USB5806
6-Port USB 3.2 Gen 1 SmartHubTM IC
Highlights
• USB Hub Feature Controller IC Hub with 6 USB
3.2 Gen 1 / USB 2.0 downstream ports
• USB-IF Battery Charger revision 1.2 support on
up & downstream ports (DCP, CDP, SDP)
• FlexConnect: Downstream port able to swap with
upstream port, allowing master capable devices
to control other devices on the hub
• Internal Hub Feature Controller device enables:
- USB to I2C/SPI/GPIO bridge endpoint support
- USB to internal hub register write and read
• USB Link Power Management (LPM) support
• Enhanced OEM configuration options available
through either OTP or SPI ROM
• USB-IF certified (TID 1594), supporting latest
Engineering Change Notices for compliance with
USB-IF logo testing for new USB Type-C®
industry initiative (Revision C or newer only)
- Header Packet Timer (TD7.9, TD7.11, TD7.26)
- Power Management Timer (TD7.18, TD7.20, TD7.23)
- Unacknowledged Connect and Remote
Wake Test Failure (TD10.25)
• Available in 100-pin (12mm x 12mm) VQFN
RoHS compliant package
• Commercial and industrial grade temperature
support
Target Applications
•
•
•
•
•
Standalone USB Hubs
Laptop Docks
PC Motherboards
PC Monitor Docks
Multi-function USB 3.2 Gen 1 Peripherals
Key Benefits
• USB 3.2 Gen 1 compliant 5 Gbps, 480 Mbps,
12 Mbps, and 1.5Mbps operation
- 5V tolerant USB 2.0 pins
- 1.32V tolerant USB 3.2 Gen 1 pins
- Integrated termination and pull-up/down resistors
• Supports battery charging of most popular battery
powered devices on all ports
- Support for Microchip UCS100x family of battery
charging controllers
- Supports additional portable devices
• Smart port controller operation
- Firmware handling of companion port power
controllers
• On-chip microcontroller
- manages I/Os, VBUS, and other signals
• 8 KB RAM, 64 KB ROM
• 8 KB One-Time-Programmable (OTP) ROM
- Includes on-chip charge pump
• Configuration programming via OTP ROM,
SPI ROM, or SMBus
• FlexConnect
- Reversible upstream and downstream Port 1 roles
on command
• PortSwap
- Configurable USB 2.0 differential pair signal swap
• PHYBoostTM
- Programmable USB transceiver drive strength for
recovering signal integrity
- USB 2.0 Hi-Speed disconnect threshold adjust
(Revision C or newer only)
• VariSenseTM
- Programmable USB receive sensitivity
• Port Split
- USB2.0 and USB 3.2 Gen1 port operation can be
split for custom applications using embedded
USB3.x devices in parallel with USB2.0 devices.
• USB Power Delivery Billboard Device Support
- Internal port can enumerate as a Power Delivery
Billboard device to communicate Power Delivery
Alternate Mode negotiation failure cases to USB
host
• Compatible with Microsoft Windows 10, 8, 7, XP,
Apple OS X 10.4+, and Linux hub drivers
• Optimized for low-power operation and low thermal dissipation
• Package
- 100-pin VQFN (12mm x 12mm)
- USB-IF Battery Charging rev. 1.2 support
(DCP, CDP, SDP)
- Apple® portable product charger emulation
- Chinese YD/T 1591-2006 charger emulation
- Chinese YD/T 1591-2009 charger emulation
- European Union universal mobile charger support
2016-2021 Microchip Technology Inc.
DS00002236E-page 1
USB5806
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 publications 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
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welcome your feedback.
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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 document DS30000).
Errata
An errata sheet, describing minor operational differences from the data sheet and recommended workarounds, may exist for current
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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:
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When contacting a sales office, please specify which device, revision of silicon and data sheet (include literature number) you are
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Register on our web site at www.microchip.com to receive the most current information on all of our products.
DS00002236E-page 2
2016-2021 Microchip Technology Inc.
USB5806
TABLE OF CONTENTS
Introduction ........................................................................................................................................................................................... 7
Pin Descriptions and Configuration ....................................................................................................................................................... 6
Functional Descriptions ......................................................................................................................................................................... 9
Operational Characteristics................................................................................................................................................................. 13
System Application ............................................................................................................................................................................. 19
Package Outlines ................................................................................................................................................................................ 26
Revision History ................................................................................................................................................................................... 29
The Microchip Web Site ...................................................................................................................................................................... 30
Customer Change Notification Service ............................................................................................................................................... 30
Customer Support ............................................................................................................................................................................... 30
Product Identification System ............................................................................................................................................................. 31
2016-2021 Microchip Technology Inc.
DS00002236E-page 3
USB5806
1.0
PREFACE
1.1
General Terms
TABLE 1-1:
GENERAL TERMS
Term
Description
ADC
Analog-to-Digital Converter
Byte
8 bits
CDC
Communication Device Class
CSR
Control and Status Registers
DWORD
32 bits
EOP
End of Packet
EP
Endpoint
FIFO
First In First Out buffer
FS
Full-Speed
FSM
Finite State Machine
GPIO
General Purpose I/O
HS
Hi-Speed
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
Inter-Integrated Circuit
LS
Low-Speed
lsb
Least Significant Bit
LSB
Least Significant Byte
msb
Most Significant Bit
MSB
Most Significant Byte
N/A
Not Applicable
NC
No Connect
OTP
One Time Programmable
PCB
Printed Circuit Board
PCS
Physical Coding Sublayer
PHY
Physical Layer
PLL
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 guaranteed when reading reserved bits. Unless otherwise noted, do not read or write to
reserved addresses.
SDK
Software Development Kit
SMBus
System Management Bus
UUID
Universally Unique IDentifier
WORD
16 bits
DS00002236E-page 4
2016-2021 Microchip Technology Inc.
USB5806
1.2
1.
2.
3.
4.
5.
Reference Documents
UNICODE UTF-16LE For String Descriptors USB Engineering Change Notice, December 29th, 2004, http://
www.usb.org
Universal Serial Bus Revision 3.2 Specification, http://www.usb.org/developers/docs/
Battery Charging Specification, Revision 1.2, Dec. 07, 2010, http://www.usb.org
I2C-Bus Specification, Version 1.1, http://www.nxp.com
System Management Bus Specification, Version 1.0, http://smbus.org/specs
2016-2021 Microchip Technology Inc.
DS00002236E-page 5
USB5806
2.0
INTRODUCTION
2.1
General Description
The Microchip USB5806 hub is a low-power, OEM configurable, USB 3.2 Gen 1 hub controller with 6 downstream ports
and advanced features for embedded USB applications. The USB5806 is fully compliant with the Universal Serial Bus
Revision 3.2 Specification and USB 2.0 Link Power Management Addendum. The USB5806 supports 5 Gbps SuperSpeed (SS), 480 Mbps Hi-Speed (HS), 12 Mbps Full-Speed (FS), and 1.5 Mbps Low-Speed (LS) USB downstream
devices on all enabled downstream ports.
The USB5806 supports the legacy USB speeds (HS/FS/LS) through a dedicated USB 2.0 hub controller that is the culmination of five generations of Microchip hub controller design and experience with proven reliability, interoperability,
and device compatibility. The SuperSpeed hub controller operates in parallel with the USB 2.0 hub controller, decoupling
the 5 Gbps SS data transfers from bottlenecks due to the slower USB 2.0 traffic.
The USB5806 hub feature controller enables OEMs to configure their system using “Configuration Straps.” These straps
simplify the configuration process, assigning default values to USB 3.2 Gen 1 ports and GPIOs. OEMs can disable ports,
enable battery charging, and define GPIO functions as default assignments on power-up, removing the need for OTP
or external SPI ROM.
The USB5806 supports downstream battery charging via the integrated battery charger detection circuitry, which supports the USB-IF Battery Charging (BC1.2) detection method and most Apple devices. The USB5806 provides the battery 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 SMBus or OTP
Additionally, the USB5806 includes many powerful and unique features such as:
The Hub Feature Controller, which provides an internal USB device dedicated for use as a USB to I2C/UART/SPI/
GPIO interface, allowing external circuits or devices to be monitored, controlled, or configured via the USB interface.
FlexConnect, which provides flexible connectivity options. One of the USB5806’s downstream ports can be reconfigured to become the upstream port, allowing master capable devices to control other devices on the hub.
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.
VariSense, which controls the 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.
Port Split, which allows for the USB 3.2 Gen1 and USB2.0 portions of downstream ports 5 and 6 to operate independently and enumerate two separate devices in parallel in special applications.
USB Power Delivery Billboard Device, which allows an internal device to enumerate as a Billboard class device when
a Power Delivery Alternate Mode negotiation has failed. The Billboard device will enumerate temporarily to the host PC
when a failure occurs, as indicated by a digital signal from an external Power Delivery controller.
The USB5806 can be configured for operation through internal default settings. Custom OEM configurations are supported through external SPI ROM or 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 USB5806 is available in commercial (0°C to +70°C) and industrial (-40°C to +85°C) temperature ranges. An internal
block diagram of the USB5806 is shown in Figure 2-1.
DS00002236E-page 6
2016-2021 Microchip Technology Inc.
USB5806
FIGURE 2-1:
INTERNAL BLOCK DIAGRAM
P0 ‘B’
I2C from Master
+3.3 V
I2C/SMB
AFE0 AFE0
USB3 USB2
+1.2 V
Hub Controller Logic
25 Mhz
AFE1 AFE1
AFE2 AFE2
AFE3 AFE3
AFE4 AFE4
AFE5 AFE5
AFE6 AFE6
AFE7
OTP
Hub Feature
Controller
GPIO
P1
‘A’
P2
‘A’
2016-2021 Microchip Technology Inc.
P3
‘A’
P4
‘A’
P5
‘A’
SMB
SPI
P6
‘A’
DS00002236E-page 7
USB5806
3.0
PIN DESCRIPTIONS
3.1
Pin Diagram
HOST_TYPE0/GPIO23
PRT_CTL6/GPIO22
51
54
PRT_CTL5/GPIO21
VDD33
55
52
HOST_TYPE1/GPIO67
56
53
PRT_CTL4/GANG_PWR/GPIO20
SPEED_IND3/BC_IND3/GPIO2
57
VDD12
PRT_CTL3/GPIO19
SPEED_IND4/BC_IND4/GPIO3
60
58
SPEED_IND2/BC_IND2/GPIO71
61
59
SPEED_IND1/BC_IND1/GPIO70
PRT_CTL2/GPIO18
62
VDD33
64
63
SPI_DO/C_ATTACH2/GPIO5
SPI_CLK/C_ATTACH3/GPIO4
67
65
SPI_DI/GPIO9/CFG_BC_EN
68
66
GPIO69
SPI_CE_N/GPIO7/CFG_NON_REM
69
SPEED_IND6/BC_IND6/GPIO66
PRT_CTL1/GPIO17
70
72
71
C_ATTACH1/GPIO1
VDD33
73
SMBCLK/GPIO8
SMBDATA/GPIO6
74
PIN ASSIGNMENTS (TOP VIEW)
75
FIGURE 3-1:
C_ATTACH0/GPIO64
76
50
SPEED_IND5/BC_IND5/GPIO65
SUSP_IND/GPIO68
77
49
USB3DN_RXDM5
VDD12
78
48
USB3DN_RXDP5
NC
79
47
VDD12
NC
80
46
USB3DN_TXDM5
NC
81
45
USB3DN_TXDP5
NC
82
44
USB2DN_DM5/PRT_DIS_M5
VDD12
83
43
USB2DN_DP5/PRT_DIS_P5
NC
84
42
VDD33
NC
85
41
USB3DN_RXDM4
40
USB3DN_RXDP4
USB2DN_DP6/PRT_DIS_P6
86
USB2DN_DM6/PRT_DIS_M6
87
USB3DN_TXDP6
88
USB3DN_TXDM6
89
VDD12
90
36
USB2DN_DM4/PRT_DIS_M4
USB3DN_RXDP6
91
35
USB2DN_DP4/PRT_DIS_P4
USB3DN_RXDM6
92
34
USB3DN_RXDM3
VDD33
93
33
USB3DN_RXDP3
USB2UP_DP
94
32
VDD12
Microchip
USB5806
(Top View 100-VQFN)
thermal slug connects to VSS
39
VDD12
38
USB3DN_TXDM4
37
USB3DN_TXDP4
23
24
25
VBUS_DET
RESET_N
20
TESTEN
19
USB3DN_RXDM2
GPIO12/CFG_STRAP
22
18
USB3DN_RXDP2
21
17
VDD12
FLEX_CMD
16
FLEX_STATE
15
14
USB2DN_DM2/PRT_DIS_M2
USB3DN_TXDP2
13
USB3DN_TXDM2
12
USB3DN_RXDP1
USB3DN_RXDM1
11
VDD12
USB2DN_DP2/PRT_DIS_P2
9
10
USB3DN_TXDM1
VDD12
8
26
7
100
USB3DN_TXDP1
VDD33
USB3UP_RXDM
USB2DN_DM1/PRT_DIS_M1
27
6
99
5
USB2DN_DP3/PRT_DIS_P3
USB3UP_RXDP
VDD33
28
USB2DN_DP1/PRT_DIS_P1
98
4
USB2DN_DM3/PRT_DIS_M3
VDD12
3
29
XTALO
97
XTALI/CLKIN
USB3DN_TXDP3
USB3UP_TXDM
2
USB3DN_TXDM3
30
1
31
96
RBIAS
95
VDD33
USB2UP_DM
USB3UP_TXDP
Note 1: 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. Refer to Section 3.5, Configuration Straps and Programmable Functions
DS00002236E-page 8
2016-2021 Microchip Technology Inc.
USB5806
3.2
Pin Symbols
Pin Num.
Pin Name
Reset
Pin Num.
Pin Name
Reset
1
RBIAS
A/P
51
PRT_CTL6/GPIO22
PD-50k
2
VDD33
A/P
52
PRT_CTL5/GPIO21
PD-50k
3
XTALI/CLKIN
A/P
53
HOST_TYPE0/GPIO23
PD-50k
4
XTALO
A/P
54
VDD33
A/P
5
VDD33
A/P
55
HOST_TYPE1/GPIO67
Z
6
USB2DN_DP1/PRT_DIS_P1
PD-15k
56
SPEED_IND3/BC_IND3/GPIO2
Z
7
USB2DN_DM1/PRT_DIS_M1
PD-15k
57
PRT_CTL4/GANG_PWR/GPIO20
PD-50k
8
USB3DN_TXDP1
Z
58
PRT_CTL3/GPIO19
PD-50k
9
USB3DN_TXDM1
Z
59
VDD12
A/P
10
VDD12
A/P
60
SPEED_IND4/BC_IND4/GPIO3
Z
11
USB3DN_RXDP1
Z
61
SPEED_IND2/BC_IND2/GPIO71
Z
12
USB3DN_RXDM1
Z
62
PRT_CTL2/GPIO18
PD-50k
13
USB2DN_DP2/PRT_DIS_P2
PD-15k
63
SPEED_IND1/BC_IND1/GPIO70
Z
14
USB2DN_DM2/PRT_DIS_M2
PD-15k
64
VDD33
A/P
15
USB3DN_TXDP2
Z
65
SPI_CLK/C_ATTACH3/GPIO4
Z
16
USB3DN_TXDM2
Z
66
SPI_DO/C_ATTACH2/GPIO5
PD-50k
17
VDD12
A/P
67
SPI_DI/GPIO9/CFG_BC_EN
Z
18
USB3DN_RXDP2
Z
68
SPI_CE_N/GPIO7/CFG_NON_REM
PU-50k
19
USB3DN_RXDM2
Z
69
GPIO69
Z
20
GPIO12/CFG_STRAP
Z
70
PRT_CTL1/GPIO17
PD-50k
21
FLEX_CMD
Z
71
SPEED_IND6/BC_IND6/GPIO66
Z
22
FLEX_STATE
Z
72
VDD33
A/P
23
TESTEN
Z
73
C_ATTACH1/GPIO1
Z
24
VBUS_DET
Z
74
SMBDATA/GPIO6
Z
25
RESET_N
R
75
SMBCLK/GPIO8
Z
26
VDD12
A/P
76
C_ATTACH0/GPIO64
Z
27
VDD33
A/P
77
SUSP_IND/GPIO68
Z
28
USB2DN_DP3/PRT_DIS_P3
PD-15k
78
VDD12
A/P
29
USB2DN_DM3/PRT_DIS_M3
PD-15k
79
NC
PD-15k
30
USB3DN_TXDP3
Z
80
NC
PD-15k
31
USB3DN_TXDM3
Z
81
NC
Z
32
VDD12
A/P
82
NC
Z
33
USB3DN_RXDP3
Z
83
VDD12
A/P
Z
34
USB3DN_RXDM3
Z
84
NC
35
USB2DN_DP4/PRT_DIS_P4
PD-15k
85
NC
Z
36
USB2DN_DM4/PRT_DIS_M4
PD-15k
86
USB2DN_DP6/PRT_DIS_P6
PD-15k
37
USB3DN_TXDP4
Z
87
USB2DN_DM6/PRT_DIS_M6
PD-15k
38
USB3DN_TXDM4
Z
88
USB3DN_TXDP6
Z
39
VDD12
A/P
89
USB3DN_TXDM6
Z
40
USB3DN_RXDP4
Z
90
VDD12
A/P
41
USB3DN_RXDM4
Z
91
USB3DN_RXDP6
Z
42
VDD33
A/P
92
USB3DN_RXDM6
Z
43
USB2DN_DP5/PRT_DIS_P5
PD-15k
93
VDD33
A/P
44
USB2DN_DM5/PRT_DIS_M5
PD-15k
94
USB2UP_DP
PD-1M
45
USB3DN_TXDP5
Z
95
USB2UP_DM
PD-1M
46
USB3DN_TXDM5
Z
96
USB3UP_TXDP
Z
47
VDD12
A/P
97
USB3UP_TXDM
Z
48
USB3DN_RXDP5
Z
98
VDD12
A/P
49
USB3DN_RXDM5
Z
99
USB3UP_RXDP
Z
50
SPEED_IND5/BC_IND5/GPIO65
Z
100
USB3UP_RXDM
Z
2016-2021 Microchip Technology Inc.
DS00002236E-page 9
USB5806
The pin reset state definitions are detailed in Table 3-1.
TABLE 3-1:
PIN RESET STATE LEGEND
Symbol
3.3
Description
A/P
Analog/Power Input
R
Reset Control Input
Z
Hardware disables output driver (high impedance)
PU-50k
Hardware enables internal 50kΩ pull-up
PD-50k
Hardware enables internal 50kΩ pull-down
PD-15k
Hardware enables internal 15kΩ pull-down
PD-1M
Hardware enables internal 1M pull-down
USB5806 Pin Descriptions
This section contains descriptions of the various USB5806 pins. The pin descriptions have been broken into functional
groups as follows:
•
•
•
•
•
•
•
•
USB 3.2 Gen 1 Pin Descriptions
USB 2.0 Pin Descriptions
Port Control Pin Descriptions
SPI Interface
USB Type-C Connector Controls
Miscellaneous Pin Descriptions
Configuration Strap Pin Descriptions
Power and Ground Pin Descriptions
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 inactive.
TABLE 3-2:
USB 3.2 GEN 1 PIN DESCRIPTIONS
Name
Symbol
Buffer
Type
USB 3.2 Gen 1
Upstream D+ TX
USB3UP_TXDP
I/O-U
Upstream USB 3.2 Gen 1 Transmit Data Plus
USB 3.2 Gen 1
Upstream D- TX
USB3UP_TXDM
I/O-U
Upstream USB 3.2 Gen 1 Transmit Data Minus
USB 3.2 Gen 1
Upstream D+ RX
USB3UP_RXDP
I/O-U
Upstream USB 3.2 Gen 1 Receive Data Plus
USB 3.2 Gen 1
Upstream D- RX
USB3UP_RXDM
I/O-U
Upstream USB 3.2 Gen 1 Receive Data Minus
DS00002236E-page 10
Description
2016-2021 Microchip Technology Inc.
USB5806
TABLE 3-2:
USB 3.2 GEN 1 PIN DESCRIPTIONS (CONTINUED)
Name
Symbol
Buffer
Type
USB 3.2 Gen 1
Ports 6-1
D+ TX
USB3DN_TXDP[6:1]
I/O-U
Downstream Super Speed Transmit Data Plus,
ports 6 through 1.
USB 3.2 Gen 1
Ports 6-1
D- TX
USB3DN_TXDM[6:1]
I/O-U
Downstream Super Speed Transmit Data Minus,
ports 6 through 1.
USB 3.2 Gen 1
Ports 6-1
D+ RX
USB3DN_RXDP[6:1]
I/O-U
Downstream Super Speed Receive Data Plus,
ports 6 through 1.
USB 3.2 Gen 1
Ports 6-1
D- RX
USB3DN_RXDM[6:1]
I/O-U
Downstream Super Speed Receive Data Minus,
ports 6 through 1.
TABLE 3-3:
Description
USB 2.0 PIN DESCRIPTIONS
Name
Symbol
Buffer
Type
Description
USB 2.0
Upstream
D+
USB2UP_DP
I/O-U
Upstream USB 2.0 Data Plus (D+)
USB 2.0
Upstream
D-
USB2UP_DM
I/O-U
Upstream USB 2.0 Data Minus (D-)
USB 2.0
Ports 6 D+
USB2DN_DP[6:1]
I/O-U
Downstream USB 2.0 Ports 6-1 Data Plus (D+)
USB 2.0
Ports 6 D-
USB2DN_DM[6:1]
I/O-U
Downstream USB 2.0 Ports 6-1 Data Minus (D-)
VBUS Detect
VBUS_DET
IS
This signal detects the state of the upstream bus power.
When designing a detachable hub, this pin must be connected 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 controlled
(toggled) when the host desires to renegotiate a connection without requiring a full reset of the device.
2016-2021 Microchip Technology Inc.
DS00002236E-page 11
USB5806
TABLE 3-4:
PORT CONTROL PIN DESCRIPTIONS
Name
Symbol
Port 6
Power Enable /
Overcurrent
Sense
PRT_CTL6
Buffer
Type
I/OD12
(PU)
Description
Port 6 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 6.
This pin will change to an output and be driven low when
the port is disabled by configuration or by the host control.
Port 5
Power Enable /
Overcurrent
Sense
PRT_CTL5
I/OD12
(PU)
Port 5 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 5.
This pin will change to an output and be driven low when
the port is disabled by configuration or by the host control.
Port 4
Power Enable /
Overcurrent
Sense
PRT_CTL4
I/OD12
(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 disabled by configuration or by the host control.
Port 3
Power Enable /
Overcurrent
Sense
PRT_CTL3
I/OD12
(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 disabled by configuration or by the host control.
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USB5806
TABLE 3-4:
PORT CONTROL PIN DESCRIPTIONS (CONTINUED)
Name
Symbol
Port 2
Power Enable /
Overcurrent
Sense
PRT_CTL2
Buffer
Type
I/OD12
(PU)
Description
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 disabled by configuration or by the host control.
Port 1
Power Enable /
Overcurrent
Sense
PRT_CTL1
I/OD12
(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 disabled by configuration or by the host control.
Gang Power
GANG_PWR
I
GANG_PWR becomes the port control (PRTCTL) pin for
all downstream ports when the hub is configured for
ganged port power control mode. All port power controllers should be controlled from this pin when the hub is
configured for ganged port power mode.
FlexConnect
Control
FLEX_CMD
I
FlexConnect control input.
When low, the hub will operate in its default state. Port 0
is the upstream port and port 1 is a downstream port.
When high, the hub will operate in its flexed state. Port 0
is a downstream port and port 1 is an upstream port.
FlexConnect
Indicator
FLEX_STATE
O12
FlexConnect indicator output. Reflects the current state
of FlexConnect.
0 = Hub is in default mode of operation
1 = Hub is in flexed mode of operation.
2016-2021 Microchip Technology Inc.
DS00002236E-page 13
USB5806
TABLE 3-5:
SPI INTERFACE
Name
Symbol
Buffer
Type
SPI Chip Enable
SPI_CE_N
I/O12
This is the active low SPI chip enable output. If the SPI
interface is enabled, this pin must be driven high in
power-down states.
SPI Clock
SPI_CLK
I/O-U
This is the SPI clock out to the serial ROM. If the SPI
interface is disabled, by setting the SPI_DIS-ABLE bit in
the UTIL_CONFIG1 register, this pin becomes GPIO4. If
the SPI interface is enabled this pin must be driven low
during reset.
SPI Data Output
SPI_DO
I/O-U
SPI data output, when configured for SPI operation.
SPI Data Input
SPI_DI
I/O-U
SPI data input, when configured for SPI operation.
Note:
Description
If SPI memory device is not used, these pins may not be simply floated. These pins must be handled per
their respective alternate pin functions descriptions (C_ATTACH2, C_ATTACH3, CFG_BC_EN,
CFG_NON_REM).
TABLE 3-6:
USB TYPE-C CONNECTOR CONTROLS
Name
Symbol
USB Type-C
Attach Control
Input 0-3
C_ATTACH[0:3]
Buffer
Type
I
(PD)
Description
USB Type-C attach control input.
This pin indicates to the hub when a valid USB Type-C
attach has been detected. This pin is used by the hub to
enable the USB 3.2 Gen 1 PHY when a Type-C connection is present. When there is no USB Type-C connection
present, the USB 3.2 Gen 1 PHY is disabled to reduce
power consumption.
This pin behaves as follows:
- 1: USB Type-C attach detected, turn respective
USB 3.2 Gen 1 PHY on.
- 0: No USB Type-C attach detected, turn respective USB 3.2 Gen 1 PHY off.
When using legacy USB Type-A and Type-B connectors,
pull these pins to 3.3V to permanently enable all USB 3.2
PHYs.
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2016-2021 Microchip Technology Inc.
USB5806
TABLE 3-7:
MISCELLANEOUS PIN DESCRIPTIONS
Name
Symbol
Buffer
Type
SMBus/I2C
Clock
SMBCLK
I/O12
Description
SMBus/I2C Clock
The SMBus/I2C interface acts as SMBus slave or I2C
bridge dependent on the device configuration.
For information on how to configure this interface refer to
Section 3.5.1, CFG_STRAP Configuration.
SMBus/I2C Data
SMBDATA
I/O12
SMBus/I2C Data
The SMBus/I2C interface acts as SMBus slave or I2C
bridge dependent on the device configuration.
For information on how to configure this interface refer to
Section 3.5.1, CFG_STRAP Configuration.
USB Port 6-1
Speed Indicator
SPEED_IND[6:1]
O12
USB Port Speed Indicator
Indicates the connection speed of the respective port.
Tri-state: Not connected
0: USB 2.0 / USB 1.1
1: USB 3.2 Gen 1
USB Port 6-1
Battery Charging
Indicator
BC_IND[6:1]
O12
USB Battery Charging Indicator
Indicates the connection speed of the respective port.
Tri-state: Battery Charging not enabled
0: Battery Charging enabled and successful BC handshake has occurred.
1: Battery Charging enabled, but no BC handshake has
occurred.
USB Host
Port 1-0
Speed Indicator
HOST_TYPE_[1:0]
General
Purpose I/O
GPIO[1:9],
GPIO12,
GPIO[17:23],
GPIO[64:71]
I/O12
(PU/
PD)
General Purpose Inputs/Outputs
USB 2.0
Suspend State
Indicator
SUSP_IND
O12
USB 2.0 Suspend State Indicator
Reset Control
Input
RESET_N
O12
USB Host Port Speed Indicator
Tri-state: Not connected
0: USB 3.2 Gen 1
1: USB 2.0 / USB 1.1
Refer to Section 3.5.5, General Purpose input/Output
Configuration (GPIOx) for details.
SUSP_IND can be used as a sideband remote wakeup
signal for the host when in USB 2.0 suspend.
2016-2021 Microchip Technology Inc.
IS
Reset Control Input
This pin places the hub into Reset Mode when pulled low.
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USB5806
TABLE 3-7:
MISCELLANEOUS PIN DESCRIPTIONS (CONTINUED)
Name
Symbol
Buffer
Type
Bias Resistor
RBIAS
I-R
External 25 MHz
Crystal Input
XTALI
ICLK
External 25 MHz crystal input
External 25 MHz
Reference Clock
Input
CLKIN
ICLK
External reference clock input.
External 25 MHz
Crystal Output
XTALO
OCLK
External 25 MHz crystal output
Test
TESTEN
I/O12
Test pin.
Description
A 12.0 kΩ (+/- 1%) resistor is attached from ground to
this pin to set the transceiver’s internal bias settings.
Place the resistor as close to the device as possible with
a dedicated, low impedance connection to the GND
plane.
The device may alternatively be driven by a single-ended
clock oscillator. When this method is used, XTALO
should be left unconnected.
This signal is used for test purposes and must always be
connected to ground.
No Connect
NC
-
No connect.
For proper operation, this signal must be left unconnected.
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USB5806
TABLE 3-8:
CONFIGURATION STRAP PIN DESCRIPTIONS
Name
Symbol
Buffer
Type
Device Mode
Configuration
Strap
CFG_STRAP
I
Description
Device Mode Configuration Strap.
This configuration strap is used to set the device mode.
Refer to Section 3.5.1, CFG_STRAP Configuration for
details.
See Note 2
Port 6-1 D+
Disable
Configuration
Strap
PRT_DIS_P[6:1]
I
Port 6-1 D+ Disable Configuration Strap.
These configuration straps are used in conjunction with
the corresponding PRT_DIS_M[6:1] straps to disable the
related port (6-1). Refer to Section Section 3.5.2, Port
Disable Configuration (PRT_DIS_P[6:1] /
PRT_DIS_M[6:1]) for more information.
See Note 2
Port 6-1 DDisable
Configuration
Strap
PRT_DIS_M[6:1]
I
Port 6-1 D- Disable Configuration Strap.
These configuration straps are used in conjunction with
the corresponding PRT_DIS_P[6:1] straps to disable the
related port (6-1). Refer to Section 3.5.2, Port Disable
Configuration (PRT_DIS_P[6:1] / PRT_DIS_M[6:1]) for
more information.
See Note 2
Non-Removable
Ports
Configuration
Strap
CFG_NON_REM
Battery Charging
Configuration
Strap
CFG_BC_EN
I
Configuration strap to control number of reported nonremoval ports. See Section 3.5.3, Non-Removable Port
Configuration (CFG_NON_REM)
See Note 2
I
Configuration strap to control number of BC 1.2 enabled
downstream ports. See Section 3.5.4, Battery Charging
Configuration (CFG_BC_EN)
See Note 2
Note 2: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. Refer to
Section 3.5, Configuration Straps and Programmable Functions for additional information.
2016-2021 Microchip Technology Inc.
DS00002236E-page 17
USB5806
TABLE 3-9:
POWER AND GROUND PIN DESCRIPTIONS
Name
Symbol
Buffer
Type
+3.3V Power
Supply Input
VDD33
P
+1.2V Core
Power Supply
Input
VDD12
Ground
GND
Description
+3.3 V power and internal regulator input
Refer to Section 4.1, Power Connections for power connection information
P
+1.2 V core power
Refer to Section 4.1, Power Connections for power connection information.
P
Common ground.
This exposed pad must be connected to the ground plane
with a via array.
3.4
Buffer Type Descriptions
TABLE 3-10:
USB5806 BUFFER TYPE DESCRIPTIONS
BUFFER
DESCRIPTION
I
Input.
IS
Input with Schmitt trigger.
O12
Output buffer with 12 mA sink and 12 mA source.
OD12
Open-drain output with 12 mA sink
PU
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
Crystal oscillator input pin
OCLK
Crystal oscillator output pin
I/O-U
Analog input/output defined in USB specification.
I-R
RBIAS.
Note:
Refer to Section 10.5, DC Specifications for individual buffer DC electrical characteristics.
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USB5806
3.5
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 various
device configuration straps and associated programmable pin functions.
Note:
3.5.1
The system designer must guarantee that configuration straps meet the timing requirements specified in
Section 10.6.2, Power-On and Configuration Strap Timing and Section 10.6.3, 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.
CFG_STRAP CONFIGURATION
The CFG_STRAP pin is used to place the hub into preset modes of operation. The resistor options are a 200 kΩ pulldown, 200 kΩ pull-up, 10 kΩ pull-down, 10 kΩ pull-up, 10 Ω pull-down, and 10 Ω pull-up as shown in Table 3-11.
TABLE 3-11:
CFG_STRAP RESISTOR ENCODING
CFG_STRAP
Resistor Value
Config
200 kΩ Pull-Down
CONFIG1
Setting
Speed Indicator Mode + I2C Bridging Mode
The SMBus interface will operate in Master Mode for use with the USB to I2C
bridging function. For more information on USB to I2C bridging with the
USB5806, refer to the “USB to I2C Using Microchip USB 3.2 Gen 1 Hubs” application note.
The following programmable pins will be re-purposed as USB Speed Indicator
outputs:
Pin 63: SPEED_IND1
Pin 61: SPEED_IND2
Pin 56: SPEED_IND3
Pin 60: SPEED_IND4
Pin 50: SPEED_IND5
Pin 71: SPEED_IND6
The SPEED_INDx pins operate in the following manner:
Tri-state: Not connected
0: USB 2.0 / USB 1.1
1: USB 3.2 Gen 1
2016-2021 Microchip Technology Inc.
DS00002236E-page 19
USB5806
TABLE 3-11:
CFG_STRAP RESISTOR ENCODING (CONTINUED)
CFG_STRAP
Resistor Value
200 kΩ Pull-Up
Config
CONFIG2
Setting
Speed Indicator Mode + SMBus Slave Mode
The SMBus interface will operate in Slave Mode for use with hub configuration.
The following programmable pins will be re-purposed as USB Speed Indicator
outputs:
Pin 63: SPEED_IND1
Pin 61: SPEED_IND2
Pin 56: SPEED_IND3
Pin 60: SPEED_IND4
Pin 50: SPEED_IND5
Pin 71: SPEED_IND6
The SPEED_INDx pins operate in the following manner:
Tri-state: Not connected
0: USB 2.0 / USB 1.1
1: USB 3.2 Gen 1
10 kΩ Pull-Down
CONFIG3
Unused, Reserved
10 kΩ Pull-Up
CONFIG4
Unused, Reserved
10 Ω Pull-Down
CONFIG5
Battery Charging Indicator Mode
The following programmable pins will be re-purposed as USB Battery Charging
Indicator outputs:
Pin 63: BC_IND1
Pin 61: BC_IND2
Pin 56: BC_IND3
Pin 60: BC_IND4
Pin 50: BC_IND5
Pin 71: BC_IND6
The BC_INDx pins operate in the following manner:
Tri-state: Battery Charging not enabled
0: Battery Charging enabled and successful BC handshake has occurred.
1: Battery Charging enabled, but no BC handshake has occurred.
10 Ω Pull-Up
3.5.2
CONFIG6
Unused, Reserved
PORT DISABLE CONFIGURATION (PRT_DIS_P[6:1] / PRT_DIS_M[6:1])
The PRT_DIS_P[6:1] and PRT_DIS_M[6:1] configuration straps are used in conjunction to disable the related port (6-1).
For PRT_DIS_Px (where x is the corresponding port 6-1):
0 = Port x D+ Enabled
1 = Port x D+ Disabled
For PRT_DIS_Mx (where x is the corresponding port 6-1):
0 = Port x D- Enabled
1 = Port x D- Disabled
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USB5806
Note:
3.5.3
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 3.2
Gen 1 port.
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, 10 Ω pull-down and 10 Ω pullup as shown in Table 3-12.
TABLE 3-12:
CFG_NON_REM RESISTOR ENCODING
CFG_NON_REM Resistor Value
Setting
200 kΩ Pull-Down
All ports removable
200 kΩ Pull-Up
Port 1 non-removable
10 kΩ Pull-Down
Port 1, 2 non-removable
10 kΩ Pull-Up
Port 1, 2, 3, non-removable
10 Ω Pull-Down
Port 1, 2, 3, 4 non-removable
10 Ω Pull-Up
Port 1, 2, 3, 4, 5, 6 non-removable
3.5.4
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, 10 Ω pull-down and 10 Ω pull-up as
shown in Table 3-13.
TABLE 3-13:
CFG_BC_EN RESISTOR ENCODING
CFG_BC_EN Resistor Value
Setting
200 kΩ Pull-Down
No battery charging
200 kΩ Pull-Up
Port 1 battery charging
10 kΩ Pull-Down
Port 1, 2 battery charging
10 kΩ Pull-Up
Port 1, 2, 3, battery charging
10 Ω Pull-Down
Port 1, 2, 3, 4 battery charging
10 Ω Pull-Up
Port 1, 2, 3, 4, 5, 6 battery charging
3.5.5
GENERAL PURPOSE INPUT/OUTPUT CONFIGURATION (GPIOx)
General Purpose Inputs/Outputs may be used for application specific purposes. Any given GPIO may operate as an
input or an output. Inputs can apply an internal 50kΩ pull-down or pull-up resistor. Outputs may drive low or drive high
(3.3V). GPIOs may be configured and manipulated during runtime (while enumerated to a host) in one of two ways:
• SMBus configuration
• USB to GPIO bridging
3.5.5.1
SMBus configuration
The SMBus slave interface may be used to write to internal registers that configure the state of the GPIO. Refer to the
“Configuration Options for Microchip USB58xx and USB59xx Hubs” application note for additional details.
3.5.5.2
USB to GPIO Bridging
USB to GPIO Bridging may be used to write to internal registers that configure the state of the GPIO. USB to GPIO
bridging operates via host communication to the hub’s internal Hub Feature Controller. Refer to the “USB to GPIO Bridging for Microchip USB 3.2 Gen 1 Hubs” application note for additional details.
2016-2021 Microchip Technology Inc.
DS00002236E-page 21
USB5806
4.0
DEVICE CONNECTIONS
4.1
Power Connections
Figure 4-1 illustrates the device power connections.
FIGURE 4-1:
DEVICE POWER CONNECTIONS
+3.3V
Supply
+1.2V
Supply
VDD33
3.3V Internal Logic
USB5806
4.2
VDD12
1.2V Internal Logic
VSS
SPI ROM Connections
Figure 4-2 illustrates the device SPI ROM connections. Refer to Section 7.1 “SPI Master Interface” for additional information on this device interface.
FIGURE 4-2:
SPI ROM CONNECTIONS
SPI_CE_N
CE#
SPI_CLK
CLK
USB5806
4.3
SPI ROM
SPI_DO
DI
SPI_DI
DO
SMBus Slave Connections
Figure 4-3 illustrates the device SMBus slave connections. Refer to Section 7.2 “SMBus Slave Interface” for additional information on this device interface.
FIGURE 4-3:
SMBUS SLAVE CONNECTIONS
+3.3V
10K
Clock
SMCLK
USB5806
+3.3V
10K
SMDAT
DS00002236E-page 22
SMBus
Master
Data
2016-2021 Microchip Technology Inc.
USB5806
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 8.4.2, External Chip Reset (RESET_N) for additional
information on RESET_N.
1
Hub (Normal) Mode: The device operates as a configurable USB hub with battery
charger detection. This mode has various 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 transferred.
The flowchart in Figure 5-1 details the modes of operation and 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 BOOT FLOWCHART
RESET_N deasserted
SPI
Signature
Present?
YES
Run from
External ROM
NO
(SPI_INIT)
Load Config from
Internal ROM
Modify Config
Based on OTP
(CFG_RD)
Do SMBus or I2C
initialization
YES
Load Config from
External ROM
Modify Config
Based on psuedoOTP
(Ext_CFG
_RD)
CFG_STRAP for
SMBus Slave?
NO
(STRAP)
No
SOC Done?
YES
(SOC_CFG)
Combine OTP
Config Data
(OTP_CFG)
Hub Connect
NORMAL operation
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DS00002236E-page 23
USB5806
5.1
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 maximum 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.
5.2
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 0xFFFA. If a valid signature is found, then the
external 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_RD stage).
When using an external SPI ROM, a 1 Mbit, 60 MHz or faster ROM must be used. Both 1- and 2-bit SPI operation are
supported. For optimum throughput, a 2-bit SPI ROM is recommended. Both mode 0 and mode 3 SPI ROMs are also
supported.
If the system is not strapped for SPI Mode, code execution will continue from internal ROM (CFG_RD stage).
5.3
Configuration Read Stage (CFG_RD)
In this stage, the internal firmware loads the default values from the internal ROM and then uses the configuration strapping options to override the default values. Refer to Section 3.5, Configuration Straps and Programmable Functions for
information on usage of the various device configuration straps.
5.4
Strap Read Stage (STRAP)
In this stage, the firmware registers the configuration strap settings and checks the state of CFG_STRAP. If
CFG_STRAP is set for CONFIG2, then the hub will check the state of the SMBDATA and SMBCLK pins. If 10k pull-up
resistors are detected on both pins, the device will enter the SOC_CFG stage. If 10k pull-up resistors are not detected
on both pins, the hub will transition to the OTP_CFG stage instead.
5.5
SOC Configuration Stage (SOC_CFG)
In this stage, the SOC can modify any of the default configuration settings specified in the integrated ROM, such as USB
device descriptors and port electrical settings.
There is no time limit on this mode. In this stage the firmware will wait indefinitely for the SMBus/I2C configuration. When
the SOC has completed configuring the device, it must write to register 0xFF to end the configuration.
5.6
OTP Configuration Stage (OTP_CFG)
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 programmed.
After the device is fully configured, it will go idle and then into suspend if there is no VBUS or Hub.Connect present.
Once VBUS is present, and battery charging is enabled, the device will transition to the Battery Charger Detection
Stage. If VBUS is present, and battery charging is not enabled, the device will transition to the Connect stage.
5.7
Hub Connect Stage (Hub.Connect)
Once the CHGDET stage is completed, the device enters the Hub Connect stage. USB connect can be initiated by
asserting the VBUS pin function high. The device will remain in the Hub Connect stage indefinitely until the VBUS pin
function is deasserted.
DS00002236E-page 24
2016-2021 Microchip Technology Inc.
USB5806
5.8
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 system.
2016-2021 Microchip Technology Inc.
DS00002236E-page 25
USB5806
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. The hub can be configured either internally or externally depending on
the implemented interface.
Microchip provides a comprehensive software programming tool, Pro-Touch2, for configuring the USB5806 functions,
registers and OTP memory. All configuration is to be performed via the Pro-Touch2 programming tool. For additional
information on the Pro-Touch2 programming tool, refer to Software Libraries within Microchip USB5806 product page
at www.microchip.com/USB5806.
Note:
6.1
Device configuration straps and programmable pins are detailed in Section 3.5, Configuration Straps and
Programmable Functions.
Refer to Section 7.0, Device Interfaces for detailed information on each device interface.
Customer Accessible Functions
The following functions are available to the customer via the Pro-Touch2 Programming Tool.
Note:
6.1.1
6.1.1.1
For additional programming details, refer to the Pro-Touch2 programming tool User’s Guide.
USB ACCESSIBLE FUNCTIONS
I2C Bridging Access over USB
Access to I2C devices is performed as a pass-through operation from the USB Host. The device firmware has no knowledge of the operation of the attached I2C device. For more information, refer to the Microchip USB5806 product page
and Pro-Touch2 at www.microchip.com/USB5806.
Note:
6.1.1.2
Refer to Section 7.3, I2C Bridge Interface for additional information on the I2C interface.
SPI Access over USB
Access to an attached SPI device is performed as a pass-through operation from the USB Host. The device firmware
has no knowledge of the operation of the attached SPI device. For more information, refer to the Microchip USB5806
product page and SDK at www.microchip.com/USB5806.
Note:
6.1.1.3
Refer to Section 7.1, SPI Master Interface for additional information on the SPI.
OTP Access
The OTP ROM in the device is accessible via the USB bus during normal runtime operation or SMBus during the
SOC_CFG stage. For more information, refer to the Microchip USB5806product page or the Pro-Touch2 User’s Guide.
6.1.1.4
Battery Charging Access over USB
The Battery charging behavior of the device can be dynamically changed by the USB Host when something other than
the preprogrammed or OTP programmed behavior is desired. For more information, refer to the Microchip
USB5806product page or the Pro-Touch2 User’s Guide.
6.1.2
SMBUS ACCESSIBLE FUNCTIONS
OTP access and configuration of specific device functions are possible via the USB5806 SMBus slave interface. All OTP
parameters can be modified via the SMBus Host. For more information refer to the Microchip USB5806 product page.
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2016-2021 Microchip Technology Inc.
USB5806
7.0
DEVICE INTERFACES
The USB5806 provides multiple interfaces for configuration and external memory access. This section details the various device interfaces and their usage:
• SPI Master Interface
• SMBus Slave Interface
• I2C Bridge Interface
Note:
For details on how to enable each interface, refer to Section 3.5, 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, Pro-Touch2, for configuring the USB5806
functions, registers and OTP memory. All configuration is to be performed via the Pro-Touch2 programming
tool. For additional information on the Pro-Touch2 programming tool, refer to Software Libraries within
Microchip USB5806 product page at www.microchip.com/USB5806.
7.1
SPI Master Interface
The device is capable of code execution from an external SPI ROM. When configured for SPI Mode, 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 0xFFFA. If a valid signature is found, then the external 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.
Note:
7.2
For SPI timing information, refer to Section 10.6.7, SPI Timing.
SMBus Slave Interface
The device includes an integrated SMBus slave interface, which can be used to access internal device run time registers
or program the internal OTP memory. SMBus slave detection is accomplished by setting the CFG_STRAP in the correct
configuration followed by detection of pull-up resistors on both the SMDAT and SMCLK signals during the hub’s bootup sequence. Refer to Section 3.5.1, CFG_STRAP Configuration for additional information.
Note:
7.3
All configuration is to be performed via the Pro-Touch2 programming tool. For additional information on the
Pro-Touch2 programming tool, refer to Software Libraries within Microchip USB5806 product page at
www.microchip.com/USB5806.
I2C Bridge Interface
The I2C Bridge interface implements a subset of the I2C Master Specification (Please refer to the Philips Semiconductor
Standard I2C-Bus Specification for details on I2C bus protocols). The I2C Bridge conforms to the Fast-Mode I2C Specification (400 kbit/s transfer rate and 7-bit addressing) for protocol and electrical compatibility. The device acts as the
master and generates the serial clock SCL, controls the bus access (determines which device acts as the transmitter
and which device acts as the receiver), and generates the START and STOP conditions. The I2C Bridge interface frequency is configurable through the I2C Bridging commands. I2C Bridge frequencies are derived from the formula
626KHz/n, where n is any integer from 1 to 256. Refer to Section 3.5.1, CFG_STRAP Configuration for additional information.
Note:
Extensions to the I2C Specification are not supported.
All configuration is to be performed via the Pro-Touch2 programming tool. For additional information on the
Pro-Touch2 programming tool, refer to Software Libraries within Microchip USB5806 product page at
www.microchip.com/USB5806.
2016-2021 Microchip Technology Inc.
DS00002236E-page 27
USB5806
8.0
FUNCTIONAL DESCRIPTIONS
This section details various USB5806 functions, including:
•
•
•
•
•
•
•
•
USB Type-C Receptacle Support
Battery Charging
FlexConnect
Resets
Link Power Management (LPM)
Remote Wakeup Indicator
Port Control Interface
Port Split
8.1
USB Type-C Receptacle Support
The USB5806 has built-in support for the USB Type-C receptacle.
8.1.1
EXTERNAL USB 3.2 GEN 1 MULTIPLEXER
C_ATTACH[0:3] pins are used to signal to the hub when a valid USB Type-C connection has been detected. This functionality requires an external USB Type-C controller such as a Microchip UTC2000 to monitor the USB Type-C receptacle for a valid attach. This signal is used to enable and disable clocking to the USB 3.2 Gen 1 PHY in order to reduce
power consumption when there is no USB Type-C attach.
The C_ATTACH[0:3] pins are active high inputs. A high signal enables clocking to the PHY to enable a USB 3.2 Gen 1
connection. A low signal disables the PHY.
A diagram of a USB Type-C Downstream Facing Port with a USB5806, Microchip UTC2000, and external multiplexer
is shown in Figure 8-1.
A diagram of a USB Type-C Upstream Facing Port with a USB5806, Microchip UTC2000, and external multiplexer is
shown in Figure 8-2.
FIGURE 8-1:
DFP TYPE-C PORT WITH MICROCHIP UTC2000 AND EXTERNAL MUX
USB Type-C®
USB Type-C
GENERIC
PORT PWR
CTLR
PO WER
External Mux
Downstream Port
OCS
SSTX+
SSTX-
SSTX+
SSTX-
SSRX+
SSRX-
SSRX+
SSRX-
A/B
VBUS
SSTXA+
SSTXA-
SSTXA+
SSTXA-
SSRXA+
SSRXA-
SSRXA+
SSRXA-
SSTXB+
SSTXB-
SSTXB+
SSTXB-
SSRXB+
SSRXB-
SSRXB+
SSRXB-
MUX
D+
DPRTCTL
C_ATTACH
ALT_MUX_EN
CC_PO L
DS00002236E-page 28
D+
D-
3.3V
ENABLE
OCS#
PLUG_OR#
PPC_EN
CC1
CC2
CC1
CC2
UTC2000
DFP Mode
2016-2021 Microchip Technology Inc.
USB5806
FIGURE 8-2:
UFP TYPE-C PORT WITH MICROCHIP UTC2000 & EXTERNAL MUX
USB Type-C
USB Type-C
External Mux
Upstream Port
VBUS
SSTXA+
SSTXA-
SSTXA+
SSTXA-
SSRXA+
SSRXA-
SSRXA+
SSRXA-
SSTXB+
SSTXB-
SSTXB+
SSTXB-
SSRXB+
SSRXB-
SSRXB+
SSRXBA/B
VBUS_DET
SSTX+
SSTX-
SSTX+
SSTX-
SSRX+
SSRX-
SSRX+
SSRX-
MUX
D+
DPLUG_
ORIENTATION#
CC1
CC2
CC1
CC2
UTC2000
UFP Mode
3.3V
D+
D-
C_ATTACH0
CONNECTED#
8.2
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 8-3:
BATTERY CHARGING EXTERNAL POWER SUPPLY
INT
DC Power
SCL
Microchip
SOC
Hub
SDA
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_CTL[6:1] 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.
For additional information, refer to the Microchip USB5806 Battery Charging application note on the Microchip.com
USB5806 product page www.microchip.com/USB5806.
2016-2021 Microchip Technology Inc.
DS00002236E-page 29
USB5806
8.3
FlexConnect
This feature allows the upstream port to be swapped with downstream physical port 1. Only downstream port 1 can be
swapped physically. The default state is when port 0 is the upstream port. The ‘flexed” state is when port 1 is the
upstream port.
FlexConnect can be enabled/disabled in any of the following ways:
• SMBus Configuration
• USB Command
• Direct Pin Control
8.3.1
SMBUS CONFIGURATION
FlexConnect can be controlled via runtime configuration registers through the SMBus Slave Interface during hub runtime (after enumeration).
8.3.2
USB COMMAND
A USB command to the internal Hub Feature Controller can be used to configure and initiate FlexConnect.
8.3.3
DIRECT PIN CONTROL
The FLEX_CMD control input can be used to control the FlexConnect state. When driven or pulled low, the hub will
operate in it’s default state. When driven or pull high, the hub will operate in it’s “flexed” state.
The FLEX_STATE output displays the current state of FlexConnect. It operates in the same manner regardless of how
FlexConnect is controlled (SMBus, USB Command, or Direct Pin Control). When low, the hub is currently in it’s default
state. When high, the hub is in its “flexed” state.
Note:
8.4
For additional information, refer to the Microchip USB58xx/USB59xx FlexConnect application note on the
Microchip.com USB5806 product page.
Resets
• Power-On Reset (POR)
• External Chip Reset (RESET_N)
• USB Bus Reset
8.4.1
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 10.6.2, Power-On
and Configuration Strap Timing.
8.4.2
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 10.6.3, Reset and Configuration Strap Timing. While reset is asserted, the device (and its associated external circuitry) enters Standby Mode and consumes minimal current.
Assertion of RESET_N causes the following:
1.
2.
3.
4.
5.
The PHY is disabled and the differential pairs will be in a high-impedance state.
All transactions immediately terminate; no states are saved.
All internal registers return to the default state.
The external crystal oscillator is halted.
The PLL is halted.
Note:
All power supplies must have reached the operating levels mandated in Section 10.2, Operating Conditions**, prior to (or coincident with) the assertion of RESET_N.
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2016-2021 Microchip Technology Inc.
USB5806
8.4.3
USB BUS RESET
In response to the upstream port signaling a reset to the device, the device performs the following:
1.
2.
3.
4.
Sets default address to 0.
Sets configuration to Unconfigured.
Moves device from suspended to active (if suspended).
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:
8.5
The device does not propagate the upstream USB reset to downstream devices.
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:
LPM STATE DEFINITIONS
State
8.6
Description
Entry/Exit Time to L0
L2
Suspend
Entry: ~3 ms
Exit: ~2 ms (from start of RESUME)
L1
Sleep
Entry: