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SC28L91A1BNXPN/a458avai3.3 V or 5.0 V Universal Asynchronous Receiver/Transmitter (UART)


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SC28L91A1B
3.3 V or 5.0 V Universal Asynchronous Receiver/Transmitter (UART)
Product data sheet
Supersedes data of 2000 Sep 22
2004 Oct 21
Philips Semiconductors Product data sheet
SC28L913.3 V or 5.0 V Universal Asynchronous
Receiver/Transmitter (UART)
DESCRIPTION

The SC28L91 is a new member of the IMPACT family of Serial
Communications Controllers. It is a single channel UART operating
at 3.3 V and 5.0 V VCC, 8 or 16 byte FIFOs and is quite compatible
with software of the SC28L92 and previous UARTs offered by
Philips. It is a new part that is similar to our previous one channel
part but is vastly improved. The improvements being: 16 character
receiver, 16 character transmit FIFOs, watch dog timer for the
receiver, mode register 0 is added, extended baud rate, over all
faster bus and data speeds, programmable receiver and transmitter
interrupts and versatile I/O structure. (The previous one channel
part, SCC2691, is NOT being discontinued.)
Pin programming will allow the device to operate with either the
Motorola or Intel bus interface. Bit 3 of the MR0 register allows the
device to operate in an 8-byte FIFO mode if strict compliance with
an 8-byte FIFO structure is required.
The Philips Semiconductors SC28L91 Universal Asynchronous
Receiver/Transmitter (UART) is a single-chip CMOS-LSI
communications device that provides a full-duplex asynchronous
receiver/transmitter channel in a single package. It interfaces
directly with microprocessors and may be used in a polled or
interrupt driven system with modem and DMA interface.
The operating mode and data format of the channel can be
programmed independently. Additionally, the receiver and
transmitter can select its operating speed as one of 28 fixed baud
rates; a 16X clock derived from a programmable counter/timer, or an
external 1X or 16X clock. The baud rate generator and counter/timer
can operate directly from a crystal or from external clock inputs. The
ability to independently program the operating speed of the receiver
and transmitter make the UART particularly attractive for dual-speed
channel applications such as clustered terminal systems.
The receiver and transmitter is buffered by 8 or 16 character FIFOs
to minimize the potential of receiver overrun, transmitter underrun
and to reduce interrupt overhead in interrupt driven systems. In
addition, a flow control capability is provided via RTS/CTS signaling
to disable a remote transmitter when the receiver buffer is full.
DMA interface is and other general purpose signals are provided on
the SC28L91 via a multipurpose 7-bit input port and a multipurpose
8-bit output port. These can be used as general-purpose ports or
can be assigned specific functions (such as clock inputs or
status/interrupt outputs, FIFO conditions) under program control.
The SC28L91 is available in two package versions: a 44-pin PLCC
and 44-pin plastic quad flat pack (PQFP).
FEATURES
Member of IMPACT family: 3.3 to 5.0 volt , –40°C to +85°C and
68K for 80xxx bus interface for all devices. A full-duplex independent asynchronous receiver/transmitter 16 character FIFOs for each receiver and transmitter Pin programming selects 68K or 80xxx-bus interface Programmable data format 5 to 8 data bits plus parity Odd, even, no parity or force parity 16-bit programmable Counter/Timer Programmable baud rate for each receiver and transmitter
selectable from: 28 fixed rates: 50 to 230.4 k baud Other baud rates to 1 MHz at 16X Programmable user-defined rates derived from a programmable
counter/timer External 1X or 16X clock Parity, framing, and overrun error detection False start bit detection Line break detection and generation Programmable channel mode Normal (full-duplex) Automatic echo Local loop back Remote loop back Multi-drop mode (also called ‘wake-up’ or ‘9-bit’) Multi-function 7-bit input port (includes IACKN) Can serve as clock or control inputs Change of state detection on four inputs Inputs have typically >100 kΩ pull-up resistors Change of state detectors for modem control Multi-function 8-bit output port Individual bit set/reset capability Outputs can be programmed to be status/interrupt signals FIFO status for DMA interface Versatile interrupt system Single interrupt output with eight maskable interrupting
conditions Output port can be configured to provide a total of up to six
separate interrupt outputs that may be wire ORed. Each FIFO can be programmed for four different interrupt levels Watchdog timer for the receiver Maximum data transfer rates:
1X – 1 Mbit/s, 16X – 1 Mbit/s Automatic wake-up mode for multi-drop applications Start-end break interrupt/status with mid-character break detect. On-chip crystal oscillator Power-down mode Receiver time-out mode Single +3.3 V or +5 V power supply
Philips Semiconductors Product data sheet
SC28L913.3 V or 5.0 V Universal Asynchronous
Receiver/Transmitter (UART)
ORDERING INORMATION

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Philips Semiconductors Product data sheet
SC28L913.3 V or 5.0 V Universal Asynchronous
Receiver/Transmitter (UART)
PIN CONFIGURATION DIAGRAM
80XXX PIN CONFIGURATION

Note: Pins marked “No Connection” must NOT be connected.
Philips Semiconductors Product data sheet
SC28L913.3 V or 5.0 V Universal Asynchronous
Receiver/Transmitter (UART)
PIN CONFIGURATION DIAGRAM
68XXX PIN CONFIGURATION

Note: Pins marked “No Connection” must NOT be connected.
Philips Semiconductors Product data sheet
SC28L913.3 V or 5.0 V Universal Asynchronous
Receiver/Transmitter (UART)
Figure 1. Block Diagram (80XXX mode)
Philips Semiconductors Product data sheet
SC28L913.3 V or 5.0 V Universal Asynchronous
Receiver/Transmitter (UART)
Figure 2. Block Diagram (68XXX mode)
Philips Semiconductors Product data sheet
SC28L913.3 V or 5.0 V Universal Asynchronous
Receiver/Transmitter (UART)
PIN CONFIGURATION FOR 80XXX BUS INTERFACE (INTEL)
Philips Semiconductors Product data sheet
SC28L913.3 V or 5.0 V Universal Asynchronous
Receiver/Transmitter (UART)
PIN CONFIGURATION FOR 68XXX BUS INTERFACE (MOTOROLA
)
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Philips Semiconductors Product data sheet
SC28L913.3 V or 5.0 V Universal Asynchronous
Receiver/Transmitter (UART)
ABSOLUTE MAXIMUM RATINGS1
NOTES:
Stresses above those listed under Absolute Maximum Ratings may cause permanent damage to the device. This is a stress rating only and
functional operation of the device at these or any other condition above those indicated in the operation section of this specification is not
implied. For operating at elevated temperatures, the device must be derated based on +150°C maximum junction temperature. This product includes circuitry specifically designed for the protection of its internal devices from damaging effects of excessive static
charge. Nonetheless, it is suggested that conventional precautions be taken to avoid applying any voltages larger than the rated maxima. Parameters are valid over specified temperature and voltage range.
DC ELECTRICAL CHARACTERISTICS1, 2, 3

VCC = 5 V ± 10 %, Tamb = –40 °C to +85 °C, unless otherwise specified.
NOTES:
Parameters are valid over specified temperature and voltage range. All voltage measurements are referenced to ground (GND). For testing, all inputs swing between 0.4 V and 3.0 V with a transition time of
5 ns maximum. For X1/CLK, this swing is between 0.4 V and 0.8VCC. All time measurements are referenced at input voltages of 0.8 V and
2.0 V and output voltages of 0.8 V and 2.0 V, as appropriate. Typical values are at +25 °C, typical supply voltages, and typical processing parameters. Test conditions for outputs: CL = 125 pF, except open drain outputs. Test conditions for open drain outputs: CL = 125 pF,
constant current source = 2.6 mA. Input port pins have active pull-up transistors that will source a typical 2 μA from VCC when the input pins are at VSS.
Philips Semiconductors Product data sheet
SC28L913.3 V or 5.0 V Universal Asynchronous
Receiver/Transmitter (UART)
DC ELECTRICAL CHARACTERISTICS1, 2, 3

VCC = 3.3 V ± 10 %, Tamb = –40 °C to +85 °C, unless otherwise specified.
NOTES:
Parameters are valid over specified temperature and voltage range. All voltage measurements are referenced to ground (GND). For testing, all inputs swing between 0.4 V and 3.0 V with a transition time of
5 ns maximum. For X1/CLK, this swing is between 0.4 V and 0.8*VCC. All time measurements are referenced at input voltages of 0.8 V and
2.0 V and output voltages of 0.8 V and 2.0 V, as appropriate. Typical values are at +25 °C, typical supply voltages, and typical processing parameters. Test conditions for outputs: CL = 125 pF, except open drain outputs. Test conditions for open drain outputs: CL = 125 pF,
constant current source = 2.6 mA. Input port pins have active pull-up transistors that will source a typical 2 μA from VCC when the input pins are at VSS.
Input port pins at VCC source 0.0 μA. All outputs are disconnected. Inputs are switching between CMOS levels of VCC– 0.2 V and VSS + 0.2 V.
Philips Semiconductors Product data sheet
SC28L913.3 V or 5.0 V Universal Asynchronous
Receiver/Transmitter (UART)
AC CHARACTERISTICS (5 VOLT) 1, 2, 3, 4

VCC = 5.0 V ± 10 %, Tamb = –40 °C to +85 °C, unless otherwise specified.
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Philips Semiconductors Product data sheet
SC28L913.3 V or 5.0 V Universal Asynchronous
Receiver/Transmitter (UART)
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NOTES:
Parameters are valid over specified temperature and voltage range. All voltage measurements are referenced to ground (GND). For testing, all inputs swing between 0.4 V and 3.0 V with a transition time of
5 ns maximum. For X1/CLK this swing is between 0.4 V and 0.8*VCC. All time measurements are referenced at input voltages of 0.8 V and
2.0 V and output voltages of 0.8 V and 2.0 V, as appropriate. Test conditions for outputs: CL = 125 pF, except open drain outputs. Test conditions for open drain outputs: CL = 125 pF,
constant current source = 2.6 mA. Typical values are the average values at +25 °C and 5 V. Timing is illustrated and referenced to the WRN and RDN Inputs. Also, CEN may be the “strobing” input. CEN and RDN (also CEN and
WRN) are ORed internally. The signal asserted last initiates the cycle and the signal negated first terminates the cycle. Guaranteed by characterization of sample units. If CEN is used as the “strobing” input, the parameter defines the minimum High times between one CEN and the next. The RDN signal must
be negated for tRWD to guarantee that any status register changes are valid. Minimum frequencies are not tested but are guaranteed by design. Clocks for 1X mode should maintain a 60/40 duty cycle or better.
10. Minimum DACKN time is tDCR = tDSC + tDCR + two positive edges of the X1 clock. For faster bus cycles, the 80XXX bus timing may be used
while in the 68XXX mode. It is not necessary to wait for DACKN to insure the proper operation of the SC28C91. In all cases the data will be
written to the SC28L91 on the falling edge of DACKN or the rise of CEN. The fall of CEN initializes the bus cycle. The rise of CEN ends the
bus cycle. DACKN low or CEN high completes the write cycle.
NOTES:

Bus cycle times:
(80XXX mode): tDD + tRWD = 70 ns @ 5V, 40 ns @ 3.3 V + rise and fall time of control signals
(68XXX mode) = tCSC + tDAT + 1 cycle of the X1 clock @ 5 V + rise and fall time of control signals
Philips Semiconductors Product data sheet
SC28L913.3 V or 5.0 V Universal Asynchronous
Receiver/Transmitter (UART)
AC CHARACTERISTICS (3.3 VOLT) 1, 2, 3, 4

VCC = 3.3 V ± 10 %, Tamb = –40 °C to +85 °C, unless otherwise specified.
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Philips Semiconductors Product data sheet
SC28L913.3 V or 5.0 V Universal Asynchronous
Receiver/Transmitter (UART)
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NOTES:
Parameters are valid over specified temperature and voltage range. All voltage measurements are referenced to ground (GND). For testing, all inputs swing between 0.4 V and 3.0 V with a transition time of
5 ns maximum. For X1/CLK this swing is between 0.4 V and 0.8*VCC. All time measurements are referenced at input voltages of 0.8 V and
2.0 V and output voltages of 0.8 V and 2.0 V, as appropriate. Test conditions for outputs: CL = 125 pF, except open drain outputs. Test conditions for open drain outputs: CL = 125 pF,
constant current source = 2.6 mA. Typical values are the average values at +25 °C and 3.3 V. Timing is illustrated and referenced to the WRN and RDN Inputs. Also, CEN may be the “strobing” input. CEN and RDN (also CEN and
WRN) are ORed internally. The signal asserted last initiates the cycle and the signal negated first terminates the cycle. Guaranteed by characterization of sample units. If CEN is used as the “strobing” input, the parameter defines the minimum High times between one CEN and the next. The RDN signal must
be negated for tRWD to guarantee that any status register changes are valid. Minimum frequencies are not tested but are guaranteed by design. Clocks for 1X mode should maintain a 60/40 duty cycle or better.
10. Minimum DACKN time is tDCR = tDSC + tDCR + two positive edges of the X1 clock. For faster bus cycles, the 80XXX bus timing may be used
while in the 68XXX mode. It is not necessary to wait for DACKN to insure the proper operation of the SC28C91. In all cases the data will be
written to the SC28L91 on the falling edge of DACKN or the rise of CEN. The fall of CEN initializes the bus cycle. The rise of CEN ends the
bus cycle. DACKN low or CEN high completes the write cycle.
Philips Semiconductors Product data sheet
SC28L913.3 V or 5.0 V Universal Asynchronous
Receiver/Transmitter (UART)
Block Diagram

The SC28L91 UART consists of the following seven major sections:
data bus buffer, operation control, interrupt control, timing, Rx and
Tx FIFO Buffers, input port and output port control. Refer to the
Block Diagram.
Data Bus Buffer

The data bus buffer provides the interface between the external and
internal data buses. It is controlled by the operation control block to
allow read and write operations to take place between the controlling
CPU and the UART.
Operation Control

The operation control logic receives operation commands from the
CPU and generates appropriate signals to internal sections to
control device operation. It contains address decoding and read and
write circuits to permit communications with the microprocessor via
the data bus.
Interrupt Control

A single active-Low interrupt output (INTRN) is provided which is
activated upon the occurrence of any of eight internal events.
Associated with the interrupt system are the Interrupt Mask Register
(IMR) and the Interrupt Status Register (ISR). The IMR can be
programmed to select only certain conditions to cause INTRN to be
asserted. The ISR can be read by the CPU to determine all currently
active interrupting conditions. Outputs OP3–OP7 can be
programmed to provide discrete interrupt outputs for the transmitter,
receiver, and counter/timer. Programming the OP3 to OP7 pins as
interrupts causes their output buffers to change to an open drain
active low configuration. The OP pins may be used for DMA and
modem control as well. (See output port notes).
FIFO Configuration

Each receiver and transmitter has a 16 byte FIFO. These FIFOs
may be configured to operate at a fill capacity of either 8 or 16 bytes.
This feature may be used if it is desired to operate the 28L91 in
close compliance to 26C92 software. The 8-byte/16-byte mode is
controlled by the MR0[3] bit. A 0 value for this bit sets the 8-bit mode
( the default); a 1 sets the 16-byte mode.
The FIFO fill interrupt level automatically follow the programming of
the MR0[3] bit. See Tables 3 and 4.
68XXX mode

When the I/M pin is connected to VSS (ground), the operation of the
SC28L91 switches to the bus interface compatible with the Motorola
bus interfaces. Several of the pins change their function as follows: IP6 becomes IACKN input RDN becomes DACKN WRN becomes R/WN
The interrupt vector is enabled and the interrupt vector will be placed
on the data bus when IACKN is asserted low. The interrupt vector
register is located at address 0xC. The contents of this register are
set to 0x0F on the application of RESETN.
The generation of DACKN uses two positive edges of the X1 clock
as the DACKN delay from the falling edge of CEN. If the CEN is
withdrawn before two edges of the X1 clock occur, the
TIMING CIRCUITS
Crystal Clock

The timing block consists of a crystal oscillator, a baud rate
generator, a programmable 16-bit counter/timer, and four clock
selectors. The crystal oscillator operates directly from a crystal
connected across the X1/CLK and X2 inputs. If an external clock of
the appropriate frequency is available, it may be connected to
X1/CLK. The clock serves as the basic timing reference for the Baud
Rate Generator (BRG), the counter/timer, and other internal circuits.
A clock signal within the limits specified in the specifications section
of this data sheet must always be supplied to the UART. If an
external clock is used instead of a crystal, X1 should be driven using
a configuration similar to the one in Figure 11. X2 should be open or
driving a nominal gate load. Nominal crystal rate is 3.6864 MHz.
Rates up to 8 MHz may be used.
BRG

The baud rate generator operates from the oscillator or external
clock input and is capable of generating 28 commonly used data
communications baud rates ranging from 50 to 38.4 K baud.
Programming bit 0 of MR0 to a “1” gives additional baud rates of
57.6 kB, 115.2 kB and 230.4 kB (500 kHz with X1 at 8.0 MHz).
These will be in the 16X mode. A 3.6864 MHz crystal or external
clock must be used to get the standard baud rates. The clock
outputs from the BRG are at 16X the actual baud rate. The
counter/timer can be used as a timer to produce a 16X clock for any
other baud rate by counting down the crystal clock or an external
clock. The four clock selectors allow the independent selection, for
the receiver and transmitter, of any of these baud rates or external
timing signal.
Counter/Timer

The counter timer is a 16-bit programmable divider that operates in
one of three modes: counter, timer, and time out. In the timer mode it
generates a square wave. In the counter mode it generates a time
delay. In the time out mode it monitors the time between received
characters. The C/T uses the numbers loaded into the
Counter/Timer Lower Register (CTLR) and the Counter/Timer Upper
Register (CTUR) as its divisor.
The counter/timer clock source and mode of operation (counter or
timer) is selected by the Auxiliary Control Register bits 6 to 4
(ACR[6:4]). The output of the counter/timer may be used for a baud
rate and/or may be output to the OP pins for some external function
that may be totally unrelated to data transmission. The counter/timer
also sets the counter/timer ready bit in the Interrupt Status Register
(ISR) when its output transitions from 1 to 0. A register read address
(see Table 1) is reserved to issue a start counter/timer command
and a second register read address is reserved to issue a stop
command. The value of D[7:0] is ignored. The START command
always loads the contents of CTUR, CTLR to the counting registers.
The STOP command always resets the ISR[3] bit in the interrupt
status register.
Timer Mode

In the timer mode a symmetrical square wave is generated whose
half period is equal in time to division of the selected counter/timer
clock frequency by the 16-bit number loaded in the CTLR CTUR.
Thus, the frequency of the counter/timer output will be equal to the
counter/timer clock frequency divided by twice the value of the
Philips Semiconductors Product data sheet
SC28L913.3 V or 5.0 V Universal Asynchronous
Receiver/Transmitter (UART)
This continues regardless of issuance of the stop counter command.
ISR[3] is reset by the stop counter command.
NOTE: Reading of the CTU and CTL registers in the timer mode is
not meaningful. When the C/T is used to generate a baud rate and
the C/T is selected through the CSR then the receiver and/or
transmitter will be operating in the 16x mode. Calculation for the
number ‘n’ to program the counter timer upper and lower registers is
shown below.� c�tclock rate*16* Baud rate
Often this division will result in a non-integer number; 26.3 for
example. One can only program integer numbers to a digital divider.
Therefore 26 would be chosen. This gives a baud rate error of
0.3/26.3 which is 1.14%; well within the ability of the asynchronous
mode of operation.
Counter Mode

In the counter mode the counter/timer counts the value of the CTLR
CTUR down to zero and then sets the ISR[3] bit and sets the
counter/timer output from 1 to 0. It then rolls over to 65,365 and
continues counting with no further observable effect. Reading the
C/T in the counter mode outputs the present state of the C/T. If the
C/T is not stopped, a read of the C/T may result in changing data on
the data bus.
Timeout Mode

The timeout mode uses the received data stream to control the
counter. The time-out mode forces the C/T into the timer mode.
Each time a received character is transferred from the shift register
to the RxFIFO, the counter is restarted. If a new character is not
received before the counter reaches zero count, the counter ready
bit is set, and an interrupt can be generated. This mode can be used
to indicate when data has been left in the Rx FIFO for more than the
programmed time limit. If the receiver has been programmed to
interrupt the CPU when the receive FIFO is full, and the message
ends before the FIFO is full, the CPU will not be interrupted for the
remaining characters in the RxFIFO.
By programming the C/T such that it would time out in just over one
character time, the above situation could be avoided. The processor
would be interrupted any time the data stream had stopped for more
than one character time. NOTE: This is very similar to the watch dog
timer of MR0. The difference is in the programmability of the delay
timer and that this indicates that the data stream has stopped. The
watchdog timer is more of an indicator that data is in the FIFO is not
enough to cause an interrupt. The watchdog is restarted by either a
receiver load to the RxFIFO or a system read from it.
This mode is enabled by writing the appropriate command to the
command register. Writing an ‘0xAn’ to CR will invoke the timeout
mode for that channel. Writing a ‘Cx’ to CR will disable the timeout
mode. The timeout mode disables the regular START/STOP counter
commands and puts the C/T into counter mode under the control of
the received data stream. Each time a received character is
transferred from the shift register to the RxFIFO, the C/T is stopped
after one C/T clock, reloaded with the value in CTUR and CTLR and
then restarted on the next C/T clock. If the C/T is allowed to end the
count before a new character has been received, the counter ready
Bit, ISR[3], will be set. If IMR[3] is set, this will generate an interrupt.
ISR [3], and the interrupt. Invoking the ‘Set Timeout Mode On’
command, CRx = 0xAn, will also clear the counter ready bit and stop
the counter until the next character is received. The counter timer is
controlled with six commands: Start/Stop C/T, Read/Write
Counter/Timer lower register and Read/Write Counter/Timer upper
register. These commands have slight differences depending on the
mode of operation. Please see the detail of the commands under the
CTLR CTUR Register descriptions.
Time Out Mode Caution

When operating in the special time out mode it is possible to
generate what appears to be a “false interrupt”, i.e. an interrupt
without a cause. This may result when a time-out interrupt occurs
and then, BEFORE the interrupt is serviced, another character is
received, i.e., the data stream has started again. (The interrupt
latency is longer than the pause in the data stream.) In this case,
when a new character has been receiver, the counter/timer will be
restarted by the receiver, thereby withdrawing its interrupt. If, at this
time, the interrupt service begins for the previously seen interrupt, a
read of the ISR will show the “Counter Ready” bit not set. If nothing
else is interrupting, this read of the ISR will return a x’00 character.
This action may present the appearance of a spurious interrupt.
Communications

The communications channel of the SC28L91 comprises a
full-duplex asynchronous receiver/transmitter (UART). The operating
frequency for the receiver and transmitter can be selected
independently from the baud rate generator, the counter/timer, or
from an external input. The transmitter accepts parallel data from the
CPU, converts it to a serial bit stream, inserts the appropriate start,
stop, and optional parity bits and outputs a composite serial stream
of data on the TxD output pin. The receiver accepts serial data on
the RxD pin, converts this serial input to parallel format, checks for
start bit, stop bit, parity bit (if any), or break condition and sends an
assembled character to the CPU via the receive FIFO. Three status
bits (Break Received, Framing and Parity Errors) are also FIFOed
with the data character.
Input Port

The inputs to this unlatched 7-bit (6-bit for 68xxx mode) port can be
read by the CPU by performing a read operation at address 0xD. A
High input results in a logic 1 while a Low input results in a logic 0.
D7 will always read as a logic 1. The pins of this port can also serve
as auxiliary inputs to certain portions of the UART logic, modem and
DMA.
Four change-of-state detectors are provided which are associated
with inputs IP3, IP2, IP1 and IP0. A High-to-Low or Low-to-High
transition of these inputs, lasting longer than 25–50 μs, will set the
corresponding bit in the input port change register. The bits are
cleared when the register is read by the CPU. Any change-of-state
can also be programmed to generate an interrupt to the CPU.
The input port change of state detection circuitry uses a 38.4 kHz
sampling clock derived from one of the baud rate generator taps.
This results in a sampling period of slightly more than 25 μs (this
assumes that the clock input is 3.6864 MHz). The detection circuitry,
in order to guarantee that a true change in level has occurred,
requires two successive samples at the new logic level be observed.
As a consequence, the minimum duration of the signal change is
25 μs if the transition occurs “coincident with the first sample pulse”.
Philips Semiconductors Product data sheet
SC28L913.3 V or 5.0 V Universal Asynchronous
Receiver/Transmitter (UART)
“just missed” and the first change-of-state is not detected until 25 μs
later.
Output Port

The output ports are controlled from six places: the OPCR, OPR,
MR, Command, SOPR and ROPR registers. The OPCR register
controls the source of the data for the output ports OP2 through
OP7. The data source for output ports OP0 and OP1 is controlled by
the MR and CR registers. When the OPR is the source of the data
for the output ports, the data at the ports is inverted from that in the
OPR register. The content of the OPR register is controlled by the
“Set Output Port Bits Command” and the “Reset Output Bits
Command”. These commands are at E and F, respectively. When
these commands are used, action takes place only at the bit
locations where ones exist. For example, a one in bit location 5 of
the data word used with the “Set Output Port bits” command will
result in OPR[5] being set to one. The OP5 would then be set to
zero (VSS). Similarly, a one in bit position 5 of the data word
associated with the “Reset Output Ports Bits” command would set
OPR[5] to zero and, hence, the pin OP5 to a one (VDD).
These pins along with the IP pins and their change of state detectors
are often used for modem and DMA control.
OPERATION
Transmitter

The SC28L91 is conditioned to transmit data when the transmitter is
enabled through the command register. The SC28L91 indicates to
the CPU that it is ready to accept a character by setting the TxRDY
bit in the status register. This condition can be programmed to
generate an interrupt request at OP6 or OP7 and INTRN. When the
transmitter is initially enabled the TxRDY and TxEMPT bits will be
set in the status register. When a character is loaded to the transmit
FIFO the TxEMPT bit will be reset. The TxEMPT will not set until: 1)
the transmit FIFO is empty and the transmit shift register has
finished transmitting the stop bit of the last character written to the
transmit FIFO, or 2) the transmitter is disabled and then re-enabled.
The TxRDY bit is set whenever the transmitter is enabled and the
TxFIFO is not full. Data is transferred from the holding register to
transmit shift register when it is idle or has completed transmission
of the previous character. Characters cannot be loaded into the
TxFIFO while the transmitter is disabled.
The transmitter converts the parallel data from the CPU to a serial
bit stream on the TxD output pin. It automatically sends a start bit
followed by the programmed number of data bits, an optional parity
bit, and the programmed number of stop bits. The least significant
bit is sent first. Following the transmission of the stop bits, if a new
character is not available in the TxFIFO, the TxD output remains
High and the TxEMT bit in the Status Register (SR) will be set to 1.
Transmission resumes and the TxEMT bit is cleared when the CPU
loads a new character into the TxFIFO.
If the transmitter is disabled it continues operating until the character
currently being transmitted and any characters in the TxFIFO,
including parity and stop bits, have been transmitted. New data
cannot be loaded to the TxFIFO when the transmitter is disabled.
When the transmitter is reset it stops sending data immediately.
The transmitter can be forced to send a break (a continuous low
If CTS option is enabled (MR2[4] = 1), the CTS input at IP0 or IP1
must be Low in order for the character to be transmitted. The
transmitter will check the state of the CTS input at the beginning of
the character transmitted. If it is found to be High, the transmitter will
delay the transmission of any following characters until the CTS has
returned to the low state. CTS going high during the serialization of
a character will not affect that character.
The transmitter can also control the RTSN outputs, OP0 or OP1 via
MR2[5]. When this mode of operation is set, the meaning of the OP0
or OP1 signals will usually be ‘end of message’. See description of
the MR2[5] bit for more detail. This feature may be used to
automatically “turn around” a transceiver in simplex systems.
Receiver

The SC28L91 is conditioned to receive data when enabled through
the command register. The receiver looks for a High-to-Low
(mark-to-space) transition of the start bit on the RxD input pin. If a
transition is detected, the state of the RxD pin is sampled the 16X
clock for 7–1/2 clocks (16X clock mode) or at the next rising edge of
the bit time clock (1X clock mode). If RxD is sampled high, the start
bit is invalid and the search for a valid start bit begins again. If RxD
is still Low, a valid start bit is assumed and the receiver continues to
sample the input at one-bit time intervals at the theoretical center of
the bit. When the proper number of data bits and parity bit (if any)
have been assembled, and one/half stop bit has been detected the
byte is loaded to the RxFIFO. The least significant bit is received
first. The data is then transferred to the Receive FIFO and the
RxRDY bit in the SR is set to a 1. This condition can be
programmed to generate an interrupt at OP4 or OP5 and INTRN. If
the character length is less than 8 bits, the most significant unused
bits in the RxFIFO are set to zero.
After the stop bit is detected, the receiver will immediately look for
the next start bit. However if a framing error occurs (a non-zero
character was received without a stop bit) and then RxD remains
low one/half bit time the receiver operates as if a new start bit was
detected. It then continues to assemble the next character.
The parity error, framing error, and overrun error (if any) are strobed
into the SR from the next byte to be read from the Rx FIFO.
If a break condition is detected (RxD is Low for the entire character
including the stop bit), a character consisting of all zeros will be
loaded into the RxFIFO and the received break bit in the SR is set to
1. The RxD input must return to high for two (2) clock edges of the
X1 crystal clock for the receiver to recognize the end of the break
condition and begin the search for a start bit.
This will usually require a high time of one X1 clock period or 3 X1
edges since the clock of the controller is not synchronous to the X1
clock.
Transmitter Reset and Disable

Note the difference between transmitter disable and reset. A
transmitter reset stops transmitter action immediately, clears the
transmitter FIFO and returns the idle state. A transmitter disable
withdraws the transmitter interrupts but allows the transmitter to
continue operation until all bytes in its FIFO and shift register have
been transmitted including the final stop bits. It then returns to its
idle state.
Receiver FIFO
Philips Semiconductors Product data sheet
SC28L913.3 V or 5.0 V Universal Asynchronous
Receiver/Transmitter (UART)
in the status register is set whenever one or more characters are
available to be read, and a FFULL status bit is set if all 8 or 16 stack
positions are filled with data. Either of these bits can be selected to
cause an interrupt. A read of the RxFIFO outputs the data at the top
of the FIFO. After the read cycle, the data FIFO and its associated
status bits (see below) are ‘popped’ thus emptying a FIFO position
for new data.
A disabled receiver with data in its FIFO may generate an interrupt
(see “Receiver Status Bits”, below). Its status bits remain active and
its watchdog, if enabled, will continue to operate.
Receiver Status Bits

In addition to the data word, three status bits (parity error, framing
error, and received break) are also appended to the data character
in the FIFO. The overrun error, MR1[5], and the change of break
(ISR[2]) are not FIFOed.
The status of the Rx FIFO may be provided in two ways, as
programmed by the error mode control bit in the mode register
(MR1[5]). In the ‘character’ mode, status is provided on a
character-by-character basis; the status applies only to the
character at the top of the FIFO. In the ‘block’ mode, the status
provided in the SR for these three bits is the logical-OR of the status
for all characters coming to the top of the FIFO since the last ‘reset
error’ from the command register was issued. In either mode
reading the SR does not affect the FIFO. The FIFO is ‘popped’ only
when the RxFIFO is read. Therefore the status register should be
read prior to reading the FIFO.
If the FIFO is full when a new character is received, that character is
held in the receive shift register until a FIFO position is available. If
an additional character is received while this state exits, the
contents of the FIFO are not affected; the character previously in the
shift register is lost and the overrun error status bit (SR[4]) will be
set-upon receipt of the start bit of the new (overrunning) character.
The receiver can control the deactivation of RTS. If programmed to
operate in this mode, the RTSN output will be negated when a valid
start bit was received and the FIFO is full. When a FIFO position
becomes available, the RTSN output will be re-asserted (set low)
automatically. This feature can be used to prevent an overrun, in the
receiver, by connecting the RTSN output to the CTSN input of the
transmitting device.
If the receiver is disabled, the FIFO characters can be read.
However, no additional characters can be received until the receiver
is enabled again. If the receiver is reset, the FIFO and all of the
receiver status, and the corresponding output ports and interrupt are
reset. No additional characters can be received until the receiver is
enabled again.
Receiver Reset and Disable

Receiver disable stops the receiver immediately—data being
assembled in the receiver shift register is lost. Data and status in the
FIFO is preserved and may be read. A re-enable of the receiver
after a disable will cause the receiver to begin assembling
characters at the next start bit detected.
A receiver reset will discard the present shift register date, reset the
receiver ready bit (RxRDY), clear the status of the byte at the top of
the FIFO and re-align the FIFO read/write pointers.
read. This situation may occur at the end of a transmission when the
last few characters received are not sufficient to cause an interrupt.
This counter times out after 64 bit times. It is reset each time a
character is transferred from the receiver shift register to the
RxFIFO or a read of the RxFIFO is executed.
Receiver Time-out Mode

In addition to the watch dog timer described in the receiver section,
the counter/timer may be used for a similar function. Its 16-bit
programmability allows much greater precision of time out intervals.
The time-out mode uses the received data stream to control the
counter. Each time a received character is transferred from the shift
register to the RxFIFO, the counter is restarted. If a new character is
not received before the counter reaches zero count, the counter
ready bit is set, and an interrupt can be generated. This mode can
be used to indicate when data has been left in the RxFIFO for more
than the programmed time limit. Otherwise, if the receiver has been
programmed to interrupt the CPU when the receive FIFO is full, and
the message ends before the FIFO is full, the CPU may not know
there is data left in the FIFO. The CTU and CTL value would be
programmed for just over one character time, so that the CPU would
be interrupted as soon as it has stopped receiving continuous data.
This mode can also be used to indicate when the serial line has
been marking for longer than the programmed time limit. In this
case, the CPU has read all of the characters from the FIFO, but the
last character received has started the count. If there is no new data
during the programmed time interval, the counter ready bit will get
set, and an interrupt can be generated.
The time-out mode is enabled by writing the appropriate command
to the command register. Writing an 0xAn to CR will invoke the
time-out mode for that channel. Writing a ‘Cx’ to CR will disable the
time-out mode. The time-out mode should only be used by one
channel at once, since it uses the C/T. CTU and CTL must be
loaded with a value greater than the normal receive character
period. The time-out mode disables the regular START/STOP
Counter commands and puts the C/T into counter mode under the
control of the received data stream. Each time a received character
is transferred from the shift register to the RxFIFO, the C/T is
stopped after 1 C/T clock, reloaded with the value in CTU and CTL
and then restarted on the next C/T clock. If the C/T is allowed to end
the count before a new character has been received, the counter
ready bit, ISR[3], will be set. If IMR[3] is set, this will generate an
interrupt. Receiving a character after the C/T has timed out will clear
the counter ready bit, ISR[3], and the interrupt. Invoking the ‘Set
Time-out Mode On’ command, CRx = ‘Ax’, will also clear the counter
ready bit and stop the counter until the next character is received.
Watchdog and Time Out Mode Differences

The watchdog timer is restarted each time a character is read from
or written to the Rx FIFO. It is an indicator that data is in the FIFO
that has not been read. If the Rx FIFO is empty no action occurs. In
the time out mode the C/T is stopped and restarted each time a
character is written to the Rx FIFO. From this point of view the time
out of the C/T is an indication that the data stream has stopped.
After the time out mode is invoked the timer will not start until the
first character is written to the Rx FIFO.
Time Out Mode Caution

When operating in the special time out mode, it is possible to
Philips Semiconductors Product data sheet
SC28L913.3 V or 5.0 V Universal Asynchronous
Receiver/Transmitter (UART)
latency is longer than the pause in the data stream.) In this case,
when a new character has been received, the counter/timer will be
restarted by the receiver, thereby withdrawing its interrupt. If, at this
time, the interrupt service begins for the previously seen interrupt, a
read of the ISR will show the “Counter Ready” bit not set. If nothing
else is interrupting, this read of the ISR will return a x’00 character.
Multi-drop Mode (9-bit or Wake-Up)

The UART is equipped with a wake up mode for multi-drop
applications. This mode is selected by programming bits MR1[4:3]or
to ‘11’. In this mode of operation, a ‘master’ station transmits an
address character followed by data characters for the addressed
‘slave’ station. The slave station(s) whose receiver(s) that are
normally disabled, examine the received data stream and ‘wakeup’
the CPU (by setting RxRDY) only upon receipt of an address
character. The CPU compares the received address to its station
address and enables the receiver if it wishes to receive the
subsequent data characters. Upon receipt of another address
character, the CPU may disable the receiver to initiate the process
again.
A transmitted character consists of a start bit, the programmed
number of data bits, and Address/Data (A/D) bit, and the
programmed number of stop bits. The polarity of the transmitted A/D
bit is selected by the CPU by programming bit MR1[2]. MR1[2]= 0
transmits a zero in the A/D bit position, which identifies the
corresponding data bits as data. MR1[2] = 1 transmits a one in the
A/D bit position, which identifies the corresponding data bits as an
address. The CPU should program the mode register prior to
loading the corresponding data bits into the TxFIFO.
MR1[2] = 1 transmits a one in the A/D bit position, which identifies
the corresponding data bits as an address. The CPU should
program the mode register prior to loading the corresponding data
bits into the TxFIFO.
In this mode, the receiver continuously looks at the received data
stream, whether it is enabled or disabled. If disabled, it sets the
RxRDY status bit and loads the character into the RxFIFO if the
received A/D bit is a one (address tag), but discards the received
character if the received A/D bit is a zero (data tag). If enabled, all
received characters are transferred to the CPU via the RxFIFO. In
either case, the data bits are loaded into the data FIFO while the
A/D bit is loaded into the status FIFO position normally used for
parity error (SR[5] ). Framing error, overrun error, and break detect
operate normally whether or not the receiver is enabled.
PROGRAMMING

The operation of the UART is programmed by writing control words
into the appropriate registers. Operational feedback is provided via
status registers which can be read by the CPU. The addressing of
the registers is described in Table 1.
The contents of certain control registers are initialized to zero on
RESET. Care should be exercised if the contents of a register are
changed during operation, since certain changes may cause
operational problems.
For example, changing the number of bits per character while the
transmitter is active may cause the transmission of an incorrect
character. In general, the contents of the MR, the CSR, and the
OPCR should only be changed while the receiver(s) and
transmitter(s) are not enabled, and certain changes to the ACR
should only be made while the C/T is stopped.
The channel has 3 mode registers (MR0, 1, 2) which control the
basic configuration of the channel. Access to these registers is
controlled by independent MR address pointers. These pointers are
set to 0 or 1 by MR control commands in the command register
“Miscellaneous Commands”. Each time the MR registers are
accessed the MR pointer increments, stopping at MR2. It remains
pointing to MR2 until set to 0 or 1 via the miscellaneous commands
of the command register. The pointer is set to 1 on reset for
compatibility with previous Philips Semiconductors UART software.
Refer to Table 2 for register bit descriptions. The reserved registers
at addresses 0x02 and 0x0A should never be read during normal
operation since they are reserved for internal diagnostics.
Table 1. SC28L91 register addressing

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Philips Semiconductors Product data sheet
SC28L913.3 V or 5.0 V Universal Asynchronous
Receiver/Transmitter (UART)
Table 2. Condensed Register bit formats
Philips Semiconductors Product data sheet
SC28L913.3 V or 5.0 V Universal Asynchronous
Receiver/Transmitter (UART)
REGISTER DESCRIPTIONS MODE REGISTERS
MR0 – Mode Register 0

Mode Register 0. MR0 is accessed by setting the MR pointer to 0 via the command register command B.
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MR0[7]—Watchdog Control

This bit controls the receiver watchdog timer. 0 = disable,
1 = enable. When enabled, the watch dog timer will generate a
receiver interrupt if the receiver FIFO has not been accessed within
64 bit times of the receiver 1X clock. This is used to alert the control
processor that data is in the RxFIFO that has not been read. This
situation may occur when the byte count of the last part of a
message is not large enough to generate an interrupt.
MR0[6]—Rx Interrupt bit 2

Bit 2 of receiver FIFO interrupt level. This bit along with Bit 6 of MR1
sets the fill level of the FIFO that generates the receiver interrupt.
MR0[6], MR1[6] Rx Interrupt bits

Note that this control is split between MR0 and MR1. This is for
backward compatibility to legacy software of the SC2692 and
SCN2681 dual UART devices.
Table 3. Receiver FIFO

Interrupt fill level (MR0(3) = 0 (8 bytes)
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Table 3a. Receiver FIFO

Interrupt fill level(MR0(3)=1 (16 bytes)
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For the receiver these bits control the number of FIFO positions
filled when the receiver will attempt to interrupt. After the reset the
receiver FIFO is empty. The default setting of these bits cause the
receiver to attempt to interrupt when it has one or more bytes in it.
MR0[5:4]—Tx interrupt fill level.
Table 4. Transmitter FIFO

Interrupt fill level MR0(3) = 0 (8 bytes)
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Table 4a. Transmitter FIFO

Interrupt fill level MR0(3) = 1 (16 bytes)
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For the transmitter these bits control the number of FIFO positions
empty when the transmitter will attempt to interrupt. After the reset
the transmit FIFO has 8 bytes empty. It will then attempt to interrupt
as soon as the transmitter is enabled. The default setting of the MR0
bits [5:4] condition the transmitter to attempt to interrupt only when it
is completely empty. As soon as one–byte is loaded, it is no longer
empty and hence will withdraw its interrupt request.
MR0[3]—FIFO size

Selects the FIFO depth at 8 or 16 bytes. See Tables 3 and 4
MR0[2:0]—Baud Rate Group Selection

These bits are used to select one of the six–baud rate groups.
See Table 5 for the group organization. 000 Normal mode 001 Extended mode I 100 Extended mode II
Other combinations of MR2[2:0] should not be used.
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