USB7002T-KDXV [MICROCHIP]
4-Port SS/HS USB Type-C⢠PD Smart Hub;型号: | USB7002T-KDXV |
厂家: | MICROCHIP |
描述: | 4-Port SS/HS USB Type-C⢠PD Smart Hub 光电二极管 |
文件: | 总56页 (文件大小:519K) |
中文: | 中文翻译 | 下载: | 下载PDF数据表文档文件 |
USB7002
™
4-Port SS/HS USB Type-C PD Smart Hub
-
-
-
-
Chinese YD/T 1591-2006 charger emulation
Chinese YD/T 1591-2009 charger emulation
European Union universal mobile charger support
Supports additional portable devices
Highlights
• 4-Port USB Smart Hub with:
-
-
Native USB Type-C™ support on upstream port
Native USB Type-C support on downstream ports
1 and 2
• On-chip Microcontroller
-
Manages I/Os, VBUS, and other signals
-
-
Two Standard USB 2.0 downstream ports
Internal Hub Feature Controller device which
enables:
• 64kB RAM, 256kB ROM
• 8kB One-Time-Programmable (OTP) ROM
- USB to I2C/SPI/UART/I2S/GPIO bridge endpoint
support
-
Includes on-chip charge pump
• Configuration programming via OTP ROM, SPI
ROM, or SMBus
- USB to internal hub register write and read
• USB-IF Certified - TID 1212. Testing includes:
• FlexConnect
-
-
USB3.1 Gen1 Hub with BC1.2 support
Power Delivery 2.0 using UPD350 PD Transceiver
(TID 330000077)
-
The roles of the upstream and any downstream
port are reversible on command
-
-
Billboard endpoint device for Alternate Mode nego-
tiation status
Advanced multi-port system policy management
• Multi-Host Endpoint Reflector
-
Integrated host-controller endpoint reflector via
CDC/NCM device class for automotive applications
• USB Link Power Management (LPM) support
• USB Bridging
• USB-IF Battery Charger revision 1.2 support on
downstream ports (DCP, CDP, SDP)
-
USB to I2C, SPI, UART, I2S, and GPIO
• PortSwap
• Enhanced OEM configuration options available
through either OTP or SPI ROM
-
Configurable USB 2.0 differential pair signal swap-
ping
• Commercial and industrial grade temperature
support
• PHYBoost
-
Programmable USB 2.0 transceiver drive strength
for recovering signal integrity
• Automotive/AEC-Q100 qualified
• VariSense
Target Applications
• Standalone USB Hubs
-
Programmable USB 2.0 receiver sensitivity
• Compatible with Microsoft Windows 10, 8, 7, XP,
Apple OS X 10.4+, and Linux hub drivers
• Laptop Docks
• PC Motherboards
• Optimized for low-power operation and low ther-
mal dissipation
• PC Monitor Docks
• Multi-function USB 3.1 Gen 1 Peripherals
• Automotive integrated head unit and breakout box
• Package: 100-pin RoHS compliant VQFN
(12mm x 12mm)
Key Benefits
• USB 3.1 Gen 1 compliant 5 Gbps, 480 Mbps, 12
Mbps, and 1.5Mbps operation
* USB Type-C™ and USB-C™ are trademarks of USB
Implementers Forum.
-
-
-
5V tolerant USB 2.0 pins
1.32V tolerant USB 3.1 Gen 1 pins
Integrated termination and pull-up/down resistors
• Native USB Type-C Support
-
-
Type-C CC Pin with integrated Rp and Rd
Integrated multiplexer on USB Type-C enabled
ports. USB 3.1 Gen 1 PHYs are disabled until a
valid Type-C attach is detected, saving idle power.
Control for external VCONN supply
-
• Supports battery charging of most popular battery
powered devices on all ports
-
USB-IF Battery Charging rev. 1.2 support
(DCP, CDP, SDP)
-
Apple® portable product charger emulation
2018-2019 Microchip Technology Inc.
DS00002670D-page 1
USB7002
TO OUR VALUED CUSTOMERS
It is our intention to provide our valued customers with the best documentation possible to ensure successful use of
your Microchip products. To this end, we will continue to improve our publications to better suit your needs. Our pub-
lications will be refined and enhanced as new volumes and updates are introduced.
If you have any questions or comments regarding this publication, please contact the Marketing Communications
Department via E-mail at docerrors@microchip.com or fax the Reader Response Form in the back of this data
sheet to (480) 792-4150. We welcome your feedback.
Most Current Data Sheet
To obtain the most up-to-date version of this data sheet, please register at our Worldwide Web site at:
http://www.microchip.com
You can determine the version of a data sheet by examining its literature number found on the bottom outside corner
of any page. The last character of the literature number is the version number, (e.g., DS30000A is version A of doc-
ument DS30000).
Errata
An errata sheet, describing minor operational differences from the data sheet and recommended workarounds, may
exist for current devices. As device/documentation issues become known to us, we will publish an errata sheet. The
errata will specify the revision of silicon and revision of document to which it applies.
To determine if an errata sheet exists for a particular device, please check with one of the following:
• Microchip’s Worldwide Web site; http://www.microchip.com
• Your local Microchip sales office (see last page)
When contacting a sales office, please specify which device, revision of silicon and data sheet (include literature num-
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Customer Notification System
Register on our web site at www.microchip.com to receive the most current information on all of our products.
DS00002670D-page 2
2018-2019 Microchip Technology Inc.
USB7002
Table of Contents
1.0 Preface ............................................................................................................................................................................................ 4
2.0 Introduction ..................................................................................................................................................................................... 6
3.0 Pin Descriptions and Configuration ................................................................................................................................................. 8
4.0 Device Connections ...................................................................................................................................................................... 23
5.0 Modes of Operation ...................................................................................................................................................................... 26
6.0 Device Configuration ..................................................................................................................................................................... 29
7.0 Device Interfaces .......................................................................................................................................................................... 30
8.0 Functional Descriptions ................................................................................................................................................................. 34
9.0 Operational Characteristics ........................................................................................................................................................... 40
10.0 Package Outline .......................................................................................................................................................................... 49
Appendix A: Revision History .............................................................................................................................................................. 52
Product Identification System ............................................................................................................................................................. 53
The Microchip Web Site ...................................................................................................................................................................... 54
Customer Change Notification Service ............................................................................................................................................... 54
Customer Support ............................................................................................................................................................................... 54
2018-2019 Microchip Technology Inc.
DS00002670D-page 3
USB7002
1.0
1.1
PREFACE
General Terms
TABLE 1-1:
Term
GENERAL TERMS
Description
ADC
Analog-to-Digital Converter
Byte
8 bits
CDC
Communication Device Class
Control and Status Registers
Downstream Facing Port
32 bits
CSR
DFP
DWORD
EOP
End of Packet
EP
Endpoint
FIFO
First In First Out buffer
Full-Speed
FS
FSM
Finite State Machine
General Purpose I/O
Hi-Speed
GPIO
HS
HSOS
High Speed Over Sampling
Hub Feature Controller
The Hub Feature Controller, sometimes called a Hub Controller for short is the internal
processor used to enable the unique features of the USB Controller Hub. This is not to
be confused with the USB Hub Controller that is used to communicate the hub status
back to the Host during a USB session.
I2C
LS
Inter-Integrated Circuit
Low-Speed
lsb
Least Significant Bit
Least Significant Byte
Most Significant Bit
Most Significant Byte
Not Applicable
LSB
msb
MSB
N/A
NC
No Connect
OTP
PCB
PCS
PHY
PLL
One Time Programmable
Printed Circuit Board
Physical Coding Sublayer
Physical Layer
Phase Lock Loop
RESERVED
Refers to a reserved bit field or address. Unless otherwise noted, reserved bits must
always be zero for write operations. Unless otherwise noted, values are not guaran-
teed when reading reserved bits. Unless otherwise noted, do not read or write to
reserved addresses.
SDK
SMBus
UFP
Software Development Kit
System Management Bus
Upstream Facing Port
Universally Unique IDentifier
16 bits
UUID
WORD
DS00002670D-page 4
2018-2019 Microchip Technology Inc.
USB7002
1.2
Buffer Types
TABLE 1-2:
Buffer Type
BUFFER TYPES
Description
I
Input.
IS
Input with Schmitt trigger.
O12
OD12
PU
Output buffer with 12 mA sink and 12 mA source.
Open-drain output with 12 mA sink
50 μA (typical) internal pull-up. Unless otherwise noted in the pin description, internal pull-
ups are always enabled.
Internal pull-up resistors prevent unconnected inputs from floating. Do not rely on internal
resistors to drive signals external to the device. When connected to a load that must be
pulled high, an external resistor must be added.
PD
50 μA (typical) internal pull-down. Unless otherwise noted in the pin description, internal
pull-downs are always enabled.
Internal pull-down resistors prevent unconnected inputs from floating. Do not rely on
internal resistors to drive signals external to the device. When connected to a load that
must be pulled low, an external resistor must be added.
ICLK
OCLK
I/O-U
I-R
Crystal oscillator input pin
Crystal oscillator output pin
Analog input/output defined in USB specification.
RBIAS.
A
Analog.
P
Power pin.
1.3
Reference Documents
1. Universal Serial Bus Revision 3.1 Specification, http://www.usb.org
2. Battery Charging Specification, Revision 1.2, Dec. 07, 2010, http://www.usb.org
3. I2C-Bus Specification, Version 1.1, http://www.nxp.com/documents/user_manual/UM10204.pdf
4. I2S-Bus Specification, http://www.nxp.com/acrobat_download/various/I2SBUS.pdf
5. System Management Bus Specification, Version 1.0, http://smbus.org/specs
Note:
Additional USB7002 resources can be found on the Microchip USB7002 product page at www.micro-
chip.com/USB7002.
2018-2019 Microchip Technology Inc.
DS00002670D-page 5
USB7002
2.0
2.1
INTRODUCTION
General Description
The Microchip USB7002 hub is low-power, OEM configurable, USB 3.1 Gen 1 hub controller with 4 downstream ports
and advanced features for embedded USB applications. The USB7002 is fully compliant with the Universal Serial Bus
Revision 3.1 Specification and USB 2.0 Link Power Management Addendum. The USB7002 supports 5 Gbps Super-
Speed (SS), 480 Mbps Hi-Speed (HS), 12 Mbps Full-Speed (FS), and 1.5 Mbps Low-Speed (LS) USB downstream
devices on two standard USB 3.1 Gen 1 downstream ports and only legacy speeds (HS/FS/LS) on two standard USB
2.0 downstream ports.
The USB7002 supports native Type-C connectivity on the upstream port and two of the downstream ports. The hub
includes internal Type-C CC pin logic and an internal USB 3.1 Gen 1 multiplexer to support both Type-C insertion ori-
entations.
The USB7002 supports the legacy USB speeds (HS/FS/LS) through a dedicated USB 2.0 hub controller that is the cul-
mination of six generations of Microchip hub feature controller design and experience with proven reliability, interoper-
ability, and device compatibility. The SuperSpeed hub controller operates in parallel with the USB 2.0 controller,
decoupling the 5 Gbps SS data transfers from bottlenecks due to the slower USB 2.0 traffic.
The USB7002 enables OEMs to configure their system using “Configuration Straps.” These straps simplify the config-
uration process assigning default values to USB 3.1 Gen 1 ports and GPIOs. OEMs can disable ports, enable battery
charging and define GPIO functions as default assignments on power up.
The USB7002 supports downstream battery charging. The USB7002 integrated battery charger detection circuitry sup-
ports the USB-IF Battery Charging (BC1.2) detection method and most Apple devices. The USB7002 provides the bat-
tery charging handshake and supports the following USB-IF BC1.2 charging profiles:
• DCP: Dedicated Charging Port (Power brick with no data)
• CDP: Charging Downstream Port (1.5A with data)
• SDP: Standard Downstream Port (0.5A with data)
• Custom profiles loaded via SPI EEPROM or OTP
Additionally, the USB7002 includes many powerful and unique features such as:
The Hub Feature Controller, an internal USB device dedicated for use as a USB to I2C/UART/SPI/GPIO interface that
allows external circuits or devices to be monitored, controlled, or configured via the USB interface.
Multi-Host Endpoint Reflector, which provides unique USB functionality whereby USB data can be “mirrored” between
two USB hosts (Multi-Host) in order to perform a single USB transaction.This capability is fully covered by Microchip
intellectual property (U.S. Pat. Nos. 7,523,243 and 7,627,708) and is instrumental in enabling Apple CarPlay™, where
the Apple iPhone® becomes a USB Host.
FlexConnect, which provides flexible connectivity options. Any one of the USB7002’s downstream ports can be recon-
figured to become the upstream port, allowing master capable devices to control other devices on the hub.
AEC-Q100 compliance:, which tailors the device for use in automotive applications requiring automotive grade robust-
ness, starting with the comprehension of proprietary design for reliability techniques within the silicon IC itself, as well
as for the package design.
• Automotive qualified technologies and processes are used to fabricate the products with enhanced monitors to
continuously drive improvements in accordance with Microchip's zero-dpm methodology.
• Product qualification is focused on customer expectations and exceeds many of the automotive reliability stan-
dards including AEC-Q100.
• Microchip automotive services are provided during the life of the product from a dedicated organization of opera-
tions, quality, and product support personnel specialized in meeting the requirements of the automotive customer.
PortSwap, which adds per-port programmability to USB differential-pair pin locations. PortSwap allows direct alignment
of USB signals (D+/D-) to connectors to avoid uneven trace length or crossing of the USB differential signals on the
PCB.
PHYBoost, which provides programmable levels of Hi-Speed USB signal drive strength
in the downstream port transceivers. PHYBoost attempts to restore USB signal integrity
in a compromised system environment. The graphic on the right shows an example of
Hi-Speed USB eye diagrams before and after PHYBoost signal integrity restoration. in
a compromised system environment.
DS00002670D-page 6
2018-2019 Microchip Technology Inc.
USB7002
VariSense, which controls the Hi-Speed USB receiver sensitivity enabling programmable levels of USB signal receive
sensitivity. This capability allows operation in a sub-optimal system environment, such as when a captive USB cable is
used.
The USB7002 can be configured for operation through internal default settings. Custom OEM configurations are sup-
ported through external SPI ROM or internal OTP ROM. All port control signal pins are under firmware control in order
to allow for maximum operational flexibility and are available as GPIOs for customer specific use.
The USB7002 is available in commercial (0°C to +70°C) and industrial (-40°C to +85°C) temperature ranges. An internal
block diagram of the USB7002 in an upstream Type-C application is shown in Figure 2-1.
FIGURE 2-1:
USB7002 INTERNAL BLOCK DIAGRAM - UPSTREAM TYPE-C APPLICATION
P0
C
I2C from Master
USB7002
+3.3 V
+1.2 V
I2C/SMB
PHY0 PHY5
PHY0 CC
A
B
USB3 USB2
Hub Controller Logic
PHY1 PHY2
HFC
PHY
PHY3 PHY4
25 Mhz
PHY1 CC
PHY2
PHY4
PHY3 CC
A
B
A
B
OTP
Hub Feature Controller
I2S
UART
GPIO SMB SPI
Mux
P1
C
P2
C
P3
A
P4
A
2018-2019 Microchip Technology Inc.
DS00002670D-page 7
USB7002
3.0
PIN DESCRIPTIONS AND CONFIGURATION
The pin assignments for the USB7002 are detailed in Section 3.1, Pin Assignments. Pin descriptions are provided in
Section 3.2, Pin Descriptions.
3.1
Pin Assignments
The device pin diagram for the USB7002 can be seen in Figure 3-1. Table 3-1 provides a USB7002 pin assignments
table. Pin descriptions are provided in Section 3.2, Pin Descriptions.
FIGURE 3-1:
USB7002 100-VQFN PIN ASSIGNMENTS
1
2
75
74
73
72
71
70
69
68
67
66
65
64
63
62
61
60
59
58
57
56
55
54
53
52
51
RESET_N
PF26
PF30/VBUS_DET
PF31
PF29
3
PF25
4
DP1_VBUS_MON
USB2DN_DP1/PRT_DIS_P1
USB2DN_DM1/PRT_DIS_M1
USB3DN_TXDP1A
USB3DN_TXDM1A
VDD12
PF24
5
PF23
6
PF22/CFG_BC_EN
PF20/CFG_NON_REM
PF21
7
8
9
VDD33
PF19
10
11
12
13
14
15
16
17
18
19
20
21
22
23
24
25
USB3DN_RXDP1A
USB3DN_RXDM1A
DP1_CC1
TEST3
TEST2
TEST1
VDD33
PF18
Microchip
DP1_CC2
USB7002
USB2DN_DP3/PRT_DIS_P3
USB2DN_DM3/PRT_DIS_M3
USB3DN_TXDP1B
USB3DN_TXDM1B
VDD12
(Top View 100-VQFN)
PF17
PF16
PF15
USB3DN_RXDP1B
USB3DN_RXDM1B
CFG_STRAP1
PF14
PF13
Thermal slug connects to VSS
VDD12
PF12
CFG_STRAP2
CFG_STRAP3
VDD33
PF11
TESTEN
VDD12
PF10
Note:
Configuration straps are identified by an underlined symbol name. Signals that function as configuration
straps must be augmented with an external resistor when connected to a load.
DS00002670C-page 8
2018-2019 Microchip Technology Inc.
USB7002
Pin
Num
Pin
Num
Pin Name
Pin Name
1
2
RESET_N
PF30/VBUS_DET
PF31
51
52
53
54
55
56
57
58
59
60
61
62
63
64
65
66
67
68
69
70
71
72
73
74
75
76
77
78
79
80
81
82
83
84
85
86
87
88
89
90
91
92
93
94
PF10
PF11
3
VDD33
4
DP1_VBUS_MON
USB2DN_DP1/PRT_DIS_P1
USB2DN_DM1/PRT_DIS_M1
USB3DN_TXDP1A
USB3DN_TXDM1A
VDD12
PF12
5
VDD12
6
PF13
7
PF14
8
PF15
9
PF16
10
11
12
13
14
15
16
17
18
19
20
21
22
23
24
25
26
27
28
29
30
31
32
33
34
35
36
37
38
39
40
41
42
43
44
USB3DN_RXDP1A
USB3DN_RXDM1A
DP1_CC1
PF17
PF18
VDD33
DP1_CC2
TEST1
USB2DN_DP3/PRT_DIS_P3
USB2DN_DM3/PRT_DIS_M3
USB3DN_TXDP1B
USB3DN_TXDM1B
VDD12
TEST2
TEST3
PF19
VDD33
PF21
USB3DN_RXDP1B
USB3DN_RXDM1B
CFG_STRAP1
PF20/CFG_NON_REM
PF22/CFG_BC_EN
PF23
CFG_STRAP2
PF24
CFG_STRAP3
PF25
TESTEN
PF29
VDD12
PF26
VDD33
PF27
DP2_CC1
PF28
DP2_CC2
VDD12
USB2DN_DP2/PRT_DIS_P2
USB2DN_DM2/PRT_DIS_M2
USB3DN_TXDP2A
USB3DN_TXDM2A
VDD12
VDD33
VBUS_MON_UP
USB3UP_TXDPB
USB3UP_TXDMB
VDD12
USB3DN_RXDP2A
USB3DN_RXDM2A
DP2_VBUS_MON
USB2DN_DP4/PRT_DIS_P4
USB2DN_DM4/PRT_DIS_M4
USB3DN_TXDP2B
USB3DN_TXDM2B
VDD12
USB3UP_RXDPB
USB3UP_RXDMB
VDD33
CC1_UP
CC2_UP
USB2UP_DP
USB2UP_DM
USB3UP_TXDPA
USB3UP_TXDMA
VDD12
USB3DN_RXDP2B
USB3DN_RXDM2B
VDD33
USB3UP_RXDPA
2018-2019 Microchip Technology Inc.
DS00002670C-page 9
USB7002
Pin
Num
Pin
Num
Pin Name
Pin Name
45
46
47
48
49
50
PF4
PF5
PF6
PF7
PF8
PF9
95
96
USB3UP_RXDMA
ATEST
97
XTALO
98
XTALI/CLK_IN
VDD33
99
100
RBIAS
Exposed Pad (VSS) must be connected to ground.
3.2
Pin Descriptions
This section contains descriptions of the various USB7002 pins. The “_N” symbol in the signal name indicates that the
active, or asserted, state occurs when the signal is at a low voltage level. For example, RESET_N indicates that the
reset signal is active low. When “_N” is not present after the signal name, the signal is asserted when at the high voltage
level.
The terms assertion and negation are used exclusively. This is done to avoid confusion when working with a mixture of
“active low” and “active high” signal. The term assert, or assertion, indicates that a signal is active, independent of
whether that level is represented by a high or low voltage. The term negate, or negation, indicates that a signal is inac-
tive.
Buffer type definitions are detailed in Section 1.2, Buffer Types.
TABLE 3-1:
Name
PIN DESCRIPTIONS
Symbol
Buffer
Type
Description
USB 3.1 Gen 1 Interfaces
Upstream USB
3.1 Gen 1 TX D+
Orientation A
USB3UP_TXDPA
USB3UP_TXDMA
USB3UP_RXDPA
USB3UP_RXDMA
USB3UP_TXDPB
USB3UP_TXDMB
USB3UP_RXDPB
I/O-U
I/O-U
I/O-U
I/O-U
I/O-U
I/O-U
I/O-U
Upstream USB Type-C™ “Orientation A” USB 3.1 Gen 1
Transmit Data Plus.
Upstream USB
3.1 Gen 1 TX D-
Orientation A
Upstream USB Type-C “Orientation A” USB 3.1 Gen 1
Transmit Data Minus.
Upstream USB
3.1 Gen 1 RX D+
Orientation A
Upstream USB Type-C “Orientation A” USB 3.1 Gen 1
Receive Data Plus.
Upstream USB
3.1 Gen 1 RX D-
Orientation A
Upstream USB Type-C “Orientation A” USB 3.1 Gen 1
Receive Data Minus.
Upstream USB
3.1 Gen 1 TX D+
Orientation B
Upstream USB Type-C “Orientation B” USB 3.1 Gen 1
Transmit Data Plus.
Upstream USB
3.1 Gen 1 TX D-
Orientation B
Upstream USB Type-C “Orientation B” USB 3.1 Gen 1
Transmit Data Minus.
Upstream USB
3.1 Gen 1 RX D+
Orientation B
Upstream USB Type-C “Orientation B” USB 3.1 Gen 1
Receive Data Plus.
DS00002670C-page 10
2018-2019 Microchip Technology Inc.
USB7002
TABLE 3-1:
Name
PIN DESCRIPTIONS (CONTINUED)
Buffer
Symbol
Type
Description
Upstream USB
3.1 Gen 1 RX D-
Orientation B
USB3UP_RXDMB
I/O-U
I/O-U
Upstream USB Type-C “Orientation B” USB 3.1 Gen 1
Receive Data Minus.
Downstream
Port 1 USB 3.1
Gen 1 TX D+
Orientation A
USB3DN_TXDP1A
Downstream USB Type-C “Orientation A” Super Speed
Transmit Data Plus, port 1.
Downstream
Port 1 USB 3.1
Gen 1 TX D- Ori-
entation A
USB3DN_TXDM1A
USB3DN_RXDP1A
USB3DN_RXDM1A
USB3DN_TXDP1B
USB3DN_TXDM1B
USB3DN_RXDP1B
USB3DN_RXDM1B
USB3DN_TXDP2A
USB3DN_TXDM2A
I/O-U
I/O-U
I/O-U
I/O-U
I/O-U
I/O-U
I/O-U
I/O-U
I/O-U
Downstream USB Type-C “Orientation A” Super Speed
Transmit Data Minus, port 1.
Downstream
Port 1 USB 3.1
Gen 1 RX D+
Orientation A
Downstream USB Type-C “Orientation A” Super Speed
Receive Data Plus, port 1.
Downstream
Port 1 USB 3.1
Gen 1 RX D- Ori-
entation A
Downstream USB Type-C “Orientation A” Super Speed
Receive Data Minus, port 1.
Downstream
Port 1 USB 3.1
Gen 1 TX D+
Orientation B
Downstream USB Type-C “Orientation B” Super Speed
Transmit Data Plus, port 1.
Downstream
Port 1 USB 3.1
Gen 1 TX D- Ori-
entation B
Downstream USB Type-C “Orientation B” Super Speed
Transmit Data Minus, port 1.
Downstream
Port 1 USB 3.1
Gen 1 RX D+
Orientation B
Downstream USB Type-C “Orientation B” Super Speed
Receive Data Plus, port 1.
Downstream
Port 1 USB 3.1
Gen 1 RX D- Ori-
entation B
Downstream USB Type-C “Orientation B” Super Speed
Receive Data Minus, port 1.
Downstream
Port 2 USB 3.1
Gen 1 TX D+
Orientation A
Downstream USB Type-C “Orientation A” Super Speed
Transmit Data Plus, port 2.
Downstream
Port 2 USB 3.1
Gen 1 TX D-
Orientation A
Downstream USB Type-C “Orientation A” Super Speed
Transmit Data Minus, port 2.
2018-2019 Microchip Technology Inc.
DS00002670C-page 11
USB7002
TABLE 3-1:
PIN DESCRIPTIONS (CONTINUED)
Buffer
Type
Name
Symbol
Description
Downstream
Port 2 USB 3.1
Gen 1 RX D+
Orientation A
USB3DN_RXDP2A
I/O-U
I/O-U
I/O-U
I/O-U
I/O-U
I/O-U
Downstream USB Type-C “Orientation A” Super Speed
Receive Data Plus, port 2.
Downstream
Port 2 USB 3.1
Gen 1 RX D-
Orientation A
USB3DN_RXDM2A
USB3DN_TXDP2B
USB3DN_TXDM2B
USB3DN_RXDP2B
USB3DN_RXDM2B
Downstream USB Type-C “Orientation A” Super Speed
Receive Data Minus, port 2.
Downstream
Port 2 USB 3.1
Gen 1 TX D+
Orientation B
Downstream USB Type-C “Orientation B” Super Speed
Transmit Data Plus, port 2.
Downstream
Port 2 USB 3.1
Gen 1 TX D-
Orientation B
Downstream USB Type-C “Orientation B” Super Speed
Transmit Data Minus, port 2.
Downstream
Port 2 USB 3.1
Gen 1 RX D+
Orientation B
Downstream USB Type-C “Orientation B” Super Speed
Receive Data Plus, port 2.
Downstream
Port 2 USB 3.1
Gen 1 RX D-
Orientation B
Downstream USB Type-C “Orientation B” Super Speed
Receive Data Minus, port 2.
USB 2.0 Interfaces
Upstream USB
2.0 D+
USB2UP_DP
USB2UP_DM
I/O-U
I/O-U
I/O-U
Upstream USB 2.0 Data Plus (D+).
Upstream USB
2.0 D-
Upstream USB 2.0 Data Minus (D-).
Downstream
Ports 1-4 USB
2.0 D+
USB2DN_DP[1:4]
Downstream USB 2.0 Ports 1-4 Data Plus (D+).
Downstream
Ports 1-4 USB
2.0 D-
USB2DN_DM[1:4]
I/O-U
Downstream USB 2.0 Ports 1-4 Data Minus (D-)
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USB7002
TABLE 3-1:
Name
PIN DESCRIPTIONS (CONTINUED)
Buffer
Symbol
Type
Description
VBUS Detect
VBUS_DET
IS
This signal detects the state of the upstream bus power
in legacy Type-B upstream implementations.
When designing a detachable hub, this pin must be con-
nected to the VBUS power pin of the upstream USB port
through a resistor divider (50 kΩ by 100 kΩ) to provide
3.3 V.
For self-powered applications with a permanently
attached host, this pin must be connected to either 3.3 V
or 5.0 V through a resistor divider to provide 3.3 V.
In embedded applications, VBUS_DET may be con-
trolled (toggled) when the host desires to renegotiate a
connection without requiring a full reset of the device.
USB Type-C Connector Control
Downstream
Port 1 Type-C
Voltage Monitor
DP1_VBUS_MON
I/O12
Used to detect Type-C VBUS vSafe5V and vSafe0V
states on Port 1. A potential divider is needed for this pin
(44.2 k to 49.9 k , 1.0%).
Downstream
Port 1 Type-C
CC1
DP1_CC1
I/O12
Used for Type-C attach and orientation detection on Port
1. Includes configurable Rp/Ra selection. Connect this
pin directly to the CC1 pin of the respective Type-C con-
nector.
Downstream
Port 1 Type-C
CC2
DP1_CC2
I/O12
Used for Type-C attach and orientation detection on Port
1. Includes configurable Rp/Ra selection. Connect this
pin directly to the CC2 pin of the respective Type-C con-
nector.
Downstream
Port 2 Type-C
Voltage Monitor
DP2_VBUS_MON
I/O12
I/O12
Used for detect Type-C VBUS vSafe5V and vSafe0V
states on Port 2. A potential divider is needed for this pin
(44.2 k to 49.9 k , 1.0%).
Downstream
Port 2 Type-C
CC1
DP2_CC1
Used for Type-C attach and orientation detection on Port
2. Includes configurable Rp/Ra selection. Connect this
pin directly to the CC1 pin of the respective Type-C con-
nector.
Downstream
Port 2 Type-C
CC2
DP2_CC2
I/O12
Used for Type-C attach and orientation detection on Port
2. Includes configurable Rp/Ra selection. Connect this
pin directly to the CC2 pin of the respective Type-C con-
nector.
Upstream
Type-C CC1
CC1_UP
CC2_UP
I/O12
I/O12
I/O12
Used for Type-C attach and orientation detection.
Includes configurable Rp/Ra selection.
Upstream
Type-C CC2
Used for Type-C attach and orientation detection.
Includes configurable Rp/Ra selection.
Upstream
Type-C Voltage
Monitor
VBUS_MON_UP
Used to detect Type-C VBUS vSafe5V and vSafe0V
states on the upstream port. A potential divider is
needed for this pin (44.2 k to 49.9 k , 1.0%).
2018-2019 Microchip Technology Inc.
DS00002670C-page 13
USB7002
TABLE 3-1:
PIN DESCRIPTIONS (CONTINUED)
Buffer
Type
Name
Symbol
Description
Miscellaneous
Programmable
Function Pins
PF[31:4]
I/O12
Programmable function pins.
Refer to Section 3.3, Configuration Straps and Program-
mable Functions for details.
Reset Input
RESET_N
RBIAS
IS
This active low signal is used by the system to reset the
device.
Bias Resistor
I-R
A 12.0 k 1.0% resistor is attached from ground to this
pin to set the transceiver’s internal bias settings. Place
the resistor as close the device as possible with a dedi-
cated, low impedance connection to the ground plane.
Test 1
Test 2
TEST1
TEST2
TEST3
TESTEN
ATEST
A
A
Test 1 pin.
This signal is used for test purposes and must always
be pulled-up to 3.3V via a 4.7 k resistor.
Test 2 pin.
This signal is used for test purposes and must always
be pulled-down to ground via a 4.7 k resistor.
Test 3
A
Test 3 pin.
This signal is used for test purposes and must always
be pulled-down to ground via a 4.7 k resistor.
Test
I/O12
A
Test pin.
This signal is used for test purposes and must always
be connected to ground.
Analog Test
Analog test pin.
This signal is used for test purposes and must either be
left unconnected or tied to ground.
External 25 MHz
Crystal Input
XTALI
CLKIN
ICLK
ICLK
External 25 MHz crystal input
External 25 MHz
Reference Clock
Input
External reference clock input.
The device may alternatively be driven by a single-
ended clock oscillator. When this method is used,
XTALO should be left unconnected.
External 25 MHz
Crystal Output
XTALO
OCLK
External 25 MHz crystal output
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USB7002
TABLE 3-1:
Name
PIN DESCRIPTIONS (CONTINUED)
Buffer
Symbol
Type
Description
Configuration Straps
Port 4-1 D+
Disable
PRT_DIS_P[4:1]
I
Port 4-1 D+ Disable Configuration Strap.
Configuration
Strap
These configuration straps are used in conjunction with
the corresponding PRT_DIS_M[4:1] straps to disable
the related port (4-1). See Note 3-1.
Both USB data pins for the corresponding port must be
tied to 3.3V to disable the associated downstream port.
Port 4-1 D-
Disable
PRT_DIS_M[4:1]
I
Port 4-1 D- Disable Configuration Strap.
Configuration
Strap
These configuration straps are used in conjunction with
the corresponding PRT_DIS_P[4:1] straps to disable the
related port (4-1). See Note 3-1.
Both USB data pins for the corresponding port must be
tied to 3.3V to disable the associated downstream port.
Non-Removable
Ports
Configuration
Strap
CFG_NON_REM
CFG_BC_EN
I
Non-Removable Ports Configuration Strap.
This configuration strap controls the number of reported
non-removable ports. See Note 3-1.
BatteryCharging
Configuration
Strap
I/O12
Battery Charging Configuration Strap.
This configuration strap controls the number of BC 1.2
enabled downstream ports. See Note 3-1.
Device Mode
Configuration
Straps 3-1
CFG_STRAP[3:1]
I
Device Mode Configuration Straps 3-1.
These configuration straps are used to select the
device’s mode of operation. See Note 3-1.
Power/Ground
+3.3V I/O Power
Supply Input
VDD33
VDD12
P
+3.3 V power and internal regulator input.
+1.2V Core
Power Supply
Input
P
+1.2 V digital core power supply input.
Ground
VSS
P
Common ground.
This exposed pad must be connected to the ground
plane with a via array.
Note 3-1
Configuration strap values are latched on Power-On Reset (POR) and the rising edge of RESET_N
(external chip reset). Configuration straps are identified by an underlined symbol name. Signals that
function as configuration straps must be augmented with an external resistor when connected to a
load. For additional information, refer to Section 3.3, Configuration Straps and Programmable
Functions.
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USB7002
3.3
Configuration Straps and Programmable Functions
Configuration straps are multi-function pins that are used during Power-On Reset (POR) or external chip reset
(RESET_N) to determine the default configuration of a particular feature. The state of the signal is latched following
deassertion of the reset. Configuration straps are identified by an underlined symbol name. This section details the var-
ious device configuration straps and associated programmable pin functions.
Note:
The system designer must ensure that configuration straps meet the timing requirements specified in
Section 9.6.2, Power-On and Configuration Strap Timing and Section 9.6.3, Reset and Configuration Strap
Timing. If configuration straps are not at the correct voltage level prior to being latched, the device may
capture incorrect strap values.
3.3.1
PORT DISABLE CONFIGURATION (PRT_DIS_P[4:1] / PRT_DIS_M[4:1])
The PRT_DIS_P[4:1] / PRT_DIS_M[4:1] configuration straps are used in conjunction to disable the related port (4-1)
For PRT_DIS_Px (where x is the corresponding port 4-1):
0 = Port x D+ Enabled
1 = Port x D+ Disabled
For PRT_DIS_Mx (where x is the corresponding port 4-1):
0 = Port x D- Enabled
1 = Port x D- Disabled
Note:
Both PRT_DIS_Px and PRT_DIS_Mx (where x is the corresponding port) must be tied to 3.3 V to disable
the associated downstream port. Disabling the USB 2.0 port will also disable the corresponding USB 3.0
port.
3.3.2
NON-REMOVABLE PORT CONFIGURATION (CFG_NON_REM)
The CFG_NON_REM configuration strap is used to configure the non-removable port settings of the device to one of
five settings. These modes are selected by the configuration of an external resistor on the CFG_NON_REM pin. The
resistor options are a 200 kΩ pull-down, 200 kΩ pull-up, 10 kΩ pull-down, 10 kΩ pull-up, and 10 Ω pull-down, as shown
in Table 3-2.
TABLE 3-2:
CFG_NON_REM RESISTOR ENCODING
CFG_NON_REM Resistor Value
Setting
200 kΩ Pull-Down
200 kΩ Pull-Up
10 kΩ Pull-Down
10 kΩ Pull-Up
All ports removable
Port 1 non-removable
Ports 1, 2 non-removable
Ports 1, 2, 3 non-removable
Ports 1, 2, 3, 4 non-removable
10 Ω Pull-Down
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USB7002
3.3.3
BATTERY CHARGING CONFIGURATION (CFG_BC_EN)
The CFG_BC_EN configuration strap is used to configure the battery charging port settings of the device to one of
five settings. These modes are selected by the configuration of an external resistor on the CFG_BC_EN pin. The resistor
options are a 200 kΩ pull-down, 200 kΩ pull-up, 10 kΩ pull-down, 10 kΩ pull-up, and 10 Ω pull-down, as shown in
Table 3-3.
TABLE 3-3:
CFG_BC_EN RESISTOR ENCODING
CFG_BC_EN Resistor Value
Setting
Battery charging not enable on any port
200 kΩ Pull-Down
200 kΩ Pull-Up
10 kΩ Pull-Down
10 kΩ Pull-Up
BC1.2 DCP and CDP battery charging enabled on Port 1
BC1.2 DCP and CDP battery charging enabled on Ports 1, 2
BC1.2 DCP and CDP battery charging enabled on Ports 1, 2, 3
BC1.2 DCP and CDP battery charging enabled on Ports 1, 2, 3, 4
10 Ω Pull-Down
3.3.4
PF[31:4] CONFIGURATION (CFG_STRAP[2:1])
The USB7002 provides 28 programmable function pins (PF[31:4]). These pins can be configured to 4 predefined con-
figurations via the CFG_STRAP[2:1] pins. These configurations are selected via external resistors on the
CFG_STRAP[2:1] pins, as detailed in Table 3-4. Resistor values and combinations not detailed in Table 3-4 are reserved
and should not be used.
Note:
CFG_STRAP3 is not used and can be left unconnected.
TABLE 3-4:
CFG_STRAP[2:1] RESISTOR ENCODING
CFG_STRAP2
Resistor Value
CFG_STRAP1
Resistor Value
Mode
Configuration 1
Configuration 2
Configuration 3
Configuration 4
200 kΩ Pull-Down
200 kΩ Pull-Down
200 kΩ Pull-Down
200 kΩ Pull-Down
200 kΩ Pull-Down
200 kΩ Pull-Up
10 kΩ Pull-Down
10 kΩ Pull-Up
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DS00002670C-page 17
USB7002
A summary of the configuration pin assignments for each of the 4 configurations is provided in Table 3-5. For details on
behavior of each programmable function, refer to Table 3-6.
TABLE 3-5:
Pin
PF[31:4] FUNCTION ASSIGNMENT
Configuration 1
(SMBus/I2C)
Configuration 2
Configuration 3
(UART)
Configuration 4
(Flex)
(I2S)
PF4
DP2_DISCHARGE
DP1_DISCHARGE
GPIO70
DP2_DISCHARGE
DP1_DISCHARGE
GPIO70
DP2_DISCHARGE
DP1_DISCHARGE
UART_RX
UART_TX
DP2_DISCHARGE
DP1_DISCHARGE
GPIO70
PF5
PF6
PF7
GPIO71
MIC_DET
GPIO71
PF8
DP1_VCONN1
DP1_VCONN2
DP2_VCONN1
DP2_VCONN2
GPIO76
DP1_VCONN1
DP1_VCONN2
DP2_VCONN1
DP2_VCONN2
GPIO76
DP1_VCONN1
DP1_VCONN2
DP2_VCONN1
DP2_VCONN2
GPIO76
DP1_VCONN1
DP1_VCONN2
DP2_VCONN1
DP2_VCONN2
GPIO76
PF9
PF10
PF11
PF12
PF13
PF14
PF15
PF16
PF17
PF18
PF19
PF20
PF21
PF22
PF23
PF24
PF25
PF26
PF27
PF28
PF29
PF30
PF31
PRT_CTL4
GPIO78
PRT_CTL4
I2S_SDI
PRT_CTL4
UART_nCTS
PRT_CTL2
PRT_CTL3
PRT_CTL1
UART_nDCD
UART_nRTS
SPI_CE_N
SPI_CLK
PRT_CTL4
GPIO78
PRT_CTL2
PRT_CTL3
PRT_CTL1
MSTR_I2C_CLK
MSTR_I2C_DATA
SPI_CE_N
SPI_CLK
PRT_CTL2
PRT_CTL3
PRT_CTL1
I2S_LRCK
I2S_SDO
PRT_CTL2
PRT_CTL3
PRT_CTL1
GPIO82
GPIO83
SPI_CE_N
SPI_CLK
SPI_CE_N
SPI_CLK
SPI_D0
SPI_D0
SPI_D0
SPI_D0
SPI_D1
SPI_D1
SPI_D1
SPI_D1
SPI_D2
SPI_D2
SPI_D2
SPI_D2
SPI_D3
SPI_D3
SPI_D3
SPI_D3
SLV_I2C_CLK
SLV_I2C_DATA
GPIO92
I2S_SCK
UART_nDSR
UART_nDTR
GPIO92
GPIO90
I2S_MCLK
GPIO92
GPIO91
GPIO92
GPIO93
GPIO93
GPIO93
GPIO93
GPIO94
MSTR_I2C_CLK
MSTR_I2C_DATA
GPIO94
GPIO94
GPIO95
GPIO95
GPIO95
Note:
The default PFx pin functions can be overridden with additional configuration by modification of the pin mux
registers. These changes can be made during the SMBus configuration stage, by programming to OTP
memory, or during runtime (after hub has attached and enumerated) by register writes via the SMBus slave
interface or USB commands to the internal Hub Feature Controller Device.
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USB7002
TABLE 3-6:
Function
PROGRAMMABLE FUNCTIONS DESCRIPTIONS
Buffer
Description
Type
Master SMBus/I2C Interface
MSTR_I2C_CLK
MSTR_I2C_DATA
I/O12
I/O12
Bridging Master SMBus/I2C controller clock (SMBus/I2C controller 1)
Bridging Master SMBus/I2C controller data (SMBus/I2C controller 1)
Slave SMBus/I2C Interface
SLV_I2C_CLK
SLV_I2C_DATA
I/O12
I/O12
Slave SMBus/I2C controller clock (SMBus/I2C controller 2)
Slave SMBus/I2C controller data (SMBus/I2C controller 2)
SPI Interface
SPI_CLK
SPI_D[3:0]
SPI_CE_N
I/O-U
I/O-U
I/O12
SPI clock. If the SPI interface is enabled, this pin must be driven low during
reset.
SPI Data 3-0. If the SPI interface is enabled, these signals function as Data
3 through 0.
Active low SPI chip enable input. If the SPI interface is enabled, this pin
must be driven high in powerdown states.
UART Interface
UART Transmit
UART_TX
UART_RX
O12
I
UART Receive
UART_nCTS
UART_nRTS
UART_nDCD
UART_nDSR
UART_nDTR
I
UART Clear To Send
UART Request To Send
UART Data Carrier Detect
UART Data Set Ready
UART Data Terminal Ready
I2S Interface
O12
I
I
O12
I2S_SDI
I2S_SDO
I2S_SCK
I2S_LRCK
I2S_MCLK
MIC_DET
I
I2S Serial Data In
O12
O12
O12
O12
I
I2S Serial Data Out
I2S Continuous Serial Clock
I2S Word Select / Left-Right Clock
I2S Master Clock
I2S Microphone Plug Detect
0 = No microphone plugged into the audio jack
1 = Microphone plugged into the audio jack
Miscellaneous
Port 2 VCONN1 enable
Port 2 VCONN2 enable
DP2_VCONN1
DP2_VCONN2
I/O12
I/O12
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DS00002670C-page 19
USB7002
TABLE 3-6:
PROGRAMMABLE FUNCTIONS DESCRIPTIONS (CONTINUED)
Buffer
Type
Function
Description
DP2_DISCHARGE
DP1_VCONN1
DP1_VCONN2
DP1_DISCHARGE
PRT_CTL4
I/O12
I/O12
I/O12
I/O12
Port 2 DISCHARGE enable
Port 1 VCONN1 enable
Port 1 VCONN2 enable
Port 1 DISCHARGE enable
I/O12
(PU)
Port 4 power enable / overcurrent sense
When the downstream port is enabled, this pin is set as an input with an
internal pull-up resistor applied. The internal pull-up enables power to the
downstream port while the pin monitors for an active low overcurrent signal
assertion from an external current monitor on USB port 4.
This pin will change to an output and be driven low when the port is dis-
abled by configuration or by the host control.
Note:
This signal controls both the USB 2.0 and USB 3.1 portions of
the port.
PRT_CTL3
I/O12
(PU)
Port 3 power enable / overcurrent sense
When the downstream port is enabled, this pin is set as an input with an
internal pull-up resistor applied. The internal pull-up enables power to the
downstream port while the pin monitors for an active low overcurrent signal
assertion from an external current monitor on USB port 3.
This pin will change to an output and be driven low when the port is dis-
abled by configuration or by the host control.
Note:
This signal controls both the USB 2.0 and USB 3.1 portions of
the port.
PRT_CTL2
I/O12
(PU)
Port 2 power enable / overcurrent sense
When the downstream port is enabled, this pin is set as an input with an
internal pull-up resistor applied. The internal pull-up enables power to the
downstream port while the pin monitors for an active low overcurrent signal
assertion from an external current monitor on USB port 2.
This pin will change to an output and be driven low when the port is dis-
abled by configuration or by the host control.
Note:
This signal controls both the USB 2.0 and USB 3.1 portions of
the port.
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USB7002
TABLE 3-6:
Function
PROGRAMMABLE FUNCTIONS DESCRIPTIONS (CONTINUED)
Buffer
Description
Type
PRT_CTL1
I/O12
(PU)
Port 1 power enable / overcurrent sense
When the downstream port is enabled, this pin is set as an input with an
internal pull-up resistor applied. The internal pull-up enables power to the
downstream port while the pin monitors for an active low overcurrent signal
assertion from an external current monitor on USB port 1.
This pin will change to an output and be driven low when the port is dis-
abled by configuration or by the host control.
Note:
This signal controls both the USB 2.0 and USB 3.1 portions of
the port.
GPIOx
I/O12
General Purpose Inputs/Outputs
(x = 70-71, 76, 78, 82-83, 90-95)
3.4
Physical and Logical Port Mapping
The USB70xx family of devices are based upon a common architecture, but all have different modifications and/or pin
bond outs to achieve the various device configurations. The base chip is composed of a total of 6 USB3 PHYs and 7
USB2 PHYs. These PHYs are physically arranged on the chip in a certain way, which is referred to as the PHYSICAL
port mapping.
The actual port numbering is remapped by default in different ways on each device in the family. This changes the way
that the ports are numbered from the USB host’s perspective. This is referred to as LOGICAL mapping.
The various configuration options available for these devices may, at times, be with respect to PHYSICAL mapping or
LOGICAL mapping. Each individual configuration option which has a PHYSICAL or LOGICAL dependency is declared
as such within the register description.
The PHYSICAL vs. LOGICAL mapping is described for all port related pins in Table 3-7. A system design in schematics
and layout is generally performed using the pinout in Section 3.1, Pin Assignments, which is assigned by the default
LOGICAL mapping. Hence, it may be necessary to cross reference the PHYSICAL vs. LOGICAL look up tables when
determining the hub configuration.
Note:
The MPLAB Connect tool makes configuration simple; the settings can be selected by the user with respect
to the LOGICAL port numbering. The tool handles the necessary linking to the PHYSICAL port settings.
Refer to Section 6.0, Device Configuration for additional information.
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DS00002670C-page 21
USB7002
TABLE 3-7:
USB7002 PHYSICAL VS. LOGICAL PORT MAPPING
LOGICAL PORT NUMBER
PHYSICAL PORT NUMBER
Device
Pin
Pin Name
0
1
2
3
4
5
0
1
2
3
4
5
6
5
USB2DN_DP1
USB2DN_DM1
X
X
X
X
X
X
X
X
X
X
X
X
6
7
USB3DN_TXDP1A
USB3DN_TXDM1A
USB3DN_RXDP1A
USB3DN_RXDM1A
USB2DN_DP3
8
10
11
14
15
16
17
19
20
29
30
31
32
34
35
37
38
39
40
42
43
81
82
84
85
89
90
91
92
94
95
X
X
X
X
X
X
X
X
USB2DN_DM3
USB3DN_TXDP1B
USB3DN_TXDM1B
USB3DN_RXDP1B
USB3DN_RXDM1B
USB2DN_DP2
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
USB2DN_DM2
USB3DN_TXDP2A
USB3DN_TXDM2A
USB3DN_RXDP2A
USB3DN_RXDM2A
USB2DN_DP4
X
X
X
X
X
X
X
X
USB2DN_DM4
USB3DN_TXDP2B
USB3DN_TXDM2B
USB3DN_RXDP2B
USB3DN_RXDM2B
USB3UP_TXDPB
USB3UP_TXDMB
USB3UP_RXDPB
USB3UP_RXDMB
USB2UP_DP
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
USB2UP_DM
USB3UP_TXDPA
USB3UP_TXDMA
USB3UP_RXDPA
USB3UP_RXDMA
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USB7002
4.0
4.1
DEVICE CONNECTIONS
Power Connections
Figure 4-1 illustrates the device power connections.
FIGURE 4-1:
POWER CONNECTIONS
+3.3V
Supply
+1.2V
Supply
VDD12 (x9)
VDD33 (x8)
3.3V Internal Logic
1.2V Internal Logic
VSS (exposed pad)
USB7002
+3.3V
+3.3V
+1.2V
+1.2V
x8
x9
4.2
SPI/SQI Flash Connections
Figure 4-2 illustrates the Quad-SPI flash connections.
FIGURE 4-2:
QUAD-SPI FLASH CONNECTIONS
+3.3V
SPI_CE_N
CE#
SPI_CLK
SPI_D0
SPI_D1
CLK
SIO0
SIO1
SPI_D2
SPI_D3
SIO2/WPn
SIO3/HOLDn
Quad-SPI Flash
USB7002
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USB7002
4.3
SMBus/I2C Connections
Figure 4-3 illustrates the SMBus/I2C connections.
FIGURE 4-3:
SMBUS/I2C CONNECTIONS
+3.3V
R
x_I2C_CLK
Clock
SMBus/I2C
+3.3V
R
USB7002
x_I2C_DAT
Data
R = 4.7K for 400/100KHz Master I2C interfaces,
1.0K for 1MHz Master I2C interfaces,
10K for Slave I2C interfaces
Note:
Resistor values detailed in Figure 4-3 are suggestions. Optimal pull-up values may vary dependent on
external factors.
4.4
I2S Connections
Figure 4-4 illustrates the I2S connections.
FIGURE 4-4:
I2S CONNECTIONS
+3.3V
CODEC
USB7002
I2S_MCLK
I2S_SCK
I2S_LRCK
I2S_SDO
I2S_SD
I2S
MSTR_I2C_CLK
MSTR_I2C_DAT
MIC_DET
I2C
Audio Jack
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USB7002
4.5
UART Connections
Figure 4-5 illustrates the UART connections.
FIGURE 4-5:
UART CONNECTIONS
UART
Transceiver
UART
Connector
USB7002
UART_TX
UART_RX
UART_nRTS
UART_nCTS
UART_nDTR
UART_nDSR
UART_nDCD
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DS00002670D-page 25
USB7002
5.0
MODES OF OPERATION
The device provides two main modes of operation: Standby Mode and Hub Mode. These modes are controlled via the
RESET_N pin, as shown in Table 5-1.
TABLE 5-1:
MODES OF OPERATION
RESET_N Input
Summary
0
Standby Mode: This is the lowest power mode of the device. No functions are active other
than monitoring the RESET_N input. All port interfaces are high impedance and the PLL is
halted. Refer to Section 8.11, Resets for additional information on RESET_N.
1
Hub (Normal) Mode: The device operates as a configurable USB hub. This mode has vari-
ous sub-modes of operation, as detailed in Figure 5-1. Power consumption is based on the
number of active ports, their speed, and amount of data received.
The flowchart in Figure 5-1 details the modes of operation and details how the device traverses through the Hub Mode
stages (shown in bold). The remaining sub-sections provide more detail on each stage of operation.
FIGURE 5-1:
HUB MODE FLOWCHART
RESET_N deasserted
(SPI_INIT)
In SPI Mode
(CFG_ROM)
NO
Load Config from
Internal ROM
& Ext. SPI ROM
present?
YES
(CFG_STRAP)
Modify Config
Based on Config
Straps
Run From
External SPI ROM
YES
Configuration 1?
NO
Perform SMBus/I2C
Initialization
YES
SMBus Slave Pull-ups?
NO
(SMBUS_CHECK)
NO
SOC Done?
YES
(CFG_SMBUS)
Combine OTP
Config Data
(CFG_OTP)
Hub Connect
(USB_ATTACH)
Normal Operation
(NORMAL_MODE)
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USB7002
5.1
Boot Sequence
5.1.1
STANDBY MODE
If the RESET_N pin is asserted, the hub will be in Standby Mode. This mode provides a very low power state for maxi-
mum power efficiency when no signaling is required. This is the lowest power state. In Standby Mode all downstream
ports are disabled, the USB data pins are held in a high-impedance state, all transactions immediately terminate (no
states saved), all internal registers return to their default state, the PLL is halted, and core logic is powered down in order
to minimize power consumption. Because core logic is powered off, no configuration settings are retained in this mode
and must be re-initialized after RESET_N is negated high.
5.1.2
SPI INITIALIZATION STAGE (SPI_INIT)
The first stage, the initialization stage, occurs on the deassertion of RESET_N. In this stage, the internal logic is reset,
the PLL locks if a valid clock is supplied, and the configuration registers are initialized to their default state. The internal
firmware then checks for an external SPI ROM. The firmware looks for an external SPI flash device that contains a valid
signature of “2DFU” (device firmware upgrade) beginning at address 0x3FFFA. If a valid signature is found, then the
external SPI ROM is enabled and the code execution begins at address 0x0000 in the external SPI device. If a valid
signature is not found, then execution continues from internal ROM (CFG_ROM stage).
The required SPI ROM must be a minimum of 1 Mbit, and 60 MHz or faster. Both 1, 2, and 4-bit SPI operation is sup-
ported. For optimum throughput, a 2-bit SPI ROM is recommended. Both mode 0 and mode 3 SPI ROMs are also sup-
ported.
If the system is not strapped for SPI Mode, code execution will continue from internal ROM (CFG_ROM stage).
5.1.3
CONFIGURATION FROM INTERNAL ROM STAGE (CFG_ROM)
In this stage, the internal firmware loads the default values from the internal ROM. Most of the hub configuration regis-
ters, USB descriptors, electrical settings, etc. will be initialized in this state.
5.1.4
CONFIGURATION STRAP READ STAGE (CFG_STRAP)
In this stage, the firmware reads the following configuration straps to override the default values:
• CFG_STRAP[3:1]
• PRT_DIS_P[4:1]
• PRT_DIS_M[4:1]
• CFG_NON_REM
• CFG_BC_EN
If the CFG_STRAP[3:1] pins are set to Configuration 1, the device will move to the SMBUS_CHECK stage, otherwise
it will move to the CFG_OTP stage. Refer to Section 3.3, Configuration Straps and Programmable Functions for infor-
mation on usage of the various device configuration straps.
5.1.5
SMBUS CHECK STAGE (SMBUS_CHECK)
Based on the PF[31:4] configuration selected (refer to Section 3.3.4, PF[31:4] Configuration (CFG_STRAP[2:1])), the
firmware will check for the presence of external pull up resistors on the SMBus slave programmable function pins. If
pull-ups are detected on both pins, the device will be configured as an SMBus slave, and the next state will be CFG_SM-
BUS. If a pull-up is not detected in either of the pins, the next state is CFG_OTP.
5.1.6
SMBUS CONFIGURATION STAGE (CFG_SMBUS)
In this stage, the external SMBus master can modify any of the default configuration settings specified in the integrated
ROM, such as USB device descriptors, port electrical settings, and control features such as downstream battery
charging.
There is no time limit on this mode. In this stage the firmware will wait indefinitely for the SMBus/I2C configuration. The
external SMBus master writes to register 0xFF to end the configuration in legacy mode. In non-legacy mode, the SMBus
command USB_ATTACH (opcode 0xAA55) or USB_ATTACH_WITH_SMBUS (opcode 0xAA56) will finish the configu-
ration.
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USB7002
5.1.7
OTP CONFIGURATION STAGE (CFG_OTP)
Once the SOC has indicated that it is done with configuration, all configuration data is combined in this stage. The
default data, the SOC configuration data, and the OTP data are all combined in the firmware and the device is pro-
grammed.
5.1.8
HUB CONNECT STAGE (USB_ATTACH)
Once the hub registers are updated through default values, SMBus master, and OTP, the device firmware will enable
attaching the USB host by setting the USB_ATTACH bit in the HUB_CMD_STAT register (for USB 2.0) and the
USB3_HUB_ENABLE bit (for USB 3.1). The device will remain in the Hub Connect stage indefinitely.
5.1.9
NORMAL MODE (NORMAL_MODE)
Lastly, the hub enters Normal Mode of operation. In this stage full USB operation is supported under control of the USB
Host on the upstream port. The device will remain in the normal mode until the operating mode is changed by the sys-
tem.
If RESET_N is asserted low, then Standby Mode is entered. The device may then be placed into any of the designated
hub stages. Asserting a soft disconnect on the upstream port will cause the hub to return to the Hub Connect stage until
the soft disconnect is negated.
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USB7002
6.0
DEVICE CONFIGURATION
The device supports a large number of features (some mutually exclusive), and must be configured in order to correctly
function when attached to a USB host controller. Microchip provides a comprehensive software programming tool,
MPLAB Connect Configurator (formerly ProTouch2), for OTP configuration of various USB7002 functions and registers.
All configuration is to be performed via the MPLAB Connect Configurator programming tool. For additional information
on this tool, refer to the MPLAB Connect Configurator programming tool product page at http://www.microchip.com/
design-centers/usb/mplab-connect-configurator.
Additional information on configuring the USB7002 is also provided in the “Configuration of the USB7002/USB705x”
application note, which contains details on the hub operational mode, SOC configuration stage, OTP configuration, USB
configuration, and configuration register definitions. This application note, along with additional USB7002 resources,
can be found on the Microchip USB7002 product page at www.microchip.com/USB7002.
Note:
Note:
The USB7002 requires external firmware to operate. Refer to the “Configuration of the USB7002/
USB705x” application note for additional information.
Device configuration straps and programmable pins are detailed in Section 3.3, Configuration Straps and
Programmable Functions.
Refer to Section 7.0, Device Interfaces for detailed information on each device interface.
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7.0
DEVICE INTERFACES
The USB7002 provides multiple interfaces for configuration, external memory access, etc.. This section details the var-
ious device interfaces:
• SPI/SQI Master Interface
• SMBus/I2C Master/Slave Interfaces
• I2S Interface
• UART Interface
Note:
For details on how to enable each interface, refer to Section 3.3, Configuration Straps and Programmable
Functions.
For information on device connections, refer to Section 4.0, Device Connections. For information on device
configuration, refer to Section 6.0, Device Configuration.
Microchip provides a comprehensive software programming tool, MPLAB Connect Configurator (formerly
ProTouch2), for configuring the USB7002 functions, registers and OTP memory. All configuration is to be
performed via the MPLAB Connect Configurator programming tool. For additional information on this tool,
refer to th MPLAB Connect Configurator programming tool product page at http://www.microchip.com/
design-centers/usb/mplab-connect-configurator.
7.1
SPI/SQI Master Interface
The SPI/SQI controller has two basic modes of operation: execution of an external hub firmware image, or the USB to
SPI bridge. On power up, the firmware looks for an external SPI flash device that contains a valid signature of 2DFU
(device firmware upgrade) beginning at address 0x3FFFA. If a valid signature is found, then the external ROM mode is
enabled and the code execution begins at address 0x0000 in the external SPI device. If a valid signature is not found,
then execution continues from internal ROM and the SPI interface can be used as a USB to SPI bridge.
The second mode of operation is the USB to SPI bridge operation. Additional details on this feature can be found in
Section 8.8, USB to SPI Bridging.
Table 7-1 details how the associated pins are mapped in SPI vs. SQI mode.
TABLE 7-1:
SPI/SQI PIN USAGE
SPI Mode
SQI Mode
Description
SPI_CE_N
SPI_CLK
SPI_D0
SPI_D1
-
SPI_CE_N
SPI_CLK
SPI_D0
SPI_D1
SPI/SQI Chip Enable (Active Low)
SPI/SQI Clock
SPI Data Out; SQI Data I/O 0
SPI Data In; SQI Data I/O 1
SQI Data I/O 2
SPI_D2
SPI_D3
-
SQI Data I/O 3
Note:
For SPI/SQI master timing information, refer to Section 9.6.8, SPI/SQI Master Timing.
7.2
SMBus/I2C Master/Slave Interfaces
The device provides two independent SMBus/I2C controllers (Slave, and Master) which can be used to access internal
device run time registers or program the internal OTP memory. The device contains two 128 byte buffers to enable
simultaneous master/slave operation and to minimize firmware overhead in processed I2C packets. The I2C interfaces
support 100KHz Standard-mode (Sm) and 400KHz Fast Mode (Fm) operation.
The SMBus/I2C interfaces are assigned to programmable pins (PFx) and therefore the device must be programmed into
specific configurations to enable specific interfaces. Refer to Section 3.3.4, PF[31:4] Configuration (CFG_STRAP[2:1])
for additional information.
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USB7002
Note:
For SMBus/I2C timing information, refer to Section 9.6.5, SMBus Timing and Section 9.6.6, I2C Timing.
7.3
I2S Interface
The device provides an integrated I2S interface to facilitate the connection of digital audio devices. The I2S interface
conforms to the voltage, power, and timing characteristics/specifications as set forth in the I2S-Bus Specification, and
consists of the following signals:
• I2S_SDI: Serial Data Input
• I2S_SDO: Serial Data Output
• I2S_SCK: Serial Clock
• I2S_LRCK: Left/Right Clock (SS/FSYNC)
• I2S_MCLK: Master Clock
• MIC_DET: Microphone Plug Detect
Each audio connection is half-duplex, so I2S_SDO exists only on the transmit side and I2S_SDI exists only on the
receive side of the interface. Some codecs refer to the Serial Clock (I2S_SCK) as Baud/Bit Clock (BCLK). Also, the Left/
Right Clock is commonly referred to as LRC or LRCK. The I2S and other audio protocols refer to LRC as Word Select
(WS).
The following codec is supported by the default settings:
• Analog Devices ADAU1961 (24-bit 48kHz)
Additional codecs are also supported with modifications to the configuration register settings. Use the following table as
a guide for assessing I2S codec compatibility. For additional details on how to implement the necessary configuration
settings, refer to the application note, “USB7002/USB705x I2S Operation”.
TABLE 7-2:
USB TO I2S
Parameter
Supported Values
Sampling Frequency (fs)
MCLK Frequency.
8kHz, 11.025kHz, 12kHz, 16kHz, 22.05kHz, 24kHz, 32kHz, 44.1kHz, 48kHz
From 1*fs to 1024*fs.
(Multiple of Sampling frequency) MCLK can take continuous values also. However, the I2S LRCLK signal is derived
from the MCLK source, so it is advisable to keep MCLK signal frequency “Even
integer Multiple of Sampling frequency”.
Audio Sample size
16-bits/sample, 24-bits/sample, 32-bits/sample
I2S Mode, Left Justified Mode, Right Justified Mode
100kHz and 400kHz
I2S Audio Interface Format
I2C Master Control Interface
Frequency
Audio channels
Mono Mode and Stereo Mode
Enabling disabling the I2S-
Bridge Interfaces
Audio Out only (Speaker Interface) Mode (Or) Audio IN only (Mic Interface) (Or)
Enable both Audio IN and OUT interfaces (Or) Disable both Audio IN and Audio
Out interfaces.
Enabling Disabling of Jack-
Detection interface
Enable the Audio Jack-Insert detection HID interface / Disable the Jack detection
interface.
Note:
For I2S timing information, refer to Section 9.6.7, I2S Timing. For detailed information on utilizing the I2S
interface, refer to the application note “USB7002/USB705x I2S Operation”, which can be found on the
Microchip USB7002 product page at www.microchip.com/USB7002.
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USB7002
7.3.1
MODES OF OPERATION
The USB audio class operates in three ways: Asynchronous, Synchronous and Adaptive. There are also multiple oper-
ating modes, such as hi-res, streaming, etc.. Typically for USB devices, inputs such as microphones are Asynchronous,
and output devices such as speakers are Adaptive. The hardware is set up to handle all three modes of operation. It is
recommended that the following configuration be used: Asynchronous IN; Adaptive OUT; 48Khz streaming mode; Two
channels: 16 bits per channel.
7.3.1.1
Asynchronous IN 48KHz Streaming
In this mode, the codec sampling clock is set to 48Khz based on the local oscillator. This clock is never changed. The
data from the codec is fed into the input FIFO. Since the sampling clock is asynchronous to the host clock, the amount
of data captured in every USB frame will vary. This issue is left for the host to handle. The input FIFO has two markers,
a low water mark (THRESHOLD_LOW_VAL), and a high water mark (THRESHOLD_HIGH_VAL). There are three reg-
isters to determine how much data to send back in each frame. If the amount of data in the FIFO exceeds the high water
mark, then HI_PKT_SIZE worth of data is sent. If the data is between the high and low water mark, the normal MID_P-
KT_SIZE amount of data is sent. If the data is below the low water mark, LO_PKT_SIZE worth of data is sent.
7.3.1.2
Adaptive OUT 48KHz Streaming
In this mode, the codec sampling clock is initially set to 48Khz based on the local oscillator. The host data is fed into the
OUT FIFO. The host will send the same amount of data on every frame, i.e. 48KHz of data based on the host clock. The
codec sampling clock is asynchronous to the host clock. This will cause the amount of data in the OUT FIFO to vary. If
the amount of data in the FIFO exceeds the high water mark, then the sampling clock is increased. If the data is between
the high and low water mark, the sampling clock does not change. If the data is below the low water mark, the sampling
clock is decreased.
7.3.1.3
Synchronous Operation
For synchronous operation, the internal clock must be synchronized with the host SOF. The Frame SOF is nominally
1mS. Since there is significant jitter in the SOFs, there is circuitry provided to measure the SOFs over a long period of
time to get a more accurate reading. The calculated host frequency is used to calculate the codec sampling clock.
7.4
UART Interface
The device incorporates a configurable universal asynchronous receiver/transmitter (UART) that is functionally compat-
ible with the NS 16550AF, 16450, 16450 ACE registers and the 16C550A. The UART performs serial-to-parallel con-
version on received characters and parallel-to-serial conversion on transmit characters. Two sets of baud rates are
provided: 24 Mhz and 16 MHz. When the 24 Mhz source clock is selected, standard baud rates from 50 to 115.2 K are
available. When the source clock is 16 MHz, baud rates from 125 K to 1,000 K are available. The character options are
programmable for the transmission of data in word lengths of from five to eight, 1 start bit; 1, 1.5 or 2 stop bits; even,
odd, sticky or no parity; and prioritized interrupts. The UART contains a programmable baud rate generator that is capa-
ble of dividing the input clock or crystal by a number from 1 to 65535. The UART is also capable of supporting the MIDI
data rate.
The UART interface is assigned to programmable pins (PFx) and therefore the device must be programmed into specific
configurations to enable the interface. Refer to Section 3.3.4, PF[31:4] Configuration (CFG_STRAP[2:1]) for additional
information.
7.4.1
TRANSMIT OPERATION
Transmission is initiated by writing the data to be sent to the TX Holding Register or TX FIFO (if enabled). The data is
then transferred to the TX Shift Register together with a start bit and parity and stop bits as determined by settings in
the Line Control Register. The bits to be transmitted are then shifted out of the TX Shift Register in the order Start bit,
Data bits (LSB first), Parity bit, Stop bit, using the output from the Baud Rate Generator (divided by 16) as the clock.
If enabled, a TX Holding Register Empty interrupt will be generated when the TX Holding Register or the TX FIFO (if
enabled) becomes empty.
When FIFOs are enabled (i.e. bit 0 of the FIFO Control Register is set), the UART can store up to 16 bytes of data for
transmission at a time. Transmission will continue until the TX FIFO is empty. The FIFO’s readiness to accept more data
is indicated by interrupt.
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7.4.2
RECEIVE OPERATION
Data is sampled into the RX Shift Register using the Receive clock, divided by 16. The Receive clock is provided by the
Baud Rate Generator. A filter is used to remove spurious inputs that last for less than two periods of the Receive clock.
When the complete word has been clocked into the receiver, the data bits are transferred to the RX Buffer Register or
to the RX FIFO (if enabled) to be read by the CPU. (The first bit of the data to be received is placed in bit 0 of this reg-
ister.) The receiver also checks that the parity bit and stop bits are as specified by the Line Control Register.
If enabled, an RX Data Received interrupt will be generated when the data has been transferred to the RX Buffer Reg-
ister or, if FIFOs are enabled, when the RX Trigger Level has been reached. Interrupts can also be generated to signal
RX FIFO Character Timeout, incorrect parity, a missing stop bit (frame error) or other Line Status errors.
When FIFOs are enabled (i.e. bit 0 of the FIFO Control Register is set), the UART can store up to 16 bytes of received
data at a time. Depending on the selected RX Trigger Level, interrupt will go active to indicate that data is available when
the RX FIFO contains 1, 4, 8 or 14 bytes of data.
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USB7002
8.0
FUNCTIONAL DESCRIPTIONS
This section details various USB7002 functions, including:
• Downstream Battery Charging
• Port Power Control
• CC Pin Orientation and Detection
• FlexConnect
• Multi-Host Endpoint Reflector
• USB to GPIO Bridging
• USB to I2C Bridging
• USB to SPI Bridging
• USB to UART Bridging
• Link Power Management (LPM)
• Resets
8.1
Downstream Battery Charging
The device can be configured by an OEM to have any of the downstream ports support battery charging. The hub’s role
in battery charging is to provide acknowledgment to a device’s query as to whether the hub system supports USB battery
charging. The hub silicon does not provide any current or power FETs or any additional circuitry to actually charge the
device. Those components must be provided externally by the OEM.
FIGURE 8-1:
BATTERY CHARGING EXTERNAL POWER SUPPLY
DC Power
Microchip
Hub
PRT_CTLx
VBUS[n]
If the OEM provides an external supply capable of supplying current per the battery charging specification, the hub can
be configured to indicate the presence of such a supply from the device. This indication, via the PRT_CTLx pins, is on
a per port basis. For example, the OEM can configure two ports to support battery charging through high current power
FETs and leave the other two ports as standard USB ports.
The port control signals are assigned to programmable pins (PFx) and therefore the device must be programmed into
specific configurations to enable the signals. Refer to Section 3.3.4, PF[31:4] Configuration (CFG_STRAP[2:1]) for addi-
tional information.
For detailed information on utilizing the battery charging feature, refer to the application note “USB Battery Charging
with Microchip USB7002 and USB705x Hubs”, which can be found on the Microchip USB7002 product page www.micro-
chip.com/USB7002.
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USB7002
8.2
Port Power Control
Port power and over-current sense share the same pin (PRT_CTLx) for each port. These functions can be controlled
directly from the USB hub, or via the processor.
Note:
The PRT_CTLx function is assigned to programmable function pins (PFx) via configuration straps. Refer
to Section 3.3.4, PF[31:4] Configuration (CFG_STRAP[2:1]) for additional information.
8.2.1
PORT POWER CONTROL USING USB POWER SWITCH
When operating in combined mode, the device will have one port power control and over-current sense pin for each
downstream port. When disabling port power, the driver will actively drive a '0'. To avoid unnecessary power dissipation,
the pull-up resistor will be disabled at that time. When port power is enabled, it will disable the output driver and enable
the pull-up resistor, making it an open drain output. If there is an over-current situation, the USB Power Switch will assert
the open drain OCS signal. The Schmidt trigger input will recognize that as a low. The open drain output does not inter-
fere. The over-current sense filter handles the transient conditions such as low voltage while the device is powering up.
FIGURE 8-2:
PORT POWER CONTROL WITH USB POWER SWITCH
Pull‐Up Enable
5V
50k
PRT_CTLx
OCS
USB Power
Switch
EN
PRTPWR
USB
Device
FILTER
OCS
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USB7002
8.2.1.1
Port Power Control Using Poly Fuse
When using the device with a poly fuse, there is no need for an output power control. A single port power control and
over-current sense for each downstream port is still used from the Hub's perspective. When disabling port power, the
driver will actively drive a '0'. This will have no effect as the external diode will isolate pin from the load. When port power
is enabled, it will disable the output driver and enable the pull-up resistor. This means that the pull-up resistor is providing
3.3 volts to the anode of the diode. If there is an over-current situation, the poly fuse will open. This will cause the cath-
ode of the diode to go to 0 volts. The anode of the diode will be at 0.7 volts, and the Schmidt trigger input will register
this as a low resulting in an over-current detection. The open drain output does not interfere.
FIGURE 8-3:
PORT POWER CONTROL USING A POLY FUSE
5V
Pull-Up Enable
Poly Fuse
50k
PRT_CTLx
USB
Device
PRTPWR
FILTER
OCS
8.3
CC Pin Orientation and Detection
The device provides CC1 and CC2 pins on all Type-C ports for cable plug orientation and detection of a USB Type-C
receptacle. The device also integrates a comparator and DAC circuit to implement Type-C attach and detach functions,
which supports up to eight programmable thresholds for attach detection between a UFP and DFP. When operating as
a UFP, the device supports detecting changes in the DFP’s advertised thresholds. Default nominal values for the thresh-
olds detected by the CC comparator are:
• 0.20 V
• 0.40 V
• 0.66 V
• 0.80 V
• 1.23 V
• 1.60 V
• 2.60 V
When operating as a DFP, the device implements current sources to advertise current charging capabilities on both CC
pins. When a UFP connection is established, the current driven across the CC pins creates a voltage across the UFP’s
Rd pull-down that can be detected by the integrated CC comparator. When connected to an active cable, an alternative
pull-down, Ra, appears on the CC pin.
When operating as a UFP, the device applies an Rd pull-down on both CC lines and waits for a DFP connection from
the assertion of VBUS. The CC comparator is used to determine the advertised current charger capabilities supported
by the DFP.
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USB7002
VCONN is a 5V supply used to power circuitry in the USB Type-C plug that is required to implement Electronically
Marked Cables. By default the DFP always sources VCONN when connected to an active cable. The USB7002 requires
the use of two external VCONN FETs. The device provides the enables for these FETs, and can detect an OCS by mon-
itoring the output voltage of the FET via the CC pins.
The device also implements a comparator for determining when a VBUS is within a programmed range, vSafe5V or
vSafe0V. VBUS is divided down externally to provide a nominal 3.3V at the VBUS_MON pin. For a DFP, the VBUS com-
parator is useful to detect when VBUS is within the desired range per power delivery negotiations. For a UFP, the VBUS
comparator is utilized to determine when a DFP is attached or detached. It may also use the comparator to determine
when VBUS is within a new voltage range per power delivery negotiations.
Note:
The native USB Type-C functionality (including CC pin orientation and detection features) is managed
autonomously by the USB7002.
8.4
FlexConnect
The device allows the upstream port to be swapped with any downstream port, enabling any USB port to assume the
role of USB host at any time during hub operation. This host role exchange feature is called FlexConnect. Additionally,
the USB 2.0 ports can be flexed independently of the USB 3.1 ports.
This functionality can be used in two primary ways:
1. Host Swapping: This functionality can be achieved through a hub wherein a host and device can agree to swap
the host/device relationship; The host becomes a device, and the device becomes a host.
2. Host Sharing: A USB ecosystem can be shared between multiple hosts. Note that only 1 host may access to
the USB tree at a time.
FlexConnect can be enabled through any of the following three methods:
• I2C Control: The embedded I2C slave can be used to control the state of the FlexConnect feature through basic
write/read operations.
• USB Command: FlexConnect can be initiated via a special USB command directed to the hub’s internal Hub
Feature Controller device.
• Direct Pin Control: Any available GPIO pin on the hub can be assigned the role of a FlexConnect control pin.
For detailed information on utilizing the FlexConnect feature, refer to the application note “USB7002/USB705x FlexCon-
nect Operation”, which can be found on the Microchip USB7002 product page at www.microchip.com/USB7002.
8.5
Multi-Host Endpoint Reflector
The internal Multi-Host Endpoint Reflector allows for smart-phone automotive mode sessions to be entered on the
downstream ports. The device supports the Multi-Host Endpoint Reflector on downstream ports.
The Multi-Host Endpoint Reflector uses standard Network Control Model (NCM) device protocol, which is a sub-class
of Communication Device Class (CDC) group of protocols. Standard NCM USB drivers may be utilized; No custom driv-
ers are required.
AMulti-Host Endpoint Reflector session may be entered on only 1 downstream port at a time. Entry into Multi-Host mode
is initiated via a no data Control USB transfer addressed to the internal Multi-Host Endpoint Reflector device in the hub.
The USB7002 has two internal USB devices. The Multi-Host Endpoint Reflector is a Composite WinUSB and NCM
device. The Hub Feature Controller is a WinUSB device which enables the USB bridging functions.
The hub ports which are connected to both the Multi-Host Endpoint Reflector and Hub Feature Controller are both con-
figured as non-removable.
For detailed information on utilizing the multi-host endpoint reflector feature, refer to the application note “USB7002/
USB705x Multi-Host Endpoint Reflector Operation”, which can be found on the Microchip USB7002 product page at
www.microchip.com/USB7002.
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USB7002
8.6
USB to GPIO Bridging
The USB to GPIO bridging feature provides system designers expanded system control and potential BOM reduction.
General Purpose Input/Outputs (GPIOs) may be used for any general 3.3V level digital control and input functions.
Commands may be sent from the USB Host to the internal Hub Feature Controller device in the Microchip hub to per-
form the following functions:
• Set the direction of the GPIO (input or output)
• Enable a pull-up resistor
• Enable a pull-down resistor
• Read the state
• Set the state
For detailed information on utilizing the USB to GPIO bridging feature, refer to the application note “USB to GPIO Bridg-
ing with Microchip USB7002 and USB705x Hubs”, which can be found on the Microchip USB7002 product page at
www.microchip.com/USB7002.
8.7
USB to I2C Bridging
The USB to I2C bridging feature provides system designers expanded system control and potential BOM reduction. The
use of a separate USB to I2C device is no longer required and a downstream USB port is not lost, as occurs when a
standalone USB to I2C device is implemented.
Commands may be sent from the USB Host to the internal Hub Feature Controller device in the Microchip hub to per-
form the following functions:
• Configure I2C Pass-Through Interface
• I2C Write
• I2C Read
For detailed information on utilizing the USB to I2C bridging feature, refer to the application note “USB to I2C Bridging
with Microchip USB7002 and USB705x Hubs”, which can be found on the Microchip USB7002 product page at
www.microchip.com/USB7002.
8.8
USB to SPI Bridging
The USB to SPI bridging feature provides system designers expanded system control and potential BOM reduction. The
use of a separate USB to SPI device is no longer required and a downstream USB port is not lost, as occurs when a
standalone USB to SPI device is implemented.
Commands may be sent from the USB Host to the internal Hub Feature Controller device in the Microchip hub to per-
form the following functions:
• Enable SPI Pass-Through Interface
• SPI Write/Read
• Disable SPI Pass-Through Interface
For detailed information on utilizing the USB to SPI bridging feature, refer to the application note “USB to SPI Bridging
with Microchip USB7002 and USB705x Hubs”, which can be found on the Microchip USB7002 product page at
www.microchip.com/USB7002.
8.9
USB to UART Bridging
The USB to UART bridging feature provides system designers with expanded system control and potential BOM reduc-
tion. When using Microchip’s USB hubs, a separate USB to UART device is no longer required and a downstream USB
port is not lost, as occurs when a standalone USB to UART device is implemented.
Commands may be sent from the USB Host to the internal Hub Feature Controller device in the Microchip hub to per-
form the following functions:
• Enable/Disable UART Interface
• Set UART Interface Baud Rate
• UART Write
• UART Read
DS00002670D-page 38
2018-2019 Microchip Technology Inc.
USB7002
For detailed information on utilizing the USB to UART bridging feature, refer to the application note “USB to UART Bridg-
ing with Microchip USB7002 and USB705x Hubs”, which can be found on the Microchip USB7002 product page at
www.microchip.com/USB7002.
8.10 Link Power Management (LPM)
The device supports the L0 (On), L1 (Sleep), and L2 (Suspend) link power management states. These supported LPM
states offer low transitional latencies in the tens of microseconds versus the much longer latencies of the traditional USB
suspend/resume in the tens of milliseconds. The supported LPM states are detailed in Table 8-1.
TABLE 8-1:
State
LPM STATE DEFINITIONS
Description
Entry/Exit Time to L0
L2
Suspend
Entry: ~3 ms
Exit: ~2 ms (from start of RESUME)
L1
L0
Sleep
Entry: <10 us
Exit: <50 us
Fully Enabled (On)
-
8.11 Resets
The device includes the following chip-level reset sources:
• Power-On Reset (POR)
• External Chip Reset (RESET_N)
• USB Bus Reset
8.11.1
POWER-ON RESET (POR)
A power-on reset occurs whenever power is initially supplied to the device, or if power is removed and reapplied to the
device. A timer within the device will assert the internal reset per the specifications listed in Section 9.6.2, Power-On
and Configuration Strap Timing.
8.11.2
EXTERNAL CHIP RESET (RESET_N)
A valid hardware reset is defined as assertion of RESET_N, after all power supplies are within operating range, per the
specifications in Section 9.6.3, Reset and Configuration Strap Timing. While reset is asserted, the device (and its asso-
ciated external circuitry) enters Standby Mode and consumes minimal current.
Assertion of RESET_N causes the following:
1. The PHY is disabled and the differential pairs will be in a high-impedance state.
2. All transactions immediately terminate; no states are saved.
3. All internal registers return to the default state.
4. The external crystal oscillator is halted.
5. The PLL is halted.
Note:
All power supplies must have reached the operating levels mandated in Section 9.2, Operating Condi-
tions**, prior to (or coincident with) the assertion of RESET_N.
8.11.3
USB BUS RESET
In response to the upstream port signaling a reset to the device, the device performs the following:
1. Sets default address to 0.
2. Sets configuration to Unconfigured.
3. Moves device from suspended to active (if suspended).
4. Complies with the USB Specification for behavior after completion of a reset sequence.
The host then configures the device in accordance with the USB Specification.
Note:
The device does not propagate the upstream USB reset to downstream devices.
2018-2019 Microchip Technology Inc.
DS00002670D-page 39
USB7002
9.0
9.1
OPERATIONAL CHARACTERISTICS
Absolute Maximum Ratings*
+1.2 V Supply Voltage (VDD12) (Note 1)...............................................................................................-0.5 V to +1.32 V
+3.3 V Supply Voltage (VDD33) (Note 1).................................................................................................-0.5 V to +4.6 V
Positive voltage on input signal pins, with respect to ground (Note 2)................................................................... +4.6 V
Negative voltage on input signal pins, with respect to ground ................................................................................ -0.5 V
Positive voltage on XTALI/CLK_IN, with respect to ground................................................................................+3.63 V
Positive voltage on USB DP/DM signal pins, with respect to ground......................................................................+6.0 V
Positive voltage on USB 3.1 Gen 1 USB3UP_xxxx and USB3DN_xxxx signal pins, with respect to ground..........1.32 V
Storage Temperature.............................................................................................................................. -55oC to +150oC
Junction Temperature............................................................................................................................................+125oC
Lead Temperature Range............................................................................................Refer to JEDEC Spec. J-STD-020
HBM ESD Performance ........................................................................................................................................ +/-3 kV
1: When powering this device from laboratory or system power supplies, it is important that the absolute max-
imum ratings not be exceeded or device failure can result. Some power supplies exhibit voltage spikes on
their outputs when AC power is switched on or off. In addition, voltage transients on the AC power line may
appear on the DC output. If this possibility exists, it is suggested that a clamp circuit be used.
2: This rating does not apply to the following pins: All USB DM/DP pins, XTAL1/CLK_IN, and XTALO
*Stresses exceeding those listed in this section could cause permanent damage to the device. This is a stress rating
only. Exposure to absolute maximum rating conditions for extended periods may affect device reliability. Functional
operation of the device at any condition exceeding those indicated in Section 9.2, Operating Conditions**, Section 9.5,
DC Specifications, or any other applicable section of this specification is not implied.
9.2
Operating Conditions**
+1.2 V Supply Voltage (VDD12)..........................................................................................................+1.08 V to +1.32 V
+3.3 V Supply Voltage (VDD33)..............................................................................................................+3.0 V to +3.6 V
Input Signal Pins Voltage (Note 2) ...........................................................................................................-0.3 V to +3.6 V
XTALI/CLK_IN Voltage...........................................................................................................................-0.3 V to +3.6 V
USB 2.0 DP/DM Signal Pins Voltage .......................................................................................................-0.3 V to +5.5 V
USB 3.1 Gen 1 USB3UP_xxxx and USB3DN_xxxx Signal Pins Voltage...............................................-0.3 V to +1.32 V
Ambient Operating Temperature in Still Air (TA)..................................................................................................... Note 3
+1.2 V Supply Voltage Rise Time (TRT in Figure 9-1) ............................................................................................ 400 µs
+3.3 V Supply Voltage Rise Time (TRT in Figure 9-1) ............................................................................................ 400 µs
3: 0oC to +70oC for commercial version, -40oC to +85oC for industrial version.
**Proper operation of the device is ensured only within the ranges specified in this section.
Note:
Do not drive input signals without power supplied to the device.
DS00002670D-page 40
2018-2019 Microchip Technology Inc.
USB7002
FIGURE 9-1:
SUPPLY RISE TIME MODEL
Voltage
VDD33
TRT
3.3 V
1.2 V
100%
100%
90%
90%
VDD12
10%
VSS
t90%
Time
t10%
9.3
Package Thermal Specifications
TABLE 9-1:
PACKAGE THERMAL PARAMETERS
Symbol
°C/W
Velocity (Meters/s)
JA
JT
JC
19
16
0
1
0
1
0
1
0.1
0.1
1.3
1.3
Note:
Thermal parameters are measured or estimated for devices in a multi-layer 2S2P PCB per JESDN51. For
industrial applications, the USB7002 requires multi-layer 2S4P PCB power dissipation.
2018-2019 Microchip Technology Inc.
DS00002670D-page 41
USB7002
9.4
Power Consumption
This section details the power consumption of the device as measured during various modes of operation. Power dis-
sipation is determined by temperature, supply voltage, and external source/sink requirements.
TABLE 9-2:
DEVICE POWER CONSUMPTION
Typical (mA)
Typical Power
(mW)
VDD12
VDD33
Global Suspend
No VBUS
10
9
11
11
0
48.3
47.1
5
Reset/Standby
Idle
3
63
447
20
62
140
741
Active Idle
SuperSpeed Active Operation
2 SuperSpeed Active Ports
1 SuperSpeed Active Port
Hi-Speed Active Operation
465
358
56
44
743
576
4 Hi-Speed Active Ports
3 Hi-Speed Active Ports
2 Hi-Speed Active Ports
1 Hi-Speed Active Port
67
66
64
63
49
41
32
28
241
215
181
168
Full-Speed Active Operation
4 Full-Speed Active Ports
3 Full-Speed Active Ports
62
62
62
62
31
30
30
29
178
174
173
172
2 Full-Speed Active Ports
1 Full-Speed Active Port
Mixed SuperSpeed / Hi-Speed Active Operation
2 SS / 2 HS Active Ports
440
64
738
DS00002670D-page 42
2018-2019 Microchip Technology Inc.
USB7002
9.5
DC Specifications
TABLE 9-3:
I/O DC ELECTRICAL CHARACTERISTICS
Parameter
Symbol
Min
Typical
Max
Units
Notes
I Type Input Buffer
Low Input Level
VIL
VIH
Note 4
V
V
High Input Level
1.25
IS Type Input Buffer
Low Input Level
VIL
VIH
Note 4
240
V
V
High Input Level
1.25
100
Schmitt Trigger Hysteresis
VHYS
160
mV
(VIHT - VILT
)
O12 Type Output Buffer
Low Output Level
VOL
VOH
0.4
0.4
V
V
IOL = 12 mA
High Output Level
VDD33-0.4
I
OH = -12 mA
OD12 Type Output Buffer
Low Output Level
VOL
V
IOL = 12 mA
Note 5
ICLK Type Input Buffer
(XTALI Input)
Low Input Level
VIL
VIH
0.35
1.2
V
V
High Input Level
0.9
IO-U Type Buffer
Note 6
(See Note 6)
4: 0.42V for interface using open drain with pull-ups to voltages up to 2.1V, 0.34V for interface using open drain
with pull-ups to voltages greater than 2.1V.
5: XTALI can optionally be driven from a 25 MHz singled-ended clock oscillator.
6: Refer to the USB 3.1 Gen 1 Specification for USB DC electrical characteristics.
2018-2019 Microchip Technology Inc.
DS00002670D-page 43
USB7002
9.6
AC Specifications
This section details the various AC timing specifications of the device.
9.6.1
POWER SUPPLY AND RESET_N SEQUENCE TIMING
Figure 9-2 illustrates the recommended power supply sequencing and timing for the device. VDD33 should rise after or
at the same rate as VDD12. Similarly, RESET_N and/or VBUS_DET should rise after or at the same rate as VDD33.
VBUS_DET and RESET_N do not have any other timing dependencies.
FIGURE 9-2:
POWER SUPPLY AND RESET_N SEQUENCE TIMING
VDD12
tVDD33
VDD33
treset
RESET_N/
VBUS_DET
TABLE 9-4:
Symbol
POWER SUPPLY AND RESET_N SEQUENCE TIMING
Description
Min
Typ
Max
Units
tVDD33
treset
VDD12 to VDD33 rise time
0
0
ms
ms
VDD33 to RESET_N/VBUS_DET rise time
9.6.2
POWER-ON AND CONFIGURATION STRAP TIMING
Figure 9-3 illustrates the configuration strap valid timing requirements in relation to power-on, for applications where
RESET_N is not used at power-on. In order for valid configuration strap values to be read at power-on, the following
timing requirements must be met. The operational levels (Vopp) for the external power supplies are detailed in
Section 9.2, Operating Conditions**.
FIGURE 9-3:
POWER-ON CONFIGURATION STRAP VALID TIMING
All External
Power Supplies
Vopp
tcsh
Configuration
Straps
TABLE 9-5:
Symbol
tcsh
POWER-ON CONFIGURATION STRAP LATCHING TIMING
Description
Min
Typ
Max
Units
Configuration strap hold after external power supplies at opera-
tional levels
1
ms
Device configuration straps are also latched as a result of RESET_N assertion. Refer to Section 9.6.3, Reset and Con-
figuration Strap Timing for additional details.
DS00002670D-page 44
2018-2019 Microchip Technology Inc.
USB7002
9.6.3
RESET AND CONFIGURATION STRAP TIMING
Figure 9-4 illustrates the RESET_N pin timing requirements and its relation to the configuration strap pins. Assertion of
RESET_N is not a requirement. However, if used, it must be asserted for the minimum period specified. Refer to
Section 8.11, Resets for additional information on resets. Refer to Section 3.3, Configuration Straps and Programmable
Functions for additional information on configuration straps.
FIGURE 9-4:
RESET_N CONFIGURATION STRAP TIMING
trstia
RESET_N
tcsh
Configuration
Straps
TABLE 9-6:
Symbol
RESET_N CONFIGURATION STRAP TIMING
Description
Min
Typ
Max
Units
trstia
tcsh
RESET_N input assertion time
5
1
s
Configuration strap pins hold after RESET_N deassertion
ms
Note:
The clock input must be stable prior to RESET_N deassertion.
Configuration strap latching and output drive timings shown assume that the Power-On reset has finished
first otherwise the timings in Section 9.6.2, Power-On and Configuration Strap Timing apply.
9.6.4
USB TIMING
All device USB signals conform to the voltage, power, and timing characteristics/specifications as set forth in the Uni-
versal Serial Bus Specification. Please refer to the Universal Serial Bus Revision 3.1 Specification, available at http://
www.usb.org/developers/docs.
9.6.5
SMBUS TIMING
All device SMBus signals conform to the voltage, power, and timing characteristics/specifications as set forth in the Sys-
tem Management Bus Specification. Please refer to the System Management Bus Specification, Version 1.0, available
at http://smbus.org/specs.
2
9.6.6
I C TIMING
All device I2C signals conform to the 100KHz Standard-mode (Sm) and 400KHz Fast Mode (Fm) voltage, power, and
timing characteristics/specifications as set forth in the I2C-Bus Specification. Please refer to the I2C-Bus Specification,
available at http://www.nxp.com/documents/user_manual/UM10204.pdf.
2
9.6.7
I S TIMING
All device I2S signals conform to the voltage, power, and timing characteristics/specifications as set forth in the I2S-Bus
Specification. Please refer to the I2S-Bus Specification, available at http://www.nxp.com/acrobat_download/various/
I2SBUS.pdf.
2018-2019 Microchip Technology Inc.
DS00002670D-page 45
USB7002
9.6.8
SPI/SQI MASTER TIMING
This section specifies the SPI/SQI master timing requirements for the device.
FIGURE 9-5:
SPI/SQI MASTER TIMING
tceh
tceh
SPI_CE_N
SPI_CLK
tfc
tcel
tclq
tdh
Input
data valid
SPI_D[3:0] (in)
SPI_D[3:0] (out)
tos toh
tov
toh
Output
data valid
Output
data valid
TABLE 9-7:
Symbol
SPI/SQI MASTER TIMING (30 MHZ OPERATION)
Description
Min
Typ
Max
Units
tfc
tceh
tclq
tdh
tos
Clock frequency
30
MHz
ns
Chip enable (SPI_CE_N) high time
Clock to input data
100
13
ns
Input data hold time
0
5
ns
Output setup time
ns
toh
tov
tcel
tceh
Output hold time
5
ns
Clock to output valid
4
ns
Chip enable (SPI_CE_N) low to first clock
Last clock to chip enable (SPI_CE_N) high
12
12
ns
ns
TABLE 9-8:
Symbol
SPI/SQI MASTER TIMING (60 MHZ OPERATION)
Description
Min
Typ
Max
Units
tfc
tceh
tclq
tdh
tos
Clock frequency
60
MHz
ns
Chip enable (SPI_CE_N) high time
Clock to input data
50
9
ns
Input data hold time
0
5
ns
Output setup time
ns
toh
tov
tcel
tceh
Output hold time
5
ns
Clock to output valid
4
ns
Chip enable (SPI_CE_N) low to first clock
Last clock to chip enable (SPI_CE_N) high
12
12
ns
ns
DS00002670D-page 46
2018-2019 Microchip Technology Inc.
USB7002
9.7
Clock Specifications
The device can accept either a 25MHz crystal or a 25MHz single-ended clock oscillator input. If the single-ended clock
oscillator method is implemented, XTALO should be left unconnected and XTALI/CLK_IN should be driven with a
nominal 0-3.3V clock signal. The input clock duty cycle is 40% minimum, 50% typical and 60% maximum.
It is recommended that a crystal utilizing matching parallel load capacitors be used for the crystal input/output signals
(XTALI/XTALO). The following circuit design (Figure 9-6) and specifications (Table 9-9) are required to ensure proper
operation.
FIGURE 9-6:
25MHZ CRYSTAL CIRCUIT
USB7002
XTALO
Y1
XTALI
C2
C1
2018-2019 Microchip Technology Inc.
DS00002670D-page 47
USB7002
9.7.1
CRYSTAL SPECIFICATIONS
It is recommended that a crystal utilizing matching parallel load capacitors be used for the crystal input/output signals
(XTALI/XTALO). Refer to Table 9-9 for the recommended crystal specifications.
TABLE 9-9:
CRYSTAL SPECIFICATIONS
Parameter
Symbol
Min
Nom
Max
Units
Notes
Crystal Cut
AT, typ
Crystal Oscillation Mode
Crystal Calibration Mode
Frequency
Frequency Tolerance @ 25oC
Frequency Stability Over Temp
Frequency Deviation Over Time
Total Allowable PPM Budget
Shunt Capacitance
Fundamental Mode
Parallel Resonant Mode
Ffund
Ftol
-
25.000
-
MHz
PPM
PPM
PPM
PPM
pF
-
-
±50
Ftemp
Fage
-
-
±50
-
±3 to 5
-
Note 7
-
-
7 typ
20 typ
-
±100
CO
CL
PW
R1
-
-
Load Capacitance
-
-
pF
Drive Level
100
-
uW
Equivalent Series Resistance
Operating Temperature Range
XTALI/CLK_IN Pin Capacitance
XTALO Pin Capacitance
-
-
60
Ω
oC
Note 8
-
Note 9
-
-
3 typ
3 typ
-
-
pF
Note 10
Note 10
pF
7: Frequency Deviation Over Time is also referred to as Aging.
8: 0 °C for commercial version, -40 °C for industrial version.
9: +70 °C for commercial version, +85 °C for industrial version.
10: This number includes the pad, the bond wire and the lead frame. PCB capacitance is not included in this
value. The XTALI/CLK_IN pin, XTALO pin and PCB capacitance values are required to accurately calcu-
late the value of the two external load capacitors. These two external load capacitors determine the accu-
racy of the 25.000 MHz frequency.
9.7.2
EXTERNAL REFERENCE CLOCK (CLK_IN)
When using an external reference clock, the following input clock specifications are suggested:
• 25 MHz
• 50% duty cycle ±10%, ±100 ppm
• Jitter < 100 ps RMS
DS00002670D-page 48
2018-2019 Microchip Technology Inc.
USB7002
10.0 PACKAGE OUTLINE
Note:
For the most current package drawings, see the Microchip Packaging Specification at:
http://www.microchip.com/packaging.
FIGURE 10-1:
100-VQFN PACKAGE (DRAWING)
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2018-2019 Microchip Technology Inc.
DS00002670D-page 49
USB7002
Note:
For the most current package drawings, see the Microchip Packaging Specification at:
http://www.microchip.com/packaging.
FIGURE 10-2:
100-VQFN PACKAGE (DIMENSIONS)
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DS00002670D-page 50
2018-2019 Microchip Technology Inc.
USB7002
Note:
For the most current package drawings, see the Microchip Packaging Specification at:
http://www.microchip.com/packaging.
FIGURE 10-3:
100-VQFN PACKAGE (LAND-PATTERN)
C1
X2
EV
100
1
2
ØV
C2 Y2
EV
G1
Y1
X1
SILK SCREEN
E
RECOMMENDED LAND PATTERN
Units
Dimension Limits
E
MILLIMETERS
NOM
0.40 BSC
MIN
0.20
MAX
Contact Pitch
Optional Center Pad Width
Optional Center Pad Length
Contact Pad Spacing
X2
Y2
C1
C2
X1
Y1
G1
V
8.10
8.10
11.70
11.70
Contact Pad Spacing
Contact Pad Width (X100)
Contact Pad Length (X100)
Contact Pad to Center Pad (X100)
Thermal Via Diameter
0.20
1.05
0.33
1.20
Thermal Via Pitch
EV
Notes:
1. Dimensioning and tolerancing per ASME Y14.5M
BSC: Basic Dimension. Theoretically exact value shown without tolerances.
2. For best soldering results, thermal vias, if used, should be filled or tented to avoid solder loss during
reflow process
Microchip Technology Drawing C04-2407A
2018-2019 Microchip Technology Inc.
DS00002670D-page 51
USB7002
APPENDIX A: REVISION HISTORY
TABLE A-1:
REVISION HISTORY
Section/Figure/Entry
Revision Level & Date
Correction
DS00002670D (08-09-19) Section 2.1, General Description
• Updated last sentence of the first para-
graph for greater clarity.
Document Title
• Title modified changing “Controller” to
“PD Smart”
Key Benefits on cover
• “USB Power Delivery Billboard Device
Support” bullet removed
Cover
Added TID data
Table 3-5, Table 3-6
• Changed PF15 from PRT_CTL3 to
PRT_CTL2
• Changed PF16 from PRT_CTL2 to
PRT_CTL3
• Updated programmable functions
descriptions table to match new assigned
PRT_CTLx and PRT_CTLx_U3 numbers.
Section 3.4, Physical and Logical Port Added new section with physical and logical
Mapping
port mapping.
Figure 2-1
Updated internal PHY numbering to match
physical port numbering detailed in new
Section 3.4, Physical and Logical Port Map-
ping.
Figure 4-3, SMBus/I2C Connections
Updated suggested nominal external resistor
values. Added note under figure: “Resistor
values detailed in Figure 4-3 are suggestions.
Optimal pull-up values may vary dependent
on external factors.”
Section 5.1.5, SMBus Check Stage
(SMBUS_CHECK)
Updated second sentence: “If pull-ups are
detected on both pins...”
DS00002670C (02-20-19) All
DS00002670B (09-07-18) All
Public Release
Initial Release
DS00002670D-page 52
2018-2019 Microchip Technology Inc.
USB7002
PRODUCT IDENTIFICATION SYSTEM
To order or obtain information, e.g., on pricing or delivery, refer to the factory or the listed sales office.
[X](1)
PART NO.
[X]
XXX
XXX
-
/
Examples:
Device Tape and Reel
Option
Temperature
Range
Package
Automotive
Code
a)
USB7002/KDX
Tray, 0°C to +70°C, 100-pin VQFN
USB7002T/KDX
b)
Tape & reel, 0°C to +70°C, 100-pin VQFN
c)
d)
e)
USB7002-I/KDX
Tray, -40°C to +85°C, 100-pin VQFN
Device:
USB7002
USB7002T-I/KDX
Tape & reel, -40°C to +85°C, 100-pin VQFN
Tape and Reel
Option:
Blank = Standard packaging (tray)
T
= Tape and Reel (Note 1)
USB7002-I/KDXVAO
Tray, -40°C to +85°C, Automotive Grade 3,
100-pin VQFN
USB7002T-I/KDXVAO
Tape & reel, -40°C to +85°C, Automotive Grade 3,
100-pin VQFN
Temperature
Range:
Blank
I
=
=
0C to +70C (Commercial)
-40C to +85C (Industrial/Automotive Grade 3)
f)
Package:
KDX
= 100-pin VQFN
Note 1:
Tape and Reel identifier only appears in
the catalog part number description. This
identifier is used for ordering purposes and
is not printed on the device package.
Check with your Microchip Sales Office
for package availability with the Tape and
Reel option.
Automotive Code: Vxx
= 3 character code with “V” prefix,
specifying automotive product.
2018-2019 Microchip Technology Inc.
DS00002670D-page 53
USB7002
THE MICROCHIP WEB SITE
Microchip provides online support via our WWW site at www.microchip.com. This web site is used as a means to make
files and information easily available to customers. Accessible by using your favorite Internet browser, the web site con-
tains the following information:
• Product Support – Data sheets and errata, application notes and sample programs, design resources, user’s
guides and hardware support documents, latest software releases and archived software
• General Technical Support – Frequently Asked Questions (FAQ), technical support requests, online discussion
groups, Microchip consultant program member listing
• Business of Microchip – Product selector and ordering guides, latest Microchip press releases, listing of semi-
nars and events, listings of Microchip sales offices, distributors and factory representatives
CUSTOMER CHANGE NOTIFICATION SERVICE
Microchip’s customer notification service helps keep customers current on Microchip products. Subscribers will receive
e-mail notification whenever there are changes, updates, revisions or errata related to a specified product family or
development tool of interest.
To register, access the Microchip web site at www.microchip.com. Under “Support”, click on “Customer Change Notifi-
cation” and follow the registration instructions.
CUSTOMER SUPPORT
Users of Microchip products can receive assistance through several channels:
• Distributor or Representative
• Local Sales Office
• Field Application Engineer (FAE)
• Technical Support
Customers should contact their distributor, representative or Field Application Engineer (FAE) for support. Local sales
offices are also available to help customers. A listing of sales offices and locations is included in the back of this docu-
ment.
Technical support is available through the web site at: http://microchip.com/support
DS00002670D-page 54
2018-2019 Microchip Technology Inc.
USB7002
Note the following details of the code protection feature on Microchip devices:
•
Microchip products meet the specification contained in their particular Microchip Data Sheet.
•
Microchip believes that its family of products is one of the most secure families of its kind on the market today, when used in the
intended manner and under normal conditions.
•
There are dishonest and possibly illegal methods used to breach the code protection feature. All of these methods, to our
knowledge, require using the Microchip products in a manner outside the operating specifications contained in Microchip’s Data
Sheets. Most likely, the person doing so is engaged in theft of intellectual property.
•
•
Microchip is willing to work with the customer who is concerned about the integrity of their code.
Neither Microchip nor any other semiconductor manufacturer can guarantee the security of their code. Code protection does not
mean that we are guaranteeing the product as “unbreakable.”
Code protection is constantly evolving. We at Microchip are committed to continuously improving the code protection features of our
products. Attempts to break Microchip’s code protection feature may be a violation of the Digital Millennium Copyright Act. If such acts
allow unauthorized access to your software or other copyrighted work, you may have a right to sue for relief under that Act.
Information contained in this publication regarding device applications and the like is provided only for your convenience and may be
superseded by updates. It is your responsibility to ensure that your application meets with your specifications. MICROCHIP MAKES NO
REPRESENTATIONS OR WARRANTIES OF ANY KIND WHETHER EXPRESS OR IMPLIED, WRITTEN OR ORAL, STATUTORY OR
OTHERWISE, RELATED TO THE INFORMATION, INCLUDING BUT NOT LIMITED TO ITS CONDITION, QUALITY, PERFORMANCE,
MERCHANTABILITY OR FITNESS FOR PURPOSE. Microchip disclaims all liability arising from this information and its use. Use of Micro-
chip devices in life support and/or safety applications is entirely at the buyer’s risk, and the buyer agrees to defend, indemnify and hold
harmless Microchip from any and all damages, claims, suits, or expenses resulting from such use. No licenses are conveyed, implicitly or
otherwise, under any Microchip intellectual property rights unless otherwise stated.
Trademarks
The Microchip name and logo, the Microchip logo, Adaptec, AnyRate, AVR, AVR logo, AVR Freaks, BesTime, BitCloud, chipKIT, chipKIT logo,
CryptoMemory, CryptoRF, dsPIC, FlashFlex, flexPWR, HELDO, IGLOO, JukeBlox, KeeLoq, Kleer, LANCheck, LinkMD, maXStylus, maXTouch,
MediaLB, megaAVR, Microsemi, Microsemi logo, MOST, MOST logo, MPLAB, OptoLyzer, PackeTime, PIC, picoPower, PICSTART, PIC32 logo,
PolarFire, Prochip Designer, QTouch, SAM-BA, SenGenuity, SpyNIC, SST, SST Logo, SuperFlash, Symmetricom, SyncServer, Tachyon,
TempTrackr, TimeSource, tinyAVR, UNI/O, Vectron, and XMEGA are registered trademarks of Microchip Technology Incorporated in the U.S.A. and
other countries.
APT, ClockWorks, The Embedded Control Solutions Company, EtherSynch, FlashTec, Hyper Speed Control, HyperLight Load, IntelliMOS, Libero,
motorBench, mTouch, Powermite 3, Precision Edge, ProASIC, ProASIC Plus, ProASIC Plus logo, Quiet-Wire, SmartFusion, SyncWorld, Temux,
TimeCesium, TimeHub, TimePictra, TimeProvider, Vite, WinPath, and ZL are registered trademarks of Microchip Technology Incorporated in the
U.S.A.
Adjacent Key Suppression, AKS, Analog-for-the-Digital Age, Any Capacitor, AnyIn, AnyOut, BlueSky, BodyCom, CodeGuard,
CryptoAuthentication, CryptoAutomotive, CryptoCompanion, CryptoController, dsPICDEM, dsPICDEM.net, Dynamic Average Matching, DAM,
ECAN, EtherGREEN, In-Circuit Serial Programming, ICSP, INICnet, Inter-Chip Connectivity, JitterBlocker, KleerNet, KleerNet logo, memBrain,
Mindi, MiWi, MPASM, MPF, MPLAB Certified logo, MPLIB, MPLINK, MultiTRAK, NetDetach, Omniscient Code Generation, PICDEM, PICDEM.net,
PICkit, PICtail, PowerSmart, PureSilicon, QMatrix, REAL ICE, Ripple Blocker, SAM-ICE, Serial Quad I/O, SMART-I.S., SQI, SuperSwitcher,
SuperSwitcher II, Total Endurance, TSHARC, USBCheck, VariSense, ViewSpan, WiperLock, Wireless DNA, and ZENA are trademarks of
Microchip Technology Incorporated in the U.S.A. and other countries.
SQTP is a service mark of Microchip Technology Incorporated in the U.S.A.
The Adaptec logo, Frequency on Demand, Silicon Storage Technology, and Symmcom are registered trademarks of Microchip Technology Inc. in
other countries.
GestIC is a registered trademark of Microchip Technology Germany II GmbH & Co. KG, a subsidiary of Microchip Technology Inc., in other
countries.
All other trademarks mentioned herein are property of their respective companies.
© 2018-2019, Microchip Technology Incorporated, All Rights Reserved.
ISBN: 9781522448501
For information regarding Microchip’s Quality Management Systems,
please visit www.microchip.com/quality.
2018-2019 Microchip Technology Inc.
DS00002670D-page 55
Worldwide Sales and Service
AMERICAS
ASIA/PACIFIC
ASIA/PACIFIC
EUROPE
Corporate Office
2355 West Chandler Blvd.
Chandler, AZ 85224-6199
Tel: 480-792-7200
Fax: 480-792-7277
Technical Support:
http://www.microchip.com/
support
Australia - Sydney
Tel: 61-2-9868-6733
India - Bangalore
Tel: 91-80-3090-4444
Austria - Wels
Tel: 43-7242-2244-39
Fax: 43-7242-2244-393
China - Beijing
Tel: 86-10-8569-7000
India - New Delhi
Tel: 91-11-4160-8631
Denmark - Copenhagen
Tel: 45-4450-2828
Fax: 45-4485-2829
China - Chengdu
Tel: 86-28-8665-5511
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Tel: 91-20-4121-0141
Finland - Espoo
Tel: 358-9-4520-820
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Tel: 86-23-8980-9588
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Web Address:
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Tel: 33-1-69-53-63-20
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Philippines - Manila
Germany - Munich
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Norway - Trondheim
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Poland - Warsaw
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Tel: 631-435-6000
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2018-2019 Microchip Technology Inc.
DS00002670D-page 56
05/14/19
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