home
***
CD-ROM
|
disk
|
FTP
|
other
***
search
/
InfoMagic Standards 1994 January
/
InfoMagic Standards - January 1994.iso
/
ccitt
/
1992
/
v
/
v17.asc
next >
Wrap
Text File
|
1991-12-31
|
24KB
|
775 lines
IMPORT
R:\\ART\\W INTERNATIONAL TELECOMMUNICATION UNION
MF\\ITU.WM
F \*
mergeforma
t
CCITT V.17
THE INTERNATIONAL
TELEGRAPH AND TELEPHONE
CONSULTATIVE COMMITTEE
DATA COMMUNICATION
OVER THE TELEPHONE NETWORK
A 2-WIRE MODEM FOR FACSIMILE
APPLICATIONS WITH RATES UP
TO 14 400 bit/s
Recommendation V.17
IMPORT Geneva, 1991
R:\\ART\\
WMF\\CCIT
TRUF.WMF
\*
mergeform
at
Printed in Switzerland
FOREWORD
The CCITT (the International Telegraph and Telephone Consultative
Committee) is a permanent organ of the International Telecommunication Union
(ITU). CCITT is responsible for studying technical, operating and tariff
questions and issuing Recommendations on them with a view to standardizing
telecommunications on a worldwide basis.
The Plenary Assembly of CCITT which meets every four years, establishes
the topics for study and approves Recommendations prepared by its Study Groups.
The approval of Recommendations by the members of CCITT between Plenary
Assemblies is covered by the procedure laid down in CCITT Resolution No. 2
(Melbourne, 1988).
Recommendation V.17 was prepared by Study Group XVII and was approved
under the Resolution No. 2 procedure on the 22 of February 1991.
___________________
CCITT NOTE
In this Recommendation, the expression "Administration" is used for
conciseness to indicate both a telecommunication Administration and a recognized
private operating agency.
F ITU 1991
All rights reserved. No part of this publication may 0 be reproduced or utilized
in any form or by any means, electronic or mechanical, including photocopying and
microfilm, without permission in writing from the ITU.
PAGE BLANCHE
Recommendation V.17
Recommendation V.17
A 2 -WIRE MODEM FOR FACSIMILE APPLICATIONS WITH
RATES UP TO 14 400 bit/s
1 Introduction
This Recommendation defines the modulation methods and operating sequences
for a modem intended only for use in high speed facsimile applications.
Appropriate T-Series Recommendations should be consulted regarding
operating procedures and other features employed in facsimile transmission
applications, as these differ from those recommended for high speed modems for
general applications.
The modem has the following principal characteristics:
a) Provision for half duplex operation at data signalling rates of:
ù 14 400 bit/s synchronous,
ù 12 000 bit/s synchronous,
ù 9600 bit/s synchronous,
ù 7200 bit/s synchronous;
b) Quadrature amplitude modulation with synchronous line transmission at
2400 symbols per second.
c) Inclusion of data scramblers, adaptive equalizers and eight-state
trellis coding.
d) Two sequences for training and synchronization: long train and resync.
2 Line signals
2.1 Carrier frequency
The channel carrier frequency is 1800 ▒ 1 Hz. The receiver must be able to
operate with received frequency offsets of up to ▒ 7 Hz.
2.2 Modulation
The modulation rate shall be 2400 ▒ 0.01% symbols per second.
2.3 Signal element codings
2.3.1 Signal element codings for 14 400 bit/s
The scrambled data stream to be transmitted is divided into groups of six
consecutive data bits, which are ordered according to their time of occurrence.
As shown in Figure 1/V.17, the first two bits in each group, Q1n and Q2n (where n
designates the sequence number of the group) are first differentially encoded
into Y1n and Y2n according to Table 1/V.17.
styleref head_footRecommendation V.17PAGE
11
Figure 1/V.17 = 13.5 cm
include 17-t01-eTABLE 1/V.17
Differential coding for use with trellis coding
Input Previous Outputs
outputs
Q1n Q2n Y1nù1 Y2nù1 Y1n Y2n
0 0 0 0 0 0
0 0 0 1 0 1
0 0 1 0 1 0
0 0 1 1 1 1
0 1 0 0 0 1
0 1 0 1 0 0
0 1 1 0 1 1
0 1 1 1 1 0
1 0 0 0 1 0
1 0 0 1 1 1
1 0 1 0 0 1
1 0 1 1 0 0
1 1 0 0 1 1
1 1 0 1 1 0
1 1 1 0 0 0
1 1 1 1 0 1
The two differentially encoded bits Y1n and Y2n are used as inputs to a
systematic convolutional encoder which generates a redundant bit Y0n. This
redundant bit and the six information-carrying bits Y1n, Y2n, Q3n, Q4 , Q5n and
Q6n are then mapped into the coordinates of the signal element to be transmitted
according to the signal space diagram shown in Figure 2/V.17.
Figure 2/V.17 = 21 cm
2.3.2 Signal element codings for 12 000 bit/s
The scrambled data stream to be transmitted is divided into groups of five
consecutive data bits, which are ordered according to their time of occurrence.
As shown in Figure 1/V.17, the first two bits in each group, Q1n and Q2n (where n
designates the sequence number of the group) are first differentially encoded
into Y1n and Y2n according to Table 1/V.17.
The two differentially encoded bits Y1n and Y2n are used as inputs to a
systematic convolutional encoder which generates a redundant bit Y0n. This
redundant bit and the five information-carrying bits Y1n, Y2n, Q3n, Q n and Q5n
are then mapped into the coordinates of the signal element to be transmitted
according to the signal space diagram shown in Figure 3/V.17.
Figure 3/V.17 = 18.5 cm
2.3.3 Signal element codings for 9600 bit/s
The scrambled data stream to be transmitted is divided into groups of four
consecutive data bits, which are ordered according to their time of occurrence.
As shown in Figure 1/V.17, the first two bits in each group, Q1n and Q2n (where n
designates the sequence number of the group) are first differentially encoded
into Y1n and Y2n according to Table 1/V.17.
The two differentially encoded bits Y1n and Y2n are used as inputs to a
systematic convolutional encoder which generates a redundant bit Y0n. This
redundant bit and the four information-carrying bits Y1n, Y2n, Q3n and Q4n are
then mapped into the coordinates of the signal element to be transmitted,
according to the signal space diagram shown in Figure 4/V.17.
Figure 4/V.17 = 13 cm
2.3.4 Signal element codings for 7200 bit/s
The scrambled data stream to be transmitted is divided into groups of
three consecutive data bits, which are ordered according to their time of
occurrence. As shown in Figure 1/V.17, the first two bits in each group, Q1n and
Q2n (where n designates the sequence number of the group) are first
differentially encoded into Y1n and Y2n according to Table 1/V.17.
PAGE10 styleref head_footRecommendation V.17
The two differentially encoded bits Y1n and Y2n are used as inputs to a
systematic convolutional encoder which generates a redundant bit Y0n. This
redundant bit and the three information-carrying bits Y1n, Y2n and Q3n are then
mapped into the coordinates of the signal element to be transmitted according to
the signal space diagram shown in Figure 5/V.17.
Figure 5/V.17 = 11 cm
2.4 Transmitted spectra
With continuous binary ONEs applied to the input of the scrambler, the
transmitted energy density at 600 Hz and 3000 Hz should be attenuated by
4.5 ▒ 2.5 dB with respect to the maximum energy density between 600 Hz and
3000 Hz.
3 Interchange circuits
3.1 List of interchange circuits
References in the Recommendation to V.24 interchange circuit numbers are
intended to refer to the functional equivalent of such circuits and are not
intended to imply the physical implementation of such circuits. For example,
references to circuit 103 should be understood to refer to the functional
equivalent of circuit 103 (see Table 2/V.17).
include 17-t02-eTABLE 2/V.17
Interchange circuits
Number Description
102 Signal ground or common return
103 Transmitted data
104 Received data
105 Request to send
106 Ready for sending
107 Data set ready
108/1 Connect data set to line (Note)
or Data terminal ready (Note)
108/2 Data channel received line signal detector
109 Transmitter signal element timing (DCE source)
114 Receiver signal element timing (DCE source)
115 Calling indicator
125
Note ù This circuit shall be capable of operating as circuit
108/1 or circuit 108/2.
3.2 Transmit data
The modem shall accept data from the facsimile control function on circuit
103; the data on circuit 103 shall be under the control of circuit 114.
3.3 Receive data
The modem shall pass data to the facsimile control function on
circuit 104; data on circuit 104 shall be under the control of circuit 115.
3.4 Timing arrangements
Clocks shall be included in the modem to provide the facsimile control
function with transmitter element timing on circuit 114 and receiver signal
element timing on circuit 115.
3.5 Data rate control
This shall be provided by a connection between the modem and the facsimile
control function; the nature of this connection is beyond the scope of this
Recommendation.
3.6 Circuits 106 and 109 response times
After the training and synchronizing sequences defined in S 5, circuit 106
shall follow OFF to ON or ON to OFF transitions of circuit 105 within 3.5 ms. The
OFF to ON transition of circuit 109 is part of the training sequence specified in
S 5. Circuit 109 shall turn OFF 30 to 50 ms after the level of the received
signal appearing at the line terminal of the modem falls below the relevant
threshold defined in S 3.7. Following a dropout, after the initial handshake,
circuit 109 shall turn ON 40 to 205 ms after the level of the received signal
appearing at the line terminal of the modem exceeds the relevant threshold
defined in S 3.7.
3.7 Circuit 109 threshold
> ù43 dBm ON.
> ù48 dBm OFF.
The condition of circuit 109 between the ON and OFF levels is not
specified except that the signal detector shall exhibit a hysteresis action, such
that the level at which the OFF to ON transition occurs shall be at least 2 dB
styleref head_footRecommendation V.17PAGE
11
greater than that for the ON to OFF transition.
Circuit 109 thresholds are specified at the input to the modem when
receiving scrambled binary ONEs.
Administrations are permitted to change these thresholds where
transmission conditions are known.
Note ù Circuit 109 ON to OFF response time should be suitably chosen
within the specified limits to ensure that all valid data bits have appeared on
circuit 104.
3.8 Clamping
The DCE shall hold, where implemented, circuit 104 in the binary ONE
condition and circuit 109 in the OFF condition when circuit 105 is in the ON
condition and, where required to protect circuit 104 from false signals, for a
period of 150 ▒ 25 ms following the ON to OFF transition on circuit 105. The use
of this additional delay is optional, based on system considerations.
4 Scrambler and descrambler
The modem shall use a self-synchronizing scrambler/descrambler with the
generator polynomial:
eq 1 + xù18 + xù23
At the transmitter, the scrambler shall effectively divide the message
data sequence by the generating polynomial. The coefficients of the quotient of
this division, taken in descending order, form the data sequence which shall
appear at the output of the scrambler. At the receiver, the received data
sequence shall be multiplied by the scrambler generating polynomial to recover
the message sequence.
5 Operating sequences
5.1 Training and synchronizing sequences
Two separate sequences of training and synchronizing signals are defined
in Table 3/V.17.
The long train sequence is for initial establishment of a connection or
for retraining when needed.
The resync. sequence is for resynchronization after a successful long
train.
include 17-t03-eTABLE 3/V.17
Training and synchronizing signals
Segment 1 Segment 2 Segment Segment
3 4
ABAB Equalizer Bridge Scramble Total Approxima
alternation training signal d ONEs symbol te time
s signal interval (ms)
Long train 256 2976 64 48 3344 1393
Resync. 256 2938 64
PAGE10 styleref head_footRecommendation V.17
48 3342 1142
styleref head_footRecommendation V.17PAGE
11
5.1.1 Segment 1: ABAB alternations
This segment consists of alternations between states A and B as shown in
Figures 2/V.17 to 5/V.17.
5.1.2 Segment 2: equalizer training signal
This segment consists of the sequential transmission of four signal
elements A, B, C, and D as shown in Figures 2/V.17 to 5/V.17.
The equalizer conditioning pattern is a pseudo-random sequence at 4800
bit/s generated by the
1 + xù18 + xù23 data scramble . During segment 2, any differential quadrant
encoding is disabled and the scrambled dibits are encoded as shown in
Table 4/V.17.
With a binary ONE applied to the input, the initial scrambler state shall
be selected to produce the following scrambler output pattern and corresponding
signal elements:
include 17-t04-eTABLE 4/V.17
Encoding for four phase training signal
00 01 00 01 00 01 00 01 00 01 00 01 1001
C D C D C D C D C D C D BD
10 01
B D
Segment 2
Dibit Signal
state
00 C
01 D
11 A
10 B
5.1.3 Segment 3: bridge signal
This segment, which is used only during an initial long train, consists of
a 16-bit binary sequence transmitted eight times. The sequence as defined in
Table 5/V.17 is scrambled, and transmitted at 4800 bit/s using the signal
elements A, B, C, and D as defined in Figures 2/V.17 to 5/V.17.
include 17-t05-eTABLE 5/V.17
Segment 3: Bit designations
B B B B B
PAGE10 styleref head_footRecommendation V.17
B B B B B B B BB
B B
0 1 2 3 4 5 6 7 8 9 1 1 121
0 1
1 15
4
0 0 0 0 0 0
styleref head_footRecommendation V.17PAGE
11
0 1 0 0 0 1 00
0 1
Note 1 ù The B0 bit is the first bit in the data stream as
it enters the scambler.
Note 2 ù Any use of bits 4-6, 8-10, 12-14 would be for
further study. Some existing equipment may set one or more
of these bits to binary ONE; such bits shall be ignored.
The dibits are differentially encoded as defined in Table 6/V.17.
The differential encoder shall be initialized using the final symbol of
the previous segment. The first two bits and subsequent dibits of each 16-bit
sequence shall be encoded as one signal state.
include 17-t06-eTABLE 6/V.17
Segment 3: Dibit encoding
Dibit Phase change Previous output/output
00 + 90 degrees A/B, B/C, C/D, D/A
01 0 degrees A/A, B/B, C/C, D/D
10 180 degrees A/C, B/D, C/A, D/B
11 ù 90 degrees A/D, B/A, C/B, D/C
5.1.4 Segment 4
Scrambled binary ONEs shall be sent at the channel data bit rate.
For the long train sequence, the differential encoder shall be initialized
using the first symbol of segment 3.
For the short train sequence, the differential encoder shall be
initialized using the last symbol of segment 2.
The convolutional encoder initial state shall be initialized to zero.
PAGE10 styleref head_footRecommendation V.17
The scrambler shall be clocked at the bit rate and the scrambler output
sequence encoded as defined in S 4. The initial scrambler state is that state
produced by the last symbol interval of the previous segment.
The duration of segment 4 is 48 symbol intervals. At the end of segment 4,
circuit 106 is turned ON and data are applied to the input of the data scrambler.
Circuit 109 shall be turned ON during the reception of segment 4.
5.2 Turn OFF sequence
After an ON to OFF transition of circuit 105, the line signals emitted
after remaining data or the end of the training check signal during retrain
procedure have been transmitted are shown in Table 7/V.17.
include 17-t07-eTABLE 7/V.17
Turn OFF sequence
Segment A Segment B
Continuous No Total of Approximate
scrambled transmitted segments time
ONEs energy
32 SI 48 SI 80 SI 33 ms
SI denotes Symbol intervals
Note ù If an OFF to ON transition of circuit 105 occurs
during the turn OFF sequence, it will not be taken into
account until the end of the turn OFF sequence.
5.3 Talker echo protection (TEP) signal
A TEP signal may, optionally, be transmitted prior to the transmission of
training and synchronization sequences. The TEP signal shall consist of an
unmodulated carrier for a duration of 185 to 200 ms followed by a silent period
of 20 to 25 ms.
When used, the TEP signal shall be considered as part of the training
sequences.
Alternative methods for achieving the intended benefits of a TEP signal
are for further study.
styleref head_footRecommendation V.17PAGE
11
