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InfoMagic Standards 1994 January
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1988
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.rs
.\" Troff code generated by TPS Convert from ITU Original Files
.\" Not Copyright ( c) 1991
.\"
.\" Assumes tbl, eqn, MS macros, and lots of luck.
.TA 1c 2c 3c 4c 5c 6c 7c 8c
.ds CH
.ds CF
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.EN
.nr LL 40.5P
.nr ll 40.5P
.nr HM 3P
.nr FM 6P
.nr PO 4P
.nr PD 9p
.po 4P
.rs
\v | 5i'
.LP
\fBMONTAGE: FIN DE LA RECOMMANDATION O.22 EN\(hyT\* | TE DE CETTE PAGE\fR
.sp 2P
.LP
\v'38P'
\fBRecommendation\ O.25\fR
.RT
.sp 2P
.sp 1P
.ce 1000
\fBSEMIAUTOMATIC |
\fBIN\(hyCIRCUIT\ ECHO\ SUPPRESSOR\ TESTING\ SYSTEM\ (ESTS)\fR
.EF '% Fascicle\ IV.4\ \(em\ Rec.\ O.25''
.OF '''Fascicle\ IV.4\ \(em\ Rec.\ O.25 %'
.ce 0
.sp 1P
.ce 1000
\fI(Geneva, 1976; amended Melbourne, 1988)\fR
.sp 9p
.RT
.ce 0
.sp 1P
.LP
\fB1\fR \fBGeneral\fR
.sp 1P
.RT
.PP
The CCITT semiautomatic \fIin\(hycircuit\fR echo suppressor testing
system is intended to test the sensitivity\(hyrelated operational
characteristics of echo suppressors assigned to all categories of international
circuits.
.PP
The ESTS is suitable for testing
echo suppressors
complying
with Recommendation\ G.161\ [1] of the \fIOrange Book\fR . It may also be found
suitable
for certain applications on circuits employing echo suppressors complying
with Recommendation\ G.164\ [2].
.bp
.PP
The ESTS will consist of two parts: a)
\fIdirecting equipment\fR at the outgoing end and b)
\fIresponding equipment\fR at the incoming end. The directing equipment
will be manually connected to the circuit under test
after a connection has been established to a responder at the incoming
end. The responding equipment will be accessed via a test call over the
circuit under
test.
.PP
In order to simplify the test equipment design and its operation,
quantitative measurement results will not be given. The two\(hyway circuit
loss, noise and the echo suppressor tests will be made and reported on
a
\fIpass\fR /\fIfail\fR basis. The test results shall be indicated only
at the outgoing end by the directing equipment. The Administrations in
charge of the incoming end need not be notified of the test results except
as required to eliminate a deficiency evidenced by the test results.
.PP
The ESTS shall be capable of testing a full echo suppressor located at
either the outgoing or incoming end as well as both echo suppressors when
split echo suppressors are used. This equipment can be used on any circuit
routed
completely on terrestrial facilities, or any circuit routed on terrestrial
facilities and not more than one
satellite link
.
.PP
This equipment will not provide reliable test results for a circuit
which is routed through a circuit multiplication system (CMS) employing
interpolation techniques [this includes the case where a circuit is routed
over time division multiple access/digital speech interpolation (TDMA/DSI)
satellite channels], and therefore should not be used in this instance
unless a permanent trunk\(hychannel association in both directions of transmission
can be made for the duration of the test sequence. The reason for this
is that without such a trunk\(hychannel association, circuit continuity
may not be maintained
within the CMS in the absence of a signal and during very low signal level
conditions.
.RT
.sp 2P
.LP
\fB2\fR \fBKinds of tests\fR
.sp 1P
.RT
.PP
A loss test will be made in both directions of transmission to
ensure that the circuit loss is within \(+- | .5\ dB of nominal value.
.PP
A noise test will be made in both directions of transmission to
determine if the circuit noise exceeds \(em40\ dBm0p and is therefore likely to
interfere with echo suppressor measurements.
.PP
The suppression and break\(hyin sensitivities of the echo suppressor(s)
are tested to ensure that they are within established limits.
.RT
.sp 2P
.LP
\fB3\fR \fBMethod of access\fR
.sp 1P
.RT
.sp 1P
.LP
3.1
\fIOutgoing international exchange\fR
.sp 9p
.RT
.PP
Access to the circuit under test at the outgoing international
exchange will be on a 4\(hywire basis on the exchange side of the near\(hyend
echo
suppressor.
.PP
The attachment of the directing equipment to the circuit under test
will be done on a manual basis, such as at a testboard.
.RT
.sp 1P
.LP
3.2
\fIIncoming international exchange\fR
.sp 9p
.RT
.PP
Access to the responding equipment, by the circuit under test, at the incoming
international exchange will be gained via the normal exchange
switching equipment on a 4\(hywire basis.
.RT
.sp 1P
.LP
3.3
\fIAddress information\fR
.sp 9p
.RT
.PP
The address information to be used to gain access to the responding equipment
at the incoming international exchange is specified in
Recommendation\ O.11, \(sc\ 2.4.
.RT
.LP
.sp 2P
.LP
\fB4\fR \fBOperating principles\fR
.sp 1P
.RT
.PP
4.1
After a switched connection has been established at the
incoming end between the circuit under test and the responding equipment,
the directing equipment is attached to the circuit at the outgoing end.
It shall
then be possible to make any number of circuit loss, circuit noise
and echo suppressor tests without releasing the connection.
.bp
.sp 9p
.RT
.PP
4.2
The tests shall be manually initiated at the outgoing end,
which can either be accomplished on a test\(hyby\(hytest basis or the full
overall
test sequence can be programmed and initiated by a single control.
.PP
4.3
A fail or pass indication for each test shall be provided
to the outgoing end. In order to avoid possible ambiguities in the
interpretation of the test results, all suppressor tests [i.e. tests e)
to l) in \(sc\ 5.3.3\ below] should be made during any test sequence.
.PP
4.4
The echo suppressor tests should be made only after the two\(hyway
loss tests are completed satisfactorily. A programmed test sequence should
not continue beyond a failed loss test.
.LP
\fB5\fR \fBTesting procedure\fR
.sp 1P
.RT
.sp 2P
.LP
5.1
\fIEstablishment of connection\fR
.sp 1P
.RT
.PP
5.1.1
When the outgoing circuit is seized, the appropriate address
information is transmitted (see \(sc\ 3.3\ above).
.sp 9p
.RT
.PP
5.1.2
When the access is gained to the responding equipment, the answer signal
will be transmitted. If the responding equipment is occupied, a
busy indication will be returned to the outgoing end in accordance with
normal signalling arrangements for the circuit.
.PP
5.1.3
Upon receipt of the answer signal the directing equipment is
manually attached to the circuit under test and the tests initiated as
described in \(sc\ 5.2\ below.
.PP
5.1.4
The responding equipment will transmit a high level monitor tone at the
time of access. This can be monitored at the outgoing end to assure that
the responding equipment has been accessed and activated.
.PP
5.1.5
When the tests are completed the attachment of the directing
equipment to the circuit under test is removed and the circuit is immediately
released.
.LP
.PP
5.1.6
The responding equipment shall automatically time out and initiate a clear
back if it has been accessed continuously for more than 15\ minutes.
.sp 2P
.LP
5.2
\fITest initialization\fR
.sp 1P
.RT
.PP
5.2.1
Each test is initiated by the sending of an associated
multi\(hyfrequency command signal from the directing to the responding
equipment. Before sending a multi\(hyfrequency command signal, the directing
equipment shall assume a quiescent state so as to avoid interference with
the proper
detection of the command signal by the responding equipment.
.sp 9p
.RT
.PP
5.2.2
Upon the detection of a valid multi\(hyfrequency (MF) command
signal at any time, the responding equipment shall be returned to its quiescent
state. Immediately after the cessation of the command signal the responding
equipment will send a 610\(hyHz acknowledgement signal for a period of
500\ \(+-\ 25\ ms. The responding equipment will also begin sending a monitor
tone
and other test tones as required for the tests described below. The responding
equipment shall time out and return to its quiescent state 10\ seconds
after the cessation of an MF command signal.
.LP
.PP
5.2.3
After sending an MF command signal the directing equipment shall be conditioned
to detect the receipt of the acknowledgement signal for an
interval of time up to 1400\ ms. If acknowledgement is not received by the
directing equipment during this interval a failure shall be indicated and
the test should not proceed any further.
.PP
5.2.4
600\ \(+-\ 30 ms after the cessation of the acknowledgement signal the
directing equipment shall begin sending test and/or monitor tones for the
various tests as described below.
.sp 2P
.LP
5.3
\fITest description\fR
.sp 1P
.RT
.PP
5.3.1
Tone detection will be made by the directing equipment for the purpose
of determining whether a test passed or failed during a 375\ \(+-\ 25\
ms
test interval. This interval will begin 1000\ \(+-\ 50\ ms after the directing
equipment begins sending test and/or monitor tones. This delay is required
to permit the exchange of test and monitor tones on circuits with long
delay (one satellite and long terrestrial facilities).
.bp
.sp 9p
.RT
.LP
.PP
5.3.2
The responding equipment shall be designed to send a monitor tone whenever
it is not receiving a monitor tone from the directing equipment,
except during the near\(hyto\(hyfar loss and noise tests. For the near\(hyto\(hyfar
loss
and noise tests the responding equipment shall stop sending a monitor tone
to indicate to the directing equipment a test failure condition.
.PP
5.3.3
Under the control of the directing equipment the ESTS will be
capable of making 12 tests from the near end.
.LP
a)
near\(hyto\(hyfar loss,
.LP
b)
far\(hyto\(hynear loss,
.LP
c)
near\(hyto\(hyfar noise,
.LP
d)
far\(hyto\(hynear noise,
.LP
e)
near\(hyend suppressor non\(hyoperate,
.LP
f
)
near\(hyend suppressor operate,
.LP
g)
near\(hyend break\(hyin non\(hyoperate,
.LP
h)
near\(hyend break\(hyin operate,
.LP
i)
far\(hyend suppressor non\(hyoperate,
.LP
j)
far\(hyend suppressor operate,
.LP
k)
far\(hyend break\(hyin non\(hyoperate,
.LP
l)
far\(hyend break\(hyin operate.
.PP
5.3.4
These tests are described below. The descriptions begin at the
cessation of the acknowledgement signal as referred to in \(sc\ 5.2.4\
above. For
all tests the responding equipment has started sending monitor and any
required test tones as noted in \(sc\ 5.2.2\ above.
.sp 1P
.LP
5.3.5
\fINear\(hyto\(hyfar loss test\fR
.sp 9p
.RT
.PP
The responding equipment is silent. The directing equipment sends a \(em10\
dBm0 test tone at 820\ Hz for 100\ \(+-\ 10\ ms. If the test tone is within
\(+- | .5\ dB of \(em10\ dBm0 as measured at the far end, the responding
equipment will send high level monitor tone. The detection of monitor tone
by the directing
equipment during the test interval will indicate that the test has passed.
.RT
.sp 1P
.LP
5.3.6
\fIFar\(hyto\(hynear loss test\fR
.sp 9p
.RT
.PP
The responding equipment is sending a \(em10\ dBm0 test tone at
1020\ Hz. The directing equipment measures the test tone during the test
interval. If the test tone is within \(+- | .5\ dB of \(em10\ dBm0, the
test has
passed.
.RT
.LP
.sp 1P
.LP
5.3.7
\fINear\(hyto\(hyfar noise test\fR
.sp 9p
.RT
.PP
The responding equipment is silent. The directing equipment
terminates the transmit path in 600\ ohms. Six hundred milliseconds after
transmitting the acknowledgement signal, the responding equipment measures
the noise during the following 375\ \(+-\ 25\ milliseconds. If the noise
is below
\(em40\ dBm0p, the responding equipment will send a high level monitor
tone. The
detection of this monitor tone by the directing equipment during the test
interval will indicate that the test has passed.
.RT
.sp 1P
.LP
5.3.8
\fIFar\(hyto\(hynear noise test\fR
.sp 9p
.RT
.PP
The responding equipment terminates its transmit path in 600 ohms. The
directing equipment measures the noise during the test interval and if
the noise is below \(em40\ dBm0p the test has passed.
.RT
.sp 1P
.LP
5.3.9
\fINear\(hyend suppressor non\(hyoperate test\fR
.sp 9p
.RT
.PP
The responding equipment is sending a monitor tone and a \(em40\ dBm0 test
tone at 1020\ Hz. The directing equipment starts sending a monitor tone.
Upon detection of the monitor tone from the directing equipment, the
responding equipment stops sending its monitor tone. The absence of the
monitor tone received from the responding equipment during the test interval
indicates to the directing equipment that the near\(hyend suppressor has not
operated and that the test has passed.
.bp
.RT
.LP
.sp 1P
.LP
5.3.10
\fINear\(hyend suppressor operate test\fR
.sp 9p
.RT
.PP
The responding equipment is sending a monitor tone and a \(em26\ dBm0 test
tone at 1020\ Hz. The directing equipment starts sending a monitor tone.
If the near\(hyend suppressor has operated, the monitor tone from the directing
equipment will not reach the responding equipment. The responding equipment
will therefore continue sending a monitor tone and the detection of this
monitor tone by the directing equipment during the test interval will indicate
that the test has passed.
.RT
.sp 1P
.LP
5.3.11
\fINear\(hyend break\(hyin non\(hyoperate test\fR
.sp 9p
.RT
.PP
The responding equipment is sending a monitor tone and a \(em15\ dBm0 test
tone at 1020\ Hz. After the detection of the 1020\(hyHz test tone sent
out by the responding equipment, the directing equipment starts sending
a high level monitor tone and a \(em20\ dBm0 test tone at 820\ Hz. If break\(hyin
does not occur at the near\(hyend suppressor, the monitor tone from the
directing equipment will not reach the responding equipment. The responding
equipment will therefore
continue sending a monitor tone and the detection of this monitor tone
by the direction equipment during the test interval will indicate that
the test has
passed.
.RT
.LP
.sp 1P
.LP
5.3.12
\fINear\(hyend break\(hyin operate test\fR
.sp 9p
.RT
.PP
The responding equipment is sending a monitor tone and a \(em15\ dBm0 test
tone at 1020\ Hz. After the detection of the 1020\(hyHz test tone sent
out by the responding equipment the directing equipment starts sending
a high\(hylevel
monitor tone [see \(sc\ 6.1.2\ c) below] and a \(em10\ dBm0 test tone at
820\ Hz. If
break\(hyin does occur at the near\(hyend suppressor, the monitor tone from the
directing equipment will reach the responding equipment. The responding
equipment, upon detection of the monitor tone from the directing equipment,
will stop sending its monitor tone and this absence of monitor tone during
the test interval will indicate to the directing equipment that the test
has
passed.
.RT
.sp 1P
.LP
5.3.13
\fIFar\(hyend suppressor non\(hyoperate test\fR
.sp 9p
.RT
.PP
The responding equipment is sending a monitor tone. The directing equipment
starts sending a \(em40\ dBm0 test tone at 1020\ Hz. If the far\(hyend
suppressor does not operate, the monitor tone from the responding equipment
will continue to reach the directing equipment, and the detection of the
monitor tone by the directing equipment during the test interval will indicate
that the test has passed.
.RT
.LP
.sp 1P
.LP
5.3.14
\fIFar\(hyend suppressor operate test\fR
.sp 9p
.RT
.PP
The responding equipment is sending a monitor tone. The directing equipment
starts sending a \(em26\ dBm0 test tone at 1020\ Hz. If the far\(hyend
suppressor does operate, the monitor tone from the responding equipment
will be prevented from reaching the directing equipment, and this absence
of monitor
tone during the test interval will indicate to the directing equipment
that the test has passed.
.RT
.sp 1P
.LP
5.3.15
\fIFar\(hyend break\(hyin non\(hyoperate test\fR
.sp 9p
.RT
.PP
The responding equipment is silent. The directing equipment starts sending
a \(em10\ dBm0 test tone at 1020\ Hz. Fifty milliseconds after detection
of the 1020\(hyHz test tone from the directing equipment, the responding
equipment
starts sending a high level monitor tone and a \(em15\ dBm0 test tone at
820\ Hz. If break\(hyin does not occur at the far\(hyend suppressor, the
monitor tone from the
responding equipment will be prevented from reaching the directing equipment
and this absence of monitor tone during the test interval will indicate to
the directing equipment that the test has passed.
.RT
.sp 1P
.LP
5.3.16
\fIFar\(hyend break\(hyin operate test\fR
.sp 9p
.RT
.PP
The responding equipment is silent. The directing equipment starts sending
a \(em20\ dBm0 test tone at 1020\ Hz. Fifty milliseconds after detection
of the 1020\(hyHz test tone from the directing equipment, the responding
equipment starts sending a high level monitor tone and a \(em15\ dBm0 test
tone at 820\ Hz.
If break\(hyin does occur at the far\(hyend suppressor, the monitor tone
from the
responding equipment reaches the directing equipment and detection of
the monitor tone by the directing equipment during the test interval will
indicate that the test has passed.
.bp
.RT
.sp 2P
.LP
\fB6\fR \fBSpecifications for transmission measuring equipment\fR
.sp 1P
.RT
.PP
The following specifications apply over a temperature range of
+5 | (deC to +50 | (deC.
.RT
.LP
.sp 2P
.LP
6.1
\fISending apparatus of the directing and responding equipment\fR
.sp 1P
.RT
.sp 1P
.LP
6.1.1
\fISignal and tone frequencies\fR \v'4p'
.sp 9p
.RT
.LP
a)
test\ tones:\ 820\ \(+-\ \ 9\ Hz
.LP
test\ tones:\
1020\ \(+-\ 11\ Hz,
.LP
b)
monitor tone: 510\ \(+-\ 5.5\ Hz,
.LP
c)
acknowledgement signal: 610\ \(+-\ 6.5\ Hz.
.sp 1P
.LP
6.1.2
\fISignal and tone levels\fR \v'4p'
.sp 9p
.RT
.LP
a)
for loss measurements:
.LP
\(em10\ \(+-\ 0.1\ dBm0,
.LP
b)
for test tones:
.LP
\(em10\ \(+-\ 0.2\ dBm0 (directing equipment only),
.LP
\(em15\ \(+-\ 0.2\ dBm0 (responding equipment only),
.LP
\(em20\ \(+-\ 0.2\ dBm0 (directing equipment only),
.LP
\(em26\ \(+-\ 0.2\ dBm0,
.LP
\(em40\ \(+-\ 0.2\ dBm0,
.LP
c)
for monitor tone:
.LP
\(em42\ \(+-\ 0.5\ dBm0 (normal level),
.LP
\(em29\ \(+-\ 0.5\ dBm0 (high level),
.LP
d)
for acknowledgement signal:
.LP
\(em29\ \(+-\ 0.5\ dBm0.
.sp 1P
.LP
6.1.3
\fIOutput impedance\fR (frequency range 300 Hz to 4 kHz)
.sp 9p
.RT
.PP
\(em
Balanced, earth free
600\ ohms
.PP
\(em
Return loss
\(>=" 30 dB
.PP
\(em
Output signal balance
\(>=" 40 dB
.RT
.sp 1P
.LP
6.1.4
\fIDistortion and spurious\(hymodulation supression\fR
.sp 9p
.RT
.PP
Better than 25\ dB.
.RT
.sp 2P
.LP
6.2
\fIReceiving apparatus of the directing and responding equipment\fR
.sp 1P
.RT
.sp 1P
.LP
6.2.1
\fIMeasuring ranges\fR \v'4p'
.sp 9p
.RT
.LP
a)
for loss measurement:
.LP
from \(em7.5\ \(+-\ 0.2 dBm0 to \(em12.5\ \(+-\ 0.2\ dBm0,
.LP
b)
for noise measurement:
.LP
test threshold \(em40\ \(+-\ 1.0\ dBm0p measured with psophometric
weighting as specified in Recommendation\ P.51\ [3],
.LP
c)
for monitor tone and acknowledgement signal
detection:
.LP
test threshold of \(em54\ \(+-\ 2.0 dBm0 measured with selective
receivers having sufficient discrimination to reject other
tones and noise that may be present on the circuit under test.
.bp
.sp 1P
.LP
6.2.2
\fITest interval\fR
.sp 9p
.RT
.PP
375\ \(+-\ 25\ ms.
.RT
.sp 1P
.LP
6.2.3
\fIInput impedance\fR (frequency range 300 Hz to 4 kHz)
.sp 9p
.RT
.PP
\(em
Balanced, earth free
600 ohms
.PP
\(em
Return loss
\(>=" 30 dB
.PP
\(em
Input longitudinal interference loss
\(>=" 46 dB
.RT
.sp 2P
.LP
\fB7\fR \fBCommand signals from the directing equipment to the responding\fR
\fBequipment\fR
.sp 1P
.RT
.PP
Each test shall be initiated by the sending of a unique
multi\(hyfrequency (MF) command signal from the directing equipment to the
responding equipment.
.PP
The signal sender and signal receiver are those specified for the
CCITT\ No.\ 5 Interregister Signalling System and the equipment used should be
as specified in Recommendations\ Q.153\ [4] and Q.154\ [5], except that the MF
command signals will be sent for 500\ \(+-\ 100\ ms and that the MF receiver
shall respond to MF command signals between \(em26\ dBm0 and \(em3\ dBm0.
.RT
.LP
CODE\ No.
FREQUENCY\ (Hz)
TEST
.sp 1P
.LP
\ \ 1
\ \ 700\ +\ \ 900
Near\(hyto\(hyfar loss
.sp 9p
.RT
.LP
\ \ 2
\ \ 700\ +\ 1100
Far\(hyto\(hynear loss
.LP
\ \ 3
\ \ 900\ +\ 1100
Near\(hyto\(hyfar noise
.LP
\ \ 4
\ \ 700\ +\ 1300
Far\(hyto\(hynear noise
.LP
\ \ 5
\ \ 900\ +\ 1300
Near\(hyend suppressor non\(hyoperate
.LP
\ \ 6
\ 1100\ +\ 1300
Near\(hyend suppressor operate
.LP
\ \ 7
\ \ 700\ +\ 1500
Near\(hyend break\(hyin non\(hyoperate
.LP
\ \ 8
\ \ 900\ +\ 1500
Near\(hyend break\(hyin operate
.LP
\ \ 9
\ 1100\ +\ 1500
Far\(hyend suppressor non\(hyoperate
.LP
\ 10
\ 1300\ +\ 1500
Far\(hyend suppressor operate
.LP
\ 11
\ \ 700\ +\ 1700
Far\(hyend break\(hyin non\(hyoperate
.LP
\ 12
\ \ 900\ +\ 1700
Far\(hyend break\(hyin operate
.LP
.sp 2P
.LP
\fBReferences\fR
.sp 1P
.RT
.LP
[1]
CCITT Recommendation \fIEcho\(hysuppressor suitable for circuits having\fR
\fIeither short or long propagation times\fR , Orange Book, Vol.\ III\(hy1,
Rec.\ G.161, ITU, Geneva,\ 1977.
.LP
[2]
CCITT Recommendation \fIEcho suppressors\fR , Vol.\ III, Rec.\ G.164.
.LP
[3]
CCITT Recommendation \fIArtificial ear and artificial mouth\fR ,\fR
Vol.\ V, Rec.\ P.51.
.LP
[4]
CCITT Recommendation \fIMultifrequency signal sender\fR , Green Book,
Vol.\ VI.2, Rec.\ Q.153, ITU, Geneva,\ 1973.
.LP
[5]
CCITT Recommendation \fIMultifrequency signal receiver\fR , Green Book,
Vol.\ VI.2, Rec.\ Q.154, ITU, Geneva,\ 1973.
.bp
.sp 2P
.LP
\fBRecommendation\ O.27\fR
.RT
.sp 2P
.sp 1P
.ce 1000
\fBIN\(hySTATION\ ECHO\ CANCELLER\ TEST\ EQUIPMENT\fR
.EF '% Fascicle\ IV.I\ \(em\ Rec.\ O.27''
.OF '''Fascicle\ IV.I\ \(em\ Rec.\ O.27 %'
.ce 0
.sp 1P
.ce 1000
\fI(Melbourne, 1988)\fR
.sp 9p
.RT
.ce 0
.sp 1P
.LP
\fB1\fR \fBGeneral\fR
.sp 1P
.RT
.PP
The in\(hystation echo canceller test equipment (ISET) is intended to test
type C and D echo cancellers including tone disablers as specified in Recommendation\
G.165\ [1]. Two test modes are provided as described below. The tests performed
in each test mode are listed in Table\ 1/O.27.
.RT
.sp 2P
.LP
\fB2\fR \fBTest modes\fR
.sp 1P
.RT
.sp 1P
.LP
2.1
\fIRoutine test mode\fR
.sp 9p
.RT
.PP
In this test mode, ISET provides 7 simplified tests of echo
canceller performance under normal circuit conditions with the adaptation and
.PP
non\(hylinear processing logic activated. Access to the echo canceller being
tested is on a 4\(hywire basis, and these simple performance tests are made by
applying test signals to the receive\(hyin (R\di\\dn\u) and the send\(hyin
(S\di\\dn\u) ports of the echo canceller. Test results are measured at
the send\(hyout
(S\do\\du\\dt\u) port. A functional block diagram of the test arrangement is
shown in Figure\ 1/O.27.
.RT
.LP
.rs
.sp 22P
.ad r
\fBFigure 1/O.27, p.\fR
.sp 1P
.RT
.ad b
.RT
.sp 1P
.LP
2.2
\fIDiagnostic test mode\fR
.sp 9p
.RT
.PP
In this mode, all performance tests are made according to
procedures specified in Recommendation\ G.165\ [1]. The adaptation and
non\(hylinear processing logic is disabled when necessary by controlling
the echo canceller that is being tested.
.bp
.RT
.sp 2P
.LP
\fB3\fR \fBOperating principles\fR
.sp 1P
.RT
.sp 1P
.LP
3.1
\fIMethod of access\fR
.sp 9p
.RT
.PP
When an echo canceller to be tested is fitted to a particular
circuit, a reserved echo canceller should be substituted so that the tests
can be made without causing any disturbance to the circuit. If no reserved
echo
canceller is available, the circuit should be blocked from service while the
tests are being performed.
.PP
ISET may be connected to an echo canceller under test either manually at
local access points or remotely by access arrangements through a switching
system. Administrations may wish to provide remote access capability to
echo
cancellers for routine tests as shown in Figure\ 2/O.27. Local access as
shown in Figure 3/O.27 is for diagnostic tests where the use of control
signals to
inhibit the\ H register, adaptation and center clipper logic are needed.
.RT
.LP
.rs
.sp 17P
.ad r
\fBFigure 2/O.27, p.\fR
.sp 1P
.RT
.ad b
.RT
.LP
.rs
.sp 22P
.ad r
\fBFigure 3/O.27, p.\fR
.sp 1P
.RT
.ad b
.RT
.LP
.bp
.sp 1P
.LP
3.2
\fITesting sequences\fR
.sp 9p
.RT
.PP
When access has been established, a series of tests is performed
manually or automatically. The tests to be performed in the routine and
diagnostic test modes are given in Table\ 1/O.27. Measurement results for
each test shall be provided to the maintenance personel by a visual display
or
printed message.
.PP
If an echo canceller fails any of the routine tests, it should be
completely tested in the diagnostic test mode.
.RT
.LP
.sp 3
.ce
\fBH.T. [T1.27]\fR
.ce
TABLE\ 1/O.27
.ce
\fBTest Procedures\fR
.ps 9
.vs 11
.nr VS 11
.nr PS 9
.TS
center box;
cw(18p) | cw(114p) | cw(36p) | cw(30p) sw(30p) , ^ | ^ | ^ | c | c.
No. Type of Test G.165 [1] Reference Test modes
Routine Diagnostic
_
.T&
cw(18p) | lw(114p) | cw(36p) | cw(30p) | cw(30p) .
\ 1 {
Steady state residual and returned echo level test
} 3.4.2.1 | 0 0
_
.T&
cw(18p) | lw(114p) | cw(36p) | cw(30p) | cw(30p) .
\ 2 Convergence test 3.4.2.2 | 0 0
_
.T&
cw(18p) | lw(114p) | cw(36p) | cw(30p) | cw(30p) .
\ 3 {
Double talk detection oversensitivity test
} 3.4.2.3.1 0 0
_
.T&
cw(18p) | lw(114p) | cw(36p) | cw(30p) | cw(30p) .
\ 4 {
Double talk detection undersensitivity test
} 3.4.2.3.2 0 0
_
.T&
cw(18p) | lw(114p) | cw(36p) | cw(30p) | cw(30p) .
\ 5 Leak rate test 3.4.2.4 | 0
_
.T&
cw(18p) | lw(114p) | cw(36p) | cw(30p) | cw(30p) .
\ 6 {
Infinite return loss convergence test
} 3.4.2.5 | 0 0
_
.T&
cw(18p) | lw(114p) | cw(36p) | cw(30p) | cw(30p) .
\ 7 {
Tone disabler send side sensitivity test
} \ | .2 | | 0 0
_
.T&
cw(18p) | lw(114p) | cw(36p) | cw(30p) | cw(30p) .
\ 8 {
Tone disabler receive side sensitivity test
} \ | .2 | | 0 0
_
.T&
cw(18p) | lw(114p) | cw(36p) | cw(30p) | cw(30p) .
\ 9 Tone disabler guard band test \ | .3 | | 0
_
.T&
cw(18p) | lw(114p) | cw(36p) | cw(30p) | cw(30p) .
10 {
Tone disabler holding band test
} \ | .4 | | 0
_
.T&
cw(18p) | lw(114p) | cw(36p) | cw(30p) | cw(30p) .
11 {
Tone disabler operate time test
} \ | .5 | | 0
_
.T&
cw(18p) | lw(114p) | cw(36p) | cw(30p) | cw(30p) .
12 {
Tone disabler release time test
} \ | .8 | | 0
_
.T&
cw(18p) | lw(114p) | cw(36p) | cw(30p) | cw(30p) .
13 {
External disabler control test
} \ | .3 | | 0
_
.TE
.nr PS 9
.RT
.ad r
\fBTable 1/O.27 [T1.27], p.\fR
.sp 1P
.RT
.ad b
.RT
.LP
.bp
.sp 2P
.LP
\fB4\fR \fBTest procedures and test requirements\fR
.sp 1P
.RT
.sp 1P
.LP
4.1
\fIRoutine test mode\fR
.sp 9p
.RT
.PP
Different echo cancellers may be designed to work
satisfactorily for different echo path delays depending on their application
in various networks. Thus\ \(*D represents the echo path delay for which
the echo
canceller is designed. Each Administration may choose a delay value of\ \(*D
appropriate for their equipment.
.FE
Figure 1/O.27 shows a functional arrangement for the routine test mode.
The following seven tests should be repeated with an appropriate echo
path delay\ \(*D ms
set in the adjustable echo delay unit.
.PP
At the beginning of each of the seven tests, a conditioning tone is
applied for 1\ second to the\ R\di\\dn\uport for initialization of the echo
canceller to be tested. The conditioning tone is a 2100\ Hz signal of \(em10\
dBm0 with periodic phase reversals occurring every 0.45\ seconds and is
also used to disable echo cancellers. During this initialization period
the\ H register
of the canceller is cleared. After the conditioning tone is disconnected, no
signal is applied to the canceller for at least 0.4\ seconds to allow it to
return to an enabled state. Further information on the characteristics
of echo canceller tone disablers may be found in \(sc\ 4 and Annex\ B of
Recommendation\ G.165\ [1].
.RT
.sp 1P
.LP
4.1.1
\fICheck of steady state residual and returned echo\fR
\fIlevel\fR \v'3p'
.sp 9p
.RT
.LP
Step\ 1:
A random noise signal (A) of \(em10\ dBm0 is applied to
the R\di\\dn\uport. With the echo path loss set at 10\ dB, an echo appears at
the S\di\\dn\uport.
.LP
Step\ 2:
After 2 seconds the returned echo level at the
S\do\\du\\dt\uport is measured.
.LP
Requirement:
The returned echo level must be less than
\(em65\ dBm0.
.sp 1P
.LP
4.1.2
\fICheck of convergence\fR \v'3p'
.sp 9p
.RT
.LP
Step\ 1:
A random noise signal (A) of \(em10 dBm0 is applied to
the R\di\\dn\uport. With the echo path loss set at 6\ dB, an echo is appears
at the S\di\\dn\u\ port.
.LP
Step\ 2:
A second random noise signal (B) of \(em10 dBm0 is
applied to the S\di\\dn\u\ port as shown in Figure\ 1/O.27.
.LP
Step\ 3:
After 0.5 seconds noise signal (B) is disconnected,
and 0.5\ seconds later the returned signal level at the S\do\\du\\dt\u\ port is
measured.
.LP
Requirement:
The signal level must be less than \(em37 dBm0.
.sp 1P
.LP
4.1.3
\fICheck of double talk detection oversensibility\fR \v'3p'
.sp 9p
.RT
.LP
Step\ 1:
A random noise signal (A) of \(em10 dBm0 is applied to
the R\di\\dn\u\ port. With the echo path loss set as 6\ dB, an echo appears
at the S\di\\dn\u\ port.
.LP
Step\ 2:
After 0.5 seconds, a second random noise signal (B) of \(em25\ dBm0 is
applied to the S\di\\dn\u\ port.
.LP
Step\ 3:
One second later noise signal (B) is disconnected and the returned echo
level at the S\do\\du\\dt\u\ port is measured.
.LP
Requirement:
The returned echo level must be less than
\(em25\ dBm0.
.sp 1P
.LP
4.1.4
\fICheck of double talk detection undersensitivity\fR \v'3p'
.sp 9p
.RT
.LP
Step\ 1:
With the echo path loss set at 10 dB, a random noise signal\ (A) of \(em10\
dBm0 is applied to the R\di\\dn\u\ port.
.LP
Step\ 2:
After 1 second the noise signal (A) at the
R\di\\dn\u\ port is disconnected.
.LP
Step\ 3:
After an interval of 0.5 seconds, the noise signal (A) is reapplied to
the R\di\\dn\u\ port. Simultaneously a second noise signal\ (B) of 0\ dBm0
is applied to the S\di\\dn\u\ port.
.LP
.sp 1
.bp
.LP
Step\ 4:
0.5 seconds later the noise signal (B) is disconnected and the residual
echo level at the S\do\\du\\dt\u\ port is measured.
.LP
Requirement:
The returned echo level must be less than
\(em26\ dBm0.
.sp 1P
.LP
4.1.5
\fICheck of infinite return loss convergence\fR \v'3p'
.sp 9p
.RT
.LP
Step\ 1:
With the echo path loss set at 6 dB, a random noise
signal\ (A) of \(em10\ dBm0 is applied to the R\di\\dn\u\ port.
.LP
Step\ 2:
After 1 second the echo path between R\do\\du\\dt\uand S\di\\dn\uis disconnected
while noise signal\ (A) remains connected to the
R\di\\dn\u\ port.
.LP
Step\ 3:
0.5 seconds later the returned echo level at the
S\do\\du\\dt\u\ port is measured.
.LP
Requirement:
The returned echo level must be less than
\(em37\ dBm0.
.sp 1P
.LP
4.1.6
\fICheck of tone disabler send\(hyside sensitivity\fR
.sp 9p
.RT
.PP
There are two parts to this test to ensure that the disabler tone detection
circuit on the send side is not oversensitive or undersensitive.
.RT
.LP
Step\ 1:
A 2100 Hz signal of \(em36.5 dBm0 with periodic phase
reversals every 0.45\ seconds is applied for one second to the S\di\\dn\u\
port.
.LP
Step\ 2:
A random noise signal (A) of \(em10 dBm0 is applied to
the R\di\\dn\u\ port.
.LP
Step\ 3:
After 0.5 seconds the returned echo level at the
S\do\\du\\dt\u\ port is measured.
.LP
Requirement:
The returned echo level must be less than
\(em32\ dBm0 to show that the disabler is not operated.
.LP
Step\ 4:
The conditioning tone is re
applied for one second to the R\di\\dn\u\ port. After at least 0.4\ seconds,
the 2100\ Hz signal with
periodic phase reversals every 0.45\ seconds is reapplied to the S\di\\dn\u\
port at a level of \(em29.5\ dBm0 for one second.
.LP
Step\ 5:
Then the random noise signal (A) of \(em10 dBm0 is
reapplied to the R\di\\dn\u\ port with the echo path loss set at 10\ dB.
.LP
Step\ 6:
After 0.5 seconds the returned echol level at the
S\do\\du\\dt\u\ port is measured.
.LP
Requirement:
The returned echo level must be between
\(em29.5\ dBm0 and \(em26.5\ dBm0 to show that the disabler is operated.
.sp 1P
.LP
4.1.7
\fICheck of tone disabler receive\(hyside sensitivity\fR
.sp 9p
.RT
.PP
There are also two parts to this test to ensure that the disabler tone
detection on the receive side is not oversensitive or undersensitive.
.RT
.LP
Step\ 1:
A 2100 Hz signal of \(em36.5\ dBm0 with period periodic
phase reversals every 0.45\ seconds is applied for one second to the
R\di\\dn\u\ port.
.LP
Step\ 2:
A random noise signal (A) of \(em10 dBm0 is applied to
the R\di\\dn\u\ port. With the echo path loss set at 10\ dB, an echo appears at
the S\di\\dn\u\ port.
.LP
Step\ 3:
After 0.5 seconds the returned echo level at the
S\do\\du\\dt\u\ port is measured.
.LP
Requirement:
The returned level must be less than \(em32 dBm0 to show that the disabler
is not operated.
.LP
Step\ 4:
The conditioning tone is reapplied for one second to the R\di\\dn\u\
port. After at least 0.4\ seconds, the 2100\ Hz signal with
periodic phase reversals every 0.45\ seconds is reapplied to the S\di\\dn\u\
port at a level of \(em29.5\ dBm0 for one second.
.LP
Step\ 5:
Then the random noise signal (A) of \(em10 dBm0 is
reapplied to the R\di\\dn\u\ port with the echo path loss set at 10\ dB.
.LP
Step\ 6:
After 0.5 seconds the returned echo level at the
S\do\\du\\dt\u\ port is measured.
.LP
Requirement:
The returned echo level must be between \(em29.5
dBm0 and \(em26.5\ dBm0 to show that the disabler is operated.
.bp
.sp 1P
.LP
4.2
\fIDiagnostic test mode\fR
.sp 9p
.RT
.PP
In this mode diagnostic tests are performed as specified in
Recommendation\ G.165. \(sc\ 3.3.2 and \(sc\ 4\ [1].
.RT
.sp 2P
.LP
\fB5\fR \fBSpecifications for transmission measuring equipment\fR
.sp 1P
.RT
.PP
The following specifications apply for climatic conditions
specified in Recommendation\ O.3.
.RT
.sp 2P
.LP
5.1
\fISignal generator\fR
.sp 1P
.RT
.sp 1P
.LP
5.1.1
\fIRange of frequency\fR
.sp 9p
.RT
.LP
0.3 to 3.4 kHz in 0.01 kHz steps.
.sp 1P
.LP
5.1.2
\fIRange of level\fR
.sp 9p
.RT
.LP
\(em40 to 0 dBm0 in 0.1 dB steps.
.sp 1P
.LP
5.1.3
\fIAccuracy\fR
.sp 9p
.RT
.LP
Frequency
\(+- | .01 kHz
.LP
Level
\(+- | .1 dB.
.sp 2P
.LP
5.2
\fILevel meter\fR
.sp 1P
.RT
.sp 1P
.LP
5.2.1
\fIRange of measurement\fR
.sp 9p
.RT
.LP
\(em70 to + 3.2 dBm0.
.sp 1P
.LP
5.2.2
\fIAccuracy\fR
.sp 9p
.RT
.LP
\(+- | .1 dB (above \(em40 dBm0).
.sp 1P
.LP
5.2.3
\fIDynamic response time\fR
.sp 9p
.RT
.LP
Under study
.FS
A meter with a rapid response time will be needed to meet the timing requirements
of some of the tests specified above.
.FE
.
.sp 2P
.LP
5.3
\fIRandom noise source\fR
.sp 1P
.RT
.sp 1P
.LP
5.3.1
\fILevel\fR
.sp 9p
.RT
.LP
\(em40 to + 0 dBm0.
.sp 1P
.LP
5.3.2
\fINoise signal\fR
.sp 9p
.RT
.PP
The noise test signal is a band\(hylimited white noise
(300\(hy3400\ Hz).
.RT
.sp 2P
.LP
5.4
\fIEcho path\fR
.sp 1P
.RT
.sp 1P
.LP
5.4.1
\fIEcho loss\fR
.sp 9p
.RT
.LP
0 dB to 40 dB in 0.1 dB steps.
.LP
.sp 2
.bp
.sp 1P
.LP
5.4.2
\fIEcho delay\fR
.sp 9p
.RT
.LP
0 to \(*D ms
in 1 ms steps.
.sp 1P
.LP
5.4.3
\fIBandwidth\fR
.sp 9p
.RT
.LP
0.3 to 3.4 kHz.
.sp 2P
.LP
\fB6\fR \fBCalibration\fR
.sp 1P
.RT
.sp 1P
.LP
6.1
\fICalibration of measuring equipment\fR
.sp 9p
.RT
.PP
Calibration features should be provided to check that the accuracy requirements
are met.
.RT
.sp 1P
.LP
6.2
\fISelf\(hycheck of operational function\fR
.sp 9p
.RT
.PP
A local self\(hychecking facility should be provided to make sure that
the testing functions are operating properly.
.RT
.sp 2P
.LP
\fB7\fR \fBOptional arrangements\fR
.sp 1P
.RT
.sp 1P
.LP
\fI\fR 7.1
\fIAutomatic test function\fR
.sp 9p
.RT
.PP
A function to perform tests in sequence automatically according to the
predetermined procedure, may be provided.
.RT
.sp 1P
.LP
7.2
\fIAutomatic start function\fR
.sp 9p
.RT
.PP
A timed automatic start function which enables the unattended
operations, may be provided.
.RT
.sp 2P
.LP
\fBReferences\fR
.sp 1P
.RT
.LP
[1]
CCITT Recommendation \fIEcho Cancellers\fR , Vol. III, Rec. G.165.
.LP
.sp 16
.bp
.sp 2P
.LP
\fBRecommendation\ O.31\fR \v'3P'
.RT
.sp 2P
.sp 1P
.ce 1000
\fBAUTOMATIC\ MEASURING\ EQUIPMENT
\fBFOR\ SOUND\(hyPROGRAMME\ CIRCUITS\fR
.EF '% Fascicle\ IV.4\ \(em\ Rec.\ O.31''
.OF '''Fascicle\ IV.4\ \(em\ Rec.\ O.31 %'
.ce 0
.sp 1P
.ce 1000
\fI(Geneva, 1972; amended at Geneva, 1976)\fR \v'4P'
.sp 9p
.RT
.ce 0
.sp 1P
.LP
\fB1\fR \fBGeneral\fR
.sp 1P
.RT
.PP
The CCITT automatic measuring equipment for sound\(hyprogramme
circuits is capable of rapidly measuring all relevant parameters necessary
for checking the quality of such circuits. The measuring results are recorded
by
means of an analogue recorder and/or digital receiver. The results of the
measurements are suitable for subsequent documentation and not only permit
an immediate decision by the staff in the field on whether the
sound\(hyprogramme circuit or sound\(hyprogramme connection respectively can be
used for service, but they also provide the basis for later exact evaluation
by the responsible transmission engineer.
.PP
The overall time for the measurements amounts to 136\ seconds. It is
thus short enough to check the quality also of international chains of
sound\(hyprogramme circuits interconnected on a short\(hyterm basis during the
preparatory and lining\(hyup period according to Recommendation\ N.4\ [1].
Measurements for this purpose, made by the ISPCs involved in accordance with
Recommendations\ N.12\ [2] and N.13\ [3], do not require any preceding
agreement.
.RT
.sp 2P
.LP
\fB2\fR \fBQuality criteria to be checked\fR
.sp 1P
.RT
.PP
With the CCITT automatic measuring equipment for sound\(hyprogramme
circuits the following quality criteria can be checked:
.RT
.LP
\fIa\fR =
deviation of the received absolute power level of the
0.8\(hykHz reference frequency from the nominal value;
.LP
\fIb\fR =
weighted and unweighted noise;
.LP
\fIc\fR =
nonlinear distortion measured selectively as harmonic
distortion of the 2nd\ order (\fIk\fR\d2\u) and
3rd\ order (\fIk\fR\d3\u) and as a difference tone
distortion of the 3rd\ order (\fId\fR\d3\u);
.LP
\fId\fR =
compandor functioning test;
.LP
\fIe\fR =
loss/frequency distortion.
.PP
The complete measuring programme comprises three subroutines which can
be chosen individually. The quality criteria to be checked are allotted
to the subroutines in the following way:
.LP
Subroutine\ 1:\ \fIs\fR \ +\ \fIa\fR
.LP
Subroutine\ 2:\ \fIb\fR \ +\ \fIc\fR \ +\ \fId\fR
.LP
Subroutine\ 3:\ \fIe\fR
.LP
where
.LP
in subroutine\ 1, \fIs\fR is the station coding of the sending
unit.
.PP
Within the subroutine the timing of the programme in the sending unit and
in the receiving unit is synchronized by means of a series of pulses provided
by a generator within the equipment.
.bp
.LP
\fB3\fR \fBSpecifications\fR
.sp 1P
.RT
.sp 2P
.LP
3.1
\fISending unit\fR
.sp 1P
.RT
.sp 1P
.LP
3.1.1
\fIStart, stop and time base for synchronization\fR \fIand selection
of measuring mode\fR
.sp 9p
.RT
.PP
By means of a locking press\(hybutton in the sending unit the
measuring programme for single or permanent mode of operation can be started.
The timing of the measuring programme is controlled by a pulse generator.
The smallest time base that can be programmed is fixed at 1.33\ second.
The
synchronizing frequency related to this time base gives 0.75\ Hz and has
to be kept within \(+- | %. A second press\(hybutton offers the possibility
of stopping the measuring programme. By the activation of this press\(hybutton
a means is
provided whereby the locking mechanism of the start press\(hybutton for
permanent operation is simultaneously released. Start, synchronization
and stop of the
receiving unit are triggered by coded pulses (1.3\ kHz at \(em12\ dBm0).
.PP
Every subroutine is preceded by coded pulses which serves as a
start signal. By means of a special stop signal which is triggered by pressing
the stop button, the progress of the measuring programme can be interrupted
at any time and another programme, selected with the aid of a switch, can
be
started instead. Operating the stop button will also reset the time pulse
generator to the starting condition.
.PP
The start and stop signals consist of four pulses whose duration can be
fixed at 60\ ms (value\ O) or 120\ ms (value\ L) by means of digital coding.
The time between the beginning of every pulse within the coded signal is
240\ ms.
.PP
The coding of the pulses is as follows:
.RT
.LP
a)
Start signals for:
.LP
\(em
Subroutine\ 1:\ OOOL
.LP
\(em
Subroutine\ 2:\ OOLO
.LP
\(em
Subroutine\ 3:\ OLOO
.LP
b)
Stop signal:\ LLLL
.PP
The start signals are read from right to left, as is usual in the case
of digital codes, and are transmitted in the same time sequence.
.PP
The sending of the coded signal (duration 960\ ms) which is controlled
by the time pulse generator must be delayed 370\ ms (in order to comply
with the time pulse duration of 1330\ ms).
.RT
.sp 1P
.LP
3.1.2
\fIStation coding\fR
.sp 9p
.RT
.PP
The measuring programme is preceded by the code of the sending
station using the Morse alphabet. For this purpose 19\ timing intervals are
allocated. The station code is sent by keying a 0.8\(hykHz tone between
a level of \(em32\ dBm0 and the reference test level. The duration of Morse
dots and dashes
shall be about 10% and 35% respectively, of one timing interval.
.RT
.sp 1P
.LP
3.1.3
\fITest level sent for the\fR
\fImeasurement of level at the\fR \fIreference frequency\fR \fIand level/frequency
response\fR (quality criteria \fIs\fR , \fIa\fR and \fIe\fR )\fR
.sp 9p
.RT
.PP
The test level sent for loss measurements at the reference
frequency (0.8\ kHz) and for the measurement of level/frequency response
should be \(em12\ dBm0 (see Recommendation\ N.21\ [4]). The measurements
of level/frequency response are to be carried out with the aid of a sweep
generator covering the frequency range from 0.03\(hy16\ kHz. Each octave
\(em\ the first one beginning at
0.05\ kHz\ \(em is marked by short pulses (1.3\ kHz/\(em12\ dBm0 from 50\
to 100\ ms
duration). The speed of this sequence of operations for the frequency range
from 30\(hy16 | 00\ Hz which covers 9.06\ octaves should be 5\ seconds/octave
so that the recording device dealt with in \(sc\ 3.2.7\ below records one
octave over 10\ mm and 3.3\ mm respectively.
.bp
.RT
.sp 1P
.LP
3.1.4
\fITest level sent for nonlinear distortion measurements\fR
.FS
It
shall be possible for the signal sent for the measurement of
nonlinearity distortion to be included in or omitted from the test
cycle at will (for example, under control of a switch). Whether or not
the nonlinearity distortion measurement is admissible must be
determined for each circuit by the users of the equipment, and in a
manner ensuring that the prescriptions of Recommendation\ N.21\ [4] are
respected.
.FE
.sp 9p
.RT
.PP
The sent level of the test frequencies corresponds to the peak
programme level (see the Recommendation cited in\ [5]), that is, the single
tones for the nonlinear distortion measurements lead to the same peak loading
as the double tone for the difference tone factor measurements (single
tone of +9\ dBm0 equivalent to 2.2\ V\dr\\d.\\dm\\d.\\ds\\d.\u\ =\ 3.1\
V\dp\\d0\uand
double tone each of +3\ dBm0 equivalent to (because it is stuck to \*Q2\*U
in the
Orange Book) 2\ \(mu\ 1.1\ V\dr\\d.\\dm\\d.\\ds\\d.\u\ =
2\ \(mu\ 1.55\ V\dp\\d0\ureferred to\ = 3.1\ V\dp\\d0\ua zero
relative level point). In order to avoid overload of carrier\(hyfrequency
transmission systems, only frequencies below\ 2\ kHz (with regard to circuits
equipped with equipped with pre\(hy and de\(hyemphasis techniques) are
applied and
the duration of transmission is automatically reduced to the length of
a single timing pulse
.FS
Other methods are under study by the CCITT.
.FE
. The
following test frequencies should be used:
.RT
.LP
a)
\fIFor the measurement of nonlinear distortion in the lower\fR \fIaudio\(hyfrequency
range:\fR
.LP
\fIc\fR\d1\u =\ 0.09\ kHz/+9\ dBm0 for the \fIk\fR\d2\u\(hymeasurement;
.LP
\fIc\fR\d2\u =\ 0.06\ kHz/+9\ dBm0 for the \fIk\fR\d3\u\(hymeasurement.
.LP
b)
\fIFor the measurement of nonlinear distortion in the\fR
\fIcarrier\(hyfrequency range of a frequency division multiplex channel:\fR
.LP
\fIc\fR\d3\u =\ 0.8\ kHz/+3\ dBm0 and 1.42\ kHz/+3\ dBm0 for the
\fId\fR\d3\u\(hymeasurement.
.LP
c)
\fIFor the\fR
\fImeasurement of nonlinear distortion\fR
\fIin the medium audio\(hyfrequency range:\fR
.LP
\fIc\fR\d4\u =\ 0.8\ kHz/+9\ dBm0 for the \fIk\fR\d2\u\(hymeasurement;
.LP
\fIc\fR\d5\u =\ 0.533\ kHz/+9\ dBm0 for the
\fIk\fR\d3\u\(hymeasurement.
.sp 1P
.LP
3.1.5
\fISignal sent for\fR
\fIcompandor functioning test\fR |
.FS
This
test is intended for provisional use. A change will be
necessary when, after further study, the CCITT issues Recommendations
for compandors and appropriate methods of their testing.
.FE
(quality criterion\ \fId\fR )
.sp 9p
.RT
.PP
In order to detect a noncomplementary behaviour of regulating
amplifiers in compandors a 0.8\(hykHz signal is injected, the level of which is
switched between the values +6, \(em6, +6\ dBm0 for three consecutive timing
intervals.
.RT
.sp 1P
.LP
3.1.6
\fIRemote control of the sending unit\fR
.sp 9p
.RT
.PP
Provision should be made for sending up to 16\ command signals.
These signals may be applied to the sending equipment in either binary
code or by applying earth to 16\ signal paths. In case of binary coding
for starting
the complete measuring programme the coded signal\ LOOL should be used in
addition to the start signal given under \(sc\ 3.1.1\ above.
.RT
.sp 2P
.LP
3.2
\fIReceiving unit\fR
.sp 1P
.RT
.sp 1P
.LP
3.2.1
\fIStart, stop and synchronization\fR
.sp 9p
.RT
.PP
In the receiving unit the coded pulses must be detected and
separated by means of a selective process. A guard circuit similar to the
one normally used for signal receivers is required to protect against false
operation. In combination with the above\(hymentioned guard circuit the
4\(hybit code chosen offers a highly reliable protection against the possibility
that the
starting mechanism might be activated by sound\(hyprogramme signals. Thus, the
receiving unit can remain continuously connected to a sound\(hyprogramme
circuit and can record the measuring programme without intervention by
an operator.
.PP
The timing schedule must be in conformity with the requirements
specified for the sending unit (see \(sc\ 3.1.1\ above).
.PP
The time pulse generator shall be triggered after the reception of the
start signal. Reception of the stop signal shall cause the time pulse generator
to be reset to the starting condition.
.bp
.RT
.sp 1P
.LP
3.2.2
\fIMeasuring ranges\fR
.sp 9p
.RT
.PP
The measuring device should have a logarithmic characteristic, and a linear
measuring range of \(+- | 0\ dB referred to the respective centre\(hyof\(hyrange
should be provided.
.PP
For the particular measuring function the following centres\(hyof\(hyrange
should be provided:
.RT
.LP
\(em
station coding, level measurement at 0.8\ kHz
and measure of level/frequency response (\fIs\fR , \fIa\fR , \fIe\fR )
\(em12\ dBm0
.LP
\(em
noise level weighted (\fIb\fR\d1\u) and
unweighted (\fIb\fR\d2\u)
\(em51\ dBm0
.LP
(signal/noise ratio, referred to +9\ dBm0
\ 60\ dB)
.LP
\(em
nonlinear distortion
.LP
\fIk\fR\d2\u\(hy and \fIk\fR\d3\u\(hymeasurements
(\fIc\fR\d1\u, \fIc\fR\d2\u, \fIc\fR\d4\u, \fIc\fR\d5\u)
\(em31\ dBm0
.LP
(ratio, referred to +9\ dBm0
\ 40\ dB)
.LP
\fId\fR\d3\u\(hymeasurement (\fIc\fR\d3\u)
\(em37\ dBm0
.LP
(ratio, referred to +3\ dBm0
\ 40\ dB)
.LP
\(em
level step signal (\fId\fR )
\ \ 0\ dBm0
.PP
The quality criteria\ \fIa\fR , \fIc\fR , \fId\fR and \fIe\fR are expressed in
terms of r.m.s. values.
.sp 1P
.LP
3.2.3
\fINoise measurements\fR
.sp 9p
.RT
.PP
The quality criteria \fIb\fR\d1\uand\ \fIb\fR\d2\u(weighted and unweighted
noise measurements) are measured in a quasi\(hypeak mode. The dynamic properties
of the rectifier circuitry and the network for weighted noise measurement
(\fIb\fR\d1\u) should meet the requirements of CCIR
Recommendation\ 468\ [6].
.RT
.sp 1P
.LP
3.2.4
\fIProvision of filters and their characteristics\fR
.sp 9p
.RT
.PP
Two bandpass filters should be provided for selecting the nonlinear distortion
products, one for 0.18\ kHz and the other for 1.6\ kHz. They should be
used as follows:
\v'3p'
.RT
.LP
\fI0.18\(hykHz filter\fR
.LP
\(em
for \fIk\fR\d2\u\(hymeasurement of 0.09\ kHz (\fIc\fR\d1\u),
.LP
\(em
for \fIk\fR\d3\u\(hymeasurement of 0.06\ kHz (\fIc\fR\d2\u),
.LP
\(em
for \fId\fR\d3\u\(hymeasurement of 0.8/1.42\ kHz
(\fIc\fR\d3\u);
.LP
\fI1.6\(hykHz filter\fR
.LP
\(em
for \fIk\fR\d2\u\(hymeasurement of 0.8\ kHz (\fIc\fR\d4\u),
.LP
\(em
for \fIk\fR\d3\u\(hymeasurement of 0.533\ kHz
(\fIc\fR\d5\u).
.PP
With the 0.18\ kHz filter only the lower \fId\fR\d3\u\(hyproduct
(2\ \(mu\ 0.8\ kHz\ \(em1.42\ kHz\ =\ 0.18\ kHz) is measured. The measurement
of the upper
\fId\fR\d3\u\(hyproduct at 2.04\ kHz (=\ 2\ \(mu\ 1.42\ kHz\ \(em\ 0.8\
kHz) is not made. To
compensate for this, two times the lower \fId\fR\d3\u\(hyproduct at 0.18\
kHz is taken.
.PP
The bandpass filters should meet the following selectivity
requirements:
.RT
.LP
\(em
passband defined by insertion loss values less than 1\ dB:
.LP
0.18\ kHz filter:\ \(+- | 3\ Hz\ \(rt
.LP
1.6\ \ kHz filter:\ \(+- | 4\ Hz\ \(rb
\(rk\ \ referred
to the centre frequency
.LP
\(em
rejection frequency range defined by insertion loss values
greater than 70\ dB:
.LP
0.18 kHz filter:\ < | .09 kHz and > | .36 kHz
.LP
1.6\
kHz filter:\ < | .8\
kHz and > | .2\
kHz
.sp 1P
.LP
3.2.5
\fIAdditional markers provided at digital receivers\fR
.sp 9p
.RT
.PP
Additional markers can be generated in the digital receiver as
required by making use of the octave markers received from the sending unit
as a timing base.
.RT
.sp 1P
.LP
3.2.6
\fIProgramming of digital receivers\fR
.sp 9p
.RT
.PP
Where a digital receiver is used it shall be possible to programme it so
as to check that the circuits tested meet the required
tolerances.
.bp
.RT
.sp 1P
.LP
3.2.7
\fIRecording device\fR
.sp 9p
.RT
.PP
The transient response time of the recording device should not
exceed 200\ ms. In connection with
the rectifier circuitry of the receiving unit for noise measurements the
requirements of CCIR
Recommen
dation\ 468\ [6] should be fulfilled.
.PP
Paper width and speed may be chosen according to national standards. The
following values have proved to be practicable:
.RT
.LP
\(em
paper width 100\ mm;
.LP
\(em
paper speed 2\ mm/s and 2/3\ mm/s.
.LP
These paper speeds should be manually adjustable.
.PP
The above\(hymentioned values yield (on the 20\(hydB level range) a
level scale of 2\ dB/10\ mm and (on the 136\(hyseconds overall time) a
record length of 272\ mm and 90.7\ mm respectively.
.PP
In addition to the recording device it would be desirable to provide appropriate
access points for the use of an oscilloscope.
.RT
.sp 1P
.LP
3.3
\fISequence of operations\fR
.sp 9p
.RT
.PP
The sequence of operations of the measuring programme and the
associated time units is shown in Annex\ A.
.RT
.sp 2P
.LP
3.4
\fILong\(hyterm measurements of noise\fR
.sp 1P
.RT
.sp 1P
.LP
3.4.1
\fIAutomatic measurements\fR
.sp 9p
.RT
.PP
After a period of 10\ time intervals following the end of a complete measuring
programme, and without receipt of a start signal, the receiver will automatically
commence long\(hyterm noise measurements. Weighted noise will be
measured over a period of 60\ time intervals and unweighted noise over
a period of 20\ time intervals. The same centre\(hyof\(hyrange as given
in \(sc\ 3.2.2\ above for
noise, weighted and unweighted will be used.
.RT
.sp 1P
.LP
3.4.2
\fIManual measurements\fR
.sp 9p
.RT
.PP
In order to make measurements of weighted or unweighted noise
continuously for unspecified periods of time, it must be possible to make
the timing mechanism inoperative. Where an analogue receiver is used, a
manually
controlled switch should be provided, so that the centre\(hyof\(hyrange can be
changed by 10\ dB in either direction.
.RT
.sp 1P
.LP
3.5
\fIMatching characteristics\fR
.sp 9p
.RT
.PP
According to the lining\(hyup procedure for sound\(hyprogramme circuits
using the constant voltage method the following impedances are to be
provided:
.RT
.LP
\(em
output impedance of the sending unit < | 0 ohms,
.LP
\(em
input impedance of the receiving unit > | 0\ kohms.
.PP
Both values may be changed by internal switching to 600\ ohms if, for the
lining\(hyup of the sound\(hyprogramme circuit, the impedance matching
method is applied. It should be possible to adjust the sending and receiving
units
by means of a switch to the following relative levels:
.PP
+6\ dBr
| u4\d\u)\d\
=\ nominal value at the repeater stations
of Administrations;
.PP
\ 0\ dBr
.FS
For certain purposes a level of \(em3 dBr or lower
may be used.
.FE
\ =\ nominal value at the studios of broadcasting
organizations.
.RT
.sp 2P
.LP
3.6
\fIAccuracy of sending and receiving units\fR
.sp 1P
.RT
.sp 1P
.LP
3.6.1
\fISending unit\fR \v'3p'
.sp 9p
.RT
.LP
a)
\fIIndividual frequency oscillators\fR
.ad r
\(em
level tolerance
\(+- | .2\ dB
\v'4p'
.ad b
.RT
.ad r
\(em
frequency tolerance
< | .0%\ \
\v'4p'
.ad b
.RT
.ad r
\(em
harmonic distortion at 2\fIf\fR .PS 10
and 3\fIf\fR .PS 10
< | .1%\ \
\v'4p'
.ad b
.RT
.LP
.bp
.LP
b)
\fISweep frequency oscillator\fR .PS 10
.ad r
\(em
level tolerance at 0.8\ kHz
\(+- | .2\ dB
\v'4p'
.ad b
.RT
.ad r
\(em
level/frequency response referred to 0.8\ kHz
\(+- | .2\ dB
\v'4p'
.ad b
.RT
.sp 1P
.LP
3.6.2
\fIReceiving unit\fR
.sp 9p
.RT
.PP
Tolerances, including recording device:
.RT
.ad r
\(em
mid\(hyscale value \(em12\ dBm0 and 0\ dBm0
\(+- | .3\ dB
\v'4p'
.ad b
.RT
.ad r
\(em
mid\(hyscale value \(em51\ dBm0 and \(em31\ dBm0
\(+- | .0\ dB
\v'4p'
.ad b
.RT
.PP
Operational stability should be reached within 15\ minutes after
switching on. As far as the details of the division of the tolerances are
concerned, reference is made to the values given in Supplement\ No.\ 3.1
at the end of this fascicle.
.PP
The tolerances may then be reduced by calibrating the sending and
receiving units when interconnected on a loop basis (in order to compensate
residual errors).
.RT
.LP
.rs
.sp 39P
.ad r
Blanc
.ad b
.RT
.LP
.bp
.ce 1000
ANNEX\ A
.ce 0
.ce 1000
(to Recommendation O.31)
.sp 9p
.RT
.ce 0
.ce
\fBH.T. [T1.31]\fR
.ce
TABLE\ A\(hy1/O.31
.ce
\fBSequence of operations\fR
.ce
\fBMONTAGE: TABLEAU A RECUPERER DU LIVRE ROUGE, SANS CORRECTIONS.\fR
.ce
blanc
.ce
\fBH.T. [T1.32]\fR
.ce
TABLE\ 1/O.32
.ce
\fBMeasurement of quality criteria\fR
.ce
\fIa\fR
\fBto\fR
\fIi\fR
\fB, sender\fR
\fBand receiver requirements\fR
.ce
\fBMONTAGE: TABLEAU A RECUPERER DU LIVRE ROUGE, SANS CORRECTIONS.\fR
.ce
blanc
.ce
\fBH.T. [T2.32]\fR
.ce
TABLE\ 2/O.32
.ps 9
.vs 11
.nr VS 11
.nr PS 9
.TS
center box;
lw(36p) | lw(48p) | cw(132p) .
Subroutines
_
.TE
.TS
cw(36p) | lw(48p) | cw(12p) | cw(18p) | cw(12p) | lw(18p) sw(12p) sw(18p) sw(12p) sw(18p) sw(12p) , ^ | c | c | c | c | c | c | c | c | c | l.
Mains routines Monophonic 1 2 3 Stereophonic
1 2 3 4 5 6 7 8 9
_
.T&
cw(84p) | cw(12p) | cw(18p) | cw(12p) | cw(18p) | cw(12p) | cw(18p) | cw(12p) | cw(18p) | cw(12p) .
Quality criteria \fIs\fR \fIa\fR {
\fIb\fR
\fIc\fR
\fId\fR
} \fIe\fR \fIa\fR \fIf\fR {
\fIb\fR
\fIc\fR
\fId\fR
} \fIe\fR \fIg\fR \fIh\fR \fIi\fR
_
.TE
.nr PS 9
.RT
.ad r
\fBTable\ A\(hy1/O.31 [T1.31], p.\fR
.sp 1P
.RT
.ad b
.RT
.LP
.bp
.ce 1000
APPENDIX\ I
.ce 0
.ce 1000
(to Recommendation O.31)
.sp 9p
.RT
.ce 0
.ce 1000
\fBExample of the record of measurements made by a tipical\fR \fB\fBmodel\fR
.sp 1P
.RT
.ce 0
.ce 1000
\fBof the automatic measuring equipment\fR
.ce 0
.LP
.rs
.sp 26P
.ad r
\fBFigure I, p.\fR
.sp 1P
.RT
.ad b
.RT
.sp 2P
.LP
\fBReferences\fR
.sp 1P
.RT
.LP
[1]
CCITT Recommendation \fIDefinition and duration of the line\(hyup\fR
\fIperiod and the preparatory period\fR , Vol.\ IV, Rec.\ N.4.
.LP
[2]
CCITT Recommendation \fIMeasurements to be made during the line\(hyup\fR
\fIperiod that precedes a sound\(hyprogramme transmission\fR ,
Vol.\ IV, Rec.\ N.12.
.LP
[3]
CCITT Recommendation \fIMeasurements to be made by the broadcasting\fR
\fIorganizations during the preparatory period\fR ,
Vol.\ IV, Rec.\ N.13.
.LP
[4]
CCITT Recommendation \fILimits and procedures for the lining\(hyup\fR
\fIof a sound\(hyprogramme circuit\fR , Vol.\ IV, Rec.\ N.21.
.LP
[5]
CCITT Recommendation \fIMeasurements to be made by the broadcasting\fR
\fIorganizations during the preparatory period\fR ,
Vol.\ IV, Rec.\ N.13, Note.
.LP
[6]
CCIR Recommendation \fIMeasurement of audio\(hyfrequency noise in\fR
\fIsound broadcasting\fR , Vol.\ X, Rec.\ 468, ITU, Geneva,\ 1986.
.bp
.sp 2P
.LP
\fBRecommendation\ O.32\fR
.RT
.sp 2P
.ce 1000
\fBAUTOMATIC\ MEASURING\ EQUIPMENT\ FOR\fR
.EF '% Fascicle\ IV.4\ \(em\ Rec.\ O.32''
.OF '''Fascicle\ IV.4\ \(em\ Rec.\ O.32 %'
.ce 0
.sp 1P
.ce 1000
\fBSTEREOPHONIC\ PAIRS\ OF\ SOUND\(hyPROGRAMME\ CIRCUITS\fR
.ce 0
.sp 1P
.ce 1000
\fI(Geneva, 1972)\fR
.sp 9p
.RT
.ce 0
.sp 1P
.LP
\fB1\fR \fBGeneral\fR
.sp 1P
.RT
.PP
An equipment designed in accordance with this Recommendation is
intended for use on stereophonic pairs of sound\(hyprogramme circuits. The
equipment is very similar to the equipment specified in Recommendation\ O.31.
The stereophonic and monophonic equipments are compatible for the testing of
monophonic sound\(hyprogramme circuits.
.PP
The differences between the monophonic and the stereophonic equipment are
as follows:
.PP
The monophonic equipment (Recommendation\ O.31) measures 5\ different
parameters in 136\ seconds; the stereophonic set measures the same 5\ parameters
in channels\ A and\ B of the stereophonic pair; in addition it measures
the level and phase difference between channels\ A and\ B, and the crosstalk
at three
specified frequencies between the two channels. The overall time for the
stereophonic measurements therefore amounts to approximately\ 371\ seconds.
.RT
.sp 2P
.LP
\fB2\fR \fBQuality criteria and measuring routines\fR
.sp 1P
.RT
.sp 1P
.LP
2.1
\fIQuality criteria to be checked\fR
.sp 9p
.RT
.PP
Table 1/O.32 gives the various quality criteria, designated by the letters\
\fIa\fR to\ \fIi\fR , including the criteria of Recommendation\ O.31.
.RT
.sp 1P
.LP
2.2
\fIMain routines\fR
.sp 9p
.RT
.PP
The measuring programmes for monophonic and for stereophonic
circuits can be chosen as main routines, the monophonic programme being in
accordance with the complete measuring programme of Recommendation\ O.31.
.PP
Each main routine consists of the subroutines shown in Table\ 2/O.32
which can be chosen individually (in subroutine\ 1, \fIs\fR \ is the station
coding
of the sending unit).
.RT
.sp 2P
.LP
2.3
\fISubroutines\fR
.sp 1P
.RT
.sp 1P
.LP
2.3.1
\fISubroutine\ 1\fR | station coding and monophonic quality
criterion\ \fIa\fR )
.sp 9p
.RT
.PP
A station coding signal is sent in accordance with \(sc\ 3.1.2\ below
followed by measurement of the level of channel\ A at the reference
frequency.
.RT
.sp 1P
.LP
2.3.2
\fISubroutine\ 2\fR | monophonic criteria\ \fIb\fR , \fIc\fR , and\ \fId\fR )
.sp 9p
.RT
.PP
Subroutine\ 2 comprises three\ steps:
.RT
.LP
1)
measurement of the weighted and unweighted noise level of
channel\ A (\fIb\fR\d1\u, and \fIb\fR\d2\u);
.LP
2)
nonlinear distortion of channel\ A measured selectively as
harmonic distortion of the\ 2nd and\ 3rd order and as a difference tone
distortion of the\ 3rd order (\fIc\fR\d1\u\ . | | \ \fIc\fR\d5\u);
.LP
3)
compandor functioning test of channel\ A\ (\fId\fR ).
.sp 1P
.LP
2.3.3
\fISubroutine\ 3\fR | monophonic criterion\ \fIe\fR )
.sp 9p
.RT
.PP
Measurement of the level/frequency response of channel\ A.
.RT
.sp 1P
.LP
2.3.4
\fISubroutine\ 4\fR | monophonic quality criterion\ \fIa\fR and
stereophonic quality criterion\ \fIf\fR )
.sp 9p
.RT
.PP
Subroutine\ 4 comprises 3\ steps: the first step checks received level
at the reference frequency in channel\ B (monophonic criterion corresponding
to subroutine\ 1). The second and third steps are used to determine the
sum\ (
\fIf\fR\d1\u) and difference (
\fIf\fR\d2\u)\ levels of
channels\ A and\ B. Both measured values serve for the polarity check and the
approximate assessment of phase differences exceeding the range fixed in
subroutine\ 8 (stereophonic criterion\ \fIh\fR ). In the case of negligible
level and phase differences between channels\ A and\ B, the resulting sum
level must exceed the received level at the reference frequency on the
individual channel by 6\ dB and in this case the difference level is so
small that it is not indicated. If the channels are of opposite polarity
(\(*D\(*F\ =\ 180\(de), the sum level and the
difference level behave inversely.
.PP
Large phase differences can be estimated from
Table\ 3/O.32.
.bp
.RT
.ce
\fBH.T. [T1.32]\fR
.ce
TABLE\ 1/O.32
.ce
\fBMeasurement of quality criteria\fR
.ce
\fIa\fR
.ce
\fBto\fR
.ce
\fIi\fR
.ce
\fB, sender\fR
.ce
\fBand receiver requirements\fR
.ce
\fBMONTAGE: TABLEAU A RECUPERER DU LIVRE ROUGE, SANS CORRECTIONS.\fR
.ce
blanc
.ce
\fBH.T. [T2.32]\fR
.ce
TABLE\ 2/O.32
.ps 9
.vs 11
.nr VS 11
.nr PS 9
.TS
center box;
lw(36p) | lw(48p) | cw(132p) .
Subroutines
_
.TE
.TS
center box ;
cw(36p) | lw(48p) | cw(12p) | cw(18p) | cw(12p) | lw(18p) sw(12p) sw(18p) sw(12p) sw(18p) sw(12p) , ^ | c | c | c | c | c | c | c | c | c | l.
Mains routines Monophonic 1 2 3 Stereophonic
1 2 3 4 5 6 7 8 9
_
.T&
cw(84p) | cw(12p) | cw(18p) | cw(12p) | cw(18p) | cw(12p) | cw(18p) | cw(12p) | cw(18p) | cw(12p) .
Quality criteria \fIs\fR \fIa\fR {
\fIb\fR
\fIc\fR
\fId\fR
} \fIe\fR \fIa\fR \fIf\fR {
\fIb\fR
\fIc\fR
\fId\fR
} \fIe\fR \fIg\fR \fIh\fR \fIi\fR
_
.TE
.nr PS 9
.RT
.ad r
\fBTable\ 1/O.32 [T1.32], p.\fR
.sp 1P
.RT
.ad b
.RT
.ce
\fBH.T. [T2.32]\fR
.ce
TABLE\ 2/O.32
.ps 9
.vs 11
.nr VS 11
.nr PS 9
.TS
center box;
lw(36p) | lw(48p) | cw(132p) .
Subroutines
_
.TE
.TS
center box ;
cw(36p) | lw(48p) | cw(12p) | cw(18p) | cw(12p) | lw(18p) sw(12p) sw(18p) sw(12p) sw(18p) sw(12p) , ^ | c | c | c | c | c | c | c | c | c | l.
Mains routines Monophonic 1 2 3 Stereophonic
1 2 3 4 5 6 7 8 9
_
.T&
cw(84p) | cw(12p) | cw(18p) | cw(12p) | cw(18p) | cw(12p) | cw(18p) | cw(12p) | cw(18p) | cw(12p) .
Quality criteria \fIs\fR \fIa\fR {
\fIb\fR
\fIc\fR
\fId\fR
} \fIe\fR \fIa\fR \fIf\fR {
\fIb\fR
\fIc\fR
\fId\fR
} \fIe\fR \fIg\fR \fIh\fR \fIi\fR
_
.TE
.nr PS 9
.RT
.ad r
\fBTable\ 2/O.32 [T2.32], p.\fR
.sp 1P
.RT
.ad b
.RT
.LP
.bp
.ce
\fBH.T. [T3.32]\fR
.ce
TABLE\ 3/O.32
.ps 9
.vs 11
.nr VS 11
.nr PS 9
.TS
center box;
cw(60p) | cw(66p) | cw(54p) .
Sum level \(*D\fIn\fI (dB) {
Difference level
\(*D\fIn\fI
(dB)
} Phase difference \(*D\(*F
_
.T&
cw(60p) | cw(66p) | cw(54p) .
+6.0 \(em\(if | \ \ 0/360\uo\d
.T&
cw(60p) | cw(66p) | cw(54p) .
+5.7 \(em5.7 \ 30/330\uo\d
.T&
cw(60p) | cw(66p) | cw(54p) .
+4.8 \ 0 | \ 60/300\uo\d
.T&
cw(60p) | cw(66p) | cw(54p) .
+3.0 +3.0 \ 90/270\uo\d
.T&
cw(60p) | cw(66p) | cw(54p) .
\ 0 | +4.8 120/240\uo\d
.T&
cw(60p) | cw(66p) | cw(54p) .
\(em5.7 +5.7 150/210\uo\d
.T&
cw(60p) | cw(66p) | cw(54p) .
\(em\(if | +6.0 180\uo\d
.TE
.LP
\fINote\fR
\ \(em
The above table is derived from the following formulae:
.LP
\(*D\fIn\fI
\ =\ 3\ dB\ +\ 10\ log\ [1\ \(em\ cos\ (180\ \(em\ \(*D\(*F)]
.LP
\(*D\fIn\fI
\ =\ 3\ dB\ +\ 10\ log\ (1\ \(em\ cos\ \(*D\(*F)
.nr PS 9
.RT
.ad r
\fBTable 3/O.32 [T3.32], p.\fR
.sp 1P
.RT
.ad b
.RT
.sp 1P
.LP
2.3.5
\fISubroutine\ 5\fR | monophonic criteria \fIb\fR , \fIc\fR and \fId\fR )
.sp 9p
.RT
.PP
Measurement of weighted and unweighted noise levels and nonlinear distortion
and compandor functioning test, as specified in subroutine\ 2, but
for channel\ B.
.RT
.sp 1P
.LP
2.3.6
\fISubroutine\ 6\fR | monophonic criterion \fIe\fR )
.sp 9p
.RT
.PP
Measurement of the level/frequency response of channel\ B.
(Corresponds to subroutine\ 3 for channel\ A.)
.RT
.sp 1P
.LP
2.3.7
\fISubroutine\ 7\fR | stereophonic criterion \fIg\fR )
.sp 9p
.RT
.PP
The level difference between channels\ A and\ B, determined as a
function of the frequency.
.RT
.sp 1P
.LP
2.3.8
\fISubroutine\ 8\fR | stereophonic criterion\ \fIh\fR )
.sp 9p
.RT
.PP
The phase difference between channels\ A and\ B, measured as a
function of the frequency.
.RT
.sp 1P
.LP
2.3.9
\fISubroutine\ 9\fR | stereophonic criterion\ \fIi\fR )
.sp 9p
.RT
.PP
The signal\(hyto\(hycrosstalk ratio between channels\ A and\ B at
frequencies of 180, 1600 and 9000\ Hz.
.RT
.sp 2P
.LP
\fB3\fR \fBSpecifications\fR
.sp 1P
.RT
.PP
The following specifications for carrying out the measurements
of the monophonic quality criteria \fIa\fR to \fIe\fR are identical with
those laid
down in Recommendation\ O.31 for the monophonic version of such equipment.
.RT
.sp 2P
.LP
3.1
\fISending unit\fR
.sp 1P
.RT
.sp 1P
.LP
3.1.1
\fIStart, stop and time base for synchronization and selection\fR
\fIof measuring mode\fR
.sp 9p
.RT
.PP
By means of a locking press\(hybutton in the sending unit the
measuring programme for single or permanent mode of operation can be started.
The timing of the measuring programme is controlled by a pulse generator.
The smallest time base that can be programmed is fixed at 1.33\ second.
The
synchronizing frequency related to this time base is 0.75\ Hz and has to
be kept within \(+- | %. A second press\(hybutton offers the possibility
of stopping the
measuring programme. By the activation of this press\(hybutton a means
is provided whereby the locking mechanism of the start press\(hybutton
for permanent operation is simultaneously released. Start, synchronization
and stop of the receiving
unit are triggered by coded pulses (1.3\ kHz at \(em12\ dBm0).
.bp
.PP
Every subroutine is preceded by coded pulses which serve as a start
signal. By means of a special stop signal which is triggered by pressing the
stop button, the progress of the measuring programme can be interrupted
at any time and another programme, selected with the aid of a switch, can
be started instead. Operating the stop button will also reset the time
pulse generator
to the starting condition.
.PP
The start and stop signals consist of four pulses whose duration can be
fixed at 60\ ms (value\ O) or 120\ ms (value\ L) by means of digital coding.
The time between the beginning of every pulse within the coded signal is
240\ ms.
.PP
The coding of the pulses is as follows:
.RT
.LP
a)
Start signals for:
.LP
\(em
Subroutine\ 1:\ OOOL
.LP
\(em
Subroutine\ 2:\ OOLO
.LP
\(em
Subroutine\ 3:\ OLOO
.LP
\(em
Subroutine\ 4:\ LOOO
.LP
\(em
Subroutine\ 5:\ OOLL
.LP
\(em
Subroutine\ 6:\ OLLO
.LP
\(em
Subroutine\ 7:\ LLOO
.LP
\(em
Subroutine\ 8:\ OLOL
.LP
\(em
Subroutine\ 9:\ LOLO
.LP
b)
Stop signal:\ LLLL
.PP
The start signals are read from right to left, as is usual in the case
of digital codes, and are transmitted in the same time sequence.
.PP
The sending of the coded signal (duration 960\ ms) which is controlled
by the time pulse generator must be delayed 370\ ms (in order to comply
with
the time pulse duration of 1330\ ms).
.RT
.sp 1P
.LP
3.1.2
\fIStation coding\fR
.sp 9p
.RT
.PP
The measuring programme is preceded by the code of the sending
station using the Morse alphabet. For this purpose, 19\ timing intervals are
allocated. The station code is sent by keying a 0.8\(hykHz tone between
a level of \(em32\ dBm0 and the reference test level. The duration of Morse
dots and dashes
shall be about 10% and 35% respectively, of one timing interval.
.RT
.sp 1P
.LP
3.1.3
\fITest level for the\fR
\fImeasurements of level at the\fR \fIreference frequency\fR \fIand\fR
\fIlevel/frequency response\fR
.sp 9p
.RT
.PP
The test level sent for level measurements at the reference
frequency (0.8\ kHz) and for the measurements of level/frequency response
should be \(em12\ dBm0 (see Recommendation\ N.21\ [2]). The measurements
of level/frequency response are to be carried out with the aid of a sweep
generator comprising the frequency range from 0.03 to 16\ kHz. Each octave\
\(em beginning at 0.05\ kHz\ \(em is marked by short pulses (1.3\ kHz/\(em12\
dBm0 from 50 to 100\ ms duration). The
speed of this sequence of operations for the frequency range from
30\(hy16 | 00\ Hz which covers 9.06\ octaves should be 5\ seconds/octave
so that
the recording device dealt with in \(sc\ 3.2.9 below records one octave
over 10\ mm and 3.3\ mm respectively.
.RT
.sp 1P
.LP
3.1.4
\fITest level sent for nonlinear distortion\fR \fImeasurements\fR
.FS
It shall be possible for the signal sent for the
measurement of nonlinearity distortion to be included in or omitted from the
test cycle at will (for example, under control of a switch). Whether or
not the nonlinearity distortion measurement is admissible must be determined
for
each circuit by the user of the equipment, and in a manner ensuring that the
prescriptions of Recommendation\ N.21\ [2] are respected.
.FE
.sp 9p
.RT
.PP
The sent level of the test frequencies corresponds to the peak
programme level (see the Recommendation cited in\ [3]), that is, the single
tones for the nonlinear distortion measurements lead to the same peak loading
as the double tone for the difference tone factor measurements (single
tone of +9\ dBm0, equivalent to 2.2\ V\dr\\d.\\dm\\d.\\ds\\d.\u\ =\ 3.1\
V\dp\\d0\uand
double tone each of +3\ dBm0, equivalent
.bp
.PP
to
2\ \(mu\ 1.1\ V\dr\\d.\\dm\\d.\\ds\\d.\u= 2\ \(mu\ 1.55\ V\dp\\d0\u= 3.1\
V\dp\\d0\ureferred to a zero relative level point). In order to avoid overload
of
carrier\(hyfrequency transmission systems, only frequencies below 2\ kHz (with
regard to circuits equipped with pre\(hy and de\(hyemphasis techniques)
are applied and the duration of transmission is automatically reduced to
the length of a
single timing pulse
.FS
Other methods are under study by the CMTT.
.FE
. The
following test frequencies should be used:
.RT
.LP
a)
\fIFor the measurement of nonlinear distortion in the lower\fR \fIaudio\(hyfrequency
range\fR
.LP
\fIc\fR\d1\u= 0.09 kHz/+9 dBm0 for the \fIk\fR\d2\u\(hymeasurement,
.LP
\fIc\fR\d2\u= 0.06 kHz/+9 dBm0 for the \fIk\fR\d3\u\(hymeasurement.
.LP
b)
\fIFor the measurement of nonlinear distortion in the\fR \fIcarrier\(hyfrequency
range of a frequency division multiplex\fR \fIchannel\fR
.LP
\fIc\fR\d3\u= 0.8\ kHz/+3\ dBm0 and 1.42\ kHz/+3\ dBm0 for the
\fId\fR\d3\u\(hymeasurement.
.LP
c)
\fIFor the measurement of nonlinear distortion in the medium\fR \fIaudio\(hyfrequency
range\fR
.LP
\fIc\fR\d4\u= 0.8\ kHz/+9\ dBm0 for the \fIk\fR\d2\u\(hymeasurement,
.LP
\fIc\fR\d5\u= 0.533\ kHz/+9\ dBm0 for the \fIk\fR\d3\u\(hymeasurement.
.sp 1P
.LP
3.1.5
\fISignal sent for\fR
\fIcompandor functioning test\fR |
.FS
This
test is intended for provisional use. A change will be
necessary when, after further study, the CCITT issues Recommendations for
compandors and appropriate methods of their testing.
.FE
.sp 9p
.RT
.PP
In order to detect a noncomplementary behaviour of regulating
amplifiers in compandors a 0.8\(hykHz signal is injected, the level of which is
switched between the values +6, \(em6, +6\ dBm0 for three consecutive timing
intervals.
.RT
.sp 1P
.LP
3.1.6
\fICrosstalk\fR \fIbetween channels\ A and\ B\fR
.sp 9p
.RT
.PP
The signal\(hyto\(hycrosstalk ratio between channels\ A and\ B is measured
at the frequencies 180, 1600 and 9000\ Hz. The sent level should be
\(em12\ dBm0.
.RT
.sp 1P
.LP
3.1.7
\fIRemote control of the sending unit\fR
.sp 9p
.RT
.PP
Provision should be made for sending up to 16 command signals.
These signals may be applied to the sending equipment in either binary
code or by applying earth to 16 signal paths. In the case of binary coding
for
starting the monophonic or stereophonic main routine, the coded signals
LOOL or LLLO respectively should be used in addition to the start signals
given
under \(sc\ 3.1.1\ above.
.RT
.sp 2P
.LP
3.2
\fIReceiving unit\fR
.sp 1P
.RT
.sp 1P
.LP
3.2.1
\fIStart, stop and synchronization\fR
.sp 9p
.RT
.PP
In the receiving unit the coded pulses must be detected and
separated by means of a selective process. A guard circuit similar to the
one normally used for signal receivers is required to protect against false
operation. In combination with the above\(hymentioned guard circuit the
4\(hybit code chosen offers a highly reliable protection against the possibility
that the
starting mechanism might be activated by sound\(hyprogramme signals. Thus, the
receiving unit can remain continuously connected to a sound\(hyprogramme
circuit and can record the measuring programme without intervention by
an operator.
.PP
The timing schedule must be in conformity with the requirements
specified for the sending unit (see \(sc\ 3.1.1).
.PP
The time pulse generator shall be triggered after the reception of the
start signal. Reception of the stop signal shall cause the time pulse generator
to be reset to the starting condition.
.bp
.RT
.sp 1P
.LP
3.2.2
\fIMeasuring ranges\fR
.sp 9p
.RT
.PP
The measuring device should have a logarithmic characteristic, and a linear
measuring range of \(+- | 0\ dB referred to the respective centre\(hyof\(hyrange
should be provided.
.PP
For the particular measuring function the centres\(hyof\(hyrange as
indicated in Table\ 1/O.32 should be provided.
.RT
.sp 1P
.LP
3.2.3
\fINoise measurements\fR
.sp 9p
.RT
.PP
The quality criteria \fIb\fR\d1\uand \fIb\fR\d2\u(weighted and unweighted
noise measurements) are measured in a quasi\(hypeak mode. In this case,
the
dynamic properties of the rectifier circuitry and the network for weighted
noise measurement (\fIb\fR\d1\u) should meet the requirements of CCIR
Recommendation\ 468\ [1].
.RT
.sp 1P
.LP
3.2.4
\fIProvision of filters and their characteristics\fR
.sp 9p
.RT
.PP
Two bandpass filters should be provided for selecting the nonlinear distortion
products, one for 0.18\ kHz and the other for 1.6\ kHz. They should be
used as follows:
.RT
.LP
\fI0.18\(hykHz filter\fR
.LP
\(em
for \fIk\fR\d2\u\(hymeasurement of 0.09 kHz (\fIc\fR\d1\u),
.LP
\(em
for \fIk\fR\d3\u\(hymeasurement of 0.06 kHz (\fIc\fR\d2\u),
.LP
\(em
for \fId\fR\d3\u\(hymeasurement of 0.8/1.42 kHz (\fIc\fR\d3\u);
.LP
\fI1.6\(hykHz filter\fR
.LP
\(em
for \fIk\fR\d2\u\(hymeasurement of 0.8 kHz (\fIc\fR\d4\u),
.LP
\(em
for \fIk\fR\d3\u\(hymeasurement of 0.533 kHz (\fIc\fR\d5\u).
.PP
With the 0.18\(hykHz filter only the lower \fId\fR\d3\u\(hyproduct
(2 \(mu 0.8\ kHz\ \(em1.42\ kHz = 0.18\ kHz) is measured. The measurement
of the upper
\fId\fR\d3\u\(hyproduct at 2.04\ kHz (= 2\ \(mu\ 1.42\ kHz\ \(em\ 0.8\
kHz) is not made. To
compensate for this, two\ times the lower \fId\fR\d3\u\(hyproduct at 0.18\
kHz is taken.
.PP
The bandpass filters should meet the following selectivity
requirements:
.RT
.LP
\(em
passband defined by insertion loss values less than\ 1\ dB:
.LP
0.18\ kHz\ filter:\ \(+- | 3\ Hz\ \(rt
.LP
1.6\ \ kHz\ filter:\ \(+- | 4\ Hz\ \(rb
\(rk\ \ referred to
centre frequency;
.LP
\(em
rejection frequency range defined by insertion loss values
greater than 70\ dB:
.LP
0.18\ kHz\ filter:\ < | .09\ kHz and > | .36\ kHz,
.LP
1.6\ \ kHz\ filter:\ < | .8\ \ kHz and > | .2\ \ kHz.
.sp 1P
.LP
3.2.5
\fIMeasurement of the phase difference\fR \fIbetween channels\ A\fR
\fIand\ B\fR
.sp 9p
.RT
.PP
The phase difference between channels\ A and\ B is measured as a
function of the frequency. For this purpose, a phase discriminator is
required which is independent of the level difference between the two channels.
Because of the chosen linear scale of 5\(de/cm and the recommended recording
width, the measurement range is limited to 0\(hy50\(de. Larger phase
differences can be estimated from the stereophonic criterion \fIf\fR of
subroutine\ 4.
.RT
.sp 1P
.LP
3.2.6
\fIMeasurement of crosstalk\fR \fIbetween channels\ A and\ B\fR
.sp 9p
.RT
.PP
The crosstalk ratio between channels\ A and\ B at the measuring
frequencies of 180, 1600 and 9000\ Hz is measured selectively. The filters
for the first two frequencies may be the same as those used for the nonlinearity
measurements in subroutines\ 2 and\ 5.
.PP
One additional filter is required for 9\ kHz.
.PP
This bandpass filter should meet the following selectivity
requirements:
.RT
.LP
\(em
passband defined by insertion loss values of
< | \ dB:\ \(+- | .8\ kHz referred to the centre frequency;
.LP
\(em
rejection frequency range defined by insertion loss values of > | 4\
dB:\ < | .5\ kHz and > | 8\ kHz referred to the centre frequency.
.PP
The measurable signal\(hyto\(hycrosstalk ratio is confined to the
critical range between 30 and 50\ dB.
.bp
.sp 1P
.LP
3.2.7
\fIAdditional markers provided at digital receivers\fR
.sp 9p
.RT
.PP
Additional markers can be generated in the digital receiver as
required, by making use of the octave markers received from the sending
unit as a timing base.
.RT
.sp 1P
.LP
3.2.8
\fIProgramming of digital receivers\fR
.sp 9p
.RT
.PP
Where a digit receiver is used, it shall be possible to programme it so
as to check that the circuits tested meet the required tolerances.
.RT
.sp 1P
.LP
3.2.9
\fIRecording device\fR
.sp 9p
.RT
.PP
The transient response time of the recording device should not exceed 200\
ms. In connection with
the rectifier circuitry of the receiving unit for noise measurements the
requirements of CCIR Recommenda
tion\ 468\ [1] should
be fulfilled.
.PP
Paper width and speed may be chosen according to national standards. The
following values have proved to be practicable:
.RT
.LP
\(em
Paper width 100\ mm.
.LP
This value yields (on the 20\(hydB level range) a level scale of
2\ dB/10\ mm.
.LP
\(em
Paper speed 2\ mm/s and 2/3\ mm/s.
.LP
These paper speeds should be manually adjustable.
.PP
In addition to the recording device it would be desirable to
provide appropriate access points for the use of an oscilloscope.
.sp 1P
.LP
3.3
\fISequence of operations in the programme\fR
.sp 9p
.RT
.PP
The sequence of operations of the stereophonic measuring programme including
all subroutines is shown in Annex\ A. The first and second time
pulse of each subroutine are provided for the start signal and a pause,
respectively.
.RT
.sp 2P
.LP
3.4
\fILong\(hyterm measurements of noise\fR
.sp 1P
.RT
.sp 1P
.LP
3.4.1
\fIAutomatic measurements\fR
.sp 9p
.RT
.PP
After completion of the monophonic or stereophonic main routines, automatic
long\(hyterm measurements of noise are performed on channel\ A and
channel\ B respectively, without initiation or control by the sending unit.
The sequence should be as follows:
\v'6p'
.RT
.LP
\fItime intervals\fR \fIreceiver programme\fR \fIchannel\fR \v'3p'
.LP
10
pause
.LP
60
weighted noise
\ \ |
.LP
20
unweighted noise
\ \ |
.LP
\ 2
pause
.LP
60
weighted noise
\ \ |
B
.LP
20
unweighted noise
\ \ |
B
.sp 1P
.LP
3.4.2
\fIManual measurements\fR
.sp 9p
.RT
.PP
In order to make measurements of weighted or unweighted noise
continuously for unspecified periods of time it must be possible to make the
timing mechanism inoperative. Where an analogue receiver is used, a manually
controlled switch should be provided, so that the centre\(hyof\(hyrange can be
changed by 10\ dB in either direction.
.bp
.RT
.sp 1P
.LP
3.5
\fIMatching characteristics\fR
.sp 9p
.RT
.PP
According to the lining\(hyup procedure for sound\(hyprogramme circuits
using the constant voltage method the following impedances are to be
provided:
.RT
.LP
\(em
output impedance of the sending unit < | 0\ ohms,
.LP
\(em
input impedance of the receiving unit > | 0\ kohms.
.PP
Both values may be changed by internal switching to 600\ ohms if, for the
lining\(hyup of the sound\(hyprogramme circuit, the impedance matching
method is applied. It should be possible to adjust the sending and receiving
units by means of a switch to the following relative levels:
.LP
+6\ dBr
=\ nominal value at the
repeater stations of Administrations;
.LP
\ 0\ dBr
.FS
For certain purposes a level of \(em3 dBr or lower
may be used.
.FE
=\ nominal value at the studios
of broadcasting organizations.
.sp 2P
.LP
3.6
\fIAccuracy of sending and receiving units\fR
.sp 1P
.RT
.sp 1P
.LP
3.6.1
\fISending unit\fR \v'3p'
.sp 9p
.RT
.LP
a)
\fIIndividual frequency oscillators\fR
.ad r
\(em
level tolerance
\(+- | .2\ dB
\v'4p'
.ad b
.RT
.ad r
\(em
frequency tolerance
< | .0%\ \
\v'4p'
.ad b
.RT
.ad r
\(em
harmonic distortion at 2\fIf\fR .PS 10
and 3\fIf\fR .PS 10
< | .1%\ \
\v'4p'
.ad b
.RT
.LP
b)
\fISweep frequency oscillator\fR .PS 10
.ad r
\(em
level tolerance at 0.8\ kHz
\(+- | .2\ dB
\v'4p'
.ad b
.RT
.ad r
\(em
level frequency response referred to 0.8\ kHz
\(+- | .2\ dB
\v'4p'
.ad b
.RT
.sp 1P
.LP
3.6.2
\fIReceiving unit\fR
.sp 9p
.RT
.PP
Tolerances, including recording device:
.RT
.ad r
\(em
mid\(hyscale value \(em12\ dBm0 and 0\ dBm0
\(+- | .3\ dB
\v'4p'
.ad b
.RT
.ad r
\(em
mid\(hyscale value \(em51\ dBm0 and \(em31\ dBm0
\(+- | .0\ dB
\v'4p'
.ad b
.RT
.PP
Operational stability should be reached within 15\ minutes of
switching on. As far as the details of the division of the tolerances are
concerned, reference is made to the values given in Supplement\ No.\ 3.1
at the end of this fascicle.
.PP
The tolerances may then be reduced by calibrating the sending and
receiving units when interconnected on a loop basis.
.RT
.LP
.sp 22
.bp
.ce 1000
ANNEX\ A
.ce 0
.ce 1000
(to Recommendation O.32)
.sp 9p
.RT
.ce 0
.ce
\fBH.T. [1T4.32]\fR
.ce
TABLE\ A\(hy1/O.32
.ce
\fBSequence of operations of stereophonic main routine\fR
.ce
\fBmeasuring programme\fR
.ce
\fBMONTAGE: TABLEAU A RECUPERER DU LIVRE ROUGE, SANS CORRECTIONS.\fR
.ce
blanc
.ce
\fBH.T. [2T4.32]\fR
.ce
TABLE\ A\(hy1/O.32 \fI(end)\fR
.ce
\fBMONTAGE: TABLEAU A RECUPERER DU LIVRE ROUGE, SANS CORRECTIONS.\fR
.ce
blanc
.ce
\fBH.T. [T1.33]\fR
.ce
\fBMeasurement sequence for monophonic sound\(hyprogramme circuits\fR
.ps 9
.vs 11
.nr VS 11
.nr PS 9
.TS
center box;
cw(30p) | cw(36p) sw(30p) | cw(108p) , ^ | c | c | c.
Time interval (seconds) Sending unit Programme number: 00
Frequency (Hz) Level (dBm0) Measuring function
_
.T&
lw(30p) | cw(36p) | cw(30p) | lw(108p) .
1 1650/1850 \(em12 {
Start/source/programme identification
}
_
.T&
lw(30p) | cw(36p) | cw(30p) | lw(108p) .
1 \ 1 | 20 \ \ 0 Received level
_
.T&
lw(30p) | cw(36p) | cw(30p) | lw(108p) , l | c | c | ^ .
1 \ 1 | 20 \(em12 Frequency response
1 \ \ | 40 \(em12
.T&
lw(30p) | cw(36p) | cw(30p) .
1 \ \ | 80 \(em12
_
.T&
lw(30p) | cw(36p) | cw(30p) .
1 \ \ | 00 \(em12
_
.T&
lw(30p) | cw(36p) | cw(30p) .
1 \ \ | 00 \(em12
_
.T&
lw(30p) | cw(36p) | cw(30p) .
1 \ \ | 20 \(em12
_
.T&
lw(30p) | cw(36p) | cw(30p) .
1 \ 1 | 00 \(em12
_
.T&
lw(30p) | cw(36p) | cw(30p) .
1 \ 3 | 00 \(em12
_
.T&
lw(30p) | cw(36p) | cw(30p) .
1 \ 5 | 00 \(em12
_
.T&
lw(30p) | cw(36p) | cw(30p) .
1 \ 6 | 00 \(em12
_
.T&
lw(30p) | cw(36p) | cw(30p) .
1 \ 9 | 00 \(em12
_
.T&
lw(30p) | cw(36p) | cw(30p) .
1 11 | 00 \(em12
_
.T&
lw(30p) | cw(36p) | cw(30p) .
1 13 | 00 \(em12
_
.T&
lw(30p) | cw(36p) | cw(30p) .
1 15 | 00 \(em12
.T&
lw(30p) | cw(36p) | cw(30p) | lw(108p) .
1 \ 1 | 20 \ +9 1 | ua\d\u)\d
.T&
cw(30p) | cw(36p) | lw(30p) | lw(108p) .
\(em \(em Total harmonic distortion 1
.T&
cw(30p) | cw(36p) | lw(30p) | lw(108p) .
\ \ | 60 \ +9
_
.T&
lw(30p) | cw(36p) | cw(30p) | lw(108p) .
1 \ \ | 20 \ +6 1
.T&
cw(30p) | cw(36p) | lw(30p) | lw(108p) .
\ \ | 20 \ \(em6 Compandor test 1
.T&
cw(30p) | cw(36p) | lw(30p) | lw(108p) .
\ \ | 20 \ +6
_
.T&
lw(30p) | cw(36p) | cw(30p) | lw(108p) .
8 \(em \(em Signal\(hyto\(hynoise ratio
.TE
.LP
\ua\d\u)\d\ Waiting interval.
.nr PS 9
.RT
.ad r
\fBTable A\(hy1/O.32 [1T4.32], p.\fR
.sp 1P
.RT
.ad b
.RT
.LP
.bp
.ce
\fBH.T. [2T4.32]\fR
.ce
TABLE\ A\(hy1/O.32 \fI(end)\fR
.ce
\fBMONTAGE: TABLEAU A RECUPERER DU LIVRE ROUGE, SANS CORRECTIONS.\fR
.ce
blanc
.ce
\fBH.T. [T1.33]\fR
.ce
\fBMeasurement sequence for monophonic sound\(hyprogramme circuits\fR
.ps 9
.vs 11
.nr VS 11
.nr PS 9
.TS
center box;
cw(30p) | cw(36p) sw(30p) | cw(108p) , ^ | c | c | c.
Time interval (seconds) Sending unit Programme number: 00
Frequency (Hz) Level (dBm0) Measuring function
_
.T&
lw(30p) | cw(36p) | cw(30p) | lw(108p) .
1 1650/1850 \(em12 {
Start/source/programme identification
}
_
.T&
lw(30p) | cw(36p) | cw(30p) | lw(108p) .
1 \ 1 | 20 \ \ 0 Received level
_
.T&
lw(30p) | cw(36p) | cw(30p) | lw(108p) , l | c | c | ^ .
1 \ 1 | 20 \(em12 Frequency response
1 \ \ | 40 \(em12
.T&
lw(30p) | cw(36p) | cw(30p) .
1 \ \ | 80 \(em12
_
.T&
lw(30p) | cw(36p) | cw(30p) .
1 \ \ | 00 \(em12
_
.T&
lw(30p) | cw(36p) | cw(30p) .
1 \ \ | 00 \(em12
_
.T&
lw(30p) | cw(36p) | cw(30p) .
1 \ \ | 20 \(em12
_
.T&
lw(30p) | cw(36p) | cw(30p) .
1 \ 1 | 00 \(em12
_
.T&
lw(30p) | cw(36p) | cw(30p) .
1 \ 3 | 00 \(em12
_
.T&
lw(30p) | cw(36p) | cw(30p) .
1 \ 5 | 00 \(em12
_
.T&
lw(30p) | cw(36p) | cw(30p) .
1 \ 6 | 00 \(em12
_
.T&
lw(30p) | cw(36p) | cw(30p) .
1 \ 9 | 00 \(em12
_
.T&
lw(30p) | cw(36p) | cw(30p) .
1 11 | 00 \(em12
_
.T&
lw(30p) | cw(36p) | cw(30p) .
1 13 | 00 \(em12
_
.T&
lw(30p) | cw(36p) | cw(30p) .
1 15 | 00 \(em12
.T&
lw(30p) | cw(36p) | cw(30p) | lw(108p) .
1 \ 1 | 20 \ +9 1 | ua\d\u)\d
.T&
cw(30p) | cw(36p) | lw(30p) | lw(108p) .
\(em \(em Total harmonic distortion 1
.T&
cw(30p) | cw(36p) | lw(30p) | lw(108p) .
\ \ | 60 \ +9
_
.T&
lw(30p) | cw(36p) | cw(30p) | lw(108p) .
1 \ \ | 20 \ +6 1
.T&
cw(30p) | cw(36p) | lw(30p) | lw(108p) .
\ \ | 20 \ \(em6 Compandor test 1
.T&
cw(30p) | cw(36p) | lw(30p) | lw(108p) .
\ \ | 20 \ +6
_
.T&
lw(30p) | cw(36p) | cw(30p) | lw(108p) .
8 \(em \(em Signal\(hyto\(hynoise ratio
.TE
.LP
\ua\d\u)\d\ Waiting interval.
.nr PS 9
.RT
.ad r
\fBTable\ A\(hy1/O.32 [2T4.32], p.\fR
.sp 1P
.RT
.ad b
.RT
.LP
.bp
.sp 2P
.LP
\fBReferences\fR
.sp 1P
.RT
.LP
[1]
CCIR Recommendation \fIMeasurement of audio\(hyfrequency noise in\fR
\fIsound broadcasting\fR , Vol.\ X, Rec.\ 468, ITU, Geneva,\ 1986.
.LP
[2]
CCITT Recommendation \fILimits and procedures for the lining\(hyup\fR
\fIof a sound\(hyprogramme circuit\fR , Vol.\ IV, Rec.\ N.21.
.LP
[3]
CCITT Recommendation \fIMeasurements to be made by the broadcasting\fR
\fIorganizations during the preparatory period\fR , Vol.\ IV, Rec.\ N.13,
Note.
\v'1P'
.sp 2P
.LP
\fBRecommendation\ O.33\fR
.RT
.sp 2P
.ce 1000
\fBAUTOMATIC\ EQUIPMENT\fR
.EF '% Fascicle\ IV.4\ \(em\ Rec.\ O.33''
.OF '''Fascicle\ IV.4\ \(em\ Rec.\ O.33 %'
.ce 0
.ce 1000
\fBFOR\ RAPIDLY\ MEASURING\ STEREOPHONIC\ PAIRS\fR
.ce 0
.sp 1P
.ce 1000
\fBAND\ MONOPHONIC\ SOUND\(hyPROGRAMME\ CIRCUITS,\ LINKS\ AND\ CONNECTIONS\fR
.ce 0
.sp 1P
.ce 1000
\fI(Malaga\(hyTorremolinos, 1984; amended at Melbourne, 1988)\fR
.sp 9p
.RT
.ce 0
.sp 1P
.LP
\fB1\fR \fBGeneral\fR
.sp 1P
.RT
.PP
An automatic measuring equipment for sound\(hyprogramme circuits must be
capable of rapidly measuring all relevant parameters necessary for checking
the quality of such circuits. The parameters to be measured and the facilities
that must be offered by the equipment are outlined in this specification
but
neither the measurement method nor the processing of the results are specified
in detail. Manufacturers are thus free to adopt any appropriate design
that
will fulfil the requirements of this specification. However, it is evident
that it would be advantageous to control the measurement sequence by stored
programs. The use of different measuring sequences, each suited to the
requirements of individual users and individual applications should be
possible.
.PP
It should be noted that the equipment will meet the requirements of
Recommendations\ N.12\ [1] and N.13\ [2]. However, measurement of every
parameter specified in Recommendations\ N.10\ [3], N.21\ [4] and N.23\
[5] is not possible, e.g.,\ group delay/frequency response.
.RT
.sp 2P
.LP
\fB2\fR \fBBasic design\fR
.sp 1P
.RT
.PP
The equipment shall consist of either two units, send and receive, or a
combined sending and receiving unit of modular construction permitting
a send\(hyonly or receive\(hyonly facility.
.PP
The measurement results should be made available by a direct display via
a storage mechanism to permit a long\(hyterm display of any measured
parameter.
.PP
The results of the measurements are not only to permit an immediate
decision by the staff in the field, but also to provide the basis for later
exact evaluation by the responsible transmission engineer. It is preferred
that the results be available also as a 110\(hy and 300\(hybaud ISO\(hy7
bit serial data
output\ [6] at a standard RS\ 232\(hyC\ [7] interface, selectable between
110 and
300\ bauds, or optionally, at a standard IEEE\ 488/IEC\ 625\ [8] interface.
.PP
In each case, the parameters measured must be clearly identified and the
source code given (see \(sc\ 2.1).
.PP
The equipment must be capable of measuring at least the following
parameters:
.RT
.LP
a)
received level (insertion gain);
.LP
b)
frequency/attenuation distortion (frequency response);
.LP
c)
harmonic distortion (nonlinear distortion);
.LP
d)
signal\(hyto\(hynoise ratio unweighted, and weighted in
accordance with CCIR Recommendation\ 468\ [9];
.LP
e)
compandor linearity;
.LP
f
)
programme modulated noise and expanded noise.
.PP
These parameters are further defined in \(sc\ 4.
.PP
In addition, the equipment must be capable of measuring in channels\ A
and\ B at least the following parameters:
.RT
.LP
g)
interchannel difference in gain and phase;
.LP
h)
interchannel crosstalk and circuit
transposition.
.bp
.PP
The stereo parameters are further defined in \(sc\ 5.
.PP
The physical design should preferably be such that this capability is provided
by user conversion of the monophonic equipment by the addition of
appropriate plug\(hyin units and, possibly, minor internal wiring changes.
.PP
The equipment will be required to send audio test signals at
amplitudes consistent with that required at the user's test point. Since the
nominal working levels vary from broadcasting organization to broadcasting
organization, and from PTT Administration to Administration, it is not
desirable to specify absolute levels. \*QTEST\*U level has therefore been
defined as the level 9\ dB below the maximum permitted level at the point
at which the measurement is made. TEST level corresponds to an absolute
value of 0\ dBm0 when measured at a point of zero relative level (0\ dBr)\
[10]. Manufacturers of
automatic measurement equipment should therefore choose to make TEST level
equal to a convenient level (e.g.\ 0\ dBm0).
.PP
At this fixed level, the send frequency amplitudes in the programme
measurement sequences will conform to the definitions for permitted maximum
level (+9\ dBm0s), alignment level (0\ dBm0s) and measuring level (\(em12\
dBm0s)
given in Recommendation\ N.15\ [11].
.PP
Switching should be provided so that TEST level may be set to +6\ dB, 0\
dB, or \(em3\ dB with respect to 0.775\ V\ r.m.s. This switch must be protected,
particularly for absolute values greater than\ 0\ dBm0, against unintentional
operation, e.g.\ by mounting it inside the instrument. Consideration should
also be given to providing \(em20\ dB with respect to\ 0.775\ V\ r.m.s.
.RT
.sp 1P
.LP
2.1
\fIStart/source/program identification\fR
.sp 9p
.RT
.PP
The measurement sequence will be chosen to suit the requirements of individual
applications. Defined measurement programs are annexed to this
Recommendation. The sequence of operations of the measurement program
together with the associated time units are shown.
.PP
The sequence of audio test signals is to be preceded by a
start/source/program identification signal which will:
.RT
.LP
\(em
instruct the receiving unit to start the measurement
sequence;
.LP
\(em
identify the source of the test signals;
.LP
\(em
indicate which of the stored measurement programs is to be
used.
.PP
The start/source/program identification signal using the
ISO\(hy7\ [6] code with one even parity bit and two stop bits, is to be sent by
frequency\(hyshift keying with a mark frequency of 1650\ Hz and a space
frequency of 1850\ Hz, at a transmission rate of 110\ bauds.
.PP
The message structure of the identification signal is formed by the
following order of characters:
.RT
.LP
\(em
Start of heading (character \*QSOH\*U);
.LP
\(em
Source identification (four alphanumeric characters);
.LP
\(em
Special signalling (one character);
.LP
\(em
Start of text (character \*QSTX\*U);
.LP
\(em
Measurement program identification (two numeric
characters\ 00\(hy99);
.LP
\(em
End of text (character \*QETX\*U).
.PP
The mark frequency shall be transmitted for at least 18 ms
(two bits) before the start bit of the SOH character.
.PP
The end of the second stop bit of the ETX character defines the start of
the measurement sequence.
.PP
The start/source/program identification signal shall be set at
12\ dB below TEST level.
.RT
.sp 1P
.LP
2.2
\fIModes of operation\fR
.sp 9p
.RT
.PP
It shall be possible to operate the equipment in automatic or
manual modes.
.RT
.sp 1P
.LP
2.2.1
\fIAutomatic mode\fR
.sp 9p
.RT
.PP
In the automatic mode, the sending unit shall cycle once through a complete
programmed test sequence on receipt of a start signal given either by a
push\(hybutton on the sending unit or by the momentary closing of a remote
pair of contacts. The receiver shall, on receipt of the identification
signal from the sending unit, cycle once through the complete programmed
measurement
sequence, storing and/or printing the results for subsequent
examination.
.bp
.RT
.sp 2P
.LP
2.2.2
\fIManual mode\fR
.sp 1P
.RT
.sp 1P
.LP
2.2.2.1
\fISending unit\fR
.sp 9p
.RT
.PP
In the manual mode, it shall be possible to cycle the sending unit through
the measuring sequence to any chosen test element, upon which the
appropriate test signal will be sent continuously. This mode should thus
permit the sending unit to operate with manual measuring equipment. It
shall also be possible to manually adjust the output signal to any frequency
within the range 40\ to\ 15 | 00\ Hz to a resolution of better than\ 5\
Hz. The output shall be
adjustable within the range \(em12\ dB to\ +15\ dB with respect to\ 0.775\
V r.m.s.
with a resolution of 0.2\ dB. The instrument shall indicate the output
frequency and level. A flashing warning light shall operate when the output
level exceeds 0.775\ V\ r.m.s.
.RT
.sp 1P
.LP
2.2.2.2
\fIReceiving unit\fR
.sp 9p
.RT
.PP
In the manual mode, it shall be possible to cycle the receiving
unit through the measuring sequence to any chosen parameter measurement to
permit the instrument to be used with manual sending equipment. It would be
advantageous to display the frequency of the incoming signal.
.RT
.sp 1P
.LP
2.2.3
\fIRemote control\fR
.sp 9p
.RT
.PP
Both the sending and receiving units should optionally offer
the possibility of remote control. This could be either the RS\ 232\(hyC\
[7] or
IEEE\ 488/IEC\ 625\ [8] interface.
.RT
.sp 2P
.LP
\fB3\fR \fBDesign and construction\fR
.sp 1P
.RT
.PP
It should be noted that the group delay encountered on long
circuits may lead to measurement error, particularly at low frequencies. The
design of measurement circuits should therefore be such that measurements
are made only after sufficient time has been allowed for the received waveform
to stabilize.
.PP
In general, the design and construction of the equipment shall conform
to national and international provisions, especially in relation to safety
requirements and protection against electric shock\ [12].
.RT
.sp 2P
.LP
\fB4\fR \fBParameters\fR
.sp 1P
.RT
.sp 1P
.LP
4.1
\fIReceived level\fR \fI(insertion gain)\fR
.sp 9p
.RT
.PP
1020 Hz is sent at TEST level; the received level shall be measured and
the result expressed in dB with reference to TEST level.
.RT
.sp 1P
.LP
4.2
\fIFrequency/attenuation distortion\fR \fI(frequency response)\fR
.sp 9p
.RT
.PP
The received level shall be measured at a number of discrete
frequencies. These frequencies are defined in the individual measurement
program. The sending level shall be 12\ dB below TEST level.
.PP
The results shall be displayed in dB relative to the received level at
1020\ Hz sent at 12\ dB below TEST level. It is not considered acceptable
to use the level received from the parameter in \(sc\ 4.1.
.RT
.sp 1P
.LP
4.3
\fIDistortion\fR
.sp 9p
.RT
.PP
Total harmonic distortion shall be measured at 60 Hz and 1020 Hz. Second
harmonic distortion, \fIk\fR\d2\u, shall be measured at 1020\ Hz. Third
harmonic distortion, \fIk\fR\d3\u, shall be measured at 60\ Hz.
.PP
The sending level shall be 9\ dB above TEST level. The receiving
instrument shall given an r.m.s. indication of the harmonic content and the
results shall be expressed in dB with respect to the received levels of the
fundamentals.
.PP
In order to avoid overload of carrier\(hyfrequency transmission systems,
the sending of test frequencies at the maximum permitted level should be
strictly in accordance with the prescriptions of Recommendation\ N.21\ [4].
Programs which include distortion measurements should therefore limit the
duration of transmission to a single time interval (1\ s) and a pause of at
least one interval must be allowed when successive distortion measurements
are to be made.
.PP
It shall be possible to insert the test cycle, the measurement of
nonlinearity distortion by either duplication of the stored programmes
with and without this measurement or by the use of a non\(hylocking switch.
.PP
\fINote\fR \ \(em\ The frequency of 1020 Hz has been chosen to avoid using a
sub\(hymultiple of a digital sampling rate.
.bp
.RT
.sp 1P
.LP
4.4
\fISignal\(hyto\(hynoise ratio\fR
.sp 9p
.RT
.PP
The sending unit shall suitably terminate the input to the circuit under
test and the receiving unit shall measure the highest quasi\(hypeak value,
either weighted or unweighted, over a period of eight seconds, consistent
with CCIR Recommendation\ 468\ [9]. The results shall be given in dB with
respect to the received TEST level at 1020\ Hz or at maximum permitted
level (+\ 9\ dBm0).
Selection of the weighted or unweighted characteristic and the level reference
shall be made by a manually operated switch on the receiving unit. The
switch shall be protected against unintentional operation and its position
shall be
indicated in the results. The normal position will correspond to the weighted
characteristic.
.RT
.sp 1P
.LP
4.5
\fICompandor linearity\fR
.sp 9p
.RT
.PP
820 Hz tone is sent during three consecutive time intervals, at
+6\ dB, \(em6\ dB and +6\ dB with respect to TEST level.
.PP
The receiving unit shall indicate the levels as received.
.RT
.sp 1P
.LP
4.6
\fIExpanded noise\fR
.sp 9p
.RT
.PP
The time interval used for the measurement of distortion at 60\ Hz may
also be used for the measurement of expanded noise. A high\(hypass filter
(f\d0\u\ \(=\ 400\ Hz, and \(>="\ 60\ dB/60\ Hz) is used to eliminate second
and third order harmonics. The remaining noise will be measured, either
weighted or unweighted, with a quasi\(hypeak response.
.RT
.sp 2P
.LP
\fB5\fR \fBStereo parameters\fR
.sp 1P
.RT
.sp 1P
.LP
5.1
\fIInterchannel difference in gain and phase\fR
.sp 9p
.RT
.PP
When the stereo modules are used, the equipment shall measure
simultaneously the difference in phase and level between the signals
present at its two inputs\ A and\ B. Measurements shall be made at all
frequencies specified for the measurement of frequency/attenuation distortion.
The instrument shall preferably indicate the polarity of the error.
.PP
The results shall be expressed in dB and degrees, taking the A channel
as reference.
.PP
Equipment not employing simultaneous measurement techniques may be
acceptable if it can be established that they provide results equivalent to
those obtained with simultaneous measurement. The caution given in
Recommendation\ N.21, \(sc\ 3.8\ [4], on avoiding certain frequencies should be
observed.
.RT
.sp 1P
.LP
5.2
\fIInterchannel crosstalk and circuit transposition\fR
.sp 9p
.RT
.PP
The transmitter shall send a tone at 2040 Hz at a level of 12 dB
below TEST level first from output\ A and then from output\ B, the unused
circuit being correctly terminated. The receiver shall measure the level
of the
unwanted signal in the terminated circuit.
.PP
The results shall be expressed in dB relative to the level in the used circuit.
.PP
The crosstalk test signal shall be used to test for circuit
transposition and an indication shall be given if the channels are
interchanged.
.RT
.sp 2P
.LP
\fB6\fR \fBEquipment characteristics \(em sending unit\fR \v'3p'
.sp 1P
.RT
.LP
Value does not take account of any transformer needed to comply
with
the requirements of Recommendation\ N.11\ [13] in regard to impedance and
balance with respect to earth.
.FE
Output impedance
:
<\ 10 ohms
.LP
Level error:
<\ 0.2 dB
.LP
Frequency error:
<\ 1%
.LP
Total harmonic distortion at maximum
output level,
.LP
(+21\ dB):
except 60 Hz and 1020
Hz
< 0.5%
.LP
at 60 Hz and 1020 Hz
< 0.1%
.LP
Weighted noise level output:
\(= \(em80 dBq0ps
.LP
Level difference between outputs A
and B:
< 0.2 dB
.LP
Phase difference between outputs A
and B:
< 2\(de
.bp
.LP
\fB7\fR \fBEquipment characteristics \(em receiving unit\fR
.sp 1P
.RT
.sp 2P
.LP
7.1
\fIInput impedance\fR |
\fI:\fR \ >\ 20\ kohms
.sp 1P
.RT
.sp 1P
.LP
7.2
\fIMinimum accuracy and range\fR
.sp 9p
.RT
.sp 1P
.LP
7.2.1
\fILevel measurements\fR \v'3p'
.sp 9p
.RT
.LP
\fIRange:\fR
.LP
Signal:\ +20 dB to \(em45 dB
.LP
Noise:\ \(em20 dB to \(em70 dB
.LP
with respect to 0.775 V r.m.s.
.LP
\fIError:\fR
.LP
\(= \(+- | .2 dB over the range +15 to \(em20 dB
.LP
\(= \(+- | .5 dB over the range \(em20 to \(em50 dB
.LP
\(= \(+- | .0 dB over the range \(em50 to \(em60 dB
.LP
\(= \(+- | .0 dB over the range \(em60 to \(em70 dB
.PP
\fINote\fR \ \(em\ Noise measurements are band limited to comply with the
frequency response given in Annex\ 1, CCIR Recommendation\ 468\ [9].
.LP
\fIFrequency range:\fR | 0 Hz\(hy50 kHz
.sp 1P
.LP
7.2.2
\fIDistortion measurement\fR \v'3p'
.sp 9p
.RT
.LP
\fIRange:\fR down to 0.3% (\(em50 dB)
.LP
\fIError:\fR (\(+- | \ dB)
.sp 1P
.LP
7.2.3
\fIPhase measurement\fR \v'3p'
.sp 9p
.RT
.LP
\fIRange:\fR \(+- | 80\(de
.LP
\fIError:\fR \(= +2\(de over whole range
.sp 2P
.LP
\fB8\fR \fBOperating equipment\fR
.sp 1P
.RT
.PP
The electrical performance requirements shall be met when operating at
the climatic conditions as specified in Recommendation\ O.3, \(sc\ 2.1.
.RT
.LP
.sp 17
.bp
.ce 1000
ANNEX\ A
.ce 0
.ce 1000
(to Recommendation O.33)
.sp 9p
.RT
.ce 0
.ce
\fBH.T. [T1.33]\fR
.ce
\fBMeasurement sequence for monophonic sound\(hyprogramme circuits\fR
.ps 9
.vs 11
.nr VS 11
.nr PS 9
.TS
center box;
cw(30p) | cw(36p) sw(30p) | cw(108p) , ^ | c | c | c.
Time interval (seconds) Sending unit Programme number: 00
Frequency (Hz) Level (dBm0) Measuring function
_
.T&
lw(30p) | cw(36p) | cw(30p) | lw(108p) .
1 1650/1850 \(em12 {
Start/source/programme identification
}
_
.T&
lw(30p) | cw(36p) | cw(30p) | lw(108p) .
1 \ 1 | 20 \ \ 0 Received level
_
.T&
lw(30p) | cw(36p) | cw(30p) | lw(108p) , l | c | c | ^ .
1 \ 1 | 20 \(em12 Frequency response
1 \ \ | 40 \(em12
.T&
lw(30p) | cw(36p) | cw(30p) .
1 \ \ | 80 \(em12
_
.T&
lw(30p) | cw(36p) | cw(30p) .
1 \ \ | 00 \(em12
_
.T&
lw(30p) | cw(36p) | cw(30p) .
1 \ \ | 00 \(em12
_
.T&
lw(30p) | cw(36p) | cw(30p) .
1 \ \ | 20 \(em12
_
.T&
lw(30p) | cw(36p) | cw(30p) .
1 \ 1 | 00 \(em12
_
.T&
lw(30p) | cw(36p) | cw(30p) .
1 \ 3 | 00 \(em12
_
.T&
lw(30p) | cw(36p) | cw(30p) .
1 \ 5 | 00 \(em12
_
.T&
lw(30p) | cw(36p) | cw(30p) .
1 \ 6 | 00 \(em12
_
.T&
lw(30p) | cw(36p) | cw(30p) .
1 \ 9 | 00 \(em12
_
.T&
lw(30p) | cw(36p) | cw(30p) .
1 11 | 00 \(em12
_
.T&
lw(30p) | cw(36p) | cw(30p) .
1 13 | 00 \(em12
_
.T&
lw(30p) | cw(36p) | cw(30p) .
1 15 | 00 \(em12
.T&
lw(30p) | cw(36p) | cw(30p) | lw(108p) .
1 \ 1 | 20 \ +9 1 | ua\d\u)\d
.T&
cw(30p) | cw(36p) | lw(30p) | lw(108p) .
\(em \(em Total harmonic distortion 1
.T&
cw(30p) | cw(36p) | lw(30p) | lw(108p) .
\ \ | 60 \ +9
_
.T&
lw(30p) | cw(36p) | cw(30p) | lw(108p) .
1 \ \ | 20 \ +6 1
.T&
cw(30p) | cw(36p) | lw(30p) | lw(108p) .
\ \ | 20 \ \(em6 Compandor test 1
.T&
cw(30p) | cw(36p) | lw(30p) | lw(108p) .
\ \ | 20 \ +6
_
.T&
lw(30p) | cw(36p) | cw(30p) | lw(108p) .
8 \(em \(em Signal\(hyto\(hynoise ratio
.TE
.LP
\ua\d\u)\d\ Waiting interval.
.nr PS 9
.RT
.ad r
\fBTable A/O.33 [T1.33], p.
.sp 1P
.RT
.ad b
.RT
.LP
.bp
.ce 1000
ANNEX\ B
.ce 0
.ce 1000
(to Recommendation O.33)
.sp 9p
.RT
.ce 0
.LP
\-v'1P'
.ce
\fBH.T. [T2.33]\fR
.ce
\fBMeasurement sequence for stereophonic pairs of sound\(hyprogramme
.ce
circuits\fR
.ps 9
.vs 11
.nr VS 11
.nr PS 9
.TS
center box;
cw(30p) | cw(66p) | cw(66p) | cw(66p) .
Time interval Channel A Sending unit Channel B Sending unit Programme number: 01
_
.T&
cw(30p) | cw(36p) | cw(30p) | cw(36p) | cw(30p) | cw(66p) .
Seconds Frequency (Hz) Level (dBm0) Frequency (Hz) Level (dBm0) Measuring function
_
.T&
lw(30p) | cw(36p) | cw(30p) | cw(36p) | cw(30p) | lw(66p) .
1 1650/1850 \(em12 \(em \(em {
Start/source/programme identification
}
_
.T&
lw(30p) | cw(36p) | cw(30p) | cw(36p) | cw(30p) | lw(66p) .
1 \ 1 | 20 \ \ 0 \ 1 | 20 \ \ 0 Received level
_
.T&
lw(30p) | cw(36p) | cw(30p) | cw(36p) | cw(30p) | lw(66p) , l | c | c | c | c | ^ .
1 \ 1 | 20 \(em12 \ 1 | 20 \(em12 {
Frequency response interchannel
Gain and phase
}
1 \ \ | 40 \(em12 \ \ | 40 \(em12
.T&
lw(30p) | cw(36p) | cw(30p) | cw(36p) | cw(30p) .
1 \ \ | 80 \(em12 \ \ | 80 \(em12
_
.T&
lw(30p) | cw(36p) | cw(30p) | cw(36p) | cw(30p) .
1 \ \ | 00 \(em12 \ \ | 00 \(em12
_
.T&
lw(30p) | cw(36p) | cw(30p) | cw(36p) | cw(30p) .
1 \ \ | 00 \(em12 \ \ | 00 \(em12
_
.T&
lw(30p) | cw(36p) | cw(30p) | cw(36p) | cw(30p) .
1 \ \ | 20 \(em12 \ \ | 20 \(em12
_
.T&
lw(30p) | cw(36p) | cw(30p) | cw(36p) | cw(30p) .
1 \ 1 | 00 \(em12 \ 1 | 00 \(em12
_
.T&
lw(30p) | cw(36p) | cw(30p) | cw(36p) | cw(30p) .
1 \ 3 | 00 \(em12 \ 3 | 00 \(em12
_
.T&
lw(30p) | cw(36p) | cw(30p) | cw(36p) | cw(30p) .
1 \ 5 | 00 \(em12 \ 5 | 00 \(em12
_
.T&
lw(30p) | cw(36p) | cw(30p) | cw(36p) | cw(30p) .
1 \ 6 | 00 \(em12 \ 6 | 00 \(em12
_
.T&
lw(30p) | cw(36p) | cw(30p) | cw(36p) | cw(30p) .
1 \ 9 | 00 \(em12 \ 9 | 00 \(em12
_
.T&
lw(30p) | cw(36p) | cw(30p) | cw(36p) | cw(30p) .
1 11 | 00 \(em12 11 | 00 \(em12
_
.T&
lw(30p) | cw(36p) | cw(30p) | cw(36p) | cw(30p) .
1 13 | 00 \(em12 13 | 00 \(em12
_
.T&
lw(30p) | cw(36p) | cw(30p) | cw(36p) | cw(30p) .
1 15 | 00 \(em12 15 | 00 \(em12
.T&
lw(30p) | lw(36p) | lw(30p) | lw(36p) | lw(30p) | lw(66p) .
.T&
lw(30p) | cw(36p) | cw(30p) | cw(36p) | cw(30p) | lw(66p) , l | c | c | c | c | ^ , l | c | c | c | c | ^ .
1 \ 1 | 20 \ +9 \ 1 | 20 \ +9 Total harmonic distortion
1 | ua\d\u)\d \(em \(em \(em \(em
1 \ \ | 60 \ +9 \ \ | 60 \ +9
_
.T&
lw(30p) | cw(36p) | cw(30p) | cw(36p) | cw(30p) | lw(66p) , l | c | c | c | c | ^ .
1 \ 2 | 40 \(em12 \(em \(em {
Crosstalk and circuit transposition
}
1 \(em \(em \ 2 | 40 \(em12
_
.T&
lw(30p) | cw(36p) | cw(30p) | cw(36p) | cw(30p) | lw(66p) , l | c | c | c | c | ^ , l | c | c | c | c | ^ .
1 \ \ | 20 \ +6 \ \ | 20 \ +6 Compandor test
1 \ \ | 20 \ \(em6 \ \ | 20 \ \(em6
1 \ \ | 20 \ +6 \ \ | 20 \ +6
_
.T&
lw(30p) | cw(36p) | cw(30p) | cw(36p) | cw(30p) | lw(66p) .
8 \(em \(em \(em \(em Signal\(hyto\(hynoise ratio
.TE
.LP
\ua\d\u)\d\ Waiting interval.
.nr PS 9
.RT
.ad r
\fBTable B/O.33 [T2.33], p.
.sp 1P
.RT
.ad b
.RT
.LP
.bp
.ce 1000
ANNEX\ C
.ce 0
.ce 1000
(to Recommendation O.33)
.sp 9p
.RT
.ce 0
.ce
\fBH.T. [T3.33]\fR
.ce
\fBMeasurement sequence for medium band sound\(hyprogramme circuits\fR
.ps 9
.vs 11
.nr VS 11
.nr PS 9
.TS
center box;
cw(30p) | cw(36p) sw(30p) | cw(108p) , ^ | c | c | c.
Time interval (Secs.) Sending unit Programme number: 02
Frequency (Hz) Level (dBm0) Measuring function
_
.T&
lw(30p) | cw(36p) | cw(30p) | lw(108p) .
1 1650/1850 \(em12 {
Start/source/programme identification
}
_
.T&
lw(30p) | cw(36p) | cw(30p) | lw(108p) .
1 \ 1 | 20 \ \ 0 Received level
_
.T&
lw(30p) | cw(36p) | cw(30p) | lw(108p) , l | c | c | ^ .
1 \ 1 | 20 \(em12 Frequency response
1 \ \ | 40 \(em12
.T&
lw(30p) | cw(36p) | cw(30p) .
1 \ \ | 80 \(em12
_
.T&
lw(30p) | cw(36p) | cw(30p) .
1 \ \ | 00 \(em12
_
.T&
lw(30p) | cw(36p) | cw(30p) .
1 \ \ | 00 \(em12
_
.T&
lw(30p) | cw(36p) | cw(30p) .
1 \ \ | 00 \(em12
_
.T&
lw(30p) | cw(36p) | cw(30p) .
1 \ \ | 20 \(em12
_
.T&
lw(30p) | cw(36p) | cw(30p) .
1 \ 1 | 00 \(em12
_
.T&
lw(30p) | cw(36p) | cw(30p) .
1 \ 3 | 00 \(em12
_
.T&
lw(30p) | cw(36p) | cw(30p) .
1 \ 5 | 00 \(em12
_
.T&
lw(30p) | cw(36p) | cw(30p) .
1 \ 6 | 00 \(em12
_
.T&
lw(30p) | cw(36p) | cw(30p) .
1 \ 7 | 00 \(em12
_
.T&
lw(30p) | cw(36p) | cw(30p) .
1 \ 8 | 20 \(em12
_
.T&
lw(30p) | cw(36p) | cw(30p) .
1 10 | 00 \(em12
.T&
lw(30p) | cw(36p) | cw(30p) | lw(108p) .
1 \ 1 | 20 \ +9 1
.T&
cw(30p) | cw(36p) | lw(30p) | lw(108p) .
\(em \(em Total harmonic distortion 1
.T&
cw(30p) | cw(36p) | lw(30p) | lw(108p) .
\ \ | 60 \ +9
_
.T&
lw(30p) | cw(36p) | cw(30p) | lw(108p) .
1 \ \ | 20 \ +6 1
.T&
cw(30p) | cw(36p) | lw(30p) | lw(108p) .
\ \ | 20 \ \(em6 Compandor test 1
.T&
cw(30p) | cw(36p) | lw(30p) | lw(108p) .
\ \ | 20 \ +6
_
.T&
lw(30p) | cw(36p) | cw(30p) | lw(108p) .
8 \(em \(em Signal\(hyto\(hynoise ratio
_
.TE
.nr PS 9
.RT
.ad r
\fBTable C/O.33 [T3.33], p.
.sp 1P
.RT
.ad b
.RT
.LP
.bp
.ce 1000
ANNEX\ D
.ce 0
.ce 1000
(to Recommendation O.33)
.sp 9p
.RT
.ce 0
.ce
\fBH.T. [T4.33]\fR
.ce
\fBMeasurement sequence for narrow\(hyband (telephone type)\fR
.ce
\fBcircuits\fR
.ps 9
.vs 11
.nr VS 11
.nr PS 9
.TS
center box;
cw(30p) | cw(36p) sw(30p) | cw(108p) , ^ | c | c | c.
Time interval (Secs.) Sending unit Programme number: 03
Frequency (Hz) Level (dBm0) Measuring function
_
.T&
lw(30p) | cw(36p) | cw(30p) | lw(108p) .
1 1650/1850 \(em12 {
Start/source/programme identification
}
_
.T&
lw(30p) | cw(36p) | cw(30p) | lw(108p) .
1 \ 1 | 20 \ \ 0 Received level
_
.T&
lw(30p) | cw(36p) | cw(30p) | lw(108p) , l | c | c | ^ .
1 \ 1 | 20 \(em10 Frequency response
1 \ \ | 00 \(em10
.T&
lw(30p) | cw(36p) | cw(30p) .
1 \ \ | 00 \(em10
_
.T&
lw(30p) | cw(36p) | cw(30p) .
1 \ \ | 00 \(em10
_
.T&
lw(30p) | cw(36p) | cw(30p) .
1 \ \ | 00 \(em10
_
.T&
lw(30p) | cw(36p) | cw(30p) .
1 \ \ | 20 \(em10
_
.T&
lw(30p) | cw(36p) | cw(30p) .
1 \ 1 | 00 \(em10
_
.T&
lw(30p) | cw(36p) | cw(30p) .
1 \ 1 | 00 \(em10
_
.T&
lw(30p) | cw(36p) | cw(30p) .
1 \ 2 | 00 \(em10
_
.T&
lw(30p) | cw(36p) | cw(30p) .
1 \ 2 | 00 \(em10
_
.T&
lw(30p) | cw(36p) | cw(30p) .
1 \ 2 | 00 \(em10
_
.T&
lw(30p) | cw(36p) | cw(30p) .
1 \ 3 | 00 \(em10
_
.T&
lw(30p) | cw(36p) | cw(30p) .
1 \ 3 | 00 \(em10
_
.T&
lw(30p) | cw(36p) | cw(30p) .
1 \ 3 | 00 \(em10
.T&
lw(30p) | cw(36p) | cw(30p) | lw(108p) .
1 \ 1 | 20 \ +9 Total harmonic distortion
_
.T&
lw(30p) | cw(36p) | cw(30p) | lw(108p) .
8 \(em \(em Signal\(hyto\(hynoise ratio
_
.TE
.nr PS 9
.RT
.ad r
\fBTable D/O.33 [T4.33], p.
.sp 1P
.RT
.ad b
.RT
.LP
.bp
.ce 1000
ANNEX\ E
.ce 0
.ce 1000
(to Recommendation O.33)
.sp 9p
.RT
.ce 0
.ce
\fBH.T. [T5.33]\fR
.ce
\fBMeasurement sequence for narrow\(hyband (telephone\(hytype) circuits\fR
.ce
.ce
\fBused for sound\(hyprogramme transmissions which are fitted\fR
.ce
\fBwith compandors\fR
.ps 9
.vs 11
.nr VS 11
.nr PS 9
.TS
center box;
cw(30p) | cw(36p) sw(30p) | cw(108p) , ^ | c | c | c.
Time interval (Secs.) Sending unit Programme number: 04
Frequency (Hz) Level (dBm0) Measuring function
_
.T&
lw(30p) | cw(36p) | cw(30p) | lw(108p) .
1 1650/1850 \(em12 {
Start/source/programme identification
}
_
.T&
lw(30p) | cw(36p) | cw(30p) | lw(108p) .
1 \ 1 | 20 \ \ 0 Received level
_
.T&
lw(30p) | cw(36p) | cw(30p) | lw(108p) , l | c | c | ^ .
1 \ 1 | 20 \(em10 Frequency response
1 \ \ | 00 \(em10
.T&
lw(30p) | cw(36p) | cw(30p) .
1 \ \ | 00 \(em10
_
.T&
lw(30p) | cw(36p) | cw(30p) .
1 \ \ | 00 \(em10
_
.T&
lw(30p) | cw(36p) | cw(30p) .
1 \ \ | 00 \(em10
_
.T&
lw(30p) | cw(36p) | cw(30p) .
1 \ \ | 20 \(em10
_
.T&
lw(30p) | cw(36p) | cw(30p) .
1 \ 1 | 00 \(em10
_
.T&
lw(30p) | cw(36p) | cw(30p) .
1 \ 1 | 00 \(em10
_
.T&
lw(30p) | cw(36p) | cw(30p) .
1 \ 2 | 00 \(em10
_
.T&
lw(30p) | cw(36p) | cw(30p) .
1 \ 2 | 00 \(em10
_
.T&
lw(30p) | cw(36p) | cw(30p) .
1 \ 2 | 00 \(em10
_
.T&
lw(30p) | cw(36p) | cw(30p) .
1 \ 3 | 00 \(em10
_
.T&
lw(30p) | cw(36p) | cw(30p) .
1 \ 3 | 00 \(em10
_
.T&
lw(30p) | cw(36p) | cw(30p) .
1 \ 3 | 00 \(em10
.T&
lw(30p) | cw(36p) | cw(30p) | lw(108p) .
1 \ 1 | 20 \ +9 Total harmonic distortion
_
.T&
lw(30p) | cw(36p) | cw(30p) | lw(108p) .
1 \ \ | 20 \ +6 1
.T&
cw(30p) | cw(36p) | lw(30p) | lw(108p) .
\ \ | 20 \ \(em6 Compandor test 1
.T&
cw(30p) | cw(36p) | lw(30p) | lw(108p) .
\ \ | 20 \ +6
_
.T&
lw(30p) | cw(36p) | cw(30p) | lw(108p) .
8 \(em \(em Signal\(hyto\(hynoise ratio
_
.TE
.nr PS 9
.RT
.ad r
\fBTable E/O.33 [T5.33], p.
.sp 1P
.RT
.ad b
.RT
.LP
.bp
.ce 1000
ANNEX\ F
.ce 0
.ce 1000
(to Recommendation O.33)
.sp 9p
.RT
.ce 0
.ce
\fBH.T. [T6.33]\fR
.ce
\fBMeasurement sequence for the CMTT three\(hylevel test signals\fR
.ce
.ce
\fB
.ce
(without station announcement)\fR
.ce
.ce
\fBfor the alignment of international sound\(hyprogramme connections\fR
.ps 9
.vs 11
.nr VS 11
.nr PS 9
.TS
center box;
cw(30p) | cw(66p) | cw(66p) | cw(66p) .
Time interval Channel A sending unit Channel B sending unit Programme number: 05
_
.T&
cw(30p) | cw(36p) | cw(30p) | cw(36p) | cw(30p) | cw(66p) .
Seconds Frequency (Hz) Level (dBm0) Frequency (Hz) Level (dBm0) Measuring Function
_
.T&
lw(30p) | cw(36p) | cw(30p) | cw(36p) | cw(30p) | lw(66p) .
1 1650/1850 \(em12 \(em \(em {
Start/Source/Programme identification
}
_
.T&
lw(30p) | cw(36p) | cw(30p) | cw(36p) | cw(30p) | lw(66p) .
1 \(em \(em \(em \(em Pause
_
.T&
lw(30p) | cw(36p) | cw(30p) | cw(36p) | cw(30p) | lw(66p) , l | c | c | c | c | ^ .
1 1 | 20 \(em12 1 | 20 \(em12 Measurement level (ML)
1 1 | 20 \(em12 1 | 20 \(em12
_
.T&
lw(30p) | cw(36p) | cw(30p) | cw(36p) | cw(30p) | lw(66p) , l | c | c | c | c | ^ .
1 1 | 20 0 1 | 20 0 Alignment level (AL)
1 1 | 20 0 1 | 20 0
.T&
lw(30p) | cw(36p) | cw(30p) | cw(36p) | cw(30p) .
1 1 | 20 0 1 | 20 0
_
.T&
lw(30p) | cw(36p) | cw(30p) | cw(36p) | cw(30p) .
1 1 | 20 0 1 | 20 0
_
.T&
lw(30p) | cw(36p) | cw(30p) | cw(36p) | cw(30p) .
1 1 | 20 0 1 | 20 0
_
.T&
lw(30p) | cw(36p) | cw(30p) | cw(36p) | cw(30p) .
1 1 | 20 0 1 | 20 0
_
.T&
lw(30p) | cw(36p) | cw(30p) | cw(36p) | cw(30p) .
1 1 | 20 0 1 | 20 0
_
.T&
lw(30p) | cw(36p) | cw(30p) | cw(36p) | cw(30p) .
1 1 | 20 0 1 | 20 0
.T&
lw(30p) | cw(36p) | cw(30p) | cw(36p) | cw(30p) | lw(66p) , l | c | c | c | c | ^ .
1 1 | 20 0 | ua\d\u)\d \(em \(em {
Permitted maximum | ua\d\u)\d level (PML)
}
1 1 | 20 0 | ua\d\u)\d \(em \(em
_
.T&
lw(30p) | cw(36p) | cw(30p) | cw(36p) | cw(30p) | lw(66p) , l | c | c | c | c | ^ , l | c | c | c | c | ^ .
1 \(em \(em \(em \(em Pause
1 \(em \(em \(em \(em
1 \(em \(em \(em \(em
_
.T&
lw(30p) | cw(36p) | cw(30p) | cw(36p) | cw(30p) | lw(66p) , l | c | c | c | c | ^ .
1 \(em \(em 1 | 20 0 | ua\d\u)\d {
Permitted maximum | ua\d\u)\d level (PML)
}
.TE
.LP
\ua\d\u)\d
Provisionally 0 dBm0 level is to be used. The resulting two\(hylevel
test signal is required until all transmission systems are capable
of carrying sinusoidal signals at +9\ dBm0s without producing
excessive channel loading or crosstalk into other channels. The
active incorporation of the +9\ dBm0 level into this sequence will
need to be confirmed by CMTT and CCITT.
.LP
1 \(em \(em 1 | 20 0 | ua\d\u)\d
.nr PS 9
.RT
.ad r
\fBTable F/O.33 [T6.33], p.
.sp 1P
.RT
.ad b
.RT
.LP
.bp
.sp 2P
.LP
\fBReferences\fR
.sp 1P
.RT
.LP
[1]
CCITT Recommendation \fIMeasurements to be made during the line\(hyup\fR
\fIperiod that precedes a sound\(hyprogramme transmission\fR , Vol.\ IV,
Rec.\ N.12.
.LP
[2]
CCITT Recommendation \fIMeasurements to be made by the broadcasting\fR
\fIorganizations during the preparatory period\fR , Vol.\ IV, Rec.\ N.13.
.LP
[3]
CCITT Recommendation \fILimits for the lining\(hyup of international\fR
\fIsound\(hyprogramme links and connections\fR , Vol.\ IV, Rec.\ N.10.
.LP
[4]
CCITT Recommendation \fILimits and procedures for the lining\(hyup of a\fR
\fIsound\(hyprogramme circuit\fR , Vol.\ IV, Rec.\ N.21.
.LP
[5]
CCITT Recommendation \fIMaintenance measurements to be made on\fR
\fIinternational sound\(hyprogramme circuits\fR , Vol.\ IV, Rec.\ N.23.
.LP
[6]
CCITT Recommendation \fIInternational Alphabet No. 5\fR , Vol.\ VIII,
Rec.\ T.50, and International Organization for Standardization \fIISO 7\(hybit\fR
\fIserial data output\fR .
.LP
[7]
CCITT Recommendation \fIList of definitions for interchange circuits\fR
\fIbetween data terminal equipment and data circuit terminating equipment\fR ,
Vol.\ VIII, Rec.\ V.24, and Electronic Industries Association (EIA)
Standard RS\(hy232\(hyC \fIInterface between data terminal equipment and
data\fR
\fIcommunication equipment employing serial binary data interchange\fR .
.LP
[8]
International Electrotechnical Commission \fIInterface system for\fR
\fIprogrammable measuring instruments\fR , IEC Publications\ 625, 625\(hy1
and 625\(hy2.
.LP
[9]
CCIR Recommendation \fIMeasurement of audio\(hyfrequency noise in\fR
\fIsound broadcasting\fR , Vol.\ X, Rec.\ 468, ITU, Geneva, 1986.
.LP
[10]
CCITT Recommendation \fIRelative levels and impedances on an\fR
\fIinternational sound\(hyprogramme connection\fR , Vol.\ III, Rec.\ J.14.
.LP
[11]
CCITT Recommendation \fIMaximum permissible power during an\fR
\fIinternational sound\(hyprogramme transmission\fR , Vol.\ IV, Rec.\ N.15.
.LP
[12]
European Broadcasting Union (EBU) \fIGuiding principles for the\fR
\fIdesign of electronic equipment\fR , Document TECH 3215.
.LP
[13]
CCITT Recommendation \fIEssential transmission performance objectives\fR
\fIfor international sound\(hyprogramme centres (ISPC)\fR , Vol.\ IV,
Rec.\ N.11.
.LP
.bp
