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XR22804IL56-F

XR22804IL56-F

  • 厂商:

    SIPEX(迈凌)

  • 封装:

    56-VFQFN裸露焊盘

  • 描述:

    ICCONTROLLERETHERNET56QFN

  • 数据手册
  • 价格&库存
XR22804IL56-F 数据手册
XR22804 Hi-Speed USB to 10/100 Ethernet Bridge with 4 UARTs FEATURES General Description The XR22804 is a Hi-Speed USB 2.0 compound device with an embedded hub and 7 downstream USB functions: 10/100 Ethernet MAC and Phy, 4 UARTs, multi-master capable I2C controller, and an Enhanced Dedicated GPIO Entity (EDGE) controller. The upstream USB interface has an integrated USB 2.0 PHY and device controller that is compliant with both Hi-Speed (480Mbps) and Full-Speed (12Mbps) USB 2.0. The vendor ID, product ID, power mode, remote wakeup support and maximum power consumption are amongst the values that can be programmed using the on-chip One-Time Programmable (OTP) memory. The 10/100 Ethernet MAC and PHY is compliant with IEEE 802.3 and supports auto-negotiation, auto-MDIX, checksum offload, auto-polarity correction in 10Base-T and remote wakeup capabilities. The enhanced UART has a maximum data rate of 15 Mbps. Using a fractional baud rate generator, any baud rate between 300 bps and 15 Mbps can be accurately generated. In addition, the UART has a large 1024-byte TX FIFO and RX FIFO to optimize the overall data throughput for various applications. The automatic RS485 control feature simplifies both the hardware and software for half-duplex RS-485 applications. If required, the multidrop (9-bit) mode feature further simplifies typical multidrop applications by enabling / disabling the UART receiver depending on the address byte received. The multi-master capable I2C controller and EDGE controller (up to 32 GPIOs) can be accessed via the USB HID interface. The EDGE pins or I2C interface can be used for controlling and monitoring other peripherals. Up to 2 EDGE pins can be configured as a PWM generator.  USB 2.0 Compliant Interface  10/100 Ethernet MAC and Phy  Enhanced UART  I2C Multi-master  Enhanced Dedicated GPIO Entity (EDGE)  Single 5.0V Power Supply Input  Regulated +3.3V Output Power  Single 25MHz Crystal  ±15kV HBM ESD Protection on USB data pins  ±8kV HBM ESD Protection on all other pins  USB CDC-ACM, CDC-ECM and HID compliant  Custom Software Drivers APPLICATIONS  USB to Ethernet Dongles  POS Terminals  Test Instrumentation  Networking  Factory Automation and Process Controls  Industrial Applications Ordering Information – Back Page Block Diagram 10/100 Ethernet MAC OTP Memory Ethernet Phy I2C Multimaster USB Upstream USB Phy 25 MHz XO USB 2.0 Hub UART Ch A / UART Ch Modem IOB / UART Ch Modem IOB / UART Ch Modem IOB / Modem IO Ethernet I 2C UART Ch. A, B, C, D / EDGE EDGE Controller 1 / 48 maxlinear.com/XR22804 Rev 1D XR22804 Extended Features • USB 2.0 Compliant Interface • Enhanced UART features • Data rates up to 15 Mbps • Fractional Baud Rate Generator • 1024 byte TX and RX FIFOs • 7, 8 or 9 data bits, 1 or 2 stop bits • Automatic Hardware Flow Control • Automatic Software Flow Control • Multidrop (9-bit) mode • Auto RS-485 Half-Duplex Control • Integrated USB 2.0 PHY • Supports 480 Mbps USB Hi-Speed and 12 Mbps USB Full-Speed data rate • Supports USB suspend, resume and remote wakeup operations • Compatible with USB CDC-ECM and CDC-ACM • 10/100 Ethernet MAC and Phy • Compliant with IEEE 802.3 • Integrated 10/100 Ethernet MAC and PHY • 10BASE-T and 100BASE-TX support • Full-duplex and half-duplex support • Full-duplex and half-duplex flow control • Preamble generation and removal • Automatic 32-bit CRC generation and checking • Automatic payload padding and pad removal • Diagnostic loop-back modes • TCP/UDP/IP/ICMP checksum offload support • Flexible Address filtering modes • Wakeup packet support • Support for 2 status LEDs • I2C Multi-master • Up to 400 kbps transfers • Multi-master capable • Enhanced Dedicated GPIO Entity (EDGE) • Parallel GPIO access • Two PWM generators • Custom software drivers • Windows XP, Vista, 7, 8, 8.1 and 10 • Windows CE 6.0 • Linux • Mac OS X 2 / 48 maxlinear.com/XR22804 Rev 1D XR22804 Absolute Maximum Ratings Operating Conditions Stresses beyond the limits listed below may cause permanent damage to the device. Exposure to any Absolute Maximum Rating condition for extended periods may affect device reliability and lifetime. Operating Temperature Range................................-40°C to +85°C VCC Supply Voltage...............................................+4.4V to +5.25V VCC Supply Voltage.............................................................+5.75V Input Voltage (all pins except SCL, SDA, USBD+, USBD–)..............-0.3 to +4.0V Input Voltage (USBD+ and USBD–).......................-0.3V to +5.75V Input Voltage (SCL and SDA)...................................-0.3V to +6.0V Junction Temperature............................................................125°C Electrical Characteristics Unless otherwise noted: TA = -40°C to +85°C, VCC = 4.4V to 5.25V Symbol Parameter Conditions Min Typ Max Units Power Consumption ICC Operating Current No load on GPIO pins or 3V3_OUT 185 250 mA ISUSP Suspend Mode Current No load on GPIO pins or 3V3_OUT 3 4.5 mA UART, VBUS_SENSE, LOW_PWR# and EDGE Pins VIL Input Low Voltage -0.3 0.8 V VIH Input High Voltage 2.0 3.6 V VOL Output Low Voltage IOL = 4mA 0.3 V VOH Output High Voltage IOL = -4mA IIL Input Low Leakage Current ±10 μA IIH Input High Leakage Current ±10 μA CIN Input Pin Capacitance 5 pF 2.2 V USB I/O Pins VOL Output Low Voltage Full-speed USB. External 15kΩ to GND on USBD+ and USBD- pins 0 0.3 V VOH Output High Voltage Full-speed USB. External 15kΩ to GND on USBD+ and USBD- pins 2.8 3.6 V VOL Output Low Voltage Hi-speed USB. External 45 Ω to GND on USBD+ and USBD- pins -300 300 mV VOH Output High Voltage Hi-speed USB. External 45 Ω to GND on USBD+ and USBD- pins 360 440 mV VDrvZ Driver Output Impedance IOSC Output Short Circuit Current 45 1.5V on USBD+ and USBD- pins 3 / 48 Ω 52 mA maxlinear.com/XR22804 Rev 1D XR22804 Symbol Parameter Conditions Min Typ Max Units 950 1050 mV -950 -1050 mV 98 102 % Ethernet I/O Pins - 100Base-TX transmit mode VPPH Peak Differential Output Voltage High VPPL Peak Differential Output Voltage Low VSAS Signal Amplitude Symmetry TRF Signal Rise and Fall Time 3 5 ns DCD Duty Cycle Distortion 0 0.5 ns VOS Overshoot and Undershoot 0 5 % - Transmit Jitter 0 1.4 ns Measured at line side of transformer, line replaced by differential resistance of 100 ohms. 2.2 2.8 V Max load current 50 mA 3.0 3.6 V Measured at line side of transformer, line replaced by differential resistance of 100 ohms. Measured differentially Ethernet I/O Pins - 10Base-T transmit mode VPPH Peak Differential Output Voltage High 3.3V Regulated Power Output VOUT Output Voltage 4 / 48 3.3 maxlinear.com/XR22804 Rev 1D XR22804 SDA SCL E3/DTRA#/GA3 E2/DSRA#/GA2 E11/DTRB#/GB3 E10/DSRB#/GB2 GND LOW_PWR# E12/CTSB#/GB4 E13/RTSB#/RS485B/GB5 E15/TXB E14/RXB/RWKB# E4/CTSA#/GA4 E5/RTSA#/RS485A/GA5 56 55 54 53 52 51 50 49 48 47 46 45 44 43 Pin Configuration E30/RXD/RWKD# 1 42 E7/TXA 41 E6/RXA/RWKA# 40 GND E31/TXD 2 VBUS_SENSE 3 REXT 4 39 E9/CDB#/GB1 E29/RTSD#/RS485D/GD5 5 38 E8/RIB#/RWKB#/GB0 E28/CTSD#/GD4 6 37 E18/DSRC#/GC2 CAP1 7 36 GND GND 8 35 CAP2 USBD- 9 34 E19/DTRC#/GC3 USBD+ 10 33 ETH_LINK VCC 11 32 E16/RIC#/RWKC#/GC0 E26/DSRD#/GD2 12 31 E17/CDC#/GC1 ETH_SPD 13 30 E1/CDA#/GA1 29 E0/RIA#/RWKA#/GA0 E_PAD 25 26 27 ETH_RX- E22/RXC/RWKC# E23/TXC E21/RTSC#/RS485C/GC5 E20/CTSC#/GC4 24 GND 23 20 3V3_OUT ETH_RX+ 19 E25/CDD#/GD1 22 18 E24/RID#/RWKD#/GD0 21 17 XTALIN ETH_TX- 16 ETH_TX+ 15 14 28 CNTR_PAD XTALOUT E27/DTRD#/GD3 MaxLinear XR22804 Top View Pin Assignments Pin No. Pin Name Type Description 1 E30/RXD/RWKD# I/O Enhanced general purpose IO, or UART channel D RX data, or remote wakeup. Defaults to UART RX data. 2 E31/TXD I/O Enhanced general purpose IO, or UART channel D TX data. Defaults to UART TX data. 3 VBUS_SENSE I VBUS Sense input. In self-powered mode, the VBUS from the USB connector needs to be connected to this pin through a voltage divider circuit (VBUS = 5V, VBUS_SENSE = 3.3V input) using large resistance values to minimize power. It should also be decoupled by a 0.1uF capacitor. This feature may be enabled via the OTP whenever the hub function is configured for self-powered mode. The VBUS_SENSE input is used to disable the pull-up resistor on the USBD+ signal when VBUS is not present. In bus-powered mode, this pin is ignored. 4 REXT I Connect externally using short trace to 226 ohm 1% resistor to ground 5 E29/RTSD#/RS485D/GD5 I/O Enhanced general purpose IO, or UART channel D Request to Send, or channel D autoRS485 half-duplex enable, or general purpose IO. Defaults to UART GPIO input except when XR22804 is used with CDC-ACM driver. Refer to Automatic RTS/CTS Hardware Flow Control section on page 15 or Auto RS-485 Half-Duplex Control on page 16. 5 / 48 maxlinear.com/XR22804 Rev 1D XR22804 Pin No. Pin Name Type I/O Description 6 E28/CTSD#/GD4 7 CAP1 I 8 GND PWR 9 USBD– I/O USB port differential data negative 10 USBD+ I/O USB port differential data positive 11 VCC 12 E26/DSRD#/GD2 I/O Enhanced general purpose IO, or UART channel D Data Set Ready, or general purpose IO. Defaults to UART GPIO input. Refer to Automatic DTR/DSR Hardware Flow Control section on page 16. 13 ETH_SPD O Ethernet 10/100 Mbps Speed Indicator. Asserted high for 100 Mbps. 14 E27/DTRD#/GD3 I/O Enhanced general purpose IO, or UART channel D Data Terminal Ready, or general purpose IO. Defaults to UART GPIO input. Refer to Automatic DTR/DSR Hardware Flow Control section on page 16. 15 XTALOUT O Crystal or buffered clock output 16 XTALIN I 25 MHz +/- 50 ppm Crystal or external clock input 17 E24/RID#/RWKD#/GD0 I/O Enhanced general purpose IO, or UART channel D Ring Indicator, or remote wakeup, or general purpose IO. Defaults to UART GPIO input. Refer to Remote Wakeup section on page 11. 18 E25/CDD#/GD1 I/O Enhanced general purpose IO, or UART channel D Carrier Detect, or general purpose IO. Defaults to UART GPIO input. 19 3V3_OUT PWR 3.3 V output power. Connect externally to CAP1 and CAP2 using short trace and decouple with minimum of 4.7uF capacitor 20 GND PWR Power supply common, ground 21 ETH_TX– O Ethernet transmit data out negative 22 ETH_TX+ O Ethernet transmit data out positive 23 ETH_RX+ I Ethernet receive data in positive 24 ETH_RX– I Ethernet receive data in negative 25 E22/RXC/RWKC# I/O Enhanced general purpose IO, or UART channel C RX data, or remote wakeup. Defaults to UART RX data. 26 E23/TXC I/O Enhanced general purpose IO, or UART channel C TX data. Defaults to UART TX data. 27 E21/RTSC#/RS485C/GC5 I/O Enhanced general purpose IO, or UART channel C Request to Send, or channel C autoRS485 half-duplex enable, or general purpose IO. Defaults to UART GPIO input except when XR22804 is used with CDC-ACM driver. Refer to Automatic RTS/CTS Hardware Flow Control section on page 15 or Auto RS-485 Half-Duplex Control on page 16. 28 E20/CTSC#/GC4 I/O Enhanced general purpose IO, or UART channel D Clear to Send, or general purpose IO. Defaults to UART GPIO input except when XR22804 is used with CDC-ACM driver. Refer to Automatic RTS/CTS Hardware Flow Control section on page 15. 29 E0/RIA#/RWKA#/GA0 I/O Enhanced general purpose IO, or UART channel A Ring Indicator, or remote wakeup, or general purpose IO. Defaults to UART GPIO input. Refer to Remote Wakeup section on page 11. 30 E1/CDA#/GA1 I/O Enhanced general purpose IO, or UART channel A Carrier Detect, or general purpose IO. Defaults to UART GPIO input. PWR Enhanced general purpose IO, or UART channel D Clear to Send, or general purpose IO. Defaults to UART GPIO input except when XR22804 is used with CDC-ACM driver. Refer to Automatic RTS/CTS Hardware Flow Control section on page 15. Connect externally to CAP2 and 3V3_OUT using short trace Power supply common, ground 5.0V power supply input 6 / 48 maxlinear.com/XR22804 Rev 1D XR22804 Pin No. Pin Name Type Description 31 E17/CDC#/GC1 I/O Enhanced general purpose IO, or UART channel C Carrier Detect, or general purpose IO. Defaults to UART GPIO input. 32 E16/RIC#/RWKC#/GC0 I/O Enhanced general purpose IO, or UART channel C Ring Indicator, or remote wakeup, or general purpose IO. Defaults to UART GPIO input. Refer to Remote Wakeup section on page 11. 33 ETH_LINK O Ethernet 10/100 Activity Indicator. Toggles with activity 34 E19/DTRC#/GC3 I/O Enhanced general purpose IO, or UART channel C Data Terminal Ready, or general purpose IO. Defaults to UART GPIO input. Refer to Automatic DTR/DSR Hardware Flow Control section on page 16 35 CAP2 I 36 GND PWR 37 E18/DSRC#/GC2 I/O Enhanced general purpose IO, or UART channel C Data Set Ready, or general purpose IO. Defaults to UART GPIO input. Refer to Automatic DTR/DSR Hardware Flow Control section on page 16. 38 E8/RIB#/RWKB#/GB0 I/O Enhanced general purpose IO, or UART channel B Ring Indicator, or remote wakeup, or general purpose IO. Defaults to UART GPIO input. Refer to Remote Wakeup section on page 11. 39 E9/CDB#/GB1 I/O Enhanced general purpose IO, or UART channel B Carrier Detect, or general purpose IO. Defaults to UART GPIO input. 40 GND 41 E6/RXA/RWKA# I/O Enhanced general purpose IO, or UART channel A RX data, or remote wakeup. Defaults to UART RX data. 42 E7/TXA I/O Enhanced general purpose IO, or UART channel A TX data. Defaults to UART TX data. 43 E5/RTSA#/RS485A/GA5 I/O Enhanced general purpose IO, or UART channel A Request to Send, or auto-RS485 halfduplex enable, or general purpose IO. Defaults to UART GPIO input except when XR22804 is used with CDC-ACM driver. Refer to Automatic RTS/CTS Hardware Flow Control section on page 15 or Auto RS-485 Half-Duplex Control on page 16. 44 E4/CTSA#/GA4 I/O Enhanced general purpose IO, or UART channel A Clear to Send, or general purpose IO. Defaults to UART GPIO input except when XR22804 is used with CDC-ACM driver. Refer to Automatic RTS/CTS Hardware Flow Control section on page 15. 45 E14/RXB/RWKB# I/O Enhanced general purpose IO, or UART channel B RX data, or remote wakeup. Defaults to UART RX data. 46 E15/TXB I/O Enhanced general purpose IO, or UART channel B TX data. Defaults to UART TX data. 47 E13/RTSB#/RS485B/GB5 I/O Enhanced general purpose IO, or UART channel B Request to Send, or channel B autoRS485 half-duplex enable, or general purpose IO. Defaults to UART GPIO input except when XR22804 is used with CDC-ACM driver. Refer to Automatic RTS/CTS Hardware Flow Control section on page 15 or Auto RS-485 Half-Duplex Control on page 16. 48 E12/CTSB#/GB4 I/O Enhanced general purpose IO, or UART channel B Clear to Send, or general purpose IO. Defaults to UART GPIO input except when XR22804 is used with CDC-ACM driver. Refer to Automatic RTS/CTS Hardware Flow Control section on page 15. 49 LOW_PWR# O The LOW_PWR# pin will be asserted whenever it is not safe to draw the amount of current requested from VBUS in the Device Maximum Power field of the Configuration Descriptor. The LOW_PWR# pin is asserted when the XR22804 is in suspend mode or when it is not yet configured. The LOW_PWR# pin will be de-asserted whenever it is safe to draw the amount of current requested in the Device Maximum Power field. Note that the XR22804 device is a high power device. The default polarity of the LOW_PWR# output pin is active low and is programmable via the OTP. 50 GND PWR PWR Connect externally to CAP1 and 3V3_OUT using short trace Power supply common, ground Power supply common, ground Power supply common, ground 7 / 48 maxlinear.com/XR22804 Rev 1D XR22804 Pin No. Pin Name Type Description 51 E10/DSRB#/GB2 I/O Enhanced general purpose IO, or UART channel B Data Set Ready, or general purpose IO. Defaults to UART GPIO input. Refer to Automatic DTR/DSR Hardware Flow Control section on page 16. 52 E11/DTRB#/GB3 I/O Enhanced general purpose IO, or UART channel B Data Terminal Ready, or general purpose IO. Defaults to UART GPIO input. Refer to Automatic DTR/DSR Hardware Flow Control section on page 16 53 E2/DSRA#/GA2 I/O Enhanced general purpose IO, or UART channel A Data Set Ready, or general purpose IO. Defaults to UART GPIO input. Refer to Automatic DTR/DSR Hardware Flow Control section on page 16. 54 E3/DTRA#/GA3 I/O Enhanced general purpose IO, or UART channel A Data Terminal Ready, or general purpose IO. Defaults to UART GPIO input. Refer to Automatic DTR/DSR Hardware Flow Control section on page 16. 55 SCL I/O OD I2C Master controller serial clock (open-drain) External pull-up resistor required on this pin. 56 SDA I/O OD I2C Master controller data (open-drain). External pull-up resistor required on this pin. CNTR_PAD PWR Must be connected to ground. Type: I = Input, O = Output, I/O = Input/Output, PWR = Power, OD = Open-Drain 8 / 48 maxlinear.com/XR22804 Rev 1D XR22804 Functional Block Diagram 5.0V VCC 5.0V VCC GND GND XTALIN XTALOUT USBD+ USBD- 10/100 Ethernet MAC 10/100 Ethernet PHY 25 MHz Xtal USB 2.0 Phy UART Channel A E31/TXD E30/RXD/RW KD# E29/RTSD#/RS485D/GD5 E28/CTSD#/GD4 E27/DTRD#/GD3 E26/DSRD#/GD2 E25/CDD#/GD1 E24/RID#/RWKD#/GD0 UART Channel B E23/TXC E22/RXC/RW KC# E21/RTSC#/RS485C/GC5 E20/CTSC#/GC4 E19/DTRC#/GC3 E18/DSRC#/GC2 E17/CDC#/GC1 E16/RIC#/RWKC#/GC0 USB 2.0 Hub UART Channel C VBUS_SENSE LOW_PWR# Pin Mux USB E15/TXB E14/RXB /RW KB# E13/RTSB#/RS485B/GB 5 E12/CTSB#/GB4 E11/DTRB#/GB3 E10/DSRB#/GB2 E9/CDB#/GB1 E8/RIB#/RW KB#/GB0 E7/TXA E6/RXA/RW KA# E5/RTSA#/RS485A/GA5 E4/CTSA#/GA4 E3/DTRA#/GA3 E2/DSRA#/GA2 E1/CDA#/GA1 E0/RIA#/RW KA#/GA0 UART Channel D Descriptors ETH_LINK ETH_SPD ETH_TX+ ETH_TXETH_RX+ ETH_RX- EDGE Controller OTP I2C Master 9 / 48 SDA SCL maxlinear.com/XR22804 Rev 1D XR22804 Functional Description USB Interface The XR22804 is a USB compound device with an embedded hub and 7 downstream functions. The downstream functions of the XR22804 are 10/100 Ethernet, 4 UART functions, an I2C function, and an Enhanced Dedicated GPIO Entity (EDGE) function. The upstream USB interface of the XR22804 is compliant with both USB 2.0 full and hi-speed specifications. All functions downstream of the hub are hi-speed functions. The XR22804 will have a single vendor ID and vendor string. Each function in the XR22804 will have an individual product string and serial string. The default serial number strings will be based upon the uniquely assigned Ethernet MAC address for each XR22804 device. The serial strings for multiple functions within the same device will differ only by a single character which will be assigned a value between 0 and 7. All string and ID values can be overridden via OTP. The XR22804 can be placed into a low power or suspended state by the USB host. By default the XR22804 hub is configured for bus powered mode with a maximum power of 250 mA. All other functions in the XR22804 are configured for selfpowered mode. In bus powered mode, the Ethernet Phy must be powered down during suspended state to meet USB suspend power requirements. The Ethernet Phy may remain enabled to support Ethernet remote wakeup during suspend if the the device is self-powered and the the OTP is modified to report the hub function as self-powered in the USB descriptors. See Ethernet Remote Wakeup section on page 13. Each function of the XR22804 supports one configuration and utilizes the following USB endpoints: • USB hub • Control endpoint • Interrupt-in endpoint • Ethernet function • Control endpoint • Interrupt-in endpoint • Bulk-in and bulk-out endpoints • I2C function • Control endpoint • Interrupt-in and interrupt-out endpoints • EDGE Controller function • Control endpoint • Interrupt-in and interrupt-out endpoints • UART function • Control endpoint • Interrupt-in endpoint • Bulk-in and bulk-out endpoints USB Vendor ID Exar’s USB vendor ID is 0x04E2. This is the default vendor ID that is used for the XR22804. Companies may obtain their own vendor ID, by becoming members of USB.org. The XR22804 OTP can then be modified to report this vendor ID in the USB descriptors. USB Product ID Each function in the XR22804 has an individual USB product ID. The default product IDs for each of the functions are shown in Table 1. These values can be modified by programming the OTP. Companies using their own vendor ID may also 10 / 48 maxlinear.com/XR22804 Rev 1D XR22804 select their own product IDs. Additionally, upon request MaxLinear will provide a selection of different product IDs for use with Exar’s vendor ID for companies that do not wish to become members of USB.org, but wish to use their own product ID. Table 1: Default XR22804 Product IDs XR22804 Function Default Product ID Hub 0x0804 Ethernet 10/100 0x1300 UART Channel A 0x1400 UART Channel B 0x1401 UART Channel C 0x1402 UART Channel D 0x1403 I2C 0x1100 EDGE 0x1200 USB Suspend All USB peripheral devices must support the USB suspend mode. Per USB standard, the XR22804 device will begin to enter the suspend state if it does not detect any activity, (including Start of Frame or SOF packets) on its USB data lines for 3 ms. The peripheral device must then reduce power consumption from VBUS power within the next 7 ms to the allowed limit of 2.5 mA per function for the suspended state. Because the XR22804 is a compound device with 8 functions, the suspend state power limit is 20 mA for the device. Note that in this context, the "device" is all circuitry (including the XR22804) that draws power from the host VBUS. Remote Wakeup When the XR22804 is suspended, the E0/RIA#/RWKA#/GA0, E8/RIB#/RWKB#/GB0, E16/RIC#/RWKC#/GC0 or the E24/ RID#/RWKD#/GD0 pins may be used to request that the host exit the suspend state if configured as an input. A high to low transition on any of these pins may be used to signal a remote wakeup request to the host via MaxLinear’s custom driver. However, because the four pins are internally logically ANDed, a logic ‘0’ on any of the four inputs will prevent the resume signaling. Note that the CDC-ACM driver does not support the remote wakeup feature. The E0/RIA#/RWKA#/GA0, E8/ RIB#/RWKB#/GB0, E16/RIC#/RWKC#/GC0 or the E24/RID#/RWKD#/GD0 pins may be used to signal remote wakeup by default. Additionally, the E6/RXA/RWKA#, E14/RXB/RWKB#, E22/RXC/RWKC# or E30/RXD/RWKD# pins, if configured as an input, may also be used for remote wakeup if enabled using the REMOTE_WAKEUP register. The Ethernet function in the XR22804 can also be used for remote wakeup under certain conditions. Refer to Ethernet Remote Wakeup on page 13. USB Strings USB specifies three character string descriptors that are provided to the USB host during enumeration in string descriptors: the manufacturer, product and serial strings. In a compound device such as the XR22804, each function provides these strings to the USB host. The default manufacturer string for the XR22804 device is "Exar Corp.". The default product strings for the hub, Ethernet function, UART functions, I2C function and EDGE function are shown in Table 2. The serial number string is a unique alpha-numeric ASCII string programmed into the device at the factory. 11 / 48 maxlinear.com/XR22804 Rev 1D XR22804 Table 2: Default XR22804 Product Strings XR22804 Function Default Product String Hub Exar’s XR22804 Hub Ethernet 10/100 Exar USB Ethernet UARTs Exar USB UART I2C Exar USB I2C EDGE Exar USB EDGE The OTP may be used to override these strings. However, to ensure unique serial numbers for each device, it is recommended that the factory pre-programmed serial number string be used and not be overwritten via OTP. USB Device Drivers Each of the functions in the XR22804 require a USB device driver for operation. Both the I2C and EDGE functions conform to the HID device class and as such, utilize the embedded HID driver that is native to each Operating System. The embedded hub also uses the native hub driver. The Ethernet function conforms to the CDC device class and as such can utilize an embedded CDC-ECM driver. However, at the time of this writing, none of the Microsoft OS provide support for CDC-ECM embedded drivers. Both Linux and Mac OS-X platforms do support CDC-ECM drivers. The CDC-ECM driver is a class specific driver which provides functionality for USB Ethernet devices. Maxlinear provides a custom Ethernet device driver for Windows operating systems which has been optimized for the best possible data throughput. The UART function can be used with either a class specific CDC-ACM driver or a custom driver. When the CDC-ACM driver is used, the driver has no ability to read or write the XR22804 device registers. Because of this, the XR22804 device is initialized to the settings in Table 3. With a custom driver, all GPIOs default in hardware to inputs but these settings may be modified by a custom driver. Table 3: XR22804 Register Defaults With CDC-ACM Driver Register Value Notes Flow Control 0x001 Hardware Flow Control GPIO_MODE 0x001 RTS / CTS Flow Control GPIO_DIRECTION 0x008 E3/DTRA#/GA3, E11/DTRB#/GB3, E19/DTRC#/GC3 and E27/ DTRD#/GD3 are configured as outputs. All other GPIOs as inputs. GPIO_INT_MASK 0x030 E[n]/RI#/RWK#/G[n], E[n]/CD#/G[n] and E[n]/DSR#/G[n] for all UART channels are interrupt sensitive, i.e. can cause a USB interrupt to be generated These default settings can be overridden by programming the OTP. If a custom driver is used, the CUSTOM_DRIVER_ACTIVE bit should be immediately set to ’1’ by the USB UART driver. Once the CUSTOM_DRIVER_ACTIVE bit is set, the custom driver can use standard CDC-ACM commands without configuring the device to the default register settings used with the CDC-ACM driver. Any changes to the register settings for the GPIOs and flow control will specifically need to be configured by the driver / application software. Although there is no ability to read / write registers when using the CDC-ACM driver, basic UART functions, including setting baud rate, character format and sending line break is supported by the CDC driver. Refer to the 4 CDC_ACM_IF USB Control Commands listed in Table 4. 12 / 48 maxlinear.com/XR22804 Rev 1D XR22804 10/100 Ethernet The Ethernet port is a 10/100 Ethernet MAC and Phy compliant with IEEE 802.3. The Ethernet port supports speed / duplex auto-negotiation, auto-MDIX, 10 Mbps data auto-polarity, full and half duplex data rates at 10 and 100 Mbps, generates and validates the 32-bit FCS, and performs unicast and multicast filtering. The XR22804 also performs TCP, UDP and ICMP checksum offload over IPV4 and IPV6 as well as header checksum offload in IPV4. On chip RAM provides all required packet buffering. In Windows OS, using the MaxLinear custom Ethernet driver, the properties dialog, advanced properties can be used to set the pause frame flow control, speed and duplex, auto-negotiation, checksum offload, and Ethernet remote wakeup settings. By default, the Ethernet MAC will honor incoming pause frames sent by a peer Ethernet device, but will not generate pause frames. Auto-MDIX is always enabled. Ethernet Remote Wakeup If the XR22804 hub is configured as a self-powered device and has Ethernet remote wakeup enabled, the XR22804 will request the USB host to resume in response to a magic packet or a link state change on the Ethernet port. When the USB host is suspended, the Ethernet Phy remains active and the XR22804 is able to both meet USB suspend mode power requirements as well as respond to magic packet and link state changes. The magic packet is an Ethernet packet with specific content, i.e. 6 bytes of 0xFF, followed by 16 repetitions of the target MAC address (MAC address of the XR22804 device). This content can occur anywhere in the incoming packet payload. The link state change will wake the USB host if the link is down when the USB host is suspended and then the link goes up, or if the link is up when the USB host is suspended and then the link goes down. UART The UART can be configured via USB control transfers from the USB host. The UART transmitter and receiver sections are described separately in the following sections. At power-up, the XR22804 will default to 9600 bps, 8 data bits, no parity bit, 1 stop bit, and no flow control. If a native CDC-ACM driver accesses the XR22804, defaults will change. See Remote Wakeup section on page 11. UART transmitter The transmitter consists of a 1024-byte TX FIFO and a Transmit Shift Register (TSR). Once a bulk-out packet has been received and the CRC has been validated, the data bytes in that packet are written into the TX FIFO of the specified UART channel. Data from the TX FIFO is transferred to the TSR when the TSR is idle or has completed sending the previous data byte. The transmitter sends the start bit followed by the data bits (starting with the LSB), inserts the proper parity-bit if enabled, and adds the stop-bit(s). The transmitter can be configured for 7 or 8 data bits with or without parity or 9 data bits without parity. If 9 bit data is selected without wide mode, the 9th bit will always be ’0’. UART transmitter - Wide mode When both 9 bit data and wide mode are enabled, two bytes of data must be written. The first byte that is loaded into the TX FIFO are the first 8 bits (data bits 7-0) of the 9-bit data. Bit-0 of the second byte that is loaded into the TX FIFO is bit-8 of the 9-bit data. The data that is transmitted on the TX pin is as follows: start bit, 9-bit data, stop bit. Use the TX_WIDE_MODE register to enable transmit wide mode. UART receiver The receiver consists of a 1024-byte RX FIFO and a Receive Shift Register (RSR). Data that is received in the RSR via the RX pin is transferred into the RX FIFO. Data from the RX FIFO is sent to the USB host in response to a bulk-in request. Depending on the mode, error / status information for that data character may or may not be stored in the RX FIFO with the data. UART receiver - Normal mode with 7 or 8-bit data Data that is received is stored in the RX FIFO. Any parity, framing or overrun error or break status information related to the data is discarded. Receive data format is shown in Figure 1. 13 / 48 maxlinear.com/XR22804 Rev 1D XR22804 UART receiver - Normal mode with 9-bit data The first 8 bits of data received is stored in the RX FIFO. The 9th bit as well as any parity, framing or overrun error or break status information related to the data is discarded. 7, 8 or 9-bit data 1ST byte 7 6 5 4 3 2 1 0 7 = ‘0’ in 7 bit mode Figure 1: UART Normal Receive Data Format with 7 or 8-bit data UART receiver - Wide mode with 7 or 8-bit data Two bytes of data are loaded into the RX FIFO for each byte of data received. The first byte is the received data. The second byte consists of the error bits and break status. Wide mode receive data format is shown in Figure 2. Use the RX_WIDE_MODE register to enable receive wide mode. Use the RX_WIDE_MODE register to enable receive wide mode. UART receiver - Wide mode with 9-bit data Two bytes of data are loaded into the RX FIFO for each byte of data received. The first byte is the first 8 bits of the received data. The 9th bit received is stored in the bit 0 of the second byte. The parity bit is not received / checked. The remainder of the 2nd byte consists of the framing and overrun error bits and break status. 7 or 8 bit m ode 1st byte 7 6 5 4 3 2 1 0 2nd byte x x x x O F B P 7 = ‘0’ in 7 bit m ode P = Parity Error (= ‘0’ if not enabled) B = Break F = Fram ing Error O = O verrun Error x = ‘0’ 9 bit m ode 1st byte 7 6 5 4 3 2 1 0 2nd byte x x x x O F B 8 B = Break F = Fram ing Error O = O verrun E rror x = ‘0’ Figure 2: UART Receive Wide Mode Data Format with 7, 8 or 9-bit data Error flags are also available from the ERROR_STATUS register and the interrupt packet, however these flags are historical flags indicating that an error has occurred since the previous request. Therefore, no conclusion can be drawn as to which specific byte(s) may have contained an actual error in this manner. RX FIFO Low Latency In normal operation all bulk-in transfers will be of maxPacketSize bytes (512 bytes in hi-speed mode and 64 bytes in fullspeed mode) to improve throughput and to minimize host processing. When there are 512 / 64 bytes of data in the RX FIFO, the XR22804 will acknowledge a bulk-in request from the host and transfer the data packet. If there is less than 512 bytes in 14 / 48 maxlinear.com/XR22804 Rev 1D XR22804 the RX FIFO, the XR22804 may NAK the bulk-in request indicating that data is not ready to transfer at that time. However, if there is less than 512 bytes in the RX FIFO and no data has been received for more than 3 character times, the XR22804 will acknowledge the bulk-in request and transfer any data in the RX FIFO to the USB host. In some cases, especially when the baud rate is low, this increases latency unacceptably. The XR22804 has a low latency register bit that will cause the XR22804 to immediately transfer any received data in the RX FIFO to the USB host, i.e. it will not wait for 3 character times. The custom driver may automatically set the RX_CONTROL register to force the XR22804 to be in the low latency mode, or the user may manually set this bit. With the CDC-ACM driver, the low latency mode is automatically set whenever the baud rate is set to a value of less than 46921 bps using the CDC_ACM_IF_SET_LINE_CODING command. GPIO There can be up to 8 GPIO pins in the XR22804 UART including the UART RX and TX pins. These GPIO pins may be configured as UART GPIO, or for other UART functions, e.g. RTS# function, or be assigned to the EDGE. Refer to Enhanced Dedicated GPIO Entity section on page 17. Automatic RTS / CTS hardware flow control E[n]/RTS#/RS485/G[n] and E[n]/CTS#/G[n] of each UART channel may be enabled as the RTS# and CTS# signals for Auto RTS/CTS flow control when GPIO_MODE[2:0] = ’001’ and FLOW_CONTROL[2:0] = ’001’. Automatic RTS flow control is used to prevent data overrun errors in local RX FIFO by de-asserting the RTS signal to the remote UART. When there is room in the RX FIFO, the RTS pin will be re-asserted. Automatic CTS flow control is used to prevent data overrun to the remote RX FIFO. The CTS# input is monitored to suspend / restart the local transmitter (see Figure 3): L oc al U A R T UARTA R em ote U A R T U A R TB R e ce ive r F IF O T rig ger R ea ch ed RXA A uto R T S T rigge r Lev el RTSA# TXB CTSB# TXA T ran sm itter C TS A# A uto C T S M o nitor T ran sm itter A uto C T S M o nitor RXB R ec eiv er F IF O T rigge r R ea ch ed RTSB# A uto R T S T rigg er Lev el 9 RTSA# CTSB# 1 ON 2 6 7 ON ON OFF 10 OFF ON 3 TXB 11 8 4 5 RXA 1) C O M port op ene d, R X F IF O em p ty , R T S A # ou tp ut is as se rted 2) S ign al pro pag ated to C T S B # inp ut 3) D ata by te s en te r T X F IF O , beg in trans m ittin g on T X B 4) D ata pro pag ates to R e ce ivin g dev ic e R X A 5) R X F IF O rea ch es thres hold 6) R T S A # d e-a ss erts 7) S ign al pro pag ates to C T S B # in put 8) T rans m is sio n stops on T X B 9 ) U S B B ulk -In e m p ties R X F IF O b elow thres h o ld , R T S A # is as se rted 10 ) S igna l p rop aga te d to C T S B # inpu t 11 ) D a ta b ytes res um e tran sm itting on T X B Figure 3: Auto RTS / CTS Hardware Flow Control 15 / 48 maxlinear.com/XR22804 Rev 1D XR22804 Automatic DTR / DSR hardware flow control Auto DTR/DSR hardware flow control behaves the same as the Auto RTS/CTS hardware flow control described above except that it uses the DTR# and DSR# signals. For Auto hardware flow control, FLOW_CONTROL[2:0] = ’001’. E[n]/DTR#/ G[n] and E[n]/DSR#/G[n] of each UART channel become DTR# and DSR#, respectively, when GPIO_MODE[2:0] = ’010’. Automatic XON / XOFF software flow control When software flow control is enabled, the XR22804 compares the receive data characters with the programmed Xon or Xoff characters. If the received character matches the programmed Xoff character, the XR22804 will halt transmission as soon as the current character has completed transmission. Data transmission is resumed when a received character matches the Xon character. Software flow control is enabled when FLOW_CONTROL[2:0] = ’010’. Automatic RS-485 half duplex control The Auto RS-485 Half-Duplex Control feature changes the behavior of the E[n]/RTS#/RS485/G[n] pin of a UART channel when enabled by the GPIO_MODE register bits 2-0. See GPIO_MODE Register Description on page 24. The FLOW_CONTROL register must also be set appropriately for use in multidrop applications. See FLOW_CONTROL Register Description on page 22. If enabled, the transmitter automatically asserts the E[n]/RTS#/RS485/G[n] output prior to sending the data. By default, it de-asserts E[n]/RTS#/RS485/G[n] following the last stop bit of the last character that has been transmitted, but the RS485_DELAY register may be used to delay the deassertion. The polarity of the E[n]/RTS#/RS485/G[n] signal can also be modified using the GPIO_MODE register bit 3. Multidrop mode with address matching The XR22804 device has two address matching modes which are also set by the flow control register using modes 3 and 4. These modes are intended for a multi-drop network application. In these modes, the XON_CHAR register holds a unicast address and the XOFF_CHAR holds a multicast address. A unicast address is used by a transmitting master to broadcast an address to all attached slave devices that is intended for only one slave device. A multicast address is used to broadcast an address intended for more than one recipient device. Each attached slave device should have a unique unicast address value stored in the XON_CHAR register, while multiple slaves may have the same multicast adderss stored in the XOFF_CHAR register. An address match occurs when an address byte (9th bit or parity bit is ’1’) is received that matches the value stored in either the XON_CHAR or XOFF_CHAR register. Multidrop mode receiver If an address match occurs in either flow control mode 3 or 4, the UART Receiver will automatically be enabled and all subsequent data bytes will be loaded into the RX FIFO. The UART Receiver will automatically be disabled when an address byte is received that does not match the values in the XON_CHAR or XOFF_CHAR register. Multidrop mode transmitter In flow control mode 3, the UART transmitter is always enabled, irrespective of the RX address match. In flow control mode 4, the UART transmitter will only be enabled if there is an RX address match. Programmable Turn-Around Delay By default, the E[n]/RTS#/RS485/G[n] pin will be de-asserted immediately after the stop bit of the last byte has been shifted. However, this may not be ideal for systems where the signal needs to propagate over long cables. Therefore, the de-assertion of E[n]/RTS#/RS485/G[n] pin can be delayed from 1 to 15 bit times via the RS485_DELAY register to allow for the data to reach distant UARTs. Half-duplex mode Half-duplex mode is enabled when FLOW_CONTROL[3] = 1. In this mode, the UART will ignore any data on the RX input when the UART is transmitting data. 16 / 48 maxlinear.com/XR22804 Rev 1D XR22804 EDGE - Enhanced Dedicated GPIO Entity The XR22804 has 16 IO pins that may be assigned to the EDGE. By default, these pins are all assigned to the UART channel A and channel B functions, either to the UART data and / or flow control pins or to the UART GPIO. Note that UART GPIO and EDGE have separate register controls. Pins assigned to the UART function cannot be controlled by the EDGE registers and vice versa. To assign pins to the EDGE, use the EDGE_FUNC_SEL register. See EDGE_FUNC_SEL register description on page 38. The EDGE controller allows for GPIO signals to be individually set or cleared or to be grouped, such that the all pins in the group can be simultaneously accessed for reads or writes. Note that on write accesses, output pins will change in 4-bit subgroups on core clock (60 MHz) boundaries. For example, if an 8 bit data group is defined and the data value is written from 0x00 to 0xFF, 4 bits would change from ’0’ to ’1’ followed by the next 4 bits one clock cycle (~ 17 ns) later. EDGE IOs can be configured as inputs or outputs. Outputs can be configured as push-pull or open drain and can be tristated. Inputs can be configured to generate interrupts to the USB host on either negative or postive edge transitions. Another feature of the EDGE controller is that up to 2 GPIO pins within the EDGE can be assigned to pulse width modulated (PWM) outputs. Each of the PWM outputs can be used to generate an output clock or pulse of varying duty cycle. Both low and high cycles can be configured in steps of 267 ns up to 1.092 ms. The output can be controlled to generate a single "one-shot" pulse or to free run. Refer to the EDGE_PWM0_CTRL and EDGE_PWM1_CTRL registers on page 44 and page 45 for control of PWM outputs. I2C The XR22804 implements an I2C multi-master using the control endpoint of the full-speed USB function to transfer data to and from the I2C interface. The I2C master supports both standard (100 kbps) and fast (400 kbps) modes and supports multiple master configurations to allow other devices to access slave devices on the I2C. The I2C function is an HID function and uses the native HID driver. It supports both 7 and 10 bit addressing modes. Regulated 3.3V Power Output The XR22804 internal voltage regulator provides 3.3 VDC output power which can be utilized by other circuitry. Refer to Electrical Characteristics on page 3 for maximum power capability. For bus powered devices, significant utilization of the 3V3 output power may require increasing the maximum power request above the 250 mA default value from the USB host by programming the OTP. OTP The OTP is an on-chip non-volatile memory, that is one-time programmable via the USB interface. Bit locations within the memory may be programmed at various times allowing for customization of the XR22804. Some bits are pre-programmed at the factory and caution must be taken not to program any locations except user defined addresses. Contact the factory for information and assistance in programming the XR22804 OTP. 17 / 48 maxlinear.com/XR22804 Rev 1D XR22804 USB Control Commands The following table shows all of the USB Control Commands that are supported by the XR22804. Commands include standard USB commands, USB class specific CDC-ACM commands and USB vendor specific MaxLinear commands. Table 4: Supported USB Control Commands Name Request Type Value Index Length Request Description LSB MSB LSB MSB LSB MSB USB Standard Requests DEV GET_STATUS 0x80 0x0 0x0 0x0 0x0 0x0 0x2 0x0 Device: remote wake-up + self-powered IF GET_STATUS 0x81 0x0 0x0 0x0 0x0 0x0 0x2 0x0 Interface: zero EP GET_STATUS 0x82 0x0 0x0 0x0 0x0, 0x4, 0x84 0x0 0x2 0x0 Endpoint: halted DEV CLEAR_FEATURE 0x00 0x1 0x1 0x0 0x0 0x0 0x0 0x0 Device remote wake-up EP CLEAR_FEATURE 0x02 0x1 0x0 0x0 0x0, 0x4, 0x84 0x0 0x0 0x0 Endpoint halt DEV SET_FEATURE 0x00 0x3 0x1 0x0 0x0 0x0 0x0 0x0 Device remote wake-up EP SET_FEATURE 0x02 0x3 0x0 0x0 0x0, 0x4, 0x84 0x0 0x0 0x0 Endpoint halt SET_ADDRESS 0x00 0x5 addr 0x0 0x0 0x0 0x0 0x0 addr = 1 to 127 GET_DESCRIPTOR 0x80 0x6 0x0 0x1 0x0 0x0 len MSB len MSB Device descriptor GET_DESCRIPTOR 0x80 0x6 0x0 0x2 LangID LangID len MSB len MSB Configuration descriptor GET_DESCRIPTOR 0x80 0x6 0x0 0x3 0x0 0x0 len MSB len MSB String descriptor GET_CONFIGURATION 0x80 0x8 0x0 0x0 0x0 0x0 0x1 0x0 SET_CONFIGURATION 0x00 0x9 n 0x0 0x0 0x0 0x0 0x0 n = 0, 1 USB Class Specific Requests CDC_ACM_IF SET_LINE_CODING 0x21 0x20 0x0 0x0 0x0 0x0 0x7 0x0 Set the UART baud rate, parity, stop bits, etc. CDC_ACM_IF GET_LINE_CODING 0xA1 0x21 0x0 0x0 0x0 0x0 0x7 0x0 Get the UART baud rate, parity, stop bits, etc. CDC_ACM_IF SET_CONTROL_ LINE_STATE 0x21 0x22 0x0 0x0 0x0 0x0 0x7 0x0 Set/Clear DTR in CDCACM mode. CDC_ACM_IF SEND_BREAK 0x21 0x23 val LSB val MSB 0x0 0x0 0x0 0x0 Send a break for the specified duration. 18 / 48 maxlinear.com/XR22804 Rev 1D XR22804 Table 4: Supported USB Control Commands Value Request Type Request CDC_ECM_IF_ SET_ETH_MCAST_FILTERS 0x21 CDC_ECM_IF_ SET_ETH_PACKET_FILTERS CDC_ECM_IF_ GET_ETH_STATISTIC Name Index Length Description LSB MSB LSB MSB LSB MSB 0x40 Number (N) of filters LSB Number (N) of filters MSB 0x0 0x0 N*6 LSB N*6 MSB 0x21 0x43 *Bitmap LSB *Bitmap MSB 0x0 0x0 0x0 0x0 See Bitmap definition in note 1 below 0xA1 0x44 Selec tor 0x0 0x0 0x0 0x4 0x0 See Selector definition in note 2 below USB Vendor Specific Requests XR_GET_CHIP_ID 0xC0 0xFF 0x0 0x0 0x0 0x0 0x6 0x0 Get Exar VID (2 bytes), PID (2 bytes) and bcdDevice (2 bytes) XR_SET_REG See Table 5 0x40 0x05 writedata LSB writedata MSB write addr LSB write addr MSB 0x0 0x0 Vendor specific register access. XR_GET_REG See Table 5 0xC0 0x05 0x0 0x0 read addr LSB read addr MSB 0x2 0x0 Vendor specific register access. Note 1: SET_ETH_PACKET_FILTERS Bitmap definition: D15..D5: reserved D4: MULTICAST If 1, packets with multicast addresses set by SetEthernetMulticastFilter are forwarded to the host. 0 = Disabled. D3: BROADCAST If 1, broadcast packets are forwarded to the host. 0 = Disabled. D2: DIRECTED If 1, unicast packets with a matching address are forwarded to the host. 0 = Disabled. D1: ALL_MULTICAST If 1, all multicast packets are forwarded to the host. 0 = Disabled. D0: PROMISCUOUS If 1, all packets are forwarded to the host, regardless of address. 0 = Disbled. Note 2: SET_ETH_PACKET_FILTERS Selector definition: 0x01 = XMIT_OK 0x02 = RCV_OK 0x03 = XMIT_ERROR 0x04 = RCV_ERROR 0x05 = RCV_NO_BUFFER 0x0d = DIRECTED_FRAME_RCV 0x0f = MULTICAST_FRAME_RCV 0x11 = BROADCAST_FRAME_RCV 0x12 = RCV_CRC_ERROR 0x13 = XMIT_QUEUE_LENGTH 0x14 = RCV_ERR_ALIGNMENT 0x19 = RCV_OVERRUN 19 / 48 maxlinear.com/XR22804 Rev 1D XR22804 UART Registers UART registers are accessible via the USB interface using the XR_SET_REG and XR_GET_REG USB commands. Note that all addresses not listed in this table are reserved or undefined. Upper byte (bits 15:8) not shown in table are also reserved and should remain 0x00. Writing to any register other than those defined in Table 5 may result in undefined behavior of the device. The addresses for each of UARTs in the XR22804 are the same. Because each UART is assigned a unique USB address during enumeration by the USB host, a GUI connected to a specific COM port will be directed via the driver to the appropriate UART channel. UART Register Map Table 5: XR22804 Register Map Address Register Name Bit 7 (15) Bit 6 (14) Bit 5 (13) Bit 4 (12) Bit 3 (11) Bit 2 (10) Bit 1 (9) Bit 0 (8) 0 0 0 0 0 0 RX TX 0x040 UART_ENABLE 0x045 FORMAT 0x046 FLOW_CONTROL 0x047 XON_CHAR CHAR 0x048 XOFF_CHAR CHAR 0x049 ERROR_STATUS 0x04A STOP 0 BREAK _ACTIVE PARITY 0 0 OVERRUN PARITY DATA_BITS AUTO_ RS485 0 FRAME BREAK TX_BREAK (MSB) VALUE [MSB] TX_BREAK (LSB) VALUE [LSB] MODE 0 0 0 0x04B RS485_DELAY 0 0 0 0 0x04C GPIO_MODE 0 0 0 0 RS485_ POL 0x04D GPIO_DIRECTION 0 0 GPIO5 GPIO4 GPIO3 GPIO2 GPIO1 GPIO0 0x04E GPIO_SET 0 0 GPIO5 GPIO4 GPIO3 GPIO2 GPIO1 GPIO0 0x04F GPIO_CLEAR 0 0 GPIO5 GPIO4 GPIO3 GPIO2 GPIO1 GPIO0 0x050 GPIO_STATUS 0 0 GPIO5 GPIO4 GPIO3 GPIO2 GPIO1 GPIO0 0x051 GPIO_INT_MASK 0 0 GPIO5 GPIO4 GPIO3 GPIO2 GPIO1 GPIO0 0x052 CUSTOMIZED_INT 0 0 0 0 0 0 0 EN 0x054 PIN_PULLUP_EN TX RX GPIO5 GPIO4 GPIO3 GPIO2 GPIO1 GPIO0 0x055 PIN_PULLDOWN_EN TX RX GPIO5 GPIO4 GPIO3 GPIO2 GPIO1 GPIO0 0x056 LOOPBACK 0 0 0 0 0 DTR_ DSR RTS_ CTS TX_RX 0x057 IR_MODE 0 0 0 0 0 TX_ PULSE RX_ INVERT EN 0x05F REMOTE_WAKEUP 0 0 0 0 RX_EN RI_EN 0 0 0x060 TX_FIFO_RESET 0 0 0 0 0 0 0 RST 20 / 48 VALUE MODE maxlinear.com/XR22804 Rev 1D XR22804 Table 5: XR22804 Register Map Address Register Name TX_FIFO_FILL (MSB) 0x061 Bit 7 (15) Bit 6 (14) Bit 5 (13) Bit 4 (12) 0 0 0 0 TX_FIFO_FILL (LSB) Bit 3 (11) Bit 2 (10) Bit 0 (8) Bit 1 (9) FILL[10:8] FILL[7:0] 0x062 TX_WIDE_MODE 0 0 0 0 0 0 0 EN 0x063 RX_FIFO_RESET 0 0 0 0 0 0 0 RST RX_FIFO_FILL (MSB) 0 0 0 0 0 0x064 RX_FIFO_FILL (LSB) FILL[10:8] FILL[7:0] 0x065 RX_WIDE_MODE 0 0 0 0 0 0 0 EN 0x066 RX_CONTROL 0 0 0 0 0 0 MAX_ PKT_SIZE LOW_ LATEN CY FLOW_THRESHOLD (MSB) 0 0 0 0 0 0x067 FLOW_THRESHOLD (LSB) THRESH [10:8] THRESH [7:0] Miscellaneous Registers 0x081 CUSTOM_DRIVER 0 0 0 0 0 0 0 ACTIVE UART Register Descriptions Note that all register reset default values are ’0’ unless otherwise specified. All registers are 16 bits. UART_ENABLE (0x040) - Read/Write Bit Default Description 15:2 0x0000 Reserved 1 0 RX 0 0 TX These bits are reserved and should be written as ‘0’. 0: Disable UART RX 1: Enable UART RX 0: Disable UART TX 1: Enable UART TX 21 / 48 maxlinear.com/XR22804 Rev 1D XR22804 FORMAT (0x045) - Read/Write Note that the CDC_SET_LINE_CODING command may be used to set the UART data format in addition to this registers. Bit Default Description 15:8 0x00 Reserved 7 0 Stop 6:4 0 Parity 3:0 0x8 Data_Bits These bits are reserved and should be written as ‘0’. 0: 1 stop bit 1: 2 stop bits 000: No parity 001: Odd parity 010: Even parity 011: Mark parity 100: Space parity All other values undefined, do not use. 0111: 7-bit characters 1000: 8-bit characters 1001: 9-bit characters All other values undefined, do not use. FLOW_CONTROL (0x046) - Read/Write Bit Default Description 15:4 0x000 Reserved 3 0 Half-Duplex Mode 2:0 0 Mode These bits are reserved and should be written as ‘0’. 0: UART RX received data irrespective of UART TX 1: UART RX is disabled when UART TX is transmitting data 000: None 001: Hardware 010: Software 011: Address match RX 100: Address match RX and TX All other values undefined, do not use. XON_CHAR (0x047) - Read/Write Bit Default Description 15:8 0x00 Reserved 7:0 0x11 Char These bits are reserved and should be written as ‘0’. XON ASCII character received in hexadecimal format 22 / 48 maxlinear.com/XR22804 Rev 1D XR22804 XOFF_CHAR (0x048) - Read/Write Bit Default Description 15:8 0x00 Reserved 7:0 0x13 Char These bits are reserved and should be written as ‘0’. XOFF ASCII character received in hexadecimal format ERROR_STATUS (0x049) - Read Only Bit Default Description 15:8 0x00 Reserved 7 0 Break_Active 6 0 Overrun 5 0 Parity 4 0 Frame 3 0 Break 2:0 0 Reserved These bits are reserved and should be written as ‘0’. 0: No break condition currently active 1: Break condition currently active 0: No overrun error detected 1: Overrun error detected since last register read 0: No parity error detected 1: Parity error detected since last register read 0: No frame error detected 1: Frame error detected since last register read 0: No break error detected 1: Break error detected since last register read These bits are reserved and should be written as ‘0’. TX_BREAK (0x04A) - Read/Write Bit 15:0 Default 0x0000 Description Value This register controls transmission of break signal. Writing a non-zero value "N" to this registers causes the XR22804 to send a break signal on the UART TX pin for "N" ms, for 0 < N < 0xFFFF. A counter will decrement this value at 1 ms intervals until the count reaches 0x0 at which time the break signal will stop being sent. Writing a value of 0xFFFF causes a continuous break signal to be sent, until either a value of 0x0 is written or another non-zero value other than 0xFFFF which will again cause break signal to stop after the counter expires. 23 / 48 maxlinear.com/XR22804 Rev 1D XR22804 RS485_DELAY (0x04B) - Read/Write Bit Default Description 15:4 0x000 Reserved 3:0 000 Value These bits are reserved and should be written as ‘0’. This value is the number of bit times the XR22804 waits before de-asserting the E5/RTS#/RS485/G5 pin when it is configured for automatic RS-485 half-duplex control. GPIO_MODE (0x04C) - Read/Write Bit Default Description 15:4 0x000 Reserved 3 0 RS485 Polarity 2:0 0x0 GPIO Mode These bits are reserved and should be written as ‘0’. 0: Active low auto. RS-485 half-duplex enable 1: Active high auto. RS-485 half-duplex enable 000: Mode 0 - All GPIO are used for general purpose I/O. 001: Mode 1 - E5/RTS#/RS485/G5 and E4/CTS#/G4 used for Auto RTS/CTS HW Flow Control 010: Mode 2 - E3/DTR#/G3 and E2/DSR#/G2 used for Auto DTR/DSR HW Flow Control 011: Mode 3 - E5/RTS#/RS485/G5 pin used for auto RS-485 half-duplex enable during Transmit 100: Mode 4 - E5/RTS#/RS485/G5 pin used for auto RS-485 half-duplex enable after address match. 101 to 111: Reserved values, do not use. GPIO_DIRECTION (0x04D) - Read/Write Note that when setting direction of a UART GPIO to output, the PIN_PULLUP_EN for that IO pin should also be disabled and when setting a UART GPIO pin to input, the PIN_PULLUP_EN for that IO pin should also be enabled. Bit Default Description 15:6 0x000 Reserved 5:0 0x00 GPIO[N] Direction These bits are reserved and should be written as ‘0’. 0: GPIO[N] is an input 1: GPIO[N] is an output 24 / 48 maxlinear.com/XR22804 Rev 1D XR22804 GPIO_SET (0x04E) - Write Only Bit Default Description 15:6 0x000 Reserved 5:0 0x00 GPIO[N] Set These bits are reserved and should be written as ‘0’. 0: No effect 1: Set GPIO[N] if configured as an output to a logic ‘1’ GPIO_CLEAR (0x04F) - Write Only Bit Default Description 15:6 0x000 Reserved 5:0 0x00 GPIO[N] Clear These bits are reserved and should be written as ‘0’. 0: No effect 1: Clear GPIO[N] if configured as an output to a logic ‘0’ GPIO_STATUS (0x050) - Read Only Bit Default Description 15:6 0x000 Reserved 5:0 0x00 GPIO[N] Status These bits are reserved and should be written as ‘0’. Reading returns the current state of GPIO[N]. GPIO_INT_MASK (0x051) - Read/Write Bit Default Description 15:6 0x000 Reserved 5:0 0x00 GPIO[N] Mask These bits are reserved and should be written as ‘0’. Dictates whether a change in GPIO pin state causes the device to generate a USB interrupt packet. In either case, the GPIO status register will still report the pin's state when read, and if an interrupt packet is formed due to other interrupt trigger, the interrupt packet will contain the current state of the pin. 0: A change in the pin's state causes the device to generate an interrupt packet. 1: A change in the pin's state does not cause the device to generate an interrupt packet.’ 25 / 48 maxlinear.com/XR22804 Rev 1D XR22804 CUSTOMIZED_INT (0x052) - Read/Write Bit Default Description 15:1 0x0000 Reserved 0 0 Enable These bits are reserved and should be written as ‘0’. Enables the customized interrupt packet format to report all GPIO status in the interrupt packet. 0: Use standard interrupt packet. See Table 6 and Table 7. 1: Use customized interrupt packet. See Table 8. Table 6: Interrupt Packet Format Offset Field Size (Bytes) Value Description 0 bmRequestType 1 8’b10100001 D7 = Device-to-host direction D6:5 = Class Type D4-0: = Interface Recipient 1 bNotification 1 8’h20 2 wValue 2 16’h0000 4 wIndex 2 16’h0000 D15-8 = Reserved (0) D7-0 = Interface number, 8’h00 for the CDC Command Interface 6 wLength 2 16’h0002 2 bytes of transferred data 8 Data 2 Defined encoding for SERIAL_STATE Standard int_status (See Table 7) For customized int_status Size = 4 bytes (See Table 8) D15-7 = Reserved (0) D6 = bOverRun D5 = bParity D4 = bFraming D3 = bRingSignal (RI) D2 = bBreak D1 = bTxCarrier (DSR) D0 = bRxCarrier (CD) Table 7: Data Field of Standard Interrupt Packet Bits Field D15..D7 Description Reserved (future use) D6 bOverRun Received data has been discarded due to overrun in the device. D5 bParity A parity error has occured. D4 bFraming A framing error has occured. D3 bRingSignal State of ring signal detection of the device. D2 bBreak State of break detection mechanism of the device. D1 bTxCarrier State of transmission carrier. This signal corresponds to V.24 signal 106 and RS-232 signal DSR. 26 / 48 maxlinear.com/XR22804 Rev 1D XR22804 Table 7: Data Field of Standard Interrupt Packet Bits Field D0 bRxCarrier Description State of receiver carrier detection mechanism of device. This signal corresponds to V.24 signal 109 and RS-232 signal DCD. Table 8: Data Field of Customized Interrupt Packet - MaxLinear Vendor Specific Bit(s) 31-20 Description Reserved (0) 19 Overrun 18 Parity Error 17 Frame Error 16 Break Status 15-14 Reserved (0) 13 RTS state 12 CTS state 11 DTR state 10 DSR state 9 CD state 8 RI state 7-6 Reserved (0) 5 RTS change 4 CTS change 3 DTR change 2 DSR change 1 CD change 0 RI change Overrun, Parity Error, Frame Error, and Break all indicate that at least one event has occurred since the last interrupt message. "State" reflects the high/low state of the pin at the time the Interrupt Data IN packet was generated. "Change" indicates whether the level on the pin changed at least once since the last interrupt message. PIN_PULLUP_EN (0x054) - Read/Write Bit Default Description 15:8 0 Reserved 7 1 UART TX These bits are reserved and should be written as ‘0’. 0: Disable internal pull-up resistor on the UART TX pin 1: Enable internal pull-up resistor on the UART TX pin 27 / 48 maxlinear.com/XR22804 Rev 1D XR22804 Bit Default Description 6 1 UART RX 5:0 0x3F GPIO[N] 0: Disable internal pull-up resistor on the UART RX pin 1: Enable internal pull-up resistor on the UART RX pin 0: Disable internal pull-up resistor on the corresponding GPIO[N] pin 1: Enable internal pull-up resistor on the corresponding GPIO[N] pin PIN_PULLDOWN_EN (0x055) - Read/Write Bit Default Description 15:10 0 Reserved 7 0 UART TX 6 0 UART RX 5:0 0 GPIO[N] These bits are reserved and should be written as ‘0’. 0: Disable internal pull-down resistor on the UART TX pin 1: Enable internal pull-down resistor on the UART TX pin. (Will not be enabled if pull-up is already enabled.) 0: Disable internal pull-down resistor on the UART RX pin 1: Enable internal pull-down resistor on the UART RX pin. (Will not be enabled if pull-up is already enabled.) 0: Disable internal pull-down resistor on the corresponding GPIO[N] pin 1: Enable internal pull-down resistor on the corresponding GPIO[N] pin. (Will not be enabled if pull-up is already enabled.) LOOPBACK (0x056) - Read/Write Bit Default Description 15:3 0 Reserved 2 0 DTR_DSR 1 0 RTS_CTS 0 0 TX_RX These bits are reserved and should be written as ‘0’. 0: Disable DTR to DSR internal loopback 1: Enable DTR to DSR internal loopback 0: Disable RTS to CTS internal loopback 1: Enable RTS to CTS internal loopback When this bit is set all transmitted UART data is looped back to the UART receiver. Note that when the internal loopback is enabled, the Tx data will be disabled and Rx data will be ignored. 0: Disable TX to RX internal loopback 1: Enable TX to RX internal loopback 28 / 48 maxlinear.com/XR22804 Rev 1D XR22804 IR_MODE (0x057) - Read/Write Bit Default Description 15:3 0 Reserved 2 0 TX_Pulse 1 0 RX_Invert 0 0 En These bits are reserved and should be written as ‘0’. 0: TX pulse width is 3/16 of the bit period 1: TX pulse width is 4/16 of the bit period 0: RX input is not inverted before sampling 1: RX input is inverted before sampling 0: Disable IR mode 1: Enable IR mode REMOTE_WAKEUP (0x05F) - Read/Write Bit Default Description 15:4 0x000 Reserved 3 0 RX_En 2 1 RI_En 1:0 0x0 Reserved These bits are reserved and should be written as ‘0’. 0: RX pin remote wakeup is disabled 1: A high to low transition on the RX pin will cause a resume request to be sent to the USB host 0: RI# pin remote wakeup is disabled 1: A high to low transition on the RI# pin will cause a resume request to be sent to the USB host These bits are reserved and should be written as ‘0’. TX_FIFO_RESET (0x060) - Write Only Bit Default Description 15:1 0x0000 Reserved 0 000 Reset These bits are reserved and should be written as ‘0’. 0: No effect 1: Resets the TX FIFO to empty 29 / 48 maxlinear.com/XR22804 Rev 1D XR22804 TX_FIFO_FILL (0x061) - Read Only Bit Default Description 15:11 0x00 Reserved 10:0 0x000 Fill These bits are reserved and should be written as ‘0’. Number of bytes in the TX FIFO TX_WIDE_MODE (0x062) - Read/Write Bit Default Description 15:1 0x0000 Reserved 0 0 EN These bits are reserved and should be written as ‘0’. In wide mode, 2 bytes of data are used to transfer one character. This requires 2 bytes of FIFO space, therefore the FIFO can hold half as many characters in wide mode. In the TX direction bit 0 of the second byte will be used as bit 9 of the character, if 9-bit mode is enabled. Bits 7:1 of the second byte are not used. 0: Disable TX wide mode 1: Enable TX wide mode RX_FIFO_RESET (0x063) - Write Only Bit Default Description 15:1 0x0000 Reserved 0 000 Reset These bits are reserved and should be written as ‘0’. 0: No effect 1: Resets the RX FIFO to empty RX_FIFO_FILL (0x064) - Read Only Bit Default Description 15:11 0x00 Reserved 10:0 0x000 Fill These bits are reserved and should be written as ‘0’. Number of bytes in the RX FIFO 30 / 48 maxlinear.com/XR22804 Rev 1D XR22804 RX_WIDE_MODE (0x065) - Read/Write Bit Default Description 15:1 0x0000 Reserved 0 0 EN These bits are reserved and should be written as ‘0’. In wide mode, 2 bytes of Bulk data are used to transfer one character. This requires 2 bytes of FIFO space, therefore the FIFO can hold half as many characters in wide mode. In the RX direction, bits 3:0 of the second byte contain the error flags associated with the character. Bits 7:4 of the second byte are not used. 0: Disable RX wide mode 1: Enable RX wide mode RX_CONTROL (0x066) - Read/Write Bit Default Description 15:2 0 Reserved 1 0 Max_Pkt_Size 0 0 Low_Latency These bits are reserved and should be written as ‘0’. 0: Maximum bulk-in packet size is 512 / 64 bytes in hi-speed / full-speed mode respectively (normal operation) 1: Maximum bulk-in packet size is 508 / 60 bytes in hi-speed / full-speed mode respectively (workaround for known Windows OS CDC-ACM driver issue) 0: Disable low latency mode 1: Enable low latency mode FLOW_THRESHOLD (0x067) - Read/Write Bit Default Description 15:11 0x0 Reserved 10:0 0x2E0 Thresh These bits are reserved and should be written as ‘0’. If enabled, flow control (either hardware or software), will be asserted when the RX FIFO fill level exceeds the threshold value. CUSTOM_DRIVER (0x081) - Read/Write Bit Default Description 15:1 0x0000 Reserved 0 0 Active These bits are reserved and should be written as ‘0’. A custom driver should immediately enable this bit prior to using any CDC-ACM commands from the USB host, to ensure that the XR22804 does not enter CDC mode and default to the values listed in Table 3. 31 / 48 maxlinear.com/XR22804 Rev 1D XR22804 HID Reports The I2C and EDGE functions in the XR22804 are HID functions. I2C data may be read or written to / from the slave device using the interrupt in and interrupt out endpoints via HID input and output reports. Additionally, XR22804 device register access using the control endpoint for both I2C and EDGE functions is performed via HID feature reports. Reading uses indirect addressing such that for register reads, the register address must first be written and the register value may then be read. Both types of reports are described below. Input and Output Reports Input and output reports using the interrupt in and interrupt out endpoints follow the following format. I2C_SLAVE_OUT Transfer Type: Interrupt Out Transfer Size: 37 bytes The I2C_SLAVE_OUT report writes and / or reads up to 32 bytes of data on the I2C interface. Note that all interrupt out transfers will be automatically followed by an interrupt in transfer. For write only transfers, the interrupt in packet will contain the status of the interrupt out transfer. For read only or write and read transfers, the interrupt in packet will contain the read data, as well as the status of the interrupt out transfer. The format of the interrupt out packet is given below. Field Offset Size Value Description Report ID 0 1 0x00 Write, read, or write and read I2C data Flags 1 1 Bitmap Transfer options D0: Prefix transfer with a start bit. D1: Append a stop bit to the transfer. D2: ACK last read to extend a read transfer (e.g. if more than 32 bytes need to be read). The default is to NAK the last read in the transfer. This bit has no effect if RdSize is 0. D3: Reserved D7..D4: Sequence number. This can help the host to correlate an IN response with a prior OUT command. This field is optional. WrSize 2 1 Number Number of data bytes to write. Valid values are 0 to 32. The 7-bit slave address should not be included in this total. RdSize 3 1 Number Number of bytes to read. Valid values are 0 to 32. SlaveAddr 4 1 Number The 7-bit slave address* to send. The XR22804 will automatically set the I2 C read/write bit, so bit D0 of this field is ignored. Data 5 32 Data Data to be written to the slave. HID uses a fixed report size for each specific report ID so this field will always be 32 bytes long. However, only the number of bytes specified in WrSize will be written. Other bytes will be ignored. * Note: To support 10-bit addressing the standard 7-bit address must be set to 1111 0xxB where xx are the most significant bits of the 10bit address. All 4 of these 7-bit addresses are reserved and will not be used by any slaves with 7-bit only addresses. The least significant bit of the address byte still specifies the direction. For writes, the first data byte which was previously unformatted is now reserved for the least significant 8 bits of the 10-bit address. Additional data bytes remain unformatted. For reads, the write-then-read combined transfer format is always used. During the write portion of the combined transfer the master must send at least one data byte which contains the least significant 8 bits of the 10-bit address. After all of the write data is sent the master then sends a restart bit. This is followed with an address byte which has the same 7-bit address 1111 0xxB as in the write portion. However, the direction bit is now 1 for reading. The slave then sends the read data as usual. The least significant 8 bits of the 10-bit address are not sent again after the restart bit. 32 / 48 maxlinear.com/XR22804 Rev 1D XR22804 I2C_SLAVE_IN Transfer Type: Interrupt In Transfer Size: 36 bytes Interrupt in packet status only, or status and read data from the I2C interface. Field Offset Size Value Description Flags 0 1 Bitmap Status of the requested transfer. D0: Request Error. If 1, the OUT request had an error (e.g. invalid size) and was not executed. D1: A byte sent to a slave received an I2C NAK response. The transfer was aborted. D2: Arbitration was lost. The transfer was aborted. D3: Timeout. Bus free condition was not observed within 256 ms or an individual byte transfer extended longer than 10ms. D7..D4: Sequence number. This number matches the value provided in the corresponding OUT command packet. WrSize 1 1 Number Number of bytes written, 0 to 32. RdSize 2 1 Number Number of bytes read, 0 to 32. Reserved 3 1 Number This field is reserved. Data 4 32 Data The read data that was received from the slave. HID uses a fixed report size for each specific report ID, so this field will always be 32 bytes long. However, only the number of bytes specified in RdSize are valid. Other bytes should be ignored. Feature Reports Access to XR22804 registers via HID feature reports along with the register descriptions are given in the following sections. WRITE_HID_REGISTER Transfer Type: Control Transfer Size: 5 bytes The WRITE_HID_REGISTER report writes 2 bytes of data to the specified register address. Field Offset Size Report ID 0 1 Write Address LSB 1 1 Write Address MSB 2 1 Write Data LSB 3 1 Write Data MSB 4 1 Value 0x3C Description Write HID register Write address Write data 33 / 48 maxlinear.com/XR22804 Rev 1D XR22804 SET_HID_READ_ADDRESS Transfer Type: Control Transfer Size: 3 bytes The SET_HID_READ_ADDRESS report sets the address for the READ_HID_REGISTER report. Field Offset Size Report ID 0 1 Read Address LSB 1 1 Read Address MSB 2 1 Value 0x4B Description Set address for HID register read Read address READ_HID_REGISTER Transfer Type: Control Transfer Size: 3 bytes The READ_HID_REGISTER report reads register data from the address set by the SET_HID_READ_ADDRESS report. Field Offset Size Report ID 0 1 Read Data LSB 1 1 Read Data MSB 2 1 Value 0x5A Description Read HID register Read data 34 / 48 maxlinear.com/XR22804 Rev 1D XR22804 HID Register Map Table 9: XR22804 HID Register Map Address Register Name Bit 7 (15) Bit 6 (14) Bit 5 (13) Bit 4 (12) Bit 3 (11) Bit 2 (10) Bit 1 (9) Bit 0 (8) I2C Registers 0x341 0x342 I2C_SCL_LOW MSB [15:8] VALUE (MSB) I2C_SCL_LOW LSB [7:0] VALUE (LSB) I2C_SCL_HIGH MSB [15:8] VALUE (MSB) I2C_SCL_HIGH LSB [7:0] VALUE (LSB) EDGE Registers 0x3C0 0x3C1 0x3C2 0x3C3 0x3C4 0x3C5 0x3C6 0x3C7 0x3C8 0x3C9 EDGE_FUNC_SEL_0 [15:8] E15 E14 E13 E12 E11 E10 E9 E8 EDGE_FUNC_SEL_0 [7:0] E7 E6 E5 E4 E3 E2 E1 E0 EDGE_DIR_0 [15:8] E15 E14 E13 E12 E11 E10 E9 E8 EDGE_DIR_0 [7:0] E7 E6 E5 E4 E3 E2 E1 E0 EDGE_SET_0 [15:8] E15 E14 E13 E12 E11 E10 E9 E8 EDGE_SET_0 [7:0] E7 E6 E5 E4 E3 E2 E1 E0 EDGE_CLEAR_0 [15:8] E15 E14 E13 E12 E11 E10 E9 E8 EDGE_CLEAR_0 [7:0] E7 E6 E5 E4 E3 E2 E1 E0 EDGE_STATE_0 [15:8] E15 E14 E13 E12 E11 E10 E9 E8 EDGE_STATE_0 [7:0] E7 E6 E5 E4 E3 E2 E1 E0 EDGE_TRI_STATE_0 [15:8] E15 E14 E13 E12 E11 E10 E9 E8 EDGE_TRI_STATE_0 [7:0] E7 E6 E5 E4 E3 E2 E1 E0 EDGE_OPEN_DRAIN_0 [15:8] E15 E14 E13 E12 E11 E10 E9 E8 EDGE_OPEN_DRAIN_0 [7:0] E7 E6 E5 E4 E3 E2 E1 E0 EDGE_PULL_UP_0 [15:8] E15 E14 E13 E12 E11 E10 E9 E8 EDGE_PULL_UP_0 [7:0] E7 E6 E5 E4 E3 E2 E1 E0 EDGE_PULL_DOWN_0 [15:8] E15 E14 E13 E12 E11 E10 E9 E8 EDGE_PULL_DOWN_0 [7:0] E7 E6 E5 E4 E3 E2 E1 E0 EDGE_INTR_MASK_0 [15:8] E15 E14 E13 E12 E11 E10 E9 E8 EDGE_INTR_MASK_0 [7:0] E7 E6 E5 E4 E3 E2 E1 E0 35 / 48 maxlinear.com/XR22804 Rev 1D XR22804 Table 9: XR22804 HID Register Map Address 0x3CA 0x3CB 0x3CC 0x3CD 0x3CE 0x3CF 0x3D0 0x3D1 0x3D2 0x3D3 0x3D4 0x3D5 Bit 7 (15) Bit 6 (14) Bit 5 (13) Bit 4 (12) Bit 3 (11) Bit 2 (10) Bit 1 (9) Bit 0 (8) EDGE_INTR_POS_ EDGE_0 [15:8] E15 E14 E13 E12 E11 E10 E9 E8 EDGE_INTR_POS_ EDGE_0 [7:0] E7 E6 E5 E4 E3 E2 E1 E0 EDGE_INTR_NEG_ EDGE_0 [15:8] E15 E14 E13 E12 E11 E10 E9 E8 EDGE_INTR_NEG_ EDGE_0 [7:0] E7 E6 E5 E4 E3 E2 E1 E0 EDGE_FUNC_SEL_1 [31:24] E31 E30 E29 E28 E27 E26 E25 E24 EDGE_FUNC_SEL_1 [23:16] E23 E22 E21 E20 E19 E18 E17 E16 EDGE_DIR_1 [31:24] E31 E30 E29 E28 E27 E26 E25 E24 EDGE_DIR_1 [23:16] E23 E22 E21 E20 E19 E18 E17 E16 EDGE_SET_1 [31:24] E31 E30 E29 E28 E27 E26 E25 E24 EDGE_SET_1 [23:16] E23 E22 E21 E20 E19 E18 E17 E16 EDGE_CLEAR_1 [31:24] E31 E30 E29 E28 E27 E26 E25 E24 EDGE_CLEAR_1 [23:16] E23 E22 E21 E20 E19 E18 E17 E16 EDGE_STATE_1 [31:24] E31 E30 E29 E28 E27 E26 E25 E24 EDGE_STATE_1 [23:16] E23 E22 E21 E20 E19 E18 E17 E16 EDGE_TRI_STATE_1 [31:24] E31 E30 E29 E28 E27 E26 E25 E24 EDGE_TRI_STATE_1 [23:16] E23 E22 E21 E20 E19 E18 E17 E16 EDGE_OPEN_DRAIN_1 [31:24] E31 E30 E29 E28 E27 E26 E25 E24 EDGE_OPEN_DRAIN_1 [23:16] E23 E22 E21 E20 E19 E18 E17 E16 EDGE_PULL_UP_1 [31:24] E31 E30 E29 E28 E27 E26 E25 E24 EDGE_PULL_UP_1 [23:16] E23 E22 E21 E20 E19 E18 E17 E16 EDGE_PULL_DOWN_1 [31:24] E31 E30 E29 E28 E27 E26 E25 E24 EDGE_PULL_DOWN_1 [23:16] E23 E22 E21 E20 E19 E18 E17 E16 EDGE_INTR_MASK_1 [31:24] E31 E30 E29 E28 E27 E26 E25 E24 EDGE_INTR_MASK_1 [23:16] E23 E22 E21 E20 E19 E18 E17 E16 Register Name 36 / 48 maxlinear.com/XR22804 Rev 1D XR22804 Table 9: XR22804 HID Register Map Address 0x3D6 0x3D7 0x3D8 0x3D9 0x3DA 0x3DB 0x3DC 0x3DD Bit 7 (15) Bit 6 (14) Bit 5 (13) Bit 4 (12) Bit 3 (11) Bit 2 (10) Bit 1 (9) Bit 0 (8) EDGE_INTR_POS_ EDGE_1 [31:24] E31 E30 E29 E28 E27 E26 E25 E24 EDGE_INTR_POS_ EDGE_1 [23:16] E23 E22 E21 E20 E19 E18 E17 E16 EDGE_INTR_NEG_ EDGE_1 [31:24] E31 E30 E29 E28 E27 E26 E25 E24 EDGE_INTR_NEG_ EDGE_1 [23:16] E23 E22 E21 E20 E19 E18 E17 E16 0 0 0 0 0 0 0 CMD[2] Register Name EDGE_PWM0_CTRL MSB [15:8] EDGE_PWM0_CTRL LSB [7:0] EDGE_PWM0_HIGH MSB [15:8] CMD[1:0] 0 EN 0 0 EDGE_PWM0_HIGH LSB [7:0] EDGE_PWM0_LOW MSB [15:8] 0 0 0 0 0 0 CMD[1:0] 0 VALUE[11:8] 0 0 0 EN 0 0 EDGE_PWM1_HIGH LSB [7:0] EDGE_PWM1_LOW MSB [15:8] VALUE[11:8] VALUE [7:0] EDGE_PWM1_CTRL LSB [7:0] EDGE_PWM1_HIGH MSB [15:8] 0 VALUE [7:0] EDGE_PWM0_LOW LSB [7:0] EDGE_PWM1_CTRL MSB [15:8] PIN[4:0] 0 0 CMD[2] PIN[4:0] 0 VALUE[11:8] VALUE [7:0] 0 0 0 EDGE_PWM1_LOW LSB [7:0] 0 VALUE[11:8] VALUE [7:0] 37 / 48 maxlinear.com/XR22804 Rev 1D XR22804 HID Register Descriptions Note that all register reset default values are ’0’ unless otherwise specified. All registers are 16 bits. I2C_SCL_LOW (0x341) - Read/Write Bit 15:0 Default 0x0144 Description Value Specifies the number of periods that SCL will be asserted low by the XR22804 I2C master. Note that in clock stretching, the I2C slave may extend the SCL low period to delay the next transaction. For 100 kbps transfer rate this value must be at least 252 (0x00FC) and the sum of high and low periods must be at least 600 (0x0258). For 400kbps transfer rate this value must be at least 78 (0x004E) and the sum of the high and low periods must be at least 150 (0x0096). Measured in 60 MHz core clock periods, i.e. approximately 16.7 ns. I2C_SCL_HIGH (0x342) - Read/Write Bit 15:0 Default 0x0114 Description Value Specifies the number of periods that SCL will be asserted high by the XR22804 I2C master. Note that another multi-master may assert SCL low before the XR22804 high period is completed. For 100 kbps transfer rate this value must be at least 240 (0x00F0) and the sum of the high and low periods must be at least 600 (0x0258). For 400 kbps transfer rate this value must be at least 36 (0x0024) and the sum of the high and low periods must be at least 150 (0x0096). Measured in 60 MHz core clock periods, i.e. approximately 16.7 ns EDGE_FUNC_SEL_0 (0x3C0) - Read/Write Bit 15:0 Default 0x0000 Description E[15:0] 0: IO is assigned to the UART / GPIO function. IO pin controlled using UART registers. 1: IO is assigned to the EDGE function. IO pin controlled using EDGE registers. EDGE_DIR_0 (0x3C1) - Read/Write Note that when setting direction of an EDGE IO to output, the EDGE_PULL_UP for that IO pin should also be disabled and when setting an EDGE IO pin to input, the EDGE_PULL_UP for that IO pin should also be enabled. Bit 15:0 Default 0x0000 Description E[15:0] 0: IO pin assigned to EDGE function is configured as an input 1: IO pin assigned to EDGE function is configured as an output. 38 / 48 maxlinear.com/XR22804 Rev 1D XR22804 EDGE_SET_0 (0x3C2) - Write Only Bit 15:0 Default 0x0000 Description E[15:0] 0: No effect 1: Set IO pin assigned to EDGE function and configured as an output to a logic ‘1’ EDGE_CLEAR_0 (0x3C3) - Write Only Bit 15:0 Default 0x0000 Description E[15:0] 0: No effect 1: Clear IO pin assigned to EDGE function and configured as an output to a logic ‘0’ EDGE_STATE_0 (0x3C4) - Read/Write Bit 15:0 Default 0x0000 Description E[15:0] Writing in this register sets or clears the EDGE IO pin(s) configured as an output. Writing to an EDGE pin configured as an input has no effect. Reading this register returns the state of each IO pin configured as an EDGE pin irrespective of whether it is configured as an input or output. Note that output transitions across multiple IO pins may be slightly staggered. Refer to EDGE section on page 17. 0: Write clears the corresponding bit to a ‘0’. Read returns the current state. 1: Write sets the corresponding bit to a ‘1’. Read returns the current state. EDGE_TRI_STATE_0 (0x3C5) - Read/Write Bit 15:0 Default 0x0000 Description E[15:0] 0: IO pin assigned to EDGE function and configured as an output is actively driven 1: IO pin assigned to EDGE function and configured as an output is tri-stated EDGE_OPEN_DRAIN_0 (0x3C6) - Read/Write Bit 15:0 Default 0x0000 Description E[15:0] Note that XR22804 open drain outputs have a weak internal pull-up. 0: IO pin assigned to EDGE function and configured as an output is a push-pull output 1: IO pin assigned to EDGE function and configured as an output is an open drain output 39 / 48 maxlinear.com/XR22804 Rev 1D XR22804 EDGE_PULL_UP_0 (0x3C7) - Read/Write Bit 15:0 Default 0xFFFF Description E[15:0] 0: Disable internal pull-up resistor on IO pin assigned to EDGE function and configured as an input 1: Enable internal pull-up resistor on IO pin assigned to EDGE function and configured as an input EDGE_PULL_DOWN_0 (0x3C8) - Read/Write Bit 15:0 Default 0x0000 Description E[15:0] 0: Disable internal pull-down resistor on IO pin assigned to EDGE function and configured as an input 1: Enable internal pull-down resistor on IO pin assigned to EDGE function and configured as an input EDGE_INTR_MASK_0 (0x3C9) - Read/Write Bit 15:0 Default 0x0000 Description E[15:0] Writing a ’1’ in this register enables an input pin for the corresponding bit position EDGE IO pin(s) configured as an input to generate an interrupt if either EDGE_INTR_POS_EDGE and / or EDGE _INTR_NEG_EDGE registers has also been enabled. An EDGE pin configured as an output has no effect. 0: IO pin will not generate an interrupt 1: IO pin assigned to EDGE function and configured as an input will generate an interrupt EDGE_INTR_POS_EDGE_0 (0x3CA) - Read/Write Bit 15:0 Default 0xFFFF Description E[15:0] Writing a ’1’ in this register enables an interrupt to be generated on the rising edge of the corresponding bit position EDGE IO pin(s) configured as an input if the EDGE_INTR_MASK register is enabled for that pin. If the EDGE_INTR_NEG_EDGE register is also enabled, interrupts will be generated on both edges. Writing to an EDGE pin configured as an output has no effect. 0: IO pin will not generate an interrupt on rising edge 1: IO pin assigned to EDGE function and configured as an input will generate an interrupt on rising edge if corresponding EDGE_INTR_MASK bit is set 40 / 48 maxlinear.com/XR22804 Rev 1D XR22804 EDGE_INTR_NEG_EDGE_0 (0x3CB) - Read/Write Bit 15:0 Default 0xFFFF Description E[15:0] Writing a ’1’ in this register enables an interrupt to be generated on the falling edge of the corresponding bit position EDGE IO pin(s) configured as an input if the EDGE_INTR_MASK register is enabled for that pin. If the EDGE_INTR_POS_EDGE register is also enabled, interrupts will be generated on both edges. Writing to an EDGE pin configured as an output has no effect. 0: IO pin will not generate an interrupt on falling edge 1: IO pin assigned to EDGE function and configured as an input will generate an interrupt on falling edge if corresponding EDGE_INTR_MASK bit is set EDGE_FUNC_SEL_1 (0x3CC) - Read/Write Bit Default 31:16 0x0000 Description E[31:16] 0: IO is assigned to the UART / GPIO function. IO pin controlled using UART registers. 1: IO is assigned to the EDGE function. IO pin controlled using EDGE registers. EDGE_DIR_1 (0x3CD) - Read/Write Note that when setting direction of an EDGE IO to output, the EDGE_PULL_UP for that IO pin should also be disabled and when setting an EDGE IO pin to input, the EDGE_PULL_UP for that IO pin should also be enabled. Bit Default 31:16 0x0000 Description E[31:16] 0: IO pin assigned to EDGE function is configured as an input 1: IO pin assigned to EDGE function is configured as an output. EDGE_SET_1 (0x3CE) - Write Only Bit Default 31:16 0x0000 Description E[31:16] 0: No effect 1: Set IO pin assigned to EDGE function and configured as an output to a logic ‘1’ 41 / 48 maxlinear.com/XR22804 Rev 1D XR22804 EDGE_CLEAR_1 (0x3CF) - Write Only Bit Default 31:16 0x0000 Description E[31:16] 0: No effect 1: Clear IO pin assigned to EDGE function and configured as an output to a logic ‘0’ EDGE_STATE_1 (0x3D0) - Read/Write Bit Default 31:16 0x0000 Description E[31:16] Writing in this register sets or clears the EDGE IO pin(s) configured as an output. Writing to an EDGE pin configured as an input has no effect. Reading this register returns the state of each IO pin configured as an EDGE pin irrespective of whether it is configured as an input or output. Note that output transitions across multiple IO pins may be slightly staggered. Refer to EDGE section on page 17. 0: Write clears the corresponding bit to a ‘0’. Read returns the current state. 1: Write sets the corresponding bit to a ‘1’. Read returns the current state. EDGE_TRI_STATE_1 (0x3D1) - Read/Write Bit Default 31:16 0x0000 Description E[31:16] 0: IO pin assigned to EDGE function and configured as an output is actively driven 1: IO pin assigned to EDGE function and configured as an output is tri-stated EDGE_OPEN_DRAIN_1 (0x3D2) - Read/Write Bit Default 31:16 0x0000 Description E[31:16] Note that XR22804 open drain outputs have a weak internal pull-up. 0: IO pin assigned to EDGE function and configured as an output is a push-pull output 1: IO pin assigned to EDGE function and configured as an output is an open drain output EDGE_PULL_UP_1 (0x3D3) - Read/Write Bit Default 31:16 0xFFFF Description E[31:16] 0: Disable internal pull-up resistor on IO pin assigned to EDGE function and configured as an input 1: Enable internal pull-up resistor on IO pin assigned to EDGE function and configured as an input 42 / 48 maxlinear.com/XR22804 Rev 1D XR22804 EDGE_PULL_DOWN_1 (0x3D4) - Read/Write Bit Default 31:16 0x0000 Description E[31:16] 0: Disable internal pull-down resistor on IO pin assigned to EDGE function and configured as an input 1: Enable internal pull-down resistor on IO pin assigned to EDGE function and configured as an input EDGE_INTR_MASK_1 (0x3D5) - Read/Write Bit Default 31:16 0x0000 Description E[31:16] Writing a ’1’ in this register enables an input pin for the corresponding bit position EDGE IO pin(s) configured as an input to generate an interrupt if either EDGE_INTR_POS_EDGE and / or EDGE _INTR_NEG_EDGE registers has also been enabled. An EDGE pin configured as an output has no effect. 0: IO pin will not generate an interrupt 1: IO pin assigned to EDGE function and configured as an input will generate an interrupt EDGE_INTR_POS_EDGE_1 (0x3D6) - Read/Write Bit Default 31:16 0xFFFF Description E[31:16] Writing a ’1’ in this register enables an interrupt to be generated on the rising edge of the corresponding bit position EDGE IO pin(s) configured as an input if the EDGE_INTR_MASK register is enabled for that pin. If the EDGE_INTR_NEG_EDGE register is also enabled, interrupts will be generated on both edges. Writing to an EDGE pin configured as an output has no effect. 0: IO pin will not generate an interrupt on rising edge 1: IO pin assigned to EDGE function and configured as an input will generate an interrupt on rising edge if corresponding EDGE_INTR_MASK bit is set EDGE_INTR_NEG_EDGE_1 (0x3D7) - Read/Write Bit Default 31:16 0xFFFF Description E[31:16] Writing a ’1’ in this register enables an interrupt to be generated on the falling edge of the corresponding bit position EDGE IO pin(s) configured as an input if the EDGE_INTR_MASK register is enabled for that pin. If the EDGE_INTR_POS_EDGE register is also enabled, interrupts will be generated on both edges. Writing to an EDGE pin configured as an output has no effect. 0: IO pin will not generate an interrupt on falling edge 1: IO pin assigned to EDGE function and configured as an input will generate an interrupt on falling edge if corresponding EDGE_INTR_MASK bit is set 43 / 48 maxlinear.com/XR22804 Rev 1D XR22804 EDGE_PWM0_CTRL (0x3D8) - Read/Write Bit Default Description 15:9 0x00 Reserved 8:6 0x0 Cmd 5 0 Enable 4:0 0x00 Pin These bits are reserved and should be written as ‘0’. 000: Idle. output pin remains at same state 001: Undefined, do not use 010: Undefined, do not use 011: Undefined, do not use 100: Assert logic ‘0’ 101: One-shot -If previous state was assert ’0’, one-shot pulse will be high, If previous state was assert ’1’, oneshot pulse will be low 110: Free run output 111: Assert logic ‘0’ 0: PWM0 output is not enabled 1: PWM0 output is enabled on pin specified in Pin field using mode specified in Cmd field Specifies which pin (E31 - E0) will be assigned to PWM0 output. EDGE_PWM0_HIGH (0x3D9) - Read/Write Bit Default Description 15:12 0x0 Reserved 11:0 0x001 Value These bits are reserved and should be written as ‘0’. This register specifies the high period for PWM0 in increments of 266.667ns. High period must be in the range of 1 to 4095 (266.667 ns to 1.092 ms) EDGE_PWM0_LOW (0x3DA) - Read/Write Bit Default Description 15:12 0x0 Reserved 11:0 0x001 Value These bits are reserved and should be written as ‘0’. This register specifies the low period for PWM0 in increments of 266.667ns. Low period must be in the range of 1 to 4095 (266.667 ns to 1.092 ms) 44 / 48 maxlinear.com/XR22804 Rev 1D XR22804 EDGE_PWM1_CTRL (0x3DB) - Read/Write Bit Default Description 15:9 0x00 Reserved 8:6 0x0 Cmd 4:0 0x00 Pin These bits are reserved and should be written as ‘0’. 000: Idle. output pin remains at same state 001: Undefined, do not use 010: Undefined, do not use 011: Undefined, do not use 100: Assert logic ‘0’ 101: One-shot -If previous state was assert ’0’, one-shot pulse will be high, If previous state was assert ’1’, oneshot pulse will be low 110: Free run output 111: Assert logic ‘0’ Specifies which pin (E31 - E0) will be assigned to PWM1 output. EDGE_PWM1_HIGH (0x3DC) - Read/Write Bit Default Description 15:12 0x0 Reserved 11:0 0x001 Value These bits are reserved and should be written as ‘0’. This register specifies the high period for PWM1 in increments of 266.667ns. High period must be in the range of 1 to 4095 (266.667 ns to 1.092 ms) EDGE_PWM1_LOW (0x3DD) - Read/Write Bit Default Description 15:12 0x0 Reserved 11:0 0x001 Value These bits are reserved and should be written as ‘0’. This register specifies the low period for PWM1 in increments of 266.667ns. Low period must be in the range of 1 to 4095 (266.667 ns to 1.092 ms) 45 / 48 maxlinear.com/XR22804 Rev 1D XR22804 Mechanical Dimensions 56-Pin QFN TOP VIEW BOTTOM VIEW SIDE VIEW TERMINAL DETAILS Drawing No.: POD-00000129 Revision: B 46 / 48 maxlinear.com/XR22804 Rev 1D XR22804 Recommended Land Pattern and Stencil TYPICAL RECOMMENDED LAND PATTERN TYPICAL RECOMMENDED STENCIL Drawing No.: POD-00000129 Revision: B 47 / 48 maxlinear.com/XR22804 Rev 1D XR22804 Ordering Information(1) Part Number XR22804IL56-F Operating Temperature Range Lead-Free Package Packaging Method -40°C to +85°C Yes(2) 56-pin QFN Tray XR22804IL56-0A-EB XR22804 Evaluation Board NOTES: 1. Refer to www.maxlinear.com/XR22804 for most up-to-date Ordering Information. 2. Visit www.maxlinear.com for additional information on Environmental Rating. Revision History Revision Date Description 1A July 2014 Initial Release 1B April 2015 Corrected VBUS_SENSE pin definition and Table 1 hub PID. Corrected Request Values for CDC_ACM_IF and added 3 CDC_ECM_IF commands to Table 4 USB Commands. Added descriptions of feature and input and output reports for HID functions. Added HID register access feature reports. [ECN 1518‐04 Apr 28 2015] 1C February 2018 Update to MaxLinear logo. Update format and ordering information table. Renamed center pad and added to Pin Assignments. Updated custom software drivers on page 2. Changed standard driver to class specific driver in USB Device Drivers section and to native in UART section. 1D March 2019 Update I2C_SLAVE_IN register table. Update Ordering Information. Corporate Headquarters: 5966 La Place Court Suite 100 Carlsbad, CA 92008 Tel.:+1 (760) 692-0711 Fax: +1 (760) 444-8598 www.maxlinear.com The content of this document is furnished for informational use only, is subject to change without notice, and should not be construed as a commitment by MaxLinear, Inc.. MaxLinear, Inc. assumes no responsibility or liability for any errors or inaccuracies that may appear in the informational content contained in this guide. Complying with all applicable copyright laws is the responsibility of the user. Without limiting the rights under copyright, no part of this document may be reproduced into, stored in, or introduced into a retrieval system, or transmitted in any form or by any means (electronic, mechanical, photocopying, recording, or otherwise), or for any purpose, without the express written permission of MaxLinear, Inc. Maxlinear, Inc. does not recommend the use of any of its products in life support applications where the failure or malfunction of the product can reasonably be expected to cause failure of the life support system or to significantly affect its safety or effectiveness. Products are not authorized for use in such applications unless MaxLinear, Inc. receives, in writing, assurances to its satisfaction that: (a) the risk of injury or damage has been minimized; (b) the user assumes all such risks; (c) potential liability of MaxLinear, Inc. is adequately protected under the circumstances. MaxLinear, Inc. may have patents, patent applications, trademarks, copyrights, or other intellectual property rights covering subject matter in this document. Except as expressly provided in any written license agreement from MaxLinear, Inc., the furnishing of this document does not give you any license to these patents, trademarks, copyrights, or other intellectual property. Company and product names may be registered trademarks or trademarks of the respective owners with which they are associated. © 2015 - 2019 MaxLinear, Inc. All rights reserved 48 / 48 maxlinear.com/XR22804 Rev 1D
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