XR21V1412IL32 [EXAR]
2-CH FULL-SPEED USB UART; 2 - CH全速USB UART型号: | XR21V1412IL32 |
厂家: | EXAR CORPORATION |
描述: | 2-CH FULL-SPEED USB UART |
文件: | 总24页 (文件大小:698K) |
中文: | 中文翻译 | 下载: | 下载PDF数据表文档文件 |
XR21V1412
2-CH FULL-SPEED USB UART
REV. 1.0.0
JUNE 2009
FEATURES
GENERAL DESCRIPTION
• USB 2.0 Compliant Interface
The XR21V1412 (V1412) is an enhanced 2-channel
Universal Asynchronous Receiver and Transmitter
(UART) with a USB interface. The USB interface is
fully compliant to Full Speed USB 2.0 specification
that supports 12 Mbps USB data transfer rate. The
USB interface also supports USB suspend, resume
and remote wakeup operations.
■ Supports 12 Mbps USB full-speed data rate
■ Supports USB suspend, resume and remote
wakeup operations
• Enhanced Features of each UART
■ Data rates up to 12 Mbps
■ Fractional Baud Rate Generator
■ 128 byte TX FIFO
The V1412 operates from an internal 48MHz clock
therefore no external crystal/oscillator is required like
previous generation UARTs. With the fractional baud
rate generator, any baud rate can accurately be
generated using the internal 48MHz clock.
■ 384 byte RX FIFO
■ 7, 8 or 9 data bits, 1 or 2 stop bits
■ Automatic Hardware (RTS/CTS or DTR/DSR)
The large 128-byte FIFO and 384-byte RX FIFO of
the V1412 helps to optimize the overall data
throughput for various applications. The Automatic
Transceiver Direction control feature simplifies both
the hardware and software for half-duplex RS-485
applications. If required, the multidrop (9-bit) mode
with automatic half-duplex transceiver control feature
Flow Control
■ Automatic Software (Xon/Xoff) Flow Control
■ Multidrop mode w/ Auto Half-Duplex
Transceiver Control
■ Multidrop mode w/ Auto TX Enable
■ Half-Duplex mode
further
simplifies
typical
multidrop
RS-485
■ Sleep Mode with Remote Wake-up
■ Selectable GPIO or Modem I/O
applications.
The V1412 operates from a single 2.97 to 3.63 volt
power supply and has 5V tolerant inputs. The V1412
is available in a 32-pin QFN package.
• Internal 48 MHz clock
• Single 2.97-3.63V power supply
• 5V tolerant inputs
Software drivers for Windows 2000, XP, Vista, and
CE, as well as Linux and Mac are supported for the
XR21V1412.
• 32-pin QFN package
• Virtual COM Port drivers
APPLICATIONS
■ Windows 2000, XP and Vista
■ Windows CE 4.2, 5.0, 6.0
■ Linux
• Portable Appliances
• External Converters (dongles)
• Battery-Operated Devices
• Cellular Data Devices
■ Mac
• Factory Automation and Process Controls
• Industrial applications
Exar Corporation 48720 Kato Road, Fremont CA, 94538 • (510) 668-7000 • FAX (510) 668-7017 • www.exar.com
XR21V1412
2-CH FULL-SPEED USB UART
REV. 1.0.0
FIGURE 1. XR21V1412 BLOCK DIAGRAM
128-byte
TX FIFO
TXA
RXA
Fractional
BRG
3.3V VCC
GND
384-byte
RX FIFO
GPIOA5/RTSA#
GPIOA4/CTSA#
GPIOA3/DTRA#
GPIOA2/DSRA#
GPIOA1/CDA#
GPIOA0/RIA#
Internal
Status and
Control
GPIOs/
Modem IO
USB Slave
Interface
USBD+
USBD-
Registers
UART Channel A
128-byte
TX FIFO
I2C
Interface
SDA
SCL
TXB
RXB
Fractional
BRG
384-byte
RX FIFO
GPIOB5/RTSB#
GPIOB4/CTSB#
GPIOB3/DTRB#
GPIOB2/DSRB#
GPIOB1/CDB#
GPIOB0/RIB#
Internal
Status and
Control
GPIOs/
Modem IO
Internal
48MHz
Oscillator
Registers
UART Channel B
2
XR21V1412
REV. 1.0.0
2-CH FULL-SPEED USB UART
FIGURE 2. PIN OUT ASSIGNMENT
24
23
22 21 20 19 18
17
RXB
TXB
GND
VCC
GPIOA0/RIA#
GPIOA1/CDA#
GPIOA2/DSRA#
GPIOA3/DTRA#
SDA 25
16
15
14
13
12
11
10
9
SCL
GND
GND
26
27
28
29
30
31
32-pin QFN
USBD-
USBD+
VCC
VCC
32
7 8
2 3 4 5 6
1
ORDERING INFORMATION
PART NUMBER
PACKAGE
OPERATING TEMPERATURE RANGE
DEVICE STATUS
XR21V1412IL32
32-pin QFN
-40°C to +85°C
Active
3
XR21V1412
2-CH FULL-SPEED USB UART
REV. 1.0.0
PIN DESCRIPTIONS
Pin Description
32-QFN
NAME
TYPE
DESCRIPTION
PIN #
UART Channel A Signals
RXA
6
I
UART Channel A Receive Data or IR Receive Data. This pin has an internal pull-up
resistor. Internal pull-up resistor is not disabled during suspend mode.
TXA
5
O
UART Channel A Transmit Data or IR Transmit Data.
12
I/O
GPIOA0/RIA#
General purpose I/O or UART Ring-Indicator input (active low). This pin has an inter-
nal pull-up resistor. Internal pull-up resistor is disabled during suspend mode. If
using this GPIO as an input, a pull-up resistor is required to minimize the power con-
sumption in the suspend mode.
11
10
9
I/O
I/O
I/O
I/O
I/O
GPIOA1/CDA#
GPIOA2/DSRA#
GPIOA3/DTRA#
GPIOA4/CTSA#
GPIOA5/RTSA#
General purpose I/O or UART Carrier-Detect input (active low). This pin has an inter-
nal pull-up resistor. Internal pull-up resistor is disabled during suspend mode. If
using this GPIO as an input, a pull-up resistor is required to minimize the power con-
sumption in the suspend mode.
General purpose I/O or UART Data-Set-Ready input (active low). This pin has an
internal pull-up resistor. Internal pull-up resistor is disabled during suspend mode. If
using this GPIO as an input, a pull-up resistor is required to minimize the power con-
sumption in the suspend mode.
General purpose I/O or UART Data-Terminal-Ready output (active low). This pin has
an internal pull-up resistor. Internal pull-up resistor is disabled during suspend mode.
If using this GPIO as an input, a pull-up resistor is required to minimize the power
consumption in the suspend mode.
8
General purpose I/O or UART Clear-to-Send input (active low). This pin has an inter-
nal pull-up resistor. Internal pull-up resistor is disabled during suspend mode. If
using this GPIO as an input, a pull-up resistor is required to minimize the power con-
sumption in the suspend mode.
7
General purpose I/O or UART Request-to-Send output (active low). This pin has an
internal pull-up resistor. Internal pull-up resistor is disabled during suspend mode. If
using this GPIO as an input, a pull-up resistor is required to minimize the power con-
sumption in the suspend mode.
UART Channel B Signals
RXB
16
I
UART Channel B Receive Data or IR Receive Data. This pin has an internal pull-up
resistor. Internal pull-up resistor is not disabled during suspend mode.
TXB
15
22
O
UART Channel B Transmit Data or IR Transmit Data.
I/O
GPIOB0/RIB#
General purpose I/O or UART Ring-Indicator input (active low). This pin has an inter-
nal pull-up resistor. Internal pull-up resistor is disabled during suspend mode. If
using this GPIO as an input, a pull-up resistor is required to minimize the power con-
sumption in the suspend mode.
21
20
I/O
I/O
GPIOB1/CDB#
General purpose I/O or UART Carrier-Detect input (active low). This pin has an inter-
nal pull-up resistor. Internal pull-up resistor is disabled during suspend mode. If
using this GPIO as an input, a pull-up resistor is required to minimize the power con-
sumption in the suspend mode.
GPIOB2/DSRB#
General purpose I/O or UART Data-Set-Ready input (active low). This pin has an
internal pull-up resistor. Internal pull-up resistor is disabled during suspend mode. If
using this GPIO as an input, a pull-up resistor is required to minimize the power con-
sumption in the suspend mode.
4
XR21V1412
REV. 1.0.0
2-CH FULL-SPEED USB UART
Pin Description
32-QFN
PIN #
NAME
TYPE
DESCRIPTION
19
18
17
I/O
GPIOB3/DTRB#
General purpose I/O or UART Data-Terminal-Ready output (active low). This pin has
an internal pull-up resistor. Internal pull-up resistor is disabled during suspend mode.
If using this GPIO as an input, a pull-up resistor is required to minimize the power
consumption in the suspend mode.
I/O
I/O
GPIOB4/CTSB#
GPIOB5/RTSB#
General purpose I/O or UART Clear-to-Send input (active low). This pin has an inter-
nal pull-up resistor. Internal pull-up resistor is disabled during suspend mode. If
using this GPIO as an input, a pull-up resistor is required to minimize the power con-
sumption in the suspend mode.
General purpose I/O or UART Request-to-Send output (active low). This pin has an
internal pull-up resistor. Internal pull-up resistor is disabled during suspend mode. If
using this GPIO as an input, a pull-up resistor is required to minimize the power con-
sumption in the suspend mode.
USB Interface Signals
USBD+
USBD-
30
29
I/O
I/O
USB port differential data plus. This pin has a 1.5 K Ohm internal pull-up resistor.
USB port differential data minus.
I2C Interface Signals
SDA
25
OD
I2C-controller data input/output (open-drain). 1K pull-up resistor is required. An
optional external I2C EEPROM can be used to store default configurations upon
power-up including the USB Vendor ID and Device ID.
If an EEPROM is not used, this pin can be used with the SCL pin to select the
Remote Wake-up and Power modes. An external pull-up or pull-down resistor is
required. See Table 1.
SCL
26
I
I2C-controller serial input clock. 1K pull-up resistor is required. An optional external
I2C EEPROM can be used to store default configurations upon power-up including
the USB Vendor ID and Device ID.
If an EEPROM is not used, this pin can be used with the SDA pin to select the
Remote Wake-up and Power modes. An external pull-up or pull-down resistor is
required. See Table 1.
Ancillary Signals
2
O
LOWPOWER
Low power status output. This pin is HIGH when the XR21V1412 is in the suspend
mode. This pin is LOW when the XR21V1412 is not in the suspend mode. An exter-
nal pull-up or pull-down resistor is required on this pin. This pin is sampled upon
power-on to configure the polarity of the LOWPOWER output during suspend mode.
An external pull-up resistor will cause the LOWPOWER pin to be HIGH during sus-
pend mode. An external pull-down resistor will cause the LOWPOWER pin to be
LOW during suspend mode
4, 13, 24, Pwr
31, 32
VCC
GND
+3.3V power supply. All inputs are 5V tolerant.
Power supply common, ground.
1, 3, 14, Pwr
23, 27,
28
NOTE: Pin type: I=Input, O=Output, I/O= Input/output, OD=Output Open Drain.
5
XR21V1412
2-CH FULL-SPEED USB UART
1.0 FUNCTIONAL DESCRIPTIONS
REV. 1.0.0
1.1
USB interface
The USB interface of the V1412 is compliant with the USB 2.0 Full-Speed Specifications. The USB
configuration model presented by the V1412 to the device driver is compatible to the Abstract Control Model of
the USB Communication Device Class (CDC-ACM). The V1412 uses the following set of parameters:
• 1 Control Endpoint
■ Endpoint 0 as outlined in the USB specifications
• 1 Configuration is supported
• 2 interfaces per UART channel
■ Each UART channel has a single interrupt endpoint
■ Each UART channel have bulk-in and bulk-out endpoints
1.1.1
USB Vendor ID
Exar’s USB Vendor ID is 0x04E2. This is the default Vendor ID that is used for the V1412 unless a valid
EEPROM is present on the I2C interface signals. If a valid EEPROM is present, the Vendor ID from the
EEPROM will be used.
1.1.2
USB Product ID
The default USB Product ID for the V1412 is 0x1412. If a valid EEPROM is present, the Product ID from the
EEPROM will be used.
1.2
I2C Interface
The I2C interface provides connectivity to an external I2C memory device (i.e. EEPROM) that can be read by
the V1412 for configuration.
The SDA and SCL are used to specify whether Remote Wakeup and/or Bus Powered configurations are to be
supported. These pins are sampled at power-up. The following table describes how Remote Wakeup and Bus
Powered support.
TABLE 1: REMOTE WAKEUP AND POWER MODES
REMOTE WAKE-UP
SDA
SCL
POWER MODE
COMMENTS
SUPPORT
No
1
1
0
0
1
0
1
0
Self-Powered
Bus-Powered
Self-Powered
Bus-Powered
Default, if no EEPROM is present
No
Yes
Yes
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XR21V1412
REV. 1.0.0
2-CH FULL-SPEED USB UART
1.2.1
EEPROM Contents
The I2C address should be 0xA0. An EEPROM can be used to override default Vendor IDs and Device IDs, as
well as other attributes and maximum power consumption. The EEPROM must contain 8 bytes of data as
specified in Table 2
TABLE 2: EEPROM CONTENTS
EEPROM
CONTENTS
ADDRESS
0
1
2
3
4
5
6
7
Vendor ID (LSB)
Vendor ID (MSB)
Product ID (LSB)
Product ID (MSB)
Device Attributes
Device Maximum Power
Reserved
Signature of 0x58 (’X’). If the signature is not correct, the contents of the EEPROM are ignored.
These values are uploaded from the EEPROM to the corresponding USB Standard Device Descriptor or
Standard Configuration Descriptor. For details of the USB Descriptors, refer to the USB 2.0 specifications.
1.2.1.1
The Vendor ID value replaces the idVendor field in the USB Standard Device Descriptor.
1.2.1.2 Product ID
The Product ID value replaces the idProduct field in the USB Standard Device Descriptor.
1.2.1.3 Device Attributes
The Device Attributes value replaces the bmAttributes field in the USB Standard Configuration Descriptor.
1.2.1.4 Device Maximum Power
Vendor ID
The Device Maximum Power value replaces the bMaxPower field in the USB Standard Configuration
Descriptor.
1.3
UART Manager
The UART Manager enables/disables each UART including the TX and RX FIFOs for each UART. The UART
Manager is located in a separate register block from the 2 UART channels.
1.4
UART
There are 2 enhanced UART channels in the V1412. Each UART channel is independent, therefore, they will
need to be initialized and configured independently. Each UART can be configured via USB control transfers
from the USB host.
1.4.1
Transmitter
The transmitter consists of a 128-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 TSR shifts the data out onto the TX output pin at the data rate
defined by the CLOCK_DIVISOR and TX_CLOCK_MASK registers. 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 parity or 9 data bits with no parity.
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XR21V1412
2-CH FULL-SPEED USB UART
REV. 1.0.0
1.4.1.1
9-Bit Data Mode
In 9-bit data mode, 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.
1.4.2
Receiver
The receiver consists of a 384-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 along with any error tags such as Framing, Parity, Break
and Overrun errors. Data from the RX FIFO can be sent to the USB host by sending a bulk-in packet.
1.4.2.1
In character mode, up to 64 bytes of data can be sent at a time to the USB host.
1.4.2.2 Character + Status Mode
Character Mode
In this mode, each 8-bit character and the 4 error bits associated with it can be transmitted to the USB host.
The 4 error bits will be in the second byte following the 8-bit character. In this mode, up to 32 character bytes
are sent per bulk-in packet.
1.4.2.3
9-Bit Data Mode
In 9-bit data mode, two bytes of data are sent to the USB host for each byte 9-bit data that is received. The first
byte sent to the USB host is the first 8-bits of data. Bit-0 of the second byte is the bit-9 of the data.
1.4.3
GPIO
Each UART has 6 GPIOs. By default, the GPIOs are general purpose I/Os. However, there are few modes
that can be enabled to add additional feature such as Auto RTS/CTS Flow control, Auto DTR/DSR Flow
Control or Transceiver Enable Control. See Table 13.
1.4.4
Automatic RTS/CTS Hardware Flow Control
GPIO5 and GPIO4 of the UART channel can 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
8
XR21V1412
REV. 1.0.0
2-CH FULL-SPEED USB UART
prevent data overrun to the remote RX FIFO. The CTS# input is monitored to suspend/restart the local
transmitter (see Figure 3):
FIGURE 3. AUTO RTS AND CTS FLOW CONTROL OPERATION
Local UART
UARTA
Remote UART
UARTB
RXA
TXB
Receiver FIFO
Trigger Reached
Transmitter
RTSA#
TXA
CTSB#
RXB
Auto RTS
Auto CTS
Monitor
Trigger Level
Receiver FIFO
Trigger Reached
Transmitter
CTSA#
RTSB#
Auto CTS
Monitor
Auto RTS
Trigger Level
Assert RTS# to Begin
Transmission
1
10
ON
ON
ON
RTSA#
OFF
7
2
ON
11
OFF
CTSB#
TXB
8
3
Restart
Data Starts
6
Suspend
9
4
RXA FIFO
Receive
Data
RX FIFO
Trigger Level
RTS High
Threshold
RTS Low
Threshold
5
RX FIFO
Trigger Level
12
INTA
(RXA FIFO
Interrupt)
RTSCTS1
9
XR21V1412
2-CH FULL-SPEED USB UART
REV. 1.0.0
1.4.5
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’. GPIO3 and GPIO2 become DTR# and DSR#, respectively, when
GPIO_MODE[2:0] = ’010’.
1.4.6
Automatic XON/XOFF Software Flow Control
When software flow control is enabled, the V1412 compares the receive data characters with the programmed
Xon or Xoff characters. If the received character matches the programmed Xoff character, the V1412 will halt
transmission as soon as the current character has completed transmission. Data transmission is resumed
when a received character matches the Xon character.
FLOW_CONTROL[2:0] = ’010’.
Software flow control is enabled when
1.4.7
Multidrop Mode with Automatic Half-Duplex Transceiver Control
Multidrop mode with Automatic Half-Duplex Transceiver Control is enabled when GPIO_MODE[2:0] = ’011’
and FLOW_CONTROL[2:0] = ’011’.
1.4.7.1
Receiver
In this mode, the UART Receiver will automatically be enabled when an address byte (9th bit or parity bit is ’1’)
is received that matches the value stored in the XON_CHAR or XOFF_CHAR register. The address byte will
not be loaded into the RX FIFO. 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.
1.4.7.2
Transmitter
GPIO5/RTS# pin behaves as control pin for the direction of a half-duplex RS-485 transceiver. The polarity of
the GPIO5/RTS# pin can be configured via GPIO_MODE[3]. When the UART is not transmitting data, the
GPIO5/RTS# pin will be de-asserted. The GPIO5/RTS# pin will be asserted immediately before the UART
starts transmitting data. When the UART is done transmitting data, the GPIO5/RTS# pin will be de-asserted.
1.4.8
Multidrop Mode with Automatic Transmitter Enable
Multidrop mode with Automatic Transmitter Enable is enabled when GPIO_MODE[2:0] = ’100’ and
FLOW_CONTROL[2:0] = ’100’.
1.4.8.1
The behavior of the receiver is the same in this mode as it is in the Address Match mode described above.
1.4.8.2 Transmitter
Receiver
When there is an address match with the XON_CHAR register, the GPIO5/RTS# pin is asserted and remains
asserted whether the UART is transmitting data or not. The GPIO5/RTS# pin will be de-asserted when an
address byte is received that does not match the value in the XON_CHAR register. The polarity of the GPIO5/
RTS# pin can be configured via GPIO_MODE[3].
1.4.9
Programmable Turn-Around Delay
By default, the GPIO5/RTS# 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 GPIO5/RTS# pin can be delayed from 1 to 15 bit times via the
XCVR_EN_DELAY register to allow for the data to reach distant UARTs.
1.4.10 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.
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XR21V1412
REV. 1.0.0
2-CH FULL-SPEED USB UART
2.0 USB CONTROL COMMANDS
The following table shows all of the USB Control Commands that are supported by the V1412. Commands
included are standard USB commands, CDC-ACM commands and custom Exar commands. .
TABLE 3: SUPPORTED USB CONTROL COMMANDS
REQUEST
TYPE
NAME
REQUEST
VALUE
INDEX
LENGTH
DESCRIPTION
DEV GET_STATUS
0x80
0
0
0
0
0
0
0
2
2
0
0
Device: remote wake-up +
self-powered
IF GET_STATUS
0x81
0x82
0
0
1-4,
129-
132
Interface: zero
EP GET_STATUS
0
0
0
0-4,
0
2
0
129-
136
Endpoint: halted
Device remote wake-up
Endpoint halt
DEV CLEAR_FEATURE
EP CLEAR_FEATURE
0x00
0x02
1
1
1
0
0
0
0
0
0
0
0
0
0
0-4,
129-
136
DEV SET_FEATURE
DEV SET_FEATURE
EP SET_FEATURE
0x00
0x00
0x02
3
3
3
1
2
0
00
0
0
0
0
test
0
0
0
0
0
0
0
Device remote wake-up
Test mode
0
0-4,
129-
136
Endpoint halt
SET_ADDRESS
0x00
0x80
5
6
addr
0
0
1
0
0
0
0
0
0
GET_DESCRIPTOR
len
len
Device descriptor
LSB MSB
len len
LSB MSB
GET_DESCRIPTOR
0x80
6
0
2
0
0
Configuration descriptor
GET_CONFIGURATION
SET_CONFIGURATION
GET_INTERFACE
0x80
0x00
0x81
0x21
8
9
0
n
0
0
0
0
0
0
0
0
0
0
0
0
1
0
1
7
0
0
0
0
10
32
0-7
CDC_ACM_IF
SET_LINE_CODING
0, 2,
4, 6
Set the UART baud rate,
parity, stop bits, etc.
CDC_ACM_IF
GET_LINE_CODING
0xA1
0x21
33
34
0
0
0
0, 2,
4, 6
0
0
7
0
0
0
Get the UART baud rate,
parity, stop bits, etc.
CDC_ACM_IF
SET_CONTROL_LINE_STATE
val
0, 2,
4, 6
Set UART control lines
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XR21V1412
2-CH FULL-SPEED USB UART
REV. 1.0.0
TABLE 3: SUPPORTED USB CONTROL COMMANDS
REQUEST
TYPE
NAME
REQUEST
VALUE
INDEX
LENGTH
DESCRIPTION
CDC_ACM_IF
SEND_BREAK
0x21
35
val
val
0, 2,
4, 6
0
0
0
0
0
Send a break for the speci-
fied duration
LSB MSB
XR_SET_REG
0x40
0xC0
0
1
val
0
0
regis- block
ter
Exar custom command: set
one 8-bit register
val: 8-bit register value
register address: see
Table 6
block number: see Table 4
XR_GETN_REG
0
regis- block count count Exar custom register: get
ter
LSB MSB
count 8-bit registers
register address: see
Table 6
block number: see Table 4
2.1
UART Block Numbers
The table below lists the block numbers for accessing each of the UART channels and the UART Manager..
TABLE 4: CONTROL BLOCKS
BLOCK NAME
UART Channel A
UART Channel B
Reserved
BLOCK NUMBER
DESCRIPTION
0
1
The configuration and control registers for UART channel A.
The configuration and control registers for UART channel B.
Block Numbers 2-3 are reserved.
2-3
4
UART Manager
The control registers for the UART Manager. The UART Manager
enables/disables the TX and RX FIFOs for each UART.
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2-CH FULL-SPEED USB UART
3.0 REGISTER SET DESCRIPTION
The internal register set of the V1412 consists of 2 different types of registers: UART Manager and UART
registers. The UART Manager controls the TX, RX and FIFOs of all UART channels. The UART registers
configure and control the remaining UART channel functionality not related to the UART FIFO.
3.1
UART Manager Registers..
TABLE 5: UART MANAGER REGISTERS
ADDRESS
REGISTER NAME
BIT-7
BIT-6
0
BIT-5
0
BIT-4
0
BIT-3
0
BIT-2
0
BIT-1
RX
BIT-0
TX
0X10 FIFO_ENABLE_CHA
0X11 FIFO_ENABLE_CHB
0X18 RX_FIFO_RESET_CHA
0X19 RX_FIFO_RESET_CHB
0x1C TX_FIFO_RESET_CHA
0x1D TX_FIFO_RESET_CHB
0
0
0
0
0
0
0
RX
TX
Bit-7
Bit-7
Bit-7
Bit-7
Bit-6
Bit-6
Bit-6
Bit-6
Bit-5
Bit-5
Bit-5
Bit-5
Bit-4
Bit-4
Bit-4
Bit-4
Bit-3
Bit-3
Bit-3
Bit-3
Bit-2
Bit-2
Bit-2
Bit-2
Bit-1
Bit-1
Bit-1
Bit-1
Bit-0
Bit-0
Bit-0
Bit-0
FIFO_ENABLE Registers
Enables the RX FIFO and TX FIFOs. For proper functionality, the UART TX and RX must be enabled in the
following order:
FIFO_ENABLE_CHx = 0x1
UART_ENABLE = 0x3
// Enable TX FIFO
// Enable TX and RX of that channel
// Enable RX FIFO
FIFO_ENABLE_CHx = 0x3
RX_FIFO_RESET and TX_FIFO_RESET Registers
Writing a non-zero value to these registers resets the FIFOs.
13
XR21V1412
2-CH FULL-SPEED USB UART
REV. 1.0.0
3.2
UART Register Map
TABLE 6: UART REGISTERS
ADDRESS
REGISTER NAME
BIT-7
0
BIT-6
0
BIT-5
0
BIT-4
0
BIT-3
0
BIT-2
0
BIT-1
0
BIT-0
0
0X00 Reserved
0X01 Reserved
0
0
0
0
0
0
0
0
0X02 Reserved
0
0
0
0
0
0
0
0
0X03 UART_ENABLE
0X04 CLOCK_DIVISOR0
0x05 CLOCK_DIVISOR1
0x06 CLOCK_DIVISOR2
0x07 TX_CLOCK_MASK0
0x08 TX_CLOCK_MASK1
0x09 RX_CLOCK_MASK0
0x0A RX_CLOCK_MASK1
0x0B CHARACTER_FORMAT
0x0C FLOW_CONTROL
0
0
0
0
0
0
RX
TX
Bit-7
Bit-15
0
Bit-6
Bit-14
0
Bit-5
Bit-13
0
Bit-4
Bit-12
0
Bit-3
Bit-11
0
Bit-2
Bit-10
Bit-18
Bit-2
Bit-10
Bit-2
Bit-10
Bit-1
Bit-9
Bit-17
Bit-1
Bit-9
Bit-1
Bit-9
Bit-0
Bit-8
Bit-16
Bit-0
Bit-8
Bit-0
Bit-8
Bit-7
Bit-15
Bit-7
Bit-15
Stop
Bit-6
Bit-14
Bit-6
Bit-14
Bit-5
Bit-13
Bit-5
Bit-13
Parity
Bit-4
Bit-12
Bit-4
Bit-12
Bit-3
Bit-11
Bit-3
Bit-11
Data Bits
Flow Control Mode Select
Half-
Duplex
0
0
0
0
0x0D Reserved
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0x0E Reserved
0x0F Reserved
0
0
0
0
0
0
0
0
0x10 XON_CHAR
0x11 XOFF_CHAR
0x12 Reserved
Bit-7
Bit-7
0
Bit-6
Bit-6
0
Bit-5
Bit-5
0
Bit-4
Bit-4
0
Bit-3
Bit-3
0
Bit-2
Bit-2
0
Bit-1
Bit-1
0
Bit-0
Bit-0
0
0x13 ERROR_STATUS
Break
Status
Overrun
Error
Parity
Error
Framing
Error
Break
Error
0
0
0
0x14 TX_BREAK
0x15 XCVR_EN_DELAY
0x16 Reserved
Bit-7
Bit-6
Bit-5
Bit-4
Bit-3
Bit-2
Bit-1
Bit-0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
Delay
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0x17 Reserved
0x18 Reserved
0x19 Reserved
0x1A GPIO_MODE
XCVR
Enable
Polarity
0
0
0
0
Mode Select
0x1B GPIO_DIRECTION
0x1D GPIO_SET
0
0
0
0
0
0
0
0
GPIO5
GPIO5
GPIO5
GPIO5
GPIO4
GPIO4
GPIO4
GPIO4
GPIO3
GPIO3
GPIO3
GPIO3
GPIO2
GPIO2
GPIO2
GPIO2
GPIO1
GPIO1
GPIO1
GPIO1
GPIO0
GPIO0
GPIO0
GPIO0
0x1E GPIO_CLEAR
0x1F GPIO_STATUS
14
XR21V1412
REV. 1.0.0
2-CH FULL-SPEED USB UART
3.3
UART Register Descriptions
UART_ENABLE Register Description (Read/Write)
3.3.1
This register enables the UART TX and RX. For proper functionality, the UART TX and RX must be enabled in
the following order:
FIFO_ENABLE_CHx = 0x1
UART_ENABLE = 0x3
// Enable TX FIFO
// Enable TX and RX of that channel
// Enable RX FIFO
FIFO_ENABLE_CHx = 0x3
UART_ENABLE[0]: Enable UART TX
• Logic 0 = UART TX disabled.
• Logic 1 = UART TX enabled.
UART_ENABLE[1]: Enable UART RX
• Logic 0 = UART RX disabled.
• Logic 1 = UART RX enabled.
UART_ENABLE[7:2]: Reserved
These bits are reserved and should remain ’0’.
3.3.2 CLOCK_DIVISOR0, CLOCK_DIVISOR1, CLOCK_DIVISOR2 Register Description (Read/Write)
These registers are used for programming the baud rate. The V1412 uses a 19-bit divisor and 16-bit mask
register. Using the internal 48MHz oscillator, the 19-bit divisor is calculated as follows:
CLOCK_DIVISOR = Trunc ( 48000000 / Baud Rate )
For example, if the the baud rate is 115200bps, then
CLOCK_DIVISOR = Trunc ( 48000000 / 115200 ) = Trunc (416.66667) = 416
CLOCK_DIVISOR0[7:0]: Baud rate clock divisor bits [7:0]
CLOCK_DIVISOR1[7:0]: Baud rate clock divisor bits [15:8]
CLOCK_DIVISOR2[2:0]: Baud rate clock divisor bits [18:16]
CLOCK_DIVISOR2[7:3]: Reserved
These bits are reserved and should remain ’0’.
3.3.3
TX_CLOCK_MASK0, TX_CLOCK_MASK1 Register Description (Read/Write)
A look-up table is used for the value of the 16-bit TX Clock mask registers. The index of the look-up table is
calculated as follows:
index = Trunc ( ( ( 48000000 / Baud Rate ) - CLOCK_DIVISOR ) * 32)
For example, if the baud rate is 115200bps, then the index will be:
index = Trunc ( ( ( 48000000 / 115200 ) - 416 ) * 32) = Trunc (21.3333) = 21
The values for some baud rates to program the TX_CLOCK_MASK registers are listed in Table 7. For baud
rates that are not listed, use the index to select TX_CLOCK_MASK register values from Table 8.
3.3.4
RX_CLOCK_MASK0, RX_CLOCK_MASK1 Register Description (Read/Write)
The values for some baud rates to program the RX_CLOCK_MASK registers are listed in Table 7. For baud
rates that are not listed, use the same index calculated for the TX_CLOCK_MASK register to select
RX_CLOCK_MASK register values from Table 8.
15
XR21V1412
2-CH FULL-SPEED USB UART
REV. 1.0.0
TABLE 7: CLOCK DIVISOR AND CLOCK MASK VALUES FOR COMMON BAUD RATES
BAUD RATE (BPS)
1200
CLOCK DIVISOR (DECIMAL)
TX CLOCK MASK (HEX)
0x0000
0x0000
0x0000
0x0000
0x0000
0x0000
0x0912
0x0B6D
0x0912
0x0208
0x0000
0x0912
0x0040
0x0000
0x0B6D
0x0000
0x0000
0x0104
0x0000
0x0492
0x076D
0x0000
0x0122
0x0B6D
0x0000
0x0000
RX CLOCK MASK (HEX)
0x0000
0x0000
0x0000
0x0000
0x0000
0x0000
0x0924
0x0B6A
0x0924
0x0040
0x0000
0x0924
0x0000
0x0000
0x0DB6
0x0000
0x0000
0x0108
0x0000
0x0492
0x0BB6
0x0000
0x0224
0x0DB6
0x0000
0x0000
40000
20000
10000
5000
2500
1250
833
416
208
104
96
2400
4800
9600
19200
38400
57600
115200
230400
460800
500000
576000
921600
1000000
1152000
1500000
2000000
2500000
3000000
3125000
3500000
4000000
4250000
6250000
8000000
12000000
83
52
48
41
32
24
19
16
15
13
12
11
7
6
4
For baud rates that are not listed in the table above, use the index value calcuated using the formula in
“Section 3.3.3, TX_CLOCK_MASK0, TX_CLOCK_MASK1 Register Description (Read/Write)” on page 15
to determine which TX Clock and RX Clock Mask register values to use from Table 8. For the the RX Clock
Mask register, there are 2 values listed and would depend on whether the Clock Divisor is even or odd. For
even Clock Divisors, use the value from the first column. For odd Clock Divisors, use the value from the last
column.
16
XR21V1412
REV. 1.0.0
2-CH FULL-SPEED USB UART
TABLE 8: TX AND RX CLOCK MASK VALUES
INDEX
RX CLOCK MASK (HEX) -
RX CLOCK MASK (HEX) -
ODD CLOCK DIVISOR
TX CLOCK MASK (HEX)
EVEN CLOCK DIVISOR
(DECIMAL)
0
0x0000
0x0000
0x0100
0x0020
0x0010
0x0208
0x0104
0x0844
0x0444
0x0122
0x0912
0x0492
0x0252
0x094A
0x052A
0x0AAA
0x0AAA
0x0555
0x0B55
0x06B5
0x05B5
0x0B6D
0x076D
0x0EDD
0x0DDD
0x07BB
0x0F7B
0x0DF7
0x07F7
0x0FDF
0x0F7F
0x0FFF
0x0000
0x0000
0x0000
0x0400
0x0100
0x0040
0x0820
0x0210
0x0110
0x0888
0x0448
0x0248
0x0928
0x04A4
0x0AA4
0x0954
0x0554
0x0AD4
0x0AB4
0x05AC
0x0D6C
0x0B6A
0x06DA
0x0DDA
0x0BBA
0x0F7A
0x0EF6
0x0BF6
0x0FEE
0x0FBE
0x0EFE
0x0FFE
0x0000
0x0000
0x0100
0x0020
0x0010
0x0208
0x0108
0x0884
0x0444
0x0224
0x0924
0x0492
0x0292
0x0A52
0x054A
0x04AA
0x0AAA
0x05AA
0x055A
0x0B56
0x06D6
0x0DB6
0x0BB6
0x076E
0x0EEE
0x0DDE
0x07DE
0x0F7E
0x0EFE
0x07FE
0x0FFE
0x0FFD
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
19
20
21
22
23
24
25
26
27
28
29
30
31
17
XR21V1412
2-CH FULL-SPEED USB UART
REV. 1.0.0
3.3.5
CHARACTER_FORMAT Register Description (Read/Write)
This register controls the character format such as the word length (7, 8 or 9), parity (odd, even, forced ’0’, or
forced ’1’) and number of stop bits (1 or 2).
CHARACTER_FORMAT[3:0]: Data Bits.
TABLE 9: DATA BITS
DATA BITS
CHARACTER_FORMAT[3:0]
7
8
9
0111
1000
1001
All other values for CHARACTER_FORMAT[3:0] are reserved.
CHARACTER_FORMAT[6:4]: Parity Mode Select
These bits select the parity mode. If 9-bit data mode has been selected, then writing to these bits will not have
any effect. In other words, there will not be an additional parity bit.
TABLE 10: PARITY SELECTION
BIT-6
BIT-5
BIT-4
PARITY SELECTION
No parity
0
0
0
0
1
0
0
1
1
0
0
1
0
1
0
Odd parity
Even parity
Force parity to mark, “1”
Force parity to space, “0”
CHARACTER_FORMAT[7]: Stop Bit select
This register selects the number of stop bits to add to the transmitted character and how many stop bits to
check for in the received character.
TABLE 11: STOP BIT SELECTION
BIT-7
NUMBER OF STOP BITS
1 stop bit
0
1
2 stop bits
3.3.6
FLOW_CONTROL Register Description (Read/Write)
These registers select the flow control mode. These registers should only be written to when the UART is
disabled. Writing to the FLOW_CONTROL register when the UART is enabled will result in undefined
behavior.
18
XR21V1412
REV. 1.0.0
2-CH FULL-SPEED USB UART
FLOW_CONTROL[2:0]: Flow control mode select
TABLE 12: FLOW CONTROL MODE SELECTION
BIT-2
BIT-1
BIT-0 MODE DESCRIPTION
0
0
0
0
1
0
0
1
1
0
0
1
0
1
0
No flow control.
HW flow control enabled
SW flow control enabled
Multidrop mode with Automatic Half-Duplex Transceiver control
Multidrop mode with Automatic Transmitter Enable
FLOW_CONTROL[3]: Half-Duplex Mode
• Logic 0 = Normal (full-duplex) mode. The UART can transmit and receive data at the same time.
• Logic 1 = Half-duplex Mode. In half-duplex mode, any data on the RX pin is ignored when the UART is
transmitting data.
FLOW_CONTROL[7:4]: Reserved
These bits are reserved and should remain ’0’.
3.3.7
XON_CHAR, XOFF_CHAR Register Descriptions (Read/Write)
The XON_CHAR and XOFF_CHAR registers store the XON and XOFF characters, respectively, that are used
in the Automatic Software Flow control.
XON_CHAR[7:0]: XON Character
In Automatic Software Flow control mode, the UART will resume data transmission when the XON character
has been received.
For behavior in the Address Match mode, see “Section 1.4.7, Multidrop Mode with Automatic Half-Duplex
Transceiver Control” on page 10.
For behavior in the Address Match with TX Flow Control mode, see “Section 1.4.8, Multidrop Mode with
Automatic Transmitter Enable” on page 10.
XOFF_CHAR[7:0]: XOFF Character
In Automatic Software Flow control mode, the UART will suspend data transmission when the XOFF character
has been received.
For behavior in the Address Match mode, see “Section 1.4.7, Multidrop Mode with Automatic Half-Duplex
Transceiver Control” on page 10.
For behavior in the Address Match with TX Flow Control mode, see “Section 1.4.8, Multidrop Mode with
Automatic Transmitter Enable” on page 10.
3.3.8
ERROR_STATUS Register Description - Read-only
This register reports any errors that may have occurred on the line such as break, framing, parity and overrun.
ERROR_STATUS[2:0]: Reserved
These bits are reserved. Any values read from these bits should be ignored.
ERROR_STATUS[3]: Break error
• Logic 0 = No break condition
• Logic 1 = A break condition has been detected (clears after read).
19
XR21V1412
2-CH FULL-SPEED USB UART
ERROR_STATUS[4]: Framing Error
REV. 1.0.0
• Logic 0 = No framing error
• Logic 1 = A framing error has been detected (clears after read). A framing error occurs when a stop bit is not
present when it is expected.
ERROR_STATUS[5]: Parity Error
• Logic 0 = No parity error
• Logic 1 = A parity error has been detected (clears after read).
ERROR_STATUS[6]: Overrun Error
• Logic 0 = No overrun error
• Logic 1 = An overrun error has been detected (clears after read). An overrun error occurs when the RX FIFO
is full and another byte of data is received.
ERROR_STATUS[7]: Break Status
• Logic 0 = Break condition is no longer present.
• Logic 1 = Break condition is currently being detected.
3.3.9
TX_BREAK Register Description (Read/Write)
Writing a non-zero value to this register causes a break condition to be generated continuously until the
register is cleared. If data is being shifted out of the TX pin, the data will be completed shifted out before the
break condition is generated.
3.3.10 XCVR_EN_DELAY Register Description (Read/Write)
XCVR_EN_DELAY[3:0]: Turn-around delay
This is the number of bit times to wait before changing the direction of the transceiver from transmit to receive
when half-duplex mode is enabled.
XCVR_EN_DELAY[3:0]: Reserved
These bits are reserved and should be ’0’.
3.3.11 GPIO_MODE Register Description (Read/Write)
GPIO_MODE[2:0]: GPIO Mode Select
There are 4 modes of operation for the GPIOs. The descriptions can be found in “Section 1.4, UART” on
page 7.
TABLE 13: GPIO MODES
BITS
GPIO0 GPIO1
GPIO2
GPIO3
GPIO4
GPIO5
MODE DESCRIPTION
[2:0]
000
001
010
011
GPIO0 GPIO1
GPIO0 GPIO1
GPIO0 GPIO1
GPIO0 GPIO1
GPIO2
GPIO2
DSR#
GPIO3
GPIO3
DTR#
GPIO4
CTS#
GPIO5 GPIO Mode
RTS# Auto RTS/CTS HW Flow Control
GPIO5 Auto DTR/DSR HW Flow Control
GPIO4
GPIO4
GPIO2
GPIO3
XCVR Multidrop Mode with Auto Half-Duplex Trans-
Enable ceiver Control
100
GPIO0 GPIO1
GPIO2
GPIO3
GPIO4
XCVR Multidrop Mode with Auto TX Enable
Enable
20
XR21V1412
REV. 1.0.0
2-CH FULL-SPEED USB UART
GPIO_MODE[3]: Transceiver Enable Polarity
• Logic 0 = Low for TX
• Logic 1 = High for TX
GPIO_MODE[7:4]: Reserved
These register bits are reserved. When writing to these bits, the value should be ’0’. When reading from these
bits, they are undefined and should be ignored.
3.3.12 GPIO_DIRECTION Register Description (Read/Write)
This register controls the direction of the GPIO if it is not controlled by the GPIO_MODE register.
GPIO_DIRECTION[5:0]: GPIOx Direction
• Logic 0 = GPIOx is an input.
• Logic 1 = GPIOx is an output.
GPIO_DIRECTION[7:6]: Reserved
These register bits are reserved and should be ’0’.
3.3.13 GPIO_SET Register Description (Read/Write)
Writing a ’1’ in this register drives the GPIO output high. Writing a ’0’ to a bit has no effect. Bits 7-6 are unused
and should be ’0’.
3.3.14 GPIO_CLEAR Register Description (Read/Write)
Writing a ’1’ in this register drives the GPIO output low. Writing a ’0’ to a bit has no effect. Bits 7-6 are unused
and should be ’0’.
3.3.15 GPIO_STATUS Register Description (Read-Only)
This register reports the current state of the GPIO pin.
21
XR21V1412
2-CH FULL-SPEED USB UART
4.0 ELECTRICAL CHARACTERISTICS
REV. 1.0.0
DC ELECTRICAL CHARACTERISTICS - POWER CONSUMPTION
UNLESS OTHERWISE NOTED: TA = -40O TO +85OC, VCC IS 2.97 TO 3.63V
LIMITS
SYMBOL
PARAMETER
3.3V
TYP
UNITS
CONDITIONS
MIN
MAX
ICC
Power Supply Current
Suspend mode Current
16
2
20
mA
mA
ISusp
2.15
DC ELECTRICAL CHARACTERISTICS - UART & GPIO PINS
UNLESS OTHERWISE NOTED: TA = -40O TO +85OC, VCC IS 2.97 TO 3.63V
LIMITS
SYMBOL
PARAMETER
3.3V
UNITS
CONDITIONS
MIN
MAX
VIL
VIH
VOL
VOH
IIL
Input Low Voltage
-0.3
0.8
V
V
Input High Voltage
2.0
5.5
0.3
Output Low Voltage
V
IOL = 4 mA
IOH = -4 mA
Output High Voltage
2.2
V
Input Low Leakage Current
Input High Leakage Current
Input Pin Capacitance
±10
±10
5
uA
uA
pF
IIH
CIN
DC ELECTRICAL CHARACTERISTICS - USB I/O PINS
UNLESS OTHERWISE NOTED: TA = -40O TO +85OC, VCC IS 2.97 TO 3.63V
LIMITS
SYMBOL
PARAMETER
3.3V
UNITS
CONDITIONS
MIN
MAX
VIL
VIH
VOL
Input Low Voltage
-0.3
0.8
V
V
V
Input High Voltage
Output Low Voltage
2.0
0
5.5
0.3
External 15 K Ohm to
GND on USBD- pin
VOH
Output High Voltage
2.8
28
3.6
V
External 15 K Ohm to
GND on USBD- pin
VDrvZ
IOSC
Driver Output Impedance
Open short current Current
44
35
Ohms
mA
1.5 V on USBD+ and
USBD-
22
XR21V1412
REV. 1.0.0
2-CH FULL-SPEED USB UART
PACKAGE DIMENSIONS (32 PIN QFN - 5 X 5 X 0.9 mm)
Note: the actual center pad
is metallic and the size (D2)
is device-dependent with a
typical tolerance of 0.3mm
Note: The control dimension is in millimeter.
INCHES
MILLIMETERS
SYMBOL
MIN
MAX
0.039
0.002
0.010
0.201
0.150
0.012
MIN
0.80
0.00
0.15
4.90
3.50
0.18
MAX
1.00
0.05
0.25
5.10
3.80
0.30
A
A1
A3
D
0.031
0.000
0.006
0.193
0.138
0.007
D2
b
e
0.0197 BSC
0.50 BSC
L
0.012
0.008
0.020
-
0.35
0.20
0.45
-
k
23
XR21V1412
2-CH FULL-SPEED USB UART
REV. 1.0.0
REVISION HISTORY
DATE
REVISION
DESCRIPTION
June 2009
1.0.0
Final Datasheet.
NOTICE
EXAR Corporation reserves the right to make changes to the products contained in this publication in order to
improve design, performance or reliability. EXAR Corporation assumes no responsibility for the use of any
circuits described herein, conveys no license under any patent or other right, and makes no representation that
the circuits are free of patent infringement. Charts and schedules contained here in are only for illustration
purposes and may vary depending upon a user’s specific application. While the information in this publication
has been carefully checked; no responsibility, however, is assumed for inaccuracies.
EXAR Corporation 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
EXAR Corporation 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 EXAR Corporation is adequately
protected under the circumstances.
Copyright 2009 EXAR Corporation
Datasheet June 2009.
Send your UART technical inquiry with technical details to hotline: uarttechsupport@exar.com.
Reproduction, in part or whole, without the prior written consent of EXAR Corporation is prohibited.
24
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