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031500

FEATURES

Four T1 DS1/ISDNPRI/J1 framing
transceivers

All four framers are fully independent

Each of the four framers contain dual two

frame elastic store slip buffers that can connect
to asynchronous backplanes up to 8.192 MHz

8bit parallel control port that can be used
directly on either multiplexed or non
multiplexed buses (Intel or Motorola)

Programmable output clocks for Fractional T1

Fully independent transmit and receive
functionality

Integral HDLC controller with 64-byte buffers
configurable for FDL or DS0 operation

Generates and detects inband loop codes from
1 to 8 bits in length including CSU loop codes

Pin compatible with DS21Q44 E1 Enhanced
Quad E1 Framer

3.3V supply with 5V tolerant I/O; low power
CMOS

Available in 128pin TQFP package

IEEE 1149.1 support

FUNCTIONAL DIAGRAM

Receive

Framer

Elastic

Store

Transmit

Formatter

Elastic

Store

FRAMER #0

FRAMER #1

FRAMER #2

FRAMER #3

Control Port

ACTUAL SIZE

QUAD

FRAMER

ORDERING INFORMATION

DS21Q42T

C to 70

DS21Q42TN (-40

C to +85

DESCRIPTION

The DS21Q42 is an enhanced version of the DS21Q41B Quad T1 Framer. The DS21Q42 contains four
framers that are configured and read through a common microprocessor compatible parallel port. Each
framer consists of a receive framer, receive elastic store, transmit formatter and transmit elastic store. All
four framers in the DS21Q42 are totally independent, they do not share a common framing synchronizer.
Also the transmit and receive sides of each framer are totally independent. The dual two-frame elastic
stores contained in each of the four framers can be independently enabled and disabled as required. The
device fully meets all of the latest T1 specifications including ANSI T1.4031995, ANSI T1.2311993,
AT&T TR 62411 (1290), AT&T TR54016, and ITU G.704 and G.706.

DS21Q42

Enhanced QUAD T1 FRAMER

www.dalsemi.com

DS21Q42

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1. INTRODUCTION

The DS21Q42 is a superset version of the popular DS21Q41 Quad T1 framer offering the new features
listed below. All of the original features of the DS21Q41 have been retained and software created for the
original device is transferable to the DS21Q42.

New Features

Additional hardware signaling capability including:

Receive signaling re-insertion to a backplane multiframe sync

Availability of signaling in a separate PCM data stream

Signaling freezing

Interrupt generated on change of signaling data

Full HDLC controller with 64byte buffers in both transmit and receive paths. Configurable for FDL
orDS0 access

Perchannel code insertion in both transmit and receive paths

Ability to monitor one DS0 channel in both the transmit and receive paths

RCL, RLOS, RRA, and RAIS alarms now interrupt on change of state

Detects AIS-CI

8.192 MHz clock synthesizer

Perchannel loopback

Ability to calculate and check CRC6 according to the Japanese standard

Ability to pass the FBit position through the elastic stores in the 2.048 MHz backplane mode

IEEE 1149.1 support

Features

Four T1 DS1/ISDNPRI/J1 framing transceivers

All four framers are fully independent

Frames to D4, ESF, and SLC96 R formats

Each of the four framers contain dual twoframe elastic store slip buffers that can connect to
asynchronous backplanes up to 8.192 MHz

8bit parallel control port that can be used directly on either multiplexed or nonmultiplexed buses
(Intel or Motorola)

Extracts and inserts robbed bit signaling

Detects and generates yellow (RAI) and blue (AIS) alarms

Programmable output clocks for Fractional T1

Fully independent transmit and receive functionality

Generates and detects inband loop codes from 1 to 8 bits in length including CSU loop codes

Contains ANSI one's density monitor and enforcer

Large path and line error counters including BPV, CV, CRC6, and framing bit errors

Pin compatible with DS21Q44 E1 Enhanced Quad E1 Framer

3.3V supply with 5V tolerant I/O; low power CMOS

Available in 128pin TQFP package

DS21Q42

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Functional Description

The receive side framer locates D4 (SLC96) or ESF multiframe boundaries as well as detects incoming
alarms including, carrier loss, loss of synchronization, blue (AIS) and yellow alarms. If needed, the
receive side elastic store can be enabled in order to absorb the phase and frequency differences between
the recovered T1 data stream and an asynchronous backplane clock which is provided at the RSYSCLK
input. The clock applied at the RSYSCLK input can be either a 2.048 MHz clock or a 1.544 MHz clock.
The RSYSCLK can be a burst clock with speeds up to 8.192 MHz.

The transmit side of the DS21Q42 is totally independent from the receive side in both the clock
requirements and characteristics. Data off of a backplane can be passed through a transmit side elastic
store if necessary. The transmit formatter will provide the necessary frame/multiframe data overhead for
T1 transmission.

Reader's Note:

This data sheet assumes a particular nomenclature of the T1 operating environment. In each 125 us frame,
there are 24 eightbit channels plus a framing bit. It is assumed that the framing bit is sent first followed
by channel 1. Each channel is made up of eight bits which are numbered 1 to 8. Bit number 1 is the MSB
and is transmitted first. Bit number 8 is the LSB and is transmitted last. Throughout this data sheet, the
following abbreviations will be used:

Superframe (12 frames per multiframe) Multiframe Structure

SLC96

Subscriber Loop Carrier 96 Channels (SLC96 is an AT&T registered trademark)

ESF

Extended Superframe (24 frames per multiframe) Multiframe Structure

B8ZS

Bipolar with 8 Zero Substitution

CRC

Cyclical Redundancy Check

Terminal Framing Pattern in D4

Signaling Framing Pattern in D4

FPS

Framing Pattern in ESF

Multiframe

BOC

Bit Oriented Code

HDLC

High Level Data Link Control

FDL

Facility Data Link

DS21Q42

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TABLE OF CONTENTS

INTRODUCTION .............................................................................................................................. 2

DS21Q42 PIN DESCRIPTION ......................................................................................................... 8

DS21Q42 PIN FUNCTION DESCRIPTION ................................................................................ 15

DS21Q42 REGISTER MAP............................................................................................................. 22

PARALLEL PORT........................................................................................................................... 26

CONTROL, ID AND TEST REGISTERS ..................................................................................... 26

STATUS AND INFORMATION REGISTERS............................................................................. 37

ERROR COUNT REGISTERS....................................................................................................... 45

DS0 MONITORING FUNCTION................................................................................................... 48

10.

SIGNALING OPERATION ............................................................................................................ 50

10.1.

PROCESSOR BASED SIGNALING ................................................................................... 50

10.2.

HARDWARE BASED SIGNALING ................................................................................... 52

11.

PERCHANNEL CODE (IDLE) GENERATION AND LOOPBACK....................................... 53

11.1.

TRANSMIT SIDE CODE GENERATION ............................................................................ 53

11.1.1.

Simple Idle Code Insertion and PerChannel Loopback ................................................. 54

11.1.2.

PerChannel Code Insertion ........................................................................................... .55

11.2.

RECEIVE SIDE CODE GENERATION ................................................................................ 55

11.2.1.

Simple Code Insertion .................................................................................................... 55

11.2.2.

PerChannel Code Insertion ............................................................................................. 56

12.

CLOCK BLOCKING REGISTERS .............................................................................................. 57

13.

ELASTIC STORES OPERATION .............................................................................................. 58

13.1.

RECEIVE SIDE ....................................................................................................................... 58

13.2.

TRANSMIT SIDE ................................................................................................................... 58

13.3.

MINIMUM DELAY SYNCHRONOUS RSYSCLK/TSYSCLK MODE .............................. 59

DS21Q42

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14.

HDLC CONTROLLER................................................................................................................... 59

14.1.

HDLC FOR DS0S ................................................................................................................... 59

15.

FDL/FS EXTRACTION AND INSERTION.................................................................................. 60

15.1.

HDLC AND BOC CONTROLLER FOR THE FDL .............................................................. 60

15.1.1.

General Overvie ............................................................................................................ .60

15.1.2.

Status Register for the HDLC ........................................................................................ 61

15.1.3.

HDLC/BOC Register Description ................................................................................. 63

15.2.

LEGACY FDL SUPPORT ...................................................................................................... 71

15.2.1.

Ov_2.1.71...................................................................................................................... 71

15.2.2.

Receive Section............................................................................................................. 71

15.2.3.

Transmit Section ........................................................................................................... 72

15.2.4.

D4/SLC96 OPERATION ............................................................................................ 73

16.

PROGRAMMABLE INBAND CODE GENERATION AND DETECTION.......................... 73

17.

TRANSMIT TRANSPARENCY .................................................................................................... 76

18.

INTERLEAVED PCM BUS OPERATION ................................................................................... 76

19.

JTAG-BOUNDARY SCAN ARCHITECTURE AND TEST ACCESS PORT .......................... 79

19.1.

DESCRIPTION ....................................................................................................................... 79

19.2.

TAP CONTROLLER STATE MACHINE.............................................................................. 80

19.3.

INSTRUCTION REGISTER AND INSTRUCTIONS ........................................................... 82

19.4.

TEST REGISTERS ................................................................................................................. 84

20.

TIMING DIAGRAMS...................................................................................................................... 89

21.

OPERATING PARAMETERS .................................................................................................... 104

22.

128-PIN TQFP PACKAGE SPECIFICATIONS ........................................................................ 119

DS21Q42

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2. DS21Q42 PIN DESCRIPTION

Pin Description Sorted by Pin Number Table 2-1

PIN

SYMBOL

TYPE DESCRIPTION

TCHBLK0

Transmit Channel Block from Framer 0

TPOS0

Transmit Bipolar Data from Framer 0

TNEG0

Transmit Bipolar Data from Framer 0

RLINK0

Receive Link Data from Framer 0

RLCLK0

Receive Link Clock from Framer 0

RCLK0

Receive Clock for Framer 0

RNEG0

Receive Bipolar Data for Framer 0

RPOS0

Receive Bipolar Data for Framer 0

RSIG0

[RCHCLK0]

[O]

Receive Signaling Output from Framer 0 [Receive Channel
Clock from Framer 0]

RCHBLK0

Receive Channel Block from Framer 0

RSYSCLK0

Receive System Clock for Elastic Store in Framer 0

RSYNC0

I/O

Receive Sync for Framer 0

RSER0

Receive Serial Data from Framer 0

VSS

Signal Ground

VDD

Positive Supply Voltage

SPARE1

[RMSYNC0]

[O]

RESERVED - must be left unconnected for normal operation
[Receive Multiframe Sync from Framer 0]

RFSYNC0

Receive Frame Sync from Framer 0

JTRST*

[RLOS/LOTC0]

I [O]

JTAG Reset [Receive Loss of Sync/Loss of Transmit clock
from Framer 0]

TCLK0

Transmit Clock for Framer 0

TLCLK0

Transmit Link Clock from Framer 0

TSYNC0

I/O

Transmit Sync for Framer 0

TLINK0

Transmit Link Data for Framer 0

Address Bus Bit 0; LSB

Address Bus Bit 1

Address Bus Bit 2

Address Bus Bit 3

Address Bus Bit 4

Address Bus Bit 5

A6/ALE (AS)

Address Bus Bit 6; MSB or Address Latch Enable (Address
Strobe)

INT*

Receive Alarm Interrupt for all Four Framers

TSYSCLK1

Transmit System Clock for Elastic Store in Framer 1

TSER1

Transmit Serial Data for Framer 1

TSSYNC1

Transmit Sync for Elastic Store in Framer 1

TSIG1

[TCHCLK1]

I [O]

Transmit Signaling Input for Framer 1
[Transmit Channel Clock from Framer 1]

TCHBLK1

Transmit Channel Block from Framer 1

TPOS1

Transmit Bipolar Data from Framer 1

TNEG1

Transmit Bipolar Data from Framer 1

RLINK1

Receive Link Data from Framer 1

DS21Q42

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PIN

SYMBOL

TYPE DESCRIPTION

RLCLK1

Receive Link Clock from Framer 1

RCLK1

Receive Clock for Framer 1

RNEG1

Receive Bipolar Data for Framer 1

RPOS1

Receive Bipolar Data for Framer 1

RSIG1

[RCHCLK1]

[O]

Receive Signaling output from Framer 1
[Receive Channel Clock from Framer 1]

RCHBLK1

Receive Channel Block from Framer 1

RSYSCLK1

Receive System Clock for Elastic Store in Framer 1

Address Bus Bit 7

FMS

Framer Mode Select

RSYNC1

I/O

Receive Sync for Framer 1

RSER1

Receive Serial Data from Framer 1

JTMS

[RMSYNC1]

[O]

JTAG Test Mode Select
[Receive Multiframe Sync from Framer 1]

RFSYNC1

Receive Frame Sync from Framer 1

JTCLK

[RLOS/LOTC1]

[O]

JTAG Test Clock
[Receive Loss of Sync/Loss of Transmit clock from Framer 1]

TCLK1

Transmit Clock for Framer 1

TLCLK1

Transmit Link Clock from Framer 1

TSYNC1

I/O

Transmit Sync for Framer 1

TLINK1

Transmit Link Data for Framer 1

TEST

3-state Control for all Output and I/O Pins

FS0

Framer Select 0 for Parallel Control Port

FS1

Framer Select 1 for Parallel Control Port

CS*

Chip Select

BTS

Bus Type Select for Parallel Control Port

RD*/(DS*)

Read Input (Data Strobe)

WR*/(R/W*)

Write Input (Read/Write)

MUX

Non-Multiplexed or Multiplexed Bus Select

TSYSCLK2

Transmit System Clock for Elastic Store in Framer 2

TSER2

Transmit Serial Data for Framer 2

TSSYNC2

Transmit Sync for Elastic Store in Framer 2

TSIG2

[TCHCLK2]

[O]

Transmit Signaling Input for Framer 2
[Transmit Channel Clock from Framer 2]

TCHBLK2

Transmit Channel Block from Framer 2

TPOS2

Transmit Bipolar Data from Framer 2

TNEG2

Transmit Bipolar Data from Framer 2

RLINK2

Receive Link Data from Framer 2

RLCLK2

Receive Link Clock from Framer 2

RCLK2

Receive Clock for Framer 2

RNEG2

Receive Bipolar Data for Framer 2

RPOS2

Receive Bipolar Data for Framer 2

RSIG2

[RCHCLK2]

[O]

Receive Signaling Output from Framer 2
[Receive Channel Clock from Framer 2]

VSS

Signal Ground

VDD

Positive Supply Voltage

RCHBLK2

Receive Channel Block from Framer 2

DS21Q42

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PIN

SYMBOL

TYPE DESCRIPTION

RSYSCLK2

Receive System Clock for Elastic Store in Framer 2

RSYNC2

I/O

Receive Sync for Framer 2

RSER2

Receive Serial Data from Framer 2

JTDI

[RMSYNC2]

[O]

JTAG Test Data Input
[Receive Multiframe Sync from Framer 2]

RFSYNC2

Receive Frame Sync from Framer 2

JTDO

[RLOS/LOTC2]

[O]

JTAG Test Data Output
[Receive Loss of Sync/Loss of Transmit clock from Framer 2]

TCLK2

Transmit Clock for Framer 2

TLCLK2

Transmit Link Clock from Framer 2

TSYNC2

I/O

Transmit Sync for Framer 2

TLINK2

Transmit Link Data for Framer 2

TSYSCLK3

Transmit System Clock for Elastic Store in Framer 3

TSER3

Transmit Serial Data for Framer 3

TSSYNC3

Transmit Sync for Elastic Store in Framer 3

TSIG3

[TCHCLK3]

[O]

Transmit Signaling Input for Framer 3
[Transmit Channel Clock from Framer 3]

TCHBLK3

Transmit Channel Block from Framer 3

TPOS3

Transmit Bipolar Data from Framer 3

TNEG3

Transmit Bipolar Data from Framer 3

RLINK3

Receive Link Data from Framer 3

RLCLK3

Receive Link Clock from Framer 3

100

RCLK3

Receive Clock for Framer 3

101

RNEG3

Receive Bipolar Data for Framer 3

102

RPOS3

Receive Bipolar Data for Framer 3

103

RSIG3

[RCHCLK3]

[O]

Receive Signaling Output from Framer 3
[Receive Channel Clock from Framer 3]

104

RCHBLK3

Receive Channel Block from Framer 3

105

RSYSCLK3

Receive System Clock for Elastic Store in Framer 3

106

RSYNC3

I/O

Receive Sync for Framer 3

107

RSER3

Receive Serial Data from Framer 3

108

8MCLK

[RMSYNC3]

[O]

8 MHz Clock
[Receive Multiframe Sync from Framer 3]

109

RFSYNC3

Receive Frame Sync from Framer 3

110

VSS

Signal Ground

111

VDD

Positive Supply Voltage

112

CLKSI

[RLOS/LOTC3]

[O]

8MCLK Clock Reference Input
[Receive Loss of Sync/Loss of Transmit clock from Framer 3]

113

TCLK3

Transmit Clock for Framer 3

114

TLCLK3

Transmit Link Clock from Framer 3

115

TSYNC3

I/O

Transmit Sync for Framer 3

116

TLINK3

Transmit Link Data for Framer 3

117

D0 or AD0

I/O

Data Bus Bit or Address/Data Bit 0; LSB

118

D1 or AD1

I/O

Data Bus Bit or Address/Data Bit 1

119

D2 or AD2

I/O

Data Bus Bit or Address/Data Bit 2

120

D3 or AD3

I/O

Data Bus Bit or Address/Data Bit 3

121

D4 or AD4

I/O

Data Bus Bit or Address/Data Bit 4

DS21Q42

12 of 119

Pin Description Sorted by Pin Function, FMS = 0 Table 2-2

PIN

SYMBOL

TYPE DESCRIPTION

108

8MCLK

8 MHz Clock

Address Bus Bit 0; LSB

Address Bus Bit 1

Address Bus Bit 2

Address Bus Bit 3

Address Bus Bit 4

Address Bus Bit 5

A6/ALE (AS)

Address Bus Bit 6; MSB or Address Latch Enable
(Address Strobe)

Address Bus Bit 7

BTS

Bus Type Select for Parallel Control Port

112

CLKSI

8MCLK Clock Reference Input

CS*

Chip Select

117

D0 or AD0

I/O

Data Bus Bit or Address/Data Bit 0; LSB

118

D1 or AD1

I/O

Data Bus Bit or Address/Data Bit 1

119

D2 or AD2

I/O

Data Bus Bit or Address/Data Bit 2

120

D3 or AD3

I/O

Data Bus Bit or Address/Data Bit 3

121

D4 or AD4

I/O

Data Bus Bit or Address/Data Bit 4

122

D5 or AD5

I/O

Data Bus Bit or Address/Data Bit 5

123

D6 or AD6

I/O

Data Bus Bit or Address/Data Bit 6

124

D7 or AD7

I/O

Data Bus Bit or Address/Data Bit 7; MSB

FMS

Framer Mode Select

FS0

Framer Select 0 for Parallel Control Port

FS1

Framer Select 1 for Parallel Control Port

INT*

Receive Alarm Interrupt for all Four Framers

JTCLK

JTAG Test Clock

JTDI

JTAG Test Data Input

JTDO

JTAG Test Data Output

JTMS

JTAG Test Mode Select

JTRST*

JTAG Reset

MUX

Non-Multiplexed or Multiplexed Bus Select

RCHBLK0

Receive Channel Block from Framer 0

RCHBLK1

Receive Channel Block from Framer 1

RCHBLK2

Receive Channel Block from Framer 2

104

RCHBLK3

Receive Channel Block from Framer 3

RCLK0

Receive Clock for Framer 0

RCLK1

Receive Clock for Framer 1

RCLK2

Receive Clock for Framer 2

100

RCLK3

Receive Clock for Framer 3

RD*/(DS*)

Read Input (Data Strobe)

RFSYNC0

Receive Frame Sync from Framer 0

RFSYNC1

Receive Frame Sync from Framer 1

RFSYNC2

Receive Frame Sync from Framer 2

109

RFSYNC3

Receive Frame Sync from Framer 3

RLCLK0

Receive Link Clock from Framer 0

DS21Q42

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PIN

SYMBOL

TYPE DESCRIPTION

RLCLK1

Receive Link Clock from Framer 1

RLCLK2

Receive Link Clock from Framer 2

RLCLK3

Receive Link Clock from Framer 3

RLINK0

Receive Link Data from Framer 0

RLINK1

Receive Link Data from Framer 1

RLINK2

Receive Link Data from Framer 2

RLINK3

Receive Link Data from Framer 3

RNEG0

Receive Bipolar Data for Framer 0

RNEG1

Receive Bipolar Data for Framer 1

RNEG2

Receive Bipolar Data for Framer 2

101

RNEG3

Receive Bipolar Data for Framer 3

RPOS0

Receive Bipolar Data for Framer 0

RPOS1

Receive Bipolar Data for Framer 1

RPOS2

Receive Bipolar Data for Framer 2

102

RPOS3

Receive Bipolar Data for Framer 3

RSER0

Receive Serial Data from Framer 0

RSER1

Receive Serial Data from Framer 1

RSER2

Receive Serial Data from Framer 2

107

RSER3

Receive Serial Data from Framer 3

RSIG0

Receive Signaling Output from Framer 0

RSIG1

Receive Signaling output from Framer 1

RSIG2

Receive Signaling Output from Framer 2

103

RSIG3

Receive Signaling Output from Framer 3

RSYNC0

I/O

Receive Sync for Framer 0

RSYNC1

I/O

Receive Sync for Framer 1

RSYNC2

I/O

Receive Sync for Framer 2

106

RSYNC3

I/O

Receive Sync for Framer 3

RSYSCLK0

Receive System Clock for Elastic Store in Framer 0

RSYSCLK1

Receive System Clock for Elastic Store in Framer 1

RSYSCLK2

Receive System Clock for Elastic Store in Framer 2

105

RSYSCLK3

Receive System Clock for Elastic Store in Framer 3

SPARE1

RESERVED - must be left unconnected for normal operation

TCHBLK0

Transmit Channel Block from Framer 0

TCHBLK1

Transmit Channel Block from Framer 1

TCHBLK2

Transmit Channel Block from Framer 2

TCHBLK3

Transmit Channel Block from Framer 3

TCLK0

Transmit Clock for Framer 0

TCLK1

Transmit Clock for Framer 1

TCLK2

Transmit Clock for Framer 2

113

TCLK3

Transmit Clock for Framer 3

TEST

3-state Control for all Output and I/O Pins

TLCLK0

Transmit Link Clock from Framer 0

TLCLK1

Transmit Link Clock from Framer 1

TLCLK2

Transmit Link Clock from Framer 2

114

TLCLK3

Transmit Link Clock from Framer 3

TLINK0

Transmit Link Data for Framer 0

TLINK1

Transmit Link Data for Framer 1

DS21Q42

14 of 119

PIN

SYMBOL

TYPE DESCRIPTION

TLINK2

Transmit Link Data for Framer 2

116

TLINK3

Transmit Link Data for Framer 3

TNEG0

Transmit Bipolar Data from Framer 0

TNEG1

Transmit Bipolar Data from Framer 1

TNEG2

Transmit Bipolar Data from Framer 2

TNEG3

Transmit Bipolar Data from Framer 3

TPOS0

Transmit Bipolar Data from Framer 0

TPOS1

Transmit Bipolar Data from Framer 1

TPOS2

Transmit Bipolar Data from Framer 2

TPOS3

Transmit Bipolar Data from Framer 3

126

TSER0

Transmit Serial Data for Framer 0

TSER1

Transmit Serial Data for Framer 1

TSER2

Transmit Serial Data for Framer 2

TSER3

Transmit Serial Data for Framer 3

128

TSIG0

Transmit Signaling Input for Framer 0

TSIG1

Transmit Signaling Input for Framer 1

TSIG2

Transmit Signaling Input for Framer 2

TSIG3

Transmit Signaling Input for Framer 3

127

TSSYNC0

Transmit Sync for Elastic Store in Framer 0

TSSYNC1

Transmit Sync for Elastic Store in Framer 1

TSSYNC2

Transmit Sync for Elastic Store in Framer 2

TSSYNC3

Transmit Sync for Elastic Store in Framer 3

TSYNC0

I/O

Transmit Sync for Framer 0

TSYNC1

I/O

Transmit Sync for Framer 1

TSYNC2

I/O

Transmit Sync for Framer 2

115

TSYNC3

I/O

Transmit Sync for Framer 3

125

TSYSCLK0

Transmit System Clock for Elastic Store in Framer 0

TSYSCLK1

Transmit System Clock for Elastic Store in Framer 1

TSYSCLK2

Transmit System Clock for Elastic Store in Framer 2

TSYSCLK3

Transmit System Clock for Elastic Store in Framer 3

VDD

Positive Supply Voltage

VDD

Positive Supply Voltage

111

VDD

Positive Supply Voltage

VSS

Signal Ground

VSS

Signal Ground

110

VSS

Signal Ground

WR*/(R/W*)

Write Input (Read/Write)

DS21Q42

15 of 119

3. DS21Q42 PIN FUNCTION DESCRIPTION

TRANSMIT SIDE PINS

Signal Name: TCLK
Signal Description: Transmit Clock
Signal Type: Input
A 1.544 MHz primary clock. Used to clock data through the transmit side formatter.

Signal Name: TSER
Signal Description: Transmit Serial Data
Signal Type: Input
Transmit NRZ serial data. Sampled on the falling edge of TCLK when the transmit side elastic store is
disabled. Sampled on the falling edge of TSYSCLK when the transmit side elastic store is enabled.

Signal Name: TCHCLK
Signal Description: Transmit Channel Clock
Signal Type: Output
A 192 KHz clock which pulses high during the LSB of each channel. Synchronous with TCLK when the
transmit side elastic store is disabled. Synchronous with TSYSCLK when the transmit side elastic store is
enabled. Useful for parallel to serial conversion of channel data. This function is available when FMS = 1
(DS21Q41 emulation).

Signal Name: TCHBLK
Signal Description: Transmit Channel Block
Signal Type: Output
A user programmable output that can be forced high or low during any of the 24 T1 channels.
Synchronous with TCLK when the transmit side elastic store is disabled. Synchronous with TSYSCLK
when the transmit side elastic store is enabled. Useful for blocking clocks to a serial UART or LAPD
controller in applications where not all T1 channels are used such as Fractional T1, 384 Kbps service, 768
Kbps or ISDNPRI . Also useful for locating individual channels in dropandinsert applications, for
external perchannel loopback, and for perchannel conditioning. See Section 12 for details.

Signal Name: TSYSCLK
Signal Description: Transmit System Clock
Signal Type: Input
1.544 MHz or 2.048 MHz clock. Only used when the transmit side elastic store function is enabled.
Should be tied low in applications that do not use the transmit side elastic store. Can be burst at rates up
to 8.192 MHz.

Signal Name: TLCLK
Signal Description: Transmit Link Clock
Signal Type: Output
4 KHz or 2 KHz (ZBTSI) demand clock for the TLINK input. See Section 15 for details.

DS21Q42

16 of 119

Signal Name: TLINK
Signal Description: Transmit Link Data
Signal Type: Input
If enabled via TCR1.2, this pin will be sampled on the falling edge of TCLK for data insertion into either
the FDL stream (ESF) or the Fsbit position (D4) or the Zbit position (ZBTSI). See Section 15 for
details.

Signal Name: TSYNC
Signal Description: Transmit Sync
Signal Type: Input /Output
A pulse at this pin will establish either frame or multiframe boundaries for the transmit side. Via TCR2.2,
the DS21Q42 can be programmed to output either a frame or multiframe pulse at this pin. If this pin is set
to output pulses at frame boundaries, it can also be set via TCR2.4 to output doublewide pulses at
signaling frames. See Section 20 for details.

Signal Name: TSSYNC
Signal Description: Transmit System Sync
Signal Type: Input
Only used when the transmit side elastic store is enabled. A pulse at this pin will establish either frame or
multiframe boundaries for the transmit side. Should be tied low in applications that do not use the
transmit side elastic store.

Signal Name: TSIG
Signal Description: Transmit Signaling Input
Signal Type: Input
When enabled, this input will sample signaling bits for insertion into outgoing PCM T1 data stream.
Sampled on the falling edge of TCLK when the transmit side elastic store is disabled. Sampled on the
falling edge of TSYSCLK when the transmit side elastic store is enabled. This function is available when
FMS = 0.

Signal Name: TPOS
Signal Description: Transmit Positive Data Output
Signal Type: Output
Updated on the rising edge of TCLK with the bipolar data out of the transmit side formatter. Can be
programmed to source NRZ data via the Output Data Format (CCR1.6) control bit.

Signal Name: TNEG
Signal Description: Transmit Negative Data Output
Signal Type: Output
Updated on the rising edge of TCLK with the bipolar data out of the transmit side formatter.

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RECEIVE SIDE PINS

Signal Name: RLINK
Signal Description: Receive Link Data
Signal Type: Output
Updated with either FDL data (ESF) or Fs bits (D4) or Z bits (ZBTSI) one RCLK before the start of a
frame. See Section 20 for details.

Signal Name: RLCLK
Signal Description: Receive Link Clock
Signal Type: Output
A 4 KHz or 2 KHz (ZBTSI) clock for the RLINK output.

Signal Name: RCHCLK
Signal Description: Receive Channel Clock
Signal Type: Output
A 192 KHz clock which pulses high during the LSB of each channel. Synchronous with RCLK when the
receive side elastic store is disabled. Synchronous with RSYSCLK when the receive side elastic store is
enabled. Useful for parallel to serial conversion of channel data. This function is available when FMS = 1
(DS21Q41 emulation).

Signal Name: RCHBLK
Signal Description: Receive Channel Block
Signal Type: Output
A user programmable output that can be forced high or low during any of the 24 T1 channels.
Synchronous with RCLK when the receive side elastic store is disabled. Synchronous with RSYSCLK
when the receive side elastic store is enabled. Useful for blocking clocks to a serial UART or LAPD
controller in applications where not all T1 channels are used such as Fractional T1, 384K bps service,
768K bps, or ISDNPRI. Also useful for locating individual channels in dropandinsert applications, for
external perchannel loopback, and for perchannel conditioning. See Section 12 for details.

Signal Name: RSER
Signal Description: Receive Serial Data
Signal Type: Output
Received NRZ serial data. Updated on rising edges of RCLK when the receive side elastic store is
disabled. Updated on the rising edges of RSYSCLK when the receive side elastic store is enabled.

Signal Name: RSYNC
Signal Description: Receive Sync
Signal Type: Input /Output
An extracted pulse, one RCLK wide, is output at this pin which identifies either frame (RCR2.4 = 0) or
multiframe (RCR2.4 = 1) boundaries. If set to output frame boundaries then via RCR2.5, RSYNC can
also be set to output doublewide pulses on signaling frames. If the receive side elastic store is enabled
via CCR1.2, then this pin can be enabled to be an input via RCR2.3 at which a frame or multiframe
boundary pulse is applied. See Section 20 for details.

Signal Name: RFSYNC
Signal Description: Receive Frame Sync
Signal Type: Output
An extracted 8 KHz pulse, one RCLK wide, is output at this pin which identifies frame boundaries.

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Signal Name: RMSYNC
Signal Description: Receive Multiframe Sync
Signal Type: Output
An extracted pulse, one RSYSCLK wide, is output at this pin which identifies multiframe boundaries. If
the receive side elastic store is disabled, then this output will output multiframe boundaries associated
with RCLK. This function is available when FMS = 1 (DS21Q41 emulation).

Signal Name: RSYSCLK
Signal Description: Receive System Clock
Signal Type: Input
1.544 MHz or 2.048 MHz clock. Only used when the elastic store function is enabled. Should be tied low
in applications that do not use the elastic store. Can be burst at rates up to 8.192 MHz.

Signal Name: RSIG
Signal Description: Receive Signaling Output
Signal Type: Output
Outputs signaling bits in a PCM format. Updated on rising edges of RCLK when the receive side elastic
store is disabled. Updated on the rising edges of RSYSCLK when the receive side elastic store is enabled.
This function is available when FMS = 0.

Signal Name: RLOS/LOTC
Signal Description: Receive Loss of Sync / Loss of Transmit Clock
Signal Type: Output
A dual function output that is controlled by the CCR3.5 control bit. This pin can be programmed to either
toggle high when the synchronizer is searching for the frame and multiframe or to toggle high if the
TCLK pin has not been toggled for 5 usec. This function is available when FMS = 1 (DS21Q41
emulation).

Signal Name: CLKSI
Signal Description: 8 MHz Clock Reference
Signal Type: Input
A 1.544 MHz reference clock used in the generation of 8MCLK. This function is available when
FMS = 0.

Signal Name: 8MCLK
Signal Description: 8 MHz Clock
Signal Type: Output
A 8.192 MHz output clock that is referenced to the clock that is input at the CLKSI pin. This function is
available when FMS = 0.

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Signal Name: RPOS
Signal Description: Receive Positive Data Input
Signal Type: Input
Sampled on the falling edge of RCLK for data to be clocked through the receive side framer. RPOS and
RNEG can be tied together for an NRZ interface. Connecting RPOS to RNEG disables the bipolar
violation monitoring circuitry.

Signal Name: RNEG
Signal Description: Receive Negative Data Input
Signal Type: Input
Sampled on the falling edge of RCLK for data to be clocked through the receive side framer. RPOS and
RNEG can be tied together for an NRZ interface. Connecting RPOS to RNEG disables the bipolar
violation monitoring circuitry.

Signal Name: RCLK
Signal Description: Receive Clock Input
Signal Type: Input
Clock used to clock data through the receive side framer.

PARALLEL CONTROL PORT PINS

Signal Name: INT*
Signal Description: Interrupt
Signal Type: Output
Flags host controller during conditions and change of conditions defined in the Status Registers 1 and 2
and the HDLC Status Register. Active low, open drain output.

Signal Name: FMS
Signal Description: Framer Mode Select
Signal Type: Input
Set low to select DS21Q42 feature set. Set high to select DS21Q41 emulation.

Signal Name: MUX
Signal Description: Bus Operation
Signal Type: Input
Set low to select nonmultiplexed bus operation. Set high to select multiplexed bus operation.

Signal Name: D0 to D7/ AD0 to AD7
Signal Description: Data Bus or Address/Data Bus
Signal Type: Input /Output
In nonmultiplexed bus operation (MUX = 0), serves as the data bus. In multiplexed bus operation (MUX
= 1), serves as a 8bit multiplexed address / data bus.

Signal Name: A0 to A5, A7
Signal Description: Address Bus
Signal Type: Input
In nonmultiplexed bus operation (MUX = 0), serves as the address bus. In multiplexed bus operation
(MUX = 1), these pins are not used and should be tied low.

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Signal Name: ALE(AS)/A6
Signal Description: A6 or Address Latch Enable (Address Strobe)
Signal Type: Input
In nonmultiplexed bus operation (MUX = 0), serves as address bit 6. In multiplexed bus operation
(MUX = 1), serves to demultiplex the bus on a positivegoing edge.

Signal Name: BTS
Signal Description: Bus Type Select
Signal Type: Input
Strap high to select Motorola bus timing; strap low to select Intel bus timing. This pin controls the
function of the RD*(DS*), ALE(AS), and WR*(R/W*) pins. If BTS = 1, then these pins assume the
function listed in parenthesis ().

Signal Name: RD*(DS*)
Signal Description: Read Input (Data Strobe)
Signal Type: Input
RD* and DS* are active low signals. Note: DS is active high when MUX=1. Refer to bus timing
diagrams in section 21 .

Signal Name: FS0 AND FS1
Signal Description: Framer Selects
Signal Type: Input
Selects which of the four framers to be accessed.

Signal Name: CS*
Signal Description: Chip Select
Signal Type: Input
Must be low to read or write to the device. CS* is an active low signal.

Signal Name: WR*( R/W*)
Signal Description: Write Input(Read/Write)
Signal Type: Input
WR* is an active low signal.

TEST ACCESS PORT PINS

Signal Name: TEST
Signal Description: 3State Control
Signal Type: Input
Set high to 3state all output and I/O pins (including the parallel control port) when FMS = 1 or when
FMS = 0 and JTRST* is tied low. Set low for normal operation. Ignored when FMS = 0 and JTRST* = 1.
Useful in board level testing.

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Signal Name: JTRST*
Signal Description: IEEE 1149.1 Test Reset
Signal Type: Input
This signal is used to asynchronously reset the test access port controller. At power up, JTRST* must be
set low and then high. This action will set the device into the DEVICE ID mode allowing normal device
operation. If boundary scan is not used and FMS = 0, this pin should be held low. This function is
available when FMS = 0. When FMS=1, this pin is held LOW internally. This pin is pulled up internally
by a 10K ohm resistor.

Signal Name: JTMS
Signal Description: IEEE 1149.1 Test Mode Select
Signal Type: Input
This pin is sampled on the rising edge of JTCLK and is used to place the test port into the various defined
IEEE 1149.1 states. This pin is pulled up internally by a 10K ohm resistor. If not used, this pin should be
left unconnected. This function is available when FMS = 0.

Signal Name: JTCLK
Signal Description: IEEE 1149.1 Test Clock Signal
Signal Type: Input
This signal is used to shift data into JTDI pin on the rising edge and out of JTDO pin on the falling edge.
If not used, this pin should be connected to VSS. This function is available when FMS = 0.

Signal Name: JTDI
Signal Description: IEEE 1149.1 Test Data Input
Signal Type: Input
Test instructions and data are clocked into this pin on the rising edge of JTCLK. This pin is pulled up
internally by a 10K ohm resistor. If not used, this pin should be left unconnected. This function is
available when FMS = 0.

Signal Name: JTDO
Signal Description: IEEE 1149.1 Test Data Output
Signal Type: Output
Test instructions and data are clocked out of this pin on the falling edge of JTCLK. If not used, this pin
should be left unconnected. This function is available when FMS = 0.

SUPPLY PINS

Signal Name: VDD
Signal Description: Positive Supply
Signal Type: Supply
2.97 to 3.63 volts.

Signal Name: VSS
Signal Description: Signal Ground
Signal Type: Supply
0.0 volts.

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4. DS21Q42 REGISTER MAP

Register Map Sorted by Address Table 4-1

ADDRESS

R/W

REGISTER NAME

REGISTER

ABBREVIATION

R/W

HDLC Control

HCR

R/W

HDLC Status

HSR

R/W

HDLC Interrupt Mask

HIMR

R/W

Receive HDLC Information

RHIR

R/W

Receive Bit Oriented Code

RBOC

Receive HDLC FIFO

RHFR

R/W

Transmit HDLC Information

THIR

R/W

Transmit Bit Oriented Code

TBOC

Transmit HDLC FIFO

THFR

Not used

(set to 00H)

R/W

Common Control 7

CCR7

Not used

(set to 00H)

Not used

(set to 00H)

Not used

(set to 00H)

Not used

(set to 00H)

Device ID

IDR

R/W

Receive Information 3

RIR3

R/W

Common Control 4

CCR4

R/W

InBand Code Control

IBCC

R/W

Transmit Code Definition

TCD

R/W

Receive Up Code Definition

RUPCD

R/W

Receive Down Code Definition

RDNCD

R/W

Transmit Channel Control 1

TCC1

R/W

Transmit Channel Control 2

TCC2

R/W

Transmit Channel Control 3

TCC3

R/W

Common Control 5

CCR5

Transmit DS0 Monitor

TDS0M

R/W

Receive Channel Control 1

RCC1

R/W

Receive Channel Control 2

RCC2

R/W

Receive Channel Control 3

RCC3

R/W

Common Control 6

CCR6

Receive DS0 Monitor

RDS0M

R/W

Status 1

SR1

R/W

Status 2

SR2

R/W

Receive Information 1

RIR1

Line Code Violation Count 1

LCVCR1

Line Code Violation Count 2

CVCR2

Path Code Violation Count 1

PCVCR1

Path Code violation Count 2

PCVCR2

Multiframe Out of Sync Count 2

MOSCR2

Receive FDL Register

RFDL

R/W

Receive FDL Match 1

RMTCH1

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ADDRESS

R/W

REGISTER NAME

REGISTER

ABBREVIATION

R/W

Receive FDL Match 2

RMTCH2

R/W

Receive Control 1

RCR1

R/W

Receive Control 2

RCR2

R/W

Receive Mark 1

RMR1

R/W

Receive Mark 2

RMR2

R/W

Receive Mark 3

RMR3

R/W

Common Control 3

CCR3

R/W

Receive Information 2

RIR2

R/W

Transmit Channel Blocking 1

TCBR1

R/W

Transmit Channel blocking 2

TCBR2

R/W

Transmit Channel Blocking 3

TCBR3

R/W

Transmit Control 1

TCR1

R/W

Transmit Control 2

TCR2

R/W

Common Control 1

CCR1

R/W

Common Control 2

CCR2

R/W

Transmit Transparency 1

TTR1

R/W

Transmit Transparency 2

TTR2

R/W

Transmit Transparency 3

TTR3

R/W

Transmit Idle 1

TIR1

R/W

Transmit Idle 2

TIR2

R/W

Transmit Idle 3

TIR3

R/W

Transmit Idle Definition

TIDR

R/W

Transmit Channel 9

TC9

R/W

Transmit Channel 10

TC10

R/W

Transmit Channel 11

TC11

R/W

Transmit Channel 12

TC12

R/W

Transmit Channel 13

TC13

R/W

Transmit Channel 14

TC14

R/W

Transmit Channel 15

TC15

R/W

Transmit Channel 16

TC16

R/W

Transmit Channel 17

TC17

R/W

Transmit Channel 18

TC18

R/W

Transmit Channel 19

TC19

R/W

Transmit Channel 20

TC20

R/W

Transmit Channel 21

TC21

R/W

Transmit Channel 22

TC22

R/W

Transmit Channel 23

TC23

R/W

Transmit Channel 24

TC24

R/W

Transmit Channel 1

TC1

R/W

Transmit Channel 2

TC2

R/W

Transmit Channel 3

TC3

R/W

Transmit Channel 4

TC4

R/W

Transmit Channel 5

TC5

R/W

Transmit Channel 6

TC6

R/W

Transmit Channel 7

TC7

R/W

Transmit Channel 8

TC8

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ADDRESS

R/W

REGISTER NAME

REGISTER

ABBREVIATION

R/W

Receive Channel 17

RC17

R/W

Receive Channel 18

RC18

R/W

Receive Channel 19

RC19

R/W

Receive Channel 20

RC20

R/W

Receive Channel 21

RC21

R/W

Receive Channel 22

RC22

R/W

Receive Channel 23

RC23

R/W

Receive Channel 24

RC24

Receive Signaling 1

RS1

Receive Signaling 2

RS2

Receive Signaling 3

RS3

Receive Signaling 4

RS4

Receive Signaling 5

RS5

Receive Signaling 6

RS6

Receive Signaling 7

RS7

Receive Signaling 8

RS8

Receive Signaling 9

RS9

Receive Signaling 10

RS10

Receive Signaling 11

RS11

Receive Signaling 12

RS12

R/W

Receive Channel Blocking 1

RCBR1

R/W

Receive Channel Blocking 2

RCBR2

R/W

Receive Channel Blocking 3

RCBR3

R/W

Interrupt Mask 2

IMR2

R/W

Transmit Signaling 1

TS1

R/W

Transmit Signaling 2

TS2

R/W

Transmit Signaling 3

TS3

R/W

Transmit Signaling 4

TS4

R/W

Transmit Signaling 5

TS5

R/W

Transmit Signaling 6

TS6

R/W

Transmit Signaling 7

TS7

R/W

Transmit Signaling 8

TS8

R/W

Transmit Signaling 9

TS9

R/W

Transmit Signaling 10

TS10

R/W

Transmit Signaling 11

TS11

R/W

Transmit Signaling 12

TS12

Not used

(set to 00H)

R/W

Test 1

TEST1 (set to 00h)

R/W

Transmit FDL Register

TFDL

R/W

Interrupt Mask Register 1

IMR1

R/W

Receive Channel 1

RC1

R/W

Receive Channel 2

RC2

R/W

Receive Channel 3

RC3

R/W

Receive Channel 4

RC4

R/W

Receive Channel 5

RC5

R/W

Receive Channel 6

RC6

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ADDRESS

R/W

REGISTER NAME

REGISTER

ABBREVIATION

R/W

Receive Channel 7

RC7

R/W

Receive Channel 8

RC8

R/W

Receive Channel 9

RC9

R/W

Receive Channel 10

RC10

R/W

Receive Channel 11

RC11

R/W

Receive Channel 12

RC12

R/W

Receive Channel 13

RC13

R/W

Receive Channel 14

RC14

R/W

Receive Channel 15

RC15

R/W

Receive Channel 16

RC16

R/W

Receive HDLC DS0 Control Register 1

RDC1

R/W

Receive HDLC DS0 Control Register 2

RDC2

R/W

Transmit HDLC DS0 Control Register 1

TDC1

R/W

Transmit HDLC DS0 Control Register 2

TDC2

R/W

Interleave Bus Operation Register

IBO

Not used

(set to 00H)

R/W

Test 2

TEST2 (set to 00h)

Not used

(set to 00H)

Not used

(set to 00H)

Not used

(set to 00H)

Not used

(set to 00H)

Not used (set to 00H)

Notes:

Test Registers 1 and 2 are used only by the factory; these registers must be cleared (set to all zeros) on
power up initialization to insure proper operation.

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5. PARALLEL PORT

The DS21Q42 is controlled via either a nonmultiplexed (MUX = 0) or a multiplexed (MUX = 1) bus by
an external microcontroller or microprocessor. The DS21Q42 can operate with either Intel or Motorola
bus timing configurations. If the BTS pin is tied low, Intel timing will be selected; if tied high, Motorola
timing will be selected. All Motorola bus signals are listed in parenthesis (). See the timing diagrams in
the A.C. Electrical Characteristics in Section 21 for more details.

6. CONTROL, ID AND TEST REGISTERS

The operation of each framer within the DS21Q42 is configured via a set of eleven control registers.
Typically, the control registers are only accessed when the system is first powered up. Once a channel in
the DS21Q42 has been initialized, the control registers will only need to be accessed when there is a
change in the system configuration. There are two Receive Control Register (RCR1 and RCR2), two
Transmit Control Registers (TCR1 and TCR2), and seven Common Control Registers (CCR1 to CCR7).
Each of the eleven registers are described in this section. There is a device Identification Register (IDR)
at address 0Fh. The MSB of this readonly register is fixed to a zero indicating that the DS21Q42 is
present. The E1 pinforpin compatible version of the DS21Q42 is the DS21Q44 and it also has an ID
register at address 0Fh and the user can read the MSB to determine which chip is present since in the
DS21Q42 the MSB will be set to a zero and in the DS21Q44 it will be set to a one. The lower four bits of
the IDR are used to display the die revision of the chip.

PowerUp Sequence

The DS21Q42 does not automatically clear its register space on powerup. After the supplies are stable,
each of the four framer's register space should be configured for operation by writing to all of the internal
registers. This includes setting the Test and all unused registers to 00Hex.

This can be accomplished using a two-pass approach on each framer within the DS21Q42.

Clear framer's register space by writing 00H to the addresses 00H through 09FH.

Program required registers to achieve desired operating mode.

Note:

When emulating the DS21Q41 feature set (FMS = 1), the full address space (00H through 09FH) must be
initialized. DS21Q41 emulation requires address pin A7 to be used.

Finally, after the TSYSCLK and RSYSCLK inputs are stable, the ESR bit should be toggled from a zero
to a one (this step can be skipped if the elastic stores are disabled).

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IDR: DEVICE IDENTIFICATION REGISTER (Address=0F Hex)

(MSB)

(LSB)

T1E1

ID3

ID2

ID1

ID0

SYMBOL

POSITION

NAME AND DESCRIPTION

T1E1

IDR.7

T1 or E1 Chip Determination Bit.
0=T1 chip
1=E1 chip

ID3

IDR.3

Chip Revision Bit 3. MSB of a decimal code that represents the chip

revision.

ID2

IDR.1

Chip Revision Bit 2.

ID1

IDR.2

Chip Revision Bit 1.

ID0

IDR.0

Chip Revision Bit 0. LSB of a decimal code that represents the chip
revision.

RCR1: RECEIVE CONTROL REGISTER 1 (Address=2B Hex)

(MSB)

(LSB)

LCVCRF

ARC

OOF1

OOF2

SYNCC

SYNCT

SYNCE

RESYNC

SYMBOL

POSITION

NAME AND DESCRIPTION

LCVCRF

RCR1.7

Line Code Violation Count Register Function Select.
0 = do not count excessive zeros
1 = count excessive zeros

ARC

RCR1.6

Auto Resync Criteria.
0 = Resync on OOF or RCL event
1 = Resync on OOF only

OOF1

RCR1.5

Out Of Frame Select 1.
0 = 2/4 frame bits in error
1 = 2/5 frame bits in error

OOF2

RCR1.4

Out Of Frame Select 2.
0 = follow RCR1.5
1 = 2/6 frame bits in error

SYNCC

RCR1.3

Sync Criteria.
In D4 Framing Mode.
0 = search for Ft pattern, then search for Fs pattern
1 = cross couple Ft and Fs pattern
In ESF Framing Mode.
0 = search for FPS pattern only
1 = search for FPS and verify with CRC6

SYNCT

RCR1.2

Sync Time.
0 = qualify 10 bits
1 = qualify 24 bits

SYNCE

RCR1.1

Sync Enable.
0 = auto resync enabled
1 = auto resync disabled

RESYNC

RCR1.0

Resync. When toggled from low to high, a resynchronization of the
receive side framer is initiated. Must be cleared and set again for a
subsequent resync.

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RCR2: RECEIVE CONTROL REGISTER 2 (Address=2C Hex)

(MSB)

(LSB)

RCS

RZBTSI

RSDW

RSM

RSIO

RD4YM

FSBE

MOSCRF

SYMBOL

POSITION

NAME AND DESCRIPTION

RCS

RCR2.7

Receive Code Select. See Section 11 for more details.
0 = idle code (7F Hex)
1 = digital milliwatt code (1E/0B/0B/1E/9E/8B/8B/9E Hex)

RZBTSI

RCR2.6

Receive Side ZBTSI Enable.
0 = ZBTSI disabled
1 = ZBTSI enabled

RSDW

RCR2.5

RSYNC DoubleWide. (note: this bit must be set to zero when
RCR2.4 = 1 or when RCR2.3 = 1)
0 = do not pulse double wide in signaling frames
1 = do pulse double wide in signaling frames

RSM

RCR2.4

RSYNC Mode Select. (A Don't Care if RSYNC is programmed as
an input)
0 = frame mode (see the timing in Section 20)
1 = multiframe mode (see the timing in Section 20)

RSIO

RCR2.3

RSYNC I/O Select. (note: this bit must be set to zero when CCR1.2
= 0)
0 = RSYNC is an output
1 = RSYNC is an input (only valid if elastic store enabled)

RD4YM

RCR2.2

Receive Side D4 Yellow Alarm Select.
0 = zeros in bit 2 of all channels
1 = a one in the Sbit position of frame 12

FSBE

RCR2.1

PCVCR FsBit Error Report Enable.
0 = do not report bit errors in Fsbit position; only Ft bit position
1 = report bit errors in Fsbit position as well as Ft bit position

MOSCRF

RCR2.0

Multiframe Out of Sync Count Register Function Select.
0 = count errors in the framing bit position
1 = count the number of multiframes out of sync

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TCR1: TRANSMIT CONTROL REGISTER 1 (Address=35 Hex)

(MSB)

(LSB)

LOTCMC

TFPT

TCPT

TSSE

GB7S

TFDLS

TBL

TYEL

SYMBOL

POSITION

NAME AND DESCRIPTION

LOTCMC

TCR1.7

Loss Of Transmit Clock Mux Control. Determines whether the
transmit side formatter should switch to RCLK if the TCLK input
should fail to transition (see Figure 1.1 for details).
0 = do not switch to RCLK if TCLK stops
1 = switch to RCLK if TCLK stops

TFPT

TCR1.6

Transmit FBit Pass Through. (see note below)
0 = F bits sourced internally
1 = F bits sampled at TSER

TCPT

TCR1.5

Transmit CRC Pass Through. (see note below)
0 = source CRC6 bits internally
1 = CRC6 bits sampled at TSER during Fbit time

TSSE

TCR1.4

Software Signaling Insertion Enable. (see note below)
0 = no signaling is inserted in any channel
1 = signaling is inserted in all channels from the TS1-TS12 registers
(the TTR registers can be used to block insertion on a channel by
channel basis)

GB7S

TCR1.3

Global Bit 7 Stuffing. (see note below)
0 = allow the TTR registers to determine which channels containing
all zeros are to be Bit 7 stuffed
1 = force Bit 7 stuffing in all zero byte channels regardless of how
the
TTR registers are programmed

TFDLS

TCR1.2

TFDL Register Select. (see note below)
0 = source FDL or Fs bits from the internal TFDL register (legacy
FDL support mode)
1 = source FDL or Fs bits from the internal HDLC/BOC controller
or the TLINK pin

TBL

TCR1.1

Transmit Blue Alarm. (see note below)
0 = transmit data normally
1 = transmit an unframed all one's code at TPOS and TNEG

TYEL

TCR1.0

Transmit Yellow Alarm. (see note below)
0 = do not transmit yellow alarm
1 = transmit yellow alarm

Note:

For a description of how the bits in TCR1 affect the transmit side formatter, see Figure 20-15.

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TCR2: TRANSMIT CONTROL REGISTER 2 (Address=36 Hex)

(MSB)

(LSB)

TEST1

TEST0

TZBTSI

TSDW

TSM

TSIO

TD4YM

TB7ZS

SYMBOL

POSITION

NAME AND DESCRIPTION

TEST1

TCR2.7

Test Mode Bit 1 for Output Pins. See Table 61.

TEST0

TCR2.6

Test Mode Bit 0 for Output Pins. See Table 61.

TZBTSI

TCR2.5

Transmit Side ZBTSI Enable.
0 = ZBTSI disabled
1 = ZBTSI enabled

TSDW

TCR2.4

TSYNC DoubleWide. (note: this bit must be set to zero when
TCR2.3=1 or when TCR2.2=0)
0 = do not pulse doublewide in signaling frames
1 = do pulse doublewide in signaling frames

TSM

TCR2.3

TSYNC Mode Select.
0 = frame mode (see the timing in Section 20)
1 = multiframe mode (see the timing in Section 20)

TSIO

TCR2.2

TSYNC I/O Select.
0 = TSYNC is an input
1 = TSYNC is an output

TD4YM

TCR2.1

Transmit Side D4 Yellow Alarm Select.
0 = zeros in bit 2 of all channels
1 = a one in the Sbit position of frame 12

TB7ZS

TCR2.0

Transmit Side Bit 7 Zero Suppression Enable.
0 = no stuffing occurs
1 = Bit 7 force to a one in channels with all zeros

OUTPUT PIN TEST MODES Table 6-1

TEST 1

TEST 0

EFFECT ON OUTPUT PINS

operate normally

force all of the selected framer's output pins 3state (excludes other
framers I/O pins and parallel port pins)

force all of the selected framer's output pins low (excludes other
framers I/O pins and parallel port pins)

force all of the selected framer's output pins high (excludes other
framers I/O pins and parallel port pins)

DS21Q42

31 of 119

CCR1: COMMON CONTROL REGISTER 1 (Address=37 Hex)

(MSB)

(LSB)

TESE

ODF

RSAO

TSCLKM

RSCLKM

RESE

PLB

FLB

SYMBOL

POSITION

NAME AND DESCRIPTION

TESE

CCR1.7

Transmit Elastic Store Enable.
0 = elastic store is bypassed
1 = elastic store is enabled

ODF

CCR1.6

Output Data Format.
0 = bipolar data at TPOS and TNEG
1 = NRZ data at TPOS; TNEG = 0

RSAO

CCR1.5

Receive Signaling All One's. This bit should not be enabled if
hardware signaling is being utilized. See Section 10 for more details.
0 = allow robbed signaling bits to appear at RSER
1 = force all robbed signaling bits at RSER to one

TSCLKM

CCR1.4

TSYSCLK Mode Select.
0 = if TSYSCLK is 1.544 MHz
1 = if TSYSCLK is 2.048 MHz

RSCLKM

CCR1.3

RSYSCLK Mode Select.
0 = if RSYSCLK is 1.544 MHz
1 = if RSYSCLK is 2.048 MHz

RESE

CCR1.2

Receive Elastic Store Enable.
0 = elastic store is bypassed
1 = elastic store is enabled

PLB

CCR1.1

Payload Loopback.
0 = loopback disabled
1 = loopback enabled

FLB

CCR1.0

Framer Loopback.
0 = loopback disabled
1 = loopback enabled

Payload Loopback

When CCR1.1 is set to a one, the DS21Q42 will be forced into Payload LoopBack (PLB). Normally, this
loopback is only enabled when ESF framing is being performed but can be enabled also in D4 framing
applications. In a PLB situation, the DS21Q42 will loop the 192 bits of payload data (with BPVs
corrected) from the receive section back to the transmit section. The FPS framing pattern, CRC6
calculation, and the FDL bits are not looped back, they are reinserted by the DS21Q42. When PLB is
enabled, the following will occur:

Data will be transmitted from the TPOS and TNEG pins synchronous with RCLK instead of TCLK

All of the receive side signals will continue to operate normally

The TCHCLK and TCHBLK signals are forced low

Data at the TSER, and TSIG pins is ignored

The TLCLK signal will become synchronous with RCLK instead of TCLK.

DS21Q42

32 of 119

Framer Loopback

When CCR1.0 is set to a one, the DS21Q42 will enter a Framer LoopBack (FLB) mode. This loopback is
useful in testing and debugging applications. In FLB, the DS21Q42 will loop data from the transmit side
back to the receive side. When FLB is enabled, the following will occur:

an unframed all one's code will be transmitted at TPOS and TNEG

data at RPOS and RNEG will be ignored

all receive side signals will take on timing synchronous with TCLK instead of RCLK

Please note that it is not acceptable to have RCLK tied to TCLK during this loopback because this will
cause an unstable condition.

CCR2: COMMON CONTROL REGISTER 2 (Address=38 Hex)

(MSB)

(LSB)

TFM

TB8ZS

TSLC96

TZSE

RFM

RB8ZS

RSLC96

RZSE

SYMBOL

POSITION

NAME AND DESCRIPTION

TFM

CCR2.7

Transmit Frame Mode Select.
0 = D4 framing mode
1 = ESF framing mode

TB8ZS

CCR2.6

Transmit B8ZS Enable.
0 = B8ZS disabled
1 = B8ZS enabled

TSLC96

CCR2.5

Transmit SLC96 / FsBit Insertion Enable. Only set this bit to a
one in D4 framing applications. Must be set to one to source the Fs
pattern. See Section 15 for details.
0 = SLC96/Fsbit insertion disabled
1 = SLC96/Fsbit insertion enabled

TZSE

CCR2.4

Transmit FDL Zero Stuffer Enable. Set this bit to zero if using
the internal HDLC/BOC controller instead of the legacy support for
the FDL. See Section 15 for details.
0 = zero stuffer disabled
1 = zero stuffer enabled

RFM

CCR2.3

Receive Frame Mode Select.
0 = D4 framing mode
1 = ESF framing mode

RB8ZS

CCR2.2

Receive B8ZS Enable.
0 = B8ZS disabled
1 = B8ZS enabled

RSLC96

CCR2.1

Receive SLC96 Enable. Only set this bit to a one in D4/SLC96
framing applications. See Section 15 for details.
0 = SLC96 disabled
1 = SLC96 enabled

DS21Q42

33 of 119

SYMBOL

POSITION

NAME AND DESCRIPTION

RZSE

CCR2.0

Receive FDL Zero Destuffer Enable. Set this bit to zero if using
the internal HDLC/BOC controller instead of the legacy support for
the FDL. See Section 15 for details.
0 = zero destuffer disabled
1 = zero destuffer enabled

CCR3: COMMON CONTROL REGISTER 3 (Address=30 Hex)

(MSB)

LSB)

RESMDM TCLKSRC RLOSF

RSMS

PDE

ECUS

TLOOP

TESMDM

SYMBOL

POSITION

NAME AND DESCRIPTION

RESMDM

CCR3.7

Receive Elastic Store Minimum Delay Mode. See Section 13 for
details.
0 = elastic stores operate at full two frame depth
1 = elastic stores operate at 32bit depth

TCLKSRC

CCR3.6

Transmit Clock Source Select. This function allows the user to
internally select RCLK as the clock source for the transmit side
formatter.
0 = Transmit side formatter clocked with signal applied at TCLK
pin.
LOTC Mux function is operational (TCR1.7)
1 = Transmit side formatter clocked with RCLK.

RLOSF

CCR3.5

Function of the RLOS/LOTC Output. Active only when FMS = 1
(DS21Q41 emulation).
0 = Receive Loss of Sync (RLOS)
1 = Loss of Transmit Clock (LOTC)

RSMS

CCR3.4

RSYNC Multiframe Skip Control. Useful in framing format
conversions from D4 to ESF. This function is not available when
the receive side elastic store is enabled.
0 = RSYNC will output a pulse at every multiframe
1 = RSYNC will output a pulse at every other multiframe note: for
this
bit to have any affect, the RSYNC must be set to output multiframe
pulses (RCR2.4=1 and RCR2.3=0).

PDE

CCR3.3

Pulse Density Enforcer Enable.
0 = disable transmit pulse density enforcer
1 = enable transmit pulse density enforcer

ECUS

CCR3.2

Error Counter Update Select. See Section 8 for details.
0 = update error counters once a second
1 = update error counters every 42 ms (333 frames)

TLOOP

CCR3.1

Transmit Loop Code Enable. See Section 16 for details.
0 = transmit data normally
1 = replace normal transmitted data with repeating code as defined
in TCD register

DS21Q42

34 of 119

SYMBOL

POSITION

NAME AND DESCRIPTION

TESMDM

CCR3.0

Transmit Elastic Store Minimum Delay Mode. See Section 13
for details.
0 = elastic stores operate at full two frame depth
1 = elastic stores operate at 32bit depth

Pulse Density Enforcer

The Framer always examines both the transmit and receive data streams for violations of the following
rules which are required by ANSI T1.403:

no more than 15 consecutive zeros

at least N ones in each and every time window of 8 x (N +1) bits where N = 1 through 23

Violations for the transmit and receive data streams are reported in the RIR2.0 and RIR2.1 bits
respectively. When the CCR3.3 is set to one, the DS21Q42 will force the transmitted stream to meet this
requirement no matter the content of the transmitted stream. When running B8ZS, the CCR3.3 bit should
be set to zero since B8ZS encoded data streams cannot violate the pulse density requirements.

CCR4: COMMON CONTROL REGISTER 4 (Address=11 Hex)

(MSB)

(LSB)

RSRE

RPCSI

RFSA1

RFE

RFF

THSE

TPCSI

TIRFS

SYMBOL

POSITION

NAME AND DESCRIPTION

RSRE

CCR4.7

Receive Side Signaling ReInsertion Enable. See Section 10 for
details.
0 = do not reinsert signaling bits into the data stream presented at
the RSER pin
1 = reinsert the signaling bits into data stream presented at the
RSER pin

RPCSI

CCR4.6

Receive PerChannel Signaling Insert. See Section 10 for more
details.
0 = do not use RCHBLK to determine which channels should have
signaling reinserted
1 = use RCHBLK to determine which channels should have
signaling reinserted

RFSA1

CCR4.5

Receive Force Signaling All Ones. See Section 10 for more
details.
0 = do not force extracted robbedbit signaling bit positions to a one
1 = force extracted robbedbit signaling bit positions to a one

RFE

CCR4.4

Receive Freeze Enable. See Section 10 for details.
0 = no freezing of receive signaling data will occur
1 = allow freezing of receive signaling data at RSIG (and RSER if
CCR4.7 = 1).

DS21Q42

35 of 119

SYMBOL

POSITION

NAME AND DESCRIPTION

RFF

CCR4.3

Receive Force Freeze. Freezes receive side signaling at RSIG (and
RSER if CCR4.7=1); will override Receive Freeze Enable (RFE).
See Section 10 for details.
0 = do not force a freeze event
1 = force a freeze event

THSE

CCR4.2

Transmit Hardware Signaling Insertion Enable. See Section 10
for details.
0 = do not insert signaling from the TSIG pin into the data stream
presented at the TSER pin.
1 = Insert the signaling from the TSIG pin into data stream
presented at the TSER pin.

TPCSI

CCR4.1

Transmit PerChannel Signaling Insert. See Section 10 for
details.
0 = do not use TCHBLK to determine which channels should have
signaling inserted from the TSIG pin.
1 = use TCHBLK to determine which channels should have
signaling inserted from the TSIG pin.

TIRFS

CCR4.0

Transmit Idle Registers (TIR) Function Select. See Section 11
for timing details.
0 = TIRs define in which channels to insert idle code
1 = TIRs define in which channels to insert data from RSER (i.e.,
Per = Channel Loopback function)

CCR5: COMMON CONTROL REGISTER 5 (Address=19 Hex)

(MSB)

(LSB)

TJC

TCM4

TCM3

TCM2

TCM1

TCM0

SYMBOL

POSITION

NAME AND DESCRIPTION

TJC

CCR5.7

Transmit Japanese CRC6 Enable.
0 = use ANSI/AT&T/ITU CRC6 calculation (normal operation)
1 = use Japanese standard JTG704 CRC6 calculation

CCR5.6

Not Assigned. Must be set to zero when written.

CCR5.5

Not Assigned. Must be set to zero when written.

TCM4

CCR5.4

Transmit Channel Monitor Bit 4. MSB of a channel decode that
determines which transmit channel data will appear in the TDS0M
register. See Section 9 for details.

TCM3

CCR5.3

Transmit Channel Monitor Bit 3.

TCM2

CCR5.2

Transmit Channel Monitor Bit 2.

TCM1

CCR5.1

Transmit Channel Monitor Bit 1.

TCM0

CCR5.0

Transmit Channel Monitor Bit 0. LSB of the channel decode.

DS21Q42

36 of 119

CCR6: COMMON CONTROL REGISTER 6 (Address=1E Hex)

(MSB)

(LSB)

RJC

RESALGN

TESALGN

RCM4

RCM3

RCM2

RCM1

RCM0

SYMBOL

POSITION

NAME AND DESCRIPTION

RJC

CCR6.7

Receive Japanese CRC6 Enable.
0 = use ANSI/AT&T/ITU CRC6 calculation (normal operation)
1 = use Japanese standard JTG704 CRC6 calculation

RESALGN

CCR6.6

Receive Elastic Store Align. Setting this bit from a zero to a one
may force the receive elastic store's write/read pointers to a
minimum separation of half a frame. No action will be taken if the
pointer separation is already greater or equal to half a frame. If
pointer separation is less then half a frame, the command will be
executed and data will be disrupted. Should be toggled after
RSYSCLK has been applied and is stable. Must be cleared and set
again for a subsequent align. See Section 13 for details.

TESALGN

CCR6.5

Transmit Elastic Store Align. Setting this bit from a zero to a one
may force the transmit elastic store's write/read pointers to a
minimum separation of half a frame. No action will be taken if the
pointer separation is already greater or equal to half a frame. If
pointer separation is less then half a frame, the command will be
executed and data will be disrupted. Should be toggled after
TSYSCLK has been applied and is stable. Must be cleared and set
again for a subsequent align. See Section 13 for details.

RCM4

CCR6.4

Receive Channel Monitor Bit 4. MSB of a channel decode that
determines which receive channel data will appear in the RDS0M
register. See Section 9 for details.

RCM3

CCR6.3

Receive Channel Monitor Bit 3.

RCM2

CCR6.2

Receive Channel Monitor Bit 2.

RCM1

CCR6.1

Receive Channel Monitor Bit 1.

RCM0

CCR6.0

Receive Channel Monitor Bit 0. LSB of the channel decode.

DS21Q42

37 of 119

CCR7: COMMON CONTROL REGISTER 7 (Address=0A Hex)

(MSB)

(LSB)

RLB

RESR

TESR

SYMBOL

POSITION

NAME AND DESCRIPTION

CCR7.7

Not Assigned. Should be set to zero when written to.

RLB

CCR7.6

Remote Loopback.
0 = loopback disabled
1 = loopback enabled

RESR

CCR7.5

Receive Elastic Store Reset. Setting this bit from a zero to a one
will force the receive elastic store to a depth of one frame. Receive
data is lost during the reset. Should be toggled after RSYSCLK has
been applied and is stable. Do not leave this bit set high.

TESR

CCR7.4

Transmit Elastic Store Reset. Setting this bit from a zero to a one
will force the transmit elastic store to a depth of one frame.
Transmit data is lost during the reset. Should be toggled after
TSYSCLK has been applied and is stable. Do not leave this bit set
high.

CCR7.3

Not Assigned. Should be set to zero when written to.

CCR7.2

Not Assigned. Should be set to zero when written to.

CCR7.1

Not Assigned. Should be set to zero when written to.

CCR7.0

Not Assigned. Should be set to zero when written to.

Remote Loopback

When CCR7.6 is set to a one, the DS21Q42 will be forced into Remote LoopBack (RLB). In this
loopback, data input via the RPOS and RNEG pins will be transmitted back to the TPOS and TNEG pins.
Data will continue to pass through the receive side framer of the DS21Q42 as it would normally and the
data from the transmit side formatter will be ignored. Please see Figure 1-1 for more details.

7. STATUS AND INFORMATION REGISTERS

There is a set of nine registers per channel that contain information on the current real time status of a
framer in the DS21Q42, Status Register 1 (SR1), Status Register 2 (SR2), Receive Information Registers
1 to 3 (RIR1/RIR2/RIR3) and a set of four registers for the onboard HDLC and BOC controller. The
specific details on the four registers pertaining to the HDLC and BOC controller are covered in Section
15 but they operate the same as the other status registers in the DS21Q42 and this operation is described
below.

When a particular event has occurred (or is occurring), the appropriate bit in one of these nine registers
will be set to a one. All of the bits in SR1, SR2, RIR1, RIR2, and RIR3 registers operate in a latched
fashion. This means that if an event or an alarm occurs and a bit is set to a one in any of the registers, it
will remain set until the user reads that bit. The bit will be cleared when it is read and it will not be set
again until the event has occurred again (or in the case of the RBL, RYEL, LRCL, and RLOS alarms, the
bit will remain set if the alarm is still present). There are bits in the four HDLC and BOC status registers
that are not latched and these bits are listed in Section 15.

DS21Q42

38 of 119

The user will always precede a read of any of the nine registers with a write. The byte written to the
register will inform the DS21Q42 which bits the user wishes to read and have cleared. The user will write
a byte to one of these registers, with a one in the bit positions he or she wishes to read and a zero in the
bit positions he or she does not wish to obtain the latest information on. When a one is written to a bit
location, the read register will be updated with the latest information. When a zero is written to a bit
position, the read register will not be updated and the previous value will be held. A write to the status
and information registers will be immediately followed by a read of the same register. The read result
should be logically AND'ed with the mask byte that was just written and this value should be written
back into the same register to insure that bit does indeed clear. This second write step is necessary
because the alarms and events in the status registers occur asynchronously in respect to their access via
the parallel port. This writeread write scheme allows an external microcontroller or microprocessor to
individually poll certain bits without disturbing the other bits in the register. This operation is key in
controlling the DS21Q42 with higherorder software languages.

The SR1, SR2, and FDLS registers have the unique ability to initiate a hardware interrupt via the INT*
output pin. Each of the alarms and events in the SR1, SR2, and HSR can be either masked or unmasked
from the interrupt pin via the Interrupt Mask Register 1 (IMR1), Interrupt Mask Register 2 (IMR2), and
HDLC Interrupt Mask Register (HIMR) respectively. The FIMR register is covered in Section 15. The
INTERRUPT STATUS REGISTER can be used to determine which framer is requesting interrupt
servicing and the type of the request: status or the HDLC controller.

The interrupts caused by alarms in SR1 (namely RYEL, RCL, RBL, RLOS and LOTC) act differently
than the interrupts caused by events in SR1 and SR2 (namely LUP, LDN, RSLIP, RMF, TMF, SEC,
RFDL, TFDL, RMTCH, RAF, and RSC) and HIMR. The alarm caused interrupts will force the INT* pin
low whenever the alarm changes state (i.e., the alarm goes active or inactive according to the set/clear
criteria in Table 7-1). The INT* pin will be allowed to return high (if no other interrupts are present)
when the user reads the alarm bit that caused the interrupt to occur even if the alarm is still present.

The event caused interrupts will force the INT* pin low when the event occurs. The INT* pin will be
allowed to return high (if no other interrupts are present) when the user reads the event bit that caused the
interrupt to occur.

ISR: INTERRUPT STATUS REGISTER (Any address from A0H to FFH)

(MSB)

(LSB)

F3HDLC

F3SR

F2HDLC

F2SR

F1HDLC

F1SR

F0HDLC

F0SR

SYMBOL

POSITION

NAME AND DESCRIPTION

F3HDLC

ISR.7

FRAMER 3 HDLC CONTROLLER INTERRUPT
REQUEST.
0 = No interrupt request pending.
1 = Interrupt request pending.

F3SR

ISR.6

FRAMER 3 SR1 or SR2 INTERRUPT REQUEST.
0 = No interrupt request pending.
1 = Interrupt request pending.

F2HDLC

ISR.5

FRAMER 2 HDLC CONTROLLER INTERRUPT
REQUEST.
0 = No interrupt request pending.
1 = Interrupt request pending.

DS21Q42

39 of 119

SYMBOL

POSITION

NAME AND DESCRIPTION

F2SR

ISR.4

FRAMER 2 SR1 or SR2 INTERRUPT REQUEST.
0 = No interrupt request pending.
1 = Interrupt request pending.

F1HDLC

ISR.3

FRAMER 1 HDLC CONTROLLER INTERRUPT
REQUEST.
0 = No interrupt request pending.
1 = Interrupt request pending.

F1SR

ISR.2

FRAMER 1 SR1 or SR2 INTERRUPT REQUEST.
0 = No interrupt request pending.
1 = Interrupt request pending.

F0HDLC

ISR.1

FRAMER 0 HDLC CONTROLLER INTERRUPT
REQUEST.
0 = No interrupt request pending.
1 = Interrupt request pending.

F0SR ISR

FRAMER 0 SR1 or SR2 INTERRUPT REQUEST.
0 = No interrupt request pending.
1 = Interrupt request pending.

RIR1: RECEIVE INFORMATION REGISTER 1 (Address=22 Hex)

(MSB)

(LSB)

COFA

8ZD

16ZD

RESF

RESE

SEFE

B8ZS

FBE

SYMBOL

POSITION

NAME AND DESCRIPTION

COFA

RIR1.7

Change of Frame Alignment. Set when the last resync
resulted in a change of frame or multiframe alignment.

8ZD

RIR1.6

Eight Zero Detect. Set when a string of at least eight
consecutive zeros (regardless of the length of the string) have
been received at RPOS and RNEG.

16ZD

RIR1.5

Sixteen Zero Detect. Set when a string of at least sixteen
consecutive zeros (regardless of the length of the string) have
been received at RPOS and RNEG.

RESF

RIR1.4

Receive Elastic Store Full. Set when the receive elastic store
buffer fills and a frame is deleted.

RESE

RIR1.3

Receive Elastic Store Empty. Set when the receive elastic
store buffer empties and a frame is repeated.

SEFE

RIR1.2

Severely Errored Framing Event. Set when 2 out of 6
framing bits (Ft or FPS) are received in error.

B8ZS

RIR1.1

B8ZS Code Word Detect. Set when a B8ZS code word is
detected at RPOS and RNEG independent of whether the
B8ZS mode is selected or not via CCR2.6. Useful for
automatically setting the line coding.

FBE

RIR1.0

Frame Bit Error. Set when a Ft (D4) or FPS (ESF) framing
bit is received in error.

DS21Q42

40 of 119

RIR2: RECEIVE INFORMATION REGISTER 2 (Address=31 Hex)

(MSB)

(LSB)

RLOSC

RCLC

TESF

TESE

TSLIP

RBLC

RPDV

TPDV

SYMBOL

POSITION

NAME AND DESCRIPTION

RLOSC

RIR2.7

Receive Loss of Sync Clear. Set when the framer achieves
synchronization; will remain set until read.

RCLC

RIR2.6

Receive Carrier Loss Clear. Set when the carrier signal is
restored; will remain set until read. See Table 7-1.

TESF

RIR2.5

Transmit Elastic Store Full. Set when the transmit elastic
store buffer fills and a frame is deleted.

TESE

RIR2.4

Transmit Elastic Store Empty. Set when the transmit elastic
store buffer empties and a frame is repeated.

TSLIP

RIR2.3

Transmit Elastic Store Slip Occurrence. Set when the
transmit elastic store has either repeated or deleted a frame.

RBLC

RIR2.2

Receive Blue Alarm Clear. Set when the Blue Alarm (AIS)
is no longer detected; will remain set until read. See Table 7-1.

RPDV

RIR2.1

Receive Pulse Density Violation. Set when the receive data
stream does not meet the ANSI T1.403 requirements for pulse
density.

TPDV

RIR2.0

Transmit Pulse Density Violation. Set when the transmit
data stream does not meet the ANSI T1.403 requirements for
pulse density.

RIR3: RECEIVE INFORMATION REGISTER 3 (Address=10 Hex)

(MSB)

(LSB)

LORC

RAIS-CI

SYMBOL

POSITION

NAME AND DESCRIPTION

RIR3.7

Not Assigned. Could be any value when read.

RIR3.6

Not Assigned. Could be any value when read.

RIR3.5

Not Assigned. Could be any value when read.

LORC

RIR3.4

Loss of Receive Clock. Set when the RCLK pin has not
transitioned for at least 2 us (3 us ~~1 us).

RIR3.3

Not Assigned. Could be any value when read.

RIR3.2

Not Assigned. Could be any value when read.

RIR3.1

Not Assigned. Could be any value when read.

RAIS-CI

RIR3.0

Receive AIS-CI Detect. Set when the AIS-CI pattern is
detected.

DS21Q42

41 of 119

SR1: STATUS REGISTER 1 (Address=20 Hex)

(MSB)

(LSB)

LUP

LDN

LOTC

RSLIP

RBL

RYEL

RCL

RLOS

SYMBOL

POSITION

NAME AND DESCRIPTION

LUP

SR1.7

Loop Up Code Detected. Set when the loop up code as
defined in the RUPCD register is being received. See Section
16 for details.

LDN

SR1.6

Loop Down Code Detected. Set when the loop down code as
defined in the RDNCD register is being received. See Section
16 for details.

LOTC

SR1.5

Loss of Transmit Clock. Set when the TCLK pin has not
transitioned for one channel time (or 5.2 us). Will force the
RLOS/LOTC pin high if enabled via CCR3.5. Also will force
transmit side formatter to switch to RCLK if so enabled via
TCR1.7.

RSLIP

SR1.4

Receive Elastic Store Slip Occurrence. Set when the receive
elastic store has either repeated or deleted a frame.

RBL

SR1.3

Receive Blue Alarm. Set when an unframed all one's code is
received at RPOS and RNEG.

RYEL

SR1.2

Receive Yellow Alarm. Set when a yellow alarm is received
at RPOS and RNEG.

RCL

SR1.1

Receive Carrier Loss. Set when a red alarm is received at
RPOS and RNEG.

RLOS

SR1.0

Receive Loss of Sync. Set when the device is not
synchronized to the receive T1 stream.

DS21Q42

42 of 119

ALARM CRITERIA Table 7-1

ALARM

SET CRITERIA

CLEAR CRITERIA

Blue Alarm (AIS)
(see note 1 below)

when over a 3 ms window, 5 or
less zeros are received

when over a 3 ms window, 6 or
more zeros are received

Yellow Alarm (RAI)
1.

D4 bit 2 mode(RCR2.2=0)

when bit 2 of 256 consecutive
channels is set to zero for at least
254 occurrences

when bit 2 of 256 consecutive
channels is set to zero for less
than 254 occurrences

D4 12th Fbit mode
(RCR2.2=1; this mode is also
referred to as the "Japanese
Yellow Alarm")

when the 12th framing bit is set
to one for two consecutive
occurrences

when the 12th framing bit is set
to zero for two consecutive
occurrences

ESF mode

when 16 consecutive patterns of
00FF appear in the FDL

when 14 or less patterns of 00FF
hex out of 16 possible appear in
the FDL

Red Alarm (RCL) (this alarm is
also referred to as Loss Of
Signal)

when 192 consecutive zeros are
received

when 14 or more ones out of 112
possible bit positions are received
starting with the first one
received

Notes:

The definition of Blue Alarm (or Alarm Indication Signal) is an unframed all ones signal. Blue alarm
detectors should be able to operate properly in the presence of a 103 error rate and they should not
falsely trigger on a framed all ones signal. The blue alarm criteria in the DS21Q42 has been set to
achieve this performance. It is recommended that the RBL bit be qualified with the RLOS bit.

ANSI specifications use a different nomenclature than the DS21Q42 does; the following terms are
equivalent:

RBL = AIS
RCL = LOS
RLOS = LOF
RYEL = RAI

DS21Q42

43 of 119

SR2: STATUS REGISTER 2 (Address=21 Hex)

(MSB)

(LSB)

RMF

TMF

SEC

RFDL

TFDL

RMTCH

RAF

RSC

SYMBOL

POSITION

NAME AND DESCRIPTION

RMF

SR2.7

Receive Multiframe. Set on receive multiframe boundaries.

TMF

SR2.6

Transmit Multiframe. Set on transmit multiframe boundaries.

SEC

SR2.5

One Second Timer. Set on increments of one second based on
RCLK; will be set in increments of 999 ms, 999 ms, and 1002
ms every 3 seconds.

RFDL

SR2.4

Receive FDL Buffer Full. Set when the receive FDL buffer
(RFDL) fills to capacity (8 bits).

TFDL

SR2.3

Transmit FDL Buffer Empty. Set when the transmit FDL
buffer (TFDL) empties.

RMTCH

SR2.2

Receive FDL Match Occurrence. Set when the RFDL
matches either RMTCH1 or RMTCH2.

RAF

SR2.1

Receive FDL Abort. Set when eight consecutive one's are
received in the FDL.

RSC

SR2.0

Receive Signaling Change. Set when the DS21Q42 detects a
change of state in any of the robbedbit signaling bits.

IMR1: INTERRUPT MASK REGISTER 1 (Address=7F Hex)

(MSB)

(LSB)

LUP

LDN

LOTC

SLIP

RBL

RYEL

RCL

RLOS

SYMBOL

POSITION

NAME AND DESCRIPTION

LUP

IMR1.7

Loop Up Code Detected.
0 = interrupt masked
1 = interrupt enabled

LDN

IMR1.6

Loop Down Code Detected.
0 = interrupt masked
1 = interrupt enabled

LOTC

IMR1.5

Loss of Transmit Clock.
0 = interrupt masked
1 = interrupt enabled

SLIP

IMR1.4

Elastic Store Slip Occurrence.
0 = interrupt masked
1 = interrupt enabled

RBL

IMR1.3

Receive Blue Alarm.
0 = interrupt masked
1 = interrupt enabled

RYE

IMR1.2

Receive Yellow Alarm.
0 = interrupt masked
1 = interrupt enabled

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SYMBOL

POSITION

NAME AND DESCRIPTION

RCL

IMR1.1

Receive Carrier Loss.
0 = interrupt masked
1 = interrupt enabled

RLOS

IMR1.0

Receive Loss of Sync.
0 = interrupt masked
1 = interrupt enabled

IMR2: INTERRUPT MASK REGISTER 2 (Address=6F Hex)

(MSB)

(LSB)

RMF

TMF

SEC

RFDL

TFDL

RMTCH

RAF

RSC

SYMBOL

POSITION

NAME AND DESCRIPTION

RMF

IMR2.7

Receive Multiframe.
0 = interrupt masked
1 = interrupt enabled

TMF

IMR2.6

Transmit Multiframe.
0 = interrupt masked
1 = interrupt enabled

SEC

IMR2.5

One Second Timer.
0 = interrupt masked
1 = interrupt enabled

RFDL

IMR2.4

Receive FDL Buffer Full.
0 = interrupt masked
1 = interrupt enabled

TFDL

IMR2.3

Transmit FDL Buffer Empty.
0 = interrupt masked
1 = interrupt enabled

RMTCH

IMR2.2

Receive FDL Match Occurrence.
0 = interrupt masked
1 = interrupt enabled

RAF

IMR2.1

Receive FDL Abort.
0 = interrupt masked
1 = interrupt enabled

RSC

IMR2.0

Receive Signaling Change.
0 = interrupt masked
1 = interrupt enabled

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8. ERROR COUNT REGISTERS

There are a set of three counters in each framer that record bipolar violations, excessive zeros, errors in
the CRC6 code words, framing bit errors, and number of multiframes that the device is out of receive
synchronization. Each of these three counters are automatically updated on either one second boundaries
(CCR3.2=0) or every 42 ms (CCR3.2=1) as determined by the timer in Status Register 2 (SR2.5). Hence,
these registers contain performance data from either the previous second or the previous 42 ms. The user
can use the interrupt from the one second timer to determine when to read these registers. The user has a
full second (or 42 ms) to read the counters before the data is lost. All three counters will saturate at their
respective maximum counts and they will not rollover (note: only the Line Code Violation Count Register
has the potential to overflow but the bit error would have to exceed 10

-2

before this would occur).

Line Code Violation Count Register (LCVCR)

Line Code Violation Count Register 1 (LCVCR1) is the most significant word and LCVCR2 is the least
significant word of a 16bit counter that records code violations (CVs). CVs are defined as Bipolar
Violations (BPVs) or excessive zeros. See Table 8-1 for details of exactly what the LCVCRs count. If the
B8ZS mode is set for the receive side via CCR2.2, then B8ZS code words are not counted. This counter is
always enabled; it is not disabled during receive loss of synchronization (RLOS=1) conditions.

LCVCR1: LINE CODE VIOLATION COUNT REGISTER 1 (Address = 23 Hex)
LCVCR2: LINE CODE VIOLATION COUNT REGISTER 2 (Address = 24 Hex)

(MSB)

(LSB)

LCV15

LCV14

LCV13

LCV12

LCV11

LCV10

LCV9

LCV8

LCVCR1

LCV7

LCV6

LCV5

LCV4

LCV3

LCV2

LCV1

LCV0

LCVCR2

SYMBOL

POSITION

NAME AND DESCRIPTION

LCV15

LCVCR1.7

MSB of the 16bit code violation count

LCV0

LCVCR2.0

LSB of the 16bit code violation count

LINE CODE VIOLATION COUNTING ARRANGEMENTS Table 8-1

COUNT EXCESSIVE

ZEROS?

(RCR1.7)

B8ZS ENABLED?

(CCR2.2)

WHAT IS COUNTED

IN THE LCVCRs

BPVs

yes

BPVs + 16 consecutive zeros

yes

BPVs (B8ZS code words not
counted)

yes

BPV's + 8 consecutive zeros

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Path Code Violation Count Register

(PCVCR) When the receive side of a framer is set to operate in the ESF framing mode (CCR2.3=1),
PCVCR will automatically be set as a 12bit counter that will record errors in the CRC6 code words.
When set to operate in the D4 framing mode (CCR2.3=0), PCVCR will automatically count errors in the
Ft framing bit position. Via the RCR2.1 bit, a framer can be programmed to also report errors in the Fs
framing bit position. The PCVCR will be disabled during receive loss of synchronization (RLOS=1)
conditions. See Table 8-2 for a detailed description of exactly what errors the PCVCR counts.

PCVCR1: PATH VIOLATION COUNT REGISTER 1 (Address = 25 Hex)
PCVCR2: PATH VIOLATION COUNT REGISTER 2 (Address = 26 Hex)

(MSB)

(LSB)

(note 1)

CRC/
FB11

CRC/
FB10

CRC/
FB9

CRC/
FB8

PCVCR1

CRC/
FB7

CRC/
FB6

CRC/
FB5

CRC/
FB4

CRC/
FB3

CRC/
FB2

CRC/
FB1

CRC/
FB0

PCVCR2

SYMBOL

POSITION

NAME AND DESCRIPTION

CRC/FB11

PCVCR1.3

MSB of the 12Bit CRC6 Error or Frame Bit Error
Count (note#2)

CRC/FB0

PCVCR2.0

LSB of the 12Bit CRC6 Error or Frame Bit Error Count
(note#2)

Notes:

The upper nibble of the counter at address 25 is used by the Multiframes Out of Sync Count Register

PCVCR counts either errors in CRC code words (in the ESF framing mode; CCR2.3=1) or errors in
the framing bit position (in the D4 framing mode; CCR2.3=0).

PATH CODE VIOLATION COUNTING ARRANGEMENTS Table 8-2

FRAMING MODE

(CCR2.3)

COUNT Fs ERRORS?

(RCR2.1)

WHAT IS COUNTED IN THE

PCVCRs

errors in the Ft pattern

yes

errors in both the Ft & Fs
patterns

ESF

don't care

errors in the CRC6 code words

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MULTIFRAMES OUT OF SYNC COUNT REGISTER (MOSCR)

Normally the MOSCR is used to count the number of multiframes that the receive synchronizer is out of
sync (RCR2.0=1). This number is useful in ESF applications needing to measure the parameters Loss Of
Frame Count (LOFC) and ESF Error Events as described in AT&T publication TR54016. When the
MOSCR is operated in this mode, it is not disabled during receive loss of synchronization (RLOS=1)
conditions. The MOSCR has alternate operating mode whereby it will count either errors in the Ft
framing pattern (in the D4 mode) or errors in the FPS framing pattern (in the ESF mode). When the
MOSCR is operated in this mode, it is disabled during receive loss of synchronization (RLOS = 1)
conditions.

See Table 8-3 for a detailed description of what the MOSCR is capable of counting.

MOSCR1: MULTIFRAMES OUT OF SYNC COUNT REGISTER 1
(Address = 25 Hex)
MOSCR2: MULTIFRAMES OUT OF SYNC COUNT REGISTER 2
(Address = 27 Hex)

(MSB)

(LSB)

MOS/

FB11

MOS/

FB10

MOS/

FB9

MOS/

FB8

(note 1)

MOSCR

MOS/

FB7

MOS/

FB6

MOS/

FB5

MOS/

FB4

MOS/

FB3

MOS/

FB2

MOS/

FB1

MOS/

FB0

MOSCR

SYMBOL

POSITION

NAME AND DESCRIPTION

MOS/FB11

MOSCR1.7

MSB of the 12Bit Multiframes Out of Sync or FBit Error
Count (note #2)

MOS/FB0

MOSCR2.0

LSB of the 12Bit Multiframes Out of Sync or FBit Error
Count (note #2)

Notes:

The lower nibble of the counter at address 25 is used by the Path Code Violation Count Register

MOSCR counts either errors in framing bit position (RCR2.0=0) or the number of multiframes out of
sync (RCR2.0=1)

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MULTIFRAMES OUT OF SYNC COUNTING ARRANGEMENTS Table 8-3

FRAMING

MODE

(CCR2.3)

COUNT MOS

OR FBIT

ERRORS

(RCR2.0)

WHAT IS COUNTED IN THE MOSCRs

MOS

number of multiframes out of sync

FBit

errors in the Ft pattern

ESF

MOS

number of multiframes out of sync

ESF

FBit

errors in the FPS pattern

9. DS0 MONITORING FUNCTION

Each framer in the DS21Q42 has the ability to monitor one DS0 64 Kbps channel in the transmit
direction and one DS0 channel in the receive direction at the same time. In the transmit direction the user
will determine which channel is to be monitored by properly setting the TCM0 to TCM4 bits in the CCR5
register. In the receive direction, the RCM0 to RCM4 bits in the CCR6 register need to be properly set.
The DS0 channel pointed to by the TCM0 to TCM4 bits will appear in the Transmit DS0 Monitor
(TDS0M) register and the DS0 channel pointed to by the RCM0 to RCM4 bits will appear in the Receive
DS0 (RDS0M) register. The TCM4 to TCM0 and RCM4 to RCM0 bits should be programmed with the
decimal decode of the appropriate T1 channel. For example, if DS0 channel 6 (timeslot 5) in the transmit
direction and DS0 channel 15 (timeslot 14) in the receive direction needed to be monitored, then the
following values would be programmed into CCR5 and CCR6:

TCM4 = 0

RCM4 = 0

TCM3 = 0

RCM3 = 1

TCM2 = 1

RCM2 = 1

TCM1 = 0

RCM1 = 1

TCM0 = 1

RCM0 = 0

CCR5: COMMON CONTROL REGISTER 5 (Address=19 Hex)

[repeated here from section 6 for convenience]

(MSB)

(LSB)

TJC

TCM4

TCM3

TCM2

TCM1

TCM0

SYMBOL

POSITION

NAME AND DESCRIPTION

TJC

CCR5.7

Transmit Japanese CRC Enable. See Section 6 for details.

CCR5.5

Not Assigned. Must be set to zero when written.

CCR5.5

Not Assigned. Must be set to zero when written.

TCM4

CCR5.4

Transmit Channel Monitor Bit 4. MSB of a channel decode
that determines which transmit DS0 channel data will appear
in the TDS0M register.

TCM3

CCR5.3

Transmit Channel Monitor Bit 3.

TCM2

CCR5.2

Transmit Channel Monitor Bit 2.

TCM1

CCR5.1

Transmit Channel Monitor Bit 1.

TCM0

CCR5.0

Transmit Channel Monitor Bit 0. LSB of the channel decode
that determines which transmit DS0 channel data will appear
in the TDS0M register.

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TDS0M: TRANSMIT DS0 MONITOR REGISTER (Address=1A Hex)

(MSB)

LSB)

SYMBOL

POSITION

NAME AND DESCRIPTION

TDS0M.7

Transmit DS0 Channel Bit 1. MSB of the DS0 channel (first
bit to be transmitted).

TDS0M.6

Transmit DS0 Channel Bit 2.

TDS0M.5

Transmit DS0 Channel Bit 3.

TDS0M.4

Transmit DS0 Channel Bit 4.

TDS0M.3

Transmit DS0 Channel Bit 5.

TDS0M.2

Transmit DS0 Channel Bit 6.

TDS0M.1

Transmit DS0 Channel Bit 7.

TDS0M.0

Transmit DS0 Channel Bit 8. LSB of the DS0 channel (last
bit to be transmitted).

CCR6: COMMON CONTROL REGISTER 6 (Address=1E Hex)

[repeated here from section 6 for convenience]

(MSB)

(LSB)

RJC

RESALGN

TESALGN

RCM4

RCM3

RCM2

RCM1

RCM0

SYMBOL

POSITION

NAME AND DESCRIPTION

RJC

CCR6.7

Receive Japanese CRC6 Enable.
0 = use ANSI/AT&T/ITU CRC6 calculation (normal
operation)
1 = use Japanese standard JTG704 CRC6 calculation

RESALGN

CCR6.6

Receive Elastic Store Align. Setting this bit from a zero to a
one will force the receive elastic store's write/read pointers to
a minim separation of half a frame. If pointer separation is
already greater than half a frame, setting this bit will have no
effect. Should be toggled after RSYSCLK has been applied
and is stable. Must be cleared and set again for a subsequent
align. See Section 13 for details.

TESALGN

CCR6.5

Transmit Elastic Store Align. Setting this bit from a zero to a
one will force the transmit elastic store's write/read pointers to
a minimum separation of half a frame. If pointer separation is
already greater than half a frame, setting this bit will have no
effect. Should be toggled after TSYSCLK has been applied
and is stable. Must be cleared and set again for a subsequent
align. See Section 13 for details.

RCM4

CCR6.4

Receive Channel Monitor Bit 4. MSB of a channel decode
that determines which receive channel data will appear in the
RDS0M register. See Section 9 for details.

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SYMBOL

POSITION

NAME AND DESCRIPTION

RCM3

CCR6.3

Receive Channel Monitor Bit 3.

RCM2

CCR6.2

Receive Channel Monitor Bit 2.

RCM1

CCR6.1

Receive Channel Monitor Bit 1.

RCM0

CCR6.0

Receive Channel Monitor Bit 0. LSB of the channel decode.

RDS0M: RECEIVE DS0 MONITOR REGISTER (Address=1F Hex)

(MSB)

(LSB)

SYMBOL

POSITION

NAME AND DESCRIPTION

RDS0M.7

Receive DS0 Channel Bit 1. MSB of the DS0 channel (first
bit to be received).

RDS0M.6

Receive DS0 Channel Bit 2.

RDS0M.5

Receive DS0 Channel Bit 3.

RDS0M.4

Receive DS0 Channel Bit 4.

RDS0M.3

Receive DS0 Channel Bit 5.

RDS0M.2

Receive DS0 Channel Bit 6.

RDS0M.1

Receive DS0 Channel Bit 7.

RDS0M.0

Receive DS0 Channel Bit 8. LSB of the DS0 channel (last bit
to be received).

10. SIGNALING

OPERATION

Each framer in the DS21Q42 contains provisions for both processor based (i.e., software based) signaling
bit access and for hardware based access. Both the processor based access and the hardware based access
can be used simultaneously if necessary. The processor based signaling is covered in Section 10.1 and the
hardware based signaling is covered in Section 10.2.

10.1 PROCESSOR BASED SIGNALING

The robbedbit signaling bits embedded in the T1 stream can be extracted from the receive stream and
inserted into the transmit stream by each framer. There is a set of 12 registers for the receive side (RS1 to
RS12) and 12 registers on the transmit side (TS1 to TS12). The signaling registers are detailed below.
The CCR1.5 bit is used to control the robbed signaling bits as they appear at RSER. If CCR1.5 is set to
zero, then the robbed signaling bits will appear at the RSER pin in their proper position as they are
received. If CCR1.5 is set to a one, then the robbed signaling bit positions will be forced to a one at
RSER. If hardware based signaling is being used, then CCR1.5 must be set to zero.

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RS1 TO RS12: RECEIVE SIGNALING REGISTERS (Address=60 to 6B Hex)

(MSB)

(LSB)

A(8)

A(7)

A(6)

A(5)

A(4)

A(3)

A(2)

A(1)

RS1 (60)

A(16)

A(15)

A(14)

A(13)

A(12)

A(11)

A(10)

A(9)

RS2 (61)

A(24)

A(23)

A(22)

A(21)

A(20)

A(19)

A(18)

A(17)

RS3 (62)

B(8)

B(7)

B(6)

B(5)

B(4)

B(3)

B(2)

B(1)

RS4 (63)

B(16)

B(15)

B(14)

B(13)

B(12)

B(11)

B(10)

B(9)

RS5 (64)

B(24)

B(23)

B(22)

B(21)

B(20)

B(19)

B(18)

B(17)

RS6 (65)

A/C(8)

A/C(7)

A/C(6)

A/C(5)

A/C(4)

A/C(3)

A/C(2)

A/C(1)

RS7 (66)

A/C(16)

A/C(15)

A/C(14)

A/C(13)

A/C(12)

A/C(11)

A/C(10)

A/C(9)

RS8 (67)

A/C(24)

A/C(23)

A/C(22)

A/C(21)

A/C(20)

A/C(19)

A/C(18)

A/C(17) RS9 (68)

B/D(8)

B/D(7)

B/D(6)

B/D(5)

B/D(4)

B/D(3)

B/D(2)

B/D(1)

RS10 (69)

B/D(16)

B/D(15)

B/D(14)

B/D(13)

B/D(12)

B/D(11)

B/D(10)

B/D(9)

RS11 (6A)

B/D(24)

B/D(23)

B/D(22)

B/D(21)

B/D(20)

B/D(19)

B/D(18)

B/D(17) RS12 (6B)

SYMBOL

POSITION

NAME AND DESCRIPTION

D(24)

RS12.7

Signaling Bit D in Channel 24

A(1)

RS1.0

Signaling Bit A in Channel 1

Each Receive Signaling Register (RS1 to RS12) reports the incoming robbed bit signaling from eight
DS0 channels. In the ESF framing mode, there can be up to four signaling bits per channel (A, B, C,
and D). In the D4 framing mode, there are only two signaling bits per channel (A and B). In the D4
framing mode, the framer will replace the C and D signaling bit positions with the A and B signaling bits
from the previous multiframe. Hence, whether the framer is operated in either framing mode, the user
needs only to retrieve the signaling bits every 3 ms. The bits in the Receive Signaling Registers are
updated on multiframe boundaries so the user can utilize the Receive Multiframe Interrupt in the Receive
Status Register 2 (SR2.7) to know when to retrieve the signaling bits. The Receive Signaling Registers
are frozen and not updated during a loss of sync condition (SR1.0=1). They will contain the most recent
signaling information before the "OOF" occurred. The signaling data reported in RS1 to RS12 is also
available at the RSIG and RSER pins.

A change in the signaling bits from one multiframe to the next will cause the RSC status bit (SR2.0) to be
set. The user can enable the INT* pin to toggle low upon detection of a change in signaling by setting the
IMR2.0 bit. Once a signaling change has been detected, the user has at least 2.75 ms to read the data out
of the RS1 to RS12 registers before the data will be lost.

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TS1 TO TS12: TRANSMIT SIGNALING REGISTERS (Address=70 to 7B Hex)

(MSB)

LSB)

A(8)

A(7)

A(6)

A(5)

A(4)

A(3)

A(2)

A(1)

TS1 (70)

A(16)

A(15)

A(14)

A(13)

A(12)

A(11)

A(10)

A(9)

TS2 (71)

A(24)

A(23)

A(22)

A(21)

A(20)

A(19)

A(18)

A(17)

TS3 (72)

B(8)

B(7)

B(6)

B(5)

B(4)

B(3)

B(2)

B(1)

TS4 (73)

B(16)

B(15)

B(14)

B(13)

B(12)

B(11)

B(10)

B(9)

TS5 (74)

B(24)

B(23)

B(22)

B(21)

B(20)

B(19)

B(18)

B(17)

TS7 (75)

A/C(8)

A/C(7)

A/C(6)

A/C(5)

A/C(4)

A/C(3)

A/C(2)

A/C(1)

TS7 (76)

A/C(16) A/C(15) A/C(14) A/C(13) A/C(12) A/C(11) A/C(10) A/C(9)

TS8 (77)

A/C(24) A/C(23) A/C(22) A/C(21) A/C(20) A/C(19) A/C(18) A/C(17) TS9 (78)
B/D(8)

B/D(7)

B/D(6)

B/D(5)

B/D(4)

B/D(3)

B/D(2)

B/D(1)

TS10 (79)

B/D(16) B/D(15) B/D(14) B/D(13) B/D(12) B/D(11) B/D(10) B/D(9)

TS11 (7A)

B/D(24) B/D(23) B/D(22) B/D(21) B/D(20) B/D(19) B/D(18) B/D(17) TS12 (7B)

SYMBOL

POSITION

NAME AND DESCRIPTION

D(24)

TS12.7

Signaling Bit D in Channel 24

A(1)

TS1.0

Signaling Bit A in Channel 1

Each Transmit Signaling Register (TS1 to TS12) contains the Robbed Bit signaling for eight DS0
channels that will be inserted into the outgoing stream if enabled to do so via TCR1.4. In the ESF framing
mode, there can be up to four signaling bits per channel (A, B, C, and D). On multiframe boundaries, the
framer will load the values present in the Transmit Signaling Register into an outgoing signaling shift
register that is internal to the device. The user can utilize the Transmit Multiframe Interrupt in Status
Register 2 (SR2.6) to know when to update the signaling bits. In the ESF framing mode, the interrupt will
come every 3 ms and the user has a full 3ms to update the TSRs. In the D4 framing mode, there are only
two signaling bits per channel (A and B). However in the D4 framing mode, the framer uses the C and D
bit positions as the A and B bit positions for the next multiframe. The framer will load the values in the
TSRs into the outgoing shift register every other D4 multiframe.

10.2 HARDWARE BASED SIGNALING

Receive Side

In the receive side of the hardware based signaling, there are two operating modes for the signaling
buffer; signaling extraction and signaling reinsertion. Signaling extraction involves pulling the signaling
bits from the receive data stream and buffering them over a four multiframe buffer and outputting them in
a serial PCM fashion on a channelbychannel basis at the RSIG output. This mode is always enabled. In
this mode, the receive elastic store may be enabled or disabled. If the receive elastic store is enabled, then
the backplane clock (RSYSCLK) can be either 1.544 MHz or 2.048 MHz. In the ESF framing mode, the
ABCD signaling bits are output on RSIG in the lower nibble of each channel. The RSIG data is updated
once a multiframe (3 ms) unless a freeze is in effect. In the D4 framing mode, the AB signaling bits are
output twice on RSIG in the lower nibble of each channel. Hence, bits 5 and 6 contain the same data as
bits 7 and 8 respectively in each channel. The RSIG data is updated once a multiframe (1.5 ms) unless a
freeze is in effect. See the timing diagrams in Section 20 for some examples.

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The other hardware based signaling operating mode called signaling reinsertion can be invoked by
setting the RSRE control bit high (CCR4.7=1). In this mode, the user will provide a multiframe sync at
the RSYNC pin and the signaling data will be realigned at the RSER output according to this applied
multiframe boundary. In this mode, the elastic store must be enabled however the backplane clock can be
either 1.544 MHz or 2.048 MHz.

If the signaling reinsertion mode is enabled, the user can control which channels have signaling re
insertion performed on a channelbychannel basis by setting the RPCSI control bit high (CCR4.6) and
then programming the RCHBLK output pin to go high in the channels in which the signaling reinsertion
should not occur. If the RPCSI bit is set low, then signaling reinsertion will occur in all channels when
the signaling reinsertion mode is enabled (RSRE=1). How to control the operation of the RCHBLK
output pin is covered in Section 12.

In both hardware based signaling operating modes, the user has the option to replace all of the extracted
robbedbit signaling bit positions with ones. This option is enabled via the RFSA1 control bit (CCR4.5)
and it can be invoked on a perchannel basis by setting the RPCSI control bit (CCR4.6) high and then
programming RCHBLK appropriately just like the perchannel signaling reinsertion operates.

The signaling data in the four multiframe buffer will be frozen in a known good state upon either a loss of
synchronization (OOF event), carrier loss, or frame slip. This action meets the requirements of BellCore
TR TSY000170 for signaling freezing. To allow this freeze action to occur, the RFE control bit
(CCR4.4) should be set high. The user can force a freeze by setting the RFF control bit (CCR4.3) high.
The four multiframe buffer provides a three multiframe delay in the signaling bits provided at the RSIG
pin (and at the RSER pin if RSRE=1). When freezing is enabled (RFE=1), the signaling data will be held
in the last known good state until the corrupting error condition subsides. When the error condition
subsides, the signaling data will be held in the old state for at least an additional 9 ms (or 4.5 ms in D4
framing mode) before being allowed to be updated with new signaling data.

Transmit Side

Via the THSE control bit (CCR4.2), the framer can be set up to take the signaling data presented at the
TSIG pin and insert the signaling data into the PCM data stream that is being input at the TSER pin. The
user has the ability to control which channels are to have signaling data from the TSIG pin inserted into
them on a channelbychannel basis by setting the TPCSI control bit (CCR4.1) high. When TPCSI is
enabled, channels in which the TCHBLK output has been programmed to be set high in, will not have
signaling data from the TSIG pin inserted into them. The hardware signaling insertion capabilities of the
framer are available whether the transmit side elastic store is enabled or disabled. If the elastic store is
enabled, the backplane clock (TSYSCLK) can be either 1.544 MHz or 2.048 MHz.

11. PERCHANNEL CODE (IDLE) GENERATION AND LOOPBACK

Each framer in the DS21Q42 can replace data on a channelbychannel basis in both the transmit and
receive directions. The transmit direction is from the backplane to the T1 line and is covered in Section
11.1. The receive direction is from the T1 line to the backplane and is covered in Section 11.2.

11.1 TRANSMIT SIDE CODE GENERATION

In the transmit direction there are two methods by which channel data from the backplane can be
overwritten with data generated by the framer. The first method which is covered in Section 11.1.1 was a
feature contained in the original DS21Q41 while the second method which is covered in Section 11.1.2 is
a new feature of the DS21Q42.

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11.1.1 Simple Idle Code Insertion and PerChannel Loopback

The first method involves using the Transmit Idle Registers (TIR1/2/3) to determine which of the 24 T1
channels should be overwritten with the code placed in the Transmit Idle Definition Register (TIDR).
This method allows the same 8bit code to be placed into any of the 24 T1 channels. If this method is
used, then the CCR4.0 control bit must be set to zero.

Each of the bit position in the Transmit Idle Registers (TIR1/TIR2/TIR3) represent a DS0 channel in the
outgoing frame. When these bits are set to a one, the corresponding channel will transmit the Idle Code
contained in the Transmit Idle Definition Register (TIDR). Robbed bit signaling and Bit 7 stuffing will
occur over the programmed Idle Code unless the DS0 channel is made transparent by the Transmit
Transparency Registers.

The Transmit Idle Registers (TIRs) have an alternate function that allow them to define a PerChannel
LoopBack (PCLB). If the TIRFS control bit (CCR4.0) is set to one, then the TIRs will determine which
channels (if any) from the backplane should be replaced with the data from the receive side or in other
words, off of the T1 line. If this mode is enabled, then transmit and receive clocks and frame syncs must
be synchronized. One method to accomplish this would be to tie RCLK to TCLK and RFSYNC to
TSYNC.

TIR1/TIR2/TIR3: TRANSMIT IDLE REGISTERS (Address=3C to 3E Hex)

[Also used for PerChannel Loopback]

(MSB)

(LSB)

CH8

CH7

CH6

CH5

CH4

CH3

CH2

CH1

TIR1 (3C)

CH16

CH15

CH14

CH13

CH12

CH11

CH10

CH9

TIR2 (3D)

CH24

CH23

CH22

CH21

CH20

CH19

CH18

CH17

TIR3 (3E)

SYMBOLS POSITIONS NAME AND DESCRIPTION

CH1 24

TIR1.0 - 3.7

Transmit Idle Code Insertion Control Bits.
0 = do not insert the Idle Code in the TIDR into this channel
1 = insert the Idle Code in the TIDR into this channel

Note:

If CCR4.0=1, then a zero in the TIRs implies that channel data is to be sourced from TSER and a one
implies that channel data is to be sourced from the output of the receive side framer (i.e., PerChannel
Loopback; see Figure 11).

TIDR: TRANSMIT IDLE DEFINITION REGISTER (Address=3F Hex)

(MSB)

(LSB)

TIDR7

TIDR6

TIDR5

TIDR4

TIDR3

TIDR2

TIDR1

TIDR0

SYMBOL

POSITION

NAME AND DESCRIPTION

TIDR7

TIDR.7

MSB of the Idle Code (this bit is transmitted first)

TIDR0

TIDR.0

LSB of the Idle Code (this bit is transmitted last)

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11.1.2 PerChannel Code Insertion

The second method involves using the Transmit Channel Control Registers (TCC1/2/3) to determine
which of the 24 T1 channels should be overwritten with the code placed in the Transmit Channel
Registers (TC1 to TC24). This method is more flexible than the first in that it allows a different 8bit
code to be placed into each of the 24 T1 channels.

TC1 TO TC24: TRANSMIT CHANNEL REGISTERS
(Address=40 to 4F and 50 to 57 Hex)

(for brevity, only channel one is shown; see Table 4-1 for other register address)

(MSB)

(LSB)

TC1 (50)

SYMBOL

POSITION

NAME AND DESCRIPTION

TC1.7

MSB of the Code (this bit is transmitted first)

TC1.0

LSB of the Code (this bit is transmitted last)

TCC1/TCC2/TCC3: TRANSMIT CHANNEL CONTROL REGISTER
(Address=16 to 18 Hex)

(MSB)

(LSB)

CH8

CH7

CH6

CH5

CH4

CH3

CH2

CH1

TCC1 (16)

CH16

CH15

CH14

CH13

CH12

CH11

CH10

CH9

TCC2 (17)

CH24

CH23

CH22

CH21

CH20

CH19

CH18

CH17

TCC3 (18)

SYMBOL

POSITION

NAME AND DESCRIPTION

CH1 24

TCC1.0 - 3.7

Transmit Code Insertion Control Bits
0 = do not insert data from the TC register into the transmit
data stream
1 = insert data from the TC register into the transmit data
stream

11.2 RECEIVE SIDE CODE GENERATION

In the receive direction there are also two methods by which channel data to the backplane can be
overwritten with data generated by the framer. The first method which is covered in Section 11.2.1 was a
feature contained in the original DS21Q41 while the second method which is covered in Section 11.2.2 is
a new feature of the DS21Q42.

11.2.1 Simple Code Insertion

The first method on the receive side involves using the Receive Mark Registers (RMR1/2/3) to determine
which of the 24 T1 channels should be overwritten with either a 7Fh idle code or with a digital milliwatt
pattern. The RCR2.7 bit will determine which code is used. The digital milliwatt code is an eight byte
repeating pattern that represents a 1 KHz sine wave (1E/0B/0B/1E/9E/8B/8B/9E). Each bit in the RMRs,
represents a particular channel. If a bit is set to a one, then the receive data in that channel will be
replaced with one of the two codes. If a bit is set to zero, no replacement occurs.

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RMR1/RMR2/RMR3: RECEIVE MARK REGISTERS
(Address=2D to 2F Hex)

(MSB)

(LSB)

CH8

CH7

CH6

CH5

CH4

CH3

CH2

CH1

RMR1 (2D)

CH16

CH15

CH14

CH13

CH12

CH11

CH10

CH9

RMR2 (2E)

CH24

CH23

CH22

CH21

CH20

CH19

CH18

CH17

RMR3 (2F)

SYMBOLS

POSITIONS

NAME AND DESCRIPTION

CH1 24

RMR1.0 - 3.7

Receive Channel Mark Control Bits
0 =do not affect the receive data associated with this channel
1 = replace the receive data associated with this channel with
either the idle code or the digital milliwatt code (depends on
the RCR2.7 bit)

11.2.2 PerChannel Code Insertion

The second method involves using the Receive Channel Control Registers (RCC1/2/3) to determine
which of the 24 T1 channels off of the T1 line and going to the backplane should be overwritten with the
code placed in the Receive Channel Registers (RC1 to RC24). This method is more flexible than the first
in that it allows a different 8bit code to be placed into each of the 24 T1 channels.

RC1 TO RC24: RECEIVE CHANNEL REGISTERS
(Address=58 to 5F and 80 to 8F Hex)

(for brevity, only channel one is shown; see Table 4-1 for other register address)

(MSB)

(LSB)

RC1 (80)

SYMBOL

POSITION

NAME AND DESCRIPTION

RC1.7

MSB of the Code (this bit is sent first to the backplane)

RC1.0

LSB of the Code (this bit is sent last to the backplane)

RCC1/RCC2/RCC3: RECEIVE CHANNEL CONTROL REGISTER
(Address=1B to 1D Hex)

(MSB)

(LSB)

CH8

CH7

CH6

CH5

CH4

CH3

CH2

CH1

RCC1 (1B)

CH16

CH15

CH14

CH13

CH12

CH11

CH10

CH9

RCC2 (1C)

CH24

CH23

CH22

CH21

CH20

CH19

CH18

CH17

RCC3 (1D)

SYMBOL

POSITION

NAME AND DESCRIPTION

CH1 24

RCC1.0 - 3.7

Receive Code Insertion Control Bits
0 = do not insert data from the RC register into the receive data
stream
1 = insert data from the RC register into the receive data
stream

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12. CLOCK BLOCKING REGISTERS

The Receive Channel Blocking Registers (RCBR1/RCBR2/RCBR3) and the Transmit Channel Blocking
Registers (TCBR1/TCBR2/TCBR3) control the RCHBLK and TCHBLK pins respectively. The
RCHBLK and TCHCLK pins are user programmable outputs that can be forced either high or low during
individual channels. These outputs can be used to block clocks to a USART or LAPD controller in
Fractional T1 or ISDNPRI applications. When the appropriate bits are set to a one, the RCHBLK and
TCHCLK pins will be held high during the entire corresponding channel time. See the timing in Section
20 for an example.

RCBR1/RCBR2/RCBR3: RECEIVE CHANNEL BLOCKING REGISTERS
(Address=6C to 6E Hex)

(MSB)

(LSB)

CH8

CH7

CH6

CH5

CH4

CH3

CH2

CH1

RCBR1 (6C)

CH16

CH15

CH14

CH13

CH12

CH11

CH10

CH9

RCBR2 (6D)

CH24

CH23

CH22

CH21

CH20

CH19

CH18

CH17

RCBR3 (6E)

SYMBOLS

POSITIONS

NAME AND DESCRIPTION

CH1 24

RCBR1.0 - 3.7

Receive Channel Blocking Control Bits.
0 = force the RCHBLK pin to remain low during this channel
time
1 = force the RCHBLK pin high during this channel time

TCBR1/TCBR2/TCBR3: TRANSMIT CHANNEL BLOCKING REGISTERS
(Address=32 to 34 Hex)

(MSB)

(LSB)

CH8

CH7

CH6

CH5

CH4

CH3

CH2

CH1

TCBR1 (32)

CH16

CH15

CH14

CH13

CH12

CH11

CH10

CH9

TCBR2 (33)

CH24

CH23

CH22

CH21

CH20

CH19

CH18

CH17

TCBR3 (34)

SYMBOLS

POSITIONS

NAME AND DESCRIPTION

CH1 24

TCBR1.0 - 3.7

Transmit Channel Blocking Control Bits.
0 = force the TCHBLK pin to remain low during this channel
time
1 = force the TCHBLK pin high during this channel time

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13. ELASTIC STORES OPERATION

Each framer in the DS21Q42 contains dual twoframe (386 bits) elastic stores, one for the receive
direction, and one for the transmit direction. These elastic stores have two main purposes. First, they can
be used to rate convert the T1 data stream to 2.048 Mbps (or a multiple of 2.048 Mbps) which is the E1
rate. Secondly, they can be used to absorb the differences in frequency and phase between the T1 data
stream and an asynchronous (i.e., not frequency locked) backplane clock (which can be 1.544 MHz or
2.048 MHz). The backplane clock can burst at rates up to 8.192 MHz. Both elastic stores contain full
controlled slip capability which is necessary for this second purpose. Both elastic stores within the framer
are fully independent and no restrictions apply to the sourcing of the various clocks that are applied to
them. The transmit side elastic store can be enabled whether the receive elastic store is enabled or
disabled and vice versa. Also, each elastic store can interface to either a 1.544 MHz or 2.048 MHz
backplane without regard to the backplane rate the other elastic store is interfacing.

Two mechanisms are available to the user for resetting the elastic stores. The Elastic Store Reset (TX -
CCR7.4 & RX - CCR7.5) function forces the elastic stores to a depth of one frame unconditionally. Data
is lost during the reset. The second method, the Elastic Store Align (TX - CCR6.5 & RX - CCR6.6)
forces the elastic store depth to a minimum depth of half a frame only if the current pointer separation is
already less then half a frame. If a realignment occurs data is lost. In both mechanisms, independent
resets are provided for both the receive and transmit elastic stores.

13.1 RECEIVE SIDE

If the receive side elastic store is enabled (CCR1.2=1), then the user must provide either a 1.544 MHz
(CCR1.3=0) or 2.048 MHz (CCR1.3=1) clock at the RSYSCLK pin. The user has the option of either
providing a frame/multiframe sync at the RSYNC pin (RCR2.3=1) or having the RSYNC pin provide a
pulse on frame boundaries (RCR2.3=0). If the user wishes to obtain pulses at the frame boundary, then
RCR2.4 must be set to zero and if the user wishes to have pulses occur at the multiframe boundary, then
RCR2.4 must be set to one. The framer will always indicate frame boundaries via the RFSYNC output
whether the elastic store is enabled or not. If the elastic store is enabled, then multiframe boundaries will
be indicated via the RMSYNC output. If the user selects to apply a 2.048 MHz clock to the RSYSCLK
pin, then the data output at RSER will be forced to all ones every fourth channel. Hence channels 1
(except for the MSB), 5, 9, 13, 17, 21, 25, and 29 (timeslots 0, 4, 8, 12, 16, 20, 24, and 28) will be forced
to a one. The Fbit will be passed in the MSB of channel 1. Also, in 2.048 MHz applications, the
RCHBLK output will be forced high during the same channels as the RSER pin. See Section 19 for more
details. This is useful in T1 to CEPT (E1) conversion applications. If the 386bit elastic buffer either fills
or empties, a controlled slip will occur. If the buffer empties, then a full frame of data (193 bits) will be
repeated at RSER and the SR1.4 and RIR1.3 bits will be set to a one. If the buffer fills, then a full frame
of data will be deleted and the SR1.4 and RIR1.4 bits will be set to a one.

13.2 TRANSMIT SIDE

The operation of the transmit elastic store is very similar to the receive side. The transmit side elastic
store is enabled via CCR1.7. A 1.544 MHz (CCR1.4=0) or 2.048 MHz (CCR1.4=1) clock can be applied
to the TSYSCLK input. If the user selects to apply a 2.048 MHz clock to the TSYSCLK pin, then the data
input at TSER will be ignored every fourth channel. Hence channels 1 (except for the MSB), 5, 9, 13, 17,
21, 25, and 29 (timeslots 0, 4, 8, 12, 16, 20, 24, and 28) will be ignored. A special case exists for the MSB
of channel 1. Via TCR1.6 the MSB of channel 1 can be sampled as the F-bit. The user must supply a 8
KHz frame sync pulse to the TSSYNC input. Also, in 2.048 MHz applications, the TCHBLK output will
be forced high during the channels ignored by the framer. See Section 19 for more details. Controlled
slips in the transmit elastic store are reported in the RIR2.3 bit and the direction of the slip is reported in
the RIR2.5 and RIR2.4 bits.

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13.3 MINIMUM DELAY SYNCHRONOUS RSYSCLK/TSYSCLK MODE

In applications where the framer is connected to backplanes that are frequency locked to the recovered T1
clock (i.e., the RCLK output), the full two frame depth of the onboard elastic stores is really not needed.
In fact, in some delay sensitive applications, the normal two frame depth may be excessive. Register bits
CCR3.7 and CCR3.0 control the RX and TX elastic stores depths. In this mode, RSYSCLK and
TSYSCLK must be tied together and they must be frequency locked to RCLK. All of the slip contention
logic in the framer is disabled (since slips cannot occur). Also, since the buffer depth is no longer two
frames deep, the framer must be set up to source a frame pulse at the RSYNC pin and this output must be
tied to the TSSYNC input. On powerup after the RSYSCLK and TSYSCLK signals have locked to the
RCLK signal, the elastic stores should be reset.

14. HDLC

CONTROLLER

The DS21Q42 has an enhanced HDLC controller configurable for use with the Facilities Data Link or
DS0s. There are 64 byte buffers in both the transmit and receive paths. The user can select any DS0 or
multiple DS0s as well as any specific bits within the DS0(s) to pass through the HDLC controller. See
Figure 20-15 for details on formatting the transmit side. Note that TBOC.6 = 1 and TDC1.7 = 1 cannot
exist without corrupting the data in the FDL. For use with the FDL, see section 15.1. See Table 14-1 for
configuring the transmit HDLC controller.

Four new registers were added for the enhanced functionality of the HDLC controller; RDC1, RDC2,
TDC1, and TDC2. Note that the BOC controller is functional when the HDLC controller is used for
DS0s. Section 15 contains all of the HDLC and BOC registers and information on FDL/Fs Extraction and
Insertion with and without the HDLC controller.

Transmit HDLC Configuration Table 14-1

Function

TBOC.6

TDC1.7

TCR1.2

DS0(s)

1 or 0

FDL

Disable

1 or 0

14.1 HDLC for DS0s

When using the HDLC controllers for DS0s, the same registers shown in section 15 will be used except
for the TBOC and RBOC registers and bits HCR.7, HSR.7, and HIMR.7. As a basic guideline for
interpreting and sending HDLC messages and BOC messages, the following sequences can be applied.

Receive a HDLC Message

1. Enable RPS interrupts
2. Wait for interrupt to occur
3. Disable RPS interrupt and enable either RPE, RNE, or RHALF interrupt
4. Read RHIR to obtain REMPTY status

a. If REMPTY=0, then record OBYTE, CBYTE, and POK bits and then read the FIFO

a1. If CBYTE=0 then skip to step 5
a2. If CBYTE=1 then skip to step 7

b. If REMPTY=1, then skip to step 6

5. Repeat step 4
6. Wait for interrupt, skip to step 4
7. If POK=0, then discard whole packet, if POK=1, accept the packet
8. Disable RPE, RNE, or RHALF interrupt, enable RPS interrupt and return to step 1.

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Transmit a HDLC Message

Make sure HDLC controller is done sending any previous messages and is current sending flags by
checking that the FIFO is empty by reading the TEMPTY status bit in the THIR register

Enable either the THALF or TNF interrupt

Read THIR to obtain TFULL status

If TFULL=0, then write a byte into the FIFO and skip to next step (special case occurs when
the last byte is to be written, in this case set TEOM=1 before writing the byte and then skip to
step 6)

If TFULL=1, then skip to step 5

Repeat step 3

Wait for interrupt, skip to step 3

Disable THALF or TNF interrupt and enable TMEND interrupt

Wait for an interrupt, then read TUDR status bit to make sure packet was transmitted correctly.

15. FDL/Fs EXTRACTION AND INSERTION

Each Framer/Formatter has the ability to extract/insert data from/ into the Facility Data Link (FDL) in the
ESF framing mode and from/into Fsbit position in the D4 framing mode. Since SLC96 utilizes the Fs-
bit position, this capability can also be used in SLC96 applications. The DS21Q42 contains a complete
HDLC and BOC controller for the FDL and this operation is covered in Section 15.1. To allow for
backward compatibility between the DS21Q42 and earlier devices, the DS21Q42 maintains some legacy
functionality for the FDL and this is covered in Section 15.2. Section 15.3 covers D4 and SLC96
operation. Please contact the factory for a copy of C language source code for implementing the FDL on
the DS21Q42.

15.1 HDLC AND BOC CONTROLLER FOR THE FDL

15.1.1 General Overview

The DS21Q42 contains a complete HDLC controller with 64byte buffers in both the transmit and
receive directions as well as separate dedicated hardware for Bit Oriented Codes (BOC). The HDLC
controller performs all the necessary overhead for generating and receiving Performance Report
Messages (PRM) as described in ANSI T1.403 and the messages as described in AT&T TR54016. The
HDLC controller automatically generates and detects flags, generates and checks the CRC check sum,
generates and detects abort sequences, stuffs and destuffs zeros (for transparency), and byte aligns to the
HDLC data stream. The 64byte buffers in the HDLC controller are large enough to allow a full PRM to
be received or transmitted without host intervention. The BOC controller will automatically detect
incoming BOC sequences and alert the host. When the BOC ceases, the DS21Q42 will also alert the host.
The user can set the device up to send any of the possible 6bit BOC codes.

There are thirteen registers that the host will use to operate and control the operation of the HDLC and
BOC controllers. A brief description of the registers is shown in Table 151.

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HDLC/BOC CONTROLLER REGISTER LIST Table 15-1

NAME

FUNCTION

HDLC Control Register (HCR)

general control over the HDLC and BOC
controllers

HDLC Status Register (HSR)

key status information for both transmit and receive
directions

HDLC Interrupt Mask Register (HIMR)

allows/stops status bits to/from causing an interrupt

Receive HDLC Information Register (RHIR)

status information on receive HDLC controller

Receive BOC Register (RBOC)

status information on receive BOC controller

Receive HDLC FIFO Register (RHFR)

access to 64byte HDLC FIFO in receive direction

Receive HDLC DS0 Control Register 1 (RDC1)
Receive HDLC DS0 Control Register 2 (RDC2)

controls the HDLC function when used on DS0
channels

Transmit HDLC Information Register (THIR)

status information on transmit HDLC controller

Transmit BOC Register (TBOC)

enables/disables transmission of BOC codes

Transmit HDLC FIFO Register (THFR)

access to 64byte HDLC FIFO in transmit
direction

Transmit HDLC DS0 Control Register 1 (TDC1)
Transmit HDLC DS0 Control Register 2 (TDC2)

controls the HDLC function when used on DS0
channels

15.1.2 Status Register for the HDLC

Four of the HDLC/BOC controller registers (HSR, RHIR, RBOC, and THIR) provide status information.
When a particular event has occurred (or is occurring), the appropriate bit in one of these four registers
will be set to a one. Some of the bits in these four HDLC status registers are latched and some are real
time bits that are not latched. Section 15.1.4 contains register descriptions that list which bits are latched
and which are not. With the latched bits, when an event occurs and a bit is set to a one, it will remain set
until the user reads that bit. The bit will be cleared when it is read and it will not be set again until the
event has occurred again. The real time bits report the current instantaneous conditions that are occurring
and the history of these bits is not latched.

Like the other status registers in the DS21Q42, the user will always proceed a read of any of the four
registers with a write. The byte written to the register will inform the DS21Q42 which of the latched bits
the user wishes to read and have cleared (the real time bits are not affected by writing to the status
register). The user will write a byte to one of these registers, with a one in the bit positions he or she
wishes to read and a zero in the bit positions he or she does not wish to obtain the latest information on.
When a one is written to a bit location, the read register will be updated with current value and it will be
cleared. When a zero is written to a bit position, the read register will not be updated and the previous
value will be held. A write to the status and information registers will be immediately followed by a read
of the same register. The read result should be logically AND'ed with the mask byte that was just written
and this value should be written back into the same register to insure that bit does indeed clear. This
second write step is necessary because the alarms and events in the status registers occur asynchronously
in respect to their access via the parallel port. This writereadwrite (for polled driven access) or write
read (for interrupt driven access) scheme allows an external microcontroller or microprocessor to
individually poll certain bits without disturbing the other bits in the register. This operation is key in
controlling the DS21Q42 with higherorder software languages.

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Like the SR1 and SR2 status registers, the HSR register has the unique ability to initiate a hardware
interrupt via the INT* output pin. Each of the events in the HSR can be either masked or unmasked from
the interrupt pin via the HDLC Interrupt Mask Register (HIMR). Interrupts will force the INT* pin low
when the event occurs. The INT* pin will be allowed to return high (if no other interrupts are present)
when the user reads the event bit that caused the interrupt to occur.

Basic Operation Details

To allow the framer to properly source/receive data from/to the HDLC and BOC controller the legacy
FDL circuitry (which is described in Section 15.2) should be disabled and the following bits should be
programmed as shown:

TCR1.2 = 1 (source FDL data from the HDLC and BOC controller)
TBOC.6 = 1 (enable HDLC and BOC controller)
CCR2.5 = 0 (disable SLC96 and D4 Fsbit insertion)
CCR2.4 = 0 (disable legacy FDL zero stuffer)
CCR2.1 = 0 (disable SLC96 reception)
CCR2.0 = 0 (disable legacy FDL zero stuffer)
IMR2.4 = 0 (disable legacy receive FDL buffer full interrupt)
IMR2.3 = 0 (disable legacy transmit FDL buffer empty interrupt)
IMR2.2 = 0 (disable legacy FDL match interrupt)
IMR2.1 = 0 (disable legacy FDL abort interrupt).

As a basic guideline for interpreting and sending both HDLC messages and BOC messages, the following
sequences can be applied:

Receive a HDLC Message or a BOC

Enable RBOC and RPS interrupts

Wait for interrupt to occur

If RBOC=1, then follow steps 5 and 6

If RPS=1, then follow steps 7 through 12

If LBD=1, a BOC is present, then read the code from the RBOC register and take action as needed

If BD=0, a BOC has ceased, take action as needed and then return to step 1

Disable RPS interrupt and enable either RPE, RNE, or RHALF interrupt

Read RHIR to obtain REMPTY status a. if REMPTY=0, then record OBYTE, CBYTE, and POK bits
and then read the FIFO a1. if CBYTE=0 then skip to step 9 a2. if CBYTE=1 then skip to step 11 b. if
REMPTY=1, then skip to step 10

Repeat step 8

10.

Wait for interrupt, skip to step 8

11.

If POK=0, then discard whole packet, if POK=1, accept the packet 12. disable RPE, RNE, or RHALF
interrupt, enable RPS interrupt and return to step 1.

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Transmit a HDLC Message

Make sure HDLC controller is done sending any previous messages and is current sending flags by
checking that the FIFO is empty by reading the TEMPTY status bit in the THIR register

Enable either the THALF or TNF interrupt

Read THIR to obtain TFULL status a. if TFULL=0, then write a byte into the FIFO and skip to next
step (special case occurs when the last byte is to be written, in this case set TEOM=1 before writing
the byte and then skip to step 6) b. if TFULL=1, then skip to step 5

Repeat step 3

Wait for interrupt, skip to step 3

Disable THALF or TNF interrupt and enable TMEND interrupt

Wait for an interrupt, then read TUDR status bit to make sure packet was transmitted correctly.

Transmit a BOC

Write 6bit code into TBOC

Set SBOC bit in TBOC=1

15.1.3 HDLC/BOC Register Description

HCR: HDLC CONTROL REGISTER (Address = 00 Hex)

(MSB)

(LSB)

RBR

RHR

TFS

THR

TABT

TEOM

TZSD

TCRCD

SYMBOL

POSITION

NAME AND DESCRIPTION

RBR

HCR.7

Receive BOC Reset. A 0 to 1 transition will reset the BOC
circuitry. Must be cleared and set again for a subsequent reset.

RHR

HCR.6

Receive HDLC Reset. A 0 to 1 transition will reset the HDLC
controller. Must be cleared and set again for a subsequent reset.

TFS

HCR.5

Transmit Flag/Idle Select.
0 = 7Eh
1 = FFh

THR

HCR.4

Transmit HDLC/BOC Reset. A 0 to 1 transition will reset
both the HDLC controller and the transmit BOC circuitry. Must
be cleared and set again for a subsequent reset.

TABT

HCR.3

Transmit Abort. A 0 to 1 transition will cause the FIFO
contents to be dumped and one FEh abort to be sent followed
by 7Eh or FFh flags/idle until a new packet is initiated by
writing new data into the FIFO. Must be cleared and set again
for a subsequent abort to be sent.

TEOM

HCR.2

Transmit End of Message. Should be set to a one just before
the last data byte of a HDLC packet is written into the transmit
FIFO at THFR. The HDLC controller will clear this bit when
the last byte has been transmitted.

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SYMBOL

POSITION

NAME AND DESCRIPTION

TZSD

HCR.1

Transmit Zero Stuffer Defeat. Overrides internal enable.
0 = enable the zero stuffer (normal operation)
1 = disable the zero stuffer

TCRCD

HCR.0

Transmit CRC Defeat.
0 = enable CRC generation (normal operation)
1 = disable CRC generation

HSR: HDLC STATUS REGISTER (Address = 01 Hex)

(MSB)

(LSB)

RBOC

RPE

RPS

RHALF

RNE

THALF

TNF

TMEND

SYMBOL

POSITION

NAME AND DESCRIPTION

RBOC

HSR.7

Receive BOC Detector Change of State. Set whenever the
BOC detector sees a change of state from a BOC Detected to a
No Valid Code seen or vice versa. The setting of this bit prompt
the user to read the RBOC register for details.

RPE

HSR.6

Receive Packet End. Set when the HDLC controller detects
either the finish of a valid message (i.e., CRC check complete)
or when the controller has experienced a message fault such as a
CRC checking error, or an overrun condition, or an abort has
been seen. The setting of this bit prompts the user to read the
RHIR register for details.

RPS

HSR.5

Receive Packet Start. Set when the HDLC controller detects an
opening byte. The setting of this bit prompts the user to read the
RHIR register for details.

RHALF

HSR.4

Receive FIFO Half Full. Set when the receive 64byte FIFO
fills beyond the half way point. The setting of this bit prompts
the user to read the RHIR register for details.

RNE

HSR.3

Receive FIFO Not Empty. Set when the receive 64byte FIFO
has at least one byte available for a read. The setting of this bit
prompts the user to read the RHIR register for details.

THALF

HSR.2

Transmit FIFO Half Empty. Set when the transmit 64byte
FIFO empties beyond the half way point. The setting of this bit
prompts the user to read the THIR register for details.

TNF

HSR.1

Transmit FIFO Not Full. Set when the transmit 64byte FIFO
has at least one byte available. The setting of this bit prompts the
user to read the THIR register for details.

TMEND

HSR.0

Transmit Message End. Set when the transmit HDLC
controller has finished sending a message. The setting of this bit
prompts the user to read the THIR register for details.

Note:

The RBOC, RPE, RPS, and TMEND bits are latched and will be cleared when read.

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HIMR: HDLC INTERRUPT MASK REGISTER (Address = 02 Hex)

(MSB)

(LSB)

RBOC

RPE

RPS

RHALF

RNE

THALF

TNF

TMEND

SYMBOL

POSITION

NAME AND DESCRIPTION

RBOC

HIMR.7

Receive BOC Detector Change of State.
0 = interrupt masked
1 = interrupt enabled

RPE

HIMR.6

Receive Packet End.
0 = interrupt masked
1 = interrupt enabled

RPS

HIMR.5

Receive Packet Start.
0 = interrupt masked
1 = interrupt enabled

RHALF

HIMR.4

Receive FIFO Half Full.
0 = interrupt masked
1 = interrupt enabled

RNE

HIMR.3

Receive FIFO Not Empty.
0 = interrupt masked
1 = interrupt enabled

THALF

HIMR.2

Transmit FIFO Half Empty.
0 = interrupt masked
1 = interrupt enabled

TNF

HIMR.1

Transmit FIFO Not Full.
0 = interrupt masked
1 = interrupt enabled

TMEND

HIMR.0

Transmit Message End.
0 = interrupt masked
1 = interrupt enabled

RHIR: RECEIVE HDLC INFORMATION REGISTER (Address = 03 Hex)

(MSB)

(LSB)

RABT

RCRCE

ROVR

RVM

REMPTY

POK

CBYTE

OBYTE

SYMBOL

POSITION

NAME AND DESCRIPTION

RABT

RHIR.7

Abort Sequence Detected. Set whenever the HDLC controller
sees 7 or more ones in a row.

RCRCE

RHIR.6

CRC Error. Set when the CRC checksum is in error.

ROVR

RHIR.5

Overrun. Set when the HDLC controller has attempted to write
a byte into an already full receive FIFO.

RVM

RHIR.4

Valid Message. Set when the HDLC controller has detected and
checked a complete HDLC packet.

REMPTY

RHIR.3

Empty. A realtime bit that is set high when the receive FIFO is
empty.

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SYMBOL

POSITION

NAME AND DESCRIPTION

POK

RHIR.2

Packet OK. Set when the byte available for reading in the
receive FIFO at RHFR is the last byte of a valid message (and
hence no abort was seen, no overrun occurred, and the CRC was
correct).

CBYTE

RHIR.1

Closing Byte. Set when the byte available for reading in the
receive FIFO at RHFR is the last byte of a message (whether the
message was valid or not).

OBYTE

RHIR.0

Opening Byte. Set when the byte available for reading in the
receive FIFO at RHFR is the first byte of a message.

Note:

The RABT, RCRCE, ROVR, and RVM bits are latched and will be cleared when read.

RBOC: RECEIVE BIT ORIENTED CODE REGISTER (Address = 04 Hex)

(MSB)

(LSB)

LBD

BOC5

BOC4

BOC3

BOC2

BOC1

BOC0

SYMBOL

POSITION

NAME AND DESCRIPTION

LBD

RBOC.7

Latched BOC Detected. A latched version of the BD status bit
(RBOC.6). Will be cleared when read.

RBOC.6

BOC Detected. A realtime bit that is set high when the BOC
detector is presently seeing a valid sequence and set low when
no BOC is currently being detected.

BOC5

RBOC.5

BOC Bit 5. Last bit received of the 6bit code word.

BOC4

RBOC.4

BOC Bit 4.

BOC3

RBOC.3

BOC Bit 3.

BOC2

RBOC.2

BOC Bit 2.

BOC1

RBOC.1

BOC Bit 1.

BOC0

RBOC.0

BOC Bit 0. First bit received of the 6bit code word.

Note:

The LBD bit is latched and will be cleared when read.

The RBOC0 to RBOC5 bits display the last valid BOC code verified; these bits will be set to all ones
on reset.

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RHFR: RECEIVE HDLC FIFO (Address = 05 Hex)

(MSB)

(LSB)

HDLC7

HDLC6

HDLC5

HDLC4

HDLC3

HDLC2

HDLC1

HDLC0

SYMBOL

POSITION

NAME AND DESCRIPTION

HDLC7

RHFR.7

HDLC Data Bit 7. MSB of a HDLC packet data byte.

HDLC6

RHFR.6

HDLC Data Bit 6.

HDLC5

RHFR.5

HDLC Data Bit 5.

HDLC4

RHFR.4

HDLC Data Bit 4.

HDLC3

RHFR.3

HDLC Data Bit 3.

HDLC2

RHFR.2

HDLC Data Bit 2.

HDLC1

RHFR.1

HDLC Data Bit 1.

HDLC0

RHFR.0

HDLC Data Bit 0. LSB of a HDLC packet data byte.

THIR: TRANSMIT HDLC INFORMATION (Address = 06 Hex)

(MSB)

(LSB)

TEMPTY

TFULL

UDR

SYMBOL

POSITION

NAME AND DESCRIPTION

THIR.7

Not Assigned. Could be any value when read.

THIR.6

Not Assigned. Could be any value when read.

THIR.5

Not Assigned. Could be any value when read.

THIR.4

Not Assigned. Could be any value when read.

THIR.3

Not Assigned. Could be any value when read.

TEMPTY

THIR.2

Transmit FIFO Empty. A realtime bit that is set high when
the FIFO is empty.

TFULL

THIR.1

Transmit FIFO Full. A realtime bit that is set high when the
FIFO is full.

UDR

THIR.0

Underrun. Set when the transmit FIFO unwantedly empties out
and an abort is automatically sent.

Note:

The UDR bit is latched and will be cleared when read.

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TBOC: TRANSMIT BIT ORIENTED CODE (Address = 07 Hex)

(MSB)

(LSB)

SBOC

HBEN

BOC5

BOC4

BOC3

BOC2

BOC1

BOC0

SYMBOL

POSITION

NAME AND DESCRIPTION

SBOC

TBOC.7

Send BOC. Rising edge triggered. Must be transitioned from a 0
to a
1 transmit the BOC code placed in the BOC0 to BOC5 bits
instead of data from the HDLC controller.

HBEN

TBOC.6

Transmit HDLC & BOC Controller Enable.
0 = source FDL data from the TLINK pin
1 = source FDL data from the onboard HDLC and BOC
controller

BOC5

TBOC.5

BOC Bit 5. Last bit transmitted of the 6bit code word.

BOC4

TBOC.4

BOC Bit 4.

BOC3

TBOC.3

BOC Bit 3.

BOC2

TBOC.2

BOC Bit 2.

BOC1

TBOC.1

BOC Bit 1.

BOC0

TBOC.0

BOC Bit 0. First bit transmitted of the 6bit code word.

THFR: TRANSMIT HDLC FIFO (Address = 08 Hex)

(MSB)

(LSB)

HDLC7

HDLC6

HDLC5

HDLC4

HDLC3

HDLC2

HDLC1

HDLC0

SYMBOL

POSITION

NAME AND DESCRIPTION

HDLC7

THFR.7

HDLC Data Bit 7. MSB of a HDLC packet data byte.

HDLC6

THFR.6

HDLC Data Bit 6.

HDLC5

THFR.5

HDLC Data Bit 5.

HDLC4

THFR.4

HDLC Data Bit 4.

HDLC3

THFR.3

HDLC Data Bit 3.

HDLC2

THFR.2

HDLC Data Bit 2.

HDLC1

THFR.1

HDLC Data Bit 1.

HDLC0

THFR.0

HDLC Data Bit 0. LSB of a HDLC packet data byte.

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RDC1: RECEIVE HDLC DS0 CONTROL REGISTER 1 (Address = 90 Hex)

(MSB)

(LSB)

RDS0E

RDS0M

RD4

RD3

RD2

RD1

RD0

SYMBOL

POSITION

NAME AND DESCRIPTION

RDS0E

RDC1.7

HDLC DS0 Enable.
0 = use receive HDLC controller for the FDL.
1 = use receive HDLC controller for one or more DS0 channels.

RDC1.6

Not Assigned. Should be set to 0.

RDS0M

RDC1.5

DS0 Selection Mode.
0 = utilize the RD0 to RD4 bits to select which single DS0
channel to use.
1 = utilize the RCHBLK control registers to select which DS0
channels to use.

RD4

RDC1.4

DS0 Channel Select Bit 4. MSB of the DS0 channel select.

RD3

RDC1.3

DS0 Channel Select Bit 3.

RD2

RDC1.2

DS0 Channel Select Bit 2.

RD1

RDC1.1

DS0 Channel Select Bit 1.

RD0

RDC1.0

DS0 Channel Select Bit 0. LSB of the DS0 channel select.

RDC2: RECEIVE HDLC DS0 CONTROL REGISTER 2 (Address = 91 Hex)

(MSB)

(LSB)

RDB8

RDB7

RDB6

RDB5

RDB4

RDB3

RDB2

RDB1

SYMBOL

POSITION

NAME AND DESCRIPTION

RDB8

RDC2.7

DS0 Bit 8 Suppress Enable. MSB of the DS0. Set to one to stop
this bit from being used.

RDB7

RDC2.6

DS0 Bit 7 Suppress Enable. Set to one to stop this bit from
being used.

RDB6

RDC2.5

DS0 Bit 6 Suppress Enable. Set to one to stop this bit from
being used.

RDB5

RDC2.4

DS0 Bit 5 Suppress Enable. Set to one to stop this bit from
being used.

RDB4

RDC2.3

DS0 Bit 4 Suppress Enable. Set to one to stop this bit from
being used.

RDB3

RDC2.2

DS0 Bit 3 Suppress Enable. Set to one to stop this bit from
being used.

RDB2

RDC2.1

DS0 Bit 2 Suppress Enable. Set to one to stop this bit from
being used.

RDB1

RDC2.0

DS0 Bit 1 Suppress Enable. LSB of the DS0. Set to one to stop
this bit from being used.

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TDC1: TRANSMIT HDLC DS0 CONTROL REGISTER 1 (Address = 92 Hex)

(MSB)

(LSB)

TDS0E

TDS0M

TD4

TD3

TD2

TD1

TD0

SYMBOL

POSITION

NAME AND DESCRIPTION

TDS0E

TDC1.7

HDLC DS0 Enable.
0 = use transmit HDLC controller for the FDL.
1 = use transmit HDLC controller for one or more DS0 channels.

TDC1.6

Not Assigned. Should be set to 0.

TDS0M

TDC1.5

DS0 Selection Mode.
0 = utilize the TD0 to TD4 bits to select which single DS0
channel to use.
1 = utilize the TCHBLK control registers to select which DS0
channels to use.

TD4

TDC1.4

DS0 Channel Select Bit 4. MSB of the DS0 channel select.

TD3

TDC1.3

DS0 Channel Select Bit 3.

TD2

TDC1.2

DS0 Channel Select Bit 2.

TD1

TDC1.1

DS0 Channel Select Bit 1.

TD0

TDC1.0

DS0 Channel Select Bit 0. LSB of the DS0 channel select.

TDC2: TRANSMIT HDLC DS0 CONTROL REGISTER 2 (Address = 93 Hex)

(MSB)

(LSB)

TDB8

TDB7

TDB6

TDB5

TDB4

TDB3

TDB2

TDB1

SYMBOL

POSITION

NAME AND DESCRIPTION

TDB8

TDC2.7

DS0 Bit 8 Suppress Enable. MSB of the DS0. Set to one to stop
this bit from being used.

TDB7

TDC2.6

DS0 Bit 7 Suppress Enable. Set to one to stop this bit from
being used.

TDB6

TDC2.5

DS0 Bit 6 Suppress Enable. Set to one to stop this bit from
being used.

TDB5

TDC2.4

DS0 Bit 5 Suppress Enable. Set to one to stop this bit from
being used.

TDB4

TDC2.3

DS0 Bit 4 Suppress Enable. Set to one to stop this bit from
being used.

TDB3

TDC2.2

DS0 Bit 3 Suppress Enable. Set to one to stop this bit from
being used.

TDB2

TDC2.1

DS0 Bit 2 Suppress Enable. Set to one to stop this bit from
being used.

TDB1

TDC2.0

DS0 Bit 1 Suppress Enable. LSB of the DS0. Set to one to stop
this bit from being used.

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15.2 LEGACY FDL SUPPORT

15.2.1 Overview

The DS21Q42 maintains the circuitry that existed in the previous generation of Dallas Semiconductor's
single chip transceivers and quad framers. Section 15.2 covers the circuitry and operation of this legacy
functionality. In new applications, it is recommended that the HDLC controller and BOC controller
described in Section 15.1 be used. On the receive side, it is possible to have both the new HDLC/BOC
controller and the legacy hardware working at the same time. However this is not possible on the transmit
side since their can be only one source the of the FDL data internal to the device.

15.2.2 Receive Section

In the receive section, the recovered FDL bits or Fs bits are shifted bitbybit into the Receive FDL
register (RFDL). Since the RFDL is 8 bits in length, it will fill up every 2 ms (8 times 250 us). The framer
will signal an external microcontroller that the buffer has filled via the SR2.4 bit. If enabled via IMR2.4,
the INT* pin will toggle low indicating that the buffer has filled and needs to be read. The user has 2 ms
to read this data before it is lost. If the byte in the RFDL matches either of the bytes programmed into the
RMTCH1 or RMTCH2 registers, then the SR2.2 bit will be set to a one and the INT* pin will toggled
low if enabled via IMR2.2. This feature allows an external microcontroller to ignore the FDL or Fs
pattern until an important event occurs.

The framer also contains a zero destuffer, which is controlled via the CCR2.0 bit. In both ANSI T1.403
and TR54016, communications on the FDL follows a subset of a LAPD protocol. The LAPD protocol
states that no more than 5 ones should be transmitted in a row so that the data does not resemble an
opening or closing flag (01111110) or an abort signal (11111111). If enabled via CCR2.0, the DS21Q42
will automatically look for 5 ones in a row, followed by a zero. If it finds such a pattern, it will
automatically remove the zero. If the zero destuffer sees six or more ones in a row followed by a zero, the
zero is not removed. The CCR2.0 bit should always be set to a one when the DS21Q42 is extracting the
FDL. More on how to use the DS21Q42 in FDL applications in this legacy support mode is covered in a
separate Application Note.

RFDL: RECEIVE FDL REGISTER (Address = 28 Hex)

(MSB)

(LSB)

RFDL7

RFDL6

RFDL5

RFDL4

RFDL3

RFDL2

RFDL1

RFDL0

SYMBOL

POSITION

NAME AND DESCRIPTION

RFDL7

RFDL.7

MSB of the Received FDL Code

RFDL0

RFDL.0

LSB of the Received FDL Code

The Receive FDL Register (RFDL) reports the incoming Facility Data Link (FDL) or the incoming Fs
bits. The LSB is received first.

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RMTCH1: RECEIVE FDL MATCH REGISTER 1 (Address = 29 Hex)
RMTCH2: RECEIVE FDL MATCH REGISTER 2 (Address = 2A Hex)

(MSB)

(LSB)

RMFDL7

RMFDL6

RMFDL5

RMFDL4

RMFDL3

RMFDL2

RMFDL1

RMFDL0

SYMBOL

POSITION

NAME AND DESCRIPTION

RMFDL7

RMTCH1.7

MSB of the FDL Match Code

RMTCH2.7

RMFDL0

RMTCH1.0

LSB of the FDL Match Code

RMTCH2.0

When the byte in the Receive FDL Register matches either of the two Receive FDL Match Registers
(RMTCH1/RMTCH2), SR2.2 will be set to a one and the INT* will go active if enabled via IMR2.2.

15.2.3 Transmit Section

The transmit section will shift out into the T1 data stream, either the FDL (in the ESF framing mode) or
the Fs bits (in the D4 framing mode) contained in the Transmit FDL register (TFDL). When a new value
is written to the TFDL, it will be multiplexed serially (LSB first) into the proper position in the outgoing
T1 data stream. After the full eight bits has been shifted out, the framer will signal the host
microcontroller that the buffer is empty and that more data is needed by setting the SR2.3 bit to a one.
The INT* will also toggle low if enabled via IMR2.3. The user has 2 ms to update the TFDL with a new
value. If the TFDL is not updated, the old value in the TFDL will be transmitted once again. The framer
also contains a zero stuffer, which is controlled via the CCR2.4 bit. In both ANSI T1.403 and TR54016,
communications on the FDL follows a subset of a LAPD protocol. The LAPD protocol states that no
more than 5 ones should be transmitted in a row so that the data does not resemble an opening or closing
flag (01111110) or an abort signal (11111111). If enabled via CCR2.4, the framer will automatically look
for 5 ones in a row. If it finds such a pattern, it will automatically insert a zero after the five ones. The
CCR2.0 bit should always be set to a one when the framer is inserting the FDL. More on how to use the
DS21Q42 in FDL applications is covered in a separate Application Note.

TFDL: TRANSMIT FDL REGISTER (Address = 7E Hex)

[Also used to insert Fs framing pattern in D4 framing mode; see Section 15.3]

(MSB)

(LSB)

TFDL7

TFDL6

TFDL5

TFDL4

TFDL3

TFDL2

TFDL1

TFDL0

SYMBOL

POSITION

NAME AND DESCRIPTION

TFDL7

TFDL.7

MSB of the FDL code to be transmitted

TFDL0

TFDL.0

LSB of the FDL code to be transmitted

The Transmit FDL Register (TFDL) contains the Facility Data Link (FDL) information that is to be
inserted on a byte basis into the outgoing T1 data stream. The LSB is transmitted first.

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15.2.4 D4/SLC96 OPERATION

In the D4 framing mode, the framer uses the TFDL register to insert the Fs framing pattern. To allow the
device to properly insert the Fs framing pattern, the TFDL register at address 7Eh must be programmed to
1Ch and the following bits must be programmed as shown: TCR1.2=0 (source Fs data from the TFDL
register) CCR2.5=1 (allow the TFDL register to load on multiframe boundaries)

Since the SLC96 message fields share the Fsbit position, the user can access the these message fields
via the TFDL and RFDL registers. Please see the separate Application Note for a detailed description of
how to implement a SLC96

16. PROGRAMMABLE INBAND CODE GENERATION AND DETECTION

Each framer in the DS21Q42 has the ability to generate and detect a repeating bit pattern that is from one
to eight bits in length. To transmit a pattern, the user will load the pattern to be sent into the Transmit
Code Definition (TCD) register and select the proper length of the pattern by setting the TC0 and TC1
bits in the InBand Code Control (IBCC) register. Once this is accomplished, the pattern will be
transmitted as long as the TLOOP control bit (CCR3.1) is enabled. Normally (unless the transmit
formatter is programmed to not insert the Fbit position) the framer will overwrite the repeating pattern
once every 193 bits to allow the Fbit position to be sent. See Figure 20-15 for more details. As an
example, if the user wished to transmit the standard "loop up" code for Channel Service Units which is a
repeating pattern of ...10000100001... then 80h would be loaded into TDR and the length would set to 5
bits.

Each framer can detect two separate repeating patterns to allow for both a "loop up" code and a "loop
down" code to be detected. The user will program the codes to be detected in the Receive Up Code
Definition (RUPCD) register and the Receive Down Code Definition (RDNCD) register and the length of
each pattern will be selected via the IBCC register. The framer will detect repeating pattern codes in both
framed and unframed circumstances with bit error rates as high as 10**2. The code detector has a
nominal integration period of 48 ms. Hence, after about 48 ms of receiving either code, the proper status
bit (LUP at SR1.7 and LDN at SR1.6) will be set to a one. Normally codes are sent for a period of 5
seconds. it is recommend that the software poll the framer every 100 ms to 1000 ms until 5 seconds has
relapsed to insure that the code is continuously present.

IBCC: INBAND CODE CONTROL REGISTER (Address=12 Hex)

(MSB)

(LSB)

TC1

TC0

RUP2

RUP1

RUP0

RDN2

RDN1

RDN0

SYMBOL

POSITION

NAME AND DESCRIPTION

TC1

IBCC.7

Transmit Code Length Definition Bit 1. See Table 161

TC0

IBCC.6

Transmit Code Length Definition Bit 0. See Table 161

RUP2

IBCC.5

Receive Up Code Length Definition Bit 2. See Table 162

RUP1

IBCC.4

Receive Up Code Length Definition Bit 1. See Table 162

RUP0

IBCC.3

Receive Up Code Length Definition Bit 0. See Table 162

RDN2

IBCC.2

Receive Down Code Length Definition Bit 2. See Table 162

RDN1

IBCC.1

Receive Down Code Length Definition Bit 1. See Table 162

RDN0

IBCC.0

Receive Down Code Length Definition Bit 0. See Table 162

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Table 16-1

TC1

TC0

LENGTH SELECTED

5 bits

6 bits / 3 bits

7 bits

8 bits / 4 bits / 2 bits / 1 bits

RECEIVE CODE LENGTH Table 16-2

RUP2/RDN2

RUP1/RDN1

RUP0/RDN0

LENGTH

SELECTED

1 bits

2 bits

3 bits

4 bits

5 bits

6 bits

7 bits

8 bits

TCD: TRANSMIT CODE DEFINITION REGISTER (Address=13 Hex)

(MSB)

(LSB)

SYMBOL

POSITION

NAME AND DESCRIPTION

TCD.7

Transmit Code Definition Bit 7. First bit of the repeating
pattern.

TCD.6

Transmit Code Definition Bit 6.

TCD.5

Transmit Code Definition Bit 5.

TCD.4

Transmit Code Definition Bit 4.

TCD.3

Transmit Code Definition Bit 3.

TCD.2

Transmit Code Definition Bit 2. A Don't Care if a 5 bit length
is selected.

TCD.1

Transmit Code Definition Bit 1. A Don't Care if a 5 or 6 bit
length is selected.

TCD.0

Transmit Code Definition Bit 0. A Don't Care if a 5, 6 or 7 bit
length is selected.

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RUPCD: RECEIVE UP CODE DEFINITION REGISTER (Address=14 Hex)

(MSB)

(LSB)

SYMBOL

POSITION

NAME AND DESCRIPTION

RUPCD.7

Receive Up Code Definition Bit 7. First bit of the repeating
pattern.

RUPCD.6

Receive Up Code Definition Bit 6. A Don't Care if a 1 bit
length is selected.

RUPCD.5

Receive Up Code Definition Bit 5. A Don't Care if a 1 or 2 bit
length is selected.

RUPCD.4

Receive Up Code Definition Bit 4. A Don't Care if a 1 to 3 bit
length is selected.

RUPCD.3

Receive Up Code Definition Bit 3. A Don't Care if a 1 to 4 bit
length is selected.

RUPCD.2

Receive Up Code Definition Bit 2. A Don't Care if a 1 to 5 bit
length is selected.

RUPCD.1

Receive Up Code Definition Bit 1. A Don't Care if a 1 to 6 bit
length is selected.

RUPCD.0

Receive Up Code Definition Bit 0. A Don't Care if a 1 to 7 bit
length is selected.

RDNCD: RECEIVE DOWN CODE DEFINITION REGISTER (Address=15 Hex)

(MSB)

(LSB)

SYMBOL

POSITION

NAME AND DESCRIPTION

RDNCD.7

Receive Down Code Definition Bit 7. First bit of the repeating
pattern.

RDNCD.6

Receive Down Code Definition Bit 6. A Don't Care if a 1 bit
length is selected.

RDNCD.5

Receive Down Code Definition Bit 5. A Don't Care if a 1 or 2
bit length is selected.

RDNCD.4

Receive Down Code Definition Bit 4. A Don't Care if a 1 to 3
bit length is selected.

RDNCD.3

Receive Down Code Definition Bit 3. A Don't Care if a 1 to 4
bit length is selected.

RDNCD.2

Receive Down Code Definition Bit 2. A Don't Care if a 1 to 5
bit length is selected.

RDNCD.1

Receive Down Code Definition Bit 1. A Don't Care if a 1 to 6
bit length is selected.

RDNCD.0

Receive Down Code Definition Bit 0. A Don't Care if a 1 to 7
bit length is selected.

DS21Q42

76 of 119

17. TRANSMIT

TRANSPARENCY

Each of the 24 T1 channels in the transmit direction of the framer can be either forced to be transparent or
in other words, can be forced to stop Bit 7 Stuffing and/or Robbed Signaling from overwriting the data in
the channels. Transparency can be invoked on a channel by channel basis by properly setting the TTR1,
TTR2, and TTR3 registers.

TTR1/TTR2/TTR3: TRANSMIT TRANSPARENCY REGISTER
(Address=39 to 3B Hex)

(MSB)

(LSB)

CH8

CH7

CH6

CH5

CH4

CH3

CH2

CH1

TTR1 (39)

CH16

CH15

CH14

CH13

CH12

CH11

CH10

CH9

TTR2 (3A)

CH24

CH23

CH22

CH21

CH20

CH19

CH18

CH17

TTR3 (3B)

SYMBOLS

POSITIONS

NAME AND DESCRIPTION

CH1-24

TTR1.0-3.7

Transmit Transparency Registers.
0 = this DS0 channel is not transparent
1 = this DS0 channel is transparent

Each of the bit position in the Transmit Transparency Registers (TTR1/TTR2/TTR3) represent a DS0
channel in the outgoing frame. When these bits are set to a one, the corresponding channel is transparent
(or clear). If a DS0 is programmed to be clear, no robbed bit signaling will be inserted nor will the
channel have Bit 7 stuffing performed. However, in the D4 framing mode, bit 2 will be overwritten by a
zero when a Yellow Alarm is transmitted. Also the user has the option to prevent the TTR registers from
determining which channels are to have Bit 7 stuffing performed. If the TCR2.0 and TCR1.3 bits are set
to one, then all 24 T1 channels will have Bit 7 stuffing performed on them regardless of how the TTR
registers are programmed. In this manner, the TTR registers are only affecting which channels are to have
robbed bit signaling inserted into them. Please see Figure 20-15 for more details.

18. INTERLEAVED PCM BUS OPERATION

In many architectures, the outputs of individual framers are combined into higher speed serial buses to
simplify transport across the system. The DS21Q42 can be configured to allow each framer's data and
signaling busses to be multiplexed into higher speed data and signaling busses eliminating external
hardware saving board space and cost.

The interleaved PCM bus option supports two bus speeds and interleave modes. The 4.096 MHz bus
speed allows two framers to share a common bus. The 8.192 MHz bus speed allows all four of the
DS21Q42's framers to share a common bus. Framers can interleave their data either on byte or frame
boundaries. Framers that share a common bus must be configured through software and require several
device pins to be connected together externally (see figures 18-1 & 18-2). Each framer's elastic stores
must be enabled and configured for 2.048 MHz operation. The signal RSYNC must be configured as an
input on each framer.

DS21Q42

77 of 119

For all bus configurations, one framer will be configured as the master device and the remaining framers
on the shared bus will be configured as slave devices. Refer to the IBO register description below for
more detail. In the 4.096 MHz bus configuration there is one master and one slave per bus. Figure 18-1
shows the DS21Q42 configured to support two 4.096 MHz buses. Bus 1 consists of framers 0 and 1. Bus
2 consists of framers 2 and 3. Framers 0 and 2 are programmed as master devices. Framers 1 and 3 are
programmed as slave devices. In the 8.192 MHz bus configuration there is one master and three slaves.
Figure 18-2 shows the DS21Q42 configured to support a 8.192 MHz bus. Framers 0 is programmed as
the master device. Framers 1, 2 and 3 are programmed as slave devices. Consult timing diagrams in
section 20 for additional information.

When using the frame interleave mode, all framers that share an interleaved bus must have receive signals
(RPOS & RNEG) that are synchronous with each other. The received signals must originate from the
same clock reference. This restriction does not apply in the byte interleave mode.

IBO: INTERLEAVE BUS OPERATION REGISTER (Address = 94 Hex)

(MSB)

(LSB)

IBOEN

INTSEL

MSEL0

MSEL1

SYMBOL

POSITION

NAME AND DESCRIPTION

IBO.6

Not Assigned. Should be set to 0.

IBO.6

Not Assigned. Should be set to 0.

IBO.5

Not Assigned. Should be set to 0.

IBO.4

Not Assigned. Should be set to 0.

IBOEN

IBO.3

Interleave Bus Operation Enable
0 = Interleave Bus Operation disabled.
1 = Interleave Bus Operation enabled.

INTSEL

IBO.2

Interleave Type Select
0 = Byte interleave.
1 = Frame interleave.

MSEL0

IBO.1

Master Device Bus Select Bit 0 See table 18-1.

MSEL1

IBO.0

Master Device Bus Select Bit 1 See table 18-1.

Master Device Bus Select Table 18-1

MSEL1

MSEL0

Function

Slave device.

Master device with 1 slave device (4.096 MHz bus rate)

Master device with 3 slave devices (8.192 MHz bus rate)

Reserved

DS21Q42

78 of 119

4.096 MHz Interleaved Bus External Pin Connection Example Figure 18-1

8.192 MHz Interleaved Bus External Pin Connection Example Figure 18-2

RSYSCLK0

TSYSCLK0

RSER0

TSER0

RSYNC0

TSSYNC0

RSIG0

TSIG0

FRAMER 0

RSYSCLK1

TSYSCLK1

RSER1

TSER1

RSYNC1

TSSYNC1

RSIG1

TSIG1

FRAMER 1

SYSCLK
SYNC INPUT
RSER
TSER
RSIG
TSIG

Bus 1

Bus 2

RSYSCLK2

TSYSCLK2

RSER2

TSER2

RSYNC2

TSSYNC2

RSIG2

TSIG2

FRAMER 2

RSYSCLK3

TSYSCLK3

RSER3

TSER3

RSYNC3

TSSYNC3

RSIG3

TSIG3

FRAMER 3

SYSCLK
SYNC INPUT
RSER
TSER
RSIG
TSIG

RSYSCLK0

TSYSCLK0

RSER0

TSER0

RSYNC0

TSSYNC0

RSIG0

TSIG0

FRAMER 0

RSYSCLK1

TSYSCLK1

RSER1

TSER1

RSYNC1

TSSYNC1

RSIG1

TSIG1

FRAMER 1

RSYSCLK2

TSYSCLK2

RSER2

TSER2

RSYNC2

TSSYNC2

RSIG2

TSIG2

FRAMER 2

RSYSCLK3

TSYSCLK3

RSER3

TSER3

RSYNC3

TSSYNC3

RSIG3

TSIG3

FRAMER 3

SYSCLK
SYNC INPUT
RSER
TSER
RSIG
TSIG

DS21Q42

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19. JTAG-BOUNDARY SCAN ARCHITECTURE AND TEST ACCESS PORT

19.1 Description

The DS21Q42 IEEE 1149.1 design supports the standard instruction codes SAMPLE/PRELOAD,
BYPASS, and EXTEST. Optional public instructions included with this design are HIGHZ, CLAMP, and
IDCODE. See Figure 19-1 for a block diagram. The DS21Q42 contains the following items, which meet
the requirements, set by the IEEE 1149.1 Standard Test Access Port and Boundary Scan Architecture.

Test Access Port (TAP)
TAP Controller
Instruction Register
Bypass Register
Boundary Scan Register
Device Identification Register

The JTAG feature is only available when the DS21Q42 feature set is selected (FMS = 0). The JTAG
feature is disabled when the DS21Q42 is configured for emulation of the DS21Q41B (FMS = 1). Details
on Boundary Scan Architecture and the Test Access Port can be found in IEEE 1149.1-1990, IEEE
1149.1a-1993, and IEEE 1149.1b-1994.

The Test Access Port has the necessary interface pins; JTRST*, JTCLK, JTMS, JTDI, and JTDO. See the
pin descriptions for details.

Boundary Scan Architecture Figure 19-1

Boundary Scan
Register

Identification
Register

Bypass
Register

Instruction
Register

JTDI

JTMS

JTCLK

JTRST

JTDO

Test Access Port
Controller

MUX

10K

Select
Output Enable

DS21Q42

80 of 119

19.2 TAP Controller State Machine

This section covers the details on the operation of the Test Access Port (TAP) Controller State Machine.
Please see Figure 19.2 for details on each of the states described below.

TAP Controller

The TAP controller is a finite state machine that responds to the logic level at JTMS on the rising edge of
JTCLK.

Test-Logic-Reset

Upon power up of the DS21Q42, the TAP Controller will be in the Test-Logic-Reset state. The
Instruction register will contain the IDCODE instruction. All system logic of the DS21Q42 will operate
normally.

Run-Test-Idle

The Run-Test-Idle is used between scan operations or during specific tests. The Instruction register and
Test registers will remain idle.

Select-DR-Scan

All test registers retain their previous state. With JTMS low, a rising edge of JTCLK moves the controller
into the Capture-DR state and will initiate a scan sequence. JTMS HIGH during a rising edge on JTCLK
moves the controller to the Select-IR

Capture-DR

Data may be parallel-loaded into the Test Data registers selected by the current instruction. If the
instruction does not call for a parallel load or the selected register does not allow parallel loads, the Test
register will remain at its current value. On the rising edge of JTCLK, the controller will go to the Shift-
DR state if JTMS is low or it will go to the Exit1-DR state if JTMS is high.

Shift-DR

The Test Data register selected by the current instruction will be connected between JTDI and JTDO and
will shift data one stage towards its serial output on each rising edge of JTCLK. If a Test Register
selected by the current instruction is not placed in the serial path, it will maintain its previous state.

Exit1-DR

While in this state, a rising edge on JTCLK with JTMS high will put the controller in the Update-DR
state, and terminate the scanning process. A rising edge on JTCLK with JTMS low will put the controller
in the Pause-DR state.

Pause-DR

Shifting of the test registers is halted while in this state. All Test registers selected by the current
instruction will retain their previous state. The controller will remain in this state while JTMS is low. A
rising edge on JTCLK with JTMS high will put the controller in the Exit2-DR state.

DS21Q42

81 of 119

Exit2-DR

While in this state, a rising edge on JTCLK with JTMS high will put the controller in the Update-DR
state and terminate the scanning process. A rising edge on JTCLK with JTMS low will enter the Shift-DR
state.

Update-DR

A falling edge on JTCLK while in the Update-DR state will latch the data from the shift register path of
the Test registers into the data output latches. This prevents changes at the parallel output due to changes
in the shift register. A rising edge on JTCLK with JTMS low, will put the controller in the Run-Test-Idle
state. With JTMS high, the controller will enter the Select-DR-Scan state.

Select-IR-Scan

All test registers retain their previous state. The instruction register will remain unchanged during this
state. With JTMS low, a rising edge of JTCLK moves the controller into the Capture-IR state and will
initiate a scan sequence for the Instruction register. JTMS high during a rising edge on JTCLK puts the
controller back into the Test-Logic-Reset state.

Capture-IR

The Capture-IR state is used to load the shift register in the instruction register with a fixed value. This
value is loaded on the rising edge of JTCLK. If JTMS is high on the rising edge of JTCLK, the controller
will enter the Exit1-IR state. If JTMS is low on the rising edge of JTCLK, the controller will enter the
Shift-IR state.

Shift-IR

In this state, the shift register in the instruction register is connected between JTDI and JTDO and shifts
data one stage for every rising edge of JTCLK towards the serial output. The parallel registers, as well as
all Test registers remain at their previous states. A rising edge on JTCLK with JTMS high will move the
controller to the Exit1-IR state. A rising edge on JTCLK with JTMS low will keep the controller in the
Shift-IR state while moving data one stage thorough the instruction shift register.

Exit1-IR

A rising edge on JTCLK with JTMS low will put the controller in the Pause-IR state. If JTMS is high on
the rising edge of JTCLK, the controller will enter the Update-IR state and terminate the scanning
process.

Pause-IR

Shifting of the instruction shift register is halted temporarily. With JTMS high, a rising edge on JTCLK
will put the controller in the Exit2-IR state. The controller will remain in the Pause-IR state if JTMS is
low during a rising edge on JTCLK.

Exit2-IR

A rising edge on JTCLK with JTMS low will put the controller in the Update-IR state. The controller will
loop back to Shift-IR if JTMS is high during a rising edge of JTCLK in this state.

DS21Q42

82 of 119

Update-IR

The instruction code shifted into the instruction shift register is latched into the parallel output on the
falling edge of JTCLK as the controller enters this state. Once latched, this instruction becomes the
current instruction. A rising edge on JTCLK with JTMS low, will put the controller in the Run-Test-Idle
state. With JTMS high, the controller will enter the Select-DR-Scan state.

TAP Controller State Machine Figure 19-2

19.3 Instruction Register and Instructions

The instruction register contains a shift register as well as a latched parallel output and is 3 bits in length.
When the TAP controller enters the Shift-IR state, the instruction shift register will be connected between
JTDI and JTDO. While in the Shift-IR state, a rising edge on JTCLK with JTMS low will shift the data
one stage towards the serial output at JTDO. A rising edge on JTCLK in the Exit1-IR state or the Exit 2-
IR state with JTMS high will move the controller to the Update-IR state The falling edge of that same
JTCLK will latch the data in the instruction shift register to the instruction parallel output. Instructions
supported by the DS21Q42 with their respective operational binary codes are shown in Table 19-1.

Select
DR-Scan

Capture DR

Shift DR

Exit DR

Pause DR

Exit2 DR

Update DR

Select
IR-Scan

Capture IR

Shift IR

Exit IR

Pause IR

Exit2 IR

Update IR

Test Logic
Reset

Run Test/
Idle

DS21Q42

83 of 119

Instruction Codes For The DS21352/552 IEEE 1149.1 Architecture Table 19-1

Instruction

Selected Register

Instruction Codes

SAMPLE/PRELOAD

Boundary Scan

010

BYPASS

Bypass

111

EXTEST

Boundary Scan

000

CLAMP

Boundary Scan

011

HIGHZ

Boundary Scan

100

IDCODE

Device Identification

001

SAMPLE/PRELOAD

A mandatory instruction for the IEEE 1149.1 specification. This instruction supports two functions. The
digital I/Os of the DS21Q42 can be sampled at the boundary scan register without interfering with the
normal operation of the device by using the Capture-DR state. SAMPLE/PRELOAD also allows the
DS21Q42 to shift data into the boundary scan register via JTDI using the Shift-DR state.

EXTEST

EXTEST allows testing of all interconnections to the DS21Q42. When the EXTEST instruction is latched
in the instruction register, the following actions occur. Once enabled via the Update-IR state, the parallel
outputs of all digital output pins will be driven. The boundary scan register will be connected between
JTDI and JTDO. The Capture-DR will sample all digital inputs into the boundary scan register.

BYPASS

When the BYPASS instruction is latched into the parallel instruction register, JTDI connects to JTDO
through the one-bit bypass test register. This allows data to pass from JTDI to JTDO not affecting the
device's normal operation.

IDCODE

When the IDCODE instruction is latched into the parallel instruction register, the Identification Test
register is selected. The device identification code will be loaded into the Identification register on the
rising edge of JTCLK following entry into the Capture-DR state. Shift-DR can be used to shift the
identification code out serially via JTDO. During Test-Logic-Reset, the identification code is forced into
the instruction register's parallel output. The ID code will always have a `1' in the LSB position. The next
11 bits identify the manufacturer's JEDEC number and number of continuation bytes followed by 16 bits
for the device and 4 bits for the version. See Table 19-2. Table 19-3 lists the device ID codes for the
DS21Q42 and DS21Q44 devices.

ID Code Structure Table 19-2

MSB

LSB

Contents

Version

(Contact Factory)

Device ID

(See Table 19-3)

JEDEC

"00010100001"

"1"

Length

4 bits

16bits

11bits

1bit

DS21Q42

84 of 119

Device ID Codes Table 19-3

DEVICE

16-BIT NUMBER

DS21Q42

0000h

DS21Q44

0001h

HIGH

All digital outputs of the DS21Q42 will be placed in a high impedance state. The BYPASS register will
be connected between JTDI and JTDO.

CLAMP

All digital outputs of the DS21Q42 will output data from the boundary scan parallel output while
connecting the bypass register between JTDI and JTDO. The outputs will not change during the CLAMP
instruction.

19.4 Test Registers

IEEE 1149.1 requires a minimum of two test registers; the bypass register and the boundary scan register.
An optional test register has been included with the DS21Q42 design. This test register is the
identification register and is used in conjunction with the IDCODE instruction and the Test-Logic-Reset
state of the TAP controller.

Boundary Scan Register

This register contains both a shift register path and a latched parallel output for all control cells and
digital I/O cells and is 126 bits in length. Table 17-3 shows all of the cell bit locations and definitions.

Bypass Register

This is a single one-bit shift register used in conjunction with the BYPASS, CLAMP, and HIGHZ
instructions, which provides a short path between JTDI and JTDO.

Identification Register

The identification register contains a 32-bit shift register and a 32-bit latched parallel output. This register
is selected during the IDCODE instruction and when the TAP controller is in the Test-Logic-Reset state.

DS21Q42

85 of 119

Boundary Scan Register Description Table 19-4

DEVICE

PIN

SCAN

REGISTER BIT

SYMBOL

TYPE

CONTROL

BIT DESCRIPTION

TCHBLK0

TPOS0

TNEG0

RLINK0

RLCLK0

RCLK0

RNEG0

RPOS0

RSIG0

RCHBLK0

RSYSCLK0

RSYNC0.cntl

0 = RSYNCO an input
I = RSYNCO an output

RSYNC0

I/O

RSER0

VSS

VDD

SPARE1

RFSYNCO

JTRST*

TCLK0

TLCLK0

TSYNC0.cntl

0 = TSYNCO an input
I = TSYNCO an output

TSYNC0

I/O

TLINK0

A6/ALE (AS)

INT*

TSYSCLK1

TSER1

TSSYNC1

TSIG1

TCHBLK1

TPOS1

TNEG1

RLINK1

RLCLK1

RCLK1

DS21Q42

86 of 119

DEVICE

PIN

SCAN

REGISTER BIT

SYMBOL

TYPE

CONTROL

BIT DESCRIPTION

RNEG1

RPOS1

RSIG1

RCHBLK1

RSYSCLK1

FMS

RSYNC1.cntl

0 = RSYNC1 an input
I = RSYNC1 an output

RSYNC1

I/O

RSER1

JTMS

RFSYNC1

JTCLK

TCLK1

TLCLK1

TSYNC1.cntl

0 = TSYNC1 an input
I = TSYNC1 an output

TSYNC1

I/O

TLINK1

TEST

FS0

FS1

CS*

BTS

RD*/(DS*)

WR*/(R/W*)

MUX

TSYSCLK2

TSER2

TSSYNC2

TSIG2

TCHBLK2

TPOS2

TNEG2

RLINK2

RLCLK2

RCLK2

RNEG2

RPOS2

RSIG2

VSS

-79

VDD

RCHBLK2

RSYSCLK2

RSYNC2.cntl

0 = RSYNC2 an input

DS21Q42

87 of 119

DEVICE

PIN

SCAN

REGISTER BIT

SYMBOL

TYPE

CONTROL

BIT DESCRIPTION

I = RSYNC2 an output

RSYNC2

I/O

RSER2

JTDI

RFSYNC2

JTDO

125

TCLK2

124

TLCLK2

123

TSYNC2.cntl

0 = TSYNC2 an input
I = TSYNC2 an output

122

TSYNC2

I/O

121

TLINK2

120

TSYSCLK3

119

TSER3

118

TSSYNC3

117

TSIG3

116

TCHBLK3

115

TPOS3

114

TNEG3

113

RLINK3

112

RLCLK3

100

111

RCLK3

101

110

RNEG3

102

109

RPOS3

103

108

RSIG3

104

107

RCHBLK3

105

106

RSYSCLK3

105

RSYNC3.cntl

0 = RSYNC3 an input
I = RSYNC3 an output

106

104

RSYNC3

I/O

107

103

RSER3

108

102

8MCLK

109

101

RFSYNC3

110

VSS

111

VDD

112

100

CLKSI

113

TCLK3

114

TLCLK3

TSYNC3.cntl

0 = TSYNC3 an input
I = TSYNC3 an output

115

TSYNC3

I/O

116

TLINK3

BUS.cntl

0 = D0-D7 or AD0-AD7 are inputs
I = D0-D7 or AD0-AD7 are outputs

117

D0 or AD0

I/O

118

D1 or AD1

I/O

DS21Q42

104 of 119

21. OPERATING PARAMETERS

ABSOLUTE MAXIMUM RATINGS*

Voltage on Any Non-Supply Pin Relative to Ground

1.0V to +5.5V

Supply Voltage

-0.3V to +3.63V

Operating Temperature for DS21Q42T

°C to 7

°C

Operating Temperature for DS21Q42TN

°C to +8

°C

Storage Temperature

°C to +12

°C

* This is a stress rating only and functional operation of the device at these or any other conditions above
those indicated in the operation sections of this specification is not implied. Exposure to absolute
maximum rating conditions for extended periods of time may affect reliability.

RECOMMENDED DC OPERATING CONDITIONS

(

0
0
0
0

°C to 7

0
0
0
0

°C for DS21Q42T;

0
0
0
0

°C to +8

5
5
5
5

°C for DS21Q42TN)

PARAMETER

SYMBOL

MIN

TYP

MAX

UNITS

NOTES

Logic 1

2.0

5.5

Logic 1

0.3

+0.8

Supply

2.97

3.63

CAPACITANCE

(tA =2

5
5
5
5

°C)

PARAMETER

SYMBOL

MIN

TYP

MAX

UNITS

NOTES

Input Capacitance

Output Capacitance

OUT

DC CHARACTERISTICS

(

0
0
0
0

°C to 7

0
0
0
0

°C; VDD = 2.97 to 3.63V for DS21Q42T;

-4

0
0
0
0

°C to +8

5
5
5
5

°C; VDD = 2.97 to 3.63V for DS21Q42TN)

PARAMETER

SYMBOL

MIN

TYP

MAX

UNITS

NOTES

Supply Current @ 3.3V

Input Leakage

1.0

+1.0

µA

Output Leakage

1.0

µA

Output Current (2.4V)

1.0

Output Current (0.4V)

+4.0

Notes:

TCLK=RCLK=TSYSCLK=RSYSCLK=1.544 MHz; outputs open circuited.

0.0V < V IN < V DD .

Applied to INT* when 3stated.

DS21Q42

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AC CHARACTERISTICS
MULTIPLEXED PARALLEL PORT (MUX=1)

(0ºC to 70ºC; VDD = 2.97 to 3.63V for DS21Q42T

 40ºC to +85ºC; VDD = 2.97 to 3.63V for DS21Q42TN)

PARAMETER

SYMBOL

MIN

TYP

MAX

UNITS

NOTES

Cycle Time

CYC

200

Pulse Width, DS low or
RD*high

100

Pulse Width, DS high or
RD* low

100

Input Rise/Fall times

, t

R/W* Hold Time

RWH

R/W* Set Up time before
DS high

RWS

CS*, FSO or FS1 Set Up
time before DS, WR* or
RD* active

CS*, FSO or FS1 Hold
time

Read Data Hold time

DHR

Write Data Hold time

DHW

Muxed Address valid to
AS or ALE fall

ASL

Muxed Address Hold
time

AHL

Delay time DS, WR* or
RD* to AS or ALE rise

ASD

Pulse Width AS or ALE
high

ASH

Delay time, AS or ALE
to DS, WR* or RD*

ASED

Output Data Delay time
from DS or RD*

DDR

Data Set Up time

DSW

(see Figures 21-1 to 21-3 for details)

DS21Q42

106 of 119

AC CHARACTERISTICS
NONMULTIPLEXED PARALLEL PORT (MUX=0 )

(0ºC to 70ºC; VDD = 2.97 to 3.63V for DS21Q42T;

40ºC to +85ºC; VDD = 2.97 to 3.63V for 21Q42TN)

PARAMETER

SYMBOL

MIN

TYP

MAX

UNITS

NOTES

Set Up Time for A0 to
A7, FS0 or FS1 Valid to
CS*Active

Set Up Time for CS*
Active to either RD*,
WR*, or DS* Active

Delay Time from either
RD* or DS* Active to
Data Valid

Hold Time from either
RD*, WR*, or DS*
Inactive to CS* Inactive

Hold Time from CS*
Inactive to Data Bus 3
state

Wait Time from either
WR* or DS* Active to
Latch Data

Data Set Up Time to
either WR* or DS*
Inactive

Data Hold Time from
either WR* or DS*
Inactive

Address Hold from either
WR* or DS* inactive

See Figures 214 to 217 for details.

DS21Q42

107 of 119

AC CHARACTERISTICS RECEIVE SIDE

(0ºC to 70ºC; VDD = 2.97 to 3.63V for DS21Q42T;

40ºC to +85ºC; VDD = 2.97 to 3.63V for DS21Q42TN)

PARAMETER

SYMBOL

MIN

TYP

MAX

UNITS

NOTES

RCLK Period

648

RCLK Pulse Width

75
75

ns
ns

RSYSCLK Period

122
122

648
488

ns
ns

1
2

RSYSCLK Pulse Width

t SL

50
50

ns
ns

RSYNC Set Up to
RSYSCLK Falling

RSYNC Pulse Width

RPOS/RNEG Set UP to
RCLK Falling

RPOS/RNEG Hold From
RCLK Falling

RSYSCLK/RCLK Rise
and Fall Times

, t

Delay RCLK to RSER,
RSIG, RLINK Valid

Delay RCLK to
RCHCLK, RSYNC,
RCHBLK, RFSYNC,
RLCLK

Delay RSYSCLK to
RSER, RSIG Valid

Delay RSYSCLK to
RCHCLK, RCHBLK,
RMSYNC, RSYNC

See Figures 21-8 to 21-10 for details.

Notes:

RSYSCLK = 1.544 MHz.

RSYSCLK = 2.048 MHz.

DS21Q42

108 of 119

AC CHARACTERISTICS TRANSMIT SIDE

(0ºC to 70ºC; VDD = 2.97 to 3.63V for DS21Q42T;

40ºC to +85ºC; VDD = 2.97 to 3.63V for DS21Q42TN)

PARAMETER

SYMBOL

MIN

TYP

MAX

UNITS

NOTES

TCLK Period

648

TCLK Pulse Width

75
75

ns
ns

TCLKI Pulse Width

75
75

ns
ns

TSYSCLK Period

122
122

648
448

ns
ns

1
2

TSYSCLK Pulse Width

50
50

ns
ns

TSYNC or TSSYNC Set
Up to TCLK or
TSYSCLK falling

TSYNC or TSSYNC
Pulse Width

TSER, TSIG, TLINK Set
Up to TCLK, TSYSCLK
Falling

TSER, TSIG, TLINK
Hold from TCLK,
TSYSCLK Falling

TCLK or TSYSCLK Rise
and Fall Times

, t

Delay TCLK to TPOS,
TNEG Valid

Delay TCLK to
TCHBLK, TCHBLK,
TSYNC, TLCLK

Delay TSYSCLK to
TCHCLK, TCHBLK

See Figures 2111 to 2113 for details.

Notes:

TSYSCLK = 1.544 MHz.

TSYSCLK = 2.048 MHz.

Ð­Ð»ÐµÐºÑ‚Ñ€Ð¾Ð½Ð½Ñ‹Ð¹ ÐºÐ¾Ð¼Ð¿Ð¾Ð½ÐµÐ½Ñ‚: DS21Q42

ÐÐ»ÐµÐºÑ‚Ñ€Ð¾Ð½Ð½Ñ‹Ð¹ ÐºÐ¾Ð¼Ð¿Ð¾Ð½ÐµÐ½Ñ‚: DS21Q42