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Document:	DZV11 Asynchronous Multiplexer User's Guide
Order Number:	EK-DZV11-UG
Revision:	002
Pages:	44
Original Filename:

OCR Text

DZV11 asynchronous

multiplexer

user’'s guide

EK-DZV11-UG-002

DZV11 asynchronous

multiplexer
user's guide

digital equipment' corporation - maynard, massachusetts

1st Edition, February 1978
2nd Printing (Rev), August 1978

The material in this manual is for informational
purposes and is subject to change without notice.

Digital Equipment Corporation assumes no responsibility for any errors which may appear in this
manual.
Printed in U.S.A,

This document was set on DIGITAL’s DECset-8000
computerized typesetting system.

The following are trademarks of Digital Equipment

Corporation, Maynard, Massachusetts:
DEC
DECCOMM

DECtape
DECUS

PDP

DECsystem-10

DIGITAL

DECSYSTEM-20

MASSBUS

TYPESET-8
TYPESET-11

RSTS

UNIBUS

CONTENTS

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CHAPTER 2

INSTALLATION

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CHAPTER 3

DEVICE REGISTERS

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324
3.2.5
3.2.6

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CHAPTER 1

Page

CONTENTS (Cont)
Page

CHAPTER 4

PROGRAMMING

4.1

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APPENDIX A

GLOSSARY

4.4.6

A-1

FIGURES
Figure No.

Title

Page

DZV11-A (M7957 MOAUIE)....ccuviiiiiiiiiieiicceriecreiiecere
s eeee e sara e sans s ena e e v 1=2
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Cable Assembly BCIIU-=25) ..o
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M7957 Vector SeleCtioN......cicvviiiiieiiieiiniiieeiriiireeernresrieessrmieessstesssssnenssessnssenens 274
Register Bit ASSIZNMENTS.......ccciiviiiiiiiiiiiiiiiciiiiiiiiseiseenissesmnessses
32

TABLES
Table No.
2-1

2-2
2-3
2-4

Title

Page

Items Supplied per Configuration................... rereereeranes rrreeeeere e e eeae e e raaeaaaas 2-1
Jumper Configuration......... Creererereanseeaieens cereerinene eereree et e eeeeae
et aeea e easaaeeenes.2-3
M7957 Vector Address Switch Selcctlon ............................................................... 2-4
V ector SwltCh Selcctlon
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3-1

R R BAE D E R BRI BIERBEB YD RED SR 2 - 5

CHAPTER 1
(ERAL DESCRIPTION

1.1 INTRODUCTION
The DZV11, shown in Figure 1-1, is an asynchronous multiplexer that provides an interface between
an LSI-11 processor and four asynchronous serial data communication channels. It can be used with
the LSI-11 processor in a variety of applications that include data concentration, real time processing
and cluster controlling. The DZV11 provides an EIA RS232C interface and enough data set control to
permit dial-up (auto answer) operation withmodems capable of full-duplex operation*, such as the
Bell models 103, 113, 212, or equivalent. Remote operation over private lines for full-duplex point to
point or full-duplex multipoint as a control é?fi%fiif’} station is also possible. Figure 1-2 depicts several
of the possible applications for the DZV11 in an LSI-11 system.

/ BERG CONNECTOR

VECTORSELECT

swiTCcHE2

w~ ADDRESS SELECT
SWITCH E30

9024-3

Figure 1-1

DZV11-A (M7957 Module)

*The DZV11 data set control does not support half-duplex operations or the secondary transmit and receive
operations available with some modems such as the Bell 202, etc.

-1

LOCAL

REMOTE

TELEPHONE

DATA

| REMOTE

QBUS

SET

TERMINAL

Dzvi1

___ __ _] pata

| TELEPHONE

|
|
|
I
i

LSI-11

SYSTEM

LINE

DzZV11

|
Figure 1-2

Q BUS

| SET

LSI-11

SYSTEM

MA.-0553

DZV11 System Applications

The DZVI11 has several features that provide flexible control of parameters such as baud rate, character length, number of stop bits for each line, odd or even parity for each line, and transmitter-receiver
interrupts. Additional features include limited data set control, zero receiver baud rate, break generation and detection, silo buffering of received data, and line turnaround.
Program compatibility is maintained with the Unibus option DZ11-A. The only compatibility exception is the number of serial channels supported. The DZV11 does not support 20 mA operation.
1.2 PHYSICAL DESCRIPTION
The DZV11 comprises a single quad size module, 21.6 cm X 26.5 cm (8.51 inches X 10.44 inches), and
is designated as the M7957 module. All input and output leads are available on a Berg header. The
DZV11 connects to the LSI-11 QBUS by the H9270 mounting panel or equivalent. All QBUS input/output signals enter and leave the module via the mounting panel pins.

1-2

1.2.1 DZVI 1 Configurations
The DZV11 can be supplied irg two configurations. The DZV11-A, as shown in Figure 1-1, consists
of
the M7957 module only. Cabling assemblies for connection to terminals and modem channels are not
supplied with the DZV11-A, but are available in the DZV11-B. The DZV11-B consists of an M7957
module, BC1 1U-25 cable assembly, and two accessory test connectors, H329 and H325. This configuration is shown in Figure 1-3.

M7957 MODULE

,CABLE ASSEMBLY

BC11U-25

\ TEST CONNECTOR H325
\TEST CONNECTOR
H329

9024-2

Figure 1-3 DZV11-B (M7957 Module, H325 and H329
Connectors and Cable Assembly BC11U-25)

1.2.2

BCI11U Interface Cable

The interfacing cable for terminal and modem connections to the DZV11-B is provided by the BC11U
cable assembly (see Figure 1-3). It consists of four separate cables, 762 cm (25 feet) in length, each
terminated by a separate EIA type connector housing and a common Berg housing. Each cable within
the assembly provides nine input/output leads. The EIA connector pinning conforms to EIA standard
RS232C and CCITT* recommendation V.24. The leads supported by the DZV11-B are:
Circuit AA (CCITT 101)
Circuit AB (CCITT 102)
Circuit BA (CCITT 103)
Circuit BB (CCITT 104)
Circuit CD(CCITT 108.2)
Circuit CE (CCITT 1295)
Circuit CF (CCITT 109)

Pin 1
Pin 7
Pin 2
Pin 3
Pin 20
Pin 22
Pin 8

Protective Ground
Signal Ground
Transmitted Data
Received Data
Data Terminal Ready
Ring Indicator
Carrier

NOTE

Signal ground and protective ground are connected
together.

*CCITT - the Consultive Committee International Telegraph and Telephone is an advisory committee estab-

lished under the United Nations to recommend worldwide standards.

1-3

1.2.3 Test Connectors
Figure 1-4 shows the two accessory test connectors, H329 and H325 that are provided with each
DZV11-B. The H325 plugs into an EIA connector on the BC11U to loopback data and modem signals
onto a single line. The H329 plugs into the M7957 module socket housing and provides staggered
loopback of the data and modem lines. The loopback connections are shown in Figure 1-5.

1.3 SPECIFICATIONS
Environmental, electrical, and performance specifications for the DZV11 are discussed in the following paragraphs.
1.3.1 Environmental
The DZV11 operates in an environment from 5° to 50° C (41° to 122° F) andin a relative humidity of
10% to 95%.

1.3.2

Electrical

Power Consumption

1.1I5SA@ +5Vdc

0.39A@ +12 Vdc
For each line the DZV11 provides a voltage level interface whose levels and connections conform to
EIA standard RS232C and CCITT recommendation V.24. The leads supported by the DZV11 are
listed in topic 1.2.2. Each DZV11 meets the LSI-11 QBUS Interface specification and represents one
unit load as an interface.
1.3.3 Performance
The following paragraphs describe the DZV11 performance capabilities and restrictions.

1.3.3.1 Maximum Configurations - The DZV11 multiplexer is assigned a device address in the floating address space. The floating address space starts at 760010 and extends to 764000. A maximum
configuration of DZV11s would not be limited by floating address space, but would be limited by the
rules governing an intermediate size system configuration. Therefore, a maximum of seven DZV11
multiplexers may reside in a nine by four backplane.
1.3.3.2 Throughput - Each DZV11 is capable of a throughput rate of 10,970 characters per second.
This rate is calculated as follows:

(Bits/Second X No. Lines X Direction) divided by Bits/Character.
(9600 X 4 X 2) 1/7 equals 10,970 Characters/Second.

For a character service routine of 100 us or less, the device throughput rate can be sustained.
1.3.3.3 Receivers - The receivers provide serial to parallel conversion of 5, 6, 7, 8 level code with one
start space and at least one stop mark. The character length, number of stop bits, parity generation and
operating speed are programmable parameters for each line. A receiver and transmitter of a corre]spondmg line share the same operating speed with provisions for enabling/disabling of that receive
ine

Each receiver is double-buffered and has an allowable input distortion of 43.75% on any bit. Also, the
accumulated character distortion must not exceed 43.75%. Break detection is provided on each receiver.

H329
90241

Test Connectors

1-5

25 and

H329

H329 STAGGERED TURNAROUND
TRANSMIT O

- RECEIVE 1

DTR O

® RING 1

l-—-—. CARRIER 1

RING O *'---—'--

CARRIER 0 -

RECEIVE 0 @

DTR 1

TRANSMIT 1

NOTE:
LINES 283 ARE STAGGERED IN THE SAME WAY.

H325 LOOPBACK CONNECTIONS

SCE

SCT

SCR L2

oj
SEC RCV

XMIT DATA

RCV DATA

z
4

REQ TO SEND =iy

CLR TO SEND

NEW SYNC —fi—-——-"
DATA SET RDY

DTR

RING

6
JUMPER
20

REMOVED

22
MA.-0551

Figure 1-5

Loopback Connections

1-6

1.3.3.4 Transmitters - The transmitters provide parallel to serial conversion of 5, 6, 7, 8 level code
with or without parity. The parity sense when selected can be either odd or even. The stop code can be

either 1 or 2 units except when 5 level code is selected. When 5 level code is selected, the stop code can
be set to 1 or 1.5 units. The character length, number of stop units, parity generation and sense, and
operating speed are programmable parameters for each line. The operating speed for the transmitter is
common with the receiver. Breaks are capable of being transmitted on any line. The gross start-stop
distortion for a transmitter’s TTL output will be less than 2.5% for an 8-bit character.
1.3.3.5 Baud Rate Generator - The baud rate generator is a MOS/LSI device which provides the
DZV11 multiplexer with full programmable capability for operating speed selection. Each line has an
independent generator capable of producing 1 of 15 selectable baud rates. Speed tolerance
for all rates
is less than 0.3% with a clock duty of 50% + 5%. (See below for rates.)

1.3.3.6

Performance Summary - The following summarizes the programmable features offered for

each line:

Character length

5, 6, 7, or 8 level code

Number of stop bits

1 or 2 for 6, 7, 8 level code

Parity

odd, even or none

Baud rates
Breaks
1.3.4

1 or 1.5 for 5 level code

50, 75, 110, 134.5, 150, 300, 600, 1200, 1800, 2000, 2400, 3600,

4800, 7200, and 9600

Can be generated and detected on each line.

Interrupts

The following interrupts are available on DZV11.
Receiver Done Interrupt

Occurs every time a character appears at the output of the receiver buffer register and the Silo Alarm is
disabled. Can be enabled or disabled from the bus.

Silo Alarm Interrupt

Occurs after 16 entries have been made into the receive buffer register by the scanner. This interrupt
disables Receiver Done Interrupt and is rearmed when the receive buffer register has been read.

Transmit Interrupt

Occurs every time the scanner finds a UART buffer empty condition, and the transmitter control
register bit is set for that line. Can be enabled or disabled from the bus.

1-7

CHAPTER 2

INSTALLATION

2.1

SCOPE

This chapter contains the procedures for the unpackmg, installation, and initial checkout of the
DZV11 Asynchronous Muluplexer

2.2 UNPACKING AND INSPECTION
The DZV11 is packaged in accordance with commercial packaging practices. First, remove all packing
material and check the equipment against the shipping list. (Table 2-1 contains a list of supplied items
per configuration.) Report damage or shortage:s to the shipper immediately and notify the DIGITAL
represematwe Inspect all parts and carefully inspect the module for cracks, loose components, and
separations in the etched paths.

M7957 module
BC11U-25 cable assembly
H329 test connector
H325 test connector
Print set (B-TC-DZV11-0-1)
DZVI11-A and -B
Order number M P00462
Software kit ZJ251-RB
DZV11 User's Guide
(EK-DZV11-UG)

¢ ¢

1
1

Description

¢ ¢

Quantity

Items Supplied per Configuration
&

‘Table 2-1

2.3 INSTALLATION PROCEDURE

The following paragraphs describe the installation of the DZV11 option in an LSI-11 system.
2.3.1

Jumper Configuration

There are 16 machine-insertable jumpers on the M7957 module (Figure 2-1).

2.3.1.1
Device Operation - Jumpers W10 and W11 must be installed only when the module is used on
an H9270 backplane, or one that applies LSI-11 bus signals to the C and D sections of the module.

w8 —1—

w1 *""r‘”

VV4.w”””

W’IZ“"

7::::::3&:::3@

Wi13*

wo*

Wwi14* Wi15* W16*

A12

wi1o*

[O0m00g0a0]

w11l

100000000;

ADDRESS SWITCHES

VECTOR SWITCHES

P4
|

]

*NOTES:

JUMPERS W9, W12, W13, W14, W15, AND W16 ARE REMOVED ONLY
THEY SHOULD NOT BE REMOVED IN THE FIELD.
TURING TESTS.
JUMPERS W10 AND

W11

MUST

REMAIN

INSTALLED

WHEN

THE

FOR

MODULE

MANUFAC-

USED

A BACKPLANE THAT SUPPLIES LSI-11 BUS SIGNALS TO THE C AND D CONNECTORS

WHEN THE MODULE IS USED IN A BACKOF THE DZV11 (SUCH AS THE H9270).
PLANE THAT INTERCONNECTS THE C AND D SECTIONS TO AN ADJACENT MODULE,
JUMPERS

W10

AND

W11

MUST

REMOVED.
MK-0064

Figure 2-1

M7957 Jumper Locations

2-2

2.3.1.2 Modem Control Jumpers- There are eight jumpers used for modem control. The jumpers
labeled W1 through W4 connect Data Terminal Ready (DTR) to Request To Send (RTS). This allows
the DZV11 to assert both DTR and RTS if using a modem that requires control of RTS. These

jumpers must be installed to run the cable and external test diagnostic programs. The remammg four
jumpers, W5 through W8, connect the Forced Busy (FB) leads to the RTS leads. With these jumpers
installed, the assertion cf an RTS lead places an ON or BUSY signal on the corresponding Forced
Busy lead. The Forced Busy jumpers (W5 through W8) are normally cut out unless the modem requires them (Table 2-2).

Table 2-2

Jumper Configuration

Jumper

Connection

Line

Wi
W2
W3
W4
W5
W6
w7
W8

DTR to RTS
DTR to RTS
DTR to RTS
DTR to RTS
RTSto FB
RTSto FB
RTSto FB
RTSto FB

03
02
01
00
03
02
01
00

2.3.2 Module Installation
To install the M7957 module, perform the following.
.

Refer to Paragraph 4.2 for descriptions of the address assignments. Set the switches at E30
so that the module responds to its assigned address. When a switch is closed (ON), a binary
1 is decoded. When a switch is open (OFF), a binary 0 is decoded. Note that the switch
labeled 1 corresponds to address bit 12, 2 corresponds to address bit 11, etc. ( Figure 2-2 and
Table 2-3).

Vector selection is accomplished by the 8-position switch at E2. Switch positions 7 and 8 are
not used. Switch position 6 corresponds to vector bit 3, 5 corresponds to vector bit 4, etc.
When a switch is closed (ON), a binary | is decoded. When a switch is open (OFF), a binary
0 is decoded (Figure 2-3 and Table 2-4).

If the module is part of the DZV11-A option, perform step 3. If it is a part of the DZV11-B
option, proceed to step 4 for testing.
a.

Insert the module in a quad QBus slot of the backplane.

CAUTION
Insert and remove modules slowly and carefully to
avoid snagging module components on the card
~guides and changing switch settings inadvertently.

Run the DZVll diagnostics, MAINDECs DVDZA and DVDZB, in internal mode to

verify operation. Refer to the listing for assistance. Run at least three passes without
error.

Proceed to step 8.

ADDRESS SELECTOR

A12 A11 A10 A09 A08 AO7 AO6 A05 AO4 A03

10 | SWITCH

E30

MA-0915

E30

Figure 2-2

M7957 Address Selection

Table 2-3

Address Switch Selection

Switch
Address

1
2
3
4
A12 | A11 | A10 | A9

160000

160040

160010
160020
160030

160050
160060
160070

160100

163760 | 163770

NOTE:

7
A6

8
AS

9
A4

X
X
X

|Ix

6
A7

5
A8

X = ON
- = OFF

VECTOR SELECTOR
NOT
vO8 V07 V06 V05 V04 VO3 USED

|
ON

SWITCH

MA-0914

Figure 2-3

M7957 Vector Selection

2-4

X
-

X
X

10
A3

Table 2-4

Vector Switch Selection

> X

¢|

> x|

S 1

]

IS¢
¢ |

< &
|

!
i

b
)|

R
X X

> XK

K X X K X X
b
> X

o)e
Z

NOTE:

[

770

760

~
X

300
310
320
330
340
350
360
370
400

Vector | V08

R §w

g |

Insert the H329 test connector in J1 with the letter side facing up. J1 is the cable connector at

the top of the M7957 module.

Insert the module in a quad QBus slot of the backplane.
CAUTION
Insert and remove modules slowly and carefully to
avoid snagging module components on the card
guides and changing switch settings inadvertently.

Run the DZV11 diagnostics, MAINDECs DVDZA and DVDZB, in the staggered mode to
verify module operation. Refer to the diagnostic listing for the correct procedure. Run at
least three passes without error.

Replace the H329 test connector with the Berg end of the BC11U cable assembly. Observe
the “This Side Up” wording on the assembly. Refer to D-UA-DZV11-0-0 for installation
help.

Connect the H325 test connector on the first line and run MAINDEC DVDZC. Select the
cable test portion of the diagnostic. Three passes are required without error. Repeat this step
for each line.

Run DEC/X11 system exerciser to verify the absence of QBus interference with other system devices.

The DZV11 is now ready for connection to external equipment. If the connection is to a
local terminal through the DZV11-B option, a null modem cable assembly must be used.
Use the BCO3M or BCO3P null modem cables for connection between
the BC11U and the
terminal. The H312-A null modem unit may also be used in place of the null modem cables.
If connection is to a Bell 103 or equivalent modem, install the appropriate line of the BC11U
connector into the connector on the modem. A BCO5D cable may be required between the
BC11U and the modem. Refer to Paragraph 2.3.1.2, Modem Control Jumpers, for selection
of jumpers for modem options such as RTS and forced busy. All of the cables mentioned,
excluding the BC11U, must be ordered separately as they are not components of a standard
DZV11 shipment. When possible, run the diagnostic DVDZC in echo test mode to verify the
cable connections and the terminal equipment.

2-6

CHAPTER 3
DEVICE REGISTERS

3.1

SCOPE

3.2

DEVICE REGISTERS

This chapter provides a description of each DZV11 register, its format, and bit functions.

The DZV11 contains six addressable registers. A comprehensive pictorial of these registers’ bit assignments is shown in Figure 3-1. Table 3-1 lists the registers and associated DZV11 addresses.

Table 3-1

Register
Control and Status Register
Receiver Buffer
Line Parameter Register
Transmitter Control Register
Modem Status Register
Transmit Data Register

DZV11 Register Address Assignments

|
|

Mnemonic

Address

CSR
RBUF
LPR
TCR
MSR
TDR

76XXX0
76XXX2
76XXX2
76XXX4
T6XXX6
T6XXX6

Program

Capability

Read /Write
Read Only
Write Only
Read/Write
Read Only
Write Only

XXX = Selected in accordance with floating device address scheme.

3.2.1

Control and Status Register

The control and status register (CSR) is a byte and word addressable register. All bits in the CSR are
cleared by an occurrence of BINIT or by setting device Master Clear (CSR 04). The format is shown in
Figure 3-1 and the bit assignments are listed in Table 3-2.

3.2.2

Receiver Buffer

The Receiver Buffer (RBUF) is a 16-bit read only register which contains the received character at the
from the
output of the FI/FO buffer. A read of the register causes the character entry to be extracted
Data bit
Valid
the
Only
location.
ed
unoccupi
buffer and all other entries to bubble down to the lowest
are not
00-14
Bits
04).
(CSR
Clear
Master
(RBUF 15) is cleared by BINIT or by setting device
affected. The bit assignments for the RBUF register are listed in Table 3-3.

3-1

BYTES

MSB

|RwW

| RO

HIGH g LOW

|ro

RfRO

|RW

| RW

DRO

CONTROL

T né“Q "§°mm““~”
<

asTatus | TROY | TIE | sA
(CSR)

RECEIVER

DATA |OVRN|

(RBUF)

f§ro

|Ro

|RO

VA4

,....,..........,...é. Q né\

QO Q

/& VAN
N
S
N

FRAM | PAR

VALID|ERR | ERR

sAE | S/
| /g |TLUINE
|TLINE
JapoNEl RIE | MSE | CLR | maint |
S
B
A

“““““ bee smEven cweeh GHME BGOMND ReARG Geows BUlEN THNME OREr SHERG

BUFFER
DR2 <

|Ro | RO

LSB

ERR

| & o |S/

|| sgv
|

rRo

|ro

| rx

|wo

% | LINE | LINE

§
wo

LINE

|RO

| RO | R

amaee dcase eRes N Se owwe s GERKIES SRS GSOEE WRNED SEESR WMDH SR | GG desn SRR e cGee GSGD oD ] cmm mowe aEs seems SN Eaee SRS DGR BLER DRER SPRGE GERh do TR W WERED SREEN

“-&‘

|wo

RBUF|

jJjwo

| D6 | D5 | D4
|wo

|wo

RBUF

p2 | D1

| wo

PARAMETER

cope

(LPR)

|cooe |cope |cope

§PAR | ENAB | CODE | LGTH | LGTH

&
S Gf

LINE

LINE | LINE | LINE

;

TRANSMIT
DR4< | coNnTROL

A
S ..,g?

(TCR)

A
Ry §

A
SS

A
efi;é’

bTR | DTR | DTR | DTR |

1RO

|RO

;

MODEM

-tnne&

c--!\

qp*&

S®

SRS

STATUS

?u-n—--s-— P

(MSR)

TRANSMIT | O/ 8| O/&8]
. -

DATA

O/9

lmm&=

(TDR)

[

|RO

|co

fwo

|wo

BRK

|BRK

P ARSI

|RO

|co

eé %3

|co

|
.

DR6 <

|wo

—— S——

S/al 8/ 8/e|
/& | € gé“ = 3‘;‘

*n-&

-A’Qifi-f&qn&'

S
S

S|
S

ENAB | ENAB | ENAB | ENAB

rRo

| RO

RI 3

RI2

| RI1 | RIO

P T

/8| /L
S

fwo

|wo

TSR

JTBUF | TBUF
7

———— S

|TBUF
5

|wo

- WO
I

WOi | WO
i

MA-0552

Figure 3-1

3-2

Table 3-2
Title

CSR Bit Assig iments

Fuucfion

Not uwd
Maintenance

This bit, when set, loops all the transmitter’s serial output leads
to the corresponding receiver’s serial input leads on a TTL
basis. While operating in maintenance mode, the EIA received
data leads are disabled. Normal operating mode is assumed
when this bit is cleared. This bit is read /write.

- Master Clear

When written to a 1, generates “Initialize’” within the DZV11. A
read back of the CSR with this bit set, indicates initialize in
progress within the device. This bit is self-clearing. All registers,
silos, and UARTS are cleared with the following exceptions:
1.

Only bit 15 of the receiver buffer register (VALID
DATA); the remaining bits 00-14 are not.

The high byte of the transmitter control register is not
cleared by Master Clear.

The modem status register is not cleared by Master
Clear.

Master Scan
Enable

This read/write bit must be set to permit the receiver and transmitter control sections to begin scanning. When cleared, Transmitter Ready (CSR 15) will be inhibited from setting and the
received character buffers (silos) will be cleared.

Receiver
Interrupt
Enable

This bit, when set, permits the setting of CSR 07 or CSR 13 to
generate a receiver interrupt request. This bit is read/ write.

Receiver Done

This is a read only bit that will set when a character appears at
the output of the FI/FO buffer. To operate in interrupt per
character mode, CSR 06 must be set and CSR 12 must be
cleared. With CSR 06 and CSR 12 cleared, character flag mode
would be indicated. Receiver Done will clear when the receiver
buffer register (RBUF) is read or when Master Scan Enable
(CSR 05) is cleared. If the FI/FO buffer contains an additional
character, the Receiver Done flag will stay cleared a minimum
of 1 us before presenting that character.

08-09

Transmitter Line
Number

These read only bits indicate the line number whose transmit
buffer requires servicing. These bits are valid only when Transmitter Ready (CSR 15) is set and will be cleared when Master
Scan Enable is cleared. Bit 08 is the least significant bit.

10-11

Not used

Table 3-2

CSR Bit Assignments (Cont)

]

Bit

Title

Function

Silo Enable
Alarm

This is a read /write bit, when set, enables the silo alarm counter
to keep count of the number of characters stored in the FI/FO

buffer. The counter will be cleared when the Silo Alarm Enable
bit is cleared. Conditioning of this bit must occur prior to any
character reception.

Silo Alarm

This is a read only bit set by the hardware after 16 characters
have been entered into the FI/FO buffer. Silo Alarm will be
held cleared when Silo Alarm Enable (CSR 12) is cleared. This
bit will be reset by a read to the receiver buffer register and will
not set until 16 additional characters are entered into the buffer.
If Receiver Interrupt Enable (CSR 06) is set, the occurrence of
Silo Alarm will generate a receiver interrupt request. Reception
with CSR 06 cleared, permits flag mode operation of the Silo
Alarm bit.

Transmitter
Interrupt
Enable

Transmitter
Ready

This bit must be set for Transmitter Ready to generate an interrupt. It is read/write.

This bit is read only and is set by the hardware. This bit will set
when the transmitter clock stops on a line whose transmit buffer

may be loaded with another character and whose associated
TCR bit is set. The Transmitter Line Number, specified in CSR
08 and CSR 09, is only valid when Transmitter Ready is set.
Transmitter Ready will be cleared by any of the following
conditions:

Master Scan Enable cleared.

When the associated TCR bit is cleared for the line
number pointed to in CSR 08 and CSR 09.

At the conclusion of the load instruction of the transmit data register (low byte only).

If additional transmit lines require service, Transmitter Ready
will reappear within 1.4 us from the completion of the transmit
data register load instruction. The occurrence of Transmitter
Ready with Transmitter Interrupt Enable set, will generate a
transmitter interrupt request.

Table 3-3 RBUF Bit Assignments
00-07
m

Function

Title

Bit

Received

These bits contain the received character, right justified. The

Character

08-09

least significant bitis bit 00. Unused bits are 0 The parity bitis
not shown.

Received

These bits contain the line number upon which the aforemen-

Character

tioned character was received. Bit 08 is the least significant bit.

Line Number

- 10-11

Notused

Parity {Ermr

Framing Error

This bit is set if the received character did not have a stop bit

Overrun Error

This bit is set if the received character was preceded by a charac-

Valid Data

This bit, when set, indicates that the data presented in bits 00-14

3.2.3

f’

This bit is set if the sense of the parity of the received character
does not agree with that designated for that line.

present at the proper time. This bit is usually interpreted as indicating the reception of a break.

ter that was lost due to the inability of the receiver scanner to
service the UART receiver holding buffer on that line.

is valid. This bit permits the use of a character handling program that takes characters from the FI/FO buffer until there
are no more available. This is done by reading this register and
checking bit 15 until the program obtains a word for which bit
15 is zero.

Line Parameter Register

The line parameter register (LPR) controls the operating parameters associated with each line in the
DZV11. The LPR is a word addressable, write only register. The line parameters for all lines must be
reloaded following an occurrence of either BINIT or device Master Clear. Table 3-4 lists bit assignments.

3.2.4 Transmitter Control Register
The transmitter control register (TCR) is a byte and word addressable register. The low byte of the
TCR register containsthe transmitter control bits which must be set to initiate transmission on a line.
Each TCR bit p«omtmn corresponds to a line number. For example, TCR bit 00 corresponds to line 00,
bit 01 to line 01, etc. Smtmg of a TCR bit causes the transmitter scanner clock to stop if the UART for
this line has a transmit buffer empty condition. An interrupt will then be generated if Transmitter
Interrupt Enable is set. The scanner clock will restart when either the transmit data register is loaded
with a character or the TCR bit is cleared for the line on which the clock has stopped. TCR bits must

only be cleared when the scanner is not running, (i.e., Transmitter Ready is set or Master Scan Enable
is cleared.)

The TCR bits are represented in bits 00-03. These bits are read /write and are cleared by BINIT or
device Master Clear. Bits 04-07 are unused and read as zero.

The high byte of the TCR register contains the writable modem control lead, data terminal ready
(DTR). Bit designations are as follows:
Name

DTR Line 00
DTR Line 01
DTR Line 02
DTR Line 03
Unused; read as zero

Assertion of a DTR bit puts an ON condition on the appropriate modem circuit for that line. DTR
bits are read /write and are cleared only by BINIT. Jumpers have been provided to allow the Request
to Send circuits to be asserted with Data Terminal Ready assertions.
Table 3-4

LPR Bit Assignments

Bit

Title

Function

00-01

Parameter Line
Number

These bits specify the line number for which the parameter information (bits 3-12) is to apply. Bit 00 is the least significant

Not used

Must always be written as a zero when specifying the parameter
line number. Writing this bit as a one will extend the parameter
line number field into nonexistent lines. Parameters for lines
00-03 will not be affected.

03-04

Character
Length

These bits are set to receive and transmit characters of the

bit.

length (excluding parity) as shown below.

04
0
0
1
1
05

03
0
1
0
1

5 bit
6 bit
7 bit
8 bit

Stop Code

This bit sets the stop code length (0 = 1 unit stop, 1 = 2 unit
stop or 1.5 unit stop if a S-level code is employed).

Parity Enable

If this bit is set, characters transmitted on the line have an appropriate parity bit affixed, and characters received on the line
have their parity checked.

Odd Parity

If this bit is set and bit 06 is set, characters of odd parity are
generated on the line and incoming characters are expected to
have odd parity. If this bit is not set, but bit 06 is set, characters
of even parity are generated on the line and incoming characters
are expected to have even parity. If bit 06 is not set, the setting
of this bit is immaterial.

3-6

Table 3-4

LPR Bit Assignments (Cont)

Bit

Title

Functio

08-11

Speed Code

The state of these bits determine the operating speed for the

transmitter and receiver of the selected line.

0
0

0
0O

0
0

0
0
0
0
0
0
1
1
1
1
1
1
1
1

Receiver
Enable

13-15

3.2.5

1
1
0
0
1
1
0
0
1
1
0
0
1
1

0
0
1
1
1
1
0
0
0
0
1
1
1
1

Baud Rate
0
1.

0
1
0
1
0
1
0
1
0
1
0
1
0
1

50
75

110
134.5
150
300
600
1200
1800
2000
2400
3600
4800
7200
9600
Invalid

This bit must be set before the UART receiver logic can assemble characters from the serial input line. This bit will be
cleared following a BINIT or device Master Clear.

Not used

Modem Status Register

The modem status register (MSR) is a 16-bit read only register. A read to this register results in the
status of the readable modem control leads, Ring and Carrier. The ON condition of a modem control
lead is interpreted as a logical one. Bits 04-07 and 12-15 are unused and read as a zero. Remaining bit
designations are as follows:
Bit
00
01
02
03
04-07
08
09
10
11
12-15

Name
Ring Line 00
Ring Line 01
Ring Line 02
Ring Line 03

Unused; read as zero.
Carrier Line 00
Carrier Line 01
Carrier Line 02
Carrier Line 03
Unused; read as zero.

3-7

3.2.6 Transmit Data Register
The transmit data register (TDR) is a byte and word addressable, write only register. Characters for
transmission are loaded into the low byte. TDR bit 00 is the least significant bit. Loading of a
character should occur only when Transmitter Ready (CSR 15) is set. That character which is loaded
into this register is directed to the line defined in CSR bits 08 and 09. The high byte of the TDR is
designated as the break control register.
Each of the four multiplexer lines has a corresponding break bit for that line. TDR bit 08 represents
the break bit for line 00, TDR bit 09 for line 01, etc. TDR bits 12-15 are unused. Setting a break bit
will force that line’s output to space. This condition will remain until cleared by the program. This
register is cleared by BINIT or device Master Clear. The break control register can be utilized
regardless of the state of the device Maintenance bit (CSR 03).

3-8

PROGRAMMING

4.1

SCOPE

This chapter contains information for programming the DZV11 in the most efficient manner. To do
so, the programming controls must be fully understood. The following paragraphs discuss the DZV11
from the programming point of view and describe recommended programming methods.
The device address assigned to the DZV11 resides in the floating address space of the LSI-11. This
address space ranges from 1600105 to 163776s. Each DZV11 requires increments of 103 address locations and the first option should be configured with an address of 160010s. The initial configured
address assumes that the system consists of only DZV11s in the floating address field. If the DUV11
option is also configured
in the floating address field, assign the DZV11 an address which establishes a
gap of 103 address locations between the last DUVI1I and the first DZV11. For example: If the
sg;_stcm consisted of one DUV11 located at 160010g, the DZV11 should be configured with an address
4.3

INTERRUPT VECTOR ADDRESS ASSIGNMENTS

The DZV11 device vector address is selected from the floating vector space. This space ranges from
address 300; to address 776;. Each DZV11 requires increments of 10; address locations for its two
contiguous interrupt vectors. If the DZV11 is the only option in the floating vector area, configure it

for a vector of 300s. If there are options other than the DZV11 residing in the floating vector area,
other configuration rules must be applied. When configuring the device vector, only the first vector
address must be considered. The first vector, or base vector, must start on a zero boundary.

A zero boundary is one whlch has the three least significant bits equal to zero. The second vector is
controlled by the first vector and data bit 02. Data bit 02 is generated by the M7957 hardwware.
Any option ahead of DZVII in the floating vector space which is not in the configuration should not
occupy any vector space gap. For example, if only one DZVI11 is in the system the vector for the
DZV11 should be 300. ’l%‘he simplest case is as follows:
Option

Address

Vector

Comment

GAP
GAP
GAP
GAP
GAP
GAP
GAP
DZV11

-~
300

No QBUS compatible DJ11
No QBUS compatible DH11
No QBUS compatible DQ11
NoDUVI1I
No QBUS compatible DUP11
No QBUS compatible LK 11
No QBUS compatible DMCl11

GAP

No more DZV1ls

4-1

Each DZV11 requires two interrupt vectors, one for the transmitter section and one for the receiver
section. If simultaneous interrupt requests were generated from each section, the receiver section
would have priority in placing its vector onto the LSI bus. A receiver interrupt to address XX0 will be
generated from having either a Receiver Done (CSR 07) or Silo Alarm (CSR 13) occurrence. A transmitter interrupt to address XX4 will be generated by Transmitter Ready (CSR 15). Additional prerequisites for generating interrupts are that the individual interrupt enable bits (CSR 06 and CSR 14) be
set. The recommended method of clearing interrupt enable bits is to first raise the processor status
word to level four, next clear these interrupt enable bits and then lower the processor status word to
zero. Using this method prevents false interrupts from being generated.
4.4

PROGRAMMING FEATURES

The DZV11 has several programming features that allow control of baud rate, character length, stop
bits, parity, and interrupts. This section discusses the application of these controls to achieve the
desired operating parameters.

4.4.1

Baud Rate

Selection of the desired transmission and reception speed is controlled by the conditions of bits 08-11
of the LPR. Table 4-1 depicts the required bit configuration for each operating speed. The baud rate
for each line is the same for both the transmitter and receiver. The receiver clock is turned on and off
by setting and clearing bit 12 in the LPR for the selected line.

Table 4-1 Baud Rate Selection Chart

4.4.2

0
0
0
0
0
0
0
0
1
1
1
1
1
1
1
1

0
0
0
0
1
1
1
1
0
0
0
0
|
1
1
1

Bits

Baud Rate

0
0
1
1
0
0
1
1
0
0
1
1
0
0
1
1

0
1
0
1
0
1
0
1
0
]
0
1
0
1
0
|

50
75
110
134.5
150
300
600
1200
1800
2000
2400
3600
4800
7200
9600
Not used

Character Length

The selection of one of the four available character lengths is controlled by bits 03 and 04 of the LPR.
The bit conditions for bits 04 and 03, respectively, are as follows: 00 (5-level), 01 (6-level), 10 (7level), and 11 (8-level). For character lengths of 5, 6, and 7, the high-order bits of the received character
are forced to zero.

4.4.3 Stop Bits
The length of the stop bits in a serial character string is determined by bit 05 of the LPR. If bit 05 is a

zero, the stop length is one unit; bit 05 set to a one selects a 2-unit stop unless the 5-level character
length (bits 03 and 04 at zero) is selected, in which case the stop bit length is 1.5 units.

4.4.4 Parity
The parity option is selected by bit 06 of the LPR. Parity is enabled on transmission and reception by
setting bit 06 to a one. Bit 07 of the LPR allows selection of even or odd parity, and bit 06 must be set
for bit 07 to be significant. The parity bit is generated and checked by hardware and does not appear in
the RBUF or TBUF. The parity error (bit 12, RBUF) flag is set when the received character has a
parity error.
4.4.5 Interrupts
The receiver interrupt enable (RIE) and silo alarm enable (SAE) bits in the CSR control the circumstances upon which the DZV11 receiver interrupts the LSI-11 processor.

If RIE and SAE are both clear, the DZV11 never interrupts the LSI-11 processor. In this case, the
program must periodically check for the availability of data in the silo and empty the silo when data is
present. If the program operates off a clock, it should check for characters in the silo at least as often as
the time it takes for the silo to fill, allowing a safety factor to cover processor response delays and time
to empty the silo. The RDONE bit in the CSR will set when a character is available in the silo. The
program can periodically check this bit with a TSTB or BIT instruction. When RDONE is set, the
program should empty the silo.
If RIE is set and SAE is clear, the DZV11 will interrupt the LSI-11 processor to the DZV11 receiver
vector address when RDONE is set, indicating the presence of a character at the bottom of the silo.
The interrupt service routine can obtain the character by performing a MOV instruction from the
RBUF. If the program then dismisses the interrupt, the DZV11 will interrupt when another character
is available (which may be immediately if additional characters were placed in the silo while the interrupt was being serviced.) Alternatively, the interrupt service routine may respond to the interrupt by
emptying the silo before dismissing the interrupt.
If RIE and SAE are both set, the DZV11 will interrupt the LSI-11 processor to the DZV11 receiver
vector when the silo alarm (SA) bit in the CSR is set. The SA bit will be set when 16 characters have

been placed in the silo since the last time the program has accessed the RBUF. Accessing the RBUF
will clear the SA bit and the associated counter. The program should follow the procedure described in
Paragraph 4.4.6 to empty the silo completely in response to a silo alarm interrupt. This will ensure that
any characters placed in the silo while it is being emptied are processed by the program.

NOTE
If the program processes only 16 entries in response
to each silo alarm interrupt, characters coming in
while interrupts are being processed will build up
without being counted by the silo alarm circuit and
the silo may eventually overflow without the alarm
being issued.

If the silo alarm interrupt is used, the program will not be interrupted if fewer than 16 characters are

received. In order to respond to short messages during periods of moderate activity, the LSI-11 program should periodically empty the silo. The scanning period will depend on the required responsiveness to received characters. While the program is emptying the silo, it should ensure that DZV11
receiver interrupts are inhibited. This should be done by raising the LSI-11 processor priority. The silo

alarm interrupt feature can significantly reduce the LSI-11 processor overhead required by the DZV11

receiver by eliminating the need to enter and exit an interrupt service routine each time a character is

- received.

The transmitter interrupt enable (TIE) bit controls transmitter interrupts to the LSI-11 processor. If
enabled, the DZV11 will interrupt the LSI-11 processor at the DZV11 transmitter interrupt vector
when the transmitter ready (TRDY) bit in the CSR is set, indicating that the DZV11 is ready to accept
a character to be transmitted.

4.4.6 Emptying the Silo
The program can empty the silo by repeatedly performing MOV instructions from the RBUF to
temporary storage. Each MOV instruction will copy the bottom character in the silo so it will not be
lost and will clear out the bottom of the silo, allowing the next character to move down for access by a
- subsequent MOV instruction. The program can determine when it has emptied the silo by testing the
data valid bit in each word moved out of the RBUF. A zero value indicates that the silo has been
emptied. The test can be performed conveniently by branching on the condition code following each
MOV instruction. The TST or BIT instruction must not access the RBUF because these instructions
will cause the next entry in the silo to move down without saving the current bottom character. Furthermore, following a MOV from the RBUF, the next character in the silo will not be available for at
least one us. Therefore, on fast CPUs, the program must use sufficient instructions or NOPs to ensure
that successive MOVs from the RBUF are separated by a minimum of one us. This will prevent a false
indication of an empty silo.
4.4.7 Transmitting a Character
The program controls the DZV11 transmitter through four registers on the QBUS: the control and
status register (CSR), the line parameter register (LPR), the transmit control register (TCR), and the
transmit data register (TDR).
Following DZV11 initialization, the program must use the LPR to specify the speed and character
format for each line to be used and must set the master scan enable (MSE) bit in the CSR. The

program should set the transmitter interrupt enable (TIE) bit in the CSR if it wants the DZV11
transmitter to operate on a program interrupt basis.

The TCR is used to enable and disable transmission on each line. One bit in this register is associated
with each line. The program can set and clear bits by using MOV, MOVB, BIS, BISB, BIC, and BICB
instructions. (If word instructions are used, the line enable bits and the DTR bits are simultaneously
accessed.)
The DZV11 transmitter is controlled by a scanner which is constantly looking for an enabled line (line
enable bit set) which has an empty UART transmitter buffer. When the scanner finds such a line, it
loads the number of the line into the 2-bit transmit line number (TLINE) field of the CSR and sets the
TRDY bit, interrupting the LSI-11 processor if the TIE bit is set. The program can clear the TRDY bit
by moving a character for the indicated line into the TBUF or by clearing the line enable bit. Clearing
the TRDY bit frees the scanner to resume its search for lines needing service.
|

454

wait for
To initiate transmission on an idle line, the program should set the TCR bit for that line and
the line
of
number
the
loading
scanner
the
by
the scanner to request service on the line, as indicated
the
into
ed
transmitt
be
to
character
the
load
then
should
into TLINE and setting TRDY. The program
line
a
up
starting
of
way
nt
convenie
a
used,
be
to
are
pts
TBUF by using a MOVB instruction. Ifinterru
is to set the TCR bit in the main program and let the normal transmitter interrupt routine load the
character into the TBUF.

NOTE

The scanner may find a different line needing service
before it finds the line being started up. This will oc-

cur if other lines request service before the scanner
can find the line being started. The program must
always check the TLINE field of the CSR when responding to TRDY to ensure it loads characters for
the correct line. Assuming the program services lines
as requested by the scanner, the scanner will eventually find the line being started. If several lines require
service, the scanner will request service in priority
order as determined by line number. Line 3 has the
highest priority and line 0 the lowest.

To continue transmission on a line, the program should load the next character to be transmitted into
the TBUF each time the scanner requests service for the line as indicated by TLINE and TRDY.
To terminate transmission on a line, the program loads the last character normally and waits for the
scanner to request an additional character for the line. The program clears the line enable bit at this
time instead of loading the TBUF.

The normal rest condition of the transmitted data lead for any line is the one state. The break bits are
used to apply a continuous zero signal to the line. One bit in the TDR is associated with each line. The
line will remain in this condition as long as the bit remains set. The program should use a MOVB
instruction to access the BRK bits. If the program continues to load characters for a line after setting
the break bit, transmitter operation will appear normal to the program despite the fact that no characters can be transmitted while the line is in the continuous zero sending state. The program may use this
facility for sending precisely timed zero signals by setting the break bit and using transmit ready
|
interrupts as a timer.
It should be remembered that each line in the DZV11 is double buffered. The program must not set the
BRK bit too soon or the two data characters preceding the break may not be transmitted. The program must also ensure that the line returns to the one state at the end of the zero sending period before
transmitting any additional data characters. The following procedure will accomplish this. When the
scanner requests service the first time after the program has loaded the last data character, the program
should load an all-zero character. When the scanner requests service the second time, the program
should set the BRK bit for the line. At the end of the zero sending period, the program should load an
all-zero character to be transmitted. When the scanner requests service, indicating this character has
begun transmission, the program should clear the BRK bit and load the next data character.

4-5

4.4.8

Data Set Control

The program may sense the state of the carrier and ring indicator signals for each data set and may
control the state of the data terminal ready signal to each data set. The program uses two registers to
access the DZV11 data set control logic. There are no hardware interlocks between the data set control
logic and the receiver and transmitter logic. Any required coordination should be done under program
control.

The data terminal ready (DTR) bits in the TCR are read/write bits. Setting or clearing a bit in this
register will turn the appropriate DTR signal on or off. The program may access this register with
word or byte instructions. (If word instructions are used, the DTR and line enable bits will be simulta-

neously accessed.) The DTR bits are cleared by the INIT signal on the QBUS but is not cleared if the
program clears the DZV11 by setting the CLR bit of the CSR.
The carrier (CO) and ring (RI) bits in the MSR are read-only bits. The program can determine the
current state of the carrier signal for a line by examining the appropriate bit in the MSR. It can
determine the current state of the ring signal by examining the appropriate bit of the ring register. The
program can examine these registers separately by using MOVB or BITB instructions or can examine
them as a single 16-bit register by using MOV or BIT instructions. The DZV11 data set control logic
does not interrupt the LSI-11 processor when a carrier or ring signal changes state. The program
should periodically sample these registers to determine the current status. Sampling at a high rate is
not necessary.

APPENDIX A
GLOSSARY

BBS7 L - Bussed Bank 7 Select

BDALOO L through BDALI1S5 L - Bussed Data/Address Lines
BDIN L - Bussed Data Input

BDOUT L - Buésed Data Out
BIAKI L - Bussed Interrupt Acknowledge In

BIAKO L - Bussed Interrupt Acknowledge Out
BINIT L - Bussed Initialize
BIRQ L - Bussed Interrupt Request

Break - A continuous spacing condition on the serial data line, interpreted as a framing error.

BRK 3 through BRK 0 - TDR bits 11 through 08. When set, the Break bit causes the transmission of a
Break signal.

BRPLY L - Bussed Reply
BSYNC L - Bussed Sync

BWTBT L - Bussed Write Byte

with a signal.
Carrier - A carrier is a continuous frequency capable of being modulated or impressed
line signal detector
The name Carrier, however, is used in the DZV11 print set to refer to the received
input from the modem. This signal is referred to as *“Carrier Detect” and ‘““Carrier On”’ in some books.

CCITT - The Consultive Committee International Telegraph and Telephone is an advisory committee
established under the United Nations to recommend worldwide standards.

CHAR LGTH A, CHAR LGTH B - LPR bits 03 and 04. These bits determine the length of the
characters the DZV11 receives and transmits (Table 3-4).

CLR - CSR bit 04. Controls the device Master Clear signal (Table 3-2).

CO - Carrier On. Also referred to as “‘Carrier” or “Carrier Detect.” Some sources abbreviate Carrier
Detect to CD. Do not confuse CD or CO with EIA signal CD. EIA signal CD is Data Terminal

n Carrier On (or Carrier Detect) is CF.
for
Ready. The EIA signal designatio

A-1

CO3 through CO0- MSR bits 11 through 08, representing the Carrier signal for lines 03 through 00.
CONTROL STROBE H - This signal is generated by the speed and format control circuits on circuit
schematic sheet D8. It loads the speed parameters into the baud rate generators on sheet D8, and loads
the data format parameters into the UARTSs on sheets D13 and D14.
CSR - Control and Status Register (Table 3-2).
DAOO through DAO3 - Data Available. These signals come from the
(sheets D13 and D14).

R DONE pins on the UARTs

DATA IN 00 H through DATA IN 03 H - These signals are the received data from the EIA signal
lines. They originate at the EIA/TTL receivers (sheet D7) and go to the maintenance mode data
selector (sheet D10).

DATA TERM RDY 00 through DATA TERM RDY 03 - Data Terminal Ready signals for lines 00

through 03 (sheet D6).

Data Valid - Bit 15 in the RBUF. The Output Ready signals from the four silo memory chips are
ANDed to form RECEIVER DONE H. When the RBUF is addressed, RECEIVER DONE H is
latched as VALID DATA H (sheet D12). VALID DATA H becomes Data Valid (bit 15) in the

RBUF.

DATI - Data input bus cycle.
DATIO - Data input/output bus cycle.
DATIOB - Data input/output bus cycle involving a byte.

DATO - Data output bus cycle involving a word.
DATOB - Data output bus cycle involving a byte.
DCE - Data communication equipment.

DEVICE DATA BUS - The bidirectional tri-state bus internal to the module; signal lines DEVICE .
DATA BUS 00 through DEVICE DATA BUS 15.
DEVICE SELECT H - This signal is the wired-AND of the MATCH signals from all four bus transceiver chips (sheet D2). It enables the protocol chip (sheet D4).

DTE - Data terminal equipment.
DTR - Data Terminal Ready.
DTRO through DTR3 - Bits 08 through 11 in the transmitter control register. They represent the state
of Data Terminal Ready for each of the four lines.

EIA - Electronic Industries Association.
FB - Forced Busy.

FEQOO through FE 03 - Framing Error signals from the UARTSs (sheets D13 and D14).

A-2

FIFO - First-In/First-Out.

Forced Busy - Used with some modem equipment such as Bell models 103E and 113B. Signals a
modem controller to switch to another channel.
FRAM ERR - Framing Error; RBUF bit 13.
Framing Error - This error occurs when a UART receiver does not detect a stop bit at the time it tests
for one. This may be caused by a transmission error or by a Break signal.

INITIALIZE H, INITIALIZE L - These are the device initialization signals. They are generated by

either the CLR bit (CSR bit 04) or by BINIT from the LSI-11 bus (sheet DY).

LD BREAK REGISTER H - Load pulse for the high byte of the transmit data register. (sheets D4

and D10).

LD CSR HIGHBYTEH - Load pulse for the high byte of the control and status register (sheet D4).
LD CSR LOW BYTE H - Load pulse for the low byte of the control and status register (sheet D4).
LD LPR REGISTER L - Load pulse for the line parameter register (sheets D4 and D8).

LD TCR HIGH BYTE H-» Load pulse for the high byte of the transmit control register (sheet D4).
LD TCR LOW BYTE H - Load pulse for the low byte of the transmit control register (sheet D4).
LD TDR REGISTER H - Load pulse for the low byte of the transmit data register (sheet D4).
LINE A, LINE B - Bits 00 and 01 of the line parameter register. This is a 2-bit code that specifies the
number of the line to which the parameters apply.
LINE ENABO through LINE ENAB3 - Bits 00 through 03 in the transmit control register. Each of
these bits enables transmission on the corresponding line.

LOAD IN PROGRESS L - Indicates that either the line parameter register or the transmit data
register is being loaded. BRPLY is delayed 300 ns while a load is in progress for either of these two
registers (sheet D4).

LOAD SILO H - Enables silo buffers to load data (sheets D11 and D12).
LPR - Line parameter register. Refer to Table 3-4.

MAINT - Maintenance bit (CSR bit 03). Enables the internal loop-back maintenance mode.
MAINTENANCE H - This signal is set by the MAINT bit (sheet DS) and controls the maintenance
mode data selector (sheet D10).
MASTER CLEAR H - This signal is derived from the clear bit CLR (CSR bit 04). See sheet DS5.
MASTER SCAN CLOCK H - This signal is produced by dividing the master oscillator clock signal
(sheet D8). It drives the receiver scanner (sheet D11).

MASTER SCAN ENABLE H - Set by the MSE bit. Enables both transmitter and receiver control
circuitry (sheets D5, D9, DI11).

MASTER SCAN ENABLE L - Set by the MSE bit. Enables the master scan clock (sheets D5 and

D8).

| MSE - Master Scan Enable. CSR bit 05.
MSR - Modem Status Register. Refer to Paragraph 3.2.5.

ODD PAR - Odd Parity. Line parameter register bit 07. Refer to Table 3-4.

OR 00 through OR 03 - Overrun error signals from UARTS: (sheets D13 and D14) to silo buffer (sheet
D12).

OUT HB - Output high byte. Indicates that an output data transfer will be made to the high byte of

the selected register (sheet D4).

OUT LB - Output low byte. Indicates that an output data transfer will be made to the low byte of the

selected register (sheet D4).

OVRN ERR - Overrun Error. RBUF bit 14. Refer to Table 3-3.
PAR ENAB - Parity Enable. Line parameter register bit 06. Refer to Table 3-4.
PAR ERR - Parity Error. RBUF bit 12. Refer to Table 3-3.

PE 00 through PE 03 - Parity error signals from the UARTS (sheets D13 and D 14) to silo the buffer

(sheet 12).

PSW - Processor Status Word.

QBUS - LSI-11 Bus.
RBUF - Receiver Buffer. Refer to Table 3-3.

RBUF DO through RBUF D7 - Received data bits. RBUF bits 0 through 7.

RCV CLOCK 00 H through RCV CLOCK 03 H - Receiver clocks from the baud rate generators

(sheet D8) to the UARTS (sheets D13 and D14).

RCV DATA 00 through RCV DATA 03 - Received data bits from the silo buffer (sheet D12) to the

multiplexers (sheet D3).

RCV DATA ENABLE 00 through RCV DATA ENABLE 03 - These signals enable the UARTSs for
the selected lines. They originate in the receiver control circuitry (sheet D11) and go to the UARTSs

(sheets D13 and D14).

RD1 through RD8 - Received data bits from the UARTSs (sheets D13 and D14) to the silo buffer

(sheet D12).

RDONE - Receiver Done. CSR bit 07. Refer to Table 3-2.

READ DEVICE H and READ L - These signals control the operating mode of the bus transceivers

(sheets D2 and D4).

READ RCV BUFFER H - This signal controls the unloading of the silo buffer (sheets D4 and D12).

A-4

of
RECEIVER DONE H - In the DZV11, this signal does not come from the UARTSs. It is theIt result
the
sets
12).
(sheet
chips
memory
FIFO
four
the
of
anding the Output Ready signals from each
RDONE bit in the CSR (sheet D3) to indicate that a character of received data is ready in the silo
buffer.

RECEIVER INTR ENABL - Receiver Interrupt Enable (sheet D5).

RESET DAOQO through DAO3 - These signals are made up in the receiver control circuitry (sheet D11)
to reset the Data Available signals in the UART (sheets D13 and D14) for the selected line.
RI - Ring Indicator.

RI0 through RI3 - Modem status register bits 0 through 3, indicating the states of the Ring signal on
the corresponding lines.

RIE - Receiver Interrupt Enable. CSR bit 06. Refer to Table 3-2.

RING 00 through RING 03 - The Ring Indicator signals for lines 0 through 3, after having been

converted from EIA to TTL levels (sheet D7).
RO - Read-Only.

RTS - Request to Send.
RW - Read/Write.

RX ENAB - Recéivcr Enable. Line parameter register bit 12. Refer to Table 3-4.
RX LINE A, RX LINE B.- Receiver Line A and B, respectively. RBUF bits 08 and 09. Refer to Table

3-3.

SA - Silo Alarm. CSR bit 13. Refer to Table 3-2.

SAE - Silo Alarm Enable. CSR bit 12. Refer to Table 3-2.
SEL 0 - Select line for device register 0 (the CSR). See sheet D4.

SEL 2 - Select line for device register 2. For an input (read) operation, this is the RBUF. For an output

(write) operation, this is the LPR. See sheet D4.

SEL 4 - Select line for device register 4 (the TCR). See sheet D4.

SEL 6 - Select line for device register 6. For an input (read) operation, this is the MSR. For an output

(write) operation, this is the TDR. See sheet D4.

SERIAL INOO H through SERIAL INO3 H - Serial input data from each of the four lines. It is called
Data In between the receivers (sheet D7) and the maintenance mode data selector (sheet D10). From
there to the UARTS (sheets D13 and D14), it is called Serial In.

SERIAL OUTO00 through SERIAL OUTO3 - Serial data out of the UARTSs (sheets D13 and D14). It

goes to the EIA drivers and the maintenance mode data selector (sheet D10).

SILO - This term refers to a buffer that automatically shifts data from its input end to its output end.
When a silo is loaded, the data does not queue up from the input end toward the output end, asin a
shift register. Instead, it stacks up at the output end, and is immediately available for unloading.
A-5

SILO ALARM H - This signal is the output of a latch that is set when 16 characters have entered the
silo (sheet D11). It is cleared by either reading the RBUF or clearing the Silo Alarm Enable bit in the
CSR.

SILO LOAD REQUEST H - This signal is asserted when the Data Available signal for the selected
line is set and the In Ready signals from the silo buffer chips are set. See sheet D12.
SPEED CODE A through SPEED CODE D - Bits 08 through 11 of the line parameter register. Refer
to Table 3-4.

STOP CODE - Bit 05 of the line parameter register. Refer to Table 3-4.
TBMT - Transmitter Buffer Empty.
TBMTO0 through TMBTO3 - These are Transmitter Ready signals from the UARTS (sheets D13 and
D14) to the transmitter control circuitry (sheet D9).
|

TBUFO through TBUF7 - Transmit data bits; bits 0 through 7 of the TDR.

TCR - Transmitter control register. Refer to Paragraph 3.2.4.
TDR - Transmit data register. Refer to Paragraph 3.2.6.
THRLOO L through THRLO3 L - Transmitter Holding Register Load signal for lines 0 through 3.
From the transmitter control circuitry (sheet D9) to the UARTS (sheets 13 and 14).

TIE - Transmitter Interrupt Enable. CSR bit 14. Refer to Table 3-2.
TLINE A, TLINE B - CSR bits 08 and 09. Indicate which line is selected for transmission. Refer to
- Table 3-2. .
|
TRAN INTR ENBL H - Transmitter Interrupt Enable signal (sheet D5).
TRANSMITTER READY H - This signal indicates that a line has been selected and that the corresponding UART transmitter is ready to be loaded.

TRDY - Transmitter Ready. CSR bit 15. Refer to Table 3-2.

TTL - Transistor-Transistor Logic. The normal logic levels are approximately 4 V for one state and 0
V for the other.

TX CLOCK 00 H through TX CLOCK 03 H - Transmitter clocks for lines 0 through 3. They come
from the baud rate generators (sheet D8) and go to the UARTS (sheets D13 and D14).

UART - Universal Asynchronous Receiver/Transmitter. Refer to Appendix A.

UNLOAD SILO H - The unload signal to the Shift Out pin on the silo buffer memory Chips.,
VECTOR BIT 02 - Bit 02 of the vector term. This determines whether the computer uses a receiver
interrupt service routine or a transmitter interrupt service routine. See sheets DS and D2.

VECTOR-TO-BUS H - This signal asserts the vector selected by the switch pack at E2 (sheet DS). It
also goes to the protocol chip (sheet D4) to cause assertion of BRPLY.
XMIT DATA 00 through XMIT DATA 03 - Transmitted data leaving the EIA drivers.

A-6

DZV11 ASYNCHRONOUS MULTIPLEXER

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