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TUSB8043

ZHCSGC6A –JUNE 2017–REVISED AUGUST 2017

TUSB8043带 USB 告示板的四端口 USB 3.1 1 代集线器

1 特性

•

64 引脚 QFN 封装 (RGC)

1

•

四端口 USB 3.1 1 代集线器

USB 2.0 集线器特性

2 应用

计算机系统、扩展坞、监视器和机顶盒

–

多事务转换器 (MTT) 集线器：四个事务转换器

每个事务转换器具有两个异步端点缓冲器

3 说明

•

支持电池充电：

TUSB8043 是一款四端口 USB 3.1 1 代集线器。该器

件在上行端口上可提供同步超快速和高速/全速 USB 连

接，在下行端口上可提供超快速、高速、全速或者低速

USB 连接。当上行端口连接到一个仅支持高速或全速/

低速连接的电气环境中时，下行端口上的超快速 USB

连接将会禁用。

–

在未连接或未配置上行端口的情况下，可支持

D+/D- 分频器充电端口（ACP1、ACP2 和

ACP3）

–

在未连接上行端口的情况下，可支持自动模式以

在 DCP 或 ACP 模式之间进行切换

–

支持 Galaxy 充电

充电下行端口 (CDP) 模式（上行端口已连接）

专用充电端口 (DCP) 模式（上行端口未连接）

器件信息⁽¹⁾

器件型号

TUSB8043

封装

封装尺寸（标称值）

DCP 模式符合中国电信行业标准 YD/T 1591-

2009

VQFN (64)

9.00mm x 9.00mm

(1) 如需了解所有可用封装，请见数据表末尾的可订购产品附录。

•

支持用作 USB 3.1 1 代或者 USB 2.0 复合器件

支持每端口或成组电源开关以及过流通知输入

图

支持四个外部下行端口且内部仅支持 USB 2.0 端

口，可适用于 USB HID 至 I²C 功能

Ü{. 3ꢀ1 {ystem Lmplementation

•

适用于通过 USB HID 以实现 I²C 控制的内部下行

端口支持高速、全速运行。运行速度与上行端口速

度匹配。

Ü{. 3ꢀx Iost /ontroller

支持读取和写入 I²C 的供应商请求，并且在 100k

和 400k（默认）条件下支持 EEPROM 读取

I²C 主机支持时钟拉伸

Ü{. 2ꢀ0

IL5 to L2/

Ü{. 2ꢀ0

5evice

ÇÜ{.8043

Ü{. 3ꢀx

5evice

•

可使用一次性可编程 (OTP) ROM、串行 EEPROM

或 I²C/SMBus 受控接口进行自定义配置：

Ü{. 2ꢀ0

5evice

Ü{. 3ꢀx Iub

Ü{. 2ꢀ0 Iub

–

VID 和 PID

Ü{. 3ꢀx

5evice

端口定制

Ü{. 2ꢀ0

5evice

Ü{. 3ꢀx

5evice

Ü{. 1ꢀ1

5evice

生产商和产品字串（OTP ROM 不支持）

序列号（OTP ROM 不支持）

可使用引脚选择、EEPROM 或 I²C/SMBus 从机接

Ü{. 1ꢀ1

5evice

•

口选择应用特性

Ü{. 1ꢀx /onnection

Ü{. 2ꢀ0 /onnection

•

提供 128 位通用唯一标识符 (UUID)

Ü{. 2ꢀ0ꢁ3ꢀx 5evice

Ü{. 3ꢀx 5evice

Ü{. 2ꢀ0 5evice

Ü{. 1ꢀx 5evice

通过 USB 2.0 上行端口支持板载和系统内

EEPROM 编程

Ü{. 3ꢀx /onnection

•

单时钟输入，24MHz 晶振或者振荡器

下行端口仅可对 USB 2.0 进行配置

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: SLLSEW4

TUSB8043

ZHCSGC6A –JUNE 2017–REVISED AUGUST 2017

www.ti.com.cn

8.5 Register Maps......................................................... 23

Applications and Implementation ...................... 38

9.1 Application Information............................................ 38

9.2 Typical Application .................................................. 38

1

2

3

4

5

6

7

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

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

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

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

说明（续）.............................................................. 3

Pin Configuration and Functions......................... 4

Specifications......................................................... 9

7.1 Absolute Maximum Ratings ..................................... 9

7.2 ESD Ratings.............................................................. 9

7.3 Recommended Operating Conditions....................... 9

7.4 Thermal Information.................................................. 9

7.5 Electrical Characteristics, 3.3-V I/O ........................ 10

7.6 Timing Requirements, Power-Up............................ 10

7.7 Hub Input Supply Current ....................................... 11

Detailed Description ............................................ 12

8.1 Overview ................................................................. 12

8.2 Functional Block Diagram ....................................... 12

8.3 Feature Description................................................. 13

8.4 Device Functional Modes........................................ 20

9

10 Power Supply Recommendations ..................... 47

10.1 TUSB8043 Power Supply ..................................... 47

10.2 Downstream Port Power ....................................... 47

10.3 Ground .................................................................. 47

11 Layout................................................................... 48

11.1 Layout Guidelines ................................................. 48

11.2 Layout Examples................................................... 49

12 器件和文档支持 ..................................................... 51

12.1 接收文档更新通知 ................................................. 51

12.2 社区资源................................................................ 51

12.3 商标....................................................................... 51

12.4 静电放电警告......................................................... 51

12.5 Glossary................................................................ 51

13 机械、封装和可订购信息....................................... 52

8

4 修订历史记录

注：之前版本的页码可能与当前版本有所不同。

Changes from Original (June 2017) to Revision A

Page

•

Changed pin 40 From: FULLPWRMGMTz / FULLAUTOz / SMBA1 / SS_UP / CLKOUT_ENZ To: FULLPWRMGMTz

/ FULLAUTOz / SMBA1 / SS_UP in the Pin Configuration and Functions section................................................................ 4

2

TUSB8043

www.ti.com.cn

ZHCSGC6A –JUNE 2017–REVISED AUGUST 2017

5 说明（续）

当上行端口连接到一个仅支持全速/低速连接的电气环境中时，下行端口上的超快速 USB 和高速连接将会禁用。

TUSB8043 支持每端口或成组电源开关和过流保护，并且还支持电池充电应用。

按照 USB 主机的要求，一个端口电源单独控制集线器开关为每个下行端口加电或者断电。同样地，当一个端口电

源单独控制集线器感测到一个过流事件时，它只关闭到受影响的下行端口的电源。

当需要为任一端口供电时，一个成组集线器开关打开到其所有下行端口的电源。只有当所有端口处于电源可被移除

的状态时，到下行端口的电源才可被关闭。同样地，当一个成组集线器感测到一个过流事件时，到所有下行端口的

电源将被关闭。

TUSB8043 下行端口可提供电池充电下行端口 (CDP) 握手支持，以此为电池充电应用提供支持。在未连接上行端

口的情况下，该器件还支持专用充电端口 (DCP) 模式。DCP 模式为支持 USB 电池充电、Galaxy 充电和符合中国

电信行业标准 YD/T 1591-2009 的 USB 器件提供支持。此外，在未连接上行端口的情况下，TUSB8043 支持分频

器充电端口模式（ACPx 模式），并且可在所有模式之间进行自动切换，切换顺序从 ACP3 模式开始，到 DCP 模

式结束。

TUSB8043 能够为包括电池充电支持在内的部分特性提供引脚搭接配置，还能够通过 OTP ROM、I²C EEPROM

或 I²C/SMBus 从机接口为 PID、VID、自定义端口和物理层配置提供定制支持。使用 I²C EEPROM 或 I²C/SMBus

从机接口时，还可以提供定制字串支持。

TUSB8043 通过内部 USB HID 和 I²C 接口支持连接的 EEPROM 编程。

该器件采用 64 引脚 RGC 封装，商用版的工作温度范围为 0°C 至 70°C。

3

TUSB8043

ZHCSGC6A –JUNE 2017–REVISED AUGUST 2017

www.ti.com.cn

6 Pin Configuration and Functions

RGC Package

64 Pin (VQFN)

(Top View)

48

47

46

45

44

43

42

41

40

39

38

37

36

35

34

33

32

31

30

29

28

49

50

51

52

53

TEST

PWRCTL4 / BATEN4

VDD

GRTSz

VDD

VDD33

USB_SSRXM_DN4

USB_SSRXP_DN4

USB_DP_UP

VDD

27

26

25

24

23

22

21

20

19

18

17

USB_DM_UP

54

55

56

57

58

59

60

61

62

63

64

USB_SSTXM_DN4

USB_SSTXP_DN4

USB_DM_DN4

USB_DP_DN4

USB_SSTXP_UP

USB_SSTXM_UP

VDD

VSS

USB_SSRXP_UP

USB_SSRXM_UP

NC

USB_SSRXM_DN3

USB_SSRXP_DN3

VDD

USB_SSTXM_DN3

USB_SSTXP_DN3

XO

XI

VDD33

USB_DM_DN3

USB_DP_DN3

USB_R1

1

2

3

4

5

6

7

8

9

10

11

12

13

14

15

16

4

TUSB8043

www.ti.com.cn

ZHCSGC6A –JUNE 2017–REVISED AUGUST 2017

Pin Functions

NAME

I/O

DESCRIPTION

NO.

Clock and Reset Signals

I

Global power reset. This reset brings all of the TUSB8043 internal registers to their default

states. When GRSTz is asserted, the device is completely nonfunctional.

GRSTz

50

62

PU

Crystal input. This pin is the crystal input for the internal oscillator. The input may alternately

be driven by the output of an external oscillator. When using a crystal a 1-MΩ feedback

resistor is required between XI and XO.

XI

I

Crystal output. This pin is the crystal output for the internal oscillator. If XI is driven by an

external oscillator this pin may be left unconnected. When using a crystal a 1-MΩ feedback

resistor is required between XI and XO.

XO

61

O

USB Upstream Signals

USB_SSTXP_UP

USB_SSTXM_UP

USB_SSRXP_UP

USB_SSRXM_UP

USB_DP_UP

55

56

58

59

53

54

O

I

USB SuperSpeed transmitter differential pair (positive)

USB SuperSpeed transmitter differential pair (negative)

USB SuperSpeed receiver differential pair (positive)

USB SuperSpeed receiver differential pair (negative)

USB High-speed differential transceiver (positive)

USB High-speed differential transceiver (negative)

I

I/O

I

USB_DM_UP

Precision resistor reference. A 9.53-kΩ ±1% resistor should be connected between USB_R1

and GND.

USB_R1

64

I

USB upstream port power monitor. The VBUS detection requires a voltage divider. The signal

USB_VBUS must be connected to VBUS through a 90.9-KΩ ±1% resistor, and to ground

through a 10-kΩ ±1% resistor from the signal to ground.

USB_VBUS

48

USB Downstream Signals

USB_SSTXP_DN1

USB_SSTXM_DN1

USB_SSRXP_DN1

USB_SSRXM_DN1

USB_DP_DN1

3

4

6

7

1

2

O

I

USB SuperSpeed transmitter differential pair (positive)

USB SuperSpeed transmitter differential pair (negative)

USB SuperSpeed receiver differential pair (positive)

USB SuperSpeed receiver differential pair (negative)

USB High-speed differential transceiver (positive)

USB High-speed differential transceiver (negative)

I

I/O

USB_DM_DN1

USB Port 1 Power On Control for Downstream Power/Battery Charging Enable. The pin is

used for control of the downstream power switch for Port 1. This pin be left unconnected if

power management is not implemented.

In addition, the value of the pin is sampled at the de-assertion of reset to determine the value

of the battery charging support for Port 1 as indicated in the Battery Charging Support

register:

PWRCTL1/BATEN1

36

I/O, PD

0 = Battery charging not supported

1 = Battery charging supported

USB Port 1 Over-Current Detection. This pin is typically connected to the over current output

of the downstream port power switch for Port 1.

0 = An over current event has occurred

1 = An over current event has not occurred

OVERCUR1z

46

I, PU

When GANGED power management is enabled, this pin or one of the other OVERCURz pins

must be connected to the over current output of the power switch or circuit which detects the

over current conditions. For the case when another OVERCURz pin is used, this pin can be

left unconnected.

USB_SSTXP_DN2

USB_SSTXM_DN2

USB_SSRXP_DN2

USB_SSRXM_DN2

USB_DP_DN2

11

12

14

15

9

O

I

USB SuperSpeed transmitter differential pair (positive)

USB SuperSpeed transmitter differential pair (negative)

USB SuperSpeed receiver differential pair (positive)

USB SuperSpeed receiver differential pair (negative)

USB High-speed differential transceiver (positive)

USB High-speed differential transceiver (negative)

I

I/O

USB_DM_DN2

10

5

TUSB8043

ZHCSGC6A –JUNE 2017–REVISED AUGUST 2017

www.ti.com.cn

Pin Functions (continued)

I/O

DESCRIPTION

NAME

NO.

USB Port 2 Power On Control for Downstream Power/Battery Charging Enable. The pin is

used for control of the downstream power switch for Port 2. This pin be left unconnected if

power management is not implemented.

In addition, the value of the pin is sampled at the de-assertion of reset to determine the value

of the battery charging support for Port 2 as indicated in the Battery Charging Support

register:

PWRCTL2/BATEN2

35

I/O, PD

0 = Battery charging not supported

1 = Battery charging supported

USB Port 2 Over-Current Detection. This pin is typically connected to the over current output

of the downstream port power switch for Port 2.

0 = An over current event has occurred

1 = An over current event has not occurred

OVERCUR2z

47

I, PU

When GANGED power management is enabled, this pin or one of the other OVERCURz pins

must be connected to the over current output of the power switch or circuit which detects the

over current conditions. For the case when another OVERCURz pin is used, this pin can be

left unconnected.

USB_SSTXP_DN3

USB_SSTXM_DN3

USB_SSRXP_DN3

USB_SSRXM_DN3

USB_DP_DN3

19

20

22

23

17

18

O

I

USB SuperSpeed transmitter differential pair (positive)

USB SuperSpeed transmitter differential pair (negative)

USB SuperSpeed receiver differential pair (positive)

USB SuperSpeed receiver differential pair (negative)

USB High-speed differential transceiver (positive)

USB High-speed differential transceiver (negative)

I

I/O

USB_DM_DN3

USB Port 3 Power On Control for Downstream Power/Battery Charging Enable. The pin is

used for control of the downstream power switch for Port 3. This pin be left unconnected if

power management is not implemented.

In addition, the value of the pin is sampled at the de-assertion of reset to determine the value

of the battery charging support for Port 3 as indicated in the Battery Charging Support

register:

PWRCTL3/BATEN3

33

I/O, PD

0 = Battery charging not supported

1 = Battery charging supported

USB Port 3 Over-Current Detection. This pin is typically connected to the over current output

of the downstream port power switch for Port 3.

0 = An over current event has occurred

1 = An over current event has not occurred

OVERCUR3z

44

I, PU

When GANGED power management is enabled, this pin or one of the other OVERCURz pins

must be connected to the over current output of the power switch or circuit which detects the

over current conditions. For the case when another OVERCURz pin is used, this pin can be

left unconnected.

USB_SSTXP_DN4

USB_SSTXM_DN4

USB_SSRXP_DN4

USB_SSRXM_DN4

USB_DP_DN4

26

27

29

30

24

25

O

I

USB SuperSpeed transmitter differential pair (positive)

USB SuperSpeed transmitter differential pair (negative)

USB SuperSpeed receiver differential pair (positive)

USB SuperSpeed receiver differential pair (negative)

USB High-speed differential transceiver (positive)

USB High-speed differential transceiver (negative)

I

I/O

USB_DM_DN4

USB Port 4 Power On Control for Downstream Power/Battery Charging Enable. The pin is

used for control of the downstream power switch for Port 4. This pin be left unconnected if

power management is not implemented.

In addition, the value of the pin is sampled at the de-assertion of reset to determine the value

of the battery charging support for Port 4 as indicated in the Battery Charging Support

register:

PWRCTL4/BATEN4

32

I/O, PD

0 = Battery charging not supported

1 = Battery charging supported

6

TUSB8043

www.ti.com.cn

ZHCSGC6A –JUNE 2017–REVISED AUGUST 2017

Pin Functions (continued)

NAME

I/O

DESCRIPTION

NO.

USB Port 4 Over-Current Detection. This pin is typically connected to the over current output

of the downstream port power switch for Port 4.

0 = An over current event has occurred

1 = An over current event has not occurred

OVERCUR4z

43

I, PU

When GANGED power management is enabled, this pin or one of the other OVERCURz pins

must be connected to the over current output of the power switch or circuit which detects the

over current conditions. For the case when another OVERCURz pin is used, this pin can be

left unconnected.

I²C/SMBUS I²C Signals

I²C clock/SMBus clock. Function of pin depends on the setting of the SMBUSz input.

When SMBUSz = 1, this pin acts as the serial clock interface for an I²C EEPROM.

When SMBUSz = 0, this pin acts as the serial clock interface for an SMBus host.

Can be left unconnected if external interface not implemented.

I²C data/SMBus data. Function of pin depends on the setting of the SMBUSz input.

When SMBUSz = 1, this pin acts as the serial data interface for an I²C EEPROM.

When SMBUSz = 0, this pin acts as the serial data interface for an SMBus host.

Can be left unconnected if external interface not implemented.

SCL/SMBCLK

38

37

I/O, PD

SDA/SMBDAT

I²C/SMBus mode select/SuperSpeed USB Suspend Status. The value of the pin is sampled

at the de-assertion of reset set I²C or SMBus mode as follows:

1 = I²C Mode Selected

0 = SMBus Mode Selected

SMBUSz/SS_SUSPEND

39

I/O, PU

Can be left unconnected if external interface not implemented.

After reset, this signal indicates the SuperSpeed USB Suspend status of the upstream port if

enabled through the stsOutputEn bit in the Additional Feature Configuration register. When

enabled, a value of 1 indicates the connection is suspended.

Test and Miscellaneous Signals

Full power management enable/SMBus address bit 1/SuperSpeed USB Connection Status

Upstream port.

The value of the pin is sampled at the de-assertion of reset to set the power switch control

follows:

0 = Power switching and over current inputs supported

1 = Power switching and over current inputs not supported

Full power management is the ability to control power to the downstream ports of the

TUSB8043 using PWRCTL[4:1]/BATEN[4:1].

If BATENx = 1 on any port, full power management must be enabled so the value of the

terminal is sampled at the de-assertion to initialize the value of the FULLAUTOz bit.

FULLPWRMGMTz /

FULLAUTOz /

SMBA1/SS_UP

40

I/O, PD

When AUTOENz = 0 and FULLAUTOz = 0: all ACP modes are supported.

When AUTOENz = 0 and FULLAUTOz = 1:only highest current ACP mode is used in auto

mode.

When SMBus mode is enabled, this pin sets the value of the SMBus slave address bit 1.

Can be left unconnected if full power management and SMBus are not implemented.

After reset, this signal indicates the SuperSpeed USB connection status of the upstream port

if enabled through the stsOutputEn bit in the Additional Feature Configuration register. When

enabled a value of 1 indicates the upstream port is connected to a SuperSpeed USB capable

port.

Note: Power switching must be supported for battery charging applications.

Power Control Polarity.

The value of the pin is sampled at the de-assertion of reset to set the polarity of

PWRCTL[4:1].

I/O, PU

PWRCTL_POL

41

0 = PWRCTL polarity is active low

1 = PWRCTL polarity is active high

7

TUSB8043

ZHCSGC6A –JUNE 2017–REVISED AUGUST 2017

www.ti.com.cn

Pin Functions (continued)

I/O

DESCRIPTION

NAME

NO.

Ganged operation enable/SMBus Address bit 2/HS Connection Status Upstream Port.

The value of the pin is sampled at the de-assertion of reset to set the power switch and over

current detection mode as follows:

0 = Individual power control supported when power switching is enabled

1 = Power control gangs supported when power switching is enabled

GANGED/SMBA2/

HS_UP

When SMBus mode is enabled using SMBUSz, this pin sets the value of the SMBus slave

address bit 2.

42

I/O, PD

After reset, this signal indicates the High-speed USB connection status of the upstream port if

enabled through the stsOutputEn bit in Additional Feature Configuration register. When

enabled, a value of 1 indicates the upstream port is connected to a High-speed USB capable

port.

Note: Individual power control must be enabled for battery charging applications.

Automatic Charge Mode Enable/HS Suspend Status.

The value of the pin is sampled at the de-assertion of reset to determine if automatic mode is

enabled as follows:

0 = Automatic Mode is enabled on ports that are enabled for battery charging when the

hub is unconnected. Please note that CDP is not supported on Port 1 when operating in

Automatic mode.

AUTOENz/

HS_SUSPEND

45

49

I/O, PU

1 = Automatic Mode is disabled

This value is also used to set the autoEnz bit in the Battery Charging Support Register.

After reset, this signal indicates the High-speed USB Suspend status of the upstream port if

enabled through the stsOutputEn bit in Additional Feature Configuration register. When

enabled, a value of 1 indicates the connection is suspended.

This pin is reserved for factory test. It is suggested to have this pin pulled down to ground on

PCB.

TEST

I, PD

Power and Ground Signals

5, 8,

13, 21,

28, 31,

51, 57

VDD

PWR 1.1-V power rail

16, 34,

52, 63

VDD33

PWR 3.3-V power rail

VSS (Thermal Pad)

NC

PWR Ground. Thermal pad must be connected to ground.

60

—

No connect, leave floating

8

TUSB8043

www.ti.com.cn

ZHCSGC6A –JUNE 2017–REVISED AUGUST 2017

7 Specifications

7.1 Absolute Maximum Ratings⁽¹⁾

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

MIN

–0.3

MAX

1.4

UNIT

V

V_DDSteady-state supply voltage

Supply Voltage Range

V_DD33Steady-state supply voltage

3.8

V

USB_SSRXP_UP, USB_SSRXN_UP, USB_SSRXP_DN[4:1],

USB_SSRXN_DP[4:1] and USB_VBUS terminals

-0.3

1.4

V

Voltage Range

XI terminals

-0.3

–65

2.45

3.8

V

All other terminals

Storage temperature, T_stg

150

°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.

7.2 ESD Ratings

VALUE

±2000

UNIT

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

V_(ESD)

Electrostatic discharge

V

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

C101⁽²⁾

±500

(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.

7.3 Recommended Operating Conditions

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

MIN

0.99

3

NOM

1.1

MAX

UNIT

V

VDD⁽¹⁾

VDD33

USB_VBUS

T_A

1.1V supply voltage

1.26

3.6

3.3V supply voltage

3.3

V

Voltage at USB_VBUS PAD

Operating free-air temperature

Operating junction temperature

0

1.155

70

V

TUSB8043

0

°C

T_J

–40

105

(1) A 1.05-V, 1.1-V, or 1.2-V supply may be used as long as minimum and maximum supply conditions are met.

7.4 Thermal Information

TUSB8043

RGC

64 PINS

26

THERMAL METRIC⁽¹⁾

UNIT

R_θJA

Junction-to-ambient thermal resistance

°C/W

R_θJCtop

R_θJB

Junction-to-case (top) thermal resistance

Junction-to-board thermal resistance

11.5

5.3

ψ_JT

Junction-to-top characterization parameter

Junction-to-board characterization parameter

Junction-to-case (bottom) thermal resistance

0.2

ψ_JB

5.2

R_θJCbot

1.0

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

report.

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7.5 Electrical Characteristics, 3.3-V I/O

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

PARAMETER

OPERATION TEST CONDITIONS

MIN

2

TYP

MAX

UNIT

V_IH

V_IL

V_I

High-level input voltage⁽¹⁾

Low-level input voltage⁽¹⁾

Input voltage

VDD33

0.8

V

0

VDD33

V_O

Output voltage⁽²⁾

0

Input transition time (t_riseand

t_t

0

25

ns

V

t_fall)

0.13 x

VDD33

V_hys

Input hysteresis⁽³⁾

V_OH

V_OL

High-level output voltage

Low-level output voltage

VDD33

I_OH= -4 mA

I_OL= 4 mA

2.4

V

0.4

High-impedance, output

current⁽²⁾

I_OZ

VDD33

V_I= 0 to VDD33

±20

µA

High-impedance, output current

with internal pullup or pulldown

resistor⁽⁴⁾

Input current⁽⁵⁾

I_OZP

VDD33

V_I= 0 to VDD33

±250

µA

I_I

±15

27.5

25

µA

KΩ

R_PD

R_PU

Internal pull-down resister

Internal pull-up resistor

13.5

14.5

19

(1) Applies to external inputs and bidirectional buffers.

(2) Applies to external outputs and bidirectional buffers.

(3) Applies to GRSTz.

(4) Applies to pins with internal pullups/pulldowns.

(5) Applies to external input buffers.

7.6 Timing Requirements, Power-Up

PARAMETER

DESCRIPTION

VDD33 stable before VDD stable⁽¹⁾

MIN

TYP

MAX

UNIT

ms

µs

(2)

t_d1

See

t_d2

VDD and VDD33 stable before de-assertion of GRSTz

Setup for MISC inputs⁽³⁾sampled at the de-assertion of GRSTz

Hold for MISC inputs⁽³⁾sampled at the de-assertion of GRSTz

VDD33 supply ramp requirements

3

0.1

0.2

t_{su_io}

t_{hd_io}

µs

t_{VDD33_RAMP}

t_{VDD_RAMP}

100

ms

VDD supply ramp requirements

(1) An active reset is required if the VDD33 supply is stable before the VDD11 supply. This active Reset shall meet the 3ms power-up delay

counting from both power supplies being stable to the de-assertion of GRSTz.

(2) There is no power-on relationship between VDD33 and VDD unless GRSTz is only connected to a capacitor to GND. Then VDD must

be stable minimum of 10 µs before the VDD33.

(3) MISC pins sampled at de-assertion of GRSTz: BATEN[4:1], AUTOENz, FULLPWRMGMTz, GANGED, SMBUSz, and PWRCTL_POL.

t

d2

GRSTz

VDD33

t

d1

VDD

t

hd_io

su_io

MISC_IO

Figure 1. Power-Up Timing Requirements

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7.7 Hub Input Supply Current

Typical values measured at T_A= 25°C

VDD33

3.3 V

VDD

PARAMETER

UNIT

1.1 V

LOW POWER MODES

Power On (after Reset)

3

30

24

30

mA

Upstream Disconnect

Suspend

ACTIVE MODES (US state / DS State)

3.0 host / 1 SS Device and Hub in U1 / U2

3.0 host / 1 SS Device and Hub in U0

3.0 host / 2 SS Devices and Hub in U1 / U2

3.0 host / 2 SS Devices and Hub in U0

3.0 host / 3 SS Devices and Hub in U1 / U2

3.0 host / 3 SS Devices and Hub in U0

3.0 host / 4 SS Devices and Hub in U1 / U2

3.0 host / 4 SS Devices and Hub in U0

45

84

95

45

76

240

356

301

457

372

563

440

672

372

512

55

mA

3.0 host / 1 SS Device in U0 and 1 HS Device

3.0 host / 2 SS Devices in U0 and 2 HS Devices

2.0 host / HS Device

2.0 host / 4 HS Devices

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8 Detailed Description

8.1 Overview

The TUSB8043 is a four-port USB 3.1 Gen1 compliant hub. It provides simultaneous SuperSpeed USB and high-

speed/full-speed connections on the upstream port and provides SuperSpeed USB, high-speed, full-speed, or

low-speed connections on the downstream ports. When the upstream port is connected to an electrical

environment that only supports high-speed or full-speed/low-speed connections, SuperSpeed USB connectivity is

disabled on the downstream ports. When the upstream port is connected to an electrical environment that only

supports full-speed/low-speed connections, SuperSpeed USB and high-speed connectivity are disabled on the

downstream ports.

8.2 Functional Block Diagram

VDD33

Power

Distribution

VBUS

Detect

VDD

VSS

USB 2.0 Hub

SuperSpeed Hub

XI

Oscilator

XO

Clock

and

Reset

GRSTz

Distribution

TEST

GANGED/SMBA2/HS_UP

HID

to

I2C

FULLPWRMGMTz/SMBA1/SS_UP

PWRCTL_POL

SMBUSz/SS_SUSPEND

AUTOENz/HS_SUSPEND

SCL/SMBCLK

OTP

ROM

Control

Registers

SDA/SMBDAT

GPIO

I2C

OVERCUR1z

PWRCTL1/BATEN1

SMBUS

OVERCUR2z

PWRCTL2/BATEN2

OVERCUR3z

PWRCTL3/BATEN3

OVERCUR4z

PWRCTL4/BATEN4

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8.3 Feature Description

8.3.1 Battery Charging Features

The TUSB8043 provides support for USB Battery Charging (BC1.2) and custom charging. Battery charging

support may be enabled on a per port basis through the REG_6h(batEn[3:0]).

USB Battery charging support includes both Charging Downstream Port (CDP) and Dedicated Charging Port

(DCP) modes. The DCP mode is compliant with the Chinese Telecommunications Industry Standard YD/T 1591-

2009. CDP is enabled when the upstream port has detected valid VBUS, configured, and host sets port power.

When the upstream port is not connected and battery charging support is enabled, the TUSB8043 will enable

DCP mode.

In addition to USB Battery charging (BC1.2), the TUSB8043 supports custom charging indications: Divider

Charging (ACP3, ACP2, ACP1 modes), and Galaxy compatible charging. These custom charging modes are

only supported when upstream port is unconnected and AUTOMODE is enabled. When in AUTOMODE and

upstream port is disconnected, the port will automatically transition from ACP mode to the DCP mode depending

on the portable device connected. The divided mode places a fixed DC voltage on the ports DP and DM signals

which allows some devices to identify the capabilities of the charger. The default divider mode indicates support

for up to 10W (ACP3). The divider mode can be configured to report a lower-current setting (up to 5 W) through

REG_0Ah (HiCurAcpModeEn).

When the upstream port is not connected and battery charging support is enabled for a port, the TUSB8043

drives the port power enable active. If AUTOMODE is disabled, then DCP mode is used. If AUTOMODE is

enabled and FullAutoEn bit is cleared (Reg_25h Bit 0), then TUSB8043 will start with highest enabled divider

current mode (ACPx). The TUSB8043 will remain in highest current mode as long as a pull-up is not detected on

DP pin. If an pull-up is detected on DP pin, then TUSB8043 will drive the port power enable inactive and switch

to Galaxy mode, if enabled, or to DCP mode if Galaxy mode is disabled. The TUSB8043 will again drive the port

power enable active. The TUSB8043 will remain in Galaxy mode as long as no pull-up is detected on DP pin. If

an pull-up is detected on DP pin, then TUSB8043 will drive the port power enable inactive and transition to DCP

mode. The TUSB8043 will again drive the port power enable active. In DCP mode, the TUSB8043 will look for a

pull-up detected on DP pin or RxVdat. If a pull-up or RxVdat is detected on DP, the TUSB8043 will remain in

DCP mode. If no pull-up or RxVdat is detected on DP pin after 2 seconds, the TUSB8043 will drive the port

power enable inactive and transition back to ACPx mode. This sequence will repeat until upstream port is

connected.

When Automatic mode is enabled and full automatic mode (FullAutoEn Reg_25h bit 0) is enabled, TUSB8043

will perform same sequence described in previous paragraph with the addition of attempting all supported ACPx

modes before sequencing to Galaxy Mode (if enabled) or DCP mode.

The supported battery charging modes when TUSB8043 configured for SMBus or external EEPROM is detailed

in Battery Charging Modes with SMBus/EEPROM Table.

The supported battery charging modes when TUSB8043 configured for I2C but without an external EEPROM is

determined by the sampled state of the pins. These modes are detailed in Battery Charging Modes without

EEPROM Table.

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Feature Description (continued)

Table 1. TUSB8043 Battery Charging Modes with SMBus or I2C EEPROM

Battery Charging Mode Port x

(x = n + 1)

0

1

Don’t Care

> 4V

Don't Care

Don’t Care

Don't Care

1

Don't Care

No Charging support

CDP

DCP

< 4V

AUTOMODE enabled. Sequences through all ACPx modes and DCP

with the exception of ACP3

1

< 4V

0

1

Alternate ACP2, ACP1, DCP

AUTOMODE enabled. Sequences through all ACPx modes and DCP.

Alternate ACP3, ACP2, ACP1, DCP

1

< 4V

< 4 V

< 4V

1

0

1

0

1

0

1

0

1

0

1

0

1

0

AUTOMODE enabled. Sequences between ACP2 and DCP.

Alternate ACP2, DCP

AUTOMODE enabled. Sequences between ACP3 and DCP.

Alternate ACP3, DCP

AUTOMODE enabled with Galaxy compatible charging support.

Alternate ACP2, ACP1, Galaxy, DCP.

AUTOMODE enabled with Galaxy compatible charging support.

Alternate ACP3, ACP2, ACP1, Galaxy, DCP

AUTOMODE enabled with Galaxy compatible charging support.

Alternate ACP2, Galaxy, DCP

AUTOMODE enabled with Galaxy compatible charging support.

Alternate ACP3, Galaxy, DCP

Table 2. TUSB8043 Battery Charging Modes without EEPROM

Battery Charging Mode Port x

(x = n + 1)

0

1

Don’t Care Don’t Care

Don't Care

0

No Charging support

> 4V

< 4V

Don't Care

1

CDP

DCP

AUTOMODE enabled with Galaxy compatible charging support. Sequences

through all ACPx modes.

1

< 4V

0

Alternate ACP3, ACP2, ACP1, Galaxy, DCP.

AUTOMODE enabled with Galaxy compatible charging support.

Alternate ACP3, Galaxy, DCP

1

< 4V

0

1

AUTOMODE enabled. Sequences through all ACPx modes.

Alternate ACP3, ACP2, ACP1, DCP.

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8.3.2 USB Power Management

The TUSB8043 can be configured for power switched applications using either per-port (Full power managed) or

ganged power-enable controls and over-current status inputs. When battery charge is enabled, the TUSB8043

will always function in full power managed.

Power switch support is enabled by REG_5h (fullPwrMgmtz) and the per-port or ganged mode is configured by

REG_5h(ganged).

The TUSB8043 supports both active high and active low power-enable controls. The PWRCTL[4:1] polarity is

configured by REG_Ah(pwrctlPol).

8.3.3 I²C Programming Support Using Internal Hid to I²C Interface

The TUSB8043 I²C programming mode is supported using class-specific requests through the HID interface. The

HID's embedded port will be numbered 1 greater than the highest numbered exposed port. The internal HID to

I²C function of the TUSB8043 does not have an interrupt OUT endpoint. The TUSB8043 supports GET REPORT

(Input) through the HID interrupt and control endpoints. The GET REPORT (Feature) and SET REPORT (Output)

occurs through the control endpoint.

Table 3. HID Requests I²C Programming Support

COMMAND

bmRequestType

bRequest

wValue

wIndex

wLength

DATA

Setup field Offset

Offset = 0

Offset = 1

Offset = 2

Offset = 4

Offset = 6

N/A

0100H – input

0300H - feature

GET REPORT

SET REPORT

A1H

21H

01H

09H

0000H

Report Length

Report

0200H – output

Other HID class specific requests are optional and not supported (SET IDLE, SET PROTOCOL, GET IDLE, GET

PROTOCOL) . Also report IDs are not required since all requests are not interleaved.

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8.3.3.1 SET REPORT (Output)

Report length includes overhead bytes (1 byte of opcode, 1 byte of device address and 2 bytes of data length)

and must match the number of bytes sent in the data stage or the request will be stalled.

•

1-byte opcode

–

0x01 read I2C

0x02 write I2C with stop

0x03 write I2C without stop (use to set sub-address prior to read)

•

1-byte I2C slave (7-bit) address

2-byte I2C transaction data length

"length" bytes of Data for a write, but none for a read.

Set Report status stage reports only the status of the receipt and validity of the request, not the status of the I²C

transaction. As long as the fields construct a valid request, the status stage will be Acked by a null packet.

Otherwise, it will be STALLed. For example, if the report_length is longer than the amount of data sent before the

status stage or the wLength is greater than the number of bytes of data sent in the data stage, the status stage

will be STALLed. If the number of bytes sent in the data stage is greater than wLength or report_length, the data

stage will be STALLED.

Software shall ensure properly formatted commands and data responses. The sum of the start address and

wLength shall be less than the total size of the address range of the target device in a properly formatted

command. Hardware shall wrap any data addresses above FFFFh and shall discard any data transmitted greater

than wLength and return STALL. A STALL will also be returned if opcode is 00h.

The I²C master that performs the I²C reads and writes initiated through USB HID interface supports clock

stretching. It operates at 400 kHz by default, but can be configured for 100 kHz through eFuse or register.

If the TUSB8043 is suspended (L2) by the USB host, the USB HID interface must enter suspend, but the I²C

master shall remain active while attempting to complete an active I²C write request. An active I²C read request

may be aborted if the TUSB8043 enters USB suspend state. Per the USB specification, the USB host should not

suspend the HID interface while an I²C read or write is still in progress. The USB HID interface shall refuse

requests to enter USB 2.0 sleep mode (L1) while an I²C read or write is in progress.

8.3.3.2 GET REPORT (Feature)

This HID Report will always return a 2-byte constant (0x82FF) which can be used to identify compatible HID

devices even if the customer changes the VID/PID.

8.3.3.3 GET REPORT (Input)

A report length of one reports the status byte only. To receive a report with data, the report length must be the

length of the data, plus one byte for status and two bytes for the length field.

•

1-byte Status

–

0 Success

1 Fail — timeout (35 ms)

2 Fail — Address nak

3 Fail — data nak

•

2-byte length

"length" bytes of Data for a read, but not for a write or a feature report.

A Get Report (input) request is required for both read and write. The interrupt endpoint will NAK until the I²C

transaction is complete, so that it can report length, data for a read, and final status.

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8.3.4 One Time Programmable (OTP) Configuration

The TUSB8043 allows device configuration through one time programmable non-volatile memory (OTP). The

programming of the OTP is supported using vendor-defined USB device requests. For details using the OTP

features please contact your TI representative.

Table 4 provides a list features which may be configured using the OTP.

Table 4. OTP Configurable Features

CONFIGURATION REGISTER

BIT FIELD

DESCRIPTION

OFFSET

REG_01h

REG_02h

REG_03h

REG_04h

[7:0]

Vendor ID LSB

Vendor ID MSB

Product ID LSB

Product ID MSB

Port removable configuration for downstream ports 1. OTP

configuration is inverse of rmbl[3:0], i.e. 1 = not removable, 0 =

removable.

REG_07h

[0]

[1]

[2]

[3]

Port removable configuration for downstream ports 2. OTP

configuration is inverse of rmbl[3:0], i.e. 1 = not removable, 0 =

removable.

Port removable configuration for downstream ports 3. OTP

configuration is inverse of rmbl[3:0], i.e. 1 = not removable, 0 =

removable.

Port removable configuration for downstream ports 4. OTP

configuration is inverse of rmbl[3:0], i.e. 1 = not removable, 0 =

removable.

REG_08h

REG_0Ah

REG_0Bh

REG_25h

REG_26h

REG_F0h

[3:0]

[3]

Port used Configured register.

Enable Device Attach Detection..

[4]

High-current divider mode enable.

[0]

USB 2.0 port polarity configuration for downstream ports 1.

USB 2.0 port polarity configuration for downstream ports 2.

USB 2.0 port polarity configuration for downstream ports 3.

USB 2.0 port polarity configuration for downstream ports 4.

Device Configuration Register 3

[1]

[2]

[3]

[4:0]

[3:0]

[3:1]

USB2.0 Only Port Register

USB power switch power-on delay.

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8.3.5 Clock Generation

The TUSB8043 accepts a crystal input to drive an internal oscillator or an external clock source. If a clock is

provided to XI instead of a crystal, XO is left open. Otherwise, if a crystal is used, the connection needs to follow

the guidelines below. Since XI and XO are coupled to other leads and supplies on the PCB, it is important to

keep them as short as possible and away from any switching leads. It is also recommended to minimize the

capacitance between XI and XO. This can be accomplished by shielding C1 and C2 with the clean ground lines.

R1

1M

Y1

XI

24 MHz

CLOCK

XO

CL1

CL2

Figure 2. TUSB8043 Clock

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8.3.6 Crystal Requirements

The crystal must be fundamental mode with load capacitance of 12 pF - 24 pF and frequency stability rating of

±100 PPM or better. To ensure proper startup oscillation condition, a maximum crystal equivalent series

resistance (ESR) of 50 Ω is recommended. A parallel load capacitor should be used if a crystal source is used.

The exact load capacitance value used depends on the crystal vendor. Refer to application note Selection and

Specification for Crystals for Texas Instruments USB2.0 devices (SLLA122) for details on how to determine the

load capacitance value.

8.3.7 Input Clock Requirements

When using an external clock source such as an oscillator, the reference clock should have a ±100 PPM or

better frequency stability and have less than 50-ps absolute peak to peak jitter or less than 25-ps peak to peak

jitter after applying the USB 3.1 jitter transfer function. XI should be tied to the 1.8-V clock source and XO should

be left floating.

8.3.8 Power-Up and Reset

The TUSB8043 does not have specific power sequencing requirements with respect to the core power (VDD) or

I/O and analog power (VDD33) as long as GRSTz is held in an asserted state while supplies ramp. The core

power (VDD) or I/O power (VDD33) may be powered up for an indefinite period of time while the other is not

powered up if all of these constraints are met:

•

All maximum ratings and recommended operating conditions are observed.

All warnings about exposure to maximum rated and recommended conditions are observed, particularly

junction temperature. These apply to power transitions as well as normal operation.

•

Bus contention while VDD33 is powered up must be limited to 100 hours over the projected life-time of the

device.

Bus contention while VDD33 is powered down may violate the absolute maximum ratings.

A supply bus is powered up when the voltage is within the recommended operating range. It is powered down

when it is below that range, either stable or in transition.

A minimum reset duration of 3 ms is required. This is defined as the time when the power supplies are in the

recommended operating range to the de-assertion of GRSTz. This can be generated using programmable-delay

supervisory device or using an RC circuit. When a RC circuit is used, the external capacitor size chosen must be

large enough to meet the 3ms minimum duration requirement. The R of the RC circuit is the internal R_PU

.

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8.4 Device Functional Modes

8.4.1 External Configuration Interface

The TUSB8043 supports a serial interface for configuration register access. The device may be configured by an

attached I²C EEPROM or accessed as a slave by an external SMBus master. The external interface is enabled

when both the SCL/SMBCLK and SDA/SMBDAT pins are pulled up to 3.3 V at the de-assertion of reset. The

mode, I²C master or SMBus slave, is determined by the state of SMBUSz/SS_SUSPEND pin at reset. With the

integrated USB HID to I²C master, the I²C interface can also be used to program an external EEPROM or

perform updates of an external MCU's firmware.

8.4.2 I²C EEPROM Operation

The TUSB8043 supports a single-master, fast mode (400KHz) connection to a dedicated I²C EEPROM when the

I²C interface mode is enabled. In I²C mode, the TUSB8043 reads the contents of the EEPROM at bus address

1010000b using 7-bit addressing starting at address 0. The TUSB8043 will read the entire EEPROM contents

using a single burst read transaction. The burst read transaction will end when the address reaches FFh.

If the value of the EEPROM contents at address byte 00h equals 55h, the TUSB8043 loads the configuration

registers according to the EEPROM map. If the first byte is not 55h, the TUSB8043 exits the I²C mode and

continues execution with the default values in the configuration registers. The hub will not connect on the

upstream port until the configuration is completed.

NOTE

The bytes located above offset Ah are optional. The requirement for data in those

addresses is dependent on the options configured in the Device Configuration, and Device

Configuration 2 registers.

The minimum size I²C EEPROM required is 2Kbit.

For details on I²C operation refer to the UM10204 I²C-bus Specification and User Manual.

8.4.3 Port Configuration

The TUSB8043 port configurations can be selected by registers or efuse. The Port Used Configuration register

(USED[3:0]) define how many ports can possibly be reported by the hub. The device removable configuration

register (RMBL[3:0]) define if the ports that are reported as used have permanently connected devices or not.

The USB 2.0 Only Port register (USB2_ONLY[3:0]) define whether or a used port is reported as part of the USB

2.0 hub or both the USB2.0 and USB3.1 hubs. The USB2_ONLY field will enable the USB2.0 port even if the

corresponding USED bit is low. The internal HID port will always be the highest number USB2.0 port. The table

below shows examples of the possible combinations.

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Device Functional Modes (continued)

Table 5. TUSB8043 Downstream Port Configuration Examples

USB2_ONLY

[3:0]

USED[3:0]

RMBL[3:0]

Reported Port Configuration

Physical to Logical Port mapping

Physical1 => Logical Port1 for USB3.1 and USB2.0.

Physical2 => Logical Port2 for USB3.1 and USB2.0.

Physical3 => Logical Port3 for USB3.1 and USB2.0.

Physical4 => Logical Port4 for USB3.1 and USB2.0.

Physical5 => Logical Port5 for USB2.0.

4 Port USB3.1 Hub

5 Port USB2.0 Hub

Port 5 is permanently attached HID

1111

0000

0010

1110

Physical1 Not used.

Physical2 => Logical Port1 for USB3.1 and USB2.0.

Physical3 => Logical Port2 for USB3.1 and USB2.0.

Physical4 => Logical Port3 for USB3.1 and USB2.0.

Physical5 => Logical Port4 for USB 2.0.

3 Port USB3.1 Hub

4 Port USB2.0 Hub

Port 4 is permanently attached HID

1110

1100

0011

1000

1111

0111

1111

Physical1 Not used.

2 Port USB 3.1 Hub

3 Port USB2.0 hub with permanently attached

device on Port 2

Physical2 Not used.

Physical3 => Logical Port1 for USB3.1 and USB2.0.

Physical4 => Logical Port2 for USB3.1 and USB2.0.

Physical5 => Logical Port3 for USB2.0.

Port 3 is a permanently attached HID

Physical1 => Logical Port1 for USB3.1 and USB2.0.

Physical2 => Logical Port2 for USB2.0.

Physical3 Not Used.

1 Port USB 3.1 Hub

3 Port USB 2.0 Hub

Port 3 is a permanently attached HID

Physical4 Not used.

Physical5 => Logical Port3 for USB2.0.

Physical1 Not used.

Physical2 => Logical Port2 for USB2.0.

Physical3 Not used

1 Port USB 3.1 Hub

3 Port USB 2.0 Hub

Port 3 is a permanently attached HID

Physical4 => Logical Port1 for USB3.1 and USB2.0.

Physical5 => Logical Port3 for USB2.0.

Physical1 => Logical Port1 for USB3.1 and USB2.0.

Physical2 => Logical Port2 for USB2.0.

Physical3 => Logical Port3 for USB2.0.

Physical4 => Logical Port4 for USB2.0.

Physical5 => Logical Port5 for USB2.0.

1 Port USB 3.1 Hub

5 Port USB 2.0 Hub

Port 5 is a permanently attached HID

Invalid combination when USB2_ONLY =

0000, 0001, 0100, or 0101. If invalid

combination is used, then physical port 4 will

not operate at USB3.1 Gen 1 speeds.

1010

1011

1110

1111

N/A

0x0x

0x01

010x

0101

Invalid combination when USB2_ONLY =

0001 or 0101. If invalid combination is used,

then physical port 4 will not operate at USB3.1

Gen 1 speeds.

Invalid combination when USB2_ONLY =

0100 or 0101. If invalid combination is used,

then physical port 4 will not operate at USB3.1

Gen 1 speeds.

Invalid combination when USB2_ONLY =

0101. If invalid combination is used, then

physical port 4 will not operate at USB3.1 Gen

1 speeds.

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8.4.4 SMBus Slave Operation

When the SMBus interface mode is enabled, the TUSB8043 supports read block and write block protocols as a

slave-only SMBus device.

The TUSB8043 slave address is 1000 1xyz, where:

•

x is the state of GANGED/SMBA2/HS_UP pin at reset,

y is the state of FULLPWRMGMTz/SMBA1/SS_UP pin at reset, and

z is the read/write bit; 1 = read access, 0 = write access.

If the TUSB8043 is addressed by a host using an unsupported protocol it will not respond. The TUSB8043 waits

indefinitely for configuration by the SMBus host and will not connect on the upstream port until the SMBus host

indicates configuration is complete by clearing the CFG_ACTIVE bit.

For details on SMBus requirements, refer to the System Management Bus Specification.

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8.5 Register Maps

8.5.1 Configuration Registers

The internal configuration registers are accessed on byte boundaries. The configuration register values are

loaded with defaults but can be over-written when the TUSB8043 is in I²C or SMBus mode.

Table 6. TUSB8043 Register Map

BYTE

ADDRESS

CONTENTS

EEPROM CONFIGURABLE

00h

ROM Signature Register

Vendor ID LSB

Yes

No

01h

02h

Vendor ID MSB

03h

Product ID LSB

04h

Product ID MSB

05h

Device Configuration Register

Battery Charging Support Register

Device Removable Configuration Register

Port Used Configuration Register

Reserved. Must default to 00h.

Device Configuration Register 2

USB 2.0 Port Polarity Control Register

Reserved

06h

07h

08h

09h

0Ah

0Bh

0Ch-0Fh

10h-1Fh

20h-21h

22h

UUID Byte [15:0]

No

LangID Byte [1:0]

Yes

No

Serial Number Length

Manufacturer String Length

Product String Length

Device Configuration Register 3

USB 2.0 Only Port Register

Reserved

23h

24h

25h

26h

27h-2Eh

2Fh

Reserved

30h-4Fh

50h-8Fh

90h-CFh

D0h-D4h

D5h-D7h

D8h-DCh

DDh-EFh

F0h

Serial Number String Byte [31:0]

Manufacturer String Byte [63:0]

Product String Byte [63:0]

Reserved

Yes

Yes⁽¹⁾

No

Reserved

Yes⁽¹⁾

Reserved

No

Additional Features Configuration Register

Reserved

Yes

No

F1h-F7h

F8h

SMBus Device Status and Command Register

Reserved

No

F9h - FFh

No

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8.5.2 ROM Signature Register

Figure 3. Register Offset 0h

Bit No.

7

0

6

0

5

0

4

0

3

0

2

0

1

0

Reset State

Table 7. Bit Descriptions – ROM Signature Register

Bit

Field

Type

Description

ROM Signature Register. This register is used by the TUSB8043 in I²C

mode to validate the attached EEPROM has been programmed. The

first byte of the EEPROM is compared to the mask 55h and if not a

match, the TUSB8043 aborts the EEPROM load and executes with the

register defaults.

7:0

romSignature

RW

8.5.3 Vendor ID LSB Register

Figure 4. Register Offset 1h

Bit No.

7

0

6

1

5

0

4

1

3

0

2

0

1

0

1

Reset State

Table 8. Bit Descriptions – Vendor ID LSB Register

Bit

Field

Type

Description

Vendor ID LSB. Least significant byte of the unique vendor ID

assigned by the USB-IF; the default value of this register is 51h

representing the LSB of the TI Vendor ID 0451h. The value may be

over-written to indicate a customer Vendor ID.

7:0

vendorIdLsb

RO/RW

Value used for this field will be the non-zero value written by

EEPROM/SMBus to both PID and VID. If a zero value is written by

EEPROM/SMbus to both PID and VID, then value used for this field

will be the non-zero value from OTP. If a zero value is written by OTP,

then value used for this field will be 51h.

8.5.4 Vendor ID MSB Register

Figure 5. Register Offset 2h

Bit No.

7

0

6

0

5

0

4

0

3

0

2

1

0

Reset State

Table 9. Bit Descriptions – Vendor ID MSB Register

Bit

Field

Type

Description

Vendor ID MSB. Most significant byte of the unique vendor ID

assigned by the USB-IF; the default value of this register is 04h

representing the MSB of the TI Vendor ID 0451h. The value may be

over-written to indicate a customer Vendor ID.

7:0

vendorIdMsb

RO/RW

Value used for this field will be the non-zero value written by

EEPROM/SMBus to both PID and VID. If a zero value is written by

EEPROM/SMbus to both PID and VID, then value used for this field

will be the non-zero value from OTP. If a zero value is written by OTP,

then value used for this field will be 04h.

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8.5.5 Product ID LSB Register

Figure 6. Register Offset 3h

Bit No.

7

0

6

1

5

0

4

0

3

0

2

0

1

0

Reset State

Table 10. Bit Descriptions – Product ID LSB Register

Bit

Field

Type

Description

Product ID LSB. Least significant byte of the product ID assigned by

Texas Instruments and reported in the SuperSpeed Device descriptor.

the default value of this register is 40h representing the LSB of the

SuperSpeed product ID assigned by Texas Instruments The value

reported in the USB 2.0 Device descriptor is the value of this register

bit wise XORed with 00000010b. The value may be over-written to

indicate a customer product ID.

7:0

productIdLsb

RO/RW

Value used for this field will be the non-zero value written by

EEPROM/SMBus to both PID and VID. If a zero value is written by

EEPROM/SMbus to both PID and VID, then value used for this field

will be the non-zero value from OTP. If a zero value is written by OTP,

then value used for this field will be 40h .

8.5.6 Product ID MSB Register

Figure 7. Register Offset 4h

Bit No.

7

1

6

0

5

0

4

0

3

0

2

0

1

0

1

Reset State

Table 11. Bit Descriptions – Product ID MSB Register

Bit

Field

Type

Description

Product ID MSB. Most significant byte of the product ID assigned by

Texas Instruments; the default value of this register is 83h representing

the MSB of the product ID assigned by Texas Instruments. The value

may be over-written to indicate a customer product ID.

7:0

productIdMsb

RO/RW

Value used for this field will be the non-zero value written by

EEPROM/SMBus to both PID and VID. If a zero value is written by

EEPROM/SMbus to both PID and VID, then value used for this field

will be the non-zero value from OTP. If a zero value is written by OTP,

then value used for this field will be 83h.

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8.5.7 Device Configuration Register

Figure 8. Register Offset 5h

Bit No.

7

0

6

0

5

0

4

1

3

2

1

0

Reset State

X

Table 12. Bit Descriptions – Device Configuration Register

Bit

Field

Type

Description

Custom strings enable. This bit controls the ability to write to the

Manufacturer String Length, Manufacturer String, Product String

Length, Product String, and Language ID registers

0 = The Manufacturer String Length, Manufacturer String, Product

String Length, Product String, and Language ID registers are read only

1 = The Manufacturer String Length, Manufacturer String, Product

String Length, Product String, and Language ID registers may be

loaded by EEPROM or written by SMBus

7

customStrings

customSernum

RW

The default value of this bit is 0.

Custom serial number enable. This bit controls the ability to write to the

serial number registers.

0 = The Serial Number String Length and Serial Number String

registers are read only

6

RW

1 = Serial Number String Length and Serial Number String registers

may be loaded by EEPROM or written by SMBus

The default value of this bit is 0.

U1 U2 Disable. This bit controls the U1/U2 support.

0 = U1/U2 support is enabled

1 = U1/U2 support is disabled, the TUSB8043 will not initiate or accept

any U1 or U2 requests on any port, upstream or downstream, unless it

receives or sends a Force_LinkPM_Accept LMP. After receiving or

sending an FLPMA LMP, it will continue to enable U1 and U2

according to USB 3.1 protocol until it gets a power-on reset or is

disconnected on its upstream port.

5

u1u2Disable

RW

When the TUSB8043 is in I²C mode, the TUSB8043 loads this bit from

the contents of the EEPROM.

When the TUSB8043 is in SMBUS mode, the value may be over-

written by an SMBus host.

4

3

RSVD

RO

Reserved. This bit is reserved and returns 1 when read.

Ganged. This bit is loaded at the de-assertion of reset with the value of

the GANGED/SMBA2/HS_UP pin.

0 = When fullPwrMgmtz = 0, each port is individually power switched

and enabled by the PWRCTL[4:1]/BATEN[4:1] pins

1 = When fullPwrMgmtz = 0, the power switch control for all ports is

ganged and enabled by the PWRCTL[4:1]/BATEN1 pin

When the TUSB8043 is in I²C mode, the TUSB8043 loads this bit from

the contents of the EEPROM.

ganged

RW

When the TUSB8043 is in SMBUS mode, the value may be over-

written by an SMBus host.

Full Power Management. This bit is loaded at the de-assertion of reset

with the value of the FULLPWRMGMTz/SMBA1/SS_UP pin.

0 = Port power switching status reporting is enabled

1 = Port power switching status reporting is disabled

When the TUSB8043 is in I²C mode, the TUSB8043 loads this bit from

the contents of the EEPROM.

2

fullPwrMgmtz

RW

When the TUSB8043 is in SMBUS mode, the value may be over-

written by an SMBus host.

U1 U2 Timer Override. When this field is set, the TUSB8043 will

override the downstream ports U1/U2 timeout values set by USB3.1

Host software. If software sets value in the range of 1h - FFh, the

TUSB8043 will use the value of FFh. If software sets value to 0, then

TUSB8043 will use value of 0.

1

0

u1u2TimerOvr

RSVD

RW

RO

Reserved. This field is reserved and returns 0 when read.

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8.5.8 Battery Charging Support Register

Figure 9. Register Offset 6h

Bit No.

7

0

6

0

5

0

4

0

3

2

1

0

Reset State

X

Table 13. Bit Descriptions – Battery Charging Support Register

Bit

Field

Type

Description

7:4

RSVD

RO

Reserved. Read only, returns 0 when read.

Battery Charger Support. The bits in this field indicate whether the

downstream port implements the charging port features.

0 = The port is not enabled for battery charging support features

1 = The port is enabled for battery charging support features

Each bit corresponds directly to a downstream port, i.e. batEn0

corresponds to downstream port 1, and batEN1 corresponds to

downstream port 2.

3:0

batEn[3:0]

RW

The default value for these bits are loaded at the de-assertion of reset

with the value of PWRCTL/BATEN[3:0].

When in I2C/SMBus mode the bits in this field may be over-written by

EEPROM contents or by an SMBus host.

8.5.9 Device Removable Configuration Register

Figure 10. Register Offset 7h

Bit No.

7

0

6

0

5

4

3

2

1

0

Reset State

0

X

Table 14. Bit Descriptions – Device Removable Configuration Register

Bit

7

Field

Type

Description

Custom Removable. This bit controls the ability to write to the port

removable bits, port used bits, and USB2_ONLY bits.

0 = rmbl[3:0], used[3:0], and USB2_ONLY[3:0] are read only and the

values are loaded from the OTP ROM

1 = rmbl[3:0], used[3:0], and USB2_ONLY[3:0] are read/write and can

be loaded by EEPROM or written by SMBus

customRmbl

RSVD

RW

This bit may be written simultaneously with rmbl[3:0].

6:4

RO

Reserved. Read only, returns 0 when read.

Removable. The bits in this field indicate whether a device attached to

downstream ports 4 through 1 are removable or permanently attached.

0 = The device attached to the port is not removable

1 = The device attached to the port is removable

Each bit corresponds directly to a downstream port n + 1, i.e. rmbl0

corresponds to downstream port 1, rmbl1 corresponds to downstream

port 2, etc.

3:0

rmbl[3:0]

RO/RW

This field is read only unless the customRmbl bit is set to 1. Otherwise

the value of this filed reflects the inverted values of the OTP ROM

non_rmb[3:0] field.

8.5.10 Port Used Configuration Register

Figure 11. Register Offset 8h

Bit No.

7

0

6

0

5

0

4

0

3

1

2

1

0

1

Reset State

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Table 15. Bit Descriptions – Port Used Configuration Register

Bit

Field

Type

Description

7:4

RSVD

RO

Reserved. Read only.

Used. The bits in this field indicate whether a port is enabled.

0 = The port is not used or disabled

1 = The port is used or enabled

Each bit corresponds directly to a downstream port, i.e. used0

corresponds to downstream port 1, used1 corresponds to downstream

port 2, etc. All combinations are supported with the exception of both

ports 1 and 3 marked as disabled. This field is read only unless the

customRmbl bit is set to 1. When the corresponding USB2_ONLY bit is

set, the USB2 port will be used and enabled regardless of the bit

programmed into this field.

3:0

used[3:0]

RO/RW

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8.5.11 Device Configuration Register 2

Figure 12. Register Offset Ah

Bit No.

7

0

6

0

5

4

1

3

0

2

0

1

0

Reset State

X

Table 16. Bit Descriptions – Device Configuration Register 2

Bit

Field

Type

Description

7

Reserved

RO

Reserved. Read-only, returns 0 when read.

Custom Battery Charging Feature Enable. This bit controls the ability

to write to the battery charging feature configuration controls.

0 = The HiCurAcpModeEn is read only and the values are loaded from

the OTP ROM.

1 = The HiCurAcpModeEn bit is read/write and can be loaded by

EEPROM or written by SMBus.

6

5

customBCfeatures

RW

This bit may be written simultaneously with HiCurAcpModeEn.

Power enable polarity. This bit is loaded at the de-assertion of reset

with the value of the PWRCTL_POL pin.

0 = PWRCTL polarity is active low

1 = PWRCTL polarity is active high

pwrctlPol

When the TUSB8043 is in I²C mode, the TUSB8043 loads this bit from

the contents of the EEPROM.

When the TUSB8043 is in SMBUS mode, the value may be over-

written by an SMBus host.

High-current ACP mode enable. This bit enables the high-current tablet

charging mode when the automatic battery charging mode is enabled

for downstream ports.

0 = High current divider mode disabled . High current is ACP2 (default)

1 = High current divider mode enabled. High current mode is ACP3

This bit is read only unless the customBCfeatures bit is set to 1. If

customBCfeatures is 0, the value of this bit reflects the value of the

OTP ROM HiCurAcpModeEn bit.

4

HiCurAcpModeEn

Reserved

RO/RW

RW

3:2

Reserved

Automatic Mode Enable. This bit is loaded at the de-assertion of reset

with the value of the AUTOENz/HS_SUSPEND pin.

The automatic mode only applies to downstream ports with battery

charging enabled when the upstream port is not connected. Under

these conditions:

1

0

autoModeEnz

RW

RO

0 = Automatic mode battery charging features are enabled.

1 = Automatic mode is disabled; only Battery Charging DCP and CDP

mode is supported.

NOTE: When the upstream port is connected, Battery Charging CDP

mode will be supported on all ports that are enabled for battery

charging support regardless of the value of this bit.

RSVD

Reserved. Read only, returns 0 when read.

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8.5.12 USB 2.0 Port Polarity Control Register

Figure 13. Register Offset Bh

Bit No.

7

0

6

0

5

0

4

0

3

0

2

0

1

0

Reset State

Table 17. Bit Descriptions – USB 2.0 Port Polarity Control Register

Bit

7

Field

Type

Description

Custom USB 2.0 Polarity. This bit controls the ability to write the

p[4:0]_usb2pol bits.

0 = The p[4:0]_usb2pol bits are read only and the values are loaded

from the OTP ROM.

1 = The p[4:0]_usb2pol bits are read/write and can be loaded by

EEPROM or written by SMBus.

This bit may be written simultaneously with the p[4:0]_usb2pol bits

customPolarity

RSVD

RW

6:5

RO

Reserved. Read only, returns 0 when read.

Downstream Port 4 DM/DP Polarity. This controls the polarity of the

port.

0 = USB 2.0 port polarity is as documented by the pin out

1 = USB 2.0 port polarity is swapped from that documented in the pin

out, i.e. DM becomes DP, and DP becomes DM.

This bit is read only unless the customPolarity bit is set to 1. If

customPolarity is 0 the value of this bit reflects the value of the OTP

ROM p4_usb2pol bit.

4

3

2

p4_usb2pol

p3_usb2pol

p2_usb2pol

RO/RW

Downstream Port 3 DM/DP Polarity. This controls the polarity of the

port.

0 = USB 2.0 port polarity is as documented by the pin out

1 = USB 2.0 port polarity is swapped from that documented in the pin

out, i.e. DM becomes DP, and DP becomes DM.

This bit is read only unless the customPolarity bit is set to 1. If

customPolarity is 0 the value of this bit reflects the value of the OTP

ROM p3_usb2pol bit.

Downstream Port 2 DM/DP Polarity. This controls the polarity of the

port.

0 = USB 2.0 port polarity is as documented by the pin out

1 = USB 2.0 port polarity is swapped from that documented in the pin

out, i.e. DM becomes DP, and DP becomes DM.

This bit is read only unless the customPolarity bit is set to 1. If

customPolarity is 0 the value of this bit reflects the value of the OTP

ROM p2_usb2pol bit.

Downstream Port 1 DM/DP Polarity. This controls the polarity of the

port.

0 = USB 2.0 port polarity is as documented by the pin out

1 = USB 2.0 port polarity is swapped from that documented in the pin

out, i.e. DM becomes DP, and DP becomes DM.

This bit is read only unless the customPolarity bit is set to 1. If

customPolarity is 0 the value of this bit reflects the value of the OTP

ROM p1_usb2pol bit.

1

0

p1_usb2pol

p0_usb2pol

RORW

RO/RW

Upstream Port DM/DP Polarity. This controls the polarity of the port.

0 = USB 2.0 port polarity is as documented by the pin out

1 = USB 2.0 port polarity is swapped from that documented in the pin

out, i.e. DM becomes DP, and DP becomes DM.

This bit is read only unless the customPolarity bit is set to 1. If

customPolarity is 0 the value of this bit reflects the value of the OTP

ROM p0_usb2pol bit.

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8.5.13 UUID Registers

Figure 14. Register Offset 10h-1Fh

Bit No.

7

6

5

4

3

2

1

0

Reset State

X

Table 18. Bit Descriptions – UUID Byte N Register

Bit

Field

Type

Description

UUID byte N. The UUID returned in the Container ID descriptor. The

value of this register is provided by the device and is meets the UUID

requirements of Internet Engineering Task Force (IETF) RFC 4122 A

UUID URN Namespace.

7:0

uuidByte[n]

RO

8.5.14 Language ID LSB Register

Figure 15. Register Offset 20h

Bit No.

7

0

6

0

5

0

4

0

3

1

2

0

1

0

1

Reset State

Table 19. Bit Descriptions – Language ID LSB Register

Bit

Field

Type

Description

Language ID least significant byte. This register contains the value

returned in the LSB of the LANGID code in string index 0. The

TUSB8043 only supports one language ID. The default value of this

register is 09h representing the LSB of the LangID 0409h indicating

English United States.

7:0

langIdLsb

RO/RW

When customStrings is 1, this field may be over-written by the contents

of an attached EEPROM or by an SMBus host.

8.5.15 Language ID MSB Register

Figure 16. Register Offset 21h

Bit No.

7

0

6

0

5

0

4

0

3

0

2

0

1

0

Reset State

Table 20. Bit Descriptions – Language ID MSB Register

Bit

Field

Type

Description

Language ID most significant byte. This register contains the value

returned in the MSB of the LANGID code in string index 0. The

TUSB8043 only supports one language ID. The default value of this

register is 04h representing the MSB of the LangID 0409h indicating

English United States.

7:0

langIdMsb

RO/RW

When customStrings is 1, this field may be over-written by the contents

of an attached EEPROM or by an SMBus host.

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8.5.16 Serial Number String Length Register

Figure 17. Register Offset 22h

Bit No.

7

0

6

0

5

0

4

1

3

1

2

0

1

0

Reset State

Table 21. Bit Descriptions – Serial Number String Length Register

Bit

Field

Type

Description

7:6

RSVD

RO

Reserved. Read only, returns 0 when read.

Serial number string length. The string length in bytes for the serial

number string. The default value is 18h indicating that a 24 byte serial

number string is supported. The maximum string length is 32 bytes.

When customSernum is 1, this field may be over-written by the

contents of an attached EEPROM or by an SMBus host.

When the field is non-zero, a serial number string of

5:0

serNumStringLen

RO/RW

serNumbStringLen bytes is returned at string index 1 from the data

contained in the Serial Number String registers.

8.5.17 Manufacturer String Length Register

Figure 18. Register Offset 23h

Bit No.

7

0

6

0

5

4

3

2

0

1

0

Reset State

0

Table 22. Bit Descriptions – Manufacturer String Length Register

Bit

Field

Type

Description

7

RSVD

RO

Reserved. Read only, returns 0 when read.

Manufacturer string length. The string length in bytes for the

manufacturer string. The default value is 0, indicating that a

manufacturer string is not provided. The maximum string length is 64

bytes.

6:0

mfgStringLen

RO/RW

When customStrings is 1, this field may be over-written by the contents

of an attached EEPROM or by an SMBus host.

When the field is non-zero, a manufacturer string of mfgStringLen

bytes is returned at string index 3 from the data contained in the

Manufacturer String registers.

8.5.18 Product String Length Register

Figure 19. Register Offset 24h

Bit No.

7

0

6

0

5

0

4

0

3

0

2

0

1

0

Reset State

Table 23. Bit Descriptions – Product String Length Register

Bit

Field

Type

Description

7

RSVD

RO

Reserved. Read only, returns 0 when read.

Product string length. The string length in bytes for the product string.

The default value is 0, indicating that a product string is not provided.

The maximum string length is 64 bytes.

When customStrings is 1, this field may be over-written by the contents

of an attached EEPROM or by an SMBus host.

6:0

prodStringLen

RO/RW

When the field is non-zero, a product string of prodStringLen bytes is

returned at string index 3 from the data contained in the Product String

registers.

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8.5.19 Device Configuration Register 3

Figure 20. Register Offset 25h

Bit No.

7

0

6

0

5

0

4

0

3

0

2

0

1

0

Reset State

Table 24. Bit Descriptions – Device Configuration Register 3

Bit

Field

Type

Description

7:5

RSVD

RO

Reserved. Read only, returns 0 when read.

USB 2.0 hub reports as 2.0 only. This bit disables the USB 2.0 hub

from reporting 5Gbps support in the wSpeedsSupported field of the

USB SS BOS SS device capability descriptor. This bit will also disable

the USB3.0 hub.

4

USB2.0_only

RW

This bit is read/write but the read value returned is the Boolean OR of

this bit and the corresponding eFuse bit. If either bit is set, this feature

is enabled.

3

2

Reserved

I2C_100k

RO

Switch to reserved

I2C 100kHz. This bit controls the clock rate of the I2C master for both

USB to I2C requests . The EEPROM reads will occur at 400K unless

eFuse is used to set the rate to 100k.

This bit is read/write but the read value returned is the Boolean OR of

this bit and the corresponding eFuse bit. If either bit is set, this feature

is enabled.

R/W

Disable Galaxy compatible modes. When this field is high, Galaxy

charging compatible mode will not be included in AUTOMODE charger

sequence.

This bit is read/write but the read value returned is the Boolean OR of

this bit and the corresponding eFuse bit. If either bit is set, this feature

is disabled.

1

0

Galaxy_Enz

FullAutoEn

R/W

Enable all divider battery charging modes. When automode is enabled

and this bit is set, any DS port enabled for battery charging will attempt

all divider battery charging modes before DCP, starting with the

highest current option.

The bit is writable, but the value read back is the Boolean OR of this

bit and the corresponding eFuse control.

If either bit is set, eFuse or this register, this feature is enabled.

8.5.20 USB 2.0 Only Port Register

Figure 21. Register Offset 26h

Bit No.

7

0

6

0

5

0

4

0

3

0

2

0

1

0

Reset State

Table 25. Bit Descriptions – USB 2.0 Only Port Register

Bit

Field

Type

Description

7:4

RSVD

RO

Reserved. Read only, returns 0 when read.

USB 2.0 Only Ports. The bits in this field primarily indicate whether a

port is enabled only for USB 2.0 operation. This field is read-only

unless customRmbl bit is set. Also, these bits will override the

corresponding USED bit.

A value of 0 indicates the hub port is enabled for both USB 3.1 and

USB 2.0.

3:0

USB2_ONLY[3:0]

RO/RW

A value of 1 indicates the hub port is enabled only for USB 2.0

operation.

8.5.21 Serial Number String Registers

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Figure 22. Register Offset 30h-4Fh

Bit No.

7

6

5

x

4

x

3

x

2

x

1

x

0

x

Reset State

X

Table 26. Bit Descriptions – Serial Number Registers

Bit

Field

Type

Description

Serial Number byte N. The serial number returned in the Serial

Number string descriptor at string index 1. The default value of these

registers is assigned by TI. When customSernum is 1, these registers

may be over-written by EEPROM contents or by an SMBus host.

7:0

serialNumber[n]

RO/RW

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8.5.22 Manufacturer String Registers

Figure 23. Register Offset 50h-8Fh

Bit No.

7

0

6

0

5

0

4

0

3

0

2

0

1

0

Reset State

Table 27. Bit Descriptions – Manufacturer String Registers

Bit

Field

Type

Description

Manufacturer string byte N. These registers provide the string values

returned for string index 3 when mfgStringLen is greater than 0. The

number of bytes returned in the string is equal to mfgStringLen.

The programmed data should be in UNICODE UTF-16LE encodings

as defined by The Unicode Standard, Worldwide Character Encoding,

Version 5.0.

7:0

mfgStringByte[n]

RW

8.5.23 Product String Registers

Figure 24. Register Offset 90h-CFh

Bit No.

7

0

6

0

5

0

4

0

3

0

2

0

1

0

Reset State

Table 28. Bit Descriptions – Product String Byte N Register

Bit

Field

Type

Description

Product string byte N. These registers provide the string values

returned for string index 2 when prodStringLen is greater than 0. The

number of bytes returned in the string is equal to prodStringLen.

The programmed data should be in UNICODE UTF-16LE encodings

as defined by The Unicode Standard, Worldwide Character Encoding,

Version 5.0.

7:0

prodStringByte[n]

RO/RW

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TUSB8043

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8.5.24 Additional Feature Configuration Register

Figure 25. Register Offset F0h

Bit No.

7

0

6

0

5

0

4

0

3

0

2

0

1

0

Reset State

Table 29. Bit Descriptions – Additional Feature Configuration Register

Bit

Field

Type

Description

7:5

Reserved

RW

Reserved. This field defaults to 3'b000 and must not be changed.

Status output enable. This field when set enables of the Status output

signals, HS_UP, HS_SUSPEND, SS_UP, SS_SUSPEND.

0 = STS outputs are disabled.

1 = STS outputs are enabled.

This bit may be loaded by EEPROM or over-written by a SMBUS host.

4

3:1

0

stsOutputEn

pwronTime

RW

Power On Delay Time. When the efuse_pwronTime field is all 0s, this

field sets the delay time from the removal disable of PWRCTL to the

enable of PWRCTL when transitioning battery charging modes. For

example, when disabling the power on a transition from ACP to DCP

Mode. The nominal timing is defined as follows:

TPWRON_EN = (pwronTime x 1) x 200 ms

(1)

This field may be over-written by EEPROM contents or by an SMBus

host.

USB3 Spread Spectrum Disable. This bit allows firmware to disable the

spread spectrum function of the USB3 phy PLL.

0 = Spread spectrum function is enabled

usb3spreadDis

1= Spread spectrum function is disabled

This bit may be loaded by EEPROM or over-written by a SMBUS host.

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8.5.25 SMBus Device Status and Command Register

Figure 26. Register Offset F8h

Bit No.

7

0

6

0

5

0

4

0

3

0

2

0

1

0

Reset State

Table 30. Bit Descriptions – SMBus Device Status and Command Register

Bit

Field

Type

Description

7:2

RSVD

RO

Reserved. Read only, returns 0 when read.

SMBus interface reset. This bit loads the registers back to their GRSTz

values. Note, that since this bit can only be set when in SMBus mode

the cfgActive bit is also reset to 1. When software sets this bit it must

reconfigure the registers as necessary.

This bit is set by writing a 1 and is cleared by hardware on completion

of the reset. A write of 0 has no effect.

1

smbusRst

cfgActive

RSU

RCU

Configuration active. This bit indicates that configuration of the

TUSB8043 is currently active. The bit is set by hardware when the

device enters the I2C or SMBus mode. The TUSB8043 shall not

connect on the upstream port while this bit is 1.

When in I2C mode, the bit is cleared by hardware when the TUSB8043

exits the I2C mode.

0

When in the SMBus mode, this bit must be cleared by the SMBus host

in order to exit the configuration mode and allow the upstream port to

connect.

The bit is cleared by a writing 1. A write of 0 has no effect.

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TUSB8043

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9 Applications and Implementation

NOTE

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

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

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

validate and test their design implementation to confirm system functionality.

9.1 Application Information

The TUSB8043 is a four-port USB 3.1 Gen1 compliant hub. It provides simultaneous SuperSpeed USB and high-

speed/full-speed connections on the upstream port and provides SuperSpeed USB, high-speed, full-speed, or

low speed connections on the downstream port. The TUSB8043 can be used in any application that needs

additional USB compliant ports. For example, a specific notebook may only have two downstream USB ports. By

using the TUSB8043, the notebook can increase the downstream port count to five.

9.2 Typical Application

9.2.1 Discrete USB Hub Product

A common application for the TUSB8043 is as a self powered standalone USB hub product. The product is

powered by an external 5V DC Power adapter. In this application, using a USB cable TUSB8043 upstream port

is plugged into a USB Host controller. The downstream ports of the TUSB8043 are exposed to users for

connecting USB hard drives, cameras, flash drives, and so forth.

USB

Type B

DC

PWR

Connector

US Port

TUSB8043

USB

PWR

USB

PWR

SWITCH

DS Port 1

DS Port 2 DS Port 3 DS Port 4

USB Type A

Connector

USB Type A

Connector

USB Type A

Connector

USB Type A

Connector

Figure 27. Discrete USB Hub Product

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ZHCSGC6A –JUNE 2017–REVISED AUGUST 2017

Typical Application (continued)

9.2.1.1 Design Requirements

Table 31. Design Parameters

DESIGN PARAMETER

VDD Supply

EXAMPLE VALUE

1.1 V

VDD33 Supply

3.3 V

Upstream Port USB Support (SS, HS, FS)

SS, HS, FS

Downstream Port 1 USB Support (SS, HS, FS, LS)

Downstream Port 2 USB Support (SS, HS, FS, LS)

Downstream Port 3 USB Support (SS, HS, FS, LS)

Downstream Port 4 USB Support (SS, HS, FS, LS)

Number of Removable external exposed Downstream Ports

Number of Non-Removable external exposed Downstream Ports

Full Power Management of Downstream Ports

Individual Control of Downstream Port Power Switch

Power Switch Enable Polarity

SS, HS, FS, LS

4

0

Yes. (FULLPWRMGMTZ = 0)

Yes. (GANGED = 0)

Active High. (PWRCTL_POL = 1)

Battery Charge Support for Downstream Port 1

Battery Charge Support for Downstream Port 2

Battery Charge Support for Downstream Port 3

Battery Charge Support for Downstream Port 4

I2C EEPROM Support

Yes

No

24MHz Clock Source

Crystal

9.2.1.2 Detailed Design Procedure

9.2.1.2.1 Upstream Port Implementation

The upstream of the TUSB8043 is connected to a USB3 Type B connector. This particular example has

GANGED pin and FULLPWRMGMTZ pin pulled low which results in individual power support each downstream

port. The VBUS signal from the USB3 Type B connector is feed through a voltage divider. The purpose of the

voltage divider is to make sure the level meets USB_VBUS input requirements

R1

90.9K

0402

1%

R2

C1

10uF

10K 1%

0402

1%

U1A

J1

48

42

40

USB_VBUS

GANGED/SMBA2/HS_UP

1

2

3

4

5

6

7

8

VBUS

DM

DP

USB_DM_UP

USB_DP_UP

54

53

USB_DM_UP

USB_DP_UP

FULLPWRMGMTZ/SMBA1/SS_UP

GND

CAP_UP_TXM

CAP_UP_TXP

USB_SSTXM_UP

56

55

C2

C3

0.1uF 0201

SSTXN

SSTXP

GND

SSRXN

SSRXP

SHIELD0

SHIELD1

USB_SSTXM_UP

USB_SSTXP_UP

R3

R4

USB_SSTXP_UP

USB_SSRXM_UP

USB_SSRXP_UP

4.7K

0402

5%

4.7K

0402

5%

59

58

USB_SSRXM_UP

USB_SSRXP_UP

9

10

11

TUSB8043

USB3_TYPEB_CONNECTOR

C4

0.1uF

C5

0.001uF

R5

1M

0402

5%

Figure 28. Upstream Port Implementation

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TUSB8043

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9.2.1.2.2 Downstream Port 1 Implementation

The downstream port 1 of the TUSB8043 is connected to a USB3 Type A connector. With BATEN1 pin pulled

up, Battery Charge support is enabled for Port 1. If Battery Charge support is not needed, then pull-up resistor on

BATEN1 should be uninstalled.

BOARD_3P3V

FB1

R6

POPULATE

DN1_VBUS

VBUS_DS1

4.7K

0402

5%

DN1_VBUS

FOR BC SUPPORT

220 at 100MHZ C6

0.1uF

J2

1

2

3

4

5

6

7

8

9

U1B

VBUS

DM

DP

2

1

USB_DM_DN1

USB_DP_DN1

USB_DM_DN1

USB_DP_DN1

GND

7

6

USB_SSRXM_DN1

USB_SSRXP_DN1

USB_SSRXM_DN1

USB_SSRXP_DN1

SSRXN

SSRXP

GND

SSTXN

SSTXP

0.1uF 0201

C7

C8

4

3

USB_SSTXM_DN1

USB_SSTXP_DN1

CAP_DN_TXM1

CAP_DN_TXP1

USB_SSTXM_DN1

USB_SSTXP_DN1

10

11

SHIELD0

SHIELD1

36

46

PWRCTRL1_BATEN1

OVERCUR1Z

PWRCTL1/BATEN1

OVERCUR1

USB3_TYPEA_CONNECTOR

R7

1M

C9

0.001uF

C10

0.1uF

TUSB8043

0402

5%

Figure 29. Downstream Port 1 Implementation

9.2.1.2.3 Downstream Port 2 Implementation

The downstream port 2 of the TUSB8043 is connected to a USB3 Type A connector. With BATEN2 pin pulled

up, Battery Charge support is enabled for Port 2. If Battery Charge support is not needed, then pull-up resistor on

BATEN2 should be uninstalled. For ferrite bead used on the VBUS connection, a lower resistance is

recommended due to noticeable IR drop during high current charging modes. The isolation between the Type-A

connectors shield ground and signal ground pins is not required. Some applications may have better ESD/EMI

performance when the grounds are shorted together.

BOARD_3P3V

FB2

DN2_VBUS

VBUS_DS2

R8

DN2_VBUS

POPULATE

4.7K

0402

5%

FOR BC SUPPORT

220 at 100MHZ

C11

0.1uF

J3

1

2

3

4

5

6

7

8

9

U1C

VBUS

DM

DP

10

USB_DM_DN2

USB_DP_DN2

USB_DM_DN2

9

USB_DP_DN2

GND

15

14

USB_SSRXM_DN2

USB_SSRXP_DN2

USB_SSRXM_DN2

USB_SSRXP_DN2

SSRXN

SSRXP

GND

SSTXN

SSTXP

12

11

USB_SSTXM_DN2

USB_SSTXP_DN2

CAP_DN2_TXM

CAP_DN2_TXP

C12

0.1uF 0201

USB_SSTXM_DN2

USB_SSTXP_DN2

C13

10

11

SHIELD0

SHIELD1

35

47

PWRCTRL2_BATEN2

OVERCUR2Z

PWRCTL2/BATEN2

OVERCUR2

R9

1M

C15

0.001uF

USB3_TYPEA_CONNECTOR

C14

0.1uF

0402

5%

TUSB8043

Figure 30. Downstream Port 2 Implementation

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TUSB8043

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ZHCSGC6A –JUNE 2017–REVISED AUGUST 2017

9.2.1.2.4 Downstream Port 3 Implementation

The downstream port3 of the TUSB8043 is connected to a USB3 Type A connector. With BATEN3 pin pulled up,

Battery Charge support is enabled for Port 3. If Battery Charge support is not needed, then pull-up resistor on

BATEN3 should be uninstalled. For ferrite bead used on the VBUS connection, a lower resistance is

recommended due to noticeable IR drop during high current charging modes. The isolation between the Type-A

connectors shield ground and signal ground pins is not required. Some applications may have better ESD/EMI

performance when the grounds are shorted together.

BOARD_3P3V

FB3

VBUS_DS3

R10

4.7K

0402

5%

DN3_VBUS

POPULATE

FOR BC SUPPORT

220 at 100MHZ

C16

0.1uF

J4

1

2

3

4

5

6

7

8

9

U1D

VBUS

DM

DP

18

USB_DM_DN3

USB_DP_DN3

USB_DM_DN3

17

USB_DP_DN3

GND

23

22

USB_SSRXM_DN3

USB_SSRXP_DN3

USB_SSRXM_DN3

USB_SSRXP_DN3

SSRXN

SSRXP

GND

SSTXN

SSTXP

20

19

USB_SSTXM_DN3

USB_SSTXP_DN3

CAP_DN3_TXM

CAP_DN3_TXP

C17

0.1uF 0201

USB_SSTXM_DN3

USB_SSTXP_DN3

C18

10

11

SHIELD0

SHIELD1

33

44

PWRCTRL3_BATEN3

OVERCUR3Z

PWRCTL3/BATEN3

OVERCUR3

R11

C19

0.001uF

USB3_TYPEA_CONNECTOR

C20

0.1uF

1M

0402

5%

TUSB8043

Figure 31. Downstream Port 3 Implementation

9.2.1.2.5 Downstream Port 4 Implementation

The downstream port 4 of the TUSB8043 is connected to a USB3 Type A connector. With BATEN4 pin pulled

up, Battery Charge support is enabled for Port 4. If Battery Charge support is not needed, then pull-up resistor on

BATEN4 should be uninstalled. For ferrite bead used on the VBUS connection, a lower resistance is

recommended due to noticeable IR drop during high current charging modes. The isolation between the Type-A

connectors shield ground and signal ground pins is not required. Some applications may have better ESD/EMI

performance when the grounds are shorted together.

BOARD_3P3V

FB4

VBUS_DS4

R12

4.7K

0402

5%

DN4_VBUS

POPULATE

FOR BC SUPPORT

220 at 100MHZ

C21

0.1uF

J5

1

2

3

4

5

6

7

8

9

U1E

VBUS

DM

DP

25

USB_DM_DN4

USB_DP_DN4

USB_DM_DN4

24

USB_DP_DN4

GND

30

29

USB_SSRXM_DN4

USB_SSRXP_DN4

USB_SSRXM_DN4

USB_SSRXP_DN4

SSRXN

SSRXP

GND

SSTXN

SSTXP

27

26

USB_SSTXM_DN4

USB_SSTXP_DN4

CAP_DN4_TXM

CAP_DN4_TXP

C22

0.1uF 0201

USB_SSTXM_DN4

USB_SSTXP_DN4

C23

10

11

SHIELD0

SHIELD1

32

43

PWRCTRL4_BATEN4

OVERCUR4Z

PWRCTL4/BATEN4

OVERCUR4

R13

C25

0.001uF

USB3_TYPEA_CONNECTOR

C24

0.1uF

1M

0402

5%

TUSB8043

Figure 32. Downstream Port 4 Implementation

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9.2.1.2.6 VBUS Power Switch Implementation

This particular example uses the Texas Instruments TPS2561 Dual Channel Precision Adjustable Current-

Limited power switch. For details on this power switch or other power switches available from Texas Instruments,

refer to the Texas Instruments website.

BOARD_3P3V

BOARD_5V

R19

10K

0402

5%

R20

10K

0402

5%

C42

0.1uF

U2

2

3

9

DN1_VBUS

DN2_VBUS

ILIM1

DN1_VBUS

OVERCUR1Z

DN2_VBUS

OVERCUR2Z

IN

OUT1

FAULT1Z

OUT2

10

8

PWRCTRL1_BATEN1

PWRCTRL2_BATEN2

4

5

PWRCTRL1_BATEN1

PWRCTRL2_BATEN2

EN1

EN2

6

FAULT2Z

ILIM

1

11

GND

PAD

7

C43

C45

0.1uF

+

C44

150uF

0.1uF

+

C46

150uF

TPS2561

R21

25.5K

0402

5%

Limiting DS Port VBUS current to 2.2A per port.

BOARD_3P3V

BOARD_5V

R22

10K

0402

5%

R23

10K

0402

5%

C47

0.1uF

U3

2

9

DN3_VBUS

DN4_VBUS

ILIM2

DN3_VBUS

IN

OUT1

FAULT1Z

OUT2

3

4

5

10

8

OVERCUR3Z

DN4_VBUS

PWRCTRL3_BATEN3

EN1

EN2

PWRCTRL4_BATEN4

6

OVERCUR4Z

FAULT2Z

ILIM

1

11

GND

PAD

7

C48

0.1uF

C50

+

C49

150uF

0.1uF

+

C51

150uF

TPS2561

R24

25.5K

0402

5%

Limiting DS Port VBUS current to 2.2A per port.

Figure 33. VBUS Power Switch Implementation

9.2.1.2.7 Clock, Reset, and Misc

The PWRCTL_POL is left unconnected which results in active high power enable (PWRCTL1, PWRCTL2,

PWRCTL3, and PWRCTL4) for a USB VBUS power switch. SMBUSz pin is also left unconnected which will

select I2C mode. Both PWRCTL_POL and SMBUSz pins have internal pull-ups. The 1 µF capacitor on the

GRSTN pin can only be used if the VDD11 supply is stable before the VDD33 supply. The depending on the

supply ramp of the two supplies the capacitor size may have to be adjusted.

42

TUSB8043

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ZHCSGC6A –JUNE 2017–REVISED AUGUST 2017

U1F

C39

1uF

50

38

37

GRSTN

SCL/SMBCLK

SDA/SMBDAT

39

45

SMBUSZ/SS_SUSPEND

AUTOENZ/HS_SUSPEND

PWRCTL_POL

TEST

62

61

XI

41

49

64

R14

1M

XO

Y1

USB_R1

R15

TUSB8043

R16

4.7K

R18

4.7K

0402

5%

9.53K

0402

1%

24MHz

C40

C41

18pF

Figure 34. Clock, Reset, and Misc

43

TUSB8043

ZHCSGC6A –JUNE 2017–REVISED AUGUST 2017

www.ti.com.cn

9.2.1.2.8 TUSB8043 Power Implementation

BOARD_1P1V

VDD11

FB5

C26

0.1uF

C27

C28

C29

C30

C31

C32

C33

10uF

220 at 100MHZ

0.1uF

U1G

16

VDD33

34

VDD33

60

52

63

VDD33

BOARD_3P3V

NC

FB6

C34

C35

0.1uF

C36

0.1uF

C37

0.1uF

C38

10uF

220 at 100MHZ

0.1uF

TUSB8043

Figure 35. TUSB8043 Power Implementation

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ZHCSGC6A –JUNE 2017–REVISED AUGUST 2017

9.2.1.3 Application Curves

Figure 36. Upstream Port

Figure 37. Downstream Port 1

Figure 38. Downstream Port 2

Figure 39. Downstream Port 3

Figure 40. Downstream Port 4

Figure 41. High-Speed Upstream Port

45

TUSB8043

ZHCSGC6A –JUNE 2017–REVISED AUGUST 2017

www.ti.com.cn

Figure 42. High-Speed Downstream Port 1

Figure 43. High-Speed Downstream Port 2

Figure 44. High-Speed Downstream Port 3

Figure 45. High-Speed Downstream Port 4

46

TUSB8043

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ZHCSGC6A –JUNE 2017–REVISED AUGUST 2017

10 Power Supply Recommendations

10.1 TUSB8043 Power Supply

V_DDshould be implemented as a single power plane, as should V_DD33

.

•

The V_DDpins of the TUSB8043 supply 1.1 V (nominal) power to the core of the TUSB8043. This power rail

can be isolated from all other power rails by a ferrite bead to reduce noise.

•

The DC resistance of the ferrite bead on the core power rail can affect the voltage provided to the device due

to the high current draw on the power rail. The output of the core voltage regulator may need to be adjusted

to account for this or a ferrite bead with low DC resistance (less than 0.05 Ω) can be selected.

•

The V_DD33pins of the TUSB8043 supply 3.3 V power rail to the I/O of the TUSB8043. This power rail can be

isolated from all other power rails by a ferrite bead to reduce noise.

All power rails require a 10 µF capacitor or 1 µF capacitors for stability and noise immunity. These bulk

capacitors can be placed anywhere on the power rail. The smaller decoupling capacitors should be placed as

close to the TUSB8043 power pins as possible with an optimal grouping of two of differing values per pin.

10.2 Downstream Port Power

•

The downstream port power, VBUS, must be supplied by a source capable of supplying 5V and up to 900 mA

per port. Downstream port power switches can be controlled by the TUSB8043 signals. It is also possible to

leave the downstream port power always enabled.

•

A large bulk low-ESR capacitor of 22 µF or larger is required on each downstream port’s VBUS to limit in-rush

current.

The ferrite beads on the VBUS pins of the downstream USB port connections are recommended for both

ESD and EMI reasons. A 0.1µF capacitor on the USB connector side of the ferrite provides a low impedance

path to ground for fast rise time ESD current that might have coupled onto the VBUS trace from the cable.

10.3 Ground

It is recommended that only one board ground plane be used in the design. This provides the best image plane

for signal traces running above the plane. The thermal pad of the TUSB8043 and any of the voltage regulators

should be connected to this plane with vias. An earth or chassis ground is implemented only near the USB port

connectors on a different plane for EMI and ESD purposes.

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11 Layout

11.1 Layout Guidelines

11.1.1 Placement

1. 9.53K +/-1% resistor connected to pin USB_R1 should be placed as close as possible to the TUSB8043.

2. A 0.1 µF should be placed as close as possible on each VDD and VDD33 power pin.

3. The 100 nF capacitors on the SSTXP and SSTXM nets should be placed close to the USB connector (Type

A, Type B, and so forth).

4. The ESD and EMI protection devices (if used) should also be placed as close as possible to the USB

connector.

5. If a crystal is used, it must be placed as close as possible to the TUSB8043 XI and XO pins.

6. Place voltage regulators as far away as possible from the TUSB8043, the crystal, and the differential pairs.

7. In general, the large bulk capacitors associated with each power rail should be placed as close as possible to

the voltage regulators.

11.1.2 Package Specific

1. The TUSB8043 package has a 0.5-mm pin pitch.

2. The TUSB8043 package has a 6.0-mm x 6.0-mm thermal pad. This thermal pad must be connected to

ground through a system of vias.

3. All vias under device, except for those connected to thermal pad, should be solder masked to avoid any

potential issues with thermal pad layouts.

11.1.3 Differential Pairs

This section describes the layout recommendations for all the TUSB8043 differential pairs: USB_DP_XX,

USB_DM_XX, USB_SSTXP_XX, USB_SSTXM_XX, USB_SSRXP_XX, and USB_SSRXM_XX.

1. Must be designed with a differential impedance of 90 Ω ±10%.

2. In order to minimize cross talk, it is recommended to keep high speed signals away from each other. Each

pair should be separated by at least 5 times the signal trace width. Separating with ground as depicted in the

layout example will also help minimize cross talk.

3. Route all differential pairs on the same layer adjacent to a solid ground plane.

4. Do not route differential pairs over any plane split.

5. Adding test points will cause impedance discontinuity and will therefore negative impact signal performance.

If test points are used, they should be placed in series and symmetrically. They must not be placed in a

manner that causes stub on the differential pair.

6. Avoid 90 degree turns in trace. The use of bends in differential traces should be kept to a minimum. When

bends are used, the number of left and right bends should be as equal as possible and the angle of the bend

should be ≥ 135 degrees. This will minimize any length mismatch causes by the bends and therefore

minimize the impact bends have on EMI.

7. Minimize the trace lengths of the differential pair traces. The maximum recommended trace length for SS

differential pair signals and USB 2.0 differential pair signals is eight inches. Longer trace lengths require very

careful routing to assure proper signal integrity.

8. Match the etch lengths of the differential pair traces (i.e. DP and DM or SSRXP and SSRXM or SSTXP and

SSTXM). There should be less than 5 mils difference between a SS differential pair signal and its

complement. The USB 2.0 differential pairs should not exceed 50 mils relative trace length difference.

9. The etch lengths of the differential pair groups do not need to match (i.e. the length of the SSRX pair to that

of the SSTX pair), but all trace lengths should be minimized.

10. Minimize the use of vias in the differential pair paths as much as possible. If this is not practical, make sure

that the same via type and placement are used for both signals in a pair. Any vias used should be placed as

close as possible to the TUSB8043 device.

11. To ease routing, the polarity of the SS differential pairs can be swapped. This means that SSTXP can be

routed to SSTXM or SSRXM can be routed to SSRXP.

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ZHCSGC6A –JUNE 2017–REVISED AUGUST 2017

Layout Guidelines (continued)

12. To ease routing of the USB2 DP and DM pair, the polarity of these pins can be swapped. If this is done, the

appropriate Px_usb2pol register, where x = 0, 1, 2, 3, or 4, must be set.

13. Do not place power fuses across the differential pair traces.

11.2 Layout Examples

11.2.1 Upstream Port

Figure 46. Example Routing of Upstream Port

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www.ti.com.cn

Layout Examples (continued)

11.2.2 Downstream Port

Figure 47. Example Routing of Downstream Port

The remaining three downstream ports routing can be similar to the example provided.

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TUSB8043

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ZHCSGC6A –JUNE 2017–REVISED AUGUST 2017

12 器件和文档支持

12.1 接收文档更新通知

要接收文档更新通知，请导航至德州仪器 TI.com.cn 上的器件产品文件夹。请单击右上角的通知我进行注册，即可

收到任意产品信息更改每周摘要。有关更改的详细信息，请查看任意已修订文档中包含的修订历史记录。

12.2 社区资源

下列链接提供到 TI 社区资源的连接。链接的内容由各个分销商“按照原样”提供。这些内容并不构成 TI 技术规范，

并且不一定反映 TI 的观点；请参阅 TI 的《使用条款》。

TI E2E™ 在线社区 TI 的工程师对工程师 (E2E) 社区。此社区的创建目的在于促进工程师之间的协作。在

e2e.ti.com 中，您可以咨询问题、分享知识、拓展思路并与同行工程师一道帮助解决问题。

设计支持

TI 参考设计支持可帮助您快速查找有帮助的 E2E 论坛、设计支持工具以及技术支持的联系信息。

12.3 商标

E2E is a trademark of Texas Instruments.

All other trademarks are the property of their respective owners.

12.4 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。

12.5 Glossary

SLYZ022 — TI Glossary.

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

51

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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、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，请参阅左侧的导航栏。

52

TUSB8043

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ZHCSGC6A –JUNE 2017–REVISED AUGUST 2017

PACKAGE OUTLINE

RGC0064G

VQFN - 1 mm max height

S

C

A

L

E

1

.

5

0

PLASTIC QUAD FLATPACK - NO LEAD

9.1

8.9

B

A

PIN 1 INDEX AREA

9.1

8.9

(0.1) TYP

LEADFRAME PROFILE

OPTION

S

C

A

L

E

8

.

0

1 MAX

C

SEATING PLANE

0.08

0.05

0.00

2X 7.5

(0.2) TYP

6

0.05

17

32

60X 0.5

16

33

SEE DETAIL

2X

EXPOSED

THERMAL PAD

7.5

1

48

0.30

64X

64

49

PIN 1 ID

(OPTIONAL)

0.18

0.5

0.3

0.1

C A

B

64X

0.05

4222053/B 06/2015

NOTES:

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

per ASME Y14.5M.

2. This drawing is subject to change without notice.

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

www.ti.com

53

TUSB8043

ZHCSGC6A –JUNE 2017–REVISED AUGUST 2017

www.ti.com.cn

EXAMPLE BOARD LAYOUT

RGC0064G

VQFN - 1 mm max height

PLASTIC QUAD FLATPACK - NO LEAD

(

6)

SYMM

64

49

64X (0.6)

1

48

64X (0.24)

8X (1.01)

60X (0.5)

SYMM

18X (1.16)

(8.8)

(0.58)

TYP

(

0.2) TYP

VIA

(0.58) TYP

33

16

17

32

18X (1.16)

(8.8)

8X (1.01)

(R0.05)

ALL PAD CORNERS

LAND PATTERN EXAMPLE

SCALE:10X

0.07 MIN

ALL SIDES

0.07 MAX

ALL AROUND

SOLDER MASK

OPENING

METAL

SOLDER MASK

OPENING

METAL UNDER

SOLDER MASK

NON SOLDER MASK

DEFINED

(PREFERRED)

SOLDER MASK

DEFINED

SOLDER MASK DETAILS

4222053/B 06/2015

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).

www.ti.com

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TUSB8043

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ZHCSGC6A –JUNE 2017–REVISED AUGUST 2017

EXAMPLE STENCIL DESIGN

RGC0064G

VQFN - 1 mm max height

PLASTIC QUAD FLATPACK - NO LEAD

25X ( 0.96)

64

(1.16) TYP

(R0.05) TYP

49

64X (0.6)

1

48

64X (0.24)

60X (0.5)

(1.16)

TYP

SYMM

(8.8)

(R0.05) TYP

33

16

METAL

TYP

17

32

SYMM

(8.8)

SOLDER PASTE EXAMPLE

BASED ON 0.125 mm THICK STENCIL

EXPOSED PAD

64% PRINTED SOLDER COVERAGE BY AREA

SCALE:12X

4222053/B 06/2015

NOTES: (continued)

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

design recommendations.

www.ti.com

55

PACKAGE MATERIALS INFORMATION

www.ti.com

13-Sep-2017

TAPE AND REEL INFORMATION

*All dimensions are nominal

Device

Package Package Pins

Type Drawing

SPQ

Reel

A0

B0

K0

P1

W

Pin1

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

(mm) W1 (mm)

TUSB8043RGCR

TUSB8043RGCT

VQFN

RGC

64

2000

250

330.0

180.0

16.4

9.3

1.1

12.0

16.0

Q2

Pack Materials-Page 1

PACKAGE MATERIALS INFORMATION

www.ti.com

13-Sep-2017

*All dimensions are nominal

Device

Package Type Package Drawing Pins

SPQ

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

TUSB8043RGCR

TUSB8043RGCT

VQFN

RGC

64

2000

250

367.0

210.0

367.0

185.0

38.0

35.0

Pack Materials-Page 2

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

源，不保证其中不含任何瑕疵，且不做任何明示或暗示的担保，包括但不限于对适销性、适合某特定用途或不侵犯任何第三方知识产权的暗示

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验证并测试您的应用；(3) 确保您的应用满足相应标准以及任何其他安全、安保或其他要求。所述资源如有变更，恕不另行通知。TI 对您使用

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型号：	TUSB8043RGCT
厂家：	TEXAS INSTRUMENTS
描述：	具有 HID/I2C 转换功能的 4 端口 SuperSpeed 5.0Gbps USB 3.1 集线器 \| RGC \| 64 \| 0 to 70
文件：	总60页 (文件大小：2507K)
中文：	中文翻译
下载：	下载PDF数据表文档文件

TUSB8043RGCT [TI]

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