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SC16C850SVIBSNXPN/a75avai1.8 V single UART, 20 Mbit/s (max.) with 128-byte FIFOs, infrared (IrDA), and XScale VLIO bus interface


SC16C850SVIBS ,1.8 V single UART, 20 Mbit/s (max.) with 128-byte FIFOs, infrared (IrDA), and XScale VLIO bus interfaceFeatures and benefits Single channel high performance UART 1.8 V operation Advanced package: HVQ ..
SC16C850VIBS ,1.8 V single UART, 5 Mbit/s (max.) with 128-byte FIFOs, infrared (IrDA), and XScale VLIO bus interfaceFeatures and benefits„ Single channel high performance UART„ 1.8 V operation„ Advanced package: HVQ ..
SC16C852LIB ,1.8 V dual UART, 5 Mbit/s (max.) with 128-byte FIFOs, infrared (IrDA) and 16 mode or 68 mode bus interfaceFeatures and benefits Dual channel high performance UART Intel or Motorola bus interface selectab ..
SC16C852SVIET ,1.8 V dual UART, 20 Mbit/s (max.) with 128-byte FIFOs, infrared (IrDA), and XScale VLIO bus interfaceFeaturesn Dual channel high performance UARTn 1.8 V operationn Advanced package: TFBGA36n Up to 20 ..
SC16IS740IPW ,Single UART with I2C-bus/SPI interface, 64 bytes of transmit and receive FIFOs, IrDA SIR built-in supportfeatures Single full-duplex UART2 Selectable I C-bus or SPI interface 3.3 V or 2.5 V operation ..
SC16IS741IPW ,Single UART with I2C-bus/SPI interface, 64 bytes of transmit and receive FIFOs, IrDA SIR built-in supportfeatures„ Single full-duplex UART2„ Selectable I C-bus or SPI interface„ 3.3 V or 2.5 V operation„ ..
SDB55N03L , N-Channel Logic Level E nhancement Mode Field E ffect Transistor
SDB55N03L , N-Channel Logic Level E nhancement Mode Field E ffect Transistor
SDB60N03L , N-Channel Logic Level E nhancement Mode Field E ffect Transistor
SDB65N03L , N-Channel Logic Level E nhancement Mode Field E ffect Transistor
SDB65N03L , N-Channel Logic Level E nhancement Mode Field E ffect Transistor
SDB75N03L , N-Channel Logic Level E nhancement Mode Field Effect Transistor


SC16C850SVIBS
1.8 V single UART, 20 Mbit/s (max.) with 128-byte FIFOs, infrared (IrDA), and XScale VLIO bus interface
1. General description
The SC16C850SV is a 1.8 V, low power single channel Universal Asynchronous Receiver
and Transmitter (UART) used for serial data communications. Its principal function is to
convert parallel data into serial data and vice versa. The UART can handle serial data
rates up to 20 Mbit/s (4 sampling rate). SC16C850SV can be programmed to operate in
extended mode where additional advanced UART features are available (see
Section 6.2).The SC16C850SV family UART provides enhanced UART functions with
128-byte FIFOs, modem control interface and IrDA encoder/decoder. On-board status
registers provide the user with error indications and operational status. System interrupts
and modem control features may be tailored by software to meet specific user
requirements. An internal loopback capability allows on-board diagnostics. Independent
programmable baud rate generators are provided to select transmit and receive baud
rates.
The SC16C850SV with Intel XScale processor VLIO interface operates at 1.8 V and is
available in the HVQFN32 package.
2. Features and benefits
Single channel high performance UART 1.8 V operation Advanced package: HVQFN32 Up to 20 Mbit/s data rate at 1.8V Programmable sampling rates: 16, 8, 4 128-byte transmit FIFO to reduce the bandwidth requirement of the external CPU 128-byte receive FIFO with error flags to reduce the bandwidth requirement of the
external CPU 128 programmable Receive and Transmit FIFO interrupt trigger levels 128 Receive and Transmit FIFO reporting levels (level counters) Automatic software (Xon/Xoff) and hardware (RTS/CTS or DTR/DSR) flow control Programmable Xon/Xoff characters 128 programmable hardware and software trigger levels Automatic 9-bit mode (RS-485) address detection Automatic RS-485 driver turn-around with programmable delay UART software reset High resolution clock prescaler, from 0 to 15 with granularity of 1 ⁄16 to allow
non-standard UART clock to be used Industrial temperature range (40 C to +85 C)
SC16C850SV
1.8 V single UART , 20 Mbit/s (max.) with 128-byte FIFOs,
infrared (IrDA), and XScale VLIO bus interface
Rev. 2 — 22 March 2011 Product data sheet
NXP Semiconductors SC16C850SV
Single UART with 128-byte FIFOs, IrDA, and XScale VLIO bus interface
Software compatible with industry standard SC16C650B Software selectable baud rate generator Supports IrDA version 1.0 (up to 115.2 kbit/s) Standard modem interface or infrared IrDA encoder/decoder interface Enhanced Sleep mode and low power feature Modem control functions (CTS, RTS, DSR, DTR, RI, CD) Independent transmitter and receiver enable/disable Pb-free, RoHS compliant package offered
3. Ordering information
Table 1. Ordering information
SC16C850SVIBS HVQFN32 plastic thermal enhanced very thin quad flat package; no leads; 32 terminals;
body 55 0.85 mm
SOT617-1
NXP Semiconductors SC16C850SV
Single UART with 128-byte FIFOs, IrDA, and XScale VLIO bus interface
4. Block diagram

NXP Semiconductors SC16C850SV
Single UART with 128-byte FIFOs, IrDA, and XScale VLIO bus interface
5. Pinning information
5.1 Pinning

5.2 Pin description

Table 2. Pin description

AD0 29 I/O Address and Data bus (bidirectional). These pins are the 8-bit multiplexed data bus and
address bus for transferring information to or from the controlling CPU. AD0 is the least
significant bit and is address A0 during the address cycle, and AD7 is the most significant bit
and is address A7 during the address cycle.
AD1 30
AD2 31
AD3 32
AD4 1
AD5 3
AD6 4
AD7 5 26 I Carrier Detect (active LOW). A logic 0 on this pin indicates that a carrier has been detected
by the modem for that channel. Status can be tested by reading MSR[7]. 8I Chip Select (active LOW). This pin enables the data transfers between the host and the
SC16C850SV.
CTS 24 I Clear to Send (active LOW). A logic 0 on the CTS pin indicates the modem or data set is
ready to accept transmit data from the SC16C850SV. Status can be tested by reading
MSR[4].
DSR 25 I Data Set Ready (active LOW). A logic 0 on this pin indicates the modem or data set is
powered-on and is ready for data exchange with the UART. Status can be tested by reading
MSR[5].
NXP Semiconductors SC16C850SV
Single UART with 128-byte FIFOs, IrDA, and XScale VLIO bus interface

[1] HVQFN32 package die supply ground is connected to both VSS pin and exposed center pad. VSS pin must be connected to supply
ground for proper device operation. For enhanced thermal, electrical, and board level performance, the exposed pad needs to be
soldered to the board using a corresponding thermal pad on the board and for proper heat conduction through the board, thermal vias
need to be incorporated in the PCB in the thermal pad region.
INT 20 O Interrupt output. The output state is defined by the user through the software setting of
MCR[5]. INT is set to the active mode when MCR[5] is set to a logic 0. INT is set to the
open-source mode when MCR[3] is set to a logic 1. See Table 19.
IOR 14 I Read strobe (active LOW). A HIGH to LOW transition on this signal starts the read cycle.
The SC16C850SV reads a byte from the internal register and puts the byte on the data bus
for the host to retrieve.
IOW 12 I Write strobe (active LOW). A HIGH to LOW transition on this signal starts the write cycle,
and a LOW to HIGH transition transfers the data on the data bus to the internal register.
LLA 19 I Latch Lower Address (active LOW). A logic LOW on this pin puts the VLIO interface in the
address phase of the transaction, where the lower 8 bits of the VLIO (specifying the UART
register and the channel address) are loaded into the address latch of the device through
the AD7to AD0 bus. A logic HIGH puts the VLIO interface in the data phase where data can
are transferred between the host and the UART.
LOWPWR9 I Low Power. When asserted (active HIGH), the device immediately goes into low-power
mode. The oscillator is shut-off and some host interface pins are isolated from the host’s bus
to reduce power consumption. The device only returns to normal mode when the LOWPWR
pin is de-asserted. On the negative edge of a de-asserting LOWPWR signal, the device is
automatically reset and all registers return to their default reset states. This pin has an
internal pull-down resistor, therefore, it can be left unconnected.
n.c. 2, 15, 16,
17, 18 not connected
RESET 23 I Master reset (active LOW). A reset pulse will reset the internal registers and all the outputs.
The SC16C850SV transmitter outputs and receiver inputs will be disabled during reset time.
(See Section 7.24 “SC16C850SV external reset condition and software reset” for
initialization details.) 27 I Ring Indicator (active LOW). A logic 0 on this pin indicates the modem has received a
ringing signal from the telephone line. A logic 1 transition on this input pin will generate an
interrupt is modem status interrupt is enabled. Status can be tested by reading MCR[6].
RTS 21 O Request to Send (active LOW). A logic 0 on the RTS pin indicates the transmitter has data
ready and waiting to send. Writing a logic 1 in the modem control register MCR[1] will set
this pin to a logic 0, indicating data is available. After a reset this pin will be set to a logic1. 6 I UART receive data. The RX signal will be a logic 1 during reset, idle (no data), or when not
receiving data. During the local Loopback mode, the RX input pin is disabled and TX data is
connected to the UART RX input internally. 7 O UART transmit data. The TX signal will be a logic 1 during reset, idle (no data), or when the
transmitter is disabled. During the local Loopback mode, the TX output pin is disabled and
TX data is internally connected to the UART RX input.
VDD 28 I Power supply input.
VSS 13[1] I Signal and power ground.
XTAL1 10 I Crystal or external clock input. Functions as a crystal input or as an external clock input. A
crystal can be connected between this pin and XTAL2 to form an internal oscillator circuit.
Alternatively, an external clock can be connected to this pin to provide custom data rates
(see Section 6.9 “Programmable baud rate generator”). See Figure4.
XTAL2 11 O Output of the crystal oscillator or buffered clock. Crystal oscillator output or buffered
clock output. Should be left open if an external clock is connected to XTAL1.
Table 2. Pin description …continued
NXP Semiconductors SC16C850SV
Single UART with 128-byte FIFOs, IrDA, and XScale VLIO bus interface
6. Functional description

The SC16C850SV provides serial asynchronous receive data synchronization,
parallel-to-serial and serial-to-parallel data conversions for both the transmitter and
receiver sections. These functions are necessary for converting the serial data stream into
parallel data that is required with digital data systems. Synchronization for the serial data
stream is accomplished by adding start and stop bits to the transmit data to form a data
character (character orientated protocol). Data integrity is ensured by attaching a parity bit
to the data character. The parity bit is checked by the receiver for any transmission bit
errors. The electronic circuitry to provide all these functions is fairly complex, especially
when manufactured on a single integrated silicon chip. The SC16C850SV represents
such an integration with greatly enhanced features. The SC16C850SV is fabricated with
an advanced CMOS process.
The SC16C850SV is an upward solution to the SC16C650B with a VLIO interface that
provides a single UART capability with 128 bytes of transmit and receive FIFO memory,
instead of 32 bytes for the SC16C650B. The SC16C850SV is designed to work with high
speed modems and shared network environments that require fast data processing time.
Increased performance is realized in the SC16C850SV by the transmit and receive
FIFOs. This allows the external processor to handle more networking tasks within a given
time. In addition, the four selectable receive and transmit FIFO trigger interrupt levels are
provided in normal mode, or 128 programmable levels are provided in extended mode for
maximum data throughput performance especially when operating in a multi-channel
environment (see Section 6.2 “Extended mode (128-byte FIFO)”). The FIFO memory
greatly reduces the bandwidth requirement of the external controlling CPU, and increases
performance.
A low power pin (LOWPWR) is provided to further reduce power consumption by isolating
the host interface bus.
The SC16C850SV is capable of operation up to 20 Mbit/s with an external 80 MHz clock.
With a 24 MHz crystal, the SC16C850SV is capable of operation up to 6 Mbit/s.
The rich feature set of the SC16C850SV is available through internal registers. These
features are: selectable and programmable receive and transmit FIFO trigger levels,
selectable TX and RX baud rates, and modem interface controls (all standard features).
Following a power-on reset an external reset or a software reset, the SC16C850SV is
software compatible with the previous generation SC16C650B.
6.1 UART selection

The UART provides the user with the capability to bidirectionally transfer information
between a CPU and an external serial device. The CS pin together with addresses A6 and
A7 determine if the UART is being accessed; see Table3. Table 3. Serial port selection
H = HIGH; L = LOW; X = Don’t care.
CS = H, A7= X, A6 = X device not selected
CS = L, A7= L, A6 = L UART selected
CS = L, A7= L, A6 = H device not selected
CS = L, A7= H, A6 = X device not selected
NXP Semiconductors SC16C850SV
Single UART with 128-byte FIFOs, IrDA, and XScale VLIO bus interface
6.2 Extended mode (128-byte FIFO)

The device is in the extended mode when any of these four registers contains any value
other than 0: FLWCNTH, FLWCNTL, TXINTLVL, RXINTLVL.
6.3 Internal registers

The SC16C850SV provides a set of 25 internal registers for monitoring and controlling the
functions of the UART. These registers are shown in Table4.
[1] These registers are accessible only when LCR[7] is a logic0.
Table 4. Internal registers decoding
General register set (THR/RHR, IER/ISR, MCR/MSR, FCR, LSR, SPR)[1]

000Receive Holding Register Transmit Holding Register
001Interrupt Enable Register Interrupt Enable Register
010Interrupt Status Register FIFO Control Register
011Line Control Register Line Control Register
100Modem Control Register Modem Control Register
101Line Status Register Extra Feature Control Register (EFCR)
110Modem Status Register n/a
111Scratchpad Register Scratchpad Register
Baud rate register set (DLL/DLM)[2]

000LSB of Divisor Latch LSB of Divisor Latch
001MSB of Divisor Latch MSB of Divisor Latch
Second special register set (TXLVLCNT/RXLVLCNT)[3]

011Transmit FIFO Level Count n/a
100Receive FIFO Level Count n/a
Enhanced register set (EFR, Xon1/Xon2, Xoff1/Xoff2)[4]

010Enhanced Feature Register Enhanced Feature Register
100Xon1 word Xon1 word
101Xon2 word Xon2 word
110Xoff1 word Xoff1 word
111Xoff2 word Xoff2 word
First extra feature register set (TXINTLVL/RXINTLVL, FLWCNTH/FLWCNTL)[5]

010Transmit FIFO Interrupt Level Transmit FIFO Interrupt Level
100Receive FIFO Interrupt Level Receive FIFO Interrupt Level
110Flow Control Count High Flow Control Count High
111Flow Control Count Low Flow Control Count Low
Second extra feature register set (CLKPRES, SAMPR, RS485TIME, AFCR2, AFCR1)[6]
1 0 Clock Prescaler Clock Prescaler
011Sampling Rate Sampling Rate
100RS-485 turn-around Timer RS-485 turn-around Timer
110Advanced Feature Control Register 2 Advanced Feature Control Register 2
111Advanced Feature Control Register 1 Advanced Feature Control Register 1
NXP Semiconductors SC16C850SV
Single UART with 128-byte FIFOs, IrDA, and XScale VLIO bus interface

[2] These registers are accessible only when LCR[7] is a logic1.
[3] Second special registers are accessible only when EFCR[0]=1.
[4] Enhanced feature registers are only accessible when LCR= 0xBF.
[5] First extra feature registers are only accessible when EFCR[2:1]= 01b.
[6] Second extra feature registers are only accessible when EFCR[2:1]= 10b.
6.4 FIFO operation
6.4.1 32-byte FIFO mode

When all four of these registers (TXINTLVL, RXINTLVL, FLWCNTH, FLWCNTL) in the
First Extra Register Set are empty (0x00) the transmit and receive trigger levels are set by
FCR[7:4]. In this mode the transmit and receive trigger levels are backward compatible to
the SC16C650B (see Table 5), and the FIFO sizes are 32 entries. The transmit and
receive data FIFOs are enabled by the FIFO Control Register bit 0 (FCR[0]). It should be
noted that the user can set the transmit trigger levels by writing to the FCR, but activation
will not take place until EFR[4] is set to a logic 1. The receiver FIFO section includes a
time-out function to ensure data is delivered to the external CPU (see Section 6.8). Please
refer to Table 10 and Table 11 for the setting of FCR[7:4].
6.4.2 128-byte FIFO mode

When either TXINTLVL, RXINTLVL, FLWCNTH or FLWCNTL in the First Extra Register
Set contains any value other than 0x00, the transmit and receive trigger levels are set by
TXINTLVL and RXINTLVL registers. TXINTLVL sets the trigger levels for the transmit
FIFO, and the transmit trigger levels can be set to any value between 1 and 128 with
granularity of 1. RXINTLVL sets the trigger levels for the receive FIFO, the receive trigger
levels can be set to any value between 1 and 128 with granularity of 1.
When the effective FIFO size changes (that is, when FCR[0] toggles or when the
combined content of TXINTLVL, RXINTLVL, FLWCNTH and FLWCNTL changes between
equal and unequal to 0x00), both RX FIFO and TX FIFO will be reset (data in the FIFO will
be lost).
6.5 Hardware flow control

When automatic hardware flow control is enabled, the SC16C850SV monitors the CTS
pin for a remote buffer overflow indication and controls the RTS pin for local buffer
overflows. Automatic hardware flow control is selected by setting EFR[6] (RTS) and
EFR[7] (CTS) to a logic 1. If CTS transitions from a logic 0 to a logic 1 indicating a flow
control request, ISR[5] will be set to a logic 1 (if enabled via IER[7:6]), and the
SC16C850SV will suspend TX transmissions as soon as the stop bit of the character in
process is shifted out. Transmission is resumed after the CTS input returns to a logic0,
indicating more data may be sent.
Table 5. Interrupt trigger level and Flow control mechanism
00816 8 0 01 16 8 16 7 10 24 24 24 15 11 28 30 28 23
NXP Semiconductors SC16C850SV
Single UART with 128-byte FIFOs, IrDA, and XScale VLIO bus interface

When AFCR1[2] is set to 1, then the function of CTS pin is mapped to the DSR pin, and
the function of RTS is mapped to DTR pin. DSR and DTR pins will behave as described
above for CTS and RTS.
With the automatic hardware flow control function enabled, an interrupt is generated when
the receive FIFO reaches the programmed trigger level. The RTS (or DTR) pin will not be
forced to a logic 1 (RTS off) until the receive FIFO reaches the next trigger level. However,
the RTS (or DTR) pin will return to a logic 0 after the receive buffer (FIFO) is unloaded to
the next trigger level below the programmed trigger level. Under the above described
conditions, the SC16C850SV will continue to accept data until the receive FIFO is full.
When TXINTLVL, RXINTLVL, FLWCNTH and FLWCNTL in the First Extra Register Set
are all zeroes, the hardware and software flow control trigger levels are set by FCR[7:4];
see Table5.
When either TXINTLVL, RXINTLVL, FLWCNTH or FLWCNTL in the First Extra Register
Set contains any value other than 0x00, the hardware and software flow control trigger
levels are set by FLWCNTH and FLWCNTL. The content in FLWCNTH determines how
many bytes are in the receive FIFO before RTS (or DTR) is de-asserted or Xoff is sent.
The content of FLWCNTL determines how many bytes are in the receive FIFO before
RTS (or DTR) is asserted, or Xon is sent.
In 128-byte FIFO mode, hardware and software flow control trigger levels can be set to
any value between 1 and 128 in granularity of 1. The value of FLWCNTH should always
be greater than FLWCNTL. The UART does not check for this condition automatically, and
if this condition is not met spurious operation of the device might occur. When using
FLWCNTH and FWLCNTL, these registers must be initialized to the proper values before
hardware or software flow control is enabled via the EFR register.
6.6 Software flow control

When software flow control is enabled, the SC16C850SV compares one or two
sequentially received data characters with the programmed Xon or Xoff character
value(s). If the received character(s) match the programmed Xoff values, the
SC16C850SV will halt transmission (TX) as soon as the current character(s) has
completed transmission. When a match occurs, ISR bit 4 will be set (if enabled via IER[5])
and the interrupt output pin (if receive interrupt is enabled) will be activated. Following a
suspension due to a match of the Xoff characters’ values, the SC16C850SV will monitor
the receive data stream for a match to the Xon1/Xon2 character value(s). If a match is
found, the SC16C850SV will resume operation and clear the flags (ISR[4]).
Reset initially sets the contents of the Xon/Xoff 8-bit flow control registers to a logic0.
Following reset, the user can write any Xon/Xoff value desired for software flow control.
Different conditions can be set to detect Xon/Xoff characters and suspend/resume
transmissions (see Table 24). When double 8-bit Xon/Xoff characters are selected, the
SC16C850SV compares two consecutive receive characters with two software flow
control 8-bit values (Xon1, Xon2, Xoff1, Xoff2) and controls TX transmissions accordingly.
Under the above described flow control mechanisms, flow control characters are not
placed (stacked) in the receive FIFO. When using software flow control, the Xon/Xoff
characters cannot be used for data transfer.
NXP Semiconductors SC16C850SV
Single UART with 128-byte FIFOs, IrDA, and XScale VLIO bus interface

In the event that the receive buffer is overfilling, the SC16C850SV automatically sends an
Xoff character (when enabled) via the serial TX output to the remote UART. The
SC16C850SV sends the Xoff1/Xoff2 characters as soon as the number of received data in
the receive FIFO passes the programmed trigger level. To clear this condition, the
SC16C850SV will transmit the programmed Xon1/Xon2 characters as soon as the
number of characters in the receive FIFO drops below the programmed trigger level.
6.7 Special character detect

A special character detect feature is provided to detect an 8-bit character when EFR[5] is
set. When an 8-bit character is detected, it will be placed on the user-accessible data
stack along with normal incoming RX data. This condition is selected in conjunction with
EFR[3:0] (see Table 24). Note that software flow control should be turned off when using
this special mode by setting EFR[3:0] to all zeroes.
The SC16C850SV compares each incoming receive character with Xoff2 data. If a match
occurs, the received data will be transferred to the FIFO, and ISR[4] will be set to indicate
detection of a special character. Although Table 7 “SC16C850SV internal registers” shows
Xon1, Xon2, Xoff1, Xoff2 with eight bits of character information, the actual number of bits
is dependent on the programmed word length. Line Control Register bits LCR[1:0] define
the number of character bits, that is, either 5 bits, 6 bits, 7 bits or 8 bits. The word length
selected by LCR[1:0] also determine the number of bits that will be used for the special
character comparison. Bit 0 in the Xon1, Xon2, Xoff1, Xoff2 registers corresponds with the
LSB bit for the received character.
6.8 Interrupt priority and time-out interrupts

The interrupts are enabled by IER[7:0]. Care must be taken when handling these
interrupts. Following a reset, if Interrupt Enable Register (IER) bit1= 1, the SC16C850SV
will issue a Transmit Holding Register interrupt. This interrupt must be serviced prior to
continuing operations. The ISR indicates the current singular highest priority interrupt
only. A condition can exist where a higher priority interrupt masks the lower priority
interrupt(s) (see Table 12). Only after servicing the higher pending interrupt will the lower
priority interrupt(s) be reflected in the status register. Servicing the interrupt without
investigating further interrupt conditions can result in data errors.
Receive Data Ready and Receive Time Out have the same interrupt priority (when
enabled by IER[0]), and it is important to serve these interrupts correctly. The receiver
issues an interrupt after the number of characters have reached the programmed trigger
level. In this case, the SC16C850SV FIFO may hold more characters than the
programmed trigger level. Following the removal of a data byte, the user should re-check
LSR[0] to see if there are any additional characters. A Receive Time Out will not occur if
the receive FIFO is empty. The time-out counter is reset at the center of each stop bit
received or each time the Receive Holding Register (RHR) is read. The actual time-out
value is 4 character time, including data information length, start bit, parity bit, and the size
of stop bit, that is, 1, 1.5, or 2 bit times.
NXP Semiconductors SC16C850SV
Single UART with 128-byte FIFOs, IrDA, and XScale VLIO bus interface
6.9 Programmable baud rate generator

The SC16C850SV UART contains a programmable rational baud rate generator that
takes any clock input and divides it by a divisor in the range between 1 and (216 1). The
SC16C850SV offers the capability of dividing the input frequency by rational divisor. The
fractional part of the divisor is controlled by the CLKPRES register in the First Extra
Register Set.
(1)
where:
N is the integer part of the divisor in DLL and DLM registers;
M is the fractional part of the divisor in CLKPRES register;
fXTAL1 is the clock frequency at XTAL1 pin;
SAMPR is the sampling rate in SAMPR register (16, 8, 4); M/ SAMPR should
always be less than 1.
Prescaler= 1 when MCR[7] is set to 0.
Prescaler= 4 when MCR[7] is set to 1.
A single baud rate generator is provided for the transmitter and receiver. The
programmable Baud Rate Generator is capable of operating with a frequency of up to MHz. To obtain maximum data rate, it is necessary to use full rail swing on the clock
input. The SC16C850SV can be configured for internal or external clock operation. For
internal clock operation, an industry standard crystal is connected externally between the
XTAL1 and XTAL2 pins (see Figure 4). Alternatively, an external clock can be connected
to the XTAL1 pin (see Figure 5) to clock the internal baud rate generator for standard or
custom rates (see Table6).
The generator divides the input 16 clock by any divisor from 1 to (216 1). The
SC16C850SV divides the basic external clock by 16. The baud rate is configured via the
CLKPRES, DLL and DLM internal register functions. Customized baud rates can be
achieved by selecting the proper divisor values for the MSB and LSB sections of baud
rate generator. However, the user can also select 8, 4 sampling rate to operate at four
times, or two times faster than the 16 sampling rate (see Section 7.20 “Sampling rate
(SAMPR)”).
NXP Semiconductors SC16C850SV
Single UART with 128-byte FIFOs, IrDA, and XScale VLIO bus interface

Programming the baud rate generator registers CLKPRES, DLM (MSB) and DLL (LSB)
provides a user capability for selecting the desired final baud rate. The example in Table6
shows the selectable baud rate table available when using a 1.8432 MHz external clock
input with MCR[7] is 0, SAMPR[1:0]= 00b, and CLKPRES = 0x00.
Table 6. Baud rate generator programming table using a 1.8432 MHz clock with
MCR[7]= 0, SAMPR[1:0]= 00b, and CLKPRE[3:0]=0
2304 900 09 00 1536 600 06 00
110 1047 417 04 17
150 768 300 03 00
300 384 180 01 80
600 192 C0 00 C0
1.2k 96 60 00 60
2.4k 48 30 00 30
3.6k 32 20 00 20
4.8k 24 18 00 18
7.2k 16 10 00 10
9.6k 12 0C 00 0C
19.2k 6 06 00 06
NXP Semiconductors SC16C850SV
Single UART with 128-byte FIFOs, IrDA, and XScale VLIO bus interface
6.10 Loopback mode

The internal loopback capability allows on-board diagnostics. In the Loopback mode, the
normal modem interface pins are disconnected and reconfigured for loopback internally
(see Figure 6). MCR[3:0] register bits are used for controlling loopback diagnostic testing.
In the Loopback mode, the transmitter output (TX) and the receiver input (RX) are
disconnected from their associated interface pins, and instead are connected together
internally. The CTS, DSR, CD, and RI are disconnected from their normal modem control
inputs pins, and instead are connected internally to RTS, DTR, MCR[3] (OP2) and MCR[2]
(OP1). Loopback test data is entered into the transmit holding register via the user data
bus interface, AD[7:0]. The transmit UART serializes the data and passes the serial data
to the receive UART via the internal loopback connection. The receive UART converts the
serial data back into parallel data that is then made available at the user data interface
AD[7:0]. The user optionally compares the received data to the initial transmitted data for
verifying error-free operation of the UART TX/RX circuits.
In this mode, the receiver and transmitter interrupts are fully operational. The modem
control interrupts are also operational.
38.4k 3 03 00 03
57.6k 2 02 00 02
115.2k 1 01 00 01
Table 6. Baud rate generator programming table using a 1.8432 MHz clock with
MCR[7]= 0, SAMPR[1:0]= 00b, and CLKPRE[3:0]= 0 …continued
NXP Semiconductors SC16C850SV
Single UART with 128-byte FIFOs, IrDA, and XScale VLIO bus interface
NXP Semiconductors SC16C850SV
Single UART with 128-byte FIFOs, IrDA, and XScale VLIO bus interface
6.11 Sleep mode

Sleep mode is an enhanced feature of the SC16C850SV UART. It is enabled when
EFR[4], the enhanced functions bit, is set and when IER[4] bit is also set.
6.11.1 Conditions to enter Sleep mode

Sleep mode is entered when: Modem input pins are not toggling. The serial data input line, RX, is idle for 4 character time (logic HIGH) and AFCR1[4]
is 0. When AFCR1[4] is 1, the device will go to sleep regardless of the state of the RX
pin (see Section 7.22 for the description of AFCR1 bit 4). The TX FIFO and TX shift register are empty. There are no interrupts pending. The RX FIFO is empty.
In Sleep mode, the UART clock and baud rate clock are stopped. Since most registers are
clocked using these clocks, the power consumption is greatly reduced.
Remark: Writing to the divisor latches, DLL and DLM, to set the baud clock, must not be

done during Sleep mode. Therefore, it is advisable to disable Sleep mode using IER[4]
before writing to DLL or DLM.
6.11.2 Conditions to resume normal operation

SC16C850SV resumes normal operation by any of the following: Receives a start bit on RX pin. Data is loaded into transmit FIFO. A change of state on any of the modem input pins.
If the device is awakened by one of the conditions described above, it will return to the
Sleep mode automatically after all the conditions described in Section 6.11.1 are met. The
device will stay in Sleep mode until it is disabled by setting any channel’s IER bit 4 to a
logic0.
When the SC16C850SV is in Sleep mode and the host interface bus (AD7to AD0, IOW,
IOR, CS) remains in steady state, either HIGH or LOW, the sleep current will be in the
microampere range as specified in Table 37 “Static characteristics”. If any of these signals
is toggling or floating then the sleep current will be higher.
6.12 Low power feature

A low power feature is provided by the SC16C850SV to prevent the switching of the host
data bus from influencing the sleep current. When the pin LOWPWR is activated (logic
HIGH), the device immediately and unconditionally goes into Low Power mode. All clocks
are stopped and most host interface pins are isolated to reduce power consumption. The
device only returns to normal mode when the LOWPWR pin is de-asserted. The pin can
be left unconnected because it has an internal pull-down resistor.
NXP Semiconductors SC16C850SV
Single UART with 128-byte FIFOs, IrDA, and XScale VLIO bus interface
6.13 RS-485 Features
6.13.1 Auto RS-485 RTS control

Normally the RTS pin is controlled by MCR bit 1, or if hardware flow control is enabled, the
logic state of the RTS pin is controlled by the hardware flow control circuitry. EFCR2
register bit 4 will take the precedence over the other two modes; once this bit is set, the
transmitter will control the state of the RTS pin. The transmitter automatically asserts the
RTS pin (logic 0) once the host writes data to the transmit FIFO, and de-asserts the RTS
pin (logic 1) once the last bit of the data has been transmitted.
To use the auto RS-485 RTS mode, the software would have to disable the hardware flow
control function.
6.13.2 RS-485 RTS inversion

EFCR2 bit 5 reverses the polarity of the RTS pin if the UART is in auto RS-485 RTS
mode.
When the transmitter has data to be sent, it will de-assert the RTS pin (logic 1), and when
the last bit of the data has been sent out, the transmitter asserts the RTS pin (logic0).
6.13.3 Auto 9-bit mode (RS-485)

EFCR2 bit 0 is used to enable the 9-bit mode (Multi-drop or RS-485 mode). In this mode
of operation, a ‘master’ station transmits an address character followed by data characters
for the addressed ‘slave’ stations. The slave stations examine the received data and
interrupt the controller if the received character is an address character (paritybit= 1).
To use the auto 9-bit mode the software would have to disable the hardware and software
flow control functions.
6.13.3.1 Normal Multi-drop mode

The 9-bit Mode in EFCR (bit 0) is enabled, but not Special Character Detect (EFR bit 5).
The receiver is set to Force Parity 0 (LCR[5:3] = 111) in order to detect address bytes.
With the receiver initially disabled, it ignores all the data bytes (paritybit= 0) until an
address byte is received (paritybit= 1). This address byte will cause the UART to set the
parity error. The UART will generate a line status interrupt (IER bit 2 must be set to ‘1’ at
this time), and at the same time puts this address byte in the RX FIFO. After the controller
examines the byte it must make a decision whether or not to enable the receiver; it should
enable the receiver if the address byte addresses its ID address, and must not enable the
receiver if the address byte does not address its ID address.
If the controller enables the receiver, the receiver will receive the subsequent data until
being disabled by the controller after the controller has received a complete message
from the ‘master’ station. If the controller does not disable the receiver after receiving a
message from the ‘master’ station, the receiver will generate a parity error upon receiving
another address byte. The controller then determines if the address byte addresses its ID
address, if it is not, the controller then can disable the receiver. If the address byte
addresses the ‘slave’ ID address, the controller take no further action, the receiver will
receive the subsequent data.
NXP Semiconductors SC16C850SV
Single UART with 128-byte FIFOs, IrDA, and XScale VLIO bus interface
6.13.3.2 Auto address detection

If Special Character Detect is enabled (EFR[5] is set and the Xoff2 register contains the
address byte), the receiver will try to detect an address byte that matches the
programmed character in the Xoff2 register. If the received byte is a data byte or an
address byte that does not match the programmed character in the Xoff2 register, the
receiver will discard these data. Upon receiving an address byte that matches the Xoff2
character, the receiver will be automatically enabled if not already enabled, and the
address character is pushed into the RX FIFO along with the parity bit (in place of the
parity error bit). The receiver also generates a line status interrupt (IER[2] must be set to
logic 1 at this time). The receiver will then receive the subsequent data from the ‘master’
station until being disabled by the controller after having received a message from the
‘master’ station.
If another address byte is received and this address byte does not match Xoff2 character,
the receiver will be automatically disabled and the address byte is ignored. If the address
byte matches Xoff2 character, the receiver will put this byte in the RX FIFO along with the
parity bit in the parity error bit (LSR bit2).
7. Register descriptions

Table 7 details the assigned bit functions for the SC16C850SV internal registers. The
assigned bit functions are more fully defined in Section 7.1 through Section 7.24.
xxx
xxx
xxxx
xxx
xxxx
xxx
xx
xxxx
xxx
xxxx
xxx
xxxx
xxx
xxx
xxx
xxx
x x
x
x x
xxxx
xxx
xxxx
xxx
xxxx
xxx
xxxx
xxx
x x
xxxx
xxx
xxx
xxxx
xxx
x xx
xx
xx
xxx
xxx
xxx
xxxx
xxx
xxxx
xxx
xxxx
xx
xxx
xxxx
xxx
xxxx
xxx
xx x
xxx
xx
xxxx
xxx
xxxx
xxx
xxxx
xxx
xxx
xxxx
xxx
xxxx
xx
xxxx
xxx
xxx
x x
xxx
xxx
xxxx
xxx
xxxx
xxx
xxx
xxx
xxx
xxxx
xxx
xxxx
xxx
xxxx
xxx
xx
xxx
xxx
xxxx
xxx
xxxx
xxx
xxx
xxxx
xxx
xxxx
xxx
xxxx
xxx
xxx
xxxx
xx
xxxx
xxx
xxx
xxx
xxxx
xxx
xxxx
xxx
xxxx
xx
xxx
xxxx
xxx
xxxx
xxx
x xx
NXP Semiconductors SC16C850SV
Single UART with 128-byte FIFOs, IrDA, and XScale VLIO bus interface
ble 7.
SC1
C85
SV
inte
rna
re
gisters
l reg
ister se
ial re
gister
con
sp
ial reg
er set
xxx
xxx
xxxx
xxx
xxxx
xxx
xx
xxxx
xxx
xxxx
xxx
xxxx
xxx
xxx
xxx
xxx
x x
x
x x
xxxx
xxx
xxxx
xxx
xxxx
xxx
xxxx
xxx
x x
xxxx
xxx
xxx
xxxx
xxx
x xx
xx
xx
xxx
xxx
xxx
xxxx
xxx
xxxx
xxx
xxxx
xx
xxx
xxxx
xxx
xxxx
xxx
xx x
xxx
xx
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xxx
xxxx
xxx
xxx
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xxx
xxx
x x
xxx
xxx
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xxx
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xxx
xxx
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xxx
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xxx
xxx
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xx
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xxx
xxxx
xxx
xxxx
xxx
x xx
NXP Semiconductors SC16C850SV
Single UART with 128-byte FIFOs, IrDA, and XScale VLIO bus interface

he va
lue shown
repre
ent
s the
register
in
itialize
d hexadecimal value; X
not a
pplicable.
ccessible only
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[7] is
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his bit is only a
cessible
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aud r
te reg
isters accessible only when LCR
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econd special registers are
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only when
CR[0]
, and EFC
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e log
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Register
, Xon
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, and EF
CR[2:1] ar
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set is only a
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econd extra r
egister
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[2:1] = 10b.
he SAMP
register must be pr
ogrammed
before th
e LCR r
egister
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ed re
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irst
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tra reg
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ble 7.
SC1
C85
SV
inte
rna
re
gisters

…contin
ued
NXP Semiconductors SC16C850SV
Single UART with 128-byte FIFOs, IrDA, and XScale VLIO bus interface
7.1 Transmit and Receive Holding Registers (THR and RHR)

The serial transmitter section consists of an 8-bit Transmit Holding Register (THR) and
Transmit Shift Register (TSR). The status of the THR is provided in the Line Status
Register (LSR). Writing to the THR transfers the contents of the data bus (AD7to AD0) to
the transmit FIFO. The THR empty flag in the LSR will be set to a logic 1 when the
transmit FIFO is empty or when data is transferred to the TSR.
The serial receive section also contains an 8-bit Receive Holding Register (RHR) and a
Receive Serial Shift Register (RSR). Receive data is removed from the SC16C850SV
receive FIFO by reading the RHR. The receive section provides a mechanism to prevent
false starts. On the falling edge of a start or false start bit, an internal receiver counter
starts counting clocks at the sampling rate. After SAMPR ⁄2 clocks (SAMPR is the sampling
rate of 16, 8, or 4), the start bit time should be shifted to the center of the start bit. At
this time the start bit is sampled, and if it is still a logic 0 it is validated. Evaluating the start
bit in this manner prevents the receiver from assembling a false character. Receiver status
codes will be posted in the LSR.
7.2 Interrupt Enable Register (IER)

The Interrupt Enable Register (IER) masks the interrupts from receiver ready, transmitter
empty, line status and modem status registers. These interrupts would normally be seen
on the INT output pin. Table 8. Interrupt Enable Register bits description IER[7] CTS interrupt.
logic0= disable the CTS interrupt (normal default condition)
logic1= enable the CTS interrupt. The SC16C850SV issues an interrupt when
the CTS pin transitions from a logic 0 to a logic1. IER[6] RTS interrupt.
logic0= disable the RTS interrupt (normal default condition)
logic1= enable the RTS interrupt. The SC16C850SV issues an interrupt when
the RTS pin transitions from a logic 0 to a logic1. IER[5] Xoff interrupt.
logic0= disable the software flow control, receive Xoff interrupt (normal default
condition)
logic1= enable the receive Xoff interrupt IER[4] Sleep mode.
logic0= disable Sleep mode (normal default condition)
logic1= enable Sleep mode IER[3] Modem Status Interrupt. This interrupt will be issued whenever there is a modem
status change as reflected in MSR[3:0].
logic0= disable the modem status register interrupt (normal default condition)
logic1= enable the modem status register interrupt IER[2] Receive Line Status interrupt. This interrupt will be issued whenever a receive
data error condition exists as reflected in LSR[4:1].
logic0= disable the receiver line status interrupt (normal default condition)
logic1= enable the receiver line status interrupt
NXP Semiconductors SC16C850SV
Single UART with 128-byte FIFOs, IrDA, and XScale VLIO bus interface
7.2.1 IER versus transmit/receive FIFO interrupt mode operation

When the receive FIFO is enabled (FCR[0]= logic 1), and receive interrupts
(IER[0]= logic 1) are enabled, the receive interrupts and register status will reflect the
following: The receive RXRDY interrupt (Level 2 ISR interrupt) is issued to the external CPU
when the receive FIFO has reached the programmed trigger level. It will be cleared
when the receive FIFO drops below the programmed trigger level. Receive FIFO status will also be reflected in the user accessible ISR register when
the receive FIFO trigger level is reached. Both the ISR register receive status bit and
the interrupt will be cleared when the FIFO drops below the trigger level. The receive data ready bit (LSR[0]) is set as soon as a character is transferred from
the shift register (RSR) to the receive FIFO. It is reset when the FIFO is empty. When the Transmit FIFO and interrupts are enabled, an interrupt is generated when
the transmit FIFO is empty due to the unloading of the data by the TSR and UART for
transmission via the transmission media. The interrupt is cleared either by reading the
ISR, or by loading the THR with new data characters.
7.2.2 IER versus receive/transmit FIFO polled mode operation

When FCR[0]= logic 1, setting IER[3:0]= zeroes puts the SC16C850SV in the FIFO
polled mode of operation. In this mode, interrupts are not generated and the user must
poll the LSR register for TX and/or RX data status. Since the receiver and transmitter have
separate bits in the LSR either or both can be used in the polled mode by selecting
respective transmit or receive control bit(s). LSR[0] will be a logic 1 as long as there is one byte in the receive FIFO. LSR[4:1] will provide the type of receive errors, or a receive break, if encountered. LSR[5] will indicate when the transmit FIFO is empty. LSR[6] will indicate when both the transmit FIFO and transmit shift register are empty. LSR[7] will show if any FIFO data errors occurred. IER[1] Transmit Holding Register interrupt. In the non-FIFO mode, this interrupt will be
issued whenever the THR is empty, and is associated with LSR[5]. In the FIFO
modes, this interrupt will be issued whenever the FIFO is empty.
logic0= disable the Transmit Holding Register Empty (TXRDY) interrupt
(normal default condition)
logic1= enable the TXRDY (ISR level 3) interrupt IER[0] Receive Holding Register. In the non-FIFO mode, this interrupt will be issued
when the RHR has data, or is cleared when the RHR is empty. In the FIFO mode,
this interrupt will be issued when the FIFO has reached the programmed trigger
level or is cleared when the FIFO drops below the trigger level.
logic0= disable the receiver ready (ISR level 2, RXRDY) interrupt (normal
default condition)
logic1= enable the RXRDY (ISR level 2) interrupt
Table 8. Interrupt Enable Register bits description …continued
NXP Semiconductors SC16C850SV
Single UART with 128-byte FIFOs, IrDA, and XScale VLIO bus interface
7.3 FIFO Control Register (FCR)

This register is used to enable the FIFOs, clear the FIFOs and set the receive FIFO trigger
levels.
7.3.1 FIFO mode

[1] For 128-byte FIFO mode, refer to Section 7.16, Section 7.17, Section 7.18.
[2] For 128-byte FIFO mode, refer to Section 7.15, Section 7.17, Section 7.18.
[1] When RXINTLVL or TXINTLVL or FLWCNTH or FLWCNTL contains any value other than 0x00, receive and
transmit trigger levels are set by RXINTLVL, TXINTLVL; see Section 6.4 “FIFO operation”.
Table 9. FIFO Control Register bits description

7:6 FCR[7:6] Receive trigger level in 32-byte FIFO mode.[1]
These bits are used to set the trigger level for receive FIFO interrupt and flow
control. The SC16C850SV will issue a receive ready interrupt when the number
of characters in the receive FIFO reaches the selected trigger level. Refer to
Table 10.
5:4 FCR[5:4] Transmit trigger level in 32-byte FIFO mode.[2]
These bits are used to set the trigger level for the transmit FIFO interrupt and
flow control. The SC16C850SV will issue a transmit empty interrupt when the
number of characters in FIFO drops below the selected trigger level. Refer to
Table11. FCR[3] reserved FCR[2] XMIT FIFO reset.
logic0= no FIFO transmit reset (normal default condition)
logic1= clears the contents of the transmit FIFO and resets the FIFO counter
logic. This bit will return to a logic 0 after clearing the FIFO. FCR[1] RCVR FIFO reset.
logic0= no FIFO receive reset (normal default condition)
logic1= clears the contents of the receive FIFO and resets the FIFO counter
logic. This bit will return to a logic 0 after clearing the FIFO. FCR[0] FIFO enable.
logic0= disable the transmit and receive FIFO (normal default condition)
logic1= enable the transmit and receive FIFO
Table 10. RCVR trigger levels
0 8 bytes 1 16 bytes 0 24 bytes 1 28 bytes
NXP Semiconductors SC16C850SV
Single UART with 128-byte FIFOs, IrDA, and XScale VLIO bus interface

[1] When RXINTLVL or TXINTLVL or FLWCNTH or FLWCNTL contains any value other than 0x00, receive and
transmit trigger levels are set by RXINTLVL, TXINTLVL; see Section 6.4 “FIFO operation”.
7.4 Interrupt Status Register (ISR)

The SC16C850SV provides six levels of prioritized interrupts to minimize external
software interaction. The Interrupt Status Register (ISR) provides the user with six
interrupt status bits. Performing a read cycle on the ISR will provide the user with the
highest pending interrupt level to be serviced. No other interrupts are acknowledged until
the pending interrupt is serviced. A lower level interrupt may be seen after servicing the
higher level interrupt and re-reading the interrupt status bits. Table 12 “Interrupt source”
shows the data values (bits 5:0) for the six prioritized interrupt levels and the interrupt
sources associated with each of these interrupt levels.
Table 11. TX FIFO trigger levels
0 16 bytes 1 8 bytes 0 24 bytes 1 30 bytes
Table 12. Interrupt source
000110 LSR (Receiver Line Status Register) 000100 RXRDY (Received Data Ready) 001100 RXRDY (Receive Data time-out) 000010 TXRDY (Transmitter Holding
Register Empty) 000000 MSR (Modem Status Register) 010000 RXRDY (Received Xoff signal)/
Special character 100000 CTS, RTS change of state
Table 13. Interrupt Status Register bits description

7:6 ISR[7:6] FIFOs enabled. These bits are set to a logic 0 when the FIFOs are not being
used in the non-FIFO mode. They are set to a logic 1 when the FIFOs are
enabled in the SC16C850SV mode.
logic 0 or cleared= default condition
5:4 ISR[5:4] INT priority bits 4:3. These bits are enabled when EFR[4] is set to a logic1.
ISR[4] indicates that matching Xoff character(s) have been detected. ISR[5]
indicates that CTS, RTS have been generated. Note that once set to a
logic 1, the ISR[4] bit will stay a logic 1 until Xon character(s) are received.
logic 0 or cleared= default condition
3:1 ISR[3:1] INT priority bits 2:0. These bits indicate the source for a pending interrupt at
interrupt priority levels 1, 2, and 3 (see Table 12).
logic 0 or cleared= default condition
NXP Semiconductors SC16C850SV
Single UART with 128-byte FIFOs, IrDA, and XScale VLIO bus interface
7.5 Line Control Register (LCR)

The Line Control Register is used to specify the asynchronous data communication
format. The word length, the number of stop bits, and the parity are selected by writing the
appropriate bits in this register. ISR[0] INT status.
logic0= an interrupt is pending and the ISR contents may be used as a
pointer to the appropriate interrupt service routine
logic1= no interrupt pending (normal default condition)
Table 13. Interrupt Status Register bits description …continued
Table 14. Line Control Register bits description
LCR[7] Divisor latch enable. The internal baud rate counter latch and Enhanced Feature mode enable.
logic0 = divisor latch disabled (normal default condition)
logic1= divisor latch enabled LCR[6] Set break. When enabled, the Break control bit causes a break condition to be transmitted (the TX output is forced to a logic 0 state). This condition exists
until disabled by setting LCR[6] to a logic0.
logic0= no TX break condition (normal default condition)
logic1= forces the transmitter output (TX) to a logic 0 for alerting the
remote receiver to a line break condition
5:3 LCR[5:3] Programs the parity conditions (see Table 15). LCR[2] Stop bits. The length of stop bit is specified by this bit in conjunction with the
programmed word length (see Table 16).
logic 0 or cleared= default condition
1:0 LCR[1:0] Word length bits 1, 0. These two bits specify the word length to be transmitted
or received (see Table 17).
logic 0 or cleared= default condition
Table 15. LCR[5:3] parity selection
X 0 no parity 0 1 odd parity 1even parity 1forced parity ‘1’ 1forced parity ‘0’
Table 16. LCR[2] stop bit length
5, 6, 7, 8 1 11⁄2 6, 7, 8 2
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