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TUSB1002
SLLSEU4E – MAY 2016 – REVISED MAY 2019
TUSB1002 USB3.1 10 Gbps Dual-Channel Linear Redriver
1 Features
3 Description
•
The TUSB1002 is the industry’s first dual-channel
USB 3.1 SuperSpeedPlus (SSP) redriver and signal
conditioner. The device offers low power consumption
on a 3.3-V supply with its ultra-low-power
architecture. It supports the USB3.1 low power
modes
which
further
reduces
idle
power
consumption.
1
•
•
•
•
•
•
•
•
•
•
•
•
Supports USB3.1 SuperSpeed (5 Gbps) and
SuperSpeedPlus (10 Gbps)
Supports PCI Express Gen3, SATA Express, and
SATA Gen3.
Ultra Low-Power Architecture
– Active: < 340 mW
– U2/U3: < 8 mW
– Disconnected: < 2 mW
Adjustable Voltage Output Swing Linear Range up
to 1200 mVpp
No Host/Device Side Requirement
16 Settings for up to 16 dB at 10 Gbps of Linear
Equalization
Adjustable DC Equalization Gain
Hot-Plug Capable
Pin-to-Pin Compatible With LVPE502A and
LVPE512 USB 3.0 Redriver
Temperature Range: 0°C to 70°C
±6 KV HBM ESD
Available in Single 3.3 V Supply.
Available in 4 mm x 4 mm VQFN
The TUSB1002 is available in either a a 24-pin 4 mm
x 4 mm VQFN. It is also available in a commercial
grade (TUSB1002).
Device Information(1)
PART NUMBER
TUSB1002
PACKAGE
VQFN (24)
BODY SIZE (NOM)
4.00 mm x 4.00 mm
(1) For all available packages, see the orderable addendum at
the end of the data sheet.
2 Applications
•
•
•
•
•
•
The TUSB1002 implements a linear equalizer,
supporting up to 16 dB of loss due to Inter-Symbol
Interference (ISI). When USB signals travel across a
PCB or cable, signal integrity degrades due to loss
and inter-symbol interference. The linear equalizer
compensates for the channel loss, and thereby,
extends the channel length and enables systems to
pass USB compliance. The dual lane implementation
and small package size provides flexibility in the
placement of the TUSB1002 in the USB3.1 path.
Notebook and Desktop PC
TVs
Tablets
Cell Phones
Active Cable
Docking Stations
SPACER
RXP1
+
RXN1 -
+
USB 3.1
Host
+
TXP2
-
TXN2
+
TXP1
-
TXN1
TUSB1002
+
+
RXP2
-
RXN2
-
USB 3.1
Receptacle
Simplified Schematic
Copyright © 2016, Texas Instruments Incorporated
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.
TUSB1002
SLLSEU4E – MAY 2016 – REVISED MAY 2019
www.ti.com
Table of Contents
1
2
3
4
5
6
Features ..................................................................
Applications ...........................................................
Description .............................................................
Revision History.....................................................
Pin Configuration and Functions .........................
Specifications.........................................................
6.1
6.2
6.3
6.4
6.5
6.6
6.7
6.8
6.9
6.10
7
1
1
1
2
4
6
Absolute Maximum Ratings ...................................... 6
ESD Ratings.............................................................. 6
Recommended Operating Conditions....................... 6
Thermal Information .................................................. 6
Electrical Characteristics, Power Supply .................. 7
Electrical Characteristics........................................... 7
Power-Up Requirements........................................... 9
Timing Requirements ................................................ 9
Switching Characteristics .......................................... 9
Typical Characteristics .......................................... 11
Detailed Description ............................................ 14
7.1 Overview ................................................................. 14
7.2 Functional Block Diagram ....................................... 14
7.3 Feature Description................................................. 15
7.4
7.5
7.6
7.7
8
Device Functional Modes........................................
U0 Mode..................................................................
U1 Mode..................................................................
U2/U3 Mode ............................................................
17
17
18
18
Application and Implementation ........................ 19
8.1 Application Information............................................ 19
8.2 Typical USB3.1 Application .................................... 19
8.3 Typical SATA, PCIe and SATA Express
Application................................................................ 22
9 Power Supply Recommendations...................... 25
10 Layout................................................................... 25
10.1 Layout Guidelines ................................................. 25
10.2 Layout Example .................................................... 26
11 Device and Documentation Support ................. 27
11.1
11.2
11.3
11.4
Community Resources..........................................
Trademarks ...........................................................
Electrostatic Discharge Caution ............................
Glossary ................................................................
27
27
27
27
12 Mechanical, Packaging, and Orderable
Information ........................................................... 27
4 Revision History
Changes from Revision D (October 2017) to Revision E
Page
•
Deleted TUSB1002I industrial from the Feature, Description, and Device Information ......................................................... 1
•
Deleted TUSB1002I Operating free-air temperature from the Recommended Operating Conditions ................................... 6
•
Deleted TUSB1002I from the Thermal Information table ....................................................................................................... 6
Changes from Revision C (August 2017) to Revision D
•
Page
Changed pin 8 From: RXIN To: RX1N in the RGE pin image................................................................................................ 4
Changes from Revision B (August 2017) to Revision C
Page
•
Changed Feature From: 14 Settings for up to 15 dB at 10 Gbps of Linear Equalization To: 16 Settings for up to 16
dB at 10 Gbps of Linear Equalization..................................................................................................................................... 1
•
Deleted the RMQ package option from the Pin Configuration and Functions section .......................................................... 4
•
Deleted the RMQ package from the Pin Functions table ...................................................................................................... 4
•
Changed the description of pin 7 From: R = Test Mode To: R = PCIe / Test Mode. in the Pin Functions table .................. 5
•
Deleted the RMQ column from Thermal Information table .................................................................................................... 6
•
Added Differential crosstalk between TX and RX signal pairs. ............................................................................................. 7
•
From: EQ(GAIN-10Gbps) 15dB To: EQ(GAIN-10Gbps) 16dB .................................................................................................................. 7
•
EQ setting 15 changed from Reserved to 10.4 / 16.0 ......................................................................................................... 16
•
EQ setting 16 changed from Reserved to 10.6 / 16.3 ......................................................................................................... 16
•
Added the PCIe/SATA/SATA Express Redriver Operation section. ................................................................................... 17
•
Added the Typical SATA, PCIe, and SATA Expess Application section ............................................................................. 22
2
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SLLSEU4E – MAY 2016 – REVISED MAY 2019
Changes from Revision A (May 2016) to Revision B
Page
•
Added a capacitor to the RXP2 and RXN2 pins of the Simplified Schematic ........................................................................ 1
•
Added a capacitor to the RXP2 and RXN2 pins of Figure 17 .............................................................................................. 19
•
Updated the A/C coupling Capacitor section of Table 4 ..................................................................................................... 19
•
Changed text in the Detailed Design Procedure From: No A/C coupling capacitors are placed on the RX2P/N. To:
330nF A/C coupling capacitors along with 220k resistors are placed on the RX2P and RX2N. Inclusion of these
330nF capacitors and 220k resistors is optional but highly recommended. If not implemented, then RX2P/N should
be DC-coupled to the USB receptacle. ................................................................................................................................ 20
•
Added 330nF AC capacitors (C12 and C13) on RX2P and RX2N in Figure 18 .................................................................. 20
Changes from Original (May 2016) to Revision A
•
Page
Changed device status From: Preview To: Production ......................................................................................................... 1
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3
TUSB1002
SLLSEU4E – MAY 2016 – REVISED MAY 2019
www.ti.com
5 Pin Configuration and Functions
RX2P
19
RX2N
20
GND
21
TX1P
22
TX1N
23
RSVD1
24
GND
CH2_EQ2
CH2_EQ1
CFG2
SLP_S0#
VCC
RGE Package
24-Pin VQFN
Top View
18
17
16
15
14
13
+
-
2
3
4
5
6
CH1_EQ2
GFG1
EN
GND
VCC
1
CH1_EQ1
+
-
12
TX2P
11
TX2N
10
GND
9
RX1P
8
RX1N
7
MODE
Pin Functions
PIN
TYPE
INTERNAL PULLUP
PULLDOWN
DESCRIPTION
NAME
RGE
RX1P
9
RX1N
8
RX2P
19
RX2N
20
TX1P
22
TX1N
23
TX2P
12
TX2N
11
CH1_EQ1
2
I (4-level)
CH1_EQ1. Configuration pin used to control Rx EQ level for RX1P/N. The state
of this pin is sampled after the rising edge of EN. Refer to Figure 2 for details of
timing. This pin along with CH1_EQ2 allows for up to 16 equalization settings.
CH1_EQ2
3
I (4-level)
CH1_EQ2. Configuration pin used to control Rx EQ level for RX1P/N. The state
of this pin is sampled after the rising edge of EN. Refer to Figure 2 for details of
timing. This pin along with CH1_EQ1 allows for up to 16 equalization settings.
Differential input for SuperSpeed (SS) and SuperSpeedPlus (SSP) positive
signals for Channel 1
90Ω Differential
Input
Differential input for SuperSpeed (SS) and SuperSpeedPlus (SSP) negative
signals for Channel 1
Differential input for SuperSpeed (SS) and SuperSpeedPlus (SSP) positive
signals for Channel 2
90Ω Differential
Input
Differential input for SuperSpeed (SS) and SuperSpeedPlus (SSP) negative
signals for Channel 2.
Differential output for SuperSpeed (SS) and SuperSpeedPlus (SSP) positive
signals for Channel 1.
90Ω Differential
Output
Differential output for SuperSpeed (SS) and SuperSpeedPlus (SSP) negative
signals for Channel 1.
Differential output for SuperSpeed (SS) and SuperSpeedPlus (SSP) positive
signals for Channel 2.
90Ω Differential
Output
Differential output for SuperSpeed (SS) and SuperSpeedPlus (SSP) negative
signals for Channel 2.
PU (approx 45K)
PD (approx 95K)
CH2_EQ1
16
I (4-level)
CH2_EQ1. Configuration pin used to control Rx EQ level for RX2P/N. The state
of this pin is sampled after the rising edge of EN. Refer to Figure 2 for details of
timing. This pin along with CH2_EQ2 allows for up to 16 equalization settings.
CH2_EQ2
17
I (4-level)
CH2_EQ2. Configuration pin used to control Rx EQ level for RX2P/N. The state
of this pin is sampled after the rising edge of EN. Refer to Figure 2 for details of
timing. This pin along with CH2_EQ1 allows for up to 16 equalization settings.
4
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SLLSEU4E – MAY 2016 – REVISED MAY 2019
Pin Functions (continued)
PIN
NAME
RGE
TYPE
INTERNAL PULLUP
PULLDOWN
PU (approx 400 K)
EN
5
I (2-level)
CFG1
4
I (4-level)
PU (approx 45K)
PD (approx 95K)
CFG2
15
EN. Places TUSB1002 into shutdown mode when asserted low. Normal
operation when pin is asserted high. When in shutdown, TUSB1002’s receiver
terminations will be high impedance and tx/rx channels will be disabled.
CFG1. This pin along with CFG2 will select VOD linearity range and DC gain
for both channels 1 and 2. The state of this pin is sampled after the rising edge
of EN. Refer to Figure 2 for details of timing. Refer to Table 3 for VOD linearity
range and DC gain options.
I (4-level)
CFG2. This pin along with CFG1 will set VOD linearity range and DC gain for
both channels 1 and 2. The state of this pin is sampled after the rising edge of
EN. Refer to Figure 2 for details of timing. Refer to Table 3 for VOD linearity
range and DC gain options.
MODE. This pin is for selecting different modes of operation. The state of this
pin is sampled after the rising edge of EN. Refer to Figure 2 for details of
timing.
0 = Test Mode. TI Internal Use Only.
R = PCIe / Test Mode. PCIe Mode and TI Internal use only
F = USB3.1 Dual Channel Operation enabled (TUSB1002 normal mode).
1 = USB3.1 Single-channel operation.
MODE
7
I (4-level)
RSVD1
24
O
SLP_S0#
DESCRIPTION
PU (approx 45 K)
PD (approx 95K)
RSVD1. Under normal operation, this pin will be driven low by TUSB1002.
Recommend leaving this pin unconnected on PCB.
PU (approx 400 K)
SLP_S0#. This pin when asserted low will disable Receiver Detect functionality.
While this pin low and TUSB1002 is in U2/U3, TUSB1002 disables LOS and
LFPS detection circuitry and Rx termination for both channels will remain
enabled. If this pin is low and TUSB1002 is in Disconnect state, the Rx detect
functionality is disabled and Rx termination for both channels will be disabled. If
the system SoC does not support a GPIO that indicates system sleep state,
then it is recommended to leave this pin unconnected.
0 – Rx Detect disabled
1 – Rx Detect enabled
14
I (2-level)
VCC
1, 13
Power
3.3 V (±10%) Supply.
GND
6, 10, 18,
21
GND
Ground
NC
No Connect. Leave unconnected on PCB.
Thermal pad
Thermal pad. Recommend connecting to a solid ground plane.
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TUSB1002
SLLSEU4E – MAY 2016 – REVISED MAY 2019
www.ti.com
6 Specifications
6.1 Absolute Maximum Ratings
over operating free-air temperature range (unless otherwise noted) (1)
Supply Voltage Range (2), VCC
MIN
MAX
UNIT
–0.3
4
V
±2.5
V
V
Differential Voltage between RX1P/N and
RX2P/N.
IO Voltage Range
Voltage at RX1P/N and RX2P/N.
–0.5
VCC + 0.5
Voltage on Control IO pins
–0.5
VCC + 0.5
V
105
°C
150
°C
Maximum junction temperature, TJ
Storage temperature, Tstg
(1)
(2)
–65
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.
All voltage values are with respect to the GND terminal.
6.2 ESD Ratings
VALUE
V(ESD)
(1)
(2)
Electrostatic discharge
Human-body model (HBM), per ANSI/ESDA/JEDEC JS-001 (1)
±6000
Charged-device model (CDM), per JEDEC specification JESD22-C101
or ANSI/ESDA/JEDEC JS-002 (2)
±1500
UNIT
V
JEDEC document JEP155 states that 500-V HBM allows safe manufacturing with a standard ESD control process. .
JEDEC document JEP157 states that 250-V CDM allows safe manufacturing with a standard ESD control process.
6.3 Recommended Operating Conditions
over operating free-air temperature range (unless otherwise noted)
3.3 V Supply Voltage
VCC
MIN
NOM
MAX
3
3.3
3.6
UNIT
V
Supply Ramp requirement
50
ms
V(PSN)
Supply Noise on VCC pins
100
mV
TA
Operating free-air temperature
70
°C
0
6.4 Thermal Information
TUSB1002
THERMAL METRIC
(1)
RGE (VQFN)
UNIT
24 PINS
RθJA
Junction-to-ambient thermal resistance
38.5
°C/W
RθJC(top)
Junction-to-case (top) thermal resistance
41.6
°C/W
RθJB
Junction-to-board thermal resistance
16.3
°C/W
ψJT
Junction-to-top characterization parameter
1.0
°C/W
ψJB
Junction-to-board characterization parameter
16.4
°C/W
RθJC(bot)
Junction-to-case (bottom) thermal resistance
6.9
°C/W
(1)
6
For more information about traditional and new thermal metrics, see the Semiconductor and IC Package Thermal Metrics application
report.
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SLLSEU4E – MAY 2016 – REVISED MAY 2019
6.5 Electrical Characteristics, Power Supply
over operating free-air temperature range (unless otherwise noted)
PARAMETER
TEST CONDITIONS
MIN
TYP
MAX
UNIT
P(U0_SSP_1200mV)
TUSB1002 power under normal operation
in U0 operating a SuperSpeedPlus
datarate with linear range set to 1200mV.
At 10 Gbps; VCC supply stable; VCC = 3.3
V; VOD = 1200 mVpp; Pattern = CP9
340
mW
P(U0_SSP_1000mV)
TUSB1002 power under normal operation
in U0 operating a SuperSpeedPlus
datarate with linear range set to 1000mV.
At 10 Gbps; VCC supply stable; VCC = 3.3
V; VOD = 1000 mVpp; Pattern = CP9
325
mW
P(U0_SSP_900mV)
TUSB1002 power under normal operation
in U0 operating a SuperSpeedPlus
datarate with linear range set to 900mV.
At 10 Gbps; VCC supply stable; VCC = 3.3
V; VOD = 900 mVpp; Pattern = CP9
298
mW
P(U0_SS_1200mV)
TUSB1002 power under normal operation
in U0 operating a SuperSpeed datarate.
At 5 Gbps; VCC supply stable; VCC = 3.3 V;
VOD = 1200 mVpp; Pattern = CP0.
340
mW
P(U1)
TUSB1002 power when U1.
In U1; VCC supply stable; VCC = 3.3 V;
VOD = 1200 mVpp
340
mW
P(U2U3)
TUSB1002 power when in U2/U3.
Both channels 1 and 2 in U2/U3; VCC
supply stable; VCC = 3.3 V;
8
mW
P(U2U3_SLP)
TUSB1002 power when in U2/U3 and
SLP_S0# is low.
Both channels 1 and 2 in U2/U3; VCC
supply stable; VCC = 3.3 V;
0.850
mW
TUSB1002 power when no USB device
detected on both TX1P/N or TX2P/N.
RX1 and RX2 termination disabled; VCC
supply stable; VCC = 3.3 V
2
mW
TUSB1002 power when a USB device
detected on either TX1P/N or TX2P/N but
not both.
Either RX1 or RX2 termination enabled
both not both enabled; VCC supply stable;
VCC = 3.3 V
5
mW
P(DISCONNECT_SLP)
TUSB1002 power when no USB device
detected on either TX1P/N or TX2P/N and
SLP_S0# is low..
RX1 and RX2 termination disabled; VCC
supply stable; VCC = 3.3 V
0.850
mW
P(SHUTDOWN)
TUSB1002 power when EN is asserted
low.;
VCC supply stable; VCC = 3.3 V, EN = 0
0.6
mW
P(DISCONNECT_NON
E)
P(DISCONNECT_ONE
)
6.6 Electrical Characteristics
over operating free-air temperature range (unless otherwise noted)
PARAMETER
TEST CONDITIONS
MIN
TYP
MAX
UNIT
4-Level Inputs (MODE, CFG1, CFG2,CH1_EQ1, CH1_EQ2, CH2_EQ1, CH2_EQ2 )
IIH
High level input current
VCC = 3.6 V; VIN = 3.6 V
IIL
Low level input current
VCC = 3.6 V; VIN = 0 V
VTH
Threshold 0 / R
Threshold R/ Float
20
80
μA
–160
–40
μA
VCC = 3.3 V
0.55
V
1.65
V
Threshold Float / 1
2.8
V
RPU
Internal pull-up resistance
45
kΩ
RPD
Internal pull-down resistance
95
kΩ
EN, SLP_S0# Input
VIH
High level input voltage
VCC = 3. V
VIL
Low level input voltage
VCC = 3.3 V
1.7
VCC
0
0.7
IIH
High level input current
IIL
Low level input current
R(EN-PU)
Internal pull-up resistance for EN and
SLP_S0#.
V
V
VCC = 3.6 V, EN = 3.6 V
–10
10
µA
VCC = 3.6 V, EN = 0 V
–15
15
µA
400
kΩ
SDD11 10 MHz at 90 Ω
–19
dB
SDD11 2 GHz at 90 Ω
–14
dB
–7
dB
–10
dB
-50
dB
16
dB
-0.15
dB
USB3.1 RECEIVER INTERFACE (RX1P/N AND RX2P/N)
RL(RX-DIFF)
RX Differential return loss
SDD11 5 – 10 GHz at 90 Ω
0.5 – 5 GHz at 90 Ω
RL(RX-CM)
RX Common mode return loss
X-TALK
Differential crosstalk between TX and
RX signal pairs.
EQ(GAIN-10Gbps)
Equalization Gain
50 mVpp At 5 GHz
DC Equalization Gain at 0dB setting.
500 mVpp VID at 100 MHz; 1200mV
Linear Range Setting; Refer to Table 3
EQ(DC0)
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Electrical Characteristics (continued)
over operating free-air temperature range (unless otherwise noted)
PARAMETER
TEST CONDITIONS
MIN
TYP
MAX
UNIT
EQ(DC1)
DC Equalization Gain at +1dB setting.
500 mVpp VID at 100 MHz; 1200mV
Linear Range Setting;
EQ(DC2)
DC Equalization Gain at +2dB setting.
500 mVpp VID at 100 MHz; 1000mV
Linear Range Setting;
1.5
dB
EQ(DC-1)
DC Equalization Gain at -1dB setting.
500 mVpp VID at 100 MHz; 1200mV
Linear Range Setting;
–1.1
dB
EQ(DC-2)
DC Equalization Gain at -2dB setting.
500 mVpp VID at 100 MHz; 1200mV
Linear Range Setting;
–2.05
dB
V(DIFF_IN)
Input differential peak-peak voltage
swing range.
2000
mV
V(RX-DC-CM)
RX DC common mode voltage
R(RX-CM-DC)
Measured at connector. Present when
Receiver DC common mode impedance SuperSpeed USB device detected on
TXP/N
R(RX-DIFF-DC)
Receiver DC differential impedance
Z(RX-HIGH-IMP-DC-
dB
2.0
V
18
30
Ω
Measured at connector. Present when
SuperSpeed USB device detected on
TXP/N; SLP_S0# = 1;
72
120
Ω
DC input CM input impedance when
termination is disabled.
Measured at connector. Present when
no SuperSpeed USB device detected
on TXP/N or while VCC is ramping
30
Input differential peak-to-peak Signal
Detect Assert level
at 10 Gbps. No loss input channel and
PRBS7 pattern
92
mV
V(RX-IDLE_DET_DIFF- Input differential peak-to-peak Signal
Detect De-assert Level
PP)
at 10 Gbps. No loss input channel and
PRBS7 pattern
62
mV
V(RX-LFPS-DET-DIFF- LFPS Detect threshold. Below min is
noise.
P-P)
Measured at connector. Below min is
squelched
V(RX-CM-AC-P)
Peak RX AC common mode voltage
C(RX-PARASITIC)
Rx Input capacitance for return loss
POS)
V(RXSIGNAL_DET_DIFF-
1.65
0.80
1.85
KΩ
PP)
100
300
mV
Measured at package pin
150
mV
At package pin
0.5
pF
USB3.1 Transmitter Interface (TX1P/N and TX2P/N)
SDD22 10MHz – 2 GHz at 90 Ω
–15
dB
SDD22 5 GHz at 90 Ω
–11
dB
SDD22 5 - 10 GHz at 90 Ω
–7
dB
TX Common Mode return loss
0.05 – 5 GHz at 90 Ω
–9
dB
V(TX-DIFF-PP_1200)
Differential peak-to-peak TX voltage
swing linear dynamic range
CFG1 pin = F or 1; Refer to Table 3
Measured at -1dB compression point =
20log (VOD/VOD_linear)
1200
1450
mV
V(TX-DIFF-PP_1000)
Differential peak-to-peak TX voltage
swing linear dynamic range
CFG1 pin = R; Refer to Table 3
Measured at -1dB compression point =
20log (VOD/VOD_linear)
1000
mV
V(TX-DIFF-PP_900)
Differential peak-to-peak TX voltage
swing linear dynamic range
CFG1 pin = 0; Refer to
Table 3Measured at -1dB compression
point = 20log (VOD/VOD_linear)
900
mV
V(TX-RCV-DETECT)
The amount of voltage change allowed
during Receiver Detection.
RL(TX-DIFF)
RL(TX-CM)
TX Differential return loss
Transmitter idle common-mode voltage
V(TX-CM-IDLE-DELTA) change while in U2/3 and not actively
transmitting LFPS.
–600
V(TX-DC-CM)
TX DC common mode voltage
1200mVpp Linear Range setting.
0
V(TX-IDLE-DIFF-AC-
AC Electrical Idle differential peak-topeak output voltage
At package pin.
V(TX-IDLE-DIFF_DC)
DC Electrical Idle differential output
voltage
At package pin. After low pass filter to
remove AC component.
V(TX-CM-AC-PP)
Transmitter AC common mode peakpeak voltage in U0
1200mVpp linear range; CHx_EQ
setting matches input channel insertion
loss;
Absolute DC common mode voltage
between U1 and U0.
At package pin.
IDLE-DELTA)
I(TX-SHORT)
TX short-circuit current limit
R(TX-DC)
TX DC common mode impedance
PP)
V(TX-CM-DC-ACTIVE-
8
At package pin
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mV
600
mV
2
V
0
10
mV
0
14
mV
80
mV
200
mV
106
mA
30
Ω
18
1.85
600
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Electrical Characteristics (continued)
over operating free-air temperature range (unless otherwise noted)
PARAMETER
TEST CONDITIONS
R(TX-DIFF-DC)
TX DC differential impedance
C(TX-PARASTIC)
TX input capacitance for return loss
C(AC-COUPLING)
External AC Coupling capacitor on
differential pairs.
MIN
TYP
MAX
72
90
120
Ω
0.7
pF
265
nF
At package pin
75
UNIT
6.7 Power-Up Requirements
over operating free-air temperature range (unless otherwise noted)
PARAMETER
MIN
MAX
UNIT
td_pg
Internal Power Good asserted high when VCC
is at 2.5 V
See Figure 2
tcfg_su
CFG (1) pins setup before internal Reset (2) high
See Figure 2
0
s
tcfg_hd
CFG (1) pins hold after internal Reset (2) high
See Figure 2
500
µs
tVCC_RAMP
VCC supply ramp requirement
See Figure 2
(1)
(2)
µs
5
50
ms
Following pins comprise CFG pins: MODE, CFG1, CFG2, CH1_EQ1, CH1_EQ2, CH2_EQ1, and CH2_EQ2.
Internal reset is the AND of EN pin and internal Power Good.
6.8 Timing Requirements
MIN
NOM
MAX
UNIT
SuperSpeed (SS) and SuperSpeedPlus(SSP)
tIDLEEntry
Delay from U0 to electrical idle.
See Figure 1
150
ps
tIDLEExit_U1
U1 exit time: break in electrical idle to the
transmission of LFPS.
See Figure 1
150
ps
tIDLEExit_U2U3
U2/U3 exit time: break in electrical idle to
transmission of LFPS
See Figure 1
3.75
µs
tDIFF-DLY
Differential propagation delay
150
ps
tPWRUPACTIVE
Time when VCC reach 2.5 V to device
active and performing Rx.Detect.
7
ms
2.3
EN = H
6.9 Switching Characteristics
over operating free-air temperature range (unless otherwise noted)
PARAMETER
TEST CONDITIONS
MIN
TYP
MAX
UNIT
USB3.1 Transmitter Interface (TX1P/N, TX2P/N)
tTX-RISE-FALL
Transmitter rise/fall time
20% to 80% of differential output;
1200mVpp linear range setting
40
ps
tRF-MISMATCH
Transmitter rise/fall mismatch
20% to 80% of differential output;
1200mVpp linear range setting;
1000mVpp VID;
0.01
UI
tTX-DJ
Residual deterministic jitter
@10Gbps; 1200mVpp Linear
Range Setting
0.08
UI
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SSRXP
VCM
VRX-LFPS-DET-DiFF-PP
SSRXN
TIDLEENTRY
TIDLEEXIT
SSTXP
VCM
SSTXN
Figure 1. Idle Entry and Exit Latency
VCC
Td_pg
Internal Power
Good
Tcfg_su
Internal
Reset
EN pin
Tcfg_hd
CFG pins
Figure 2. Power-Up Diagram
10
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6.10 Typical Characteristics
VCC = 3.3V , 25°C, 200 mVpp VID sine wave, ZO = 100 Ω, RGE package
20
20
EQ1_DC0_1200mV
EQ3_DC0_1200mV
EQ5_DC0_1200mV
EQ7_DC0_1200mV
EQ9_DC0_1200mV
EQ11_DC0_1200mV
EQ13_DC0_1200mV
10
15
SDD21 (dB)
SDD21 (dB)
15
5
0
10
5
0
-5
0.01
0.1
1
Frequency (GHz)
-5
0.01
10
0.1
D001
Figure 3. 1200 mV DC0 Gain Odd EQ Settings Curves
1
Frequency (GHz)
10
D002
Figure 4. 1200 mV DC0 Even EQ Settings Curves
20
10
EQ1_DC0_1200mV
EQ1_DC1_1200mV
EQ1_DC-1_1200mV
EQ1_DC-2_1200mV
EQ1_DC0_1000mV
EQ3_DC0_1000mV
EQ5_DC0_1000mV
EQ7_DC0_1000mV
EQ9_DC0_1000mV
EQ11_DC0_1000mV
EQ13_DC0_1000mV
15
5
SDD21 (dB)
SDD21 (dB)
EQ2_DC0_1200mV
EQ4_DC0_1200mV
EQ6_DC0_1200mV
EQ8_DC0_1200mV
EQ10_DC0_1200mV
EQ12_DC0_1200mV
EQ14_DC0_1200mV
10
5
0
0
-5
0.01
0.1
1
Frequency (GHz)
-5
0.01
10
Figure 5. 1200 mV DC Gain Adjustments Curves
10
D004
Figure 6. 1000 mV DC0 Gain Odd EQ Settings Curves
EQ2_DC0_1000mV
EQ4_DC0_1000mV
EQ6_DC0_1000mV
EQ10_DC0_1000mV
EQ12_DC0_1000mV
EQ1_DC0_1000mV
EQ1_DC2_1000mV
EQ1_DC-1_1000mV
SDD21 (dB)
SDD21 (dB)
1
Frequency (GHz)
10
20
15
0.1
D003
10
5
5
0
0
-5
0.01
0.1
1
Frequency (GHz)
-5
0.01
10
D005
Figure 7. 1000 mV DC0 Gain Even EQ Settings Curves
0.1
1
Frequency (GHz)
10
D006
Figure 8. 1000 mV DC Gain Adjustments Curves
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Typical Characteristics (continued)
VCC = 3.3V , 25°C, 200 mVpp VID sine wave, ZO = 100 Ω, RGE package
20
20
EQ1_DC0_900mV
EQ3_DC0_900mV
EQ5_DC0_900mV
EQ7_DC0_900mV
EQ9_DC0_900mV
EQ11_DC0_900mV
EQ13_DC0_900mV
10
15
SDD21 (dB)
SDD21 (dB)
15
EQ2_DC0_900mV
EQ4_DC0_900mV
EQ6_DC0_900mV
EQ8_DC0_900mV
EQ10_DC0_900mV
EQ12_DC0_900mV
EQ14_DC0_900mV
5
0
10
5
0
-5
0.01
0.1
1
Frequency (GHz)
-5
0.01
10
0.1
D007
Figure 9. 900 mV DC0 Gain Odd EQ Settings Curves
1
Frequency (GHz)
10
D007
Figure 10. 900 mV DC0 Gain Even EQ Settings Curves
0
10
EQ1_DC0_900mV
EQ1_DC1_900mV
-5
SDD11 (dB)
SDD21 (dB)
-10
5
0
-15
-20
-25
-30
-35
-5
0.01
0.1
1
Frequency (GHz)
-40
0.01
10
-5
1.4
-10
1.2
-15
1
-20
10
D012
0.8
-25
0.6
-30
0.4
-35
0.2
DC0_EQ1_900mV
DC0_EQ1_1000mV
DC0_EQ1_1200mV
0
0.1
1
Frequency (GHz)
10
0
0.5
1
VID (V)
D013
Figure 13. SDD22 Return Loss
12
1
Frequency (GHz)
Figure 12. SDD11 Return Loss
1.6
VOD (V)
SDD22 (dB)
Figure 11. 900 mV DC Gain Adjustment Curves
0
-40
0.01
0.1
D009
1.5
D010
Figure 14. 5-GHz Sine Wave VID vs VOD Linearity Range
Setting
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Typical Characteristics (continued)
VCC = 3.3V , 25°C, 200 mVpp VID sine wave, ZO = 100 Ω, RGE package
1.4
1.2
VOD (V)
1
0.8
0.6
0.4
DC0_EQ1_900mV
DC0_EQ1_1000mV
DC0_EQ1_1200mV
0.2
0
0
0.5
1
VID (V)
1.5
D011
Figure 15. 100-MHz Sine Wave VID vs VOD Linearity Range Setting
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7 Detailed Description
7.1 Overview
The TUSB1002 is the industry’s first, dual lane USB 3.1 SuperSpeedPlus redriver. As signals traverse through a
channel (like FR4 trace) the amplitude of the signal is attenuated. The attenuation varies depending on the
frequency content of the signal. Depending the length of the channel this attenuation could be large enough
resulting in signal integrity issues at a USB 3.1 receiver. By placing a TUSB1002 between USB3.1 host and
device the attenuation effect of the channel can eliminated or minimized. The result is a USB3.1 compatible eye
at the devices receiver. With up to 16 receiver equalization settings, the TUSB1002 can support many different
channel loss combinations. The TUSB1002 offers low power consumption on a single 3.3 V supply with its ultra
low power architecture. It supports the USB3.1 low power modes which further reduces idle power consumption.
The TUSB1002 settings are configured through pins. In addition to equalization adjustment, the TUSB1002
provides knobs for adjusting DC gain and voltage output linearity range.
7.2 Functional Block Diagram
3.3V (+/-10%)
VCC
2.5V
Power
Management
1.2V
PG
GND
VCC
400K
EN
Vterm
50
50
VIterm
RXTERM_EN
TX1P
RX1P
TX
RX
RX1N
LFPS
LOS
TXEN1
IDLE1
RXDET1
LFPS1
LOSZ1
TX1N
Rx
Detect
LFPS1
LOSZ1
MODE
CFG1
SLP_S0#
CFG2
Digital FSM
CH1_EQ1
RSVD1
CH1_EQ2
LFPS2
LOSZ2
CH2_EQ1
CH2_EQ2
Vterm
VIterm
50
50
RXTERM_EN
TX2P
RX2P
TX
RX
RX2N
TX2N
Rx
Detect
TXEN2
IDLE2
RXDET2
LFPS2
LFPS
LOSZ2
LOS
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7.3 Feature Description
7.3.1 4-Level Control Inputs
The TUSB1002 has (MODE, CFG1, CFG2, CH1_EQ1, CH1_EQ2, CH2_EQ1, and CH2_EQ2) 4-level inputs pins
that are used to control the equalization gain and the output voltage swing dynamic range. These 4-level inputs
use a resistor divider to help set the 4 valid levels and provide a wider range of control settings. There is an
internal 45 kΩ pull-up and a 95 kΩ pull-down. These resistors, together with the external resistor connection
combine to achieve the desired voltage level.
Table 1. 4-Level Control Pin Settings
LEVEL
SETTINGS
0
Option 1: Tie 1 KΩ 5% to GND.
Option 2: Tie directly to GND.
R
Tie 20 KΩ 5% to GND.
F
Float (leave pin open)
1
Option 1: Tie 1 KΩ 5% to VCC.
Option 2: Tie directly to VCC.
NOTE
In order to conserve power, the TUSB1002 disables 4-level input’s internal pull-up/pulldown resistors after the state of 4-level pins have been sampled on rising edge of EN. A
change of state for any four level input pin is not applied to TUSB1002 until after EN pin
transitions from low to high.
7.3.2 Linear Equalization
With a linear equalizer, the TUSB1002 can electrically shorten a particular channel allowing for longer run
lengths.
Figure 16. Linear Equalizer
With a TUSB1002, the 28 in trace can be made to have similar insertion loss as the 12 inch trace.
The receiver equalization level for each channel is determined by the state of the CHx_EQ1 and CHx_EQ2 pins,
where x = 1 or 2.
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Table 2. EQ Configuration Options for 1200mV Linearity 0 dB DC Gain Setting
EQ SETTING #
CHx_EQ2 PIN LEVEL
CHx_EQ1 PIN LEVEL
EQ GAIN at 2.5GHz / 5
GHz (dB)
1
0
0
1.9 / 5.5
2
0
R
2.8 / 7.1
3
0
F
3.5 / 8.2
4
0
1
4.4 / 9.3
5
R
0
5.0 / 10.2
6
R
R
5.8 / 11.1
7
R
F
6.4 / 11.8
8
R
1
7.1 / 12.6
9
F
0
7.6 / 13.1
10
F
R
8.2 / 13.8
11
F
F
8.7 / 14.3
12
F
1
9.2 / 14.8
13
1
0
9.6 / 15.2
14
1
R
10.1 / 15.6
15
1
F
10.4 / 16.0
16
1
1
10.6 / 16.3
7.3.3 Adjustable VOD Linear Range and DC Gain
The CFG1 and CFG2 pins can be used to adjust the TUSB1002 output voltage swing linear range and receiver
equalization DC gain. Table 3 details the available options.
For best performance, the TUSB1002 should be operated within its defined VOD linearity range. The gain of the
incoming VID should be kept to less than or equal to the TUSB1002 VOD linear range setting. The can be
determined by Equation 1:
VID at 5 GHz = VOD x (10 -(Gv/20))
where
•
Gv = TUSB1002 Gain and VOD = TUSB100 VOD linearity setting.
(1)
For example, for a VOD linearity range setting of 1200 mV, the maximum incoming VID signal at 5 GHz with a
CHx_EQ[1:0] setting of 1 (5.5 dB) is 1200 x (10 -(5.5/20)) = 637 mVpp. The TUSB1002 can be operated outside its
VOD linear range but jitter will be higher.
Table 3. VOD Linear Range and DC Gain
16
CH2 DC GAIN (dB)
CH1 VOD LINEAR
RANGE (mVpp)
CH2 VOD LINEAR
RANGE (mVpp)
+1
0
900
900
0
+1
900
900
F
0
0
900
900
0
1
+1
+1
900
900
5
R
0
0
0
1000
1000
6
R
R
+1
0
1000
1000
7
R
F
0
-1
1000
1000
8
R
1
+2
+2
1000
1000
9
F
0
-1
-1
1200
1200
10
F
R
-2
-2
1200
1200
11
F
F
0
0
1200
1200
12
F
1
+1
+1
1200
1200
13
1
0
-1
0
1200
1200
14
1
R
0
-1
1200
1200
15
1
F
0
+1
1200
1200
16
1
1
+1
0
1200
1200
SETTING #
CFG1 PIN LEVEL
CFG2 PIN LEVEL
CH1 DC GAIN (dB)
1
2
0
0
0
R
3
0
4
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7.3.4 Receiver Detect Control
The SLP_S0# pin offers system designers the ability to control the TUSB1002 Rx.Detect functionality during
Disconnect and U2/U3 states and therefore achieving lower consumption in these states. When the system is in
a low power state (Sx where x = 1, 2, 3, 4, or 5), system can assert SLP_S0# low to disable TUSB1002 receiver
detect functionality. While SLP_S0# is asserted low and USB 3.1 interface is in U3, the TUSB1002 keeps
receiver termination active. The TUSB1002 will not respond to any LFPS signaling while in this state. This means
that system wake from U3 is not supported while SLP_S0# is asserted low. If the TUSB1002 is in Disconnect
state when SLP_S0# is asserted low, then TUSB1002 disables both channels receiver termination. When
SLP_S0# is asserted high, the TUSB1002 resumes normal operation of performing far-end receiver termination
detection.
7.3.5 USB3.1 Dual Channel Operation (MODE = “F”)
The TUSB1002 in dual-channel operation waits for far-end terminations on both channels 1 and 2 before
transitioning to fully active state (U0 mode). This mode of operation, defined as MODE pin = ‘F’, is the most
common configuration for USB3.1 Source (DFP) and Sink (UFP) applications.
7.3.6 USB3.1 Single Channel Operation (MODE = “1”)
In some applications, like Type-C USB3.1 active cables, only one of the two channels may be active. For this
application, setting MODE pin = ‘1’, enables single-channel operation. In this mode of operation, the TUSB1002
attempts far-end termination on both channels 1 and 2. The channel which has a far-end termination detected
will be enabled while the remaining channel will be disabled. If far-end termination is detected on both channels,
then TUSB1002 behaves in dual channel operation (both channels enabled).
7.3.7 PCIe/SATA/SATA Express Redriver Operation (MODE = “R”; CFG1 = "0"; CFG2 = "0" )
The TUSB1002 can be used as a PCI Express (PCIe) Gen3, SATA Gen3, or SATA Express redriver. When
TUSB1002's MODE pin = “R”, CFG1 pin = "0", and CFG2 pin = "0", the TUSB1002 will enable both channels
(upstream and downstream) receiver and transmitter paths upon detecting far-end termination on both TX1 and
TX2. Both upstream and downstream paths will remain enabled until EN pin is de-asserted low. All USB3.1
power management functionality is disabled in this mode. In this mode the TUSB1002 is transparent to PCIe link
power management (L0s, L1) and SATA interface power states. Once far-end termination is detected on both
TX1 and TX2, the TUSB1002 power will be at P(U0_SSP_1200mV) regardless of the PCIe or SATA power state. To
save power during system S3/S4/S5 states it is suggested to de-assert the EN pin to conserve power.
7.4 Device Functional Modes
7.4.1 Shutdown Mode
The Shutdown mode is entered when EN pin is low and VCC is active and stable. This mode is the lowest power
state of the TUSB1002. While in this mode, the TUSB1002 receiver terminations is disabled.
7.4.2 Disconnect Mode
Next to Shutdown Mode, the Disconnect mode is the lowest power state of the TUSB1002. The TUSB1002
enters this mode when exiting Shutdown mode. In this state, the TUSB1002 periodically checks for far-end
receiver termination on both SSTX1 and SSTX2. Upon detection of the far-end receiver’s termination on both
ports, the TUSB1002 transitions to a fully active mode called U0 mode.
When SLP_S0# is asserted low and the TUSB1002 is in Disconnect mode, the TUSB1002 remains in
Disconnect mode and never perform far-end receiver detection. This allows even lower TUSB1002 power
consumption while in the Disconnect mode. Once SLP_S0# is asserted high, the TUSB1002 again starts
performing far-end receiver detection so it can know when to exit the Disconnect mode.
7.5 U0 Mode
The U0 mode is the highest power state of the TUSB1002. Anytime high-speed traffic (SuperSpeed or
SuperSpeedPlus) is being received, the TUSB1002 remains in this mode. The TUSB1002 only exits this mode if
electrical idle is detected on both SSRX1 and SSRX2. While in this mode, the TUSB1002 hs speed receivers
and transmitters are powered and active.
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7.6 U1 Mode
The U1 mode is the intermediate mode between U0 mode and U2/U3 mode. In U1 mode, the TUSB1002’s
receiver termination remains enabled and the TXP/N DC common mode is maintained.
7.7 U2/U3 Mode
Next to the disconnect mode, the U2/U3 mode is next lowest power state. While in this mode, the TUSB1002
periodically performs far-end receiver detection. Anytime the far-end receiver termination is not detected on
either CH1 or CH2, the TUSB1002 leaves the U2/U3 mode and transition to the Disconnect mode. It also
monitors the SSRX1 and SSRX2 for a valid LFPS. Upon detection of a valid LFPS, the TUSB1002 immediately
transitions to the U0 mode.
When SLP_S0# is asserted low and the TUSB1002 is in U2/U3 mode, the TUSB1002 remains in U2/U3 state
and never perform far-end receiver detection. While in this state, the TUSB1002 ignores LFPS signaling. This
allows even lower TUSB1002 power consumption while in the U2/U3 mode. Once SLP_S0# is asserted high, the
TUSB1002 again starts performing far-end receive as well as monitor LFPS so it can know when to exit the
U2/U3 mode.
18
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8 Application and Implementation
NOTE
Information in the following applications sections is not part of the TI component
specification, and TI does not warrant its accuracy or completeness. TI’s customers are
responsible for determining suitability of components for their purposes. Customers should
validate and test their design implementation to confirm system functionality.
8.1 Application Information
The TUSB1002 is a linear redriver designed specifically to compensation for ISI jitter caused by attenuation
through a passive medium like traces and cables. Because the TUSB1002 has two independent channels, it can
be optimized to correct ISI in both the upstream and downstream direction through 16 different equalization
choices. Placing the TUSB1002 between a USB3.1 Host/device controller and a USB3.1 receptacle can correct
signal integrity issues resulting in a more robust system.
8.2 Typical USB3.1 Application
Downstream
FR4 Trace
of Length X
C
+
USB 3.1
Host
B
RXN1
C
TXP2
+
-
RXP1
C
C
C
FR4 Trace
of Length Y
+
+
TXP1
C
-
-
TXN1
C
RXP2
C
RXN2
C
TUSB1002
TXN2
+
+
-
-
D
USB 3.1
Receptacle
A
Upstream
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Figure 17. TUSB1002 in USB3.1 Host Application
8.2.1 Design Requirements
For this design example, use the parameters shown in Table 4.
Table 4. Design Parameters
PARAMETER
VALUE
VCC supply (3 V to 3.6 V)
3.3 V
Mode of Operation (Dual or Half Channel)
MODE = F (Floating) for USB3.1 Dual Channel
TX1, TX2, RX1 A/C coupling Capacitor (75 nF to 265 nF)
100 nF
RX2 A/C coupling Capacitor (297 nF to 363 nF)
Suggest 330 nF ±10%
RX2 pull-down resistors on USB receptacle side of AC capacitor
(200K to 242K ohms)
220k
A to B FR4 Length (inches)
8
A to B FR4 Trace Width (mils)
4
C to D FR4 length (inches)
2
C to D FR4 Trace Width (mils)
4
USB3.1 Host Sleep GPIO Support
No (SLP_S0# pin floating)
DC Gain (-2, -1, 0, +1, +2)
0 dB (CFG[2:1] pins floating)
Linear Range (900 mV, 1000 mV, or 1200 mV)
1200 mV (CFG[2:1] pins floating)
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8.2.2 Detailed Design Procedure
The TUSB1002 differential receivers and transmitters have internal BIAS and termination. For this reason, the
TUSB1002 must be connected to the USB3.1 host and receptacle through external A/C coupling capacitors. In
this example as depicted in Table 4, 100 nF capacitors are placed on TX2P and TX2N, RX1P and RX1N, and
TX1P and TX1N. 330 nF A/C coupling capacitors along with 220k resistors are placed on the RX2P and RX2N.
Inclusion of these 330nF capacitors and 220k resistors is optional but highly recommended. If not implemented,
then RX2P/N should be DC-coupled to the USB receptacle.
CH2_EQ2
CH2_EQ1
USB_VBUS
CFG2
C3
SSTXN 8
5
9
SSTXP
C5
100nF
100nF
SHIELD0 10
SHIELD1 11
R15
220k
R16
220k
TX1P
TX1N
RSVD1
GND
VCC
13
14
CFG2
SLP_S0#
15
TUSB1002
24-PIN RGE
22
23
9
8
24
7
C1
C2
C4
RX1P
C6
RX1N
MODE
2
3
4
5
100nF
100nF
VCC_3P3V
1
100nF
100nF
GND
25
VCC_3P3V
R1
1M
16
10
USB3_TYPEA_CONNECTER
C8
0.001uF
HOST_DP
6
GND
330nF
EN
330nF
CFG1
C13
HOST_DM
12 TX2P
11 TX2N
CH1_EQ2
SSRXP 6
GND 7
VCC_3P3V
RX2P 19
RX2N 20
GND 21
CH1_EQ1
C12
VCC
SSRXN
C7
100nF
CH2_EQ2
18
U1
CH2_EQ1
DP 3
GND 4
17
VBUS 1
DM 2
GND
J1
HOST_RXP
HOST_RXN
CONNECT TO
USB3.1 HOST
HOST_TXP
HOST_TXN
VCC_3P3V
R2
DNI
C9
10uF
C10
100nF
C11
100nF
CFG1
CH1_EQ2
CH1_EQ1
Copyright © 2016, Texas Instruments Incorporated
Figure 18. Host Implementation Schematic
The USB3.1 Dual channel operation is used in this example. Mode pin should be left floating (unconnected)
when using this mode.
In this example, the USB3.1 Host does not support a GPIO for indicating system Sx state or low power states
and therefore the SLP_S0# pin can be left floating.
The TUSB1002 compensates for channel loss in both the upstream (D to C) and downstream direction (A to B).
This is done by configuring the CH1_EQ[2:1] and CH2_EQ[2:1] pins to the equalization setting that matches as
close possible to the channel insertion loss. In this particular example, CH1_EQ[2:1] is for path A to B which is
the channel between USB3.1 host and the TUSB1002, and CH2_EQ[2:1] is for path C to D which is the channel
between TUSB1002 and the USB3.1 receptacle.
The TUSB1002 supports 5 levels of DC gain that are selected by the CFG[2:1] pins. Typically, the DC gain
should be set to 0 dB but may need to be adjusted to correct any one of the following conditions:
1. Input VID too high resulting in VOD being greater than USB 3.1 defined swing. For this case, a negative DC
gain should be used.
2. Input VID too low resulting in VOD being less than USB 3.1 defined swing. For this case, a positive DC gain
should be used.
3. Low frequency discontinuities in the channel resulting in DC component of the signal clipping the vertical eye
mask. For this case, a positive DC gain should be used.
It is assumed in this example the incoming VID is at the nominal defined USB3.1 range and the channel is linear
across frequency. The CFG1 and CFG2 pins can both be left floating if these assumptions are true.
20
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In this particular example, the channel A-B has a trace length of 8 inches with a 4 mil trace width. This particular
channel has about 0.83 dB per inch of insertion loss at 5 GHz. This equates to approximately 6.7 dB of loss for
the entire 8 inches of trace. An additional 1.5 dB of loss is added due to package of the USB3.1 Host,
TUSB1002, and the A/C coupling capacitor. This brings the entire channel loss at 5 GHz to 6.7 dB + 1.5 dB = 8.2
dB. A typical USB 3.1 host/device will have around 3 dB of transmitter de-emphasis. Transmitter de-emphasis
pre-compensates for the loss of the output channel. With 3 dB of de-emphasis, the total equalization required by
the TUSB1002 is in the 5.2 dB (8.2 dB - 3 dB) range. The channel A-B for this example is connected to
TUSB1002's RX1P/N input and therefore CH1_EQ[2:1] pins are used for adjusting TUSB1002 RX1P/N
equalization settings. The CH1_EQ[2:1] pins should be set such that TUSB1002 equalization is between 5dB
and 8dB.
The channel C-D has a trace length of 4 inches with a 4mil trace width. Assuming 0.83 dB per inch of insertion
loss, the 4 inch trace will equate to about 3.32 dB of loss at 5 GHz. An additional 2dB of loss needs to be added
due to package, A/C coupling capacitor, and the USB 3.1 receptacle. The total loss is around 5.32 dB. Because
channel C-D includes a USB 3.1 receptacle, the actual total loss could be much greater than 5.32dB due to the
fact that devices plugged into the receptacle will also have loss. The device plugged into receptacle will have
either a short or long channel. USB3.1 standard defines total loss limit of 23dB that is distributed as 8.5 dB for
Host, 8.5dB for device, and 6.0dB for cable. With variable channel of devices plugged into the USB3.1
receptacle, configuring TUSB1002's RX2P/N equalization settings is not as straight forward as Channel A-B.
Engineer can not set TUSB1002 CH2_EQ[2:1] pins to the largest equalization setting to accommodate the
largest allowed USB3.1 device/cable loss of 14.5 dB. Doing so will result in TUSB1002 operating outside its
linear range when a device with short channel is plugged into the receptacle. For this reason, it is recommended
to configure TUSB1002 CH2_EQ[2:1] pins to equalize a shorter device channel. This will result in requiring
USB3.1 host to compensate for remaining channel loss for the worse case USB3.1 channel of 14.5 dB. The
definition of a short device channel is not specified in USB 3.1 specification. Therefore, an engineer must make
their own loss estimate of what constitutes a short device channel. For particular example, we will assume the
short channel is around 3 to 5 dB. The device's channel loss will need to be added to estimated Channel C-D
loss minus the typical 3db of de-emphasis. This means CH2_EQ[2:1] pins should be configured to handle a loss
of 5 to 7 db.
8.2.3 Application Curves
0
-5
dB (SDD21)
-10
-15
-20
-25
-30
0
2
4
Freq = 5 GHz
6
8
10
12
Frequency (GHz)
14
16
18
20
D100
dB(SDD21) = –6.666
Figure 19. Insertion Loss for 8inch 4 mil FR4 Trace
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8.3 Typical SATA, PCIe and SATA Express Application
Downstream
A
B
C
TXP2
RXP2
SATA/PCIe/
SATA Express
Host
+
-
D
FR4 trace
of length Y
RXN2
miniCard / mSATA
socket
FR4 trace
of length X
+
-
+
-
TXN2
TUSB1002
RXP1
TXP1
+
-
+
-
TXN1
+
-
RXN1
Upstream
+
-
+
-
SATA/PCIe/
SATA Express
Device
Copyright © 2017, Texas Instruments Incorporated
Figure 20. SATA/PCIe/SATA Express Typical Application
8.3.1 Design Requirements
Table 5. Design Parameters
PARAMETER
VALUE
VCC supply (3 V to 3.6 V)
3.3 V
PCIe Support Required (Yes/No)
Yes
SATA Express Support Required (Yes/No)
Yes
SATA Support Required (Yes/No)
Yes, then ferrite beads (FB1 and FB2) and 49.9-ohm required.
No, then ferrite bead (FB1 and FB2) and 49.9-ohm not required.
TX1, TX2, RX2 A/C coupling Capacitor (176 nF to 265 nF)
220 nF ±10%
RX1 A/C coupling Capacitor (297 nF to 363 nF)
Optional. But if implemented suggest 330 nF ±10%
A to B FR4 Length (inches)
8
A to B FR4 Trace Width (mils)
4
C to D FR4 length (inches)
2
C to D FR4 Trace Width (mils)
4
USB3.1 Host Sleep GPIO Support
This feature not supported when MODE = "R", CFG1 = "0", and
CFG2 = "0".
DC Gain (-2, -1, 0, +1, +2)
Not configurable when MODE = "R", CFG1 = "0", and CFG2 = "0".
Will always default to 0 dB
Linear Range (900 mV, 1000 mV, or 1200 mV)
Not configurable when MODE = "R", CFG1 = "0", and CFG2 = "0".
Will always default to 1200mV
8.3.2 Detailed Design Procedure
The MODE pin = "R", CFG1 = "0", and CFG2 = "0" will place the TUSB1002 into PCIe mode. In this mode, the
TUSB1002 will have its DC gain fixed at 0dB and its linearity range fixed at 1200mV. The TUSB1002 will perform
far-end receiver termination detection and enable both upstream and downstream paths when far-end
termination is detected on both TX1 and TX2.
The AC coupling capacitor range defined for a SATA device is a lot smaller than the AC-coupling capacitor range
defined for SATA Express and PCI Express (PCIe) as indicated by Figure 21. The AC-coupling capacitor range
defined for SATA Express and PCI Express is within the same range as the AC-coupling capacitor range defined
by USB 3.1. The TUSB1002 will be able to detect PCIe and SATA Express device's receiver termination. But the
SATA's 12nF (max) AC-coupling capacitor will prevent TUSB1002 from detecting the SATA device's receiver
termination. To correct this problem, a ferrite bead along with 49.9 ohm resistor must be placed between CTX2
and miniCard/mSATA socket. These components can be isolated from the high-speed channel when PCIe or
22
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SATA Express is active by using an NFET as shown in Figure 22. The NFET should be enabled whenever a
SATA device is present. The ferrite bead chosen must present at least 600 ohms impedance at 100MHz so as to
not impact high-speed signalling. It is recommended to use Murata BLM03AG601SN1 or BLM03HD601SN1D or
a ferrite bead with similar characteristics from a different vendor. For applications which only require support for
PCIe and SATA Express and do not need to support SATA, the ferrite beads and 49.9 ohm resistors are not
needed.
12nF (max)
176nF t 265nF
+
-
+
-
+
-
SATA
Device
+
-
SATA
Express
Device
+
-
+
-
PCIe
Device
75nF t 265nF
Copyright © 2017, Texas Instruments Incorporated
Figure 21. AC-Coupling capacitor Implementation for SATA, SATA Express, and PCIe Devices
The TUSB1002's power will be at P(U0_SSP_1200mV) when both its upstream and downstream paths are enabled. In
order to save system power in system S3/S4/S5 states, it is suggested to control TUSB1002's EN pin. Anytime
the system enters a low power state (S3, S4, or S5), it is suggested to de-assert the EN pin. While EN pin is deasserted, the TUSB1002 will consume P(SHUTDOWN). Assertion of this pin is necessary anytime the system exits a
lower power state.
The TUSB1002 compensates for channel loss in both the upstream (C to D) and downstream direction (A to B).
This is done by configuring the CH1_EQ[2:1] and CH2_EQ[2:1] pins to the equalization setting that matches as
close possible to the channel insertion loss. In this particular example, CH2_EQ[2:1] is for path A to B which is
the channel between PCIe/SATA/SATA Express host and the TUSB1002, and CH1_EQ[2:1] is for path C to D
which is the channel between TUSB1002 and the miniCard/mSATA socket.
In this particular example, the channel A-B has a trace length of 8 inches with a 4 mil trace width. This particular
channel has about 0.83 dB per inch of insertion loss at 5 GHz. This equates to approximately 6.7 dB of loss for
the entire 8 inches of trace as depicted in Figure 19. An additional 1.5 dB of loss is added due to package of the
PCIe/SATA/SATA Express Host, TUSB1002, and the A/C coupling capacitor. This brings the entire channel loss
at 5 GHz to 6.7 dB + 1.5 dB = 8.2 dB. The channel A-B for this example is connected to TUSB1002 RX2P/N
input and therefore CH2_EQ[2:1] pins are used for adjusting TUSB1002 RX2P/N equalization settings. The
CH2_EQ[2:1] pins should be set such that TUSB1002 equalization is between 5dB and 8dB. A value closer to 5
dB maybe best if Host has transmitter de-emphasis.
A similar method should be used for the upstream path (C to D). In this particular example, C to D has a trace
length of 2 inches with a 4-mil trace width. This equates to approximately 1.5 dB at 5 GHz. The SATA/SATA
Express/PCIe device will have its own channel loss. This loss can be added to the C to D channel loss. For this
example, we will assume a value of 5dB is acceptable to compensate for C to D channel loss as well as loss
associated with the SATA/SATA Express/PCIe device. The CH1_EQ[2:1] pins should be set such that
TUSB1002 equalization is 5dB.
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VCC (3.3V)
VCC (3.3V)
REQ2A
10 µF
REQ2B
100nF
100nF
VCC (3.3V)
REQ2C
SATA_EN
REQ2D
CRX2
+
-
+
-
CTX1
RX2P
RX2N
GND
TX1P
TX1N
RSVD1
TUSB1002
49.9Q
FB1
FB2
CTX2
TX2P
TX2N
GND
RX1P
RX1N
MODE
VCC
CH1_EQ1
CH1_EQ2
CFG1
EN
GND
TPAD
SATA/PCIe/
SATA Express
Host
49.9Q
miniCard / mSATA
socket
GND
CH2_EQ2
CH2_EQ1
CFG2
SLP_S0#
VCC
10