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.rs
\v | 5i'
.sp 1P
.ce 1000
\v'3P'
SECTION\ 3
.ce 0
.sp 1P
.ce 1000
\fBAUTOMATIC\ AND\ SEMI\(hyAUTOMATIC\fR 
.ce 0
.sp 1P
.ce 1000
\fBMEASURING\ SYSTEMS\fR 
.ce 0
.sp 1P
.sp 2P
.LP
\fBRecommendation\ O.22\fR 
.FS
The text of this Recommendation has been
established under the responsibility of Study Groups\ IV and\ XI. Any
modification to this text must be submitted for approval to these Study
Groups.
.FE
.RT
.sp 2P
.ce 1000
\fBCCITT\ AUTOMATIC\ TRANSMISSION\ MEASURING\fR 
.EF '%	Fascicle\ IV.4\ \(em\ Rec.\ O.22''
.OF '''Fascicle\ IV.4\ \(em\ Rec.\ O.22	%'
.ce 0
.sp 1P
.ce 1000
\fBAND\ SIGNALLING\ TESTING\ EQUIPMENT\ ATME\ No.\ 2\fR 
.ce 0
.sp 1P
.ce 1000
\fI(Geneva, 1972; amended Geneva, 1980, Malaga\(hyTorremolinos, 1984 and\fR 
.sp 9p
.RT
.ce 0
.sp 1P
.ce 1000
\fIMelbourne, 1988)\fR 
.ce 0
.sp 1P
.LP
\fB1\fR 	\fBGeneral\fR 
.sp 1P
.RT
.PP
The CCITT automatic transmission measuring and signalling testing equipment 
(ATME\ No.\ 2) is intended to make transmission measurements, echo 
canceller tests and signalling system functional tests
.FS
The concept of
\fIfunctional texts\fR excludes marginal testing.
.FE
on all categories of
international circuits terminating in exchanges with 4\(hywire switching.
.PP
The ATME\ No.\ 2 will consist of two parts, namely:
.RT
.LP
	1)
	directing equipment
at the outgoing end, and
.LP
	2)
	responding equipment
at the incoming end.
.PP
The responding equipment will be available in the following
forms:
.LP
	a)
	a signalling system functional testing \fIand\fR transmission
measuring device (Type\ a),
.LP
	b)
	a signalling system functional testing device
(Type\ b)
.FS
The CCITT directs the attention of Administrations to the
advantages of providing sufficient signalling system functional testing 
devices (Type\ b) to permit several signalling system functional tests 
to be conducted simultaneously and to permit signalling system functional 
tests to be conducted more frequently than transmission tests. (For the 
application of 
ATME No.\ 2, see Recommendation\ M.605\ [1].)
.FE
.
.PP
It is not possible for the signalling system functional testing
devices as found in Types\ a and\ b to check the busy flash signal. For this
purpose a separate test call must be established using an appropriate test
code. Arrangements will therefore be provided to force the transmission 
of the busy flash signal over the circuit under test by the incoming international 
exchange equipment. This may be carried out by examination of the test 
code in the exchange equipment or by the provision of a separate responding 
equipment. The busy flash signal should be transmitted as the result of 
a simulation of 
exchange or circuit congestion. For the purposes of this specification, the
equipment providing this busy test arrangement shall be referred to as
responding equipment Type\ c.
.PP
Responding equipment\ Type\ a is always required. Type\ b is optional;
when used in addition to Type\ a, it is expected to provide an economical 
means for making more frequent signalling tests without occupying the transmission 
measuring equipment. Type\ c responding equipment is required in cases 
when the signalling system used on the circuits to be tested provides a 
busy flash line signal. 
.RT
.LP
.sp 1
.bp
.PP
For both\(hyway circuits, directing and responding equipments are
required at both ends for making signalling system functional tests. For
transmission measurements over both\(hyway circuits, the outgoing end is 
normally that which is the responsibility of the control station, and the 
incoming end is that which is the responsibility of the sub\(hycontrol 
station. However, these may be interchanged by mutual agreement. 
.PP
The equipment shall be of modular construction in order that only
those features desired by the using Administrations need to be included. The
present specification already takes account of operating over circuits using
CCITT Signalling Systems\ Nos.\ 3, 4, 5, 6, 7, R1 and\ R2.
.PP
Results of measurements shall be recorded only at the outgoing end,
that is by the directing equipment. However, arrangements can be made by the
Administrations or operating agencies involved to send the results of the
measurements to the Administrations in charge of the incoming end and other
points as desired, by mutually acceptable means. ATME No.\ 2 can be used on
circuits incorporating 
circuit multiplication systems
(CMSs) if the CMS concerned is so designed that a 2800\ Hz can be used 
to hold the circuits 
during absence of the normally transmitted signals. TASI is an example 
of a CMS which accepts 2800\ Hz as the 
holding tone
.
.RT
.sp 2P
.LP
\fB2\fR 	\fBKinds of measurements and tests\fR 
.sp 1P
.RT
.PP
Transmission measurements of the following kinds will be made in
both directions of transmission with Type\ a responders:
.RT
.LP
	a)
	absolute power level measurement at 1020 Hz
.FS
For further
information about the choice of the test signal frequency refer
to Recommendation\ O.6
.FE
;
.LP
	b)
	absolute power level measurement at 400, 1020 and 2800 Hz
(loss/frequency distortion);
.LP
	c)
	noise measurements;
.LP
	d)
	signal\(hyto\(hytotal\(hydistortion (including quantizing distortion)
ratio measurements at values of holding tone (i.e.\ \(em10 and
\(em25 dBm0);
.LP
	e)
	an in\(hycircuit echo canceller testing system (ECTS) sequence,
intended to test both near\(hyend and far\(hyend cancellers on a
circuit under test. The ECTS is suitable for testing echo
cancellers complying with Recommendation\ G.165\ [2];
.LP
	f
)
	on wholly digital circuits between digital exchanges,
measurements by the director of a director generated digital
test pattern looped back by a Type a responder.
.PP
In addition to tests of the normal signalling functions required in the 
process of setting up the test call, line signals such as the following 
will also be tested: 
.LP
	\(em
	clear back,
.LP
	\(em
	forward transfer,
.LP
	\(em
	 busy flash (this requires a separate test call to a separate test line, 
see Rec.\ O.11). 
.PP
In addition to the transmission measurements made between
directors and responders it shall also be possible to make measurements 
from a director to a digital loopback test line as described in Recommendation\ 
O.11 
.PP
The equipment will be designed in such a way that further
measurements and tests can be incorporated at a later date.
.RT
.sp 2P
.LP
\fB3\fR \fBEquipment for making transmission measurements and processing\fR 
\fBthe results\fR 
.sp 1P
.RT
.PP
The directing and responding equipments shall each be provided with features 
for making absolute power level, digital test pattern tests, echo 
canceller tests, 
signal\(hyto\(hytotal\(hydistortion ratio
and noise
measurements, as described below. In addition, the directing equipment shall
have the capability, where required, of receiving the results of the
measurements made by both the directing and responding equipments, making 
the necessary adjustments to these results, as discussed below, and converting 
the results to the proper form for transmission to the output device. The 
output 
device is also considered to be part of the directing equipment.
.bp
.RT
.sp 2P
.LP
3.1
	\fIAbsolute power level measurements\fR 
.sp 1P
.RT
.sp 1P
.LP
3.1.1
	\fISending end\fR 
.sp 9p
.RT
.PP
At the access point at the input to the path to be measured there will 
be connected a \fIsending equipment\fR which will send a tone of the 
appropriate frequency and level as specified in \(sc\(sc\ 6.3 and 9.1.
.RT
.sp 1P
.LP
3.1.2
	\fIMeasuring end\fR 
.sp 9p
.RT
.PP
At the access point at the output from the path to be measured
there will be connected a measuring device whose specifications are given in
\(sc\(sc\ 6.3 and 9.1.
.PP
The measuring device shall provide results in the form of a deviation, 
expressed in dB, from the nominal absolute power level of the circuit at 
the 
virtual switching point at the receiving end. This assumes that for the
responding equipment (see \(sc\ 3.6), the relative level at the receiving end
virtual switching point is \(em4\ dBr. A level higher than nominal shall be
indicated as positive \*Q |  | *U and a level lower than nominal shall 
be indicated as negative \*Q | (em | *U. For the total distortion measurements, 
the results should 
give the signal\(hyto\(hytotal\(hydistortion ratio in decibel. The transmission
parameters of the switched access path between the virtual switching point 
and the measuring device shall be allowed for (see Recommendation\ M.560\ 
[3]). 
.PP
If the equipment is capable of detecting an interruption or a
condition of instability experienced during a measurement (see \(sc\ 10.5)
the result shall be indicated as shown in Table\ 3/O.22.
.RT
.sp 1P
.LP
3.2
	\fINoise measurements\fR 
.sp 9p
.RT
.PP
\fINote\fR \ \(em\ When ATME No. 2 is implemented using digital
signal processing techniques, noise measurement is inherently limited to 
4\ kHz when using an 8\ kHz sampling frequency. 
.RT
.sp 1P
.LP
3.2.1
	\fISending end\fR 
.sp 9p
.RT
.PP
At the access point at the input to the path to be measured there will 
be connected a 600\(hyohms terminating resistance or a 
CMS locking
tone
in accordance with \(sc\(sc\ 6.4.19 or 6.4.20 and 9.3.
.RT
.sp 1P
.LP
3.2.2
	\fIMeasuring end\fR 
.sp 9p
.RT
.PP
At the access point at the output from the path to be measured,
there will be connected a noise measuring device whose specifications are 
given in \(sc\ 9.2\ below. 
.PP
The noise measuring device shall provide results in terms of absolute power 
level with psophometric weighting referred to 0\ level (dBm0p), assuming 
for the responding equipment that the relative level at the receiving end 
virtual switching point is \(em4.0\ dBr (see \(sc\ 3.6). The transmission
parameters of the switched access path between the virtual switching point 
and the noise measuring device shall be allowed for (see 
Recommendation\ M.560\ [3]).
.RT
.sp 2P
.LP
3.3
	\fISignal\(hyto\(hytotal\(hydistortion ratio measurements\fR 
.sp 1P
.RT
.sp 1P
.LP
3.3.1
	\fISending end\fR 
.sp 9p
.RT
.PP
At the access point at the input to the path to be measured, there will 
be connected a sending equipment which will send tones at two different 
levels (\(em10 and \(em25\ dBm0) as specified in \(sc\ 9.1.
.RT
.sp 1P
.LP
3.3.2
	\fIMeasuring end\fR 
.sp 9p
.RT
.PP
The signal\(hyto\(hytotal\(hydistortion ratio measurements will be carried 
out in two steps. 
.PP
\fIStep\ 1\fR 
.PP
At the access point at the output from the path to be measured,
there will be connected a noise measuring device connected with a 1000
to\ 1025\ Hz signal rejection filter. The noise measuring device and the 
signal rejection filter are specified in \(sc\ 9.2. 
.PP
\fIStep\ 2\fR 
.PP
At the access point at the output from the path to be measured
there will be connected a measuring device whose specifications are given in
\(sc\(sc\ 6.3 and\ 9.1.
.PP
The measuring device shall provide results in the form of the
signal\(hyto\(hytotal\(hydistortion ratio in decibel. A bandwidth correction 
for the 
loss of effective noise bandwidth due to the rejection filter must be
incorporated.
.bp
.RT
.sp 1P
.LP
3.4
	\fIEcho canceller testing system (ECTS)\fR 
.sp 9p
.RT
.PP
As part of the ECTS, the directing and responding equipments shall each 
be provided with features for making absolute power level, echo 
performance ratio and noise measurements, as described below. In addition, 
the directing equipment shall have the capability of receiving the results 
of the measurements made by both the directing and responding equipments, 
making the necessary adjustments to these results, as discussed below, 
and converting the results to the proper form. 
.RT
.sp 2P
.LP
3.4.1
	\fIAbsolute power level measurements\fR 
.sp 1P
.RT
.sp 1P
.LP
3.4.1.1
	\fISending end\fR 
.sp 9p
.RT
.PP
At the access point at the input to the path to be measured, there will 
be connected a \fIsending equipment\fR which will send a tone of the 
appropriate frequency and level as specified in \(sc\(sc\ 5.2 and\ 9.4.
.RT
.sp 1P
.LP
3.4.1.2
	\fIMeasuring end\fR 
.sp 9p
.RT
.PP
At the access point at the output from the path to be measured
there will be connected a measuring device whose specifications are given in
\(sc\(sc\ 6.7 and\ 9.1.
.PP
The measuring device shall provide results in the form of a deviation, 
expressed in decibel, from the nominal absolute power level of the circuit 
at the virtual switching point at the receiving end. This assumes that 
for the 
responding equipment (see \(sc\ 3.6), the relative level at the receiving end
virtual switching point is \(em4.0\ dBr. A level higher than nominal shall be
indicated as positive \*Q+\*U and a level lower than nominal shall be indicated 
as negative \*Q\(em\*U. The transmission parameters of the switched access 
path between the virtual switching point and the measuring device shall 
be allowed for (see Recommendation\ M.560\ [3]). 
.PP
If the equipment is capable of detecting an interruption or a
condition of instability experienced during a measurement (see \(sc\ 11.5), the
result shall be indicated as described in \(sc\ 3.6.
.RT
.sp 1P
.LP
3.4.2
	\fINoise measurements\fR 
.sp 9p
.RT
.PP
(To determine echo noise floor in step 1 of echo performance
test.)
.RT
.sp 1P
.LP
3.4.2.1
	\fISending end\fR 
.sp 9p
.RT
.PP
At the access point at the input to path to be measured, there will be 
connected a 600\(hyohms terminating resistance in accordance with \(sc\(sc\ 
6.7 
and\ 9.4.3.
.RT
.sp 1P
.LP
3.4.2.2
	\fIMeasuring end\fR 
.sp 9p
.RT
.PP
At the access point at the output from the path to be measured,
there will be connected a noise measuring device whose specifications are 
given in \(sc\ 9.5.1. 
.PP
The noise measuring device shall provide results as noise ratios which 
are the relative power level with psophometric weighting referred to the 
\(em10\ (dBm0p) sending level, assuming for the responding equipment that the
relative level at the receiving end virtual switching point is \(em4.0\ 
dBr (see 
\(sc\ 3.6).
.PP
\fINote\fR \ \(em\ This noise level is referred to \(em10 dBm0p rather 
than 0\ dBm0p to make it represent the minimum measurable noise ratio in 
steps\ 2 and\ 3 of the echo performance tests in \(sc\ 3.4.3. The transmission 
parameters of the switched access path between the virtual switching point 
and the noise measuring device shall be allowed for (see Recommendation\ 
M.560\ [3]). 
.RT
.sp 1P
.LP
3.4.3
	\fIEcho performance ratio measurements\fR 
.sp 9p
.RT
.PP
(Steps 2 and 3 of echo performance tests)
.RT
.sp 1P
.LP
3.4.3.1
	\fISending end\fR 
.sp 9p
.RT
.PP
At the access point at the input to the path to be measured, there will 
be connected a sending equipment which will send a \(em10\ dBm0 noise test 
signal as specified in \(sc\ 9.4.1e).
.bp
.RT
.sp 1P
.LP
3.4.3.2
	\fIMeasuring end\fR 
.sp 9p
.RT
.PP
At the access point at the ouput form the path to be measured,
there will be connected an echo performance (noise) measuring device whose
specifications are given in \(sc\ 9.5.1.
.PP
The measuring device shall provide results in terms of relative power level 
ratio with psophometric weighting referred to the \(em10\ dBm0 noise test 
signal in \(sc\ 3.4.3.1, assuming for the responding equipment that the 
relative 
level at the receiving end virtual switching point is \(em4.0\ dBr (see 
\(sc\ 3.6). The transmission parameters of the switched access path between 
the virtual 
switching point and the noise measuring device shall be allowed for (see
Recommendation\ M.560\ [3]).
.RT
.LP
3.5
	\fIDigital loopback tests\fR 
.sp 1P
.RT
.sp 2P
.LP
3.5.1
	\fIDigital test pattern tests to a digital loopback test line\fR 
.sp 1P
.RT
.sp 1P
.LP
3.5.1.1
	\fISending end\fR 
.sp 9p
.RT
.PP
At the access point at the input to the path to be measured, there will 
be connected a sending equipment which will provide a pseudo\(hyrandom 
digital test pattern as specified in Recommendation\ O.152, \(sc\ 2.
.RT
.sp 1P
.LP
3.5.1.2
	\fIMeasuring end\fR 
.sp 9p
.RT
.PP
At the access point at the output from the path to be measured,
there will be connected a receiving equipment as specified in
Recommendation\ O.152. This measuring equipment should be capable of measuring 
bit\(hyerror ratio, block\(hyerror ratio, and errored time intervals as 
defined in 
Recommendation\ G.821\ [4].
.RT
.sp 2P
.LP
3.5.2
	\fITransmission tests to a digital loopback test line\fR 
.sp 1P
.RT
.sp 1P
.LP
3.5.2.1
	\fISending end\fR 
.sp 9p
.RT
.PP
At the access point at the input to the path to be measured, there will 
be connected a sending equipment which will send tones of the appropriate 
frequency and level as specified in \(sc\(sc\ 6.3, 9.1, 9.2 and\ 9.3. 
.RT
.sp 1P
.LP
3.5.2.2
	\fIMeasuring end\fR 
.sp 9p
.RT
.PP
At the access point at the output from the path to be measured
there will be connected measuring equipment provided with features for 
making absolute power level, noise, and signal\(hyto\(hytotal\(hydistortion 
ratio measurements and as specified in \(sc\(sc\ 3.1.2, 3.2.2 and\ 3.3.2 
respectively. 
.PP
It should be noted that measurements made through the digital loopback 
test line will experience twice the circuit distance and delay characteristics 
experienced by a far end measurement device. Therefore, measurement results 
must be compared to circuit maintenance limits which are modified to reflect 
a doubling of circuit distance and quantizing distortion units (QDUs). 
.RT
.sp 1P
.LP
3.6
	\fIAdjustment results\fR 
.sp 9p
.RT
.PP
Circuits that may be used in international transit connections are operated 
with a nominal loss of 0.5\ dB, that is, the relative level at the 
receiving virtual switching point is \(em4.0\ dBr. However, circuits which 
are not intended to be used in international transit connections may be 
operated with nominal losses greater than 0.5\ dB (see Recommendation\ 
G.131\ [5]). 
.PP
The results of measurement of absolute power level deviations and
noise sent by the responding equipment to the directing end will assume a
\(em4.0\ dBr virtual switching point for all circuits. Thus, a measured value
corresponding to \(em5.0\ dBm at the virtual switching point will always be
transmitted to the directing equipment as a deviation of \(em1.0\ dB. Where a
circuit is operated with a nominal loss greater than 0.5\ dB, i.e.\ the actual
relative level at the virtual switching point is more negative than \(em4.0\ 
dBr, the directing equipment shall apply the appropriate correction to 
the results of the measurement of absolute power level deviation and noise 
received from 
the responding equipment. The signal\(hyto\(hytotal\(hydistortion and the echo
performance measurements are not affected as the results are presented as
signal\(hyto\(hytotal\(hydistortion ratio in\ dB or noise signal to echo 
signal ratio in dB. 
.bp
.RT
.sp 1P
.LP
3.7
	\fIRecording and presentation of output\fR 
.sp 9p
.RT
.PP
The output shall be recorded by suitable means, to be decided by
the Administration concerned. For absolute power level measurements at 
1020\ Hz the results shall be presented, with the appropriate algebraic 
sign, as 
deviations from the nominal absolute power level at the virtual switching
point. The results of measurements at 400 and 2800\ Hz shall be presented as
.PP
deviations from the measured absolute power level at 1020\ Hz. Results 
of noise measurements shall be expressed in dBm referred to 0\ level (dBm0p). 
The 
signal\(hyto\(hytotal\(hydistortion measurements are in the form of
signal\(hyto\(hytotal\(hydistortion ratios expressed in\ dB. The echo performance 
measurements are in the form of noise signal to echo signal ratios expressed 
in dB. 
.PP
An example is given in Table\ 1/O.22 for measurements made by the
responding equipment.
.RT
.ce
\fBH.T. [T1.22]\fR 
.ce
TABLE\ 1/O.22
.ce
\fBExample of measurements made by the responder\fR 
.ps 9
.vs 11
.nr VS 11
.nr PS 9
.TS
center box;
cw(36p) | cw(30p) | cw(42p) | lw(42p) | lw(42p) sw(36p) , ^  | ^  | ^  | ^  | l | l.
Measurement	 {
Frequencies
(Hz)
Absolute power level at the receiving virtual switching point at
responding equipment with \(em10\ dBm0 sending level
(dBm)
Deviation transmitted from responding equipment to directing equipment (a relative level of \(em4.0\ dBr at the virtual switching point is assumed)
(dB)
 }	 {
Presentation
For circuit with nominal loss of 0.5\ dB
(dB)
For circuit with nominal loss other than 0.5\ dB,
say 1.5\ dB
(dB)
 }		
					
_
.T&
lw(36p) | cw(30p) | cw(42p) | cw(42p) | cw(42p) | cw(36p) .
Level	1020  \ 400 2800	\(em13.7 \(em14.4 \(em14.6	+0.3 \(em0.4 \(em0.6	+0.3 \(em0.7 \(em0.9	+1.3 \(em0.7 \(em0.9
_
.T&
lw(36p) | cw(72p) | cw(42p) | lw(78p) .
	 {
Value at receiving virtual switching point at responding equipment
 }	 {
Value transmitted from responding equipment to directing equipment (a
relative level of \(em4.0\ dBr at the virtual switching point is
assumed)
 }	
_
.T&
lw(36p) | cw(72p) | cw(42p) | cw(42p) | cw(36p) .
Noise power (dBm0)	\(em50  | ua\d\u)\d	\(em46	\(em46	\(em45
_
.T&
lw(36p) | cw(72p) | cw(42p) | cw(42p) | cw(36p) .
 {
Signal\(hyto\(hytotal\(hy
distortion ratio | ua\d\u)\d
\ \ or 
noise ratio (dB)
 }	\ 34 | ua\d\u)\d	+34	\ 34	\ 34
.TE
.LP
\ua\d\u)\d
With a received total distortion test signal level of \(em13.7 dBm
and a total distortion power of \(em48 dBm.
.nr PS 9
.RT
.ad r
\fBTable 1/O.22 [T1.22], p.\fR 
.sp 1P
.RT
.ad b
.RT
.PP
.sp 2
Distinct indications will be given under the following
conditions:
.LP
	a)
	the absolute power level deviation exceeds the assigned
maintenance limit;
.LP
	b)
	the noise power value is outside the assigned maintenance
limit;
.LP
	c)
	the signal\(hyto\(hytotal\(hydistortion ratio is outside the assigned
maintenance limit;
.LP
	d)
	the absolute power level deviation is so great that the
circuit is rendered unfit for service;
.bp
.LP
	e)
	the noise power value is so great that the circuit is
rendered unfit for service;
.LP
	f
)
	the signal\(hyto\(hytotal\(hydistortion ratio is so low that
the circuit is rendered unfit for service;
.LP
	g)
	the echo performance ratio is outside the assigned
maintenance limits for any dely value at either end. (When
this happens, the noise floor value measured in step\ 1 of
the test must also be recorded);
.LP
	h)
	digital error performance values greater than the assigned
maintenance limit; 
.LP
	i)
	failure to complete the test call;
.LP
	j)
	failure to meet the requirements of the signalling
tests.
.PP
In cases i) and j) the point in the programme at which a given
failure occurs should be indicated.
.PP
The form that the output should take has not been specified, and
international agreement on this point does not appear to be necessary, 
except concerning the following printout conventions (see\ Table\ 3/O.22 
and \(sc\ 11.5):
.RT
.ad r
Results of the measurements out of range at the upper
end
\ \ +\ +\ +
.ad b
.RT
.PP
(printout interpretation of three Code\ 11\ signals)
.ad r
Results of the measurements out of range at the lower
end
\ \ \(em\ \(em\ \(em
.ad b
.RT
.PP
(printout interpretation of three Code\ 12\ signals)
.ad r
XX represents the results of the measurement.
.FE
Interruption in measurement tone during absolute power
level measurements
\ \ 9XX or 7XX
\v'4p'
.ad b
.RT
.ad r
Instability during absolute power level
measurements
\ \ 8XX or 6XX
\v'4p'
.ad b
.RT
.PP
It should be noted that when an interruption and instability are both detected 
during a power level measurement only the interruption will be 
recorded in the printout and no indication of the instability will be given
(see\ \(sc\ 11.5).
.PP
If directed by the input programme, the date and time (to the nearest minute) 
shall be recorded. 
.PP
The possibility shall be included to provide a complete record of the results 
of all measurements and signalling tests and the identification of all 
circuits which could not be measured or tested because the circuit was 
occupied or because the responding equipment could not be reached. A different 
indication shall be given for each of the latter two categories.
.PP
In addition a shortened record should be obtainable which omits
information concerning circuits which were within maintenance limits and on
which no instability or interruption was indicated.
.RT
.sp 1P
.LP
3.8
	\fIRemeasurement and retest arrangements\fR 
.sp 9p
.RT
.PP
Arrangements are required to provide an input data record for
circuits which were occupied on initial measurement or test and for circuits 
on which the responding equipment could not be reached. This input data 
record 
should be capable of expansion to include all circuits except those which 
are found to be within maintenance limits and on which no instability or 
interruption was indicated. The input data record shall be in such a form 
that it may be used to control the directing equipment so as to permit 
the 
reexamination of these circuits in any grouping as desired by the using
Administration.
.RT
.sp 2P
.LP
\fB4\fR 	\fBMethod of access\fR 
.sp 1P
.RT
.PP
4.1
In general, access arrangements will conform to
Recommendation\ M.560\ [3].
.sp 9p
.RT
.sp 1P
.LP
4.2
	\fIOutgoing international exchange\fR 
.sp 9p
.RT
.PP
Access to the circuit for test at the outgoing international
exchange shall conform to Recommendation\ M.565\ [6].
.RT
.sp 1P
.LP
4.3
	\fIIncoming international exchange\fR 
.sp 9p
.RT
.PP
Access to the responding equipment at the incoming international
exchange will be gained via a maintenance access line associated with the
normal switching equipment. The address information to be used to gain 
access to either Type\ a or Type\ b responding equipment or to a digital 
loopback test line at the incoming exchange is specified in \(sc\ 2.4 of 
Recommendation\ O.11.
.bp
.RT
.sp 2P
.LP
\fB5\fR 	\fBOperating principles\fR 
.sp 1P
.RT
.PP
It shall be possible to perform any one, two or more of the
measurements and tests mentioned in \(sc\ 2 on the same circuit under the
control of the directing equipment without releasing the connection except 
when the busy flash test is performed, or when tests to a digital loopback 
test 
line are performed.
.RT
.PP
5.1
When the directing equipment has indicated to the responding
equipment the kind of measurement to be made, the measurement is first 
made at the directing equipment with the responding equipment sending a 
measurement 
tone or providing a 600\(hyohm termination. The directing equipment then sends
the measurement tone or provides a 600\(hyohm termination while the responding
equipment makes the measurement.
.sp 9p
.RT
.PP
5.2
Directing equipment which has access to circuits equipped
with 
echo suppressors
and/or 
echo cancellers
must be provided   with arrangements to transmit the echo 
suppressor/canceller disabling
tone
specified in \(sc\ 9.3. Arrangements must be included in the
directing equipment to provide for the transmission of this tone only on
circuits equipped with echo suppressors and/or echo cancellers. These features 
may be omitted in equipments which do not have access to such circuits, 
but 
provision must be made to add them when required.
.PP
5.3
Directing and responding equipment which has access to circuits on routes 
incorporating a CMS system, or to circuits equipped with echo 
suppressors and/or echo cancellers, must be provided with means
for transmitting the 
CMS locking tone
as specified in \(sc\ 9.3. Means
are required in the directing equipment to transmit this tone only on such
routes or circuits. If these features are not provided initially, arrangements 
must be made so that they can be added when required. 
.PP
5.4
Initially Echo canceller testing system (ECTS) signals will be sent
by the directing equipment to disable or lock\(hyup any echo suppressor 
or circuit multiplication equipment that is present on the circuit under 
test. 
.PP
Next, loss tests will be made in both directions of transmission to ensure 
that the circuit loss is within nominal values. 
.PP
Then a series of echo performance (noise ratio) measurements will be made 
toward an echo canceller at the distant end of a circuit corresponding 
to each of three circuit conditions provided by its terminating 
equipment:
.RT
.LP
	a)
	quiet termination of both directions of transmission,
.LP
	b)
	2 dB gain loop with prescribed amount of delay to test each
stage (cascaded delay section) of the canceller, and
.LP
	c)
	10 dB loss loop with prescribed amount of delay.
.PP
The process will then be reversed so as to test both the far\(hyend and 
near\(hyend echo cancellers with one access of the circuit under test. 
.LP
\fB6\fR 	\fBSignalling system testing and transmission measuring
procedure\(emdirector to responder\fR 
.sp 1P
.RT
.sp 2P
.LP
6.1
	\fIEstablishment of connection and signalling test sequence\fR 
.sp 1P
.RT
.PP
6.1.1
When the outgoing circuit is seized, the appropriate address
information is transmitted in accordance with the specification for the
signalling system in use.
.sp 9p
.RT
.PP
6.1.2
When access is gained to the responding equipment, the answer
signal (answer, no charge in Signalling System\ No.\ 6 will be transmitted. If
the responding equipment is occupied, a busy indication will be returned 
to the directing equipment in accordance with normal signalling arrangements 
for 
the circuit and for the access arrangements concerned. If the busy indication 
is received, this will be recorded by the directing equipment and the circuit 
released (see \(sc\ 3.7.) 
.PP
\fR 6.1.3
If no signal is received by the directing equipment within 15\ \(+-\ 5 
seconds of transmission of the address information, then a fault will be 
recorded and the circuit released.
.PP
6.1.4
When the indication that the answer signal has been received is
passed to the directing equipment and transmission measurements are desired
with a responding equipment Type\ a, transmission measurement cycles may take
place as described in \(sc\ 6.4. These cycles will end with the \fIend of\fR 
\fItransmission measuring programme\fR signal (Code\ 15) transmitted by the
directing equipment, followed by the acknowledgement signal (Code\ 13)
.LP
transmitted by the responding equipment in accordance with the normal
responding sequence.
.bp
.PP
6.1.5
When the indication that the answer signal has been received is passed 
to the directing equipment and transmission measurements are not 
desired, or if the responding equipment is of Type\ b, or if the transmission
measurement cycles have been completed and a complete signalling functional
test is required, the directing equipment will transmit the forward transfer
signal, or if this signal is not provided, the Code\ 11\ signal.
.sp 9p
.RT
.PP
Where the forward transfer signal is part of the signalling system it should 
be used by the directing equipment to initiate the complete 
signalling function test
.FS
It should be noted that although the forward
transfer signal may be part of a signalling system, it may not be provided 
for in some international exchanges using such a signalling system. In 
these cases a complete signalling function test will not be possible, unless 
the use of 
Code\ 11 [see \(sc\ 6.1.5, | )] is agreed on a bilateral basis.
.FE
.
.LP
	a)
	\fIForward transfer signal provided\fR 
.LP
The transmission of the line signals initiated by ATME No.\ 2
equipment on the international circuit is performed by exchange line signalling 
equipment in accordance with normal signalling procedures. Consequently, 
the 
actual times at which the various signals are transmitted and received 
depend upon the signalling system employed and the circuit propagation 
time in any 
particular case.
.FE
	If transmission measurements have been made, a forward transfer
signal will be initiated by the directing equipment 500\ \(+-\ 100\ ms 
after the end of the transmission measuring programme signal. If transmission 
measurements 
have not been made or if Type\ b equipment is used, the transmission of the
forward transfer signal will be initiated by the directing equipment
500\ \(+-\ 100\ ms after the indication that the answer signal has been 
received is passed to the directing equipment 
. These sequences apply to circuits
fitted or not fitted with echo suppressors/cancellers.
.LP
	b)
	\fIForward transfer signal not provided\fR 
.LP
	 If transmission measurements have been made the Code\ 11 signal will 
be transmitted after the end of the transmission measuring programme signal. 
The directing equipment will transmit the CMS locking tone between the 
Code\ 15 and Code\ 11 signals on circuits equipped with echo suppressors/cancellers 
to 
ensure that they remain disabled. When the acknowledgement to the Code\ 15
signal is recognized by the directing equipment the Code\ 15 command signal 
will be disconnected and the CMS locking tone will be connected within 
60\ ms. When the end of the command acknowledgement signal is recognized 
by the directing 
equipment the CMS locking tone will be removed and the Code\ 11 command 
signal will be connected 55\ \(+-\ 5\ ms after the disconnection of the 
CMS locking tone. If transmission measurements have not been made or if 
Type\ b equipment is used, 
the transmission of the Code\ 11 signal will be preceded by transmission 
of the echo suppressor/canceller disabling tone as specified in \(sc\ 6.4.1. 
When the 
acknowledgement of the Code\ 11 signal (return of Code\ 13) is recognized 
by the directing equipment, the Code\ 11 command signal will be disconnected. 
.PP
6.1.6
If shortened signalling functional tests alone are desired, the directing 
equipment will initiate a clear\(hyforward signal on receipt of the 
answer signal if transmission measurements have not been made, or on receipt 
of the acknowledgement signal (Code\ 13) following the end of transmission 
measuring programme signal when transmission measurements have been made.
.sp 9p
.RT
.PP
6.1.7
When a complete signalling functional test is carried out, the indication 
that a forward transfer signal has been received will cause the 
responding equipment to initiate a clear\(hyback signal. For systems without a
forward transfer signal (see\ \(sc\ 6.1.5) the receipt of a Code\ 11 signal
will initiate the transmission of a clear\(hyback signal 500\ \(+-\ 100\ 
ms after the 
command acknowledgement signal.
.sp 9p
.RT
.PP
The responding equipment will initiate a reanswer
signal 500\ \(+-\ 100\ ms after the clear\(hyback signal has been initiated
.
.PP
\fINote\fR \ \(em\ It is possible that with a 500\(hyms gap between the 
initiation of the clear\(hyback and reanswer signals a CMS circuit may 
release the CMS channel. This may also happen in other parts of the signalling 
test sequence. 
.PP
If the clear\(hyback signal is not received by the directing equipment
within 5\ to 10\ seconds of sending the forward transfer signal or the Code\ 11
signal, or if the reanswer signal is not received 5 to 10\ seconds after the
receipt of the clear\(hyback signal, a fault will be recorded and the circuit
released.
.PP
When the reanswer signal is recognized, the directing equipment will
initiate a clear\(hyforward signal.
.bp
.RT
.PP
6.1.8
When the clear\(hyforward signal is transmitted (in accordance
with \(sc\(sc\ 6.1.6 or 6.1.7), a check should be made that the outgoing 
circuit 
has been released and is available for future use. If the outgoing circuit 
is not fully released within 5\ to 10\ seconds of the initiation of the 
clear\(hyforward signal by the directing equipment, a fault will be recorded.
It should be noted that the test for the release of the circuit may not be
possible on certain designs of equipment.
.sp 9p
.RT
.sp 1P
.LP
6.2
	\fIBusy flash test\fR 
.sp 9p
.RT
.PP
The busy flash signal may be tested by establishing a call using
the address code specified in \(sc\ 2.4 of Recommendation\ O.11, to force
transmission of a busy flash signal by the incoming exchange equipment. On
receipt of the busy flash signal the circuit will be released.
.PP
If the busy flash signal is not received within 10 to 20\ seconds of
transmission of the address information then a fault will be recorded and 
the circuit released. 
.PP
\fINote\fR \ \(em\ There is no need to make such a test in Signalling
Systems\ Nos.\ 6 and\ 7 or in Systems\ R1 and\ R2.
.RT
.sp 1P
.LP
6.3
	\fITransmission measuring\fR \fIprocedure and exchange of\fR 
\fIinformation between directing and responding equipments\fR 
.sp 9p
.RT
.PP
Individual measurement cycles are specified in two groups known as \*QLayer\ 
1\*U and \*QLayer\ 2\*U. One code in Layer\ 1 has been designated to indicate 
that a measurement cycle in Layer\ 2 is being requested.
.RT
.sp 1P
.LP
6.3.1 
	\fILayer 1 procedures\fR 
.sp 9p
.RT
.PP
The signalling sequence for each Layer 1 individual measurement
cycle is specified in \(sc\ 6.4 and the frequencies and codes in Tables\ 
2/O.22, 
3/O.22 and 4/O.22. An example of the signalling sequence for a cycle involving 
the measurement of absolute power level is shown in Figure\ 1/O.22. The 
signalling scheme adopted for the command signals between directing and
responding equipments consists of multi\(hyfrequency (MF) signals transmitted 
in compelled sequence; results are transmitted from the responding equipment 
to 
the directing equipment by means of multi\(hyfrequency pulse\(hytype signals.
.PP
All transmission measurements should be performed with a tone level
of \(em10\ dBm0 (total distortion measurements may also use a \(em25\ dBm0 
level). 
Certain older responding equipment may be equipped to test with two tone
levels, i.e.\ 0\ dBm0 and \(em10\ dBm0. In these circumstances a signal 
will be sent to inform the responding equipment of the measurement level 
to be used. (See 
Table\ 2/O.22 and \(sc\ 9.1.) It should be noted that the sensitivity of the
measuring equipment must be arranged to accommodate both levels.
.PP
The signal sender and signal receiver chosen are those specified for the 
CCITT interregister Signalling System No.\ 5 and the equipment used should 
be as specified in Recommendations\ Q.153\ [7] and Q.154\ [8] (see Annex\ 
A to 
this Recommendation concerning the sensitivity of the signalling
receiver.)
.RT
.sp 1P
.LP
6.3.2
	\fILayer 2 procedures\fR 
.sp 9p
.RT
.PP
The signalling sequence for each Layer 2 individual measurement
cycle is specified in \(sc\ 6.6 and the frequencies and codes in Tables\ 4/O.22
and\ 5/O.22. Multi\(hyfrequency pulse\(hytype signals are used in Layer\ 
2 both for 
command signals between directing and responding equipments and for
transmitting results from the responding equipment to the directing equipment. 
When a Layer\ 2 procedure has been completed, a designated multi\(hyfrequency 
pulse\(hytype signal command returns the dialogue to Layer\ 1.
.RT
.sp 2P
.LP
6.4
	\fIDescription of transmission measuring cycles\fR 
.sp 1P
.RT
.PP
6.4.1
When the indication that the answer signal has been received is passed 
to the directing equipment, the echo 
suppressor/canceller disabling  tone
will be transmitted from the directing equipment for
2\ seconds\ \(+-\ 250\ ms.
.sp 9p
.RT
.PP
\fINote\ 1\fR \ \(em\ This period takes into account the delay necessary 
for connection to a CMS channel, the time necessary for the assured disablement 
of the echo suppressor or echo canceller, the long propagation time likely 
to be experienced on satellite circuits and the delays attributable to 
the 
functioning of the signalling system. For circuits not using a line\(hysignalling 
system involving an answer acknowledgement signal (such as Signalling 
Systems\ Nos.\ 3 and 4) it will be sufficient to send a disabling tone for at
least 800\ ms. If, however, the circuit to be tested is not equipped with 
echo suppressors/cancellers (see \(sc\ 5), the procedure in \(sc\ 6.4.1 
will be omitted. 
.PP
\fINote\ 2\fR \ \(em\ The specifications for the echo suppressor/canceller
disabling tone and the CMS locking tone are given in \(sc\ 9.3.
.bp
.RT
.ce
\fBH.T. [T2.22]\fR 
.ce
TABLE\ 2/O.22
.ce
\fBCommand signals from directing equipment to responding
.ce
equipment
.ps 9
.vs 11
.nr VS 11
.nr PS 9
.TS
center box;
cw(24p) | cw(204p) .
Code No.	Interpretation
_
.T&
cw(24p) | lw(204p) .
\ 1	 {
Measure absolute power level at 1020\ Hz (sent level 0\ dBm0)
 }
.T&
cw(24p) | lw(204p) .
\ 2	 {
Measure absolute power level at 400\ Hz
with a sent level indicated by the 1020\ Hz
 }
.T&
cw(24p) | lw(204p) .
\ 3	 {
Measure absolute power level at 2800\ Hz
measurement command signal
\fB
 }
.T&
cw(24p) | lw(204p) .
\ 4	 {
Measure psophometric noise power (no CMS locking tone
applied) | ua\d\u)\d
 }
.T&
cw(24p) | lw(204p) .
\ 5	 {
Measure psophometric noise power (with CMS locking tone applied) 
 }
.T&
cw(24p) | lw(204p) .
\ 6	 {
Measure absolute power level at 1020\ Hz and subsequent level measurements in the programme with a sent level of \(em10\ dBm0
 }
.T&
cw(24p) | lw(204p) .
\ 7	 {
Measure total distortion with \(em10\ dBm0 signal
 }
.T&
cw(24p) | lw(204p) .
\ 8	 {
Measure total distortion with \(em25\ dBm0 signal
 }
.T&
cw(24p) | lw(204p) .
\ 9	Shift to Layer 2
.T&
cw(24p) | lw(204p) .
11	 {
Used instead of forward transfer when this signal is not provided
 }
.T&
cw(24p) | lw(204p) .
13	 {
Reverse the direction of measurement 
 }
.T&
cw(24p) | lw(204p) .
14	(Reserved for national use)
.T&
cw(24p) | lw(204p) .
15	End of transmission measurement programme
.TE
.LP
\ua\d\u)\d
Applies to circuits on routes which do not incorporate
a CMS system and are not equipped with echo suppressors and/or
cancellers.
.nr PS 9
.RT
.ad r
\fBTableau 2/O.22 [T2.22], p. 2\fR 
.sp 1P
.RT
.ad b
.RT
.ce
\fBH.T. [T3.22]\fR 
.ce
TABLE\ 3/O.22
.ce
\fBSignals from responding equipment to directing
.ce
equipment\fR 
.ps 9
.vs 11
.nr VS 11
.nr PS 9
.TS
center box;
cw(30p) | cw(150p) .
Code No.	Interpretation
_
.T&
cw(30p) | lw(150p) .
1\(hy10	 {
Digits 1, . |  |  |  9, 0 (measurement results information)
 }
.T&
cw(30p) | lw(150p) .
11	 {
\ + (prefix for transmission measurements)
 }
.T&
cw(30p) | lw(150p) .
12	 {
\ \(em (prefix for transmission measurements)
 }
.T&
cw(30p) | lw(150p) .
\ 9	 {
\ + (prefix to indicate measurement tone interruption)
 }
.T&
cw(30p) | lw(150p) .
\ 7	 {
\ \(em (prefix to indicate measurement tone interruption)
 }
.T&
cw(30p) | lw(150p) .
\ 8	 {
\ + (prefix to indicate measurement tone instability)
 }
.T&
cw(30p) | lw(150p) .
\ 6	 {
\ \(em (prefix to indicate measurement tone instability)
 }
.T&
cw(30p) | lw(150p) .
13	Command acknowledgement 
.T&
cw(30p) | lw(150p) .
\ 11 (3\(hytimes)	 {
\fI(out of range at the upper end \fR
printed out as \*Q+++\*U)
 }
.T&
cw(30p) | lw(150p) .
\ 12 (3\(hytimes)	 {
\fI(out of range at the lower end \fR
printed out as \*Q\(em\(em\(em\*U)
 }
.T&
cw(30p) | lw(150p) .
15	 {
Recognition of faulty multi\(hyfrequency signal
 }
_
.TE
.nr PS 9
.RT
.ad r
\fBTableau 3/O.22 [T3.22], p. 3\fR 
.sp 1P
.RT
.ad b
.RT
.LP
.bp
.LP
.rs
.sp 28P
.ad r
\fBFigure 1/O.22, p. 4\fR 
.sp 1P
.RT
.ad b
.RT
.ce
\fBH.T. [T4.22]\fR 
.ce
TABLE\ 4/O.22
.ce
\fBFrequency allocation and codes\fR 
.ps 9
.vs 11
.nr VS 11
.nr PS 9
.TS
center box;
cw(30p) | cw(60p) .
Code No.\fR	Frequencies (compound) (Hz)
_
.T&
cw(30p) | cw(60p) .
\ 1	\ 700 + \ 900
.T&
cw(30p) | cw(60p) .
\ 2	\ 700 + 1100
.T&
cw(30p) | cw(60p) .
\ 3	\ 900 + 1100
.T&
cw(30p) | cw(60p) .
\ 4	\ 700 + 1300
.T&
cw(30p) | cw(60p) .
\ 5	\ 900 + 1300
.T&
cw(30p) | cw(60p) .
\ 6	1100 + 1300
.T&
cw(30p) | cw(60p) .
\ 7	\ 700 + 1500
.T&
cw(30p) | cw(60p) .
\ 8	\ 900 + 1500
.T&
cw(30p) | cw(60p) .
\ 9	1100 + 1500
.T&
cw(30p) | cw(60p) .
10	1300 + 1500
.T&
cw(30p) | cw(60p) .
11	\ 700 + 1700
.T&
cw(30p) | cw(60p) .
12	\ 900 + 1700
.T&
cw(30p) | cw(60p) .
13	1100 + 1700
.T&
cw(30p) | cw(60p) .
14	1300 + 1700
.T&
cw(30p) | cw(60p) .
15	1500 + 1700
_
.TE
.nr PS 9
.RT
.ad r
\fBTableau 4/O.22 [T4.22], p. 5\fR 
.sp 1P
.RT
.ad b
.RT
.LP
.bp
.ce
\fBH.T. [T5.22]\fR 
.ce
TABLE\ 5/O.22
.ce
\fBLayer\ 2 command signals from directing equipment
.ce
\fBto responding equipment\fR 
.ps 9
.vs 11
.nr VS 11
.nr PS 9
.TS
center box;
cw(30p) | cw(120p) .
Code No.	Layer 2 Interpretation
_
.T&
cw(30p) | lw(120p) .
1	 {
Echo canceller test system \(em automatic
 }
.T&
cw(30p) | lw(120p) .
2	Reserved
.T&
cw(30p) | lw(120p) .
3	 {
Loop\(hyaround test \(em digital
 }
.T&
cw(30p) | lw(120p) .
5	Return to Layer 1
_
.TE
.nr PS 9
.RT
.ad r
\fBTableau 5/O.22 [T5.22], p. 6\fR 
.sp 1P
.RT
.ad b
.RT
.LP
.sp 4
.PP
6.4.2
When the echo suppressor/canceller disabling tone is removed,
the directing equipment will transmit a multi\(hyfrequency (MF) command 
signal to the responding equipment. The interval between cessation of the 
tone and 
transmission of the command signal will be 55\ \(+-\ 5\ ms. If, however, the
disabling tone has not been sent (see \(sc\ 5) the MF command signal will 
be sent within 60\ ms, following the indication that the answer signal 
has been 
received.
.PP
6.4.3
When the command signal is received by the responding equipment
a MF command acknowledgement signal will be transmitted.
.PP
6.4.4
When the command acknowledgement signal is recognized by the
directing equipment, the command signal will be disconnected and the CMS
locking tone, if it is to be sent (see \(sc\ 5), will be connected within\ 
60\ ms. 
.PP
6.4.5
When the cessation of the command signal is recognized by the
responding equipment the command acknowledgement signal is disconnected and
the measurement tone is connected within 60\ ms.
.PP
6.4.6
The time required for the directing equipment to detect the
cessation of the command acknowledgement signal and connect the measuring
equipment will not be less than 60 nor more than 120\ ms. However, it should 
be as close to 60\ ms as possible to reduce the probability of CMS switching 
during noise measurement.
.PP
6.4.7
The level measurement should be completed within 500\ ms after
connection of the measuring equipment. When the measurement is completed, 
the measuring equipment will be disconnected and the CMS locking tone mentioned 
in \(sc\ 6.4.4, if present, will be disconnected. 
.PP
6.4.8
Following disconnection of the CMS locking tone mentioned in
\(sc\ 6.4.7, a MF command signal will be connected. The interval between 
the tone and the signal will be 55\ \(+-\ 5\ ms. If, however, the CMS locking 
tone was not 
sent, the command signal will be connected 55\ \(+-\ 5\ ms after the measuring
equipment has been disconnected.
.PP
6.4.9
When the MF command signal is recognized by the responding
equipment, the measurement tone will be removed and a multi\(hyfrequency 
command acknowledgement signal will be transmitted. The interval between 
cessation of the measurement tone and the commencement of the MF command 
acknow 
ledgement  signal will be\ 55\ \(+-\ 5\ ms.
.PP
6.4.10
The recognition of the command acknowledgement signal by the
directing equipment will cause the disconnection of the command signal 
and the connection of the measurement tone within 60\ ms of the end of 
the command 
signal.
.PP
6.4.11
When the cessation of the MF command signal is detected by the
responding equipment, the command acknowledgement signal will be disconnected 
and the CMS locking tone, if provided in the responding equipment, will 
be 
connected within 60\ ms of the end of the command acknowledgement signal.
.PP
6.4.12
The time required for the responding equipment to detect the
cessation of the command signal and connect the measuring equipment will 
not be less than 60 nor more than 120\ ms. However, it should be as close 
to 60\ ms as possible to reduce the probability of CMS switching during 
noise 
measurement.
.PP
6.4.13
The measurement should be completed within 500\ ms after the
connection of the measuring equipment. When the measurement is completed, 
the measuring equipment will be disconnected. 
.bp
.PP
6.4.14
When the responding equipment is ready to transmit measurement
results information to the directing equipment, the CMS locking tone mentioned 
in \(sc\ 6.4.11 will be disconnected if it has been sent. The first MF 
pulse to be used for the transmission of results will follow after an interval 
of 55\ \(+-\ 5\ ms from the disconnection of the CMS locking tone. If the 
locking tone was not 
sent, the first MF pulse will be sent within 60\ ms after disconnection 
of the measuring equipment. 
.PP
6.4.15
Measurement result information will be transmitted as three
MF pulses in the form of a prefix followed by two digits of Codes\ 1 to\ 10 as
appropriate (see Table\ 4/O.22). The last two digits will be sent in order of
significance (most significant digit first). The pulse\(hylength will be 
55\ \(+-\ 5\ ms and the interval between pulses 55\ \(+-\ 5\ ms. The digit 
zero is represented by 
Code\ 10.
.PP
6.4.16
If the responding equipment is provided with a CMS locking tone
this tone will be applied within 60\ ms after the third MF pulse has been sent.
.PP
6.4.17
When the third MF pulse is recognized by the directing equipment, the measurement 
tone will be disconnected. A MF command signal will be sent by the directing 
equipment after an interval of 55\ \(+-\ 5\ ms from disconnection of 
the measurement tone. If the responding equipment has sent the CMS locking 
tone mentioned in \(sc\ 6.4.16, this tone will be disconnected on recognition 
by the 
responding equipment of the MF command signal sent by the directing equipment. 
The responding equipment must send the command acknowledgement signal 55\ 
\(+-\ 5\ ms after cessation of the CMS locking tone. If the MF command 
signal sent by the directing equipment is the start of a new measurement 
cycle the new test 
sequence will proceed from the point described in \(sc\ 6.4.4 and will 
consist of a repetition of the sequence in \(sc\(sc\ 6.4.4 to\ 6.4.17. 
.PP
6.4.18
If the foregoing test sequence completes the transmission
measuring programme, the MF command signal mentioned in  \(sc\ 6.4.17 will be
the \fIend of programme signal\fR .
.PP
6.4.19
In the case of all noise measurements, the measurement tone
mentioned in \(sc\(sc\ 6.4.5, 6.4.9, 6.4.10 and 6.4.17 must be replaced 
by a 600\(hyohm terminating resistor. 
.PP
6.4.20
In the case of noise measurements carried out on routes
incorporating a CMS system or on circuits equipped with echo
suppressors/cancellers, to ensure that the CMS locking tone is on in the
direction which is not being measured, the CMS locking tone mentioned in
\(sc\(sc\ 6.4.4, 6.4.11 and\ 6.4.16 must be applied.
.PP
6.4.21
In the case of noise measurements, the responding equipment is
informed of the necessity for the CMS locking tone mentioned in \(sc\ 6.4.20
by the MF command signal, \fImeasure psophometric noise power (with CMS 
locking \fR \fItone applied)\fR (see Table\ 2/O.22). 
.PP
6.4.22
The signal\(hyto\(hytotal\(hydistortion measurement will be carried out
in two steps:
.LP
	a)
	 detection of the total distortion measuring signal using the same method 
as for idle noise but with the 2800\ Hz stop filter replaced by the 1000\(hy1025\ 
Hz rejection filter; 
.LP
	b)
	measuring of the level using the 1004\(hy1020 Hz test
signal at either \(em10 or \(em25\ dBm0 depending on the requested test.
.PP
6.4.23
When making total distortion measurements, the measurement tone
mentioned in \(sc\(sc\ 6.4.5, 6.4.9, 6.4.10 and 6.4.17 must be replaced 
by the proper level total distortion test signal (either \(em10 or \(em25\ 
dBm0). 
.sp 1P
.LP
6.5
	\fIEnd\(hyof\(hyprogramme procedure\fR 
.sp 9p
.RT
.PP
When transmission measurement is complete, the remainder of the
operations will be continued in accordance with \(sc\(sc\ 6.1.4 through 6.1.8,
insofar as they apply.
.RT
.sp 1P
.LP
6.6
	\fIDescription of Layer 2 transmission measuring cycles\fR 
.sp 9p
.RT
.PP
After a compelled MF Code 9 has been used in Layer 1 to enter
Layer\ 2 and MP command acknowledgement has been detected (not waiting 
for it to cease), a MF pulse\(hytype signal is used to select a measurement 
cycle (see 
Table\ 5/Q.22). Some Layer\ 2 measurement cycles contain no\(hysignal intervals 
of a length sufficient to cause a CMS circuit to switch the CMS connecting 
channel. 
.PP
The directing equipment may exit a Layer 2 measurement cycle by
sending a pulse\(hytype MF Code\ 5. If required as specified in \(sc\ 6.4.1, 
the 
directing equipment will then send the echo suppressor/canceller disable 
tone. This assures that echo suppressors and/or cancellers will not interfere 
with 
the compelled MF commands used in Layer\ 1.
.bp
.RT
.sp 2P
.LP
6.7
	\fIDescription of echo canceller testing cycles\fR 
.sp 1P
.RT
.PP
6.7.1 
The test descriptions in this section follow the test sequence
shown in Figures\ 2/O.22 and\ 3/O.22. All gaps between the MF pulse bursts and
other actions shall be 80 \(+- | \ ms unless otherwise specified Timing 
and other 
error conditions are covered in \(sc\ 6.8.
.sp 9p
.RT
.PP
6.7.2 
The director sends a Code 9 MF command to indicate that a Layer\ 2
cycle is being specified.
.PP
6.7.3
When the command signal is received by the responding equipment a MF command 
acknowledgement signal will be transmitted. 
.PP
6.7.4
When the command acknowledgement signal is recognized by the
directing equipment the command signal will be disconnected and a pulsed MF
command sent (\(sc\ 6.7.6).
.PP
6.7.5
When the cessation of the command signal is recognized by the
responding equipment the command acknowledgement signal is disconnected.
.PP
6.7.6
The directing equipment begins the test sequence by transmitting to the 
responder an MF priming burst which specifies a 1020\ Hz test tone and 
automatic test timing (see \(sc\(sc\ 6.3 and\ 6.4 and Table\ 5/O.22).
.PP
6.7.7
Following the initial MF priming burst, the director pauses for
500\ ms to ensure that echo cancellers are enabled. It then sends an 800\ ms
period of 2100\ Hz tone, if required, which disables any echo suppressors 
which may be on the circuit under test and provides lockup for any circuit 
multiplication equipment employed on the circuit.
.PP
6.7.8
Next the director sends test tone (1020 Hz) at \(em10 dBm0 to the
responder while it waits for the responder to measure the received level 
of the tone and return a measurement result. 
.PP
6.7.9
The responder detects the presence of the test tone, measures the level, 
and returns the results of the measurement as pulsed MF digits. It then 
applies test tone (1020\ Hz) at \(em10\ dBm0 toward the director. 
.PP
6.7.10   \fR Upon receipt of the measurement result from the responder, the
director removes test tone and waits for receipt of test tone from the
responder upon which it makes a level measurement.
.PP
6.7.11
The director next sends MF priming bursts to specify the test
sequence for the far\(hyend echo canceller (at the responder end) or for the
near\(hyend echo canceller (at the director end). The following steps test the
far\(hyend echo canceller.
.PP
6.7.12
After sending the priming digit specifying a far\(hyend echo
canceller test, the director applies a noise test signal and waits for an MF
confirmation burst from the responder.
.PP
6.7.13
Upon receiving the priming burst indicating a far\(hyend echo
canceller test, the responder removes the test tone it had been sending,
returns an MF confirmation burst, and provides a quiet termination on both
transmit and receive paths of the circuit under test as the step\ 1 condition.
.PP
6.7.14
Upon receiving the step 1 confirmation MF burst, the director
continues the noise signal for 500\ ms to allow the far\(hyend echo canceller 
to 
zero its internal registers on receipt of the noise signal, and then the
director makes a noise ratio measurement which is an indication of the
far\(hyto\(hynear circuit noise. (This measurement is only an indication 
of the noise performance of the circuit under test but is intended to assure 
that excessive circuit noise problems are not distorting the canceller 
tests.) The director 
then sends an MF priming burst to advance the responder to step\ 2 conditions
and indicates, using two more MF priming bursts, the amount of delay to be
.LP
provided in the 2\ dB gain loop. The requested value of delay in the loop 
should be continuously variable from 0\ to 75\ ms in steps of 1\ ms. After 
the priming 
is completed, it then resumes sending the noise signal toward the responder.
.PP
6.7.15
Upon receiving the step 2 priming from the director, the responder removes 
the step\ 1 terminations, provides a 2\ dB gain loop with the specified 
delay, and returns the step\ 2 priming confirmation MF burst. 
.PP
6.7.16
The director receives the step 2 confirmation MF, continues the
noise signal for 500\ ms to allow the far\(hyend canceller to adjust to the
two\(hytalker state, and then makes a noise ratio measurement of the looped\(hyback 
signal. It then sends an MF priming burst to advance the responder to the 
step\ 3 condition which is a 10\ dB loss loop with the same delay and applies 
the noise signal toward the responder. 
.PP
6.7.17
Upon receiving the step 3 priming MF burst from the director, the responder 
applies the step\ 3 conditions and returns a confirmation MF burst. 
.bp
.PP
6.7.18
The director receives the step 3 confirmation MF burst, continues the noise 
signal for 500\ ms to allow the far\(hyend echo canceller to attempt to 
cancel the looped noise, and then makes a noise ratio measurement of the 
returned signal.
.PP
6.7.19
If the far\(hyend canceller has additional delay stages to be tested, the 
director may repeat the step\ 2 and step\ 3 sequences with the appropriate 
values of delay for testing each stage.
.PP
6.7.20
If there are no additional far\(hyend echo canceller delay stages to test 
and there is no near\(hyend echo canceller to be tested, and if no completed 
tests are to be repeated, nor has a test of the far\(hyend canceller disabler 
been requested, the director sends an MF priming burst instructing the 
responder to return to Layer\ 1. 
.LP
	a)
	If there is no near\(hyend canceller to be tested and the
disabler function of the far\(hyend canceller is to be tested, that
test is performed at this time. (Note that if there is also a
near\(hyend canceller, testing of the far\(hyend canceller disabler
function is done after the near\(hyend canceller has been tested.)
.LP
	b)
	To test the operation of the far\(hyend echo canceller
disabler, it is assumed that the previously described sequence
has been applied to the far\(hyend canceller and exited with the
10\ dB loss loop still applied by the responder while it awaits
additional commands.
.LP
	c)
	The director removes the noise signal used for the 10 dB
loss loop measurement and sends for 800\ ms an echo canceller
disable signal consisting of a 2100\ Hz burst with phase reversed
180\(de | ediodically (see \(sc\ 9.4.1\ c). Upon receipt of this signal,
the disabler in the echo canceller should operate, thus
disabling the canceller action.
.LP
	d)
	The director removes the disable signal, sends an MF priming
burst, and applies the noise signal upon which the far\(hyend
canceller should now take no action. Upon receiving the MF
burst, the responder removes the 10\ dB loss loop with delay,
returns an MF confirmation burst, and applies a 10\ dB loss loop
with no delay. Upon receipt of the MF confirmation burst from
the responder, the director continues the noise signal for
500\ ms and then makes a noise ratio measurement of the returned
signal (which should differ from the previous 10\ dB loss loop
measurement because the canceller has been disabled).
.LP
	e)
	The director then removes the noise signal and sends an MF
priming burst instructing the responder to return to
Layer\ 1.
.PP
6.7.21
If there is a near\(hyend echo canceller to be tested, the director sends 
an MF priming burst which instructs the responder to assume the control 
function and indicates the number of stages to be tested in the near\(hyend 
canceller. The director then applies test tone toward the responder (see
Figure\ 3/O.22).
.sp 9p
.RT
.PP
6.7.22
Upon receipt of the command to assume test control, the responder sends 
a step\ 1 priming MF burst to the director. The responder then applies 
a noise signal and awaits a step\ 1 confirmation MF burst from the director. 
The 3\(hystep sequence proceeds as for the far\(hyend canceller except 
that the responder returns by MF bursts the results of the previous step's 
measurement immediately after sending the MF priming burst requesting the 
next step conditions. 
.PP
6.7.23
When testing of the near\(hyend canceller is completed, the responder sends 
an MF burst indicating return of control to the director and applies test 
tone. 
.LP
	a)
	If testing only the near\(hyend canceller disabler function
has been requested, the director sends an MF priming instructing
the responder to perform a series of operations while the
director applies a quiet termination.
.LP
	b)
	Upon receipt of the disabler test MF priming burst, the
responder removes the test tone and applies for 800\ ms the echo
canceller disable signal (see \(sc\ 9.4.1\ c)). The responder then
sends an MF priming burst and applies the noise test signal.
Upon receipt of the MF priming burst, the director returns an MF
confirmation burst and applies a 10\ dB loss loop with no delay.
Upon receipt of the MF confirmation burst, the responder
continues the noise signal for 500\ ms upon which the disabled
near end canceller should take no action. The responder next
makes a noise ratio measurement of the returned signal. The
responder returns the result as MF bursts, preceded by an MF
burst indicating return of control to the director, and awaits
the next command. Upon receipt of these MF bursts, the director
removes the 10\ dB loss loop and pauses 500\ ms to allow the
canceller to become enabled.
.bp
.LP
	c)
	If testing both near\(hyend and far\(hyend disablers has been
requested, the sequence described in \ b) proceeds to the point
where the 10\ dB noise ratio value, measured with the near\(hyend
canceller disabled, has been returned by the responder. Since
the far\(hyend disabler is also to be tested, the responder returns
test tone (with no pause) and awaits further director command.
.LP
	d)
	Upon receiving the near\(hyend disabler test result, the
director removes the 10\ dB loss loop (no delay) test condition,
sends an MF burst requesting the 10\ dB loop and applies the
noise signal.
.LP
	e)
	Upon receiving the command, the responder removes the test
tone, provides a 10\ dB loss loop (no delay), and returns a
confirmation MF burst.
.LP
	f
)
	Upon receipt of the confirmation MF burst, the
director continues the noise signal for 500\ ms upon which the
disabled far\(hyend canceller should now take no action. The
director then makes a noise ratio measurement of the returned
signal (which should indicate no cancellation).
.LP
	g)
	After making the measurement, the director pauses 500\ ms to
allow the canceller(s) to become enabled.
.PP
6.7.24
The director sends an MF priming burst instructing the responder to return 
to Layer\ 1. Note, at this point any CMS on the circuit may have been released 
during the 500\ ms pause. (See Figures\ 2/O.22 and\ 3/O.22). 
.sp 9p
.RT
.LP
6.8
	\fIEcho canceller test timing and error considerations\fR 
.sp 1P
.RT
.sp 2P
.LP
6.8.1
	\fIAutomatic testing \(em director function\fR 
.sp 1P
.RT
.PP
6.8.1.1
If no response is received from the responder within 5\ seconds of a prompt, 
send a return to Layer\ 1 MF command to the responder and report 
timeout.
.sp 9p
.RT
.PP
6.8.1.2
If an MF burst is received that is out of sequence, undefined, or bad (e.g., 
more than two MF frequencies received) record an MF digit error 
condition,  remain at current position in the test sequence, and restart the
timeout timer. If correct MF is not received by the next timeout, report \*QMF
error\*U and return to Layer\ 1. If correct MF is received, continue with 
normal sequence. 
.PP
6.8.1.3
If an MF error report is received from the responder indicating
that it has perceived receipt of an undefined, out\(hyof\(hysequence, or bad MF
digit, report that disposition, send a return to Layer\ 1 MF to the responder, 
and return to Layer\ 1. 
.sp 1P
.LP
6.8.2
	\fIAutomatic testing \(em responder function\fR 
.sp 9p
.RT
.PP
If an MF burst is out of sequence, undefined, or bad, send a \*Qbad MF\*U 
report MF (Code\ 13) to the director and remain at current position in 
test sequence. 
.RT
.sp 2P
.LP
6.9
	\fIResponder digital loopback test\fR 
.sp 1P
.RT
.PP
6.9.1 
The director sends a Code 9 MF command to indicate that a Layer\ 2 cycle 
is being specified. 
.sp 9p
.RT
.PP
6.9.2
When the command signal is received by the responding equipment an MF command 
acknowledgement signal will be transmitted. 
.PP
6.9.3
When the command acknowledgement signal is recognized by the
directing equipment the command signal will be disconnected and a pulsed
Code\ 3 MF command sent.
.PP
6.9.4
When the cessation of the command signal is recognized by the
responding equipment the command acknowledgement signal is disconnected 
and the digital loopback is applied in response to the Code\ 3. 
.PP
6.9.5
The directing equipment begins the test sequence by transmitting the digital 
test pattern and analyzing the looped return signal. 
.bp
.LP
.rs
.sp 47P
.ad r
\fBFigure 2/O.22, p. 7\fR 
.sp 1P
.RT
.ad b
.RT
.LP
.bp
.LP
.rs
.sp 47P
.ad r
\fBFigure 3/O.22, p. 8\fR 
.sp 1P
.RT
.ad b
.RT
.LP
.bp
.PP
6.9.6
At the conclusion of the test, the director removes the test
pattern and sends a Code\ 5 pulsed multi\(hyfrequency command instructing the
responder to return to Layer\ 1. If a Code\ 5 is not received within 30\ 
seconds of the application of the digital loopback, the responder will 
remove the 
digital loopback and return to Layer\ 1. However, the director may begin 
a new 30\ second test interval by sending a pulsed multi\(hyfrequency Code\ 
3 command 
instead of a Code\ 5 before the current 30\ second interval has expired.
.sp 2P
.LP
6.10
	\fISystem supervision\fR 
.sp 1P
.RT
.PP
6.10.1
Each MF signal must consist of two, and only two, frequencies. If one or 
more than two frequencies are received by the directing equipment, the 
measurement is recorded as faulty and the connection is released. If one 
or 
more than two frequencies are received by the responding equipment it shall 
be arranged to return Code\ 15 in place of the command acknowledgement 
signal 
Code\ 13. The directing equipment will then recognize the signal, record the
measurements as a fault and release the connection.
.sp 9p
.RT
.PP
6.10.2
In the transmission of measurement results, the code signals must comprise 
three, and only three, digits. When this is not the case, the 
measurement is recorded as faulty, and the connection is released.
.PP
6.10.3
Arrangements must be provided at the directing equipment to
monitor the full duration of the programme. In addition to the time out
requirements given in other parts of this specification, if at any time the
programme fails to progress for a period of 20\ to 40\ seconds then the 
test is recorded as faulty and the connection is released. An alarm may 
be given to the maintenance staff. 
.sp 2P
.LP
\fB7\fR 	\fBDescription of\fR 
\fBtests to digital loopback test lines\fR 
.sp 1P
.RT
.PP
7.1
The directing equipment shall be capable of making the following tests 
of measurements to a digital loopback test line as specified in 
Recommendation\ O.11. The type of test to be made will depend on the type of
circuit under test. For all tests it is assumed that any echo suppressors or
cancellers have been disabled before the start of the tests using the
appropriate disabling tone and/or CMS locking tone (see \(sc\ 6.4).
.sp 9p
.RT
.sp 1P
.LP
7.2
	\fIAnalogue tests on all circuit types\fR 
.sp 9p
.RT
.PP
The following tests can be made on analogue, composite
digital/analogue and wholly digital circuits.
.RT
.LP
	a)
	Looped received power at 1020 Hz
.LP
	b)
	Looped received noise with and without the CMS locking tone
.LP
	c)
	Looped signal\(hyto\(hytotal distortion ratio with 1020\ Hz test
signal at \(em10 or \(em25\ dBm0 depending on the requested test.
.PP
\fINote\fR \ \(em\ Looped 400 and 2800 Hz measurements are not being
specified.
.sp 1P
.LP
7.3
	\fIDigital tests on wholly digital circuits\fR 
.sp 9p
.RT
.PP
The directing equipment shall be capable of implementing bit
integrity tests per Recommendation\ O.152 to a digital loopback test line for
wholly digital circuits between digital exchanges. The interval between
removal of the echo canceller/suppressor disabling tone and/or CMS locking
tone is removed and application of the test tone or digital test pattern 
shall be\ 55 \(+- | \ ms. The results shall be capable of being expressed 
in terms of 
estimated percent error free seconds and of estimated bit error ratio. The
length of test intervals shall be specified in seconds from\ 10 to\ 600 as an
input parameter.
.RT
.sp 2P
.LP
\fB8\fR 	\fBProgramming\fR 
.sp 1P
.RT
.PP
The directing equipment will be programmed by manual or automatic means 
at the option of the using Administration or operating agency. 
Information to be supplied to the directing equipment will consist of the
following:
.RT
.LP
	1)
	the identification of the circuit to be tested;
.LP
	2)
	the kind of circuit (CMS, echo suppressor/canceller
equipped,\ etc.) and the kind of signalling system;
.LP
	3)
	the location on the circuit of the echo cancellers:
near\(hyend, far\(hyend or both ends;
.LP
	4)
	sufficient address to identify the particular type of
responding equipment at the incoming international exchange;
.LP
	5)
	the measurements to be made, the nominal values, the
assigned maintenance limits, and whether the canceller disabler
tests are to be performed;
.bp
.LP
	6)
	whether the results are to be recorded by the output
equipment;
.LP
	7)
	whether or not the date and time of the test should be
recorded by the output equipment;
.LP
	8)
	whether there should be a shortened record as described in
\(sc\ 3.7.
.sp 2P
.LP
\fB9\fR \fBSpecifications for transmission measuring apparatus and for\fR 
\fBdisabling tones and locking tones\fR 
.sp 1P
.RT
.PP
The equipment shall perform under the climatic conditions as shown in Recommendation\ 
O.3. 
.RT
.sp 2P
.LP
9.1
	\fIAbsolute power level measuring device\fR 
.sp 1P
.RT
.sp 1P
.LP
9.1.1
	\fISending equipment\fR \v'3p'
.sp 9p
.RT
.LP
	Level measurements:
.LP
	 \fIFrequencies:\fR  | 400\ \(+-\ 5\ Hz, 1020\ +2, | (em7\ Hz and 2800 
\(+- | 4 Hz. 
.LP
	\fIAbsolute power level sent:\fR  | 0\ dBm0\ \(+-\ 0.1\ dB
(or \(em10\ dBm0\ \(+-\ 0.1\ dB, see \(sc\ 6.3).
.LP
	\fIPurity of output:\fR  | ratio of total output to unwanted signal at
least\ 36\ dB.
.LP
	Total distortion test signal:
.LP
	\fIFrequency:\fR  | The nominal frequency of the total distortion test
signal shall be 1020\ Hz.
.FS
It is intended that only a single tone in
the range 1020 +2, | (em7\ Hz will be required and that it can be used for
both 1020\ Hz level and total distortion measurements.
.FE
The
frequency stability of the test signal shall be \(+- | \ Hz.
.LP
	\fIAbsolute power level sent:\fR  | \(em10 dBm0 \(+- | .1\ dB and
\(em25 dBm0 \(+- | .1\ dB.
.LP
	\fIPurity of output:\fR  | ratio of total output to unwanted signal at
least\ 36\ dB.
.LP
	\fIImpedance:\fR  | 600\ ohms balanced \(hy earth free.
.LP
Pending the general adoption of a method for measuring the
balance with respect to earth, the method to be used is left for agreement
between the constructor of the equipment and the Administration concerned.
.FE
Any interface equipment provided to meet the signalling
requirements of the exchange, or for purposes of controlling functions with
the ATME No.\ 2, must be considered as part of the ATME No.\ 2 for the
purpose of determining the balance to earth.
.FE
	\fILongitudinal conversion loss\fR  | (see Figure 1/O.9):\ At least
46\ dB between 300 and 3400\ Hz
\u,\d |
.
.LP
Return loss requirement for older equipment should conform to
greater than 30\ dB at each of the above sending equipment frequencies.
.FE
	\fIReturn loss:\fR  | greater than 46 dB at 1020 Hz and greater
than 30\ dB between 200\ and 4000\ Hz.
.sp 1P
.LP
9.1.2
	\fIReceiving equipment\fR \v'3p'
.sp 9p
.RT
.LP
	\fIFrequency range:\fR  | 390\(hy2820\ Hz.
.LP
	\fIImpedance:\fR  | 600\ ohms balanced \(hy earth free.
.LP
	 \fIBalance with respect to earth:\fR  | at least 46\ dB between 300 and 
3400\ Hz, and below 300\ Hz increasing such that at least 60\ dB at 
50\ Hz is obtained
\u,\d\ 
.
.LP
	\fIReturn loss:\fR  | greater than 46 dB at 1020 Hz and greater
than 30\ dB between 200\ and 4000\ Hz.
.LP
	 \fIMeasuring range:\fR  | from \(em9.9\ dB to +5.1\ dB relative to the 
nominal absolute power level of the \(em4.0\ dBr receiving virtual switching 
point. It 
should be borne in mind that the nominal value of absolute power level 
at the receiving virtual switching point will depend on the absolute power 
level at 
the sending end which may be 0\ dBm0, \(em10\ dBm0 or \(em25\ dBm0 (see 
\(sc\ 6.3). 
.LP
	 \fIAccuracy (absolute):\fR  | at 1020 Hz, \(+- | .2\ dB; at 400 and 2800\ 
Hz, \(+- | .2\ dB referred to the 1020\ Hz value. 
.LP
	\fIResolution (smallest measurement step):\fR  | .1\ dB.
.sp 1P
.LP
9.2
	\fINoise and total distortion measuring apparatus\fR 
.sp 9p
.RT
.PP
\fIWeighting:\fR  | psophometric with requirements as specified in
Recommendation\ O.41.
.RT
.LP
	\fI2800\(hyHz suppression:\fR  | when noise measurements are made on
circuits involving a CMS system or on circuits equipped with echo
suppressors and/or echo
.bp
.LP
cancellers, a stop filter for 2800\ Hz must be  inserted
before carrying out the noise measurement. The requirements for the filter
are given in Figure\ 4/O.22. When measuring white noise with
psophometric weighting the insertion of the filter in the noise
measuring circuit shall not cause a difference from the reading
without the filter of more than\ 1\ dB.
.LP
	\fI1000\(hy1025 Hz suppression:\fR  | when total distortion measurements
are made, a test signal rejection filter
.FS
This is the same rejection filter characteristic as specified in Recommendation\ 
O.132. 
.FE
for 1000 to\ 1025\ Hz must be inserted before carrying out the total distortion 
signal measurement. The requirements for the filter are given in Figure\ 
5/O.22. A bandwidth 
correction for the loss of effective noise bandwidth due to the rejection
filter must be incorporated in the ATME\ No.\ 2 system.
.LP
	 \fIMethod of detection for idle noise:\fR  | the method of detection 
shall be such that if white Gaussian noise, or a sine wave of any frequency 
between 390 and 2820\ Hz is applied at the input in the absence of the 
2800\(hyHz stop 
filter mentioned above, for a period of 375\ \(+-\ 25\ ms, the output indication 
will be the same in each case, within \(+- | \ dB, as that given by the 
CCITT psophometer when the same white Gaussian noise or sine wave is applied 
at its input for a period of 5\ seconds. 
.LP
	 \fIMethod of detection of the signal\(hyto\(hytotal\(hydistortion ratio:\fR 
 | the method of detection of the total distortion signal shall be the 
same as that 
for idle noise as given above except with the 1000 to\ 1025\ Hz rejection 
filter replacing the 2800\ Hz stop filter. In addition, the level of the 
received 
1004\(hy1020\ Hz test signal must be measured and compared with the total
distortion signal to determine the signal\(hyto\(hytotal\(hydistortion 
ratio in\ dB. 
.LP
	\fIMeasuring interval:\fR  | 375\ \(+-\ 25\ ms.
.LP
	\fIImpedance:\fR  | 600\ ohms balanced.
.LP
	\fIInput longitudinal interference loss\fR  | (see Figure 5/O.9):\ at
least 46\ dB between 300 and 3400\ Hz, and below 300\ Hz increasing such
that at least 60\ dB and 50\ Hz is obtained
\u,\d\ 
.
.LP
	\fIReturn loss:\fR  | greater that 46 dB at 1020 Hz and greater
that 30\ dB between 200\ and 4000\ Hz.
.LP
	\fIMeasuring range:\fR  | \(em30 to \(em65\ dBm0p.
.LP
	\fIAccuracy:\fR  | \(+- | \ dB at calibrating frequency from \(em30 to
\(em55\ dBm0p. Between \(em55\ dBm0p and \(em65\ dBm0p an accuracy of \(+- | \ 
dB is allowed, 
but \(+- | \ dB remains desirable.
.LP
	\fIResolution (smallest measurement step):\fR  | 1\ dB.
.sp 1P
.LP
9.3
	\fIDisabling and locking tones\fR 
.sp 9p
.RT
.PP
\(em
	 Echo suppressor/canceller disabling tone: (CMS lock\(hyup or CMS locking 
tone) 
.PP
	\fIFrequency:\fR  | 2100\ Hz\ \(+-\ 8\ Hz.
.PP
	\fILevel:\fR  | \(em12\ dBm0\ \(+-\ 1\ dB.
.PP
	The 2100 Hz tone should be periodically interrupted every
450 | (+- | 5\ ms by a 180 | (+- |  degree phase shift. The interruption 
interval may be asynchronous with the beginning of the tone\(hyon interval. 
.RT
.PP
\(em
	CMS holding tone:
.PP
	\fIFrequency:\fR  | 2800\ Hz\ \(+-\ 14\ Hz.
.PP
	\fILevel:\fR  | \(em10\ dBm0\ \(+-\ 1\ dB.
.RT
.PP
\(em
	For the two tones:
.PP
	\fIImpedance:\fR  | 600\ ohms balanced \(hy earth free.
.PP
	\fIInput longitudinal interference loss\fR  | (see Figure
5/O.9): at least 46\ dB between 300 and
3400\ Hz.
\u,\d\ 
.PP
	\fIReturn loss:\fR  | greater than 46 dB at 1020 Hz and greater than
30\ dB and 4000\ Hz.
.bp
.RT
.LP
.rs
.sp 23P
.ad r
\fBFigure 4/O.22, p.\fR 
.sp 1P
.RT
.ad b
.RT
.LP
.rs
.sp 25P
.ad r
\fBFigure 5/O.22, p.\fR 
.sp 1P
.RT
.ad b
.RT
.LP
.bp
.sp 2P
.LP
9.4
	\fIECTS sending apparatus of the directing and responding\fR 
\fIequipment\fR 
.sp 1P
.RT
.sp 1P
.LP
9.4.1
	\fISignal and tone frequencies\fR \v'3p'
.sp 9p
.RT
.LP
	a)
	test tone: 1020 +2, | (em7 Hz
.LP
	b)
	disable tone: 2100 Hz \(+- |  Hz (echo suppressors and CMS)
.LP
	c)
	disable tone for echo canceller: 2100 Hz \(+- |  Hz.
The 2100 Hz tone should be periodically interrupted every
450 \(+- | 5\ ms by a 180\ \(+- |  degree phase shift. The interruption
interval may be asynchronous with the beginning of the tone\(hyon
interval.
.LP
	d)
	CMS holding tone: 2800 Hz \(+- | 4 Hz
.LP
	e)
	noise signal: the noise test signal is obtained by passing a
wideband quasi random noise source signal through a bandpass
filter network meeting the requirements given in
Table\ 6/O.22.
.ce
\fBH.T. [T6.22]\fR 
.ce
TABLE\ 6/O.22
.ce
\fBFilter response\fR 
.ps 9
.vs 11
.nr VS 11
.nr PS 9
.TS
center box;
cw(42p) | cw(54p) | cw(42p) .
Frequency  (Hz)	Loss | ua\d\u)\d  (dB)	Tolerance  (dB)
_
.T&
cw(42p) | cw(54p) | cw(42p) .
\(= \ 200	\(>=" 30\fB.8\fR	\(em
.T&
cw(42p) | cw(54p) | cw(42p) .
\fB\(=\fR  \ 300	\fB\(>="\fR  21.8\fR	\(+- | .3
.T&
cw(42p) | cw(54p) | cw(42p) .
\fB\(=\fR  \ 560	 {
\fB\(>="\fR
\ 3\fB.8\fR
 }	\(+- | .4
.T&
cw(42p) | cw(54p) | cw(42p) .
\fB\(=\fR  \ 750	\fB\(>="\fR  \ 0.2\fR	\(+- | .2
.T&
cw(42p) | cw(54p) | cw(42p) .
\fB\(=\fR  1000	 {
\fB\(>="\fR
\ 0\fB.8\fR
 }	\(+- | .1
.T&
cw(42p) | cw(54p) | cw(42p) .
\fB\(=\fR  1500	\fB\(>="\fR  \ 0.1\fR	\(+- | .2
.T&
cw(42p) | cw(54p) | cw(42p) .
\fB\(=\fR  1965	 {
\fB\(>="\fR
\ 3\fB.8\fR
 }	\(+- | .4
.T&
cw(42p) | cw(54p) | cw(42p) .
\fB\(=\fR  2400	\fB\(>="\fR  10.9\fR	\(+- | .2
.T&
cw(42p) | cw(54p) | cw(42p) .
\fB\(=\fR  3000	\fB\(>="\fR  22.9\fR	\(+- | .0
.T&
cw(42p) | cw(54p) | cw(42p) .
\fB\(=\fR  4000	\fB\(>="\fR  42.6\fR	\(+- | .0
.T&
cw(42p) | cw(54p) | cw(42p) .
\(>=" 5000	\(= 45\fB.8\fR	\(em
.TE
.LP
\ua\d\u)\d
Excluding any flat insertion loss.
.nr PS 9
.RT
.ad r
\fBTableau 6/O.22 [T6.22], p.\fR 
.sp 1P
.RT
.ad b
.RT
.sp 1P
.LP
9.4.2
	\fISignal and tone levels\fR \v'3p'
.sp 9p
.RT
.LP
	a)
	for loss measurements: \(em10 \(+- | .1 dBm0
.LP
	b)
	disable tone: \(em12 \(+- |  dBm0
.LP
	c)
	CMS holding tone: \(em10 \(+- | Bm0
.LP
	d)
	noise signal: \(em10 \(+- |  dBm0
.sp 1P
.LP
9.4.3
	\fIImpedance\fR 
.sp 9p
.RT
.PP
600 ohms balanced with longitudinal conversion
\u,\d\ 
loss (see Figure\ 1/O.9) of at least 46\ dB between 300\ and 3400\ Hz. Return
loss
greater than 46\ dB at 1020\ Hz and greater than 30\ dB between 200\ and 
4000\ Hz. 
.bp
.RT
.sp 1P
.LP
9.4.4
	\fIPurity of tone output\fR 
.sp 9p
.RT
.PP
Better than 30 dB.
.RT
.sp 1P
.LP
9.4.5
	\fILoop characteristics\fR \v'3p'
.sp 9p
.RT
.LP
	a)
	value of loop delay, 0 to 75 ms \(+- | .2 ms
.LP
	b)
	loop gain 2.0 dB \(+- | .1 dB
.LP
	c)
	loop loss 10.0 dB \(+- | .1 dB
.sp 2P
.LP
9.5
	\fIECTS receiving apparatus of the directing and responding\fR 
\fIequipment\fR 
.sp 1P
.RT
.sp 1P
.LP
9.5.1
	\fIMeasuring ranges\fR \v'3p'
.sp 9p
.RT
.LP
	a)
	for loss measurement: from 0 \(+- | .1 dBm to \(em40 \(+- | .1 dBm
.LP
	b)
	for echo performance and noise measurement: from 0 to
\(em65\ dBm (\(+- | \ dB to \(em55\ dBm, \(+- | \ dB to \(em65\ dBm) using 
a detector 
with response per Recommendation\ O.41, Table\ 1/O.41.
.sp 1P
.LP
9.5.2
	\fIMeasuring interval\fR 
.sp 9p
.RT
.PP
500 \(+- | 5 ms.
.RT
.sp 1P
.LP
9.5.3
	\fIImpedance\fR 
.sp 9p
.RT
.PP
600 ohms balanced with input longitudinal interference
loss
\u,\d
(see Figure\ 5/O.9) of at least 46\ dB between 300\ and
3400\ Hz. Return loss
greater than 46\ dB at 1020\ Hz and greater than 30\ dB between 200\ and 
4000\ Hz. 
.RT
.sp 1P
.LP
9.6
	 \fIECTS command signals exchanged between the directing equipment and\fR 
\fIthe responding equipment\fR 
.sp 9p
.RT
.PP
Test sequence commands and responses exchanged between the
directing and responding equipment will be pulse\(hytype multifrequency (MF)
signals. The signal sender and signal receiver are those specified for the
CCITT No.\ 5 Interregister Signalling System per CCITT Recommendation\ 
Q.153\ [7] and\ Q.154\ [8]. The frequencies and the meaning of the codes 
are given in 
Table\ 7/O.22.
.RT
.sp 2P
.LP
9.7
	\fIDigital pattern generator and detector\fR 
.sp 1P
.RT
.sp 1P
.LP
9.7.1
	\fITest pattern generator\fR 
.sp 9p
.RT
.PP
The test pattern generator shall utilize the pseudorandom test
pattern specified in Recommenda\(hy
tion\ O.152, \(sc\ 2.
.RT
.sp 1P
.LP
9.8
	\fITest pattern detector\fR 
.sp 9p
.RT
.PP
The detector is designed to measure the error performance of the
64\ kbit/s digital path by the direct comparison of the received pseudorandom
test pattern with an identical locally generated pseudorandom test pattern 
as specified in Recommendation\ O.152. 
.bp
.RT
.ce
\fBH.T. [T7.22]\fR 
.ce
TABLE\ 7/O.22
.ce
\fBECTS command signals between director and
.ce
responder
.ce
\fR 
.ce
\fR 
.ps 9
.vs 11
.nr VS 11
.nr PS 9
.TS
center box;
cw(30p) | cw(48p) | cw(120p) .
Code No.	Frequency (Hz)	Meaning
_
.T&
cw(30p) | cw(48p) | lw(120p) .
\ 1	\ 700 + \ 900	Automatic test
.T&
cw(30p) | cw(48p) | lw(120p) .
\ 2	\ 700 + 1100	Reserved
.T&
cw(30p) | cw(48p) | lw(120p) .
\ 3	\ 900 + 1100	Spare 
.T&
cw(30p) | cw(48p) | lw(120p) .
\ 4	\ 700 + 1300	Spare 
.T&
cw(30p) | cw(48p) | lw(120p) .
\ 5	\ 900 + 1300	Return to Layer 1
.T&
cw(30p) | cw(48p) | lw(120p) .
\ 6	1100 + 1300	Step 1 priming MF 
.T&
cw(30p) | cw(48p) | lw(120p) .
\ 7	\ 700 + 1500	Request confirmation
.T&
cw(30p) | cw(48p) | lw(120p) .
\ 8	\ 900 + 1500	Step 2 priming MF
.T&
cw(30p) | cw(48p) | lw(120p) .
\ 9	1100 + 1500	Step 3 priming MF
.T&
cw(30p) | cw(48p) | lw(120p) .
10	1300 + 1500	 {
Request responder assume control
 }
.T&
cw(30p) | cw(48p) | lw(120p) .
11	\ 700 + 1700	Test disablers at both ends
.T&
cw(30p) | cw(48p) | lw(120p) .
12	\ 900 + 1700	 {
Test near\(hyend disabler only
 }
.T&
cw(30p) | cw(48p) | lw(120p) .
13	1100 + 1700	MF error condition
.T&
cw(30p) | cw(48p) | lw(120p) .
14	1300 + 1700	Control returned to director
.T&
cw(30p) | cw(48p) | lw(120p) .
15	1500 + 1700	Spare
_
.TE
.nr PS 9
.RT
.ad r
\fBTable 7/O.22 [T7.22], p.\fR 
.sp 1P
.RT
.ad b
.RT
.sp 2P
.LP
\fB10\fR 	\fBCalibration\fR 
.sp 1P
.RT
.sp 1P
.LP
10.1
	\fIBuilt\(hyin calibration\fR 
.sp 9p
.RT
.PP
The accuracy desired from the ATME No. 2 makes calibration
equipment of laboratory\(hytype accuracy necessary. Such accuracy is seldom
provided by normal maintenance equipment available to repeater station 
staff. Hence, built\(hyin calibration features should be provided. Due 
regard should be paid to the ease of maintenance, and adequate access facilities 
should be 
provided.
.RT
.sp 1P
.LP
10.2
	\fISelf\(hycheck\fR 
.sp 9p
.RT
.PP
The responding and directing equipments shall each incorporate a
local self\(hychecking facility on the transmission measuring unit which will
bring in a local alarm and disable the unit when it is out of tolerance. 
This self\(hycheck should be applied at least daily. If they so wish, user 
Administrations may incorporate arrangements for making this self\(hycheck
automatically.
.RT
.sp 2P
.LP
\fB11\fR 	\fBOptional arrangements\fR 
.sp 1P
.RT
.sp 1P
.LP
11.1
	\fIAutomatic start\fR 
.sp 9p
.RT
.PP
In the long term, the operation of the ATME No. 2 without any
attention by technical personnel will be desirable. The addition of timed
automatic start facilities to the ATME No.\ 2 is required when unattended
operation of the ATME No.\ 2 is intended.
.RT
.sp 1P
.LP
11.2
	\fITimed automatic selection of particular circuits\fR 
\fIor groups of circuits\fR 
.sp 9p
.RT
.PP
It may be desirable to select for test a particular circuit, or
group of circuits, at specified times according to a prearranged programme, 
for example noise measurement during busy and non\(hybusy hours. 
.bp
.RT
.sp 1P
.LP
11.3
	\fIAutomatic repeat attempt\fR 
.sp 9p
.RT
.PP
It may be desirable to incorporate an automatic repeat test
facility for circuits which have been rejected as faulty. The arrangement
should permit an \fIautomatic repeat attempt\fR of the relevant test cycle
immediately following the first test.
.PP
A test cycle is defined as a sequence of measurements commencing with command 
Codes\ 1 to\ 9 and not command Code\ 13. 
.RT
.sp 1P
.LP
11.4
	\fISwitching pad test\fR 
.sp 9p
.RT
.PP
Administrations may use their ATME\ No.\ 2 directing equipment to
test a pad\(hyswitching facility provided at the outgoing end of an international 
circuit. 
.PP
Such testing must not involve any other Administration in making
changes to their signalling, switching or ATME No.\ 2 equipment or to their
operating and maintenance procedures.
.RT
.sp 1P
.LP
11.5
	\fIInterruption and instability during level measurements\fR 
.sp 9p
.RT
.PP
It may be desirable to detect an interruption or a condition of
instability during the level measuring interval at the directing and/or the
responding equipments. If such indications are available they will always be
recorded by the directing equipment (see\ \(sc\ 3.7).
.PP
When an interruption and instability are both detected during a 500\(hyms 
measuring period only the indication of an interruption shall be transmitted 
and recorded.
.RT
.sp 1P
.LP
11.6
	\fINonavailability of responding equipment\fR 
.sp 9p
.RT
.PP
It may happen that, as a result of a failure at the responding end, all 
attempts made at the directing end to set up a call with a particular 
responding equipment will be unsuccessful \(em\ there may be no reply or the
busy tone may be received. As this state of affairs could seriously affect 
the carrying out of a measurement programme as planned, it would appear 
to be 
desirable to ensure either:
.RT
.LP
	\(em
	that this situation should give rise to an alarm signal if
the directing equipment is operating under supervision;
.LP
	\(em
	 or that the directing equipment should be able automatically to select 
an alternative measurement programme if it is operating 
without supervision.
\v'1P'
.ce 1000
ANNEX\ A
.ce 0
.ce 1000
(to Recommendation\ O.22)
.sp 9p
.RT
.ce 0
.ce 1000
\fBSensitivity of the signalling receiver\fR 
.sp 1P
.RT
.ce 0
.PP
A.1
The multi\(hyfrequency signal sender and receiver specified for ATME\ No.\ 
2 is given in Recommendations\ Q.153\ [7] and Q.154\ [8] respectively, 
as used in CCITT Signalling System\ No.\ 5. 
.sp 1P
.RT
.PP
The sending level per frequency equals \(em7\ \(+-\ 1\ dBm0 and therefore 
the nominal receiving level at the \(em4.0\ dBr virtual switching point 
equals 
\(em11\ dBm.
.PP
The operating limits of the multi\(hyfrequency receiver give a minimum
margin of \(+- | \ dB on the nominal absolute level of each received signal 
(i.e. 
taken to mean per frequency).
.PP
Therefore the receiver minimum operate level range at the \(em4.0\ dBr
virtual switching point:
\v'6p'
.RT
.sp 1P
.ce 1000
=\ \(em11\ dBm\ \(+-\ 7\ dB
.ce 0
.sp 1P
.ce 1000
=\ \(em18\ dBm\ to\ \(em4\ dBm
.ce 0
.sp 1P
.LP
.bp
.PP
A.2
The maximum circuit \fIloss\fR  | eviation from nominal over which the 
multi\(hyfrequency signals can be received\ is: 
\v'6p'
.sp 1P
.ce 1000
(\(em11 \(em\ 1)\ \(em\ (\(em18)\ =\ +6.0\ dB
.ce 0
.sp 1P
.LP
.sp 1
and the minimum circuit \fIloss\fR  | eviation from nominal over which the
multi\(hyfrequency signals can be received is:
\v'6p'
.sp 1P
.ce 1000
(\(em11 +\ 1)\ \(em\ (\(em4)\ =\ \(em6.0\ dB
.ce 0
.sp 1P
.PP
.sp 1
A.3
Therefore the circuit \fIloss\fR  | eviation limits between which
multi\(hyfrequency signals can be received is \(+- | .0\ dB about the nominal 
loss, 
whereas ATME\ No.\ 2 is capable of measuring deviations greater than these
values (see\ \(sc\ 9.1 of this Recommendation).
.PP
A.4
Although the specification for the multi\(hyfrequency signal receiver (Recommendation\ 
Q.154\ [8]) stipulates that a received signal may vary \(+- | \ dB 
about the nominal receive level of \(em7\ dBm0, Recommendation\ Q.154\ [8] also
states that the receiver shall not operate to a signal 17\ dB below the 
nominal received signal level, which means that in the range \(em14 to 
\(em24\ dBm0 the 
receiver may or may not operate. It is to be expected therefore that somewhere 
within this range the receiver will cease to operate. 
.PP
A.5
In practice multi\(hyfrequency receivers are set up to operate to a minimum 
signal level in this range of \(em14 to \(em24\ dBm0. Therefore signalling 
would normally be possible over a circuit with a loss greater than that 
given in \(sc\ A.3. In those cases where the multi\(hyfrequency receiver 
fails to 
operate the circuit test would still be recorded as mentioned in \(sc\ 
6.10.3 of 
this Recommendation.
.sp 2P
.LP
	\fBReferences\fR 
.sp 1P
.RT
.LP
[1]
	 CCITT Recommendation \fIRoutine maintenance schedule for international\fR 
\fIpublic telephony circuits\fR , Vol.\ IV, Rec.\ M.605. 
.LP
[2]
	CCITT Recommendation \fIEcho Cancellers\fR Vol.\ III, Rec.\ G.165
.LP
[3]
	CCITT Recommendation \fIInternational telephone circuits \(em principles\fR ,
\fIdefinitions and relative transmission levels\fR , Vol.\ IV,
Rec.\ M.560, \(sc\ 2.
.LP
[4]
	CCITT Recommendation \fIError performance of an international digital\fR 
\fIconnection forming part of an integrated services digital network\fR ,
Vol.\ III, Rec.\ G.821.
.LP
[5]
	 CCITT Recommendation \fIStability and echo\fR , Vol.\ III, Rec.\ G.131, 
\(sc\ 2.1. 
.LP
[6]
	CCITT Recommendation \fIAccess points for International Telephone\fR 
\fICircuits\fR Vol.\ IV, Rec.\ M.565.
.LP
\fR [7]
	CCITT Recommendation \fIMultifrequency signal sender\fR , Vol.\ VI,
Rec.\ Q.153.
.LP
[8]
	CCITT Recommendation \fIMultifrequency signal receiver\fR , Vol.\ VI,
Rec.\ Q.154.
.LP
.rs
.sp 16P
.sp 2P
.LP
\fBMONTAGE: RECOMMANDATION O.25 SUR LE RESTE DE CETTE PAGE\fR 
.sp 1P
.RT
.LP
.bp