Philips sc28l198 DATASHEETS

INTEGRATED CIRCUITS

SC28L198

Octal UART for 3.3V and 5V supply
voltage

Product specification
Supersedes data of 1998 Nov 04
IC19 Data Handbook

Philips
Semiconductors

1999 Jan 14

Philips Semiconductors Product specification

SC28L198Octal UART for 3.3V and 5V supply voltage

Table of Contents

Description 2. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

Uses 3. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

Features 3. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

Pin Configurations

Pinout 4. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

Pin Description 6. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

Absolute Maximum Ratings 6. . . . . . . . . . . . . . . . .

Block Diagram

Functional Description 7. . . . . . . . . . . . . . . . . . . . .

Conceptual Overview 7. . . . . . . . . . . . . . . . . . . . . . .

Host Interface 7. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

Asynchronous bus cycle 7. . . . . . . . . . . . . . . . . . . . . . . . . . .

Synchronous bus cycle 7. . . . . . . . . . . . . . . . . . . . . . . . . . . .

Timing Circuits 7. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

Crystal Oscillator 8. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

Sclk – System Clock 8. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

Baud Rate Generator BRG 8. . . . . . . . . . . . . . . . . . . . . . . .

BRG Counters (Used for random baud rate generation) 8

Channel Blocks 8. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

Character Recognition 8. . . . . . . . . . . . . . . . . . . . . . . . . . . . .

Interrupt Control 9. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

Global Registers 9. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

I/O Ports 9. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

Detailed Descriptions 9. . . . . . . . . . . . . . . . . . . . . . .

Receiver and Transmitter

Transmitter 9. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

Status Bits 9. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

Transmission of ”break” 10. . . . . . . . . . . . . . . . . . . . . . . . . . . .

1x and 16x modes, Transmitter 10. . . . . . . . . . . . . . . . . . . . .

Transmitter FIFO 10. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

Receiver 10. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

1x and 16x mode, Receiver 10. . . . . . . . . . . . . . . . . . . . . . . . .

Receiver Status Bits 10. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

Receiver FIFO 11. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

RxFIFO Status: Status reporting modes 11. . . . . . . . . . . . . .

I/O ports 12. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

General Purpose Pins 9. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

Global Registers 8. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

Character Recognition 8. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

Xon Xoff Characters 12. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

Multi-drop or Wake up or 9 bit mode 12. . . . . . . . . . . . . . . . .

Character Stripping 12. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

Interrupt Arbitration and IRQN generation 12. . . . . . . . . . . . . . . .

IACKN Cycle, Update CIR 13. . . . . . . . . . . . . . . . . . . . . . . . . .

Polling 13. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

Enabling and Activating Interrupt sources 13. . . . . . . . . . . . .

Setting Interrupt Priorities 13. . . . . . . . . . . . . . . . . . . . . . . . . .

Modes of Operation 14. . . . . . . . . . . . . . . . . . . . . . . .

Major Modes 14. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

Minor Modes 15. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

Watch-dog Timer Time–out Mode 15. . . . . . . . . . . . . . . . . . .

Wake Up Mode 15. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

Xon/Xoff Operation 18. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

REGISTER DEFINITIONS 18. . . . . . . . . . . . . . . . . . . .

MR – Mode Registers 18. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

UCIR – Update CIR 13. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

General Purpose Output Pin Control 30. . . . . . . .

Register Maps 31. . . . . . . . . . . . . . . . . . . . . . . . . . . . .

Register Map Summary 31. . . . . . . . . . . . . . . . . . . . .

Register Map Detail 32. . . . . . . . . . . . . . . . . . . . . . . .

Reset Conditions 41. . . . . . . . . . . . . . . . . . . . . . . . . . .

Device Configuration after Hardware Reset or CRa cmd=x1F 41

4. . . . . . . . . . . . . . . . . . . . . . . . .

7. . . . . . . . . . . . . . . . . . . . . . . . . . . . .

Cleared registers: 41. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

Clears Modes for: 41. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

Disables: 41. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

Halts: 41. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

Limitations: 41. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

DC Electrical Specifications (5V) 42. . . . . . . . . . . .

AC Electrical Characteristic (5V)

DC Electrical Specifications (3.3V) 45. . . . . . . . . .

AC Electrical Characteristics (3.3V) 46. . . . . . . . . .

INDEX

DESCRIPTION

The Philips 28L198 Octal UART is a single chip CMOS–LSI
communications device that provides 8 full-duplex asynchronous
channels with significantly deeper 16 byte FIFOs, Automatic
in–band flow control using Xon/Xoff characters defined by the user
and address recognition in the wake up mode. Synchronous bus
interface is used for all communication between host and OCTAR T.
It is fabricated using Philips 1.0 micron CMOS technology that
combines the benefits of low cost, high density and low power

9. . . . . . . . . . . . . . . . . . .

consumption.
The operating speed of each receiver and transmitter can be

selected independently from one of 22 fixed baud rates, a 16X clock
derived from one of two programmable baud rate counters or one of
three external 16X clocks (1 available at 1x clock rate). The baud
rate generator and counter can operate directly from a crystal or
from seven other external or internal clock inputs. The ability to
independently program the operating speed of the receiver and
transmitter makes the Octal UART particularly attractive for dual
speed full duplex channel applications such as clustered terminal
systems. The receivers and transmitters are buffered with FIFOs of
16 characters to minimize the potential for receiver overrun and to
reduce interrupt overhead. In addition, a handshaking capability and
in–band flow control are provided to disable a remote UART
transmitter when the receiver buffer is full or nearly so.

To minimize interrupt overhead an interrupt arbitration system is
included which reports the context of the interrupting UART via
direct access or through the modification of the interrupt vector. The
context of the interrupt is reported as channel number, type of
device interrupting ( receiver COS etc.) and, for transmitters or
receivers, the fill level of the FIFO.

The Octal UART provides a power down mode in which the
oscillator is stopped but the register contents are maintained. This
results in reduced power consumption of several orders of
magnitudes. The Octal UART is fully TTL compatible when
operating from a single +5V power supply. Operation at 3.3 volts is
maintained with CMOS interface levels.

The device also offered in a version which maintains TTL input and
output levels while operating with a 3.3 volt power supply.

43. . . . . . . . . . . .

52. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

1999 Jan 14 853–2047 20654

2

Philips Semiconductors Product specification

1

Industrial

SC28L198Octal UART for 3.3V and 5V supply voltage

Uses

Statistical Multiplexers
Data Concentrators

Packet–switching networks
Process Control
Building or Plant Control
Laboratory data gathering
ISDN front ends
Computer Networks

Point–of–Sale terminals
Automotive, cab and engine controls
Entertainment systems

MIDDI keyboard control music systems

Theater lighting control
Terminal Servers

Computer–Printer/Plotter links

FEA TURES

•Single 3.3V and 5V power supply

•Eight Philips industry standard full duplex UART channels

•Sixteen byte receiver FIFOs for each UART

•Sixteen byte transmit FIFOs for each UART

•In band flow control using programmable Xon/Xoff characters

•Flow control using CTSN RTSN hardware handshaking

•Automatic address detection in multi-drop mode

•Three byte general purpose character recognition

•Fast data bus, 30 ns data bus release time, 125 ns bus cycle time

•Programmable interrupt priorities

•Automatic identification of highest priority interrupt pending

•Global interrupt and control registers ease setup and interrupt

handling

•Vectored interrupts with programmable interrupt vector formats

– Interrupt vector modified with channel number
– Interrupt vector modified with channel number and channel type
– Interrupt vector not modified

•IACKN and DACKN signal pins

•Watch dog timer for each receiver (64 receive clock counts)

•Programmable Data Formats:

– 5 to 8 data bits plus parity
– Odd, even force or no parity
– 1, 1.5 or 2 stop bits

•Flexible baud rate selection for receivers and transmitters:

– 22 fixed rates; 50 – 230.4K baud or 100 to 460.8K baud
– Additional non–standard rates to 500K baud with internal

generators

– Two reload–counters provide additional programmable baud

rate generation

– External 1x or 16x clock inputs
– Simplified baud rate selection

•1 MHz 1x and 16x data rates full duplex all channels.

•Parity, framing and overrun error detection

•False start bit detection

•Line break detection and generation

•Programmable channel mode

– Normal(full duplex)
– Diagnostic modes

automatic echo
local loop back
emote loop back

•Four I/O ports per UART for modem controls, clocks, RTSN, I/O

etc.
– All I/O ports equipped with ”Change of State Detectors”

•Two global inputs and two global outputs for general purpose I/O

•Power down mode

•On chip crystal oscillator, 2–8 MHz

•TTL input levels. Outputs switch between full V

CC

and V

SS

•High speed CMOS technology

•84 pin PLCC

•100 pin LQFP

ORDERING CODE

VCC = 5V ±10%

PACKAGES

84-Pin Plastic Leaded Chip Carrier (PLCC) SC28L198A1A SOT189-3
100-Pin Plastic Low–Profile Quad Flat Pack (LQFP) SC28L198A1BE SOT407–1

84-Pin Plastic Leaded Chip Carrier (PLCC) SC28L198A1A SOT189-3
100-Pin Plastic Low–Profile Quad Flat Pack (LQFP) SC28L198A1BE SOT407–1

NOTES:

1. For availability , please contact factory.

1999 Jan 14

3

Industrial

-40°C to +85°C

VCC = 3.3V ±10%

Industrial

-40°C to +85°C

1

DWG #

Philips Semiconductors Product specification

SC28L198Octal UART for 3.3V and 5V supply voltage

PIN CONFIGURATIONS

PINOUT

Pin

1
2
3
4
5
6
7
8

9
10
11
12
13
14
15
16
17
18
19
20
21
22
23
24
25
26
27
28

Function

V

SS

V

CC

CEN

W_RN

A2
A1
A0

DACKN

I/O0a
I/O1a
RxDa
RxDb
I/O2a
I/O3a
TxDa
I/O0b
I/O1b
I/O2b
I/O3b
TxDb
I/O0c

Vss
I/O1c
I/O2c
I/O3c
TxDc
RxDc
I/O0d

11

12

84-PIN PLCC

TOP VIEW

32

33 53

Pin

29
30
31
32
33
34
35
36
37
38
39
40
41
42
43
44
45
46
47
48
49
50
51
52
53
54
55
56

1

75

84

Function

I/O1d
I/O2d
I/O3d
RxDd

TxDd

RESETN

Gout0

I/O3h
I/O2h
I/O1h
I/O0h

RxDh
TxDh
I/O3g

74

54

Vss

Gin0

D0
D1
D2
D3

V

SS

V

CC

D4
D5
D6
D7

Gin1

Vss

Pin

57
58
59
60
61
62
63
64
65
66
67
68
69
70
71
72
73
74
75
76
77
78
79
80
81
82
83
84

Function

I/O2g
I/O1g
I/O0g
RxDg
TxDg

V

SS

X1

X2
TxDf
I/O3f
I/O2f
I/O1f
I/O0f

TxDe
I/O3e
I/O2e
I/O1e

RxDf

RxDe
I/O0e
IRQN

A7

A6

A5

A4

A3

IACKN

SCLK

1999 Jan 14

4

Philips Semiconductors Product specification

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SC28L198Octal UART for 3.3V and 5V supply voltage

PIN CONFIGURATIONS

PINOUT

Pin

1
2
3
4
5
6
7
8

9
10
11
12
13
14
15
16
17
18
19
20
21
22
23
24
25

Function

N/C

RxDb

I/02a

I/03a
TxDa
I/O0b
I/O1b
I/O2b
I/O3b
TxDb
I/O0c

V

SS

V

SS

I/O1c
I/O2c
I/O3c
TxDc
RxDc
I/O0d
I/O1d
I/O2d
I/O3d
RxDd

N/C
N/C

Pin

26
27
28
29
30
31
32
33
34
35
36
37
38
39
40
41
42
43
44
45
46
47
48
49
50

100

1

100–PIN LQFP

TOP VIEW

25

26 50

Function

V

SS

TxDd

RESETN

GIN0

G

0

OUT

D0
D1
D2
D3

V

SS

V

SS

V

CC

V

CC

D4
D5
D6
D7

GIN1

G

1

OUT

I/O3h
I/O2h
I/O1h
I/O0h

V

SS

V

SS

Pin

51
52
53
54
55
56
57
58
59
60
61
62
63
64
65
66
67
68
69
70
71
72
73
74
75

76

75

51

Function

N/C

N/C
RxDh
TxDh
I/O3g
I/O2g
I/O1g
I/O0g
RxDg
TxDg

V

SS

V

SS

X1

X2
TxDf
I/O3f
I/O2f
I/O1f
I/O0f

TxDe
I/O3e
I/O2e
I/O1e

RxDf

N/C

Pin

76
77
78
79
80
81
82
83
84
85
86
87
88
89
90
91
92
93
94
95
96
97
98
99

100

Function

N/C
RxDe
I/O0e
IRQN

A7
A6
A5
A4
A3

IACKN

Sclk
V

SS

V

SS

V

CC

V

CC

CEN

W_RN

A2
A1

JA0

DACKN

I/O0a
I/O1a
RxDa

N/C

1999 Jan 14

5

Philips Semiconductors Product specification

ÁÁÁ

ÁÁÁ

Á

Á

ÁÁÁ

ÁÁÁ

ÁÁÁ

ÁÁÁ

Á

Á

ÁÁÁ

ÁÁÁ

Á

Á

ÁÁÁ

ÁÁÁ

ÁÁÁ

ÁÁÁ

ÁÁÁ

ÁÁÁ

ÁÁÁ

ÁÁÁ

ÁÁÁ

ÁÁÁ

ÁÁÁ

Á

Á

ÁÁÁ

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SC28L198Octal UART for 3.3V and 5V supply voltage

Pin Description

MNEMONIC
SClk

ÁÁÁÁ

CEN

A(7:0)
D(7:0)

W_RN

ÁÁÁÁ

DACKN

IRQN

ÁÁÁÁ

IACKN

TD(a–h)
RD(a–h)
I/O0(a–h)
I/O1(a–h)
I/O2(a–h)
I/O3(a–h)
GIN(1:0)
G

0

OUT

RESETN

X1/CCLK

X2

ÁÁÁÁ

Power Supplies

NOTE: Many output pins will have very fast edges, especially when lightly loaded (less than 20 pf.) These edges may move as fast as 1 to 3 ns
fall or rise time. The user must be aware of the possible generation of ringing and reflections on improperly terminated interconnections. See
previous note on Sclk noise under pin assignments.

TYPE
I

ÁÁ

I

I
I/O

I

ÁÁ

O

O

ÁÁ

I

O
I
I/O
I/O
I/O
I/O
I
O
I

I

O

ÁÁ

I

DESCRIPTION
Host system clock. Used to time operations in the Host Interface and clock internal logic. Must be greater

than twice the frequency of highest X1, Counter/Timer, TxC (1x) or RxC (1x) input frequency.

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Chip select: Active low. When asserted, allows I/O access to OCTART registers by host CPU. W_RN signal
indicates direction. (Must not be active in IACKN cycle)

Address lines (A[6] is NOT used. See ”Host Interface” )
8–bit bi–directional data bus. Carries command and status information between 28L198 and the host CPU.

Used to convey parallel data for serial I/O between the host CPU and the 28L198
Write Read not control: When high indicates that the host CPU will write to a 28L198 register or transmit FIFO.

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When low, indicates a read cycle. 0 = Read; 1 = W rite
Data Acknowledge: Active low. When asserted, it signals that the last transfer of the D lines is complete.

Open drain.
Interrupt Request: Active low. When asserted, indicates that the 28L198 requires service for pending inter-

rupt(s). Open drain.

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Interrupt Acknowledge: Active low. When asserted, indicates that the host CPU has initiated an interrupt ac­knowledge cycle. (Do not use CEN in an IACKN cycle)

Transmit Data: Serial outputs from the 8 UARTs.
Receive Data: Serial inputs to the 8 UARTs
Input/Output 0: Multi–use input or output pin for the UART.
Input/Output 1: Multi–use input or output pin for the UART.
Input/Output 2: Multi–use input or output pin for the UART.
Input/Output 3: Multi–use input or output pin for the UART.
Global general purpose inputs, available to any/all channels.
Global general purpose outputs, available from any channel.
Master reset: Active Low. Must be asserted at power up and may be asserted at other times to reset and re-

start the system. See “Reset Conditions” at end of register map. Minimum width 10 SCLK.
Crystal 1 or Communication Clock: This pin may be connected to one side of a 2–8 MHz crystal. It may alter-

natively be driven by an external clock in this frequency range. Standard frequency = 3.6864 MHz
Crystal 2: If a crystal is used, this is the connection to the second terminal. If a clock signal drives X1, this pin

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must be left unconnected.
8 pins total 6 pins for Vss, 2 pins for Vcc

ABSOLUTE MAXIMUM RATINGS

SYMBOL

TA
TSTG
Vcc
Vss
PD
PD

Operating ambient temperature range
Storage temperature range
Voltage from VCC to Vss
Voltage from any pin to Vss
Package Power Dissipation (PLCC)
Package Power Dissipation (LQFP)

1

PARAMETER

4

Derate above 25 ºC (PLCC pkg.)
Derate above 25ºC (LQFP pkg.)

NOTES:

1. Stresses above those listed under Absolute Maximum Ratings may cause permanent damage to the device. This is a stress rating only and
the functional operation of the device at these or any other conditions above those indicated in the Operation Section of this specification is
not implied.

2. For operating at elevated temperatures, the device must be derated based on +150C maximum junction temperature.

3. Parameters are valid over specified temperature range. See ordering information table for applicable temperature range and operating
supply range.

4. This product includes circuitry specifically designed for the protection of its internal devices from damaging effects of excessive static
charge.

1999 Jan 14

RATING

2

See Note 3
–65 to +150
–0.5 to +7.0

–0.5 to Vcc + 0.5

3.78

2.08
30
17

UNIT

ºC
ºC

V

V
W
W

mW/ºC
mW/ºC

6

Philips Semiconductors Product specification

SC28L198Octal UART for 3.3V and 5V supply voltage

BLOCK DIAGRAM

FULL DUPLEX UART CHANNEL

FULL DUPLEX UART CHANNEL

FULL DUPLEX UART CHANNEL

FULL DUPLEX UART CHANNEL

HOST INTERFACE

As shown in the block diagram, the Octal UART consists of: an
interrupt arbiter, host interface, timing blocks and eight UART
channel blocks. The eight channels blocks operate independently,
interacting only with the timing, host I/F and interrupt blocks.

GENERATOR

TIMING AND BAUD RATE

INTERRUPT ARBITRATION

INPUT BUFFERS AND OUTPUT DRIVERS

INTERFACE

I/O PORT TIMING AND

Block Diagram SC28C/28L198

FUNCTIONAL DESCRIPTION

The SC28L198 is composed of several functional blocks:

•Synchronous host interface block

•A timing block consisting of a common baud rate generator

making 22 industry standard baud rates and 2 16–bit counters
used for non–standard baud rate generation

•4 identical independent full duplex UART channel blocks

•Interrupt arbitration system evaluating 24 contenders

•I/O port control section and change of state detectors.

CONCEPTUAL OVERVIEW
Host Interface

The Host interface is comprised of the signal pins CEN, W/RN,
IACKN, DACKN, IRQN Sclk and provides all the control for data
transfer between the external and internal data buses of the host
and the OCTAR T. The host interface operates in a synchronous
mode with the system (Sclk) which has been designed for a nominal
operating frequency of 33 MHz. The interface operates in either of
two modes; synchronous or asynchronous to the Sclk However
the bus cycle within the OCTART always takes place in four Sclk
cycles after CEN is recognized. These four cycles are the C1, C2,
C3, C4 periods shown in the timing diagrams. DACKN always

FULL DUPLEX UART CHANNEL

FULL DUPLEX UART CHANNEL

DATA DRIVERS AND MODEM INTERFACE

FULL DUPLEX UART CHANNEL

FULL DUPLEX UART CHANNEL

SD00193

occurs in the C4 time and occurs approximately 18 ns after the
rising edge of C4.

Addressing of the various functions of the OCTAR T is through the
address bus A(7:0). The 28L198 is compatible with the SC28L198
OCTAL UAR T in software and function. A[7], in a general sense, is
used to separate the data portion of the circuit from the control
portion.

Asynchronous bus cycle

The asynchronous mode requires one bus cycle of the chip select
(CEN) for each read or write to the chip. No more action will occur
on the bus after the C4 time until CEN is returned high.

Synchronous bus cycle

In the synchronous mode a read or write will be done every four
cycles of the Sclk. CEN does not require cycling but must remain
low to keep the synchronous accesses active. This provides a burst
mode of access to the chip.

In both cases each read or write operation(s) will be completed in
four (4) Sclk cycles. The difference in the two modes is only that the
asynchronous mode will not begin another bus cycle if the CEN
remains active after the four internal Sclk have completed. Internally
the asynchronous cycle will terminate after the four periods of Sclk
regardless of how long CEN is held active

In all cases the internal action will terminate at the withdrawal of
CEN. Synchronous CEN cycles shorter than multiples of four Sclk
cycles minus 1 Sclk and asynchronous CEN cycles shorter than four
Sclk cycles may cause short read or write cycles and produce
corrupted data transfers.

Timing Circuits

The timing block consists of a crystal oscillator, a fixed baud rate
generator (BRG), a pair of programmable 16 bit register based

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counters. A buffer for the System Clock generates internal timing for
processes not directly concerned with serial data flow.

Crystal Oscillator

The crystal oscillator operates directly from a crystal, tuned between

1.0 and 8.0 MHz, connected across the X1/CCLK and X2 inputs with
a minimum of external components. BRG values listed for the clock
select registers correspond to a 3.6864 MHz crystal frequency. Use
of a 7.3728 MHz crystal will double the Communication Clock
frequencies.

An external clock in the 100 KHz to 10 MHz frequency range may
be connected to X1/CCLK. If an external clock is used instead of a
crystal, X1/CCLK must be driven and X2 left floating. The X1 clock
serves as the basic timing reference for the baud rate generator
(BRG) and is available to the BRG timers . The X1 oscillator input
may be left unused if the internal BRG is not used and the X1 signal
is not selected for any counter input.

Sclk – System Clock

A clock frequency, within the limits specified in the electrical
specifications, must be supplied for the system clock Sclk. To
ensure the proper operation of internal controllers, the Sclk
frequency provided, must be strictly greater than twice the frequency
of X1 crystal clock, or any external 1x data clock input. The system
clock serves as the basic timing reference for the host interface and
other internal circuits.

Baud Rate Generator BRG

The baud rate generator operates from the oscillator or external
X1/CCLK clock input and is capable of generating 22 commonly
used data communications baud rates ranging from 50 to 230.4K
baud. These common rates may be doubled (up to 460.8 and 500K
baud) when faster clocks are used on the X1/X2 clock inputs. (See
Receiver and Transmitter Clock Select Register descriptions.) All of
these are available simultaneously for use by any receiver or
transmitter. The clock outputs from the BRG are at 16X the actual
baud rate.

BRG Counters (Used for random baud rate generation)

The two BRG Timers are programmable 16 bit dividers that are used
for generating miscellaneous clocks. These clocks may be used by
any or all of the receivers and transmitters in the Octart or output on
the general purpose output pin GPO.

Each timer unit has eight different clock sources available to it as
described in the BRG Timer Control Register. (BRGTCR). Note
that the timer run and stop controls are also contained in this
register. The BRG Timers generate a symmetrical square wave
whose half period
BRG Timer clock source by the number loaded to the BRG Timer
Reload Registers ( BRGTRU and BRGTRL). Thus, the output
frequency will be the clock source frequency divided by twice the
value loaded to the BRGTRU and BRGTRL registers. This is the
result of counting down once for the high portion of the output wave
and once for the low portion.

Whenever the these timers are selected via the receiver or
transmitter Clock Select register their output will be configured as a
16x clock for the respective receiver or transmitter. Therefore one
needs to program the timers to generate a clock 16 times faster than
the data rate. The formula for calculating ’n’, the number loaded to
the BRGTRU and BRGTRL registers, is shown below.

n 

is equal in time to the division of the selected

BRG Timer Input frequency



2  16  desired baud rate



–1

Note: ’n’ may assume values of 0 and 1. In previous Philips data
communications controllers these values were not allowed.

The BRG timer input frequency is controlled by the BRG Timer
control register (BRGTCR)

The frequency generated from the above formula will be at a rate 16
times faster than the desired baud rate. The transmitter and
receiver state machines include divide by 16 circuits which provide
the final frequency and provide various timing edges used in the
qualifying the serial data bit stream. Often this division will result in
a non–integer value; 26.3 for example. One may only program
integer numbers to a digital divider . There for 26 would be chosen.
If 26.7 was the result of the division then 27 would be chosen. This
gives a baud rate error of 0.3/26.3 or 0.3/26.7. which yields a
percentage error of 1.14% or 1.12% respectively; well within the
ability of the asynchronous mode of operation.

One should be cautious about the assumed benign effects of small
errors since the other receiver or transmitter with which one is

communicating may also have a small error in the precise baud rate.

In a ”clean” communications environment using one start bit, eight
data bits and one stop bit the total difference allowed between the
transmitter and receiver frequency is approximately 4.6%. Less
than eight data bits will increase this percentage.

Channel Blocks

There are eight channel blocks, each containing an I/O port control,
a data format control, and a single full duplex UART channel
consisting of a receiver and a transmitter with their associated 16
byte FIFOs. Each block has its own status register, interrupt status
and interrupt mask registers and their interface to the interrupt
arbitration system.

A highly programmable character recognition system is also
included in each block. This system is used for the Xon/Xoff flow
control and the multi-drop (”9 bit mode”) address character
recognition. It may also be used for general purpose character
recognition.

Four I/O pins are provided for each channel. These pins are
configured individually to be inputs or outputs. As inputs they may
be used to bring external data to the bus, as clocks for internal
functions or external control signals. Each I/O pin has a ”Change of
State” detector. The change detectors are used to signal a change
in the signal level at the pin (Either 0 to 1 or 1 to 0). The level
change on these pins must be stable for 25 to 50 Us (two edges of
the 38.4 KHz baud rate clock) before the detectors will signal a valid
change. These are typically used for interface signals from modems
to the OCTAR T and from there to the host. See the description of
the ”UART channel” under detailed descriptions below.

Character Recognition

Character recognition is specific to each of the eight UARTs. Three
programmable characters are provided for the character recognition
for each channel. The three are general purpose in nature and may
be set to only cause an interrupt or to initiate some rather complex
operations specific to ”Multi-drop” address recognition or in–band
Xon/Xoff flow control.

Character recognition is accomplished via CAM memory. The
Content Addressable Memory continually examines the incoming
data stream. Upon the recognition of a control character appropriate
bits are set in the Xon/Xoff Interrupt Status Register (XISR) and
Interrupt Status Register (ISR). The setting of these bit(s) will
initiate any of the automatic sequences or and/or an interrupt that
may have enabled via the MR0 register.

The characters of the recognition system are not controlled by the
software or hardware reset. They do not have a pre-defined “reset

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value”. They may, however, be loaded by a “Gang White” or “Gang
Load” command as described in the “Xon Xoff Characters”
paragraph.

Note: Character recognition is further described in the

of Operation.

Minor Modes

Interrupt Control

The interrupt system determines when an interrupt should be
asserted thorough an arbitration (or bidding) system. This
arbitration is exercised over the several systems within the OCTART
that may generate an interrupt. These will be referred to as
”interrupt sources”. There are 64 in all. In general the arbitration is
based on the fill level of the receiver FIFO or the empty level of the
transmitter FIFO. The FIFO levels are encoded into a four bit
number which is concatenated to the channel number and source
identification code. All of this is compared (via the bidding or
arbitration process) to a user defined ”threshold”. When ever a
source exceeds the numerical value of the threshold the interrupt
will be generated.

At the time of interrupt acknowledge (IACKN) the source which has
the highest bid (not necessarily the source that caused the interrupt
to be generated) will be captured in a ”Current Interrupt Register”
(CIR). This register will contain the complete definition of the
interrupting source: channel, type of interrupt (receiver, transmitter,
change of state, etc.), and FIFO fill level. The value of the bits in the
CIR are used to drive the interrupt vector and global registers such
that controlling processor may be steered directly to the proper
service routine. A single read operation to the CIR provides all the
information needed to qualify and quantify the most common
interrupt sources.

The interrupt sources for each channel are listed below.

•Transmit FIFO empty level for each channel

•Receive FIFO Fill level for each channel

•Change in break received status for each channel

•Receiver with error for each channel

•Change of state on channel input pins

•Receiver Watch-dog Time out Event

•Xon/Xoff character recognition

•Address character recognition

Associated with the interrupt system are the interrupt mask register
(IMR) and the interrupt status register (ISR) resident in each UART.
Programming of the IMR selects which of the above sources may
enter the arbitration process. Only the bidders in the ISR whose
associated bit in the IMR is set to one (1) will be permitted to enter
the arbitration process. The ISR can be read by the host CPU to
determine all currently active interrupting conditions. For
convenience the bits of the ISR may be masked by the bits of the
IMR. Whether the ISR is read unmasked or masked is controlled by
the setting of bit 6 in MR1.

Global Registers

The ”Global Registers”, 19 in all, are driven by the interrupt system.
These are not real hardware devices. They are defined by the
content of the CIR (Current Interrupt Register) as a result of an
interrupt arbitration. In other words they are indirect registers
contained in the Current Interrupt Register (CIR) which the CIR uses
to point to the source and context of the OCTART sub circuit

presently causing an interrupt. The principle purpose of these
”registers” is improving the efficiency of the interrupt service.

The global registers and the CIR update procedure are further
described in the

I/O Ports

Each of the eight UART blocks contains an I/O section of four ports.
These ports function as a general purpose post section which
services the particular UART they are associated with. External
clocks are input and internal clocks are output through these ports.
Each of the four pins has a change of state detector which will signal
a change (0 to 1 or 1 to 0) at the pin. The change of state detectors
are individually enabled and may be set to cause and interrupt.

These pins will normally be used for flow control hand–shaking and
the interface to a modem. Their control is further described in

section and the I/OPCR register.

Ports

Interrupt Arbitration

system

I/O

DET AILED DESCRIPTIONS
RECEIVER AND TRANSMITTER

The Octal UART has eight full-duplex asynchronous
receiver/transmitters. The operating frequency for the receiver and
transmitter can be selected independently from the baud rate
generator, the counter , or from an external input. Registers that are
central to basic full-duplex operation are the mode registers (MR0,
MR1 and MR2), the clock select registers (RxCSR and TxCSR), the
command register (CR), the status register (SR), the transmit
holding register (TxFIFO), and the receive holding register
(RxFIFO).

Transmitter

The transmitter accepts parallel data from the CPU and converts it
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. Each character is always ”framed”
by a single start bit and a stop bit that is 9/16 bit time or longer. If a
new character is not available in the TxFIFO, the TxD output
remains high, the ”marking” position, and the TxEMT bit in the SR is
set to 1.

Transmitter Status Bits

The SR (Status Register, one per UART) contains two bits that show
the condition of the transmitter FIFO. These bits are TxRDY and
TxEMT. TxRDY means the TxFIFO has space available for one or
more bytes; TxEMT means The TxFIFO is completely empty and
the last stop bit has been completed. TxEMT can not be active
without TxRDY also being active. These two bits will go active upon
initial enabling of the transmitter. They will extinguish on the disable
or reset of the transmitter.

Transmission resumes and the TxEMT bit is cleared when the CPU
loads at least one new character into the TxFIFO. The TxRDY will
not extinguish until the TxFIFO is completely full. The TxRDY bit will
always be active when the transmitter is enabled and there is at
lease one open position in the TxFIFO.

The transmitter is disabled by reset or by a bit in the command
register (CR). The transmitter must be explicitly enabled via the CR
before transmission can begin. Note that characters cannot be
loaded into the TxFIFO while the transmitter is disabled, hence it is
necessary to enable the transmitter and then load the TxFIFO. It is
not possible to load the TxFIFO and then enable the transmission.

Note the difference between transmitter disable and transmitter
reset. The transmitter may by reset by a hardware or software. The

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software reset is issued through command 3x of the Command
register (CR). The disable is done by setting the transmitter disable
bit also in the command register. If the transmitter is disabled, it
continues operating until the character currently being transmitted, if
any, is completely sent, including the stop bit. When reset the
transmitter stops immediately, drives the transmitter serial data out
put to a high level and discards any data in the TxFIFO.

Transmission of ”break”s

Transmission of a break character is often needed as a
synchronizing condition in a data stream. The ”break” is defined as
a start bit followed by all zero data bits by a zero parity bit (if parity is
enabled) and a zero in the stop bit position. The forgoing is the
minimum time to define a break. The transmitter can be forced to
send a break (continuous low condition) by issuing a start break
command via the CR. This command does not have any timing
associated with it. Once issued the TxD output will be driven low
(the spacing condition) and remain there until the host issues a
command to ”stop break” via the CR or the transmitter is issued a
software or hardware reset. In normal operation the break is usually
much longer than one character time.

1x and 16x modes, Transmitter

The transmitter clocking has two modes: 16x and 1x. Data is
always sent at the 1x rate. However the logic of the transmitter may
be operated with a clock that is 16 times faster than the data rate or
at the same rate as the data i.e. 1x. All clocks selected internally
for the transmitter (and the receiver) will be 16x clocks. Only when
an external clock is selected may the transmitter logic and state
machine operate in the 1x mode. The 1x or 16x clocking makes
little difference in transmitter operation. (this is not true in the
receiver) In the 16X clock mode the transmitter will recognize a byte
in the TxFIFO within 1/16 to 2/16 bit time and thus begin
transmission of the start bit; in the 1x mode this delay may be up to
2 bit times.

Transmitter FIFO

The transmitter buffer memory is a 16 byte by 8 bit ripple FIFO. The
host writes characters to this buffer. This buffer accepts data only
when the transmitter is enabled. The transmitter state machine
reads them out in the order they were received and presents them to
the transmitter shift register for serialization. The transmitter adds
the required start, parity and stop bits as required the MR2 register
programming. The start bit (always one bit time in length) is sent
first followed by the least significant bit (LSB) to the most significant
bit (MSB) of the character, the parity bit (if used) and the required
stop bit(s).

Logic associated with the FIFO encodes the number of empty
positions available in a four bit value. This value is concatenated
with the channel number and type interrupt type identifier and
presented to the interrupt arbitration system. The encoding of the
”positions empty” value is always 1 less than the number of
available positions. Thus, an empty TxFIFO will bid with the value
or 15; when full it will not bid at all; one position empty bids with the
value 0. A full FIFO will not bid since a character written to it will be
lost

Normally a TxFIFO will present a bid to the arbitration system when
ever it has one or more empty positions. The MR0[5:4] allow the
user to modify this characteristic so that bidding will not start until
one of four levels (empty, 3/4 empty, 1/2 empty, not full) have been
reached. As will be shown later this feature may be used to make
slight improvements in the interrupt service efficiency . A similar
system exists in the receiver.

Receiver

The receiver accepts serial data on the RxD pin, converts the serial
input to parallel format, checks for start bit, stop bit, parity bit (if
any),framing error or break condition, and presents the assembled
character and its status condition to the CPU via the RxFIFO. Three
status bits are FIFOed with each character received. The RxFIFO is
really 11 bits wide; eight data and 3 status. Unused FIFO bits for
character lengths less than 8 bits are set to zero. It is important to
note that receiver logic considers the entire message to be
contained within the start bit to the stop bit. It is not aware that a
message may contain many characters. The receiver returns to its
idle mode at the end of each stop bit! As described below it
immediately begins to search for another start bit which is normally,
of course, immediately forth coming.

1x and 16x mode, Receiver

The receiver operates in one of two modes; 1x and 16x. Of the two,
the 16x is more robust and the preferred mode. Although the 1x
mode may allow a faster data rate is does not provide for the
alignment of the receiver 1x data clock to that of the transmitter.
This strongly implies that the 1x clock of the remote transmitter is
available to the receiver; the two devices are physically close to
each other.

The 16x mode operates the receiver logic at a rate 16 times faster
than the 1x data rate. This allows for validation of the start bit,
validation of level changes at the receiver serial data input (RxD),
and a stop bit length as short as 9/16 bit time. Of most importance
in the 16x mode is the ability of the receiver logic to align the phase
of the receiver 1x data clock to that of the transmitter with an
accuracy of less than 1/16 bit time.

When the receiver is enabled ( via the CR register) it begins looking
for a high to low (mark to space) transition on the RxD input pin. If a
transition is detected, an internal counter running at 16 times the
data rate is reset to zero. If the RxD remains low and is still low
when the counter reaches a count of 7 the receiver will consider this
a valid start bit and begin assembling the character. If the RxD input
returns to a high state the receiver will reject the previous high to low
(mark to space) transition on the RxD input pin. This action is the
”validation” of the start bit and also establishes the phase of the
receiver 1x clock to that of the transmitter The counter operating at
16x the data rate is the generator for the 1x data rate clock. With
the phase of the receiver 1x clock aligned to the falling of the start
bit (and thus aligned to the transmitter clock) AND with a valid start
bit having been verified the receiver will continue receiving bits by
sampling the RxD input on the rising edge of the 1x clock that is
being generated by the above mentioned counter running 16 times
the data rate. Since the falling edge of the 1x clock was aligned to
falling edge of the start bit then the rising of the clock will be in the
”center” of the bit cell.

This action will continue until a full character has been assembled.
Parity , framing, and stop bit , and break status is then assembled
and the character and its status bits are loaded to the RxFIFO At
this point the receiver has finished its task for that character and will
immediately begin the search for another start bit.

Receiver Status Bits

There are five (5) status bits that are evaluated with each byte (or
character) received: received break, framing error, parity error,
overrun error, and change of break. The first three are appended to
each byte and stored in the RxFIFO. The last two are not
necessarily related to the a byte being received or a byte that is in
the RxFIFO. They are however developed by the receiver state
machine

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Philips Semiconductors Product specification

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. The ”received break” will always be associated with a zero byte in
the RxFIFO. It means that zero character was a break character
and not a zero data byte. The reception of a break condition will
always set the ”change of break” (see below) status bit in the
Interrupt Status Register(ISR).

A framing error occurs when a non zero character was seen and
that character has a zero in the stop bit position.

The parity error indicates that the receiver generated parity was not
the same as that sent by the transmitter.

The overrun error occurs when the RxFIFO is full, the receiver shift
register is full and another start bit is detected. At this moment the
receiver has 17 valid characters and the start bit of the 18th has
been seen. At this point the host has approximately 7/16 bit time to
read a byte from the RxFIFO or the overrun condition will be set and
the 18th character will overrun the 17th and the 19th the 18th and so
on until an open position in the RxFIFO is seen. The meaning of the
overrun is that data has been lost. Data in the RxFIFO remains
valid. The receiver will begin placing characters in the RxFIFO as
soon as a position becomes vacant.

Note: Precaution must be taken when reading an overrun FIFO.
There will be 16 valid characters. Data will begin loading as soon as
the first character is read. The 17
received as valid but it will not be known how many characters were
lost between the two characters of the 16

th.

character will have been

th.

and 17

th.

reads of the

RxFIFO
The ”Change of break” means that either a break has been detected

or that the break condition has been cleared. This bit is available in
the ISR. The beginning of a break will be signaled by the break
change bit being set in the ISR AND the received break bit being set
in the SR. At the termination of the break condition only the change
of break in the ISR will be set. After the break condition is detected
the termination of the break will only be recognized when the RxD
input has returned to the high state for two successive edges of the
1x clock; 1/2 to 1 bit time.

The receiver is disabled by reset or via CR commands. A disabled
receiver will not interrupt the host CPU under any circumstance in
the normal mode of operation. If the receiver is in the multi-drop or
special mode, it will be partially enabled and thus may cause an
interrupt. Refer to section on Wake–Up and minor modes and the
register description for MR1 for more information.

RxFIFO Status: Status reporting modes

The description below applies to the upper three bits in the ”Status
Register” These three bits are not ”in the status register”; They are
part of the RxFIFO. The three status bits at the top of the RxFIFO
are presented as the upper three bits of the status register included
in each UART.

The error status of a character , as reported by a read of the SR
(status register upper three bits) can be provided in two ways, as
programmed by the error mode control bit in the mode register:
”Character mode ” or the ”Block Mode”. The block mode may be
further modified (via a CR command) to set the status bits as the
characters enter the FIFO or as they are read from the FIFO.

In the ’character’ mode, status is provided on a character by
character basis as the characters are read from the RxFIFO: the
”status” applies only to the character at the top of the RxFIFO – The
next character to be read

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 RxFIFO, since the last reset error command was issued. In this
mode each of the status bits stored in the RxFIFO are passed
through a latch as they are sequentially read. If any of the
characters has an error bit set then that latch will set and remain set
until reset with an ”Reset Error” command from the command
register or a receiver reset. The purpose of this mode is indicating
an error in the data block as opposed to an error in a character

The latch used in the block mode to indicate ”problem data” is
usually set as the characters are read out of the RxFIFO. Via a
command in the CR the latch may be configured to set the latch as
the characters are pushed (loaded to) the RxFIFO. This gives the
advantage of indicating ”problem data” 16 characters earlier .

In either mode, reading the SR does not affect the RxFIFO. The
RxFIFO is ’popped’ only when the RxFIFO is read. Therefore, the
SR should be read prior to reading the corresponding data
character.

If the RxFIFO is full when a new character is received, that
character is held in the receive shift register until a RxFIFO position
is available. At this time there are 17 valid characters in the
RxFIFO. If an additional character is received while this state exists,
the contents of the RxFIFO 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.

Receiver FIFO

The receiver buffer memory is a 16 byte ripple FIFO with three
status bits appended to each data byte. (The FIFO is then 16 11 bit
”words”). The receiver state machine gathers the bits from the
receiver shift register and the status bits from the receiver logic and
writes the assembled byte and status bits to the RxFIFO. Logic
associated with the FIFO encodes the number of filled positions for
presentation to the interrupt arbitration system. The encoding is
always 1 less than the number of filled positions. Thus, a full
RxFIFO will bid with the value or 15; when empty it will not bit at all;
one position occupied bids with the value 0. An empty FIFO will not
bid since no character is available. Normally RxFIFO will present a
bid to the arbitration system when ever it has one or more filled
positions. The MR2[3:2 bits allow the user to modify this
characteristic so that bidding will not start until one of four levels
(one or more filled, 1/2 filled, 3/4 filled, full) have been reached. As
will be shown later this feature may be used to make slight
improvements in the interrupt service efficiency . A similar system
exists in the transmitter.

1999 Jan 14

I/O ports

Each of the eight UARTs includes four I/O ports equipped with
”change of state” detectors. The pins are individually programmable
for an input only function or one of three output functions. These
functions are controlled by the ”I/O Port Configuration Register
(I/OPCR)) They will normally be used for the RTSN–CTSN, DTR
hardware signals, RxD or TxD input or output clocks or switch inputs
as well as data out put from the I/OPIOR register.

It is important to note that the input circuits are always active. That
is the signal on a port, whether it is derived from an internal or
external source is always available to the internal circuits associated
with an input on that port.

The ”Change of State” (COS) detectors are sensitive to both a 1 to 0
or a 0 to 1 transition. The detectors are controlled by the internal

38.4 KHz baud rate and will signal a change when a transition has
been stable for two rising edges of this clock. Thus a level on the
I/O ports must be stable for 26 s to 52 s. Defining a port as an
output will disable the COS detector at that port. The condition of

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Philips Semiconductors Product specification

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the four I/O pins and their COS detectors is available at any time in
the IPR (Input Port Register)

The control of data and COS enable for these ports is through the
I/OPIOR register. This is a read/write register and gives individual
control to the enabling of the change of state detectors and also to
the level driven by I/O pins when programmed to drive the logic level
written to the four lower bits of the I/OPIOR. A read of this register
will indicate the data on the pin at the time of the read and the state
of the enabled COS detectors.

General Purpose Pins

In addition to the I/O ports for each UART four other ports are
provided which service the entire chip. Two are dedicated as inputs
and one as an output. The G
the output. These ports are multiplexed to nearly every functional
unit in the chip. See the registers which describe the multitude of
connections available for these pins. The G
multiplexed output and is controlled by four (4) registers: GPOSR,
GPOR, GPOC and GPOD. The GIN0 and GIN1 pins are available to
the receivers and transmitters, BRG counters and the G

1 and GIN0 are the input pins; G

IN

0 pin is highly

OUT

OUT

OUT

0 pin.

Global Registers

The ”Global Registers”, 19 in all, are driven by the interrupt system.
These are not real hardware devices. They are defined by the
content of the CIR (Current Interrupt Register) as a result of an
interrupt arbitration. In other words they are indirect registers
pointed to by the content of the CIR. The list of global register
follows:

GIBCR The byte count of the interrupting FIFO
GICR Channel number of the interrupting channel
GITR Type identification of interrupting channel
GRxFIFO Pointer to the interrupting receiver FIFO
GTxFIFO Pointer to the interrupting transmitter FIFO

A read of the GRxFIFO will give the content of the RxFIFO that
presently has the highest bid value. The purpose of this system is
to enhance the efficiency of the interrupt system. The global
registers and the CIR update procedure are further described in the

Interrupt Arbitration

system

Character Recognition

The character recognition circuits are basically designed to provide
general purpose character recognition. Additional control logic has
been added to allow for Xon/Xoff flow control and for recognition of
the address character in the multi-drop or ”wake–up” mode. This
logic also allows for the generation of an interrupts in either the
general purpose recognition mode or the specific conditions
mentioned above.

Xon Xoff Characters

The programming of these characters is usually done individually.
However a method has been provided to write to all of registers in
one operation. There are ”Gang Load” and a ”Gang Write”
commands provided in the channel A Command Register. When
these commands are executed all registers are programmed with
the same characters. The ”write” command loads a used defined
character; the ’load” command loads the standard Xon/Xoff
characters. Xon is x’11; Xoff x’13’. Any enabling of the Xon/Xof f
functions will use the contents of the Xon and Xoff character
registers as the basis on which recognition is predicated.

Multi-drop or Wake up or 9 bit mode

This mode is used to address a particular UART among a group
connected to the same serial data source. Normally it is

accomplished by redefining the meaning of the parity bit such that it
indicates a character as address or data. While this method is fully
supported in the SC28L198 it also supports recognition of the
character itself. Upon recognition of its address the receiver will be
enabled and data pushed onto the RxFIFO.

Further the Address recognition has the ability, if so programmed, to
disable (not reset) the receiver when an address is seen that is not
recognized as its own. The particular features of ”Auto Wake and
Auto Doze” are described in the detail descriptions below.

Note: Care should be taken in the programming of the character
recognition registers. Programming x’00, for example, may result in
a break condition being recognized as a control character. This will
be further complicated when binary data is being processed.

0

Character Stripping

The MR0 register provides for stripping the characters used for
character recognition. Recall that the character recognition may be
conditioned to control several aspects of the communication.
However this system is first a character recognition system. The
status of the various states of this system are reported in the XISR
and ISR registers. The character stripping of this system allows for
the removal of the specified control characters from the data stream:
two for the Xon /Xoff and one for the wake up. Via control in the
MR0 register these characters may be discarded (stripped) from the
data stream when the recognition system “sees” them or they may
be sent on the RxFIFO. Whether they are stripped or not the
recognition will process them according to the action requested: flow
control, wake up, interrupt generation, etc. Care should be
exercised in programming the stripping option if noisy environments
are encountered. If a normal character was corrupted to an Xoff
character turned off the transmitter and it was then stripped, then the
stripping action could make it difficult to determine the cause of
transmitter stopping.

Interrupt Arbitration and IRQN generation

Interrupt arbitration is the process used to determine that an
interrupt request should be presented to the host. The arbitration is
carried out between the ”Interrupt Threshold” and the ”sources”
whose interrupt bidding is enabled by the IMR. The interrupt
threshold is part of the ICR (Interrupt Control Register) and is a
value programmed by the user. The ”sources” present a value to
the interrupt arbiter. That value is derived from four fields: the
channel number, type of interrupt source, FIFO fill level, and
programmable value. . Only when one or more of these values
exceeds the threshold value in the interrupt control register will the
interrupt request (IRQN) be asserted.

Following assertion of the IRQN the host will either assert
IACKN(Interrupt Acknowledge) or will use the command to ”Update
the CIR”. At the time either action is taken the CIR will capture the
value of the source that is prevailing in the arbitration process. (Call
this value the winning bid)

The value in the CIR is the central quantity that results from the
arbitration. It contains the identity of the interrupting channel, the
type of interrupt in that channel (RxD, TxD, COS etc.) the fill levels
of the RxD or TxD FIFOs and , in the case of an RxD interrupt an
indicator of error data or good data. It also drives the Global
Registers associated with the interrupt. Most importantly it drives

the modification of the Interrupt Vector.

The arbitration process is driven by the Sclk. It scans the 10 bits of
the arbitration bus at the Sclk rate developing a value for the CIR
every 22 Sclk cycles. New arbitration values presented to the
arbitration block during an arbitration cycle will be evaluated in the
next arbitration cycle.

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For sources other than receiver and transmitters the user may set
the high order bits of an interrupt source’s bid value, thus tailoring
the relative priority of the interrupt sources. The priority of the
receivers and transmitters is controlled by the fill level of their
respective FIFOs. The more filled spaces in the RxFIFO the higher
the bid value; the more empty spaces in the TxFIFO the higher its
priority. Channels whose programmable high order bits are set will
be given interrupt priority higher than those with zeros in their high
order bits , thus allowing increased flexibility. The transmitter and
receiver bid values contain the character counts of the associated
FIFOs as high order bits in the bid value. Thus, as a receiver’s
RxFIFO fills, it bids with a progressively higher priority for interrupt
service. Similarly, as empty space in a transmitter’s TxFIFO
increases, its interrupt arbitration priority increases.

IACKN Cycle, Update CIR

When the host CPU responds to the interrupt, it will usually assert
the IACKN signal low. This will cause the OCTART to generate an
IACKN cycle in which the condition of the interrupting device is
determined. When IACKN asserts, the last valid interrupt number is
captured in the CIR. The value captured presents most of the
important details of the highest priority interrupt at the moment the
IACKN (or the ”Update CIR” command) was asserted.

The Octal UART will respond to the IACKN cycle with an interrupt
vector. The interrupt vector may be a fixed value, the content of the
Interrupt Vector Register, or ,when ”Interrupt Vector Modification is
enabled via ICR, it may contain codes for the interrupt type and/or
interrupting channel. This allows the interrupt vector to steer the
interrupt service directly to the proper service routine. The interrupt
value captured in the CIR remains until another IACKN cycle occurs
or until an ”Update CIR” command is given to the OCTAR T. The
interrupting channel and interrupt type fields of the CIR set the
current ”interrupt context” of the OCTAR T. The channel component
of the interrupt context allows the use of Global Interrupt Information
registers that appear at fixed positions in the register address map.
For example, a read of the Global RxFIFO will read the channel B
RxFIFO if the CIR interrupt context is channel b receiver. At another
time read of the GRxFIFO may read the channel D RxFIFO (CIR
holds a channel D receiver interrupt) and so on. Global registers
exist to facilitate qualifying the interrupt parameters and for writing to
and reading from FIFOs without explicitly addressing them.

The CIR will load with x’00 if IACKN or Update CIR is asserted when
the arbitration circuit is NOT asserting and interrupt. In this
condition there is no arbitration value that exceeds the threshold
value.

Polling

Many users prefer polled to interrupt driven service where there are
a large number of fast data channels and/or the host CPU’s other
interrupt overhead is low. The Octal UART is functional in this
environment.

The most efficient method of polling is the use of the ”update CIR”
command (with the interrupt threshold set to zero) followed by a
read of the CIR. This dummy write cycle will perform the same CIR
capture function that an IACKN falling edge would accomplish in an
interrupt driven system. A subsequent read of the CIR, at the same
address, will give information about an interrupt, if any. If the CIR
contains 0s, no interrupt is awaiting service. If the value is
non–zero, the fields of the CIR may be decoded for type, channel
and character count information. Optionally, the global interrupt
registers may be read for particular information about the interrupt

status or use of the global RxD and TxD registers for data transfer
as appropriate. The interrupt context will remain in the CIR until
another update CIR command or an IACKN cycle is initiated by the
host CPU occurs. The CIR loads with x’00 if Update CIR is asserted
when the arbitration circuit has NOT detected arbitration value that
exceeds the threshold value.

Traditional methods of polling status registers may also be used.
They of course are less efficient but give the most variable and
quickest method of changing the order in which interrupt sources
are evaluated and interrogated.

Enabling and Activating Interrupt sources

An interrupt source becomes enabled when its interrupt capability is
set by writing to the Interrupt Mask Register, IMR. An interrupt
source can never generate an IRQN or have its ”bid” or interrupt
number appear in the CIR unless the source has been enabled by
the appropriate bit in an IMR.

An interrupt source is active if it is presenting its bid to the interrupt
arbiter for evaluation. Most sources have simple activation
requirements. The watch-dog timer, break received, Xon/Xoff or
Address Recognition and change of state interrupts become active
when the associated events occur and the arbitration value
generated thereby exceeds the threshold value programmed in the
ICR (Interrupt Control Register).

The transmitter and receiver functions have additional controls to
modify the condition upon which the initiation of interrupt ”bidding”
begins: the TxINT and RxINT fields of the MR0 and MR2 registers.
These fields can be used to start bidding or arbitration when the
RxFIFO is not empty, 50% full, 75% full or 100% full. For the
transmitter it is not full, 50% empty, 75% empty and empty.

Example: To increase the probability of transferring the contents of a
nearly full RxFIFO, do not allow it to start bidding until 50% or 75%
full. This will prevent its relatively high priority from winning the
arbitration process at low fill levels. A high threshold level could
accomplish the same thing, but may also mask out low priority
interrupt sources that must be serviced. Note that for fast channels
and/or long interrupt latency times using this feature should be used
with caution since it reduces the time the host CPU has to respond
to the interrupt request before receiver overrun occurs.

Setting Interrupt Priorities

The bid or interrupt number presented to the interrupt arbiter is
composed of character counts, channel codes, fixed and
programmable bit fields. The interrupt values are generated for
various interrupt sources as shown in the table below: The value
represented by the bits 9 to 3 in the table below are compared
against the value represented by the “Threshold. The “Threshold”
,bits 6 to 0 of the ICR (Interrupt Control Register), is aligned such
that bit 6 of the threshold is compared to bit 9 of the interrupt value
generated by any of the sources. When ever the value of the
interrupt source is greater than the threshold the interrupt will be
generated.

The channel number arbitrates only against other channels. The
threshold is not used for the channel arbitration. This results in
channel D having the highest arbitration number. The decreasing
order is H to A. If all other parts of an arbitration are equal then the
channel number will determine which channel will dominate in the
arbitration process

.

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SC28L198Octal UART for 3.3V and 5V supply voltage

Table 1. Interrupt Arbitration Priority

Type
Receiver w/o error
Receiver w/ error
Transmitter
Change of Break
Change of State
Xon/Xoff
Address Recognition
Receiver Watch-dog
Threshold

B9
RxFIFO Byte Count –1
RxFIFO Byte Count –1
0
Programmed Field
Programmed Field
Programmed Field
Programmed Field
RxFIFO Byte Count –1
Bits 6:0 of Interrupt Control Register

B8

TxFIFO Byte Count –1

B7

0
0
0
0

B6

0
1

0
1
1
0
As RxFIFO Above

B5

B4
0
0
0
1
1
1
1

B3
1
1
0
0
0
1
1

Channel No
Channel No
Channel No
Channel No
Channel No
Channel No
Channel No
Channel No
000

Bits 2:0

Note several characteristics of the above table in bits 6:3. These
bits contain the identification of the bidding source as indicated
below:

x001 Receiver without error
x101 Receiver with error
xx00 Transmitter
0010 Change of Break
0110 Change of State on I/O Ports
0111 Xon/Xoff Event
0011 Address Recognition

The codes form bits 6:3 drive part of the interrupt vector modification
and the Global Interrupt Type Register. The codes are unique to
each source type and Identify them completely. The channel
numbering progresses from ”a” to ”d” as the binary numbers 000 to
011 and identify the interrupting channel uniquely. As the channels
arbitrate ”d” will have the highest bidding value and ”a” the lowest

Note that the transmitter byte count is off–set from that of the
receiver by one bit. This is to give the receiver more authority in the
arbitration since and over–run receiver corrupts the message but an
under–run transmitter is not harmful. This puts some constraints on
how the threshold value is selected. If a threshold is chosen that
has its MSB set to one then a transmitter can never generate an
interrupt! Of course the counter point to this is the desire to set the
interrupt threshold high so interrupts occur only when a maximum or
near maximum number of characters may be transferred.

To give some control over this dilemma control bits have been
provided in the MR0 and MR2 registers of each channel to
individually control when a receiver or transmitter may interrupt. The
use of these bits will prevent a receiver or a transmitter from
entering the arbitration process even though its FIFO fill level is
above that indicated by the threshold value set. The bits in the MR0
and MR2 register are named TxINT (MR0[5:4]) and RxINT
(MR2[3:2])

The watch-dog is included in the table above to show that it affects
the arbitration. It does not have an identity of its own. A barking
watch-dog will prevent any other source type from entering the
arbitration process except enabled receivers. The threshold is
effectively set to zero when any watch-dog times out. The receivers
arbitrate among them selves and the one with the highest fill level
will win the process. Note that the receiver wining the bid may not
be the one that caused the watch-dog to bark.

The fields labeled ”Programmed Field” are the contents of the
Bidding Control Registers, BCRs, for these sources. Setting these
bits to high values can elevate the interrupt importance of the
sources they represent to values almost as high as a full receiver.
For example a COS event may be very important when it represents

the DSR (Data Set Ready) signal from the modem. In this case its
arbitration value should be high. Once the DSR is recognized then
its arbitration value could be reduced or turned off.

There is a single arbiter interrupt number that is not associated with
any of the UART channels. It is the ”Threshold Value” and is
comprised of 7 bits from the Interrupt Control Register, ICR, and
three zeros in the channel field. It is only when one or more of

the enabled interrupt sources generates a arbitration value
larger than the threshold value that the IRQN will be asserted.

When the threshold bidding value is larger than any other bidding
value then the IRQN will be withdrawn. In this condition the CIR will
be loaded with if the IRQN or ”Update CIR” command is asserted.
Because the channels are numbered from 0 to 3 ( A to D) channel 3
will win the bid when all other parts of the bid are equal.

Note: Based on this coding for the receiver and transmitter, a
transmitter would not win a bid in the situation where the Count
Field = 0 unless the threshold value is equal or less than

0000011. A single empty slot is left in the TxFIFO or a single
filled slot in the RxFIFO will bid with a value of zero.

MODES OF OPERATION
Major Modes

Four major modes of operation (normal, auto echo, local loop back
and remote loop back) are provided and are controlled by MR2[7:6].
Three of these may be considered diagnostic. See the MR2 register
description.

The normal mode is the usual mode for data I/O operation. Most
reception and transmission will use the normal mode.

In the auto echo mode, the transmitter automatically re-transmits
any character captured by the channel’s receiver. The receiver 1x
clock is used for the transmitter. This mode returns the received
data back to the sending station one bit time delayed from its
departure. Receiver to host communication is normal. Host to
transmitter communication has no meaning.

In the local loop back mode (used for diagnostic purposes) the
transmitter is internally connected to the receiver input. The
transmitter 1x clock used for the receiver. The RxD input pin is
ignored and the transmitter TxD output pin is held high. This
configuration allows the transmitter to send data to the receiver
without any external parameters to affect the transmission of data.
All status bits, interrupt conditions and processor interface operate
normally. It is recommended that this mode be used when
initially verifying processor to UART interface. The
communication between the transmitter and receiver is entirely
within the UART – it is essentially ”talking to itself”.

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The remote loop back mode (also used for diagnostic purposes) is
similar to auto echo except that the characters are not sent to the
local CPU, nor is the receiver status updated. The received data is

sent directly to the transmitter where it is sent out on the TxD output.

The received data is not sent to the receive FIFO and hence the
host will not normally be participating in any diagnostics.

Minor Modes

The minor modes provide additional features within the major
modes. In general the minor modes provide a reduction in the
control burden and a less stringent interrupt latency time for the host
processor. These modes could be invoked in all of the major
modes.. However it may not be reasonable in many situations.

Watch-dog Timer Time–out Mode

Each receiver in the Octal UART is equipped with a watch-dog timer
that is enabled by the ”Watch-dog Timer Enable Register (WTER).
The watch-dog ”barks” (times out) if 64 counts of the receiver clock
(64 bit times) elapse with no RxFIFO activity. RxFIFO events are a
read of the RxFIFO or GRxFIFO, or the push of a received character
into the RxFIFO. The timer resets when the (G)RxFIFO is read or if
another character is pushed into the RxFIFO. The receiver
watch-dog timer is included to allow detection of the very last
character(s) of a received message that may be waiting in the
RxFIFO, but are too few in number to successfully initiate an
interrupt. The watch-dog timer is enabled for counting if the
channel’s bit in the Watch Dog Timer Control Register (WDTCR) is
set. Note: a read of the GRxFIFO will reset the watch-dog timer of
only the channel specified in the current interrupt context. Other
watch-dogs are unaffected.

The watch-dog timer may generate an input to the interrupt arbiter if
IMR[6] is set. The status of the Watch-dog timer can be seen as Bit
6 of the Interrupt Status Register, ISR[6]. When a W atch-dog timer
that is programmed to generate an interrupt times out it enters the
arbitration process. It will then only allow receivers to enter the
enter the arbitration. All other sources are bidding sources are
disabled. The receivers arbitrate only amongst themselves.. The
receiver only interrupt mode of the interrupt arbiter continues until
the last watch-dog timer event has been serviced. While in the
receiver only interrupt mode, the control of the interrupt threshold
level is also disabled. The receivers arbitrate only between
themselves. The threshold value is ignored. The receiver with the
most FIFO positions filled will win the bid. Hence the user need not
reduce the bidding threshold level in the ICR to see the interrupt
from a nearly empty RxFIFO that may have caused the watch-dog
time–out.

Note: When any watch-dog times our only the receivers arbitrate.
There is no increase in the probability of receiver being serviced
causing the overrun of another receiver since they will still have
priority based upon received character count.

The interrupt will be cleared automatically upon the push of the next
character received or when the RxFIFO or GRxFIFO is read. The
ICR is unaffected by the watch-dog time–out interrupt and normal
interrupt threshold level sensing resumes after the last watch-dog
timer event has been processed. If other interrupt sources are
active, the IRQN pin may remain low.

Wake Up Mode

The SC28L198 provides two modes of this common asynchronous
“party line” protocol: the new automatic mode with 3 sub modes and
the default Host operated mode. The automatic mode has several
sub modes (see below). In the full automatic the internal state
machine devoted to this function will handle all operations

associated with address recognition, data handling, receiver enables
and disables. In both modes the meaning of the parity bit is
changed. It is often referred to as the A/D bit or the address/data
bit. It is used to indicate whether the byte presently in the receiver
shift register is an ”address” byte or a ”data” byte. ”1” usually means
address; ”0” data.

Its purpose is to allow several receivers connected to the same data
source to be individually addressed. Of course addressing could be
by group also. Normally the ”Master” would send an address byte to
all receivers ”listening” The receiver would then recognize its
address and enable itself receiving the following data stream. Upon
receipt of an address not its own it would then disable itself. As
descried below appropriate status bits are available to describe the
operation.

Enabling the Wake Up mode

This mode is selected by programming bits MR1[4:3] to ’11’. The
sub modes are controlled by bits 6, 1, 0 in the MR0 register. Bit 6
controls the loading of the address byte to the RxFIFO and MR0[1:0]
determines the sub mode as shown in the following table.

MR0[1:0] = 00 Normal Wake Up Mode (default). Host controls

operation via interrupts and commands written to
the command register (CR).

MR0[1:0] = 01 Auto wake. Enable receiver on address

recognition for this station. Upon recognition of
its assigned address, in the Auto Wake mode,
the local receiver will be enabled and normal
receiver communications with the host will be
established.

MR0[1:0] = 10 Auto Doze. Disable receiver on address

recognition, not for this station. Upon recognition
of an address character that is not its own, in the
Auto Doze mode, the receiver will be disabled
and the address just received either discarded or
pushed to the RxFIFO depending on the
programming of MR0[6].

MR0[1:0] = 11 Auto wake and doze. Both modes above. The

programming of MR0[1:0] to 11 will enable both
the auto wake and auto doze features.

The enabling of the wake–up mode executes a partial enabling
of the receiver state machine. Even though the receiver has
been reset the wake up mode will over ride the disable and
reset condition.

Normal Wake up (The default configuration)

In the default configuration for this mode of operation, a ’master’
station transmits an address character followed by data characters
for the addressed ’slave’ station. The slave stations, whose
receivers are normally disabled (not reset), examine the received
data stream and interrupts the CPU (by setting RxRDY) only upon
receipt of an address character. The CPU (host) 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, an 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 bytes into the TxFIFO.

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SC28L198Octal UART for 3.3V and 5V supply voltage

While 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, but discards the received character if the
received A/D bit is a zero. If the receiver is 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.

Automatic operation, Wake Up & Doze

The automatic configuration for this mode uses on-board
comparators to examine incoming address characters. Each UART
channel may be assigned a unique address character. See the
address register map and the description of the Address
Recognition Character Register (ARCR). The device may be
programmed to automatically awaken a sleeping receiver and/or
disable an active receiver based upon address characters received.
The operation of the basic receiver is the same as described above
for the default mode of wake–up operation except that the CPU
need not be interrupted to make a change in the receiver status.

Three bits in the Mode Register 0, (MR0), control the address
recognition operation. MR0[6] controls the RxFIFO operation of the
received character; MR0[1:0] controls the wake up mode options. If
MR0[6] is set the address character will be pushed onto the
RxFIFO, otherwise the character will be discarded. (The charter is
stripped from the data stream) The MR0[1:0] bits set the options as
follows: A b’00 in this field, the default or power–on condition, puts
the device in the default (CPU controlled) wake up mode of
operation as described above. The auto–wake mode, enabled if
MR0[0] is set, will cause the dedicated comparators to examine
each address character presented by the receiver. If the received
character matches the reference character in ARCR, the receiver
will be enabled and all subsequent characters will be FIFOed until
another address event occurs or the host CPU disables the receiver
explicitly. The auto doze mode, enabled if MR0[1] is set, will
automatically disable the receiver if an address is received that does
not match the reference character in the ARCR.

The UART channel can present the address recognition event to the
interrupt arbiter for IRQN generation. The IRQN generation may be
masked by setting bit 5 of the Interrupt Mask Register, IMR. The bid
level of an address recognition event is controlled by the Bidding
Control Register, BCRA, of the channel.

Note: To ensure proper operation, the host CPU must clear any
pending Address Recognition interrupt before enabling a disabled
receiver operating in the Special or Wake–up mode. This may be
accomplished via the CR commands to clear the Address Interrupt
or by resetting the receiver.

Xon/Xoff Operation
Receiver Mode

Since the receiving FIFO resources in the Octal UART are limited,
some means of controlling a remote transmitter is desirable in order
to lessen the probability of receiver overrun. The Octal UART
provides two methods of controlling the data flow. A hardware
assisted means of accomplishing control, the so–called out–of–band
flow control, and an in–band flow control method.

The out–of–band flow control is implemented through the
CTSN–RTSN signaling via the I/O ports. The operation of these
hardware handshake signals is described in the receiver and
transmitter discussions.

In–band flow control is a protocol for controlling a remote transmitter
by embedding special characters within the message stream, itself.
Two characters, Xon and Xoff, which do not represent normal
printable characters take on flow control definitions when the
Xon/Xoff capability is enabled. Flow control characters received
may be used to gate the channel transmitter on and off. This activity
is referred to as Auto–transmitter mode. To protect the channel
receiver from overrun, fixed fill levels (hardware set at 12
characters) of the RxFIFO may be employed to automatically insert
Xon/Xoff characters in the transmitter’s data stream. This mode of
operation is referred to as auto–receiver mode. Commands issued
by the host CPU via the CR can simulate all these conditions.

Auto–transmitter mode

When a channel receiver pushes an Xoff character into the RxFIFO,
the channel transmitter will finish transmission of the current
character and then stop transmitting. A transmitter so idled can be
restarted by the receipt of an Xon character by the receiver, or by a
hardware or software reset. The last option results in the loss of the
un–transmitted contents of the TxFIFO. When operating in this
mode the Command Register commands for the transmitter are not
effective.

While idle data may be written to the TxFIFO and it continues to
present its fill level to the interrupt arbiter and maintains the integrity
of its status registers.

Use of ’00’ as an Xon/Xoff character is complicated by the Receiver
break operation which pushes a ’00’ character on the RxFIFO. The
Xon/Xoff character detectors do not discriminate this case from an
Xon/Xoff character received through the RxD pin.

Note: To be recognized as an Xon or Xoff character, the receiver
must have room in the RxFIFO to accommodate the character. An
Xon/Xoff character that is received resulting in a receiver overrun
does not effect the transmitter nor is it pushed into the RxFIFO,
regardless of the state of the Xon/Xoff transparency bit, MR0(7).

Note: Xon /Xoff characters

The Xon/Xoff characters with errors will be accepted as valid. The
user has the option sending or not sending these characters to the
FIFO. Error bits associated with Xon/Xoff will be stored normally to
the receiver FIFO.

The channel’s transmitter may be programmed to automatically
transmit an Xoff character without host CPU intervention when the
RxFIFO fill level exceeds a fixed limit (12). In this mode, it will
conversely transmit an Xon character when the RxFIFO level drops
below a second fixed limit (8). A character from the TxFIFO that has
been loaded into the TxD shift register will continue to transmit.
Character(s) in the TxFIFO that have not been popped are
unaffected by the Xon or Xoff transmission. They will be transmitted
after the Xon/Xoff activity concludes.

If the fill level condition that initiates Xon activity negates before the
flow control character can begin transmission, the transmission of
the flow control character will not occur, i.e. either of the following
sequences may be transmitted depending on the timing of the FIFO
level changes with respect to the normal character times:

Character Xoff Xon Character
Character Character

Hardware keeps track of Xoff characters sent that are not rescinded
by an Xon. This logic is reset by writing MR0(3) to ’0’. If the user
drops out of Auto–receiver mode while the XISR shows Xon as the
last character sent, the Xon/Xoff logic will not automatically send the
negating Xon.

Host mode

When neither the auto–receiver nor auto–transmitter modes are set,
the Xon/Xoff logic is operating in the host mode. In host mode, all

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Philips Semiconductors Product specification

SC28L198Octal UART for 3.3V and 5V supply voltage

activity of the Xon/Xoff logic is initiated by commands to the CRx
command forces the transmitter to disable exactly as though an Xoff
character had been received by the RxFIFO. The transmitter will
remain disabled until the chip is reset or the CR(7:3) = 10110 (Xof f
resume) command is given. In particular, reception of an Xon or
disabling or re–enabling the transmitter will NOT cause resumption
of transmission. Redundant CRTXon/off commands, i.e. CRTXon
CRTXon, are harmless, although they waste time. A CRTXon may
be used to cancel a CRTXoff (and vice versa), but both may be

transmitted depending on the timing with the transmit state machine.

The kill CRTX command can be used to cleanly terminate any
CRTX commands pending with the minimum impact on the
transmitter.

Note: In no case will an Xon/Xoff character transmission be aborted.

Once the character is loaded into the TX Shift Register, transmission
continues until completion or a chip reset is encountered.

The kill CRTX command has no effect in either of the Auto modes.

Mode control

Xon/Xoff mode control is accomplished via the MR0. Bits 3 and 2
reset to zero resulting in all Xon/Xoff processing being disabled. If
MR0[2] is set, the transmitter may be gated by Xon/Xoff characters
received. If MR0[3] is set, the transmitter will transmit Xon and Xoff
when triggered by attainment of fixed fill levels in the channel
RxFIFO. The MR0[7] bit also has an Xon/Xoff function control. If
this bit is set, a received Xon or Xoff character is not pushed into the
RxFIFO. If cleared, the power–on and reset default, the received

Xon or Xoff character is pushed onto the RxFIFO for examination by
the host CPU. The MR0(7) function operates regardless of the
value in MR0(3:2)

Xon/Xoff Interrupts

The Xon/Xoff logic generates interrupts only in response to
recognizing either of the characters in the XonCR or XoffCR (Xon or
Xoff Character Registers). The transmitter activity initiated by the
Xon/Xoff logic or any CR command does not generate an interrupt.
The character comparators operate regardless of the value in
MR0(3:2). Hence the comparators may be used as general purpose
character detectors by setting MR0(3:2)=’00’ and enabling the
Xon/Xoff interrupt in the IMR.

The Octal UART can present the Xon/Xoff recognition event to the
interrupt arbiter for IRQN generation. The IRQN generation may be
masked by setting bit 4 of the Interrupt Mask Register, IMR. The bid
level of an Xon/Xoff recognition event is controlled by the Bidding
Control Register X, BCRX, of the channel. The interrupt status can
be examined in ISR[4]. If cleared, no Xon/Xoff recognition event is
interrupting. If set, an Xon or Xoff recognition event has been
detected. The X Interrupt Status Register, XISR, can be read for
details of the interrupt and to examine other, non–interrupting, status
of the Xon/Xoff logic. Refer to the XISR in the Register
Descriptions.

The character recognition function and the associated interrupt
generation is disabled on hardware or software reset

.

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