference between CDP and SDP is the host-charge

handshaking logic that identifies this port as a CDP. A CDP is identifiable by a compliant BC1.2 client device and

allows for additional current draw by the client device.

The CDP handshaking process occurs in two steps. During step one, the portable equipment outputs a nominal

0.6-V output on the D+ line and reads the voltage input on the D– line. The portable device detects the

connection to an SDP if the voltage is less than the nominal data-detect voltage of 0.3 V. The portable device

detects the connection to a CDP if the D– voltage is greater than the nominal data detect voltage of 0.3 V and

optionally less than 0.8 V.

The second step is necessary for portable equipment to determine whether the equipment is connected to a CDP

or a DCP. The portable device outputs a nominal 0.6-V output on the D– line and reads the voltage input on the

D+ line. The portable device concludes the equipment is connected to a CDP if the data line being read remains

less than the nominal data detects voltage of 0.3 V. The portable device concludes it is connected to a DCP if

the data line being read is greater than the nominal data detect voltage of 0.3 V.

8.4.5 Dedicated Charging Port (DCP) Mode

A DCP only provides power and does not support data connection to an upstream port. As shown in the following

sections, a DCP is identified by the electrical characteristics of the data lines. The TPS2549 only emulates one

state, DCP-auto state. In the DCP-auto state, the device charge-detection state machine is activated to

selectively implement charging schemes involved with the shorted, divider3 and 1.2 v modes. The shorted DCP

mode complies with BC1.2 and Chinese Telecommunications Industry Standard YD/T 1591-2009, whereas the

divider3 and 1.2 V modes are employed to charge devices that do not comply with the BC1.2 DCP standard.

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8.4.5.1 DCP BC1.2 and YD/T 1591-2009

Both standards specify that the D+ and D– data lines must be connected together with a maximum series

impedance of 200 Ω, as shown in Figure 44.

V_BUS

5 V

D–

200 Ω

(ma x.)

D+

GND

Figure 44. DCP Supporting BC1.2 and YD/T 1591-2009

8.4.5.2 DCP Divider-Charging Scheme

The device supports divider3, as shown in Figure 45. In the Divider3 charging scheme the device applies 2.7 V

and 2.7 V to D+ and D– data lines.

V_BUS

5 V

D–

D+

2.7 V

GND

Figure 45. Divider 3 Mode

8.4.5.3 DCP 1.2-V Charging Scheme

The DCP 1.2-V charging scheme is used by some hand-held devices to enable fast charging at 2 A. The

TPS2549 device supports this scheme in DCP-auto state before the device enters BC1.2 shorted mode. To

simulate this charging scheme, the D+ and D– lines are shorted and pulled up to 1.2 V for a fixed duration. Then

the device moves to DCP shorted mode as defined in the BC1.2 specification and as shown in Figure 46.

V_BUS

5 V

200 Ω (ma x.) D–

D+

1.2 V

GND

Figure 46. 1.2-V Mode

8.4.6 DCP Auto Mode

As previously discussed, the TPS2549 device integrates an auto-detect state machine that supports all the DCP

charging schemes. The auto-detect state machine starts in the Divider3 scheme. However, if a BC1.2 or YD/T

1591-2009 compliant device is attached, the TPS2549 device responds by turning the power switch back on

without output discharge and operating in 1.2-V mode briefly before entering BC1.2 DCP mode. Then the auto-

detect state machine stays in that mode until the device releases the data line, in which case the auto-detect

state machine goes back to the Divider3 scheme. When a Divider3-compliant device is attached, the TPS2549

device stays in the Divider3 state.

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5 V

S1

S2

S3

Divider 3 Mode

V_BUS

S1, S2: ON

S3, S4: OFF

D–

D+

DM_IN

DP_IN

GND

S4

Shorted Mode

S4 ON

S1, S2, S3: OFF

GND

1.2-V Mode

S1, S2: OFF

S3, S4: ON

2.7 V 2.7 V 1.2 V

Figure 47. DCP Auto Mode

8.4.7 Client Mode

The TPS2549 device integrates client mode as shown in Figure 48. The internal power switch is OFF and only

the data analog switch is ON to block OUT power. This mode can be used for some software programming via

the USB port.

IN

OUT

DP_IN

DM_IN

OFF

DP_OUT

DM_OUT

Figure 48. Client-Mode Equivalent Circuit

8.4.8 High-Bandwidth Data-Line Switches

The TPS2549 device passes the D+ and D– data lines through the device to enable monitoring and handshaking

while supporting the charging operation. A wide-bandwidth signal switch allows data to pass through the device

without corrupting signal integrity. The data-line switches are turned on in any of the CDP, SDP, or client

operating modes. The EN input must be at logic high for the data line switches to be enabled.

NOTE

•

While in CDP mode, the data switches are ON, even during CDP handshaking.

The data line switches are OFF if EN is low, or if in DCP mode. The switches are not

automatically turned off if the power switch (IN to OUT) is in current-limit.

•

The data switches are only for a USB-2.0 differential pair. In the case of a USB-3.0

host, the super-speed differential pairs must be routed directly to the USB connector

without passing through the TPS2549 device.

Data switches are OFF during OUT (V_BUS) discharge.

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9 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.

9.1 Application Information

The TPS2549 device is a USB charging-port controller and power switch with cable compensation. It is typically

used for USB port protection and as a USB charging controller. The following design procedure can be used to

select components for the TPS2549 device. This section presents a simplified discussion of how to design cable

compensation.

9.2 Typical Application

USB port charging requires a voltage regulator to convert battery voltage to 5-V V_BUSoutput. Because the V_BUS

,

D+, and D– pins of a USB port are exposed, there is a need for a protection device that has V_BUSovercurrent

and D+ and D– ESD protection. An additional need is a charging controller with integrated CDP and DCP

charging protocols on D+ and D– to support fast charging. A schematic of an application circuit with cable

compensation is shown in Figure 49. An LMR14030 device is used as the voltage regulator, and the TPS2549

device is used as the charging controller with protection features.

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Typical Application (continued)

0.1 µF

10 µH

SW

BOOT

12 V

VIN

LMR14030

GND

V_(DC)

EN

60.4 kW

0.75 V

RT/SYNC

SS

FB

0.018 µF

To Portable Device

R_(BUS)

0.1µF

47 mΩ

2 × 47 µF

IN

OUT

V_BUS

TPS2549

DM_IN

DP_IN

R_{(GN D)}

FAULT

1.5-m USB Cable

FAULT

STATUS

GND

STATUS

CS

ILIM_LO

ILIM_HI

EN

I/O

CTL1

20 kW

80.6 kW

DM_OUT

DP_OUT

CTL2

CTL3

ToHost

Controller

Figure 49. Typical Application Schematic: USB Port Charging With Cable Compensation

9.2.1 Design Requirements

For this design example, use the following as the input parameters.

DESIGN PARAMETER

EXAMPLE VALUE

Input voltage, V_(IN)

12 V

Output voltage, V_(DC)

5 V

Total parasitic resistance including TPS2549 r_DS(on)

Maximum continuous output current, I_(OUT)

Current limit, I_(LIM)

420 mΩ

2.4 A

2.5 A to 2.9 A

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9.2.2 Detailed Design Procedure

To begin the design process, a few parameters must be decided upon. The designer needs to know the

following:

•

Total resistance including power switch r_DS(on), cable resistance, and the contact resistance of connectors

The maximum continuous output current for the charging port. The minimum current-limit setting of TPS2549

device must be higher than this current.

•

The maximum output current of the upstream dc-dc converter. The maximum current-limit setting of TPS2549

device must be lower than this current.

9.2.2.1 Input and Output Capacitance

Input and output capacitance improves the performance of the device; the actual capacitance should be

optimized for the particular application. All protection circuits including the TPS2549 device have the potential for

input voltage droop, overshoot, and output-voltage undershoot.

For all applications, TI recommends a 0.1-µF or greater ceramic bypass capacitor between IN and GND, placed

as close as possible to the device for the local noise decoupling.

The TPS2549 device is used for 5-V power rail protection when a hot-short occurs on the output or when

plugging in a capacitive load. Due to the limited response time of the upstream power supply, a large load

transient can deplete the charge on the output capacitor of the power supply, causing a voltage droop. If the

power supply is shared with other loads, ensure that voltage droop from current surges of the other loads do not

force the TPS2549 device into UVLO. Increasing the upstream power supply output capacitor can reduce this

droop. Shortening the connection impedance (resistance and inductance) between the TPS2549 device and the

upstream power supply can also help reduce the voltage droop and overshoot on the TPS2549 input power bus.

Input voltage overshoots can be caused by either of two effects. The first cause is an abrupt application of input

voltage in conjunction with input power-bus inductance and input capacitance when the IN terminal is in the high-

impedance state (before turnon). Theoretically, the peak voltage is 2 times the applied voltage. The second

cause is due to the abrupt reduction of output short-circuit current when the TPS2549 device turns off and

energy stored in the input inductance drives the input voltage high. Applications with large input inductance (for

example, connecting the evaluation board to the bench power supply through long cables) may require large

input capacitance to prevent the voltage overshoot from exceeding the absolute maximum voltage of the device.

For output capacitance, consider the following three application situations.

The first, output voltage undershoot is caused by the inductance of the output power bus just after a short has

occurred and the TPS2549 has abruptly reduced OUT current. Energy stored in the inductance will drive the

OUT voltage down and potentially negative as it discharges. Applications with large output inductance (such as

from a cable) benefit from use of a high-value output capacitor to control the voltage undershoot. Second, for

USB-port application, because the OUT pin is exposed to the air, the application must withstand ESD stress

without damage. Because there is no internal IEC ESD cell as on DP_IN and DM_IN, using a low-ESR

capacitance can make this pin robust. Third, when plugging in apacitive load such as the input capacitor of any

portable device, having a large output capacitance can help reduce the peak current and up-stream power

supply output voltage droop. So for TPS2549 output capacitance, recommended practice is typically adding two

47-µF ceramic capacitors.

9.2.2.2 Cable Compensation Calculation

Based on the known total resistance, Table 4 shows the calculation.

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Table 4. Cable Compensation Calculation

CALCULATION EQUATION⁽¹⁾

CALCULATED VALUE

ASSEMBLY VALUE

V_(DC)(V) without load

R_(G)(kΩ)

5

6.8

R_(total)(Ω)

0.42

0.075

5.6

G_(CS)(mA/A)

R_(FA)(kΩ)

R_(FA)= R_(total)/ G_(CS)

5.6

33

V_(FB)(V)

0.75

32.93

R_(FB)(kΩ)

R_(FB)= [V_(DC)/ (V_(FB)/ R_(G))] –

R_(G)– R_(FA)

V_(CS)(V)⁽²⁾

V_CS= (V_(FB)/ R_(G)) × (R_(G)

R_(FB)

+

4.39

)

Maximum I_OS(A) at 20 kΩ

V_(DC,max)output (V)⁽³⁾

2.84

6.25

V_(DC,max)= 5 + I_(OS,max)

G_(CS,max)× R_(FA)

×

C_(OUT)(µF)

C_(COMP)(nF)⁽⁴⁾

2 × 47

22

C_(COMP)≥ 3 × G_(CS)× C_(OUT)

≥21.15

(1) See Figure 38 and Design Procedure .

(2) Ensure that V_CSexceeds 2.5 V.

(3) Ensure that the maximum dc-dc output voltage is lower than 6.5 V when considering I_(OS,max)and G_(CS,max)

.

(4) C_COMPimpacts load-transient performance, so the output performance should always be verified in the end application circuit.

9.2.2.3 Power Dissipation and Junction Temperature

The low on-resistance of the N-channel MOSFET allows small surface-mount packages to pass large currents. It

is good design practice to estimate power dissipation and junction temperature. The following analysis gives an

approximation for calculating junction temperature based on the power dissipation in the package. However, it is

important to note that thermal analysis is strongly dependent on additional system-level factors. Such factors

include air flow, board layout, copper thickness and surface area, and proximity to other devices dissipating

power. Good thermal design practice must include all system-level factors in addition to individual component

analysis. Begin by determining the r_DS(on)of the N-channel MOSFET relative to the input voltage and operating

temperature. As an initial estimate, use the highest operating ambient temperature of interest and read r_DS(on)

from the typical characteristics graph. Using this value, the power dissipation can be calculated by:

2

P_D= r_DS(on)´ I_OUT

(6)

where:

P_D= Total power dissipation (W)

r_DS(on)= Power-switch on-resistance (Ω)

I_OUT= Maximum current-limit threshold (A)

This step calculates the total power dissipation of the N-channel MOSFET.

Finally, calculate the junction temperature:

T_J= P_D´ R_qJA+ T_A

(7)

where:

T_A= Ambient temperature (°C)

R_θJA= Thermal resistance (°C/W)

P_D= Total power dissipation (W)

Compare the calculated junction temperature with the initial estimate. If they are not within a few degrees, repeat

the calculation using the refined r_DS(on)from the previous calculation as the new estimate. Two or three iterations

are generally sufficient to achieve the desired result. The final junction temperature is highly dependent on

thermal resistance R_θJA, and thermal resistance is highly dependent on the individual package and board layout.

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9.2.3 Application Curves

6.2

V_BUS

V_(DC)

6

5.8

5.6

5.4

5.2

5

V_(DC)at 5-V Offset

100 mV/div

I_(OUT)

200 mA/div

4.8

0

0.5

1

1.5

I_(LOAD)(A)

2

2.5

t = 20 ms/div

D018

Figure 51. Plugging In a Portable Device, V_(DC)

Figure 50. V_(DC)and V_BUSvs I_(LOAD)Output

V_BUSat 5-V Offset

10 mV/div

V_(DC)at 5-V Offset

100 mV/div

I_(OUT)

200 mA/div

I_(OUT)

200 mA/div

t = 20 ms/div

Figure 52. Unplugging a Portable Device, V_(DC)

Figure 53. Plugging In Portable Device, V_BUS

V_(DC)at 5-V Offset

200 mV/div

I_(OUT)

200 mA/div

V_BUSat 5-V Offset

100 mV/div

I_(OUT)

1 A/div

t = 20 ms/div

t = 200 µs/div

Figure 54. Unplugging Portable Device, V_BUS

Figure 55. 0.5-A ↔ 2.4-A Load Transient With 100-mA/µs

Slew Rate, V_(DC)

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V_(DC)

1 V/div

V_BUSat 5-V Offset

200 mV/div

I_(OUT)

1 A/div

2 A/div

t = 200 µs/div

Figure 56. 0.5-A ↔ 2.4-A Load Transient With 100-mA/µs

Figure 57. V_BUSShorted to GND, V_(DC)

Slew Rate, V_BUS

10 Power Supply Recommendations

The TPS2549 device is designed for a supply-voltage range of 4.5 V ≤ V_IN≤ 6.5 V. If the input supply is located

more than a few inches from the device, an input ceramic bypass capacitor higher than 0.1 μF is recommended.

The power supply should be rated higher than the TPS2549 current-limit setting to avoid voltage droops during

overcurrent and short-circuit conditions.

11 Layout

11.1 Layout Guidelines

•

For the trace routing of DP_IN, DM_IN, DP_OUT, and DM_OUT: Route these traces as micro-strips with

nominal differential impedance of 90 Ω. Minimize the use of vias in the high-speed data lines. Keep the

reference GND plane devoid from cuts or splits above the differential pairs to prevent impedance

discontinuities. For more information, see the High Speed USB Platform Design Guideline from Intel.

•

The trace routing from the upstream regulator to the TPS2549 IN pin should as short as possible to reduce

the voltage drop and parasitic inductance.

The traces routing from the R_{ILIM_HI}and R_{ILIM_LO}resistors to the device should be as short as possible to

reduce parasitic effects on the current-limit accuracy.

•

The thermal pad should be directly connected to the PCB ground plane using a wide and short copper trace.

The trace routing from the CS pin to the feedback divider of the upstream regulator should not be routed near

any noise sources that can capacitively couple to the feedback divider.

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11.2 Layout Example

Top Layer Signal Trace

Top Layer Signal Ground Plane

Bottom Layer Signal Trace

Via to Bottom Layer Signal Ground Plane

Via to Bottom Layer Signal

16 15 14 13

IN

1

12

OUT

2

3

4

11

10

9

DM_IN

DP_IN

DM_OUT

DP_OUT

CS

STATUS

5

6

7

8

Figure 58. TPS2549 Layout Diagram

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12 器件和文档支持

12.1 文档支持

12.1.1 相关文档ꢀ

《高速 USB 平台设计指南》，Intel

12.2 接收文档更新通知

如需接收文档更新通知，请访问 www.ti.com 网站的器件产品文件夹。点击右上角的提醒我 (Alert me) 注册后，即

可每周定期收到已更改的产品信息。有关更改的详细信息，请查阅已修订文档中包含的修订历史记录。

12.3 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.

12.4 商标

E2E is a trademark of Texas Instruments.

All other trademarks are the property of their respective owners.

12.5 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。

12.6 Glossary

SLYZ022 — TI Glossary.

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

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13 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。

36

GENERIC PACKAGE VIEW

RTE 16

3 x 3, 0.5 mm pitch

WQFN - 0.8 mm max height

PLASTIC QUAD FLATPACK - NO LEAD

This image is a representation of the package family, actual package may vary.

Refer to the product data sheet for package details.

4225944/A

www.ti.com

PACKAGE OUTLINE

RTE0016C

WQFN - 0.8 mm max height

S

C

A

L

E

3

.

6

0

PLASTIC QUAD FLATPACK - NO LEAD

3.1

2.9

B

A

PIN 1 INDEX AREA

3.1

2.9

SIDE WALL

METAL THICKNESS

DIM A

OPTION 1

0.1

OPTION 2

0.2

C

0.8 MAX

SEATING PLANE

0.08

0.05

0.00

1.68 0.07

(DIM A) TYP

5

8

EXPOSED

THERMAL PAD

12X 0.5

4

9

4X

SYMM

17

1.5

1

12

0.30

16X

0.18

PIN 1 ID

(OPTIONAL)

13

16

0.1

C A B

SYMM

0.05

0.5

0.3

16X

4219117/B 04/2022

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.

3. The package thermal pad must be soldered to the printed circuit board for thermal and mechanical performance.

www.ti.com

EXAMPLE BOARD LAYOUT

RTE0016C

WQFN - 0.8 mm max height

PLASTIC QUAD FLATPACK - NO LEAD

(

1.68)

SYMM

13

16

16X (0.6)

1

12

16X (0.24)

SYMM

(2.8)

17

(0.58)

TYP

12X (0.5)

9

4

(

0.2) TYP

VIA

5

8

(R0.05)

ALL PAD CORNERS

(0.58) TYP

(2.8)

LAND PATTERN EXAMPLE

EXPOSED METAL SHOWN

SCALE:20X

0.07 MIN

ALL AROUND

0.07 MAX

ALL AROUND

SOLDER MASK

OPENING

METAL

EXPOSED

METAL

EXPOSED

METAL

SOLDER MASK

OPENING

METAL UNDER

SOLDER MASK

NON SOLDER MASK

SOLDER MASK

DEFINED

(PREFERRED)

SOLDER MASK DETAILS

4219117/B 04/2022

NOTES: (continued)

4. This package is designed to be soldered to a thermal pad on the board. For more information, see Texas Instruments literature

number SLUA271 (www.ti.com/lit/slua271).

5. Vias are optional depending on application, refer to device data sheet. If any vias are implemented, refer to their locations shown

on this view. It is recommended that vias under paste be filled, plugged or tented.

www.ti.com

EXAMPLE STENCIL DESIGN

RTE0016C

WQFN - 0.8 mm max height

PLASTIC QUAD FLATPACK - NO LEAD

(

1.55)

16

13

16X (0.6)

1

12

16X (0.24)

17

SYMM

(2.8)

12X (0.5)

9

4

METAL

ALL AROUND

5

8

SYMM

(2.8)

(R0.05) TYP

SOLDER PASTE EXAMPLE

BASED ON 0.125 mm THICK STENCIL

EXPOSED PAD 17:

85% PRINTED SOLDER COVERAGE BY AREA UNDER PACKAGE

SCALE:25X

4219117/B 04/2022

NOTES: (continued)

6. Laser cutting apertures with trapezoidal walls and rounded corners may offer better paste release. IPC-7525 may have alternate

design recommendations.

www.ti.com

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型号：	TPS2549RTET
厂家：	TEXAS INSTRUMENTS
描述：	具有电缆补偿功能的 USB 汽车类充电端口控制器和 3A 电源开关 \| RTE \| 16 \| -40 to 125 开关控制器电源开关
文件：	总43页 (文件大小：2198K)
中文：	中文翻译
下载：	下载PDF数据表文档文件

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