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TUSB8020B-Q1
SLLSEF7 – MARCH 2014
TUSB8020B-Q1 Automotive Two-Port USB 3.0 Hub
1 Features
3 Description
•
•
The TUSB8020B-Q1 is a two-port USB 3.0 compliant
hub. It provides simultaneous SuperSpeed USB and
high-speed/full-speed connections on the upstream
port and provides SuperSpeed USB, high-speed, fullspeed, 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 fullspeed/low-speed connections, SuperSpeed USB and
high-speed connectivity are disabled on the
downstream ports.
1
•
•
•
•
•
•
•
•
•
•
Two Port USB 3.0 Compliant Hub
USB 2.0 Hub Features
– Multi Transaction Translator (MTT) Hub: Two
Transaction Translators
– Four Asynchronous Endpoint Buffers Per
Transaction Translator
Supports USB Battery Charging Specification
Revision 1.2
– CDP Mode (Upstream Port Connected)
– DCP Mode (Upstream Port Unconnected)
– DCP Mode Complies with Chinese
Telecommunications Industry Standard YD/T
1591-2009
Support D+/D- Divider Mode.
Supports Operation as a USB 3.0 or USB 2.0
Compound Device
Per Port or Ganged Power Switching and OverCurrent Notification Inputs
OTP ROM, Serial EEPROM or I2C/SMBus Slave
Interface for Custom Configurations:
– VID and PID
– Port Customizations
– Manufacturer and Product Strings (not by OTP
ROM)
– Serial Number (not by OTP ROM)
Application Feature Selection Using Terminal
Selection or EEPROM/ or I2C/SMBus Slave
Interface
Provides 128-Bit Universally Unique Identifier
(UUID)
Supports On-Board and In-System OTP/EEPROM
Programming Via the USB 2.0 Upstream Port
Single Clock Input, 24-MHz Crystal or Oscillator
No special driver requirements; works seamlessly
on any operating system with USB stack support
2 Applications
•
•
•
•
•
The TUSB8020B-Q1 supports per port or ganged
power switching and over-current protection, and
supports battery charging applications.
An individually port power controlled hub switches
power on or off to each downstream port as
requested by the USB host. Also when an individually
port power controlled hub senses an over-current
event, only power to the affected downstream port
will be switched off.
A ganged hub switches on power to all its
downstream ports when power is required to be on
for any port. The power to the downstream ports is
not switched off unless all ports are in a state that
allows power to be removed. Also when a ganged
hub senses an over-current event, power to all
downstream ports will be switched off.
Device Information
ORDER NUMBER
PACKAGE
TUSB8020BIPHPRQ1
TUSB8020BIPHPQ1
Embedded
Host
BODY SIZE
HTQFP (48)
7mm × 7mm
TUSB8020B-Q1
Automotive
Computer Systems
Docking Stations
Monitors
Set-Top Boxes
Console
Convenience Port
Console
Convenience Port
USB 2.0 Connection
USB 3.0 Hub
USB 3.0 Connection
USB 3.0 Port
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.
TUSB8020B-Q1
SLLSEF7 – MARCH 2014
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Table of Contents
1
2
3
4
5
6
7
Features ..................................................................
Applications ...........................................................
Description .............................................................
Revision History.....................................................
Description (Continued) ........................................
Terminal Configuration and Functions................
Specifications.........................................................
7.1
7.2
7.3
7.4
7.5
7.6
7.7
8
8.4 Device Functional Modes........................................ 14
8.5 Register Maps ......................................................... 15
1
1
1
2
3
4
8
9
Applications and Implementation ...................... 27
9.1 Application Information............................................ 27
9.2 Typical Applications ................................................ 27
10 Power Supply Recommendations ..................... 33
10.1 Power Supply ........................................................ 33
10.2 Downstream Port Power ....................................... 33
10.3 Ground .................................................................. 33
Absolute Maximum Ratings .................................... 8
Handling Ratings....................................................... 8
Recommended Operating Conditions...................... 8
Thermal Information .................................................. 8
3.3-V I/O Electrical Characteristics ........................... 9
Power-Up Timing Requirements............................... 9
Hub Input Supply Current ....................................... 10
11 Layout................................................................... 34
11.1 Layout Guidelines ................................................. 34
11.2 Layout Example .................................................... 35
12 Device and Documentation Support ................. 37
12.1 Trademarks ........................................................... 37
12.2 Electrostatic Discharge Caution ............................ 37
12.3 Glossary ................................................................ 37
Detailed Description ............................................ 11
8.1 Overview ................................................................. 11
8.2 Functional Block Diagram ....................................... 11
8.3 Feature Description................................................. 11
13 Mechanical, Packaging, and Orderable
Information ........................................................... 37
4 Revision History
2
Date
Revision
Notes
March 2014
*
Initial release.
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5 Description (Continued)
The TUSB8020B-Q1 downstream ports provide support for battery charging applications by providing USB
Battery Charging 1.2 Charging Downstream Port (CDP) handshaking support. It also supports a Dedicated
Charging Port (DCP) mode when the upstream port is not connected. The DCP mode supports the USB Battery
Charging Specification and the Chinese Telecommunications Industry Standard YD/T 1591-2009. In addition, an
automatic mode provides transparent support for BC 1.2 compliant devices and devices supporting Divider Mode
charging solutions when the upstream port unconnected.
The TUSB8020B-Q1 provides terminal strap configuration for some features including battery charging support,
and also provides customization though OTP ROM, I2C EEPROM or via an I2C/SMBus slave interface for PID,
VID, and custom port and phy configurations. Custom string support is also available when using an I2C
EEPROM or the I2C/SMBus slave interface.
The device is available in a 48-terminal HTQFP package and is designed for operation over the industrial
temperature range of -40°C to 85°C.
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6 Terminal Configuration and Functions
FULLPWRMGMTz / SMBA1 / SS_UP
GANGED / SMBA2 / HS_UP
VDD
VDD33
USB_SSRXP_UP
USB_SSRXM_UP
VDD
USB_SSTXP_UP
USB_SSTXM_UP
USB_DM_UP
USB_DP_UP
VDD33
PHP Package
(Top View)
36
35
34
33
32
31
30
29
28
27
26
25
VDD33
37
24
USB_R1
XI
38
23
VDD33
XO
39
22
SMBUSz / SS_DN2
VDD33
40
21
PWRCTL_POL / SS_DN1
USB_DP_DN1
41
20
USB_SSRXM_DN2
USB_DM_DN1
42
19
USB_SSRXP_DN2
Thermal Pad
4
USB_SSRXP_DN1
46
15
USB_DM_DN2
USB_SSRXM_DN1
47
14
USB_DP_DN2
VDD33
48
13
VDD33
1
2
3
4
5
6
7
8
9
10
11
12
VDD
USB_SSTXP_DN2
GRSTZ
16
TEST
45
USB_VBUS
VDD
OVERCUR2z
USB_SSTXM_DN2
VDD33
17
PWRCTL2 / BATEN2
44
OVERCUR1z
USB_SSTXM_DN1
PWRCTL1 / BATEN1
VDD
SDA / SMBDAT
18
SCL / SMBCLK
43
VDD
USB_SSTXP_DN1
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Terminal Functions
TERMINAL
NAME
TERMINAL
NO.
TYPE (1)
DESCRIPTION
Clock and Reset Signals
GRSTz
11
I
PU
Global power reset. This reset brings all of the TUSB8020B-Q1 internal registers to their default states.
When GRSTz is asserted, the device is completely nonfunctional.
XI
38
I
Crystal input. This terminal 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.
XO
39
O
Crystal output. This terminal 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.
USB_SSTXP_UP
29
O
USB SuperSpeed transmitter differential pair (positive)
USB_SSTXM_UP
28
O
USB SuperSpeed transmitter differential pair (negative)
USB_SSRXP_UP
32
I
USB SuperSpeed receiver differential pair (positive)
USB_SSRXM_UP
31
I
USB SuperSpeed receiver differential pair (negative)
USB_DP_UP
26
I/O
USB High-speed differential transceiver (positive)
USB_DM_UP
27
I/O
USB High-speed differential transceiver (negative)
USB_R1
24
I
Precision resistor reference. A 9.53-kΩ ±1% resistor should be connected between USB_R1 and GND.
USB_VBUS
9
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_SSTXP_DN1
43
O
USB SuperSpeed transmitter differential pair (positive) Downstream Port 1.
USB_SSTXM_DN1
44
O
USB SuperSpeed transmitter differential pair (negative) Downstream Port 1.
USB_SSRXP_DN1
46
I
USB SuperSpeed receiver differential pair (positive) Downstream Port 1.
USB_SSRXM_DN1
47
I
USB SuperSpeed receiver differential pair (negative) Downstream Port 1.
USB_DP_DN1
41
I/O
USB High-speed differential transceiver (positive) Downstream Port 1.
USB_DM_DN1
42
I/O
USB High-speed differential transceiver (negative) Downstream Port 1.
USB Upstream Signals
USB Downstream Signals
USB Port 1 Power On Control for Downstream Power/Battery Charging Enable. The terminal is used for
control of the downstream power switch for Port 1.
PWRCTL1/BATEN1
4
I/O, PD
In addition, the value of the terminal 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.
0 = Battery charging not supported
1 = Battery charging supported
USB DS Port 1 Over-Current Detection input. This terminal is used to connect the over current output of
the downstream port power switch for Port 1.
0 = An over current event has occurred
OVERCUR1z
5
I, PU
1 = An over current event has not occurred
If power management is enabled, the external circuitry needed should be determined by the power
switch. In ganged mode either OVERCUR1z or OVERCUR2z can be used. In ganged mode the
overcurrent will be reported as a hub event instead of a port event.
USB_SSTXP_DN2
16
O
USB SuperSpeed transmitter differential pair (positive) Downstream Port 2.
USB_SSTXM_DN2
17
O
USB SuperSpeed transmitter differential pair (negative) Downstream Port 2.
USB_SSRXP_DN2
19
I
USB SuperSpeed receiver differential pair (positive) Downstream Port 2.
USB_SSRXM_DN2
20
I
USB SuperSpeed receiver differential pair (negative) Downstream Port 2.
USB_DP_DN2
14
I/O
USB High-speed differential transceiver (positive) Downstream Port 2.
USB_DM_DN2
15
I/O
USB High-speed differential transceiver (negative) Downstream Port 2.
Power On Control /Battery Charging Enable for Downstream Port 2. This terminal is used for control of
the downstream power switch for Port 2.
PWRCTL2/BATEN2
6
I/O, PD
In addition, the value of the terminal 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.
0 = Battery charging not supported
1 = Battery charging supported
(1)
I = input, O = output, I/O = input/output, PU = internal pullup resistor, PD = internal pulldown resistor, and PWR = power signal
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Terminal Functions (continued)
TERMINAL
NAME
TERMINAL
NO.
TYPE (1)
DESCRIPTION
Over-Current Detection for Downstream Port 2. This terminal is used to connect the over current output
of the downstream port power switch for Port 2.
0 = An over current event has occurred
OVERCUR2z
8
I, PU
1 = An over current event has not occurred
If power management is enabled, the external circuitry needed should be determined by the power
switch. In ganged mode either OVERCUR1z or OVERCUR2z can be used. In ganged mode the
overcurrent will be reported as a hub event instead of a port event.
I2C/SMBUS Signals
I2C clock/SMBus clock. Function of terminal depends on the setting of the SMBUSz input.
When SMBUSz = 1, this terminal acts as the serial clock interface for an I2C EEPROM.
SCL/SMBCLK
2
I/O, PD
When SMBUSz = 0, this terminal acts as the serial clock interface for an SMBus host.
This pin must be pulled up to use the OTP ROM.
Can be left unconnected if external interface not implemented.
I2C data/SMBus data. Function of terminal depends on the setting of the SMBUSz input.
When SMBUSz = 1, this terminal acts as the serial data interface for an I2C EEPROM.
SDA/SMBDAT
3
I/O, PD
When SMBUSz = 0, this terminal acts as the serial data interface for an SMBus host.
This pin must be pulled up to use the OTP ROM.
Can be left unconnected if external interface not implemented.
Test and Miscellaneous Signals
SMBUS mode / SuperSpeed USB Status for Downstream Port 2
The value of the terminal is sampled at the de-assertion of reset to enable I2C or SMBus mode.
SMBUSz/SS_DN2
22
I, PU
0 = SMBus Mode Selected
1 = I2C mode selected
After reset, this signal indicates the SuperSpeed USB connection status of downstream port 2. A value
of 1 indicates the connection is SuperSpeed USB.
Power Control Polarity / SuperSpeed USB Status for Downstream Port 1.
The value of the terminal is sampled at the de-assertion of reset to set the polarity of PWRCTL[2:1].
PWRCTL_POL/SS_DN1
21
I/O, PD
0 = PWRCTL polarity is active high.
1 = PWRCTL polarity is active loiw.
After reset, this signal indicates the SuperSpeed USB connection status of downstream port 1. A value
of 1 indicates the connection is SuperSpeed USB.
Ganged operation enable/SMBus Address bit 2/ High-Speed Status for Upstream Port
The value of the terminal is sampled at the de-assertion of reset to set the power switch and over current
detection mode as follows:
GANGED/SMBA2/
HS_UP
0 = Individual power control supported when power switching is enabled.
35
I, PU
1 = Power control gangs supported when power switching is enabled.
When SMBus mode is enabled using SMBUSz, this terminal sets the value of the SMBus slave address
bit 2. SMBus slave address bits 2 and 3 are always 1 for the TUSB8020B-Q1.
After reset, this signal indicates the High-speed USB connection status of the upstream port. A value of
1 indicates the upstream port is connected to a High-speed USB capable port.
Full power management enable/ SMBus Address bit 1/ Super-Speed USB Status for Upstream port
The value of the terminal is sampled at the de-assertion of reset to set the power switch control follows:
0 = Power switching supported
1 = Power switching not supported
FULLPWRMGMTz/
SMBA1/SS_UP
36
I, PU
Full power management is the ability to control power to the downstream ports of the TUSB8020B-Q1
using PWRCTL[2:1]/BATEN[2:1].
When SMBus mode is enabled using SMBUSz, this terminal sets the value of the SMBus slave address
bit 1. SMBus slave address bit 3 is always 1 for the TUSB8020B-Q1.
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. A value of
1 indicates the upstream port is connected to a SuperSpeed USB capable port.
TEST
6
10
I, PD
TEST mode enable. When this terminal is asserted high at reset enables test mode. This terminal is
reserved for factory use. It is recommended to pull-down this terminal to ground.
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Terminal Functions (continued)
TERMINAL
NAME
TERMINAL
NO.
TYPE (1)
DESCRIPTION
Power and Ground Signals
VDD
1, 12, 18, 30,
34, 45
PWR
1.1-V power rail
VDD33
7, 13, 23, 25,
33, 37, 40, 48
PWR
3.3-V power rail
PAD
-
GND
Ground
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7 Specifications
7.1
Absolute Maximum Ratings
over operating free-air temperature range (unless otherwise noted)
VALUE
UNIT
VDD
Steady-state supply voltage
–0.3 to 1.4
V
VDD33
Steady-state supply voltage
–0.3 to 3.8
V
7.2 Handling Ratings
MIN
Tstg
Storage temperature range
MAX
–65
Human-Body Model (HBM) AEC-Q100 Classification Level H2
VESD
7.3
UNIT
150
°C
2000
Charged-Device Model (CDM) AEQ-Q100 Classification Level C4B for
corner pins
750
Charged-Device Model (CDM) AEQ-Q100 Classification Level C4B for
non-corner pins
500
V
Recommended Operating Conditions
over operating free-air temperature range (unless otherwise noted)
MIN
NOM
MAX
UNIT
VDD (1)
1.1 supply voltage
0.99
1.1
1.26
V
VDD33
3.3 supply voltage
3
3.3
3.6
V
USB_VBUS
Voltage at USB_VBUS PAD
0
TA
Operating free-air temperature range
-40
TJ
Operating junction temperature range
-40
(1)
1.155
V
25
85
°C
25
105
°C
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
TUSB8020B-Q1
THERMAL METRIC (1)
PHP
UNIT
48 PIN
RθJA
Junction-to-ambient thermal resistance (2)
31.8
RθJCtop
Junction-to-case (top) thermal resistance (3)
16.1
RθJB
Junction-to-board thermal resistance (4)
13
ψJT
Junction-to-top characterization parameter (5)
0.5
ψJB
Junction-to-board characterization parameter (6)
12.9
RθJCbot
Junction-to-case (bottom) thermal resistance (7)
0.9
(1)
(2)
(3)
(4)
(5)
(6)
(7)
8
°C/W
For more information about traditional and new thermal metrics, see the IC Package Thermal Metrics application report, SPRA953.
The junction-to-ambient thermal resistance under natural convection is obtained in a simulation on a JEDEC-standard, high-K board, as
specified in JESD51-7, in an environment described in JESD51-2a.
The junction-to-case (top) thermal resistance is obtained by simulating a cold plate test on the package top. No specific JEDECstandard test exists, but a close description can be found in the ANSI SEMI standard G30-88.
The junction-to-board thermal resistance is obtained by simulating in an environment with a ring cold plate fixture to control the PCB
temperature, as described in JESD51-8.
The junction-to-top characterization parameter, ψJT, estimates the junction temperature of a device in a real system and is extracted
from the simulation data for obtaining θJA, using a procedure described in JESD51-2a (sections 6 and 7).
The junction-to-board characterization parameter, ψJB, estimates the junction temperature of a device in a real system and is extracted
from the simulation data for obtaining θJA , using a procedure described in JESD51-2a (sections 6 and 7).
The junction-to-case (bottom) thermal resistance is obtained by simulating a cold plate test on the exposed (power) pad. No specific
JEDEC standard test exists, but a close description can be found in the ANSI SEMI standard G30-88.
Spacer
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7.5 3.3-V I/O Electrical Characteristics
over operating free-air temperature range (unless otherwise noted)
PARAMETER
OPERATION
MIN
MAX
VDD33
2
VDD33
V
VDD33
0
0.8
V
Input voltage
0
VDD33
V
VO
Output voltage (2)
0
VDD33
V
tt
Input transition time (trise and tfall)
0
25
ns
Vhys
Input hysteresis (3)
0.13 x VDD33
V
VOH
High-level output voltage
VDD33
IOH = -4 mA
VOL
Low-level output voltage
VDD33
IOL = 4 mA
0.4
V
IOZ
High-impedance, output current (2)
VDD33
VI = 0 to VDD33
±20
µA
IOZP
High-impedance, output current
with internal pullup or pulldown
resistor (4)
VDD33
VI = 0 to VDD33
±225
µA
II
Input current (5)
VDD33
VI = 0 to VDD33
±15
µA
VIH
High-level input voltage
(1)
VIL
Low-level input voltage (1)
VI
(1)
(2)
(3)
(4)
(5)
TEST CONDITIONS
UNIT
2.4
V
Applies to external inputs and bidirectional buffers.
Applies to external outputs and bidirectional buffers.
Applies to GRSTz.
Applies to pins with internal pullups/pulldowns.
Applies to external input buffers.
7.6 Power-Up Timing Requirements
MIN
Td1
VDD33 stable before VDD stable. There is no timing relationship
between VDD33 and VDD
Td2
VDD and VDD33 stable before de-assertion of GRSTZ.
Tsu_io
Setup for MISC inputs sampled at the de-assertion of GRSTZ (1)
(1)
TYP
MAX
UNIT
0
ms
3
ms
0.1
µs
Thd_io
Hold for MISC inputs sampled at the de-assertion of GRSTZ.
TVDD33_RAMP
VDD33 supply ramp requirements
0.2
100
ms
TVDD_RAMP
VDD supply ramp requirements
0.2
100
ms
(1)
0.1
µs
Misc pins sampled at de-assertion of GRSTZ: FULLPWRMGMTz, GANGED, PWRCTL_POL, SMBUSz, BATEN1, and BATEN2
Td2
GRSTz
VDD33
Td1
VDD
Tsu_io
Thd_io
MISC_IO
Figure 1. Power-Up Timing Requirements
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7.7 Hub Input Supply Current
Typical values measured at TA = 25°C
VDD33
VDD11
3.3 V
1.1 V
Power On (after Reset)
5
39
mA
Disconnect from Host
5
39
mA
Suspend (USB2 Host)
5
39
mA
Suspend (USB3 Host)
6
40
mA
3.0 host / 1 SS Device and Hub in U1
50
218
mA
3.0 host / 1 SS Device and Hub in U0
50
342
mA
3.0 host / 2 SS Devices and Hub in U1
50
284
mA
3.0 host / 2 SS Devices and Hub in U0
50
456
mA
3.0 host / 1 SS and 1 HS Device in U1
92
242
mA
3.0 host / 1 SS and 1 HS Device in U0
93
364
mA
2.0 host / 1 HS Device active
48
71
mA
2.0 host / 2 HS Devices active
60
80
mA
PARAMETER
UNIT
LOW POWER MODES
ACTIVE MODES (US state / DS State)
10
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8 Detailed Description
8.1 Overview
The TUSB8020B-Q1 is a two-port USB 3.0 compliant hub. It provides simultaneous SuperSpeed USB and
high-speed/full-speed connections on the upstream port and provides SuperSpeed USB, high-speed, fullspeed, 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
SuperSpeed Hub
Oscilator
USB_SSTXM_DN2
USB_SSTXP_DN2
USB_SSRXM_DN2
USB_SSRXP_DN2
USB_SSTXM_DN1
USB_SSTXP_DN1
USB_DM_DN2
USB_DP_DN2
USB_DM_DN1
USB_DP_DN1
Clock
and
Reset
Distribution
USB_SSRXM_DN1
USB_SSRXP_DN1
XO
GRSTn
USB_SSTXM_UP
USB_SSTXP_UP
VBUS
Detect
Power
Distribution
USB 2.0 Hub
XI
USB_SSRXM_UP
USB_SSRXP_UP
USB_VBUS
USB_DM_UP
USB_DP_UP
USB_R1
VDD33
VDD
VSS
TEST
GANGED/SMBA2/HS_UP
FULLPWRMGMTz/SMBA1/SS_UP
PWRCTL_POL/SS_DN1
SMBUSz/SS_DN2
SCL/SMBCLK
SDA/SMDAT
OVERCUR1z
PWRCTL1/BATEN1
GPIO
I2C
SMBUS
Control
Registers
OVERCUR2z
PWRCTL2/BATEN2
8.3 Feature Description
8.3.1 Battery Charging Features
The TUSB8020B-Q1 provides support for USB Battery Charging Specification Revision 1.2 (BC 1.2). Battery
charging support may be enabled on a per port basis through the REG_6h(batEn[1:0]).
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.
In addition, to standard BC 1.2 DCP mode, the TUSB8020B-Q1 provides a mode (AUTOMODE) which
automatically provides support for BC 1.2 DCP devices and devices that support custom charging indication.
AUTOMODE is enabled by default. When in AUTOMODE, the port will automatically switch between a divider
mode and 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 5W. The divider mode can be configured to report a highcurrent setting (up to 10 W) through REG_Ah(HiCurAcpModeEn).
The battery charging mode for each port is dependent on the state of Reg_6h(batEn[n]), the status of the VBUS
input, and the state of REG_Ah(autoModeEnz) upstream port as identified in Table 1. Battery charging can also
be enabled through the PWRCTL1/BATEN1 and PWRCTL2/BATEN2 pins.
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Feature Description (continued)
Table 1. TUSB8020B-Q1 Battery Charging Modes
batEn[n]
VBUS
autoModeEnz
0
Don’t Care
Don’t Care
1
4V
(1)
(2)
(3)
(4)
BC Mode Port x
(x = n + 1)
Don’t Care
0
Automode (1)
1
(3) (4)
DCP
(2)
CDP (3)
Don’t Care
Auto-mode automatically selects divider-mode or DCP mode (BC 1.2 and YD/T 1591-2009).
Divider mode can be configured for high-current mode through register or OTP settings.
USB Battery Charging Specification Revision 1.2 Compliant
Chinese Telecommunications Industry Standard YD/T 1591-2009
8.3.2 USB Power Management
The TUSB8020B-Q1 can be configured for power switched applications using either per-port or ganged powerenable controls and over-current status inputs.
Power switch support is enabled by REG_5h(fullPwrMgmtz) and the per-port or ganged mode is configured by
REG_5h(ganged). It can also be enabled through the FULLPWRMGMTz pin. Also ganged or individual control
can be controlled by the GANGED pin.
The TUSB8020B-Q1 supports both active high and active low power-enable controls. The PWRCTL[2:1] polarity
is configured by REG_Ah(pwrctlPol). The polarity can also be configured by the PWRCTL_POL pin.
8.3.3 One Time Programmable (OTP) Configuration
The TUSB8020B-Q1 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 2 provides a list features which may be configured using the OTP. The Bit Field section in table shows
which features can be controlled by OTP ROM. The bits not listed in the table are not accessible by the OTP
ROM.
Table 2. OTP Configurable Features
CONFIGURATION REGISTER
OFFSET
BIT FIELD
DESCRIPTION
REG_01h
[7:0]
Vendor ID LSB
REG_02h
[7:0]
Vendor ID MSB
REG_03h
[7:0]
Product ID LSB
REG_04h
[7:0]
Product ID MSB
REG_07h
[0]
Port removable configuration for downstream ports 1. OTP
configuration is inverse of rmbl[1:0], i.e. 1 = not removable, 0 =
removable.
REG_07h
[1]
Port removable configuration for downstream ports 2. OTP
configuration is inverse of rmbl[1:0], i.e. 1 = not removable, 0 =
removable.
REG_0Ah
[1]
Automode enable
REG_0Ah
[4]
High-current divider mode enable.
REG_F2h
[3:1]
USB power switch power-on delay.
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8.3.4 Clock Generation
The TUSB8020B-Q1 accepts a crystal input to drive an internal oscillator or an external clock source. If a crystal
is used, a 1-MΩ shunt resistor is required. It is also important to keep the XI and XO traces as short as possible
and away from any switching leads to minimize noise coupling.
Figure 2. TUSB8020B-Q1 Clock
8.3.4.1 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 of Crystals for Texas Instruments USB 2.0 Devices (SLLA122) for details on how to determine the
load capacitance value.
8.3.4.2 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 3.0 jitter transfer function. XI should be tied to the 1.8-V clock source and XO should
be left floating.
8.3.5 Power Up and Reset
The TUSB8020B-Q1 does not have specific power sequencing requirements with respect to the VDD or VDD33
power rails. The VDD or VDD33 power rails 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.
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8.4 Device Functional Modes
8.4.1 External Configuration Interface
The TUSB8020B-Q1 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 SMBus capable host controller. The external
interface is enabled when both the SCL/SMBCLK and SDA/SMBDAT terminals are pulled up to 3.3 V at the deassertion of reset. The mode, I2C master or SMBus slave, is determined by the state of SMBUSz/SS_DN2
terminal at reset.
8.4.2 I2C EEPROM Operation
The TUSB8020B-Q1 supports a single-master, standard mode (100 kbit/s) connection to a dedicated I2C
EEPROM when the I2C interface mode is enabled. In I2C mode, the TUSB8020B-Q1 reads the contents of the
EEPROM at bus address 1010000b using 7-bit addressing starting at address 0.
If the value of the EEPROM contents at byte 00h equals 55h, the TUSB8020B-Q1 loads the configuration
registers according to the EEPROM map. If the first byte is not 55h, the TUSB8020B-Q1 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. If the TUSB8020B-Q1 detected an un-programmed EEPROM
(value other than 55h), it will enter Programming Mode and a Programming Endpoint within the hub will be
enabled.
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, Phy Custom Configuration, and Device Configuration 2
registers.
For details on I2C operation refer to the UM10204 I2C-bus Specification and User Manual.
8.4.3 SMBus Slave Operation
When the SMBus interface mode is enabled, the TUSB8020B-Q1 supports read block and write block protocols
as a slave-only SMBus device.
The TUSB8020B-Q1 slave address is 1000 1xyz, where:
• x is the state of GANGED/SMBA2/HS_UP terminal at reset,
• y is the state of FULLPWRMGMTz/SMBA1/SS_UP terminal at reset, and
• z is the read/write bit; 1 = read access, 0 = write access.
If the TUSB8020B-Q1 is addressed by a host using an unsupported protocol it will not respond. The
TUSB8020B-Q1 will wait 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 TUSB8020B-Q1 is in I2C or SMBus mode.
Table 3. TUSB8020B-Q1 Register Map
BYTE
ADDRESS
CONTENTS
00h
ROM Signature Register
No
01h
Vendor ID LSB
Yes
02h
Vendor ID MSB
Yes
03h
Product ID LSB
Yes
04h
Product ID MSB
Yes
05h
Device Configuration Register
Yes
06h
Battery Charging Support Register
Yes
07h
Device Removable Configuration Register
Yes
08h
Port Used Configuration Register
Yes
09h
Reserved
Yes, program to 00h
Yes
0Ah
Device Configuration Register 2
0Bh-0Fh
Reserved
10h-1Fh
UUID Byte [15:0]
EEPROM CONFIGURABLE
No
20h-21h
LangID Byte [1:0]
Yes, if customStrings is set
22h
Serial Number String Length
Yes, if customSerNum is set
23h
Manufacturer String Length
Yes, if customStrings is set
24h
Product String Length
Yes, if customStrings is set
25h-2Fh
Reserved
Yes
30h-4Fh
Serial Number String Byte [31:0]
Yes, if customSerNum is set
50h-8Fh
Manufacturer String Byte [63:0]
Yes, if customStrings is set
90h-CFh
Product String Byte [63:0]
Yes, if customStrings is set
D0-DFh
Reserved
No
F0h
Additional Feature Configuration Register
Yes
F1h
Reserved
No
F2h
Charging Port Control Register
Yes
F3-F7h
Reserved
No
F8h
Device Status and Command Register
No
F9-FFh
Reserved
No
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8.5.1.1 ROM Signature Register
Table 4. Register Offset 0h
Bit No.
7
6
5
4
3
2
1
0
Reset State
0
0
0
0
0
0
0
0
Table 5. Bit Descriptions – ROM Signature Register
Bit
7:0
Field Name
romSignature
Access
Description
RW
ROM Signature Register. This register is used by the TUSB8020B-Q1 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 TUSB8020B-Q1 aborts the EEPROM load and executes with
the register defaults.
8.5.1.2 Vendor ID LSB Register
Table 6. Register Offset 1h
Bit No.
7
6
5
4
3
2
1
0
Reset State
0
1
0
1
0
0
0
1
Table 7. Bit Descriptions – Vendor ID LSB Register
Bit
7:0
Field Name
vendorIdLsb
Access
Description
RO/RW
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.
This field is read/write unless the OTP ROM VID and OTP ROM PID
values are non-zero. If both values are non-zero the value when reading
this register shall reflect the OTP ROM value.
8.5.1.3 Vendor ID MSB Register
Table 8. Register Offset 2h
Bit No.
7
6
5
4
3
2
1
0
Reset State
0
0
0
0
0
1
0
0
Table 9. Bit Descriptions – Vendor ID MSB Register
Bit
7:0
16
Field Name
vendorIdMsb
Access
Description
RO/RW
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.
This field is read/write unless the OTP ROM VID and OTP ROM PID
values are non-zero. If both values are non-zero the value when reading
this register shall reflect the OTP ROM value.
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8.5.1.4 Product ID LSB Register
Table 10. Register Offset 3h
Bit No.
7
6
5
4
3
2
1
0
Reset State
0
0
1
0
0
1
0
1
Table 11. Bit Descriptions – Product ID LSB Register
Bit
7:0
Field Name
productIdLsb
Access
Description
RO/RW
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 25h 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.
This field is read/write unless the OTP ROM VID and OTP ROM PID
values are non-zero. If both values are non-zero the value when reading
this register shall reflect the OTP ROM value.
8.5.1.5 Product ID MSB Register
Table 12. Register Offset 4h
Bit No.
7
6
5
4
3
2
1
0
Reset State
1
0
0
0
0
0
0
0
Table 13. Bit Descriptions – Product ID MSB Register
Bit
7:0
Field Name
productIdMsb
Access
Description
RO/RW
Product ID MSB. Most significant byte of the product ID assigned by
Texas Instruments; the default value of this register is 80h representing
the MSB of the product ID assigned by Texas Instruments. The value
may be over-written to indicate a customer product ID.
This field is read/write unless the OTP ROM VID and OTP ROM PID
values are non-zero. If both values are non-zero, the value when reading
this register will reflect the OTP ROM value.
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8.5.1.6 Device Configuration Register
Table 14. Register Offset 5h
Bit No.
7
6
5
4
3
2
1
0
Reset State
0
0
0
1
X
X
0
0
Table 15. Bit Descriptions – Device Configuration Register
Bit
Field Name
Access
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
7
customStrings
RW
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
The default value of this bit is 0.
Custom serial number enable. This bit controls the ability to write to the
serial number registers.
6
customSernum
RW
0 = The Serial Number String Length and Serial Number String
registers are read only
1 = The 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
5
u1u2Disable
RW
1 = U1/U2 support is disabled, the TUSB8020B-Q1 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 3.0 protocol until it gets a power-on reset
or is disconnected on its upstream port.
When the TUSB8020B-Q1 is in I2C mode, the TUSB8020B-Q1 loads this
bit from the contents of the EEPROM.
When the TUSB8020B-Q1 is in SMBUS mode, the value may be overwritten by an SMBus host.
4
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 terminal.
0 = When fullPwrMgmtz = 0, each port is individually power switched
and enabled by the PWRCTL[2:1]/BATEN[2:1] terminals
3
ganged
RW
1 = When fullPwrMgmtz = 0, the power switch control for all ports is
ganged and enabled by the PWRCTL1/BATEN1 terminal
When the TUSB8020B-Q1 is in I2C mode, the TUSB8020B-Q1 loads this
bit from the contents of the EEPROM.
When the TUSB8020B-Q1 is in SMBUS mode, the value may be overwritten 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 terminal.
0 = Port power switching and over-current status reporting is
enabled
2
fullPwrMgmtz
RW
1 = Port power switching and over-current status reporting is
disabled
When the TUSB8020B-Q1 is in I2C mode, the TUSB8020B-Q1 loads this
bit from the contents of the EEPROM.
When the TUSB8020B-Q1 is in SMBUS mode, the value may be overwritten by an SMBus host.
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Table 15. Bit Descriptions – Device Configuration Register (continued)
Bit
Field Name
Access
Description
1
RSVD
RW
Reserved. This bit is reserved and should not be altered from the default.
0
RSVD
RO
Reserved. This field is reserved and returns 0 when read.
8.5.1.7 Battery Charging Support Register
Table 16. Register Offset 6h
Bit No.
7
6
5
4
3
2
1
0
Reset State
0
0
0
0
0
0
X
X
Table 17. Bit Descriptions – Battery Charging Support Register
Bit
Field Name
Access
7:2
RSVD
RO
Description
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
1:0
batEn[1:0]
RW
Each bit corresponds directly to a downstream port, i.e. batEn0
corresponds to downstream port 1, and batEN1 corresponds to
downstream port 2.
The default value for these bits are loaded at the de-assertion of reset
with the value of PWRCTL/BATEN[1:0].
When in I2C/SMBus mode the bits in this field may be over-written by
EEPROM contents or by an SMBus host.
8.5.1.8 Device Removable Configuration Register
Table 18. Register Offset 7h
Bit No.
7
6
5
4
3
2
1
0
Reset State
0
0
0
0
0
0
X
X
Table 19. Bit Descriptions – Device Removable Configuration Register
Bit
Field Name
Access
Description
7
customRmbl
RW
Custom removable status. When this field is a 1, the TUSB8020B-Q1
uses rmbl bits in this register to identify removable status for the ports.
6:2
RSVD
RO
Reserved. Read only, returns 0 when read. Bits 3:2 are RW. They are
reserved and return zero when read.
Removable. The bits in this field indicate whether a device attached to
downstream ports 2 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
1:0
rmbl[1:0]
RW
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.
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[1:0] field.
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8.5.1.9 Port Used Configuration Register
Table 20. Register Offset 8h
Bit No.
7
6
5
4
3
2
1
0
Reset State
0
0
0
0
0
0
1
1
Table 21. Bit Descriptions – Port Used Configuration Register
Bit
Field Name
Access
7:0
RSVD
RO
Description
Reserved. Read only.
8.5.1.10 PHY Custom Configuration Register
Table 22. Register Offset 9h
Bit No.
7
6
5
4
3
2
1
0
Reset State
0
0
0
0
0
0
0
0
Table 23. Bit Descriptions – PHY Custom Configuration Register
20
Bit
Field Name
Access
7:6
RSVD
RO
Reserved. Read only, returns 0 when read.
Description
5
RSVD
RW
Reserved. This bit is reserved and should not be altered from the default.
4:2
RSVD
RO
Reserved. Read only, returns 0 when read.
1:0
RSVD
RW
Reserved. This field is reserved and should not be altered from the
default.
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8.5.1.11 Device Configuration Register 2
Table 24. Register Offset Ah
Bit No.
7
6
5
4
3
2
1
0
Reset State
0
0
X
0
0
0
0
0
Table 25. Bit Descriptions – Device Configuration Register 2
Bit
Field Name
Access
7
RSVD
RO
Description
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.
6
customBCfeatures
RW
0 = The HiCurAcpModeEn and AutoModeEnz bits are read only and
the values are loaded from the OTP ROM.
1 = The HiCurAcpModeEn and AutoModeEnz bits are read/write and
can be loaded by EEPROM or written by SMBus. from this register.
This bit may be written simultaneously with HiCurAcpModeEn and
AutoModeEnz.
Power enable polarity. This bit is loaded at the de-assertion of reset with
the inverse value of the PWRCTL_POL terminal.
0 = PWRCTL polarity is active low
5
pwrctlPol
RW
1 = PWRCTL polarity is active high
When the TUSB8020B-Q1 is in I2C mode, the TUSB8020B-Q1 loads this
bit from the contents of the EEPROM.
When the TUSB8020B-Q1 is in SMBUS mode, the value may be overwritten 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.
4
HiCurAcpModeEn
RO/RW
0 = High current divider mode disabled
1 = High current divider mode enabled
This bit is read only unless the customBCfeatures bit is set to 1.
Otherwise the value of this bit reflects the value of the OTP ROM
HiCurAcpModeEn bit.
3
RSVD
RW
Reserved
DSPort ECR enable. This bit enables full implementation of the DSPORT
ECR (April 2013).
2
dsportEcrEn
RW
0 = DSPort ECR (April 2013) is enabled with the exception of
changes related to the CCS bit is set upon entering U0, and changes
related to avoiding or reporting compliance mode entry.
1 = The full DSport ECR (April 2013) is enabled.
Automatic Mode Enable. This bit is loaded from the OTP ROM.
The automatic mode only applies to downstream ports with battery
charging enabled when the upstream port is not connected. Under these
conditions:
0 = Automatic mode battery charging features are enabled.
1
autoModeEnz
RO/RW
1 = Automatic mode is disabled; only Battery Charging 1.2 DCP
mode is supported.
NOTE: When the upstream port is connected, Battery Charging 1.2 CDP
mode will be supported on all ports that enabled for battery charging
support regardless of the value of this bit. The Automode is enabled if
this field is zero and the pwrctlPol field is zero.
This bit is read only unless the customBCfeatures bit is set to 1.
Otherwise the value of this bit reflects the value of the OTP ROM
AutoModeEnz bit.
0
RSVD
RO
Reserved. Read only, returns 0 when read.
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8.5.1.12 UUID Registers
Table 26. Register Offset 10h-1Fh
Bit No.
7
6
5
4
3
2
1
0
Reset State
X
X
X
X
X
X
X
X
Table 27. Bit Descriptions – UUID Byte N Register
Bit
7:0
Field Name
Access
uuidByte[n]
RO
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.
8.5.1.13 Language ID LSB Register
Table 28. Register Offset 20h
Bit No.
7
6
5
4
3
2
1
0
Reset State
0
0
0
0
1
0
0
1
Table 29. Bit Descriptions – Language ID LSB Register
Bit
7:0
Field Name
langIdLsb
Access
Description
RW
Language ID least significant byte. This register contains the value
returned in the LSB of the LANGID code in string index 0. The
TUSB8020B-Q1 only supports one language ID. The default value of this
register is 09h representing the LSB of the LangID 0409h indicating
English United States. When customStrings is 1, this field may be overwritten by the contents of an attached EEPROM or by an SMBus host.
8.5.1.14 Language ID MSB Register
Table 30. Register Offset 21h
Bit No.
7
6
5
4
3
2
1
0
Reset State
0
0
0
0
0
1
0
0
Table 31. Bit Descriptions – Language ID MSB Register
Bit
7:0
22
Field Name
langIdMsb
Access
Description
RO/RW
Language ID most significant byte. This register contains the value
returned in the MSB of the LANGID code in string index 0. The
TUSB8020B-Q1 only supports one language ID. The default value of this
register is 04h representing the MSB of the LangID 0409h indicating
English United States.
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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8.5.1.15 Serial Number String Length Register
Table 32. Register Offset 22h
Bit No.
7
6
5
4
3
2
1
0
Reset State
0
0
0
1
1
0
0
0
Table 33. Bit Descriptions – Serial Number String Length Register
Bit
Field Name
Access
7:6
RSVD
RO
5:0
serNumStringLen
RO/RW
Description
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 serNumbStringLen
bytes is returned at string index 1 from the data contained in the Serial
Number String registers.
8.5.1.16 Manufacturer String Length Register
Table 34. Register Offset 23h
Bit No.
7
6
5
4
3
2
1
0
Reset State
0
0
0
0
0
0
0
0
Table 35. Bit Descriptions – Manufacturer String Length Register
Bit
Field Name
Access
7
RSVD
RO
6:0
mfgStringLen
RO/RW
Description
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.
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.
8.5.1.17 Product String Length Register
Table 36. Register Offset 24h
Bit No.
7
6
5
4
3
2
1
0
Reset State
0
0
0
0
0
0
0
0
Table 37. Bit Descriptions – Product String Length Register
Bit
Field Name
Access
7
RSVD
RO
6:0
prodStringLen
RO/RW
Description
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.
When the field is non-zero, a product string of prodStringLen bytes is
returned at string index 2 from the data contained in the Product String
registers.
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8.5.1.18 Serial Number Registers
Table 38. Register Offset 30h-4Fh
Bit No.
7
6
5
4
3
2
1
0
Reset State
X
X
x
x
x
x
x
x
Table 39. Bit Descriptions – Serial Number Registers
Bit
7:0
Field Name
serialNumber[n]
Access
Description
RO/RW
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
set by TI. When customSernum is 1, these registers may be over-written
by EEPROM contents or by an SMBus host.
8.5.1.19 Manufacturer String Registers
Table 40. Register Offset 50h-8Fh
Bit No.
7
6
5
4
3
2
1
0
Reset State
0
0
0
0
0
0
0
0
Table 41. Bit Descriptions – Manufacturer String Registers
Bit
7:0
Field Name
Access
mfgStringByte[n]
RO/RW
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.
8.5.1.20 Product String Registers
Table 42. Register Offset 90h-CFh
Bit No.
7
6
5
4
3
2
1
0
Reset State
0
0
0
0
0
0
0
0
Table 43. Bit Descriptions – Product String Byte N Register
Bit
7:0
24
Field Name
prodStringByte[n]
Access
Description
RW
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.
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8.5.1.21 Additional Feature Configuration Register
Table 44. Register Offset F0h
Bit No.
7
6
5
4
3
2
1
0
Reset State
0
0
0
0
0
0
0
0
Table 45. Bit Descriptions – Additional Feature Configuration Register
Bit
Field Name
Access
7:1
RSVD
RO
Description
Reserved. Read only, returns 0 when read.
USB3 Spread Spectrum Disable. This bit allows firmware to disable the
spread spectrum function of the USB3 phy PLL.
0
usb3spreadDis
0 = Spread spectrum function is enabled
RW
1= Spread spectrum function is disabled
This bit is loaded at the de-assertion of reset with the value of the
SCL/SMBCLK terminal.
8.5.1.22 Charging Port Control Register
Table 46. Register Offset F2h
Bit No.
7
6
5
4
3
2
1
0
Reset State
0
0
0
0
0
0
0
0
Table 47. Bit Descriptions – Charging Port Control Register
Bit
Field Name
Access
7:4
RSVD
RO
Reserved. Read only, returns 0 when read.
RW
Power On Delay Time. When dsportEcrEn is set, 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 custom charging mode to Dedicated
Charging Port Mode. The nominal timing is defined as follows:
3:1
pwronTime
Description
TPWRON_EN = (pwronTime + 1) x 200 ms
(1)
These registers may be over-written by EEPROM contents or by an
SMBus host.
0
RSVD
RW
Reserved. This bit is reserved and should not be altered from the default.
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8.5.1.23 Device Status and Command Register
Table 48. Register Offset F8h
Bit No.
7
6
5
4
3
2
1
0
Reset State
0
0
0
0
0
0
0
0
Table 49. Bit Descriptions – Device Status and Command Register
Bit
Field Name
Access
7:2
RSVD
RO
1
smbusRst
RSU
SMBus interface reset. This bit loads the registers back to their GRSTz
values.
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.
RCU
Configuration active. This bit indicates that configuration of the
TUSB8020B-Q1 is currently active. The bit is set by hardware when the
device enters the I2C or SMBus mode. The TUSB8020B-Q1 shall not
connect on the upstream port while this bit is 1.
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.
0
26
cfgActive
Description
Reserved. Read only, returns 0 when read.
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9 Applications and Implementation
9.1 Application Information
The TUSB8020B-Q1 is a two-port USB 3.0 compliant hub. It provides simultaneous SuperSpeed USB and highspeed/full-speed connections on the upstream port and provides SuperSpeed USB, high-speed, full-speed, or
low speed connections on the downstream port. The TUSB8020B-Q1 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 TUSB8020B-Q1, the notebook can increase the downstream port count to three.
9.2 Typical Applications
A common application for the TUSB8020B-Q1 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 TUSB8020B-Q1’s
upstream port is plugged into a USB Host controller. The downstream ports of the TUSB8020B-Q1 are exposed
to users for connecting USB hard drives, camera, flash drive, and so forth.
Figure 3. Discrete USB Hub Product
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Typical Applications (continued)
9.2.1 Design Requirements
Table 50. Input Parameters
DESIGN PARAMETER
EXAMPLE VALUE
VDD Supply
1.1V
VDD33 Supply
3.3V
Upstream Port USB Support (SS, HS, FS)
SS, HS, FS
Downstream Port 1 USB Support (SS, HS, FS, LS)
SS, HS, FS, LS
Downstream Port 2 USB Support (SS, HS, FS, LS)
SS, HS, FS, LS
# of Removable Downstream Ports
2
# of Non-Removable Downstream Ports
0
Full Power Management of Downstream Ports
Yes. (FULLPWRMGMTZ = 0)
Individual Control of Downstream Port Power
Switch
Yes. (GANGED = 0)
Power Switch Enable Polarity
Active High. (PWRCTL_POL = 0)
Battery Charge Support for Downstream Port 1
Yes
Battery Charge Support for Downstream Port 2
Yes
I2C EEPROM Support
No.
24MHz Clock Source
Crystal
9.2.2 Detailed Design Procedure
9.2.2.1 Upstream Port Implementation
The upstream of the TUSB8020B-Q1 is connected to a USB3 Type B connector. This particular example has
GANGED terminal and FULLPWRMGMTZ terminal 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%
C1
10uF
R2
10K 1%
0402
1%
U1A
J1
9
VBUS
DM
DP
GND
SSTXN
SSTXP
GND
SSRXN
SSRXP
SHIELD0
SHIELD1
1
2
3
4
5
6
7
8
9
10
11
VBUS
USB_DM_UP
USB_DP_UP
CAP_UP_TXM
CAP_UP_TXP
C2
0.1uF 0201
USB_SSTXM_UP
C3
0.1uF 0201
USB_SSTXP_UP
USB_SSRXM_UP
USB_SSRXP_UP
27
26
28
29
31
32
USB_VBUS
USB_DM_UP
USB_DP_UP
GANGED / SMBA2 / HS_UP
FULLPWRMGMTZ / SMBA1 / SS_UP
USB_SSTXM_UP
USB_SSTXP_UP
35
36
R3
4.7K
0402
5%
USB_SSRXM_UP
USB_SSRXP_UP
R4
4.7K
0402
5%
USB3_TYPEB_CONNECTOR
C4
0.1uF
C5
0.001uF
R5
1M
0402
5%
TUSB8020B
Figure 4. Upstream Port Implementation
28
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9.2.2.2 Downstream Port 1 Implementation
The downstream port 1 of the TUSB8020B-Q1 is connected to a USB3 Type A connector. With BATEN1 terminal
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. The PWRCTL_POL is pulled down which will result in active high
power enable (PWRCTL1 and PWRCTL2) for a USB VBUS power switch.
BOARD_3P3V
FB1
R6
4.7K
0402
5%
POPULATE
FOR BC SUPPORT
DN1_VBUS
DN1_VBUS
VBUS_DS1
220 @ 100MHZ
C6
0.1uF
J2
U1B
21
PWRCTL_POL / SS_DN1
R7
4.7K
0402
5%
USB_DM_DN1
USB_DP_DN1
USB_SSRXM_DN1
USB_SSRXP_DN1
USB_SSTXM_DN1
USB_SSTXP_DN1
PWRCTL1 / BATEN1
OVERCUR1Z
42
41
USB_DM_DN1
USB_DP_DN1
47
46
USB_SSRXM_DN1
USB_SSRXP_DN1
44
43
USB_SSTXM_DN1
C7
0.1uF 0201
C8
CAP_DN_TXM1
CAP_DN_TXP1
USB_SSTXP_DN1
4
0.1uF 0201
PWRCTRL1_BATEN1
5
1
2
3
4
5
6
7
8
9
10
11
VBUS
DM
DP
GND
SSRXN
SSRXP
GND
SSTXN
SSTXP
SHIELD0
SHIELD1
USB3_TYPEA_CONNECTOR
OVERCUR1Z
R8
1M
0402
5%
TUSB8020B
C9
0.001uF
C10
0.1uF
Figure 5. Downstream Port 1 Implementation
9.2.2.3 Downstream Port 2 Implementation
The downstream port 2 of the TUSB8020B-Q1 is connected to a USB3 Type A connector. With BATEN2 terminal
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.
BOARD_3P3V
FB2
POPULATE
FOR BC SUPPORT
R9
4.7K
0402
5%
DN2_VBUS
DN2_VBUS
VBUS_DS2
220 @ 100MHZ
C11
0.1uF
J3
U1C
22
SMBUSZ / SS_DN2
USB_DM_DN2
USB_DP_DN2
USB_SSRXM_DN2
USB_SSRXP_DN2
USB_SSTXM_DN2
USB_SSTXP_DN2
PWRCTL2 / BATEN2
OVERCUR2Z
15
14
USB_DM_DN2
USB_DP_DN2
20
19
USB_SSRXM_DN2
USB_SSRXP_DN2
17
16
USB_SSTXM_DN2
USB_SSTXP_DN2
6
8
TUSB8020B
C13
C12
0.1uF 0201
CAP_DN2_TXM
CAP_DN2_TXP
0.1uF 0201
PWRCTRL2_BATEN2
OVERCUR2Z
R10
1M
0402
5%
C15
0.001uF
1
2
3
4
5
6
7
8
9
10
11
VBUS
DM
DP
GND
SSRXN
SSRXP
GND
SSTXN
SSTXP
SHIELD0
SHIELD1
USB3_TYPEA_CONNECTOR
C14
0.1uF
Figure 6. Downstream Port 2 Implementation
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9.2.2.4 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, please
refer to the Texas Instruments website.
BOARD_3P3V
BOARD_3P3V
BOARD_5V
R19
10K
0402
5%
C36
0.1uF
U3
2
3
PWRCTRL1_BATEN1
PWRCTRL2_BATEN2
R20
10K
0402
5%
4
PWRCTRL1_BATEN1
5
PWRCTRL2_BATEN2
1
11
IN
IN
OUT1
DN1_VBUS
DN1_VBUS
10
FAULT1Z
EN1
OUT2
EN2
8
OVERCUR1Z
DN2_VBUS
DN2_VBUS
6
FAULT2Z
GND
PAD
9
ILIM
7
OVERCUR2Z
ILIM1
C37
0.1uF
TPS2561
C39
+
R21
25.5K
0402
5%
C38
150uF
0.1uF
+
C40
150uF
Limiting DS Port VBUS current to 2.2A per port.
Figure 7. Power Switch Implementation
9.2.2.5 Clock, Reset, and Misc
U1D
C32
SCL / SMBCLK
1uF
SDA / SMBDAT
11
38
XI
1M
39
3
GRSTZ
TEST
R11
2
USB_R1
10
24
XO
Y1
TUSB8020B
R12
9.53K
0402
1%
R13
1K
24MHz
C33
C34
18pF
18pF
Figure 8. Clock, Reset, and Misc
30
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9.2.2.6 Power Implementation
BOARD_1P1V
VDD11
TUSB8020B
VDD33
VDD33
VDD33
VDD33
VDD33
VDD33
VDD33
VDD33
C16
C17
C18
C19
C20
C21
0.1uF
0.1uF
0.1uF
0.1uF
0.1uF
0.1uF
7
13
23
25
33
37
40
48
49
TPAD
VDD
VDD
VDD
VDD
VDD
VDD
U1E
1
12
18
30
34
45
FB3
C22
10uF
220 @ 100MHZ
BOARD_3P3V
VDD33
FB4
C23
C24
C25
C26
C27
C28
C29
C30
0.1uF
0.1uF
0.1uF
0.1uF
0.1uF
0.1uF
0.1uF
0.1uF
C31
1uF
220 @ 100MHZ
Figure 9. Power Implementation
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9.2.3 Application Curves
32
Figure 10. SuperSpeed TX Eye for Downstream Port 1
Figure 11. : SuperSpeed TX Eye for Downstream Port 2
Figure 12. : HighSpeed TX Eye for Downstream Port 1
Figure 13. HighSpeed TX Eye for Downstream Port 2
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10 Power Supply Recommendations
10.1 Power Supply
VDD should be implemented as a single power plane, as should VDD33.
• The VDD terminals of the TUSB8020B-Q1 supply 1.1 V (nominal) power to the core of the TUSB8020B-Q1.
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 VDD33 terminals of the TUSB8020B-Q1 supply 3.3-V power rail to the I/O of the TUSB8020B-Q1. 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 TUSB8020B-Q1 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 5 V and at least
900 mA per port. Downstream port power switches can be controlled by the TUSB8020BPHP 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 0.1-µF 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 TUSB8020B-Q1 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 terminal USB_R1 should be placed as close as possible to the
TUSB8020B-Q1.
2. A 0.1-µF capacitor 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 possible to the USB connector.
5. If a crystal is used, it must be placed as close as possible to the TUSB8020B-Q1’s XI and XO terminals.
6. Place voltage regulators as far away as possible from the TUSB8020B-Q1, 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 TUSB8020B-Q1 package as a 0.5-mm pin pitch.
2. The TUSB8020B-Q1 package has a 3.6-mm x 3.6-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 TUSB8020B-Q1 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° 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°. 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 TUSB8020B-Q1 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.
34
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Layout Guidelines (continued)
12. Do not place power fuses across the differential pair traces.
11.2 Layout Example
11.2.1 Upstream Port
Figure 14. Example Routing of Upstream Port
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TUSB8020B-Q1
SLLSEF7 – MARCH 2014
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Layout Example (continued)
11.2.2 Downstream Port
Figure 15. Example Routing of Downstream Port
11.2.3 Thermal Pad
Figure 16. Example Thermal Pad Layout
36
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SLLSEF7 – MARCH 2014
12 Device and Documentation Support
12.1 Trademarks
All trademarks are the property of their respective owners.
12.2 Electrostatic Discharge Caution
These devices have limited built-in ESD protection. The leads should be shorted together or the device placed in conductive foam
during storage or handling to prevent electrostatic damage to the MOS gates.
12.3 Glossary
SLYZ022 — TI Glossary.
This glossary lists and explains terms, acronyms and definitions.
13 Mechanical, Packaging, and Orderable Information
The following pages include mechanical packaging and orderable information. This information is the most
current data available for the designated devices. This data is subject to change without notice and revision of
this document. For browser-based versions of this data sheet, refer to the left-hand navigation.
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37
PACKAGE OPTION ADDENDUM
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10-Dec-2020
PACKAGING INFORMATION
Orderable Device
Status
(1)
Package Type Package Pins Package
Drawing
Qty
Eco Plan
(2)
Lead finish/
Ball material
MSL Peak Temp
Op Temp (°C)
Device Marking
(3)
(4/5)
(6)
TUSB8020BIPHPQ1
ACTIVE
HTQFP
PHP
48
250
RoHS & Green
NIPDAU
Level-3-260C-168 HR
-40 to 85
T8020BIQ1
TUSB8020BIPHPRQ1
ACTIVE
HTQFP
PHP
48
1000
RoHS & Green
NIPDAU
Level-3-260C-168 HR
-40 to 85
T8020BIQ1
(1)
The marketing status values are defined as follows:
ACTIVE: Product device recommended for new designs.
LIFEBUY: TI has announced that the device will be discontinued, and a lifetime-buy period is in effect.
NRND: Not recommended for new designs. Device is in production to support existing customers, but TI does not recommend using this part in a new design.
PREVIEW: Device has been announced but is not in production. Samples may or may not be available.
OBSOLETE: TI has discontinued the production of the device.
(2)
RoHS: TI defines "RoHS" to mean semiconductor products that are compliant with the current EU RoHS requirements for all 10 RoHS substances, including the requirement that RoHS substance
do not exceed 0.1% by weight in homogeneous materials. Where designed to be soldered at high temperatures, "RoHS" products are suitable for use in specified lead-free processes. TI may
reference these types of products as "Pb-Free".
RoHS Exempt: TI defines "RoHS Exempt" to mean products that contain lead but are compliant with EU RoHS pursuant to a specific EU RoHS exemption.
Green: TI defines "Green" to mean the content of Chlorine (Cl) and Bromine (Br) based flame retardants meet JS709B low halogen requirements of