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.\"                 Not Copyright ( c) 1991 
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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'
.sp 1P
.LP
\fBMONTAGE:\ \fR REC.\ Q.412 EN T\* | TE DE CETTE PAGE
.sp 9p
.RT
.sp 1P
.ce 1000
\v'12P'
\fB2.3\ \ CLAUSES\ FOR\ TRANSMISSION\ LINE\ SIGNALLING\ EQUIPMENT\fR 
.ce 0
.sp 1P
.sp 2P
.LP
\fBRecommendation\ Q.414\fR 
.RT
.sp 2P
.sp 1P
.ce 1000
\fB2.3.1\ \ \fR \fBSIGNAL\ SENDER\fR 
.EF '%	Fascicle\ VI.4\ \(em\ Rec.\ Q.414''
.OF '''Fascicle\ VI.4\ \(em\ Rec.\ Q.414	%'
.ce 0
.sp 1P
.sp 2P
.LP
2.3.1.1
	\fISignalling frequency\fR 
.sp 1P
.RT
.PP
The nominal value of the signalling frequency is 3825 Hz. Measured at the 
sending point, the frequency variation from the nominal value must not 
exceed \(+- | \ Hz. 
.RT
.sp 1P
.LP
2.3.1.2
	\fISend level\fR 
.sp 9p
.RT
.PP
The send level of the signalling frequency, measured at the group distribution 
frame or an equivalent point, must be\ \(em20 \(+- | \ dBm0. 
.RT
.sp 1P
.LP
2.3.1.3
	\fILeaks\fR 
.sp 9p
.RT
.PP
The level of the signal frequency which may be transmitted to line as a 
leak current (e.g.\ when static modulators are used), must be at least 
25\ dB below the level of the signalling tone.
.RT
.sp 1P
.LP
2.3.1.4
	\fIPhase distribution of the signalling frequencies\fR 
.sp 9p
.RT
.PP
As the signalling frequency is sent on any circuit in idle state, the addition 
of these tones in moments of low traffic may give rise to the 
following phenomena on certain transmission systems:
.RT
.LP
	\(em
	high peak voltage on the line caused by the signalling tones
and involving the possibility of overloading the system;
.LP
	\(em
	intelligible crosstalk due to third\(hyorder intermodulation;
.LP
	\(em
	unwanted tones coming from second\(hyorder intermodulation
products and occurring within sound\(hyprogramme circuits.
.PP
The following special measures must be taken to avoid these
effects:
.PP
One method recommended is to inject the signalling frequencies with
random\ 0 and\ \(*p radian phases in the channels. An equivalent method 
is to use 
carrier frequencies of which the phases are randomly distributed\ 0 and\ \(*p
radians. With these methods the probability of occurrence of\ 0 and\ \(*p 
radian 
phases should be\ 0.5
.FS
For further details on the method of random
distribution of the phases of frequency\ 3825\ Hz, see: Ekholm, O. and
Johannesson, N.O.: \*QLoading Effects with Continuous Tone Signalling\*U, 
English edition of \fITELE\fR , No.\ 2, 1969. For further details on a 
systematic method of phase distribution, see: Rasch,\ J. and Kagelmann,\ 
H.: \*QOn Measures for 
.PP
Reducing Voltage Peaks and Distortion Noise on Carrier Transmission Paths 
with Single Channel Supervision\*U, \fINachrichtentechnische Zeitschrift\ 
(NTZ)\fR , 22 
(1969), No.\ 1, pp.\ 24\(hy31.
.FE
.
.PP
Other methods may be used provided they give comparable results.
.bp
.RT
.sp 1P
.LP
2.3.1.5
	\fIProtection of the signalling channel at the sending end\fR 
.sp 9p
.RT
.PP
This signalling channel must be protected at the sending end
against disturbance from the associated and the adjacent speech channel.
.PP
When a sinewave at\ 0\ dBm0 level is applied to the audio\(hyfrequency
input of the associated channel, the level measured at the group distribution 
frame or at an equivalent point must not exceed the levels shown in 
Figure\ 6/Q.414.
.PP
When a sinewave of frequency\ \fIf\fR is applied to the
audio\(hyfrequency input of the adjacent channel it produces two signals that
appear on the frequency scale of Figure\ 6/Q.414 as having the frequencies 
.PP
(4000\ +\ \fIf\fR ) and (4000\ \(em\ \fIf\fR ). The level of the (4000\ 
+\ \fIf\fR ) signal, measured at the group distribution frame or at an 
equivalent point, 
shall not be higher than \(em33\ dBm0 when the sinewave with frequency\ 
\fIf\fR is 
applied to the audio\(hyfrequency input of the adjacent channel at a level 
shown in Figure\ 6/Q.414 for the frequency of (4000\ +\ \fIf\fR ). The 
level of the 
(4000\ \(em\ \fIf\fR ) signal, measured at the group distribution frame 
or at an 
equivalent point, shall not be higher than \(em33\ dBm0 when the sinewave with
frequency\ \fIf\fR is applied to the audio\(hyfrequency input of the adjacent 
channel at any level below the value shown in Figure\ 6/Q.414 for the frequency 
(4000\ \(em\ \fIf\fR ).
.RT
.LP
.rs
.sp 23P
.ad r
\fBFIGURE 6/Q.414, p.\fR 
.sp 1P
.RT
.ad b
.RT
.PP
When the Go path is looped to the Return path at the group
distribution frame or an equivalent point, the signal receiver must not 
change condition when: 
.LP
	\(em
	 the click generator shown in Figure\ 7/Q.414 is connected to the associated 
speech channel or to the adjacent speech channel 
at the very point where this channel is connected to
the switching equipment;
.LP
	\(em
	to take the most difficult circumstances possible, the
channel level adjusting devices are set to such values encountered
in practice which give rise to the worst disturbance;
.LP
	\(em
	gain is introduced in the loop at the group distribution
frame or at the equivalent point, so that the receive level at the
point in question is +3\ dBm0.
.bp
.LP
.rs
.sp 10P
.ad r
\fBFIGURE 7/Q.414, p.\fR 
.sp 1P
.RT
.ad b
.RT
.sp 1P
.LP
2.3.1.6
	\fIResponse time\fR 
.sp 9p
.RT
.PP
The response time of the signal sender is defined as the interval between 
the instant when the change signalling condition command is applied to 
the sender and the instant at which the envelope of the signalling frequency, 
measured at the group distribution frame or at an equivalent point, reaches 
half of its value in the steady state. For each of the two possible changes 
of signalling condition the response time must be less than\ 7\ ms. 
.RT
.LP
.sp 2P
.LP
\fBRecommendation\ Q.415\fR 
.RT
.sp 2P
.sp 1P
.ce 1000
\fB2.3.2\ \ \fR \fBSIGNAL\ RECEIVER\fR 
.EF '%	Fascicle\ VI.4\ \(em\ Rec.\ Q.415''
.OF '''Fascicle\ VI.4\ \(em\ Rec.\ Q.415	%'
.ce 0
.sp 1P
.sp 2P
.LP
2.3.2.1
	\fIRecognition of the\fR tone\(hyon \fIcondition\fR 
.sp 1P
.RT
.PP
The receiver must have assumed or assume the \fItone\(hyon\fR condition
when at the group distribution frame or at an equivalent point:
.RT
.LP
	\(em
	the level of the received frequency has risen to\ \(em27\ dBm0 or  more;
.LP
	\(em
	its frequency lies between 3825\ \(+-\ 6\ Hz.
.PP
The level of \(em27\ dBm0 specified above does not preclude the use of 
individual adjustments in the channel translating equipment to compensate 
for constant level deviations. 
.sp 1P
.LP
2.3.2.2
	\fIRecognition of the\fR tone\(hyoff \fIcondition\fR 
.sp 9p
.RT
.LP
.PP
The receiver must have assumed or assume the \fItone\(hyoff\fR condition 
when the level of the test frequency, at the group distribution frame or 
at an equivalent point, has dropped to the values shown in 
Figure\ 8/Q.415.
.RT
.LP
.rs
.sp 15P
.ad r
\fBFIGURE 8/Q.415, p.\fR 
.sp 1P
.RT
.ad b
.RT
.LP
.bp
.sp 1P
.LP
2.3.2.3
	\fIProtection against near\(hyend disturbances\fR 
.sp 9p
.RT
.PP
The signal receiver must not change state when any one of the
following disturbing signals is applied at the 4\(hywire output of the
associated speech channel looped at the group distribution frame or at an
equivalent point:
.RT
.LP
	\(em
	a sinusoidal signal whose level as a function of the
frequency is shown in Figure\ 9/Q.415,
.LP
	\(em
	 a transient signal produced by the click generator (described in \(sc\ 
2.3.1.5\ above) applied at the point where the channel is 
connected to the switching equipment, all level adjusting
devices being set to such values encountered in practice
which give rise to the worst disturbance.
.LP
.rs
.sp 13P
.ad r
\fBFIGURE 9/Q.415, p.\fR 
.sp 1P
.RT
.ad b
.RT
.sp 1P
.LP
2.3.2.4
	\fIOverall response time of signal sender and receiver\fR 
.sp 9p
.RT
.PP
When the modulation equipment is looped at the group distribution frame 
or at an equivalent point, the overall response time is defined as the 
interval between the instant when a change signalling condition command is
applied to the sender and the moment when the changed signalling condition
appears at the receiver output. For each of the two possible changes of
signalling condition, the overall response time must be less than 30\ ms.
.RT
.LP
.sp 1P
.LP
2.3.2.5
	\fIInterference by carrier leaks\fR 
.sp 9p
.RT
.PP
The requirements stated in \(sc\(sc\ 2.3.2.1, 2.3.2.3 and 2.3.2.4 above
must be fulfilled in the presence of carrier leaks.
.PP
It is assumed that:
.RT
.LP
	\(em
	when the receive level of the signalling tone is at its
nominal value at the group distribution frame or an equivalent
point, each carrier leak is present at a level of\ \(em26\ dBm0;
.LP
	\(em
	 the level of the carrier leak varies proportionally with any variations 
in the level of the signalling tone. 
.sp 1P
.LP
2.3.2.6
	\fIInterference by pilots\fR 
.sp 9p
.RT
.PP
The specified signalling system is not intended to work in the
presence of those pilots specified by CCITT having a frequency differing by
140\ Hz from the nearest multiple of 4\ kHz (see Recommendation\ M.460).
.PP
On the other hand, the requirements stated in \(sc\(sc\ 2.3.2.1, 2.3.2.2,
2.3.2.3, 2.3.2.4 and 2.3.2.5 above must be met in the presence of any other
pilot recommended by the CCITT.
.PP
It is assumed that variations in level of the pilot and of the
signalling tones are correlated.
.bp
.RT
.LP
.sp 2P
.LP
\fBRecommendation\ Q.416\fR 
.RT
.sp 2P
.sp 1P
.ce 1000
\fB2.4\ \ \fR \fBINTERRUPTION\ CONTROL\fR 
.EF '%	Fascicle\ VI.4\ \(em\ Rec.\ Q.416''
.OF '''Fascicle\ VI.4\ \(em\ Rec.\ Q.416	%'
.ce 0
.sp 1P
.sp 2P
.LP
2.4.1
	\fIGeneral\fR 
.sp 1P
.RT
.PP
In System R2, removal of the tone corresponds to the sending of the seizing 
and answer signals. Steps must be taken, therefore, to guard against 
unwanted interruption of the signalling channels resulting in false signalling. 
Special devices monitor a number of circuits and transmit an indication 
to each individual equipment as soon as an interruption occurs. The whole 
protection 
system against the effect of interruptions is designated by the term
\fIinterruption control\fR .
.PP
In each case, the response time of the interruption control must be
based on the time required to recognize the signalling condition.
.PP
The interruption control systems in the two directions of transmission 
operate independently of each other. 
.PP
The interruption control specified uses the group pilot to detect
interruptions.
.RT
.sp 1P
.LP
2.4.2
	\fIMode of operation of interruption control\fR 
.sp 9p
.RT
.PP
For each direction of transmission of a carrier circuit connection the 
equipment for interruption control comprises: 
.RT
.LP
	\(em
	a group pilot generator at the outgoing end;
.LP
	\(em
	a pilot receiver and a wiring system for signalling the
interruption at the incoming end.
.PP
In principle, the existing pilots of the carrier system will be
used.
.PP
The receiver at one end supervises the pilot transmitted by the other end. 
When a considerable fall in the level of the pilot is detected it is 
assumed that an interruption has occurred on the signalling channels associated 
with the carrier circuits. The interruption control equipment then reacts 
to 
prevent the unwanted transmission of certain signals on those circuits which
have already been seized or to ensure that idle circuits are blocked.
.PP
Figure\ 10/Q.416 shows functionally an arrangement where the pilot
receiver controls the relay sets of interrupted circuits.
.RT
.LP
.PP
To ensure proper interruption control, it is essential that the
individual transmission or switching equipments should not react to any 
change of signalling state due to a fault. The action initiated by the 
interruption 
control must therefore be completed in less time than the sum of the response 
time of the signalling receiver and the recognition time for the \fItone\(hyoff\fR 
condition caused by interruption of the signalling channel. Again,
to prevent the unwanted transfer of certain signals, interruption control,
during re\(hyestablishment of the pilot, must return to \fIalarm\ off\fR 
after an 
interval long enough for the signalling equipment to revert to normal.
.PP
To operate independently for each direction of transmission the
incoming end interruption control supervises only the forward direction 
and, if necessary, initiates an operation at the outgoing end via the line 
signalling system. Conversely, interruption control at the outgoing end 
supervises the 
backward direction of transmission only.
.PP
Blocking of a circuit at the outgoing end therefore takes place in two 
different ways: 
.RT
.LP
	\(em
	immediate blocking by intervention of interruption control at
the outgoing end;
.LP
	\(em
	blocking on recognition in the backward direction of the
\fItone\(hyoff\fR condition caused by interruption control
intervention at the incoming end.
.PP
When the transmission system is re\(hyestablished, interruption
control reverts to normal and the signalling equipment must automatically
revert to normal operating.
.PP
Since the action to be taken on the individual circuits differs
according to their state at the time the fault occurs, the different
possibilities are dealt with in detail below.
.bp
.RT
.LP
.rs
.sp 26P
.ad r
\fBFigure 10/Q.416, p.5\fR 
.sp 1P
.RT
.ad b
.RT
.sp 1P
.LP
2.4.2.1
	 \fIMode of operation of interruption control at the incoming\fR \fIend\fR 
\fI(transmission interrupted in the forward direction)\fR \v'3p' 
.sp 9p
.RT
.LP
	a)
	\fICircuit in idle state\fR 
.PP
Transition of interruption control to alarm brings about:
.RT
.LP
	i)
	removal of the tone in the backward direction by locking
of the sending unit in the \fItone\(hyoff\fR condition;
.LP
	ii)
	locking of the receiving unit in its position, i.e. in the
\fItone\(hyon\fR condition.
.PP
The effect of operation i) is to block the circuit at the outgoing end 
against possible seizing; operation\ ii) prevents incorrect recognition 
of seizing of the incoming circuit. 
.PP
Return of interruption control to normal ensures return to the idle
state of the circuits affected by the fault, by switching sending units 
at the incoming end to the \fItone\(hyon\fR condition. 
\v'3p'
.RT
.LP
	b)
	\fICircuit seized prior to answered state\fR 
.PP
Transition of interruption control to alarm brings about:
.RT
.LP
	i)
	locking of the sending unit in its position, i.e. in the
\fItone\(hyon\fR condition;
.LP
	ii)
	locking of the receiving unit in its position, i.e. in the
\fItone\(hyoff\fR condition;
.LP
	iii)
	start of a time\(hyout device which after a certain interval
clears the chain beyond the faulty circuit; this timing
arrangement may be the one specified in
Recommendation\ Q.118, \(sc\ 4.3.3.
.bp
.PP
Operation i) prevents the transfer of an answer signal while
interruption control is in action. If the called subscriber answers before 
the time out delay mentioned in iii) above has elapsed, then the timer 
is stopped. For existing equipment this requirement may not apply. If the 
called subscriber clears while interruption control is active, the part 
of the connection beyond the faulty circuit must be released immediately. 
.PP
Operation iii) prevents blocking of the called subscriber's line if
the fault persists; short breaks, on the other hand, have no effect.
.PP
When the caller clears, operations i) and ii) block the faulty circuit 
against any new seizure even when the backward signalling channel is still 
intact; since the release\(hyguard signal has not been sent the outgoing 
circuit cannot return to the idle state. 
.PP
When interruption control reverts to normal before the called
subscriber has answered, the call may still mature normally, provided the
caller is holding.
.PP
If the called subscriber has answered during the time\(hyout delay and
the interruption control reverts to normal with both the calling and called
subscribers holding, the answer signal is sent immediately.
.PP
If at the moment when interruption control reverts to normal the
called subscriber has already cleared, operation ii) ensures that in all 
cases the release\(hyguard sequence takes place as in \(sc\ 2.2.2.6\ a) 
above (either 
.PP
immediately if the outgoing exchange has already sent the clear\(hyforward 
signal or when the caller clears). If, on the other hand, the called subscriber 
is 
still holding and the outgoing exchange is already sending the clear\(hyforward
signal when interruption control reverts to normal the circuit returns 
to the idle state at the outgoing end as described in \(sc\ 2.2.2.6\ b) 
above. 
\v'3p'
.RT
.LP
	c)
	\fICircuit in answered state\fR 
.PP
Transition of interruption control to alarm brings about:
.RT
.LP
	i)
	locking of the sending unit in its position, i.e. in
the \fItone\(hyoff\fR condition;
.LP
	ii)
	locking of the receiving unit in its position, i.e.
in the \fItone\(hyoff\fR condition.
.PP
When the caller clears, operation i) blocks the faulty circuit
against any new seizure, even when the backward signalling channel is still
intact; since the release\(hyguard signal has not been sent, the outgoing 
circuit cannot return to the idle state. 
.PP
When the called subscriber clears, the part of the connection beyond the 
faulty circuit (including the called subscriber's line) must be released 
immediately.
.PP
When interruption control reverts to normal with both subscribers
still on the line, the connection is maintained.
.PP
When the caller has already cleared by the time the interruption
control reverts to normal, the release\(hyguard sequence is carried out as in
Recommendation\ Q.412, \(sc\ 2.2.2.6\ b)\ or\ c).
\v'3p'
.RT
.LP
	d)
	\fICircuit in clear\(hyback state\fR 
.PP
Transition of interruption control to alarm causes:
.RT
.LP
	i)
	locking of the sending unit in its position, i.e. in
the \fItone\(hyon\fR condition;
.LP
	ii)
	locking of the receiving unit in its position, i.e.
in the \fItone\(hyoff\fR condition;
.LP
	iii)
	immediate release of the part of the connection
beyond the faulty circuit (including the called
subscriber's line).
.PP
When interruption control reverts to normal, the release\(hyguard
signal is sent as in Recommendation\ Q.412, \(sc\ 2.2.2.6\ c) as soon as the
clear\(hyforward signal is recognized.
\v'3p'
.LP
	e)
	\fICircuit in release\fR 
.PP
When interruption control functions after a
clear\(hyforward signal has been recognized at the incoming end, it
causes:
.RT
.LP
	i)
	 locking of the sending unit in the \fItone\(hyoff\fR  | ondition; if 
at the instant interruption control 
operates, the \fItone\(hyon\fR condition exists in the backward
direction, it will be switched to the \fItone\(hyoff\fR condition
following recognition of the clear\(hyforward signal and
locking in the \fItone\(hyoff\fR condition can take place as
prescribed;
.LP
	ii)
	locking of the receiving unit in its position,
i.e.\ in the \fItone\(hyon\fR condition.
.bp
.PP
The effect of operation i) is to guard the faulty circuit from a new seizure 
at the outgoing exchange. 
.PP
Operation ii) ensures the release of the part of the connection beyond 
the faulty circuit (including the called subscriber's line). 
.PP
When interruption control reverts to normal the \fItone\(hyon\fR  | ondition 
is established in the backward direction and causes the circuit at the 
outgoing exchange to return to the idle state. 
.RT
.sp 1P
.LP
2.4.2.2
	 \fIMode of operation of interruption control at the outgoing\fR \fIend\fR 
 | transmission in the backward direction interrupted) 
\v'3p'
.sp 9p
.RT
.LP
	a)
	\fICircuit in idle state\fR 
.PP
Transition of interruption control to alarm is
immediately followed by blocking of the outgoing circuit.
\v'3p'
.RT
.LP
	b)
	\fICircuit seized but not in answered state (including\fR 
\fIclear\(hyback)\fR 
.LP
	i)
	Transition of interruption control to alarm
causes locking of the receiving unit in its position,
i.e.\ the \fItone\(hyon\fR condition. This operation prevents
recognition of an answer signal or return to the
\fIanswered\fR state should the called subscriber have
cleared.
.LP
	ii)
	As soon as a clear\(hyforward signal is sent on the part
of the connection preceding the faulty circuit, it must be
retransmitted; the tone must therefore be established in
the forward direction to ensure, assuming that the forward
signalling channel is left intact, that the part of the
connection beyond the faulty circuit is released.
.LP
	iii)
	When interruption control reverts to normal, the
tone may already have been sent in the forward direction
as a clear\(hyforward signal. If the forward signalling
channel has remained intact, recognition at the incoming
end of the \fItone\(hyon\fR condition will have caused generation
of the release\(hyguard sequence which, because of the fault,
will not have been received at the outgoing end.
Exceptionally, therefore, return of the outgoing circuit
to the idle state must take place simply on recognition of
\fItone\(hyon\fR in the backward direction without necessarily
taking into account time\(hyout T1.
\v'3p'
.LP
	c)
	\fICircuit in answered state\fR 
.PP
In this case transition of interruption control to alarm
does not cause immediate action. A clear\(hyforward signal sent on the 
part of the connection preceding the faulty circuit must be repeated forward 
to ensure 
that, if the forward signalling channel is left intact, the part beyond the
faulty circuit is cleared.
.PP
Once the interruption control reverts to normal the
connection is maintained provided the caller and the called subscriber are
still holding. On the other hand, by the time the interruption control 
reverts to normal the clear\(hyforward signal may already have been sent 
and the situation will be the one described in \(sc\ 2.4.2.2\ b),\ iii). 
\v'3p'
.RT
.LP
	d)
	\fICircuit in release\fR 
.PP
[See \(sc 2.4.2.2\ b), iii).]
.RT
.sp 1P
.LP
2.4.3
	\fIClauses on interruption control equipment\fR 
.sp 9p
.RT
.PP
Adoption of thresholds with widely differing levels makes for
economy in the design of interruption control equipment. Against this must 
be set the fact that the device cannot cope with the effects of certain 
slow drops in level. However, the probability of these occurring in practice 
is very 
small.
.RT
.sp 1P
.LP
2.4.3.1
	\fIPilots\fR 
.sp 9p
.RT
.PP
Interruption control uses the 84.08 kHz group pilot or by bilateral agreement 
and, at the request of the receiving end country, the 104.08\ kHz 
group pilot.
.PP
However, if the ends of the supergroup link coincide with the end
of the five group links it is carrying, the supergroup pilot may also be
used.
.RT
.LP
.sp 1P
.LP
2.4.3.2
	\fIAlarm\(hyon threshold\fR 
.sp 9p
.RT
.PP
Interruption control must pass to \fIalarm\(hyon\fR  | hen the pilot level, 
measured at the group distribution frame or at an equivalent point, drops 
to 
\(em29\ dBm0.
.bp
.RT
.sp 1P
.LP
2.4.3.3
	\fIAlarm\(hyoff threshold\fR 
.sp 9p
.RT
.PP
Interruption control must revert to \fIalarm\(hyoff\fR  |  i.e. normal 
when the pilot level, measured at the group distribution frame or at an 
equivalent point, rises to \(em24\ dBm0. 
.RT
.sp 1P
.LP
2.4.3.4
	\fIResponse time for a drop in level\fR 
.sp 9p
.RT
.PP
Interruption control must pass from normal to alarm\(hyon within an
interval\ \fIt\fR \(da such that:
.RT
.sp 1P
.ce 1000
5\ ms\ \(=\ \fIt\fR \(da\ \(=\ \fIt\fR\d\fIr\fR\\d\fIs\fR\u\ \dm\\di\\dn\u\ 
+\ 13\ ms 
.ce 0
.sp 1P
.LP
when the pilot level, measured at the group distribution frame or at an
equivalent point, suddenly drops from its nominal level to \(em33\ dBm0.
.LP
.PP
In the above formula, \fIt\fR\d\fIr\fR\\d\fIs\fR\u\dm\\di\\dn\uis the minimum
response time of the signalling receiver for a drop in level, taking into
account a possible variation of\ \(+- | \ dB in the signalling tone level 
from its 
nominal value, the level being measured on the receiving side of the group
distribution frame or at an equivalent point.
.PP
If the value (40\ \(+-\ 10)\ ms is exclusively applied, it is possible 
to use the minimum value of 30\ ms instead of 13\ ms for the interruption 
control 
device.
.FE
The figure of\ 13\ ms in the above formula is derived on the assumption 
that the output of the interruption control equipment acts upon the input 
of 
the device which regulates the recognition time for the \fItone\(hyon\fR and
\fItone\(hyoff\fR conditions (20\ \(+-\ 7\ ms)
, i.e.\ absence of a direct current
signal at this input for a period of up to 13\ ms has no relevance.
.RT
.sp 1P
.LP
2.4.3.5
	\fIResponse time for rise in level\fR 
.sp 9p
.RT
.PP
Interruption control must revert from the alarm\(hyon to normal in an interval\ 
\fIt\fR \(ua such that: 
.RT
.sp 1P
.ce 1000
\fIt\fR\d\fIr\fR\\d\fIs\fR\u\ \dm\\da\\dx\u\ \(em\ 13\ ms\ \(=\ \fIt\fR 
\(ua\ \(=\ 500\ ms 
.ce 0
.sp 1P
.LP
when the pilot level, measured at the group distribution frame or at an
equivalent point, suddenly rises from its nominal level to \(em33\ dBm0.
.PP
In the above formula, \fIt\fR\d\fIr\fR\\d\fIs\fR\u\dm\\da\\dx\uis the
maximum response time of the signalling receiver for a rise in level, taking
into account a possible variation of \(+- | \ dB in the signalling tone 
level from its nominal value, the level being measured on the receiving 
side of the group distribution frame or at an equivalent point. 
.PP
The figure of 13\ ms in the above formula is derived on the assumption 
that the output of the interruption control equipment acts upon the input 
of 
the device which regulates the recognition time for \fItone\(hyon\fR and 
\fItone\(hyoff\fR condition (20\ \(+-\ 7\ ms) 
i.e.\ absence of a direct current signal at this
input for a period of up to 13\ ms has no relevance.
.RT
.LP
.sp 1P
.LP
2.4.3.6
	\fIPrecautions against noise\fR 
.sp 9p
.RT
.PP
An interruption may produce increased noise on the group link.
Interruption control must be capable of distinguishing between the pilot 
itself and a high level noise simulating the pilot. 
.PP
Interruption control must not revert to normal in the presence of
white noise having a spectral power density of not more than \(em47\ dBm0 
per\ Hz. 
.PP
To facilitate the design of interruption control equipment operating satisfactorily 
at high noise levels, the upper limit of 500\ ms 
for\ \fIt\fR \(ua has been specified.
.RT
.LP
.sp 3
.bp
.sp 1P
.ce 1000
\v'3P'
SECTION\ 3
.ce 0
.sp 1P
.ce 1000
\fBLINE\ SIGNALLING,\ DIGITAL\ VERSION\fR 
.ce 0
.sp 1P
.sp 2P
.LP
\fBRecommendation\ Q.421\fR 
.RT
.sp 2P
.sp 1P
.ce 1000
\fB3.1\ 
\fBDIGITAL\ LINE\ SIGNALLING\ CODE\fR 
.EF '%	Fascicle\ VI.4\ \(em\ Rec.\ Q.421''
.OF '''Fascicle\ VI.4\ \(em\ Rec.\ Q.421	%'
.ce 0
.sp 1P
.sp 2P
.LP
3.1.1
	\fIGeneral\fR 
.sp 1P
.RT
.PP
Primary PCM multiplexes (see Recommendations G.732 and G.734)
economically provide more than one signalling channel per speech circuit in
each direction of transmission. By making use of the increased signalling
capacity, simplification of the outgoing and incoming switching equipment 
can be achieved since the timing conditions necessary for the System\ R2 
line 
.PP
signalling, analogue version, are not required. For this reason the digital
version of System\ R2 line signalling is recommended for use on PCM systems 
in national and international public switched networks and is specified 
below.
.PP
\fINote\fR \ \(em\ The continuous line signalling scheme specified for FDM
systems may also be used on PCM systems by utilizing one signalling channel
only in each direction. In this case relay sets designed for the continuous
line signalling system on FDM\ channels can be used provided that the functions 
specified for the interruption control on FDM circuits (see 
Recommendation\ Q.416) are performed by use of the local alarm facility 
provided by PCM equipment. This method of line signalling on PCM systems 
is not 
recommended for use on international circuits.
.PP
The digital version of System R2 line signalling uses two signalling channels 
in each direction of transmission per speech circuit. These signalling 
channels are referred to as a\df\uand b\df\ufor the forward direction (i.e.\ 
the direction of call set\(hyup) and a\db\uand b\db\ufor the backward direction. 
.PP
Under normal conditions:
.RT
.LP
	\(em
	 The a\df\uchannel identifies the operating condition of the outgoing 
switching equipment and reflects the condition of the 
calling subscriber's line.
.LP
	\(em
	 The b\df\uchannel provides a means for indicating a failure in the forward 
direction to the incoming switching equipment. 
.LP
	\(em
	The a\db\uchannel reflects the condition of the called
subscriber's line (on hook or off hook).
.LP
	\(em
	 The b\db\uchannel indicates the idle or seized state of the incoming 
switching equipment. 
.PP
The line signals are transmitted link\(hyby\(hylink.
.PP
The digital version of System\ R2 line signalling also specifies a
means for appropriate action in the case of faulty transmission conditions 
on the PCM multiplex, see Recommendation\ Q.424. 
.PP
The signalling system is specified for one\(hyway operation, but both\(hyway 
operation is also possible (see \(sc\ 3.2.7 below). 
.RT
.LP
.sp 1P
.LP
3.1.2
	\fISignalling code\fR 
.sp 9p
.RT
.PP
Table 2/Q.421, shows the signalling code on the PCM line under
normal conditions.
.bp
.RT
.ce
\fBH.T. [2/Q.421]\fR 
.ce
TABLE\ 2/Q.421
.ps 9
.vs 11
.nr VS 11
.nr PS 9
.TS
center box;
cw(72p) | cw(18p) sw(18p) sw(18p) sw(18p) , ^  | c s | c 
^  | c | c | c | c.
State of the circuit	Signalling code
	Forward	Backward	a f	b f	a b	b b
_
.T&
lw(72p) | cw(18p) | cw(18p) | cw(18p) | cw(18p) .
Idle/Released	1	0	1	0
.T&
lw(72p) | cw(18p) | cw(18p) | cw(18p) | cw(18p) .
Seized	0	0	1	0
.T&
lw(72p) | cw(18p) | cw(18p) | cw(18p) | cw(18p) .
Seizure acknowledged	0	0	1	1
.T&
lw(72p) | cw(18p) | cw(18p) | cw(18p) | cw(18p) .
Answered	0	0	0	1
.T&
lw(72p) | cw(18p) | cw(18p) | cw(18p) | cw(18p) .
Clear\(hyback	0	0	1	1
.T&
lw(72p) | cw(18p) | cw(18p) | cw(18p) | cw(18p) .
Clear\(hyforward	1	0	0	1
.T&
cw(36p) .
or
.T&
lw(72p) | lw(18p) | lw(18p) | cw(18p) | cw(18p) .
			1	1
.T&
lw(72p) | cw(18p) | cw(18p) | cw(18p) | cw(18p) .
Blocked	1	0	1	1
_
.TE
.nr PS 9
.RT
.ad r
\fBTable [2/Q.421], p.\fR 
.sp 1P
.RT
.ad b
.RT
.sp 2P
.LP
\fBRecommendation\ Q.422\fR 
.RT
.sp 2P
.sp 1P
.ce 1000
\fB3.2\ CLAUSES FOR EXCHANGE LINE SIGNALLING EQUIPMENT\fR 
.EF '%	Fascicle\ VI.4\ \(em\ Rec.\ Q.422''
.OF '''Fascicle\ VI.4\ \(em\ Rec.\ Q.422	%'
.ce 0
.sp 1P
.sp 2P
.LP
3.2.1
	\fIRecognition of a change of signalling code\fR 
.sp 1P
.RT
.sp 1P
.LP
3.2.1.1
	\fISignalling channel transitions\fR 
.sp 9p
.RT
.PP
The recognition time for a transition from 0 to 1 or vice versa on a signalling 
channel is 20 \(+- 10 ms. This value presupposes the existence of 
protection against the effects of faulty transmission conditions on the PCM
multiplex.
.PP
The recognition time is defined as the duration that the signals
representing 0 or 1 must have at the output of the terminal equipment of a
signalling channel in order to be recognized by the exchange equipment.
.RT
.LP
.sp 1P
.LP
3.2.1.2
	\fIChange of signalling code\fR 
.sp 9p
.RT
.PP
Recognition of a change of signalling code is thus defined as
either of the following:
.RT
.LP
	a)
	Recognition of a transition detected on one signalling
channel with no transition detected on the second signalling
channel during the recognition period.
.LP
	b)
	Recognition of a transition detected on the second
signalling channel during the recognition period already being
applied to the first signalling channel. In this case, a change
of signalling code is recognized only when both recognition
timing periods have elapsed.
.sp 1P
.LP
3.2.2
	\fISent signal time tolerance\fR 
.sp 9p
.RT
.PP
The time difference between application of transitions intended to be simultaneous 
on two signalling channels in the same direction of 
transmission must not exceed 2\ ms.
.bp
.RT
.LP
.sp 1P
.LP
3.2.3
	\fIStates and procedures under normal conditions\fR  | see Table 2/Q.421)
.sp 9p
.RT
.PP
In the forward direction b\df\u= 0 is established permanently.
.RT
.sp 1P
.LP
3.2.3.1
	\fIIdle state\fR 
.sp 9p
.RT
.PP
In the idle state the outgoing end sends a\df\u= 1, b\df\u= 0. At the incoming 
end this results in sending 
a\db\u\ =\ 1, b\db\u= 0 in the
backward
direction, provided that the switching equipment at the incoming end of the
circuit is idle.
.RT
.sp 1P
.LP
3.2.3.2
	\fISeizing procedure\fR \v'3p'
.sp 9p
.RT
.LP
	i)
	\fISeizure\fR 
.LP
	 Seizing should occur only if a\db\u\ =\ 1, b\db\u\ =\ 0 is recognized. 
The outgoing end changes a\df\u\ =\ 1 into a\df\u\ =\ 0. The code a\df\u\ 
=\ 0, 
b\df\u\ =\ 0 must be maintained until the seizing acknowledgement signal is
recognized. In this way the outgoing switching equipment will only be able 
to send the clear\(hyforward signal after recognition of the seizing acknowledgement 
signal. 
\v'3p'
.LP
	ii)
	\fISeizure acknowledgement\fR 
.LP
	After having recognized the seizing signal, the incoming end
sends a\db\u\ =\ 1, b\db\u\ =\ 1 as an acknowledgement.
.sp 1P
.LP
3.2.3.3
	\fIAnswering\fR 
.sp 9p
.RT
.PP
The off\(hyhook condition of the called subscriber's line provokes the 
incoming switching equipment to send a\db\u\fR \ =\ 0, b\db\u\ =\ 1. 
.PP
The answered state must be established on the preceding link
immediately after it is recognized: see also \(sc\ 3.2.3.6 below.
.RT
.sp 1P
.LP
3.2.3.4
	\fIClear\(hyback\fR 
.sp 9p
.RT
.PP
The on\(hyhook condition of the called subscriber's line provokes the incoming 
switching equipment to send a\db\u\ =\ 1, b\db\u\ =\ 1. The clear\(hyback 
state must be established on the preceding link immediately after it is 
recognized: see also \(sc\ 3.2.3.6 below. 
.RT
.sp 1P
.LP
3.2.3.5
	\fIClear\(hyforward procedure\fR 
.sp 9p
.RT
.PP
The cleared condition of the calling subscriber's line or the
release of the outgoing switching equipment will normally result in sending
a\df\u\ =\ 1, b\df\u\ =\ 0. The outgoing switching equipment will not be 
restored to the idle state until recognition of the code a\db\u\ =\ 1, 
b\db\u\ =\ 0: see also 
\(sc\(sc\ 3.2.3.2, 3.2.3.6 and Table 3/Q.422.
.RT
.LP
.sp 1P
.LP
3.2.3.6
	\fIRelease procedure\fR 
.sp 9p
.RT
.PP
Recognition of the clear\(hyforward signal in the incoming switching equipment 
initiates the release of the succeeding link even though answering or clearing 
by the called party has occurred. Upon complete release of the 
incoming switching equipment, the code a\db\u\ =\ 1, b\db\u\ =\ 0 is established 
on the circuit. This will cause the circuit to be restored to the idle 
state and the outgoing switching equipment to become available for another 
call. 
.RT
.sp 1P
.LP
3.2.3.7
	\fIBlocking and unblocking procedure\fR 
.sp 9p
.RT
.PP
Blocking of an idle circuit to new calls at the outgoing end must occur 
as soon as a\db\u\ =\ 1 and b\db\u\ =\ 1 is recognized: see also Tables\ 
3/Q.422 and 4/Q.422. 
.PP
The recognition of a\db\u\ =\ 1, b\db\u\ =\ 0 restores the circuit to the
idle state.
.RT
.sp 1P
.LP
3.2.4
	\fIActions appropriate to various signalling conditions\fR 
.sp 9p
.RT
.PP
In addition to normal conditions described in Table 2/Q.421 other conditions 
due to faults may be encountered. Tables\ 3/Q.422 and\ 4/Q.422 
indicate the states appropriate to each signalling code recognized and the
actions to be taken at the outgoing and incoming end respectively of a 
circuit operated with the digital version of System\ R2 line signalling. 
.bp
.RT
.LP
.sp 1P
.LP
3.2.4.1
	\fIOutgoing end\fR 
.sp 9p
.RT
.ce
\fBH.T. [3/Q.422]\fR 
.ce
TABLE\ 3/Q.422
.ps 9
.vs 11
.nr VS 11
.nr PS 9
.TS
center box;
cw(48p) | cw(36p) | cw(36p) sw(36p) sw(36p) sw(36p) , ^  | ^  | c | c | c | c.
 {
Normal state at the out\(hygoing end
 }	Sent code	Received code
		a b\ =\ 0,\ b b\ =\ 0	a b\ =\ 0,\ b b\ =\ 1	a b\ =\ 1,\ b b\ =\ 0	a b\ =\ 1,\ b b\ =\ 1
_
.T&
lw(48p) | cw(36p) | cw(36p) | cw(36p) | cw(36p) | cw(36p) .
Idle/Released	a f\ =\ 1,\ b f\ =\ 0	Abnormal,  see Note 1	Abnormal,  see Note 1	Idle	Blocked
_
.T&
lw(48p) | cw(36p) | cw(36p) | cw(36p) | cw(36p) | cw(36p) .
Seized	a f\ =\ 0,\ b f\ =\ 0	Abnormal,  see Note 2	Abnormal,  see Note 2	Seized  see Note 2	Seizure acknowledged
_
.T&
lw(48p) | cw(36p) | cw(36p) | cw(36p) | cw(36p) | cw(36p) .
Seizure acknowledged	a f\ =\ 0,\ b f\ =\ 0	Abnormal,  see Note 3	Answered	Abnormal,  see Note 3	Seizure acknowledged
_
.T&
lw(48p) | cw(36p) | cw(36p) | cw(36p) | cw(36p) | cw(36p) .
Answered	a f\ =\ 0,\ b f\ =\ 0	Abnormal,  see Note 4	Answered	Abnormal,  see Note 4	Clear\(hyback
_
.T&
lw(48p) | cw(36p) | cw(36p) | cw(36p) | cw(36p) | cw(36p) .
Clear\(hyback	a f\ =\ 0,\ b f\ =\ 0	Abnormal,  see Note 4	Answered	Abnormal,  see Note 4	Clear\(hyback
_
.T&
lw(48p) | cw(36p) | cw(36p) | cw(36p) | cw(36p) | cw(36p) .
Clear\(hyforward	a f\ =\ 1,\ b f\ =\ 0	Abnormal,  see Note 1	Clear\(hyforward	Released = Idle	Clear\(hyforward
_
.T&
lw(48p) | cw(36p) | cw(36p) | cw(36p) | cw(36p) | cw(36p) .
Blocked	a f\ =\ 1,\ b f\ =\ 0	Abnormal,  see Note 1	Abnormal,  see Note 1	Idle	Blocked
.TE
.LP
\fINote\ 1\fR
\ \(em\ In these abnormal conditions the outgoing end must prevent
a new seizure of the circuit. A delayed alarm should also be given
(see \(sc\ 3.2.6).
.LP
\fINote\ 2\fR
\ \(em\ Non\(hyrecognition of the seizing acknowledgement signal 100\ ms\(hy200\ ms after sending the seizing signal on a terrestrial link or 1\(hy2\ seconds after
sending the seizing signal on a satellite link results in an alarm and
either congestion information being sent backward or a repeat attempt being
made to set up the call. The outgoing end must prevent a new seizure of the
circuit. When the seizing acknowledgement signal is recognized after the
time\(hyout period has elapsed, the clear\(hyforward signal must be sent.
.LP
\fINote\ 3\fR
\ \(em\ Receipt of b
b = 0 by the outgoing switching equipment
for 1\(hy2\ seconds after recognition of the seizing acknowledgement signal
and prior to recognition of the answer signal, results in an alarm and
either congestion information being sent backward or a repeat attempt being
made to set up the call. The outgoing end must prevent new seizures of the
circuit. When b
b reverts to 1 after the 1\(hy2\ seconds timeout period has
elapsed, the clear\(hyforward signal must be sent.
.LP
\fINote\ 4\fR
\ \(em\ In the case of recognition of b
b\ =\ 0 whilst in the answered
or clear\(hyback state, immediate action is not necessary. On receipt of
clearing from the preceding link, the clear\(hyforward signal (a
f\ =\ 1,
b
f\ =\ 0) must not be sent until b
b is restored to 1. A delayed alarm
should also be given.
.nr PS 9
.RT
.ad r
\fBTableau [3/Q.422] + Remarques, p.7\fR 
.sp 1P
.RT
.ad b
.RT
.LP
.rs
.sp 7P
.ad r
\fBBlanc\fR 
.ad b
.RT
.LP
.bp
.sp 1P
.LP
3.2.4.2
	\fIIncoming end\fR 
.sp 9p
.RT
.ce
\fBH.T. [4/Q.422]\fR 
.ce
TABLE\ 4/Q.422
.ps 9
.vs 11
.nr VS 11
.nr PS 9
.TS
center box;
cw(48p) | cw(36p) | cw(36p) sw(36p) sw(36p) sw(36p) , ^  | ^  | c | c | c | c.
 {
Normal state at the incoming end
 }	Sent code	Received code
		a f\ =\ 0,\ b f\ =\ 0	a f\ =\ 0,\ b f\ =\ 1	a f\ =\ 1,\ b f\ =\ 0	a f\ =\ 1,\ b f\ =\ 1
_
.T&
lw(48p) | cw(36p) | cw(36p) | cw(36p) | cw(36p) | cw(36p) .
Idle/Released	a b\ =\ 1,\ b b\ =\ 0	Seized	Fault  see Note 1	Idle	Fault  see Note 1
_
.T&
lw(48p) | cw(36p) | cw(36p) | cw(36p) | cw(36p) | cw(36p) .
Seizure acknowledged	a b\ =\ 1,\ b b\ =\ 1	Seizure  acknowledged	Fault  See Note 2	Clear\(hy  forward	Fault  See Note 2
_
.T&
lw(48p) | cw(36p) | cw(36p) | cw(36p) | cw(36p) | cw(36p) .
Answered	a b\ =\ 0,\ b b\ =\ 1	Answered	Fault  see Note 3	Clear\(hy  forward	Fault  see Note 3
_
.T&
lw(48p) | cw(36p) | cw(36p) | cw(36p) | cw(36p) | cw(36p) .
Clear\(hyback	a b\ =\ 1,\ b b\ =\ 1	Clear\(hyback	Fault  see Note 4	Clear\(hy  forward	Fault  see Note 4
_
.T&
lw(48p) | cw(36p) | cw(36p) | cw(36p) | cw(36p) | cw(36p) .
Clear\(hyforward	 {
a
b\ =\ 0,\ b
b\ =\ 1
or
a
b\ =\ 1,\ b
b\ =\ 1
 }	Abnormal  seized see Note 7	Fault  see Note 7	Clear\(hy  forward see Note 7	Fault  see Note 7
_
.T&
lw(48p) | cw(36p) | cw(36p) | cw(36p) | cw(36p) | cw(36p) .
Blocked	a b\ =\ 1,\ b b\ =\ 1	Abnormal  seized  see Note 5	Fault  see Note 6	Blocked	Fault see Note 6
.TE
.LP
\fINote\ 1\fR
\ \(em\ When in the idle/released state b
f changes to 1, b
b must
be changed to 1.
.LP
\fINote\ 2\fR
\ \(em\ In these cases a time\(hyout device is started, which after a
certain interval clears the connection beyond the faulty circuit: this
timing arrangement may be the one specified in Recommendation\ Q.118,
Section\ 4.3.3. If the answer signal is recognized during the time\(hyout delay,
the timer is stopped but the answer signal is not sent on the preceding link
until recognition of a
f\ =\ 0,\ b
f\ =\ 0. If the clear\(hyback signal is
recognized while the fault persists, the connection beyond the faulty circuit must be released immediately. Additionally, when the incoming register has not started to send the last backward signal, the rapid release procedure
described in Note 5 may be used.
.LP
\fINote\ 3\fR
\ \(em\ In these cases no action is taken until the clear\(hyback signal
is recognized, at which stage the connection beyond the faulty circuit is
immediately released.
.LP
\fINote\ 4\fR
\ \(em\ Under these conditions the succeeding link must be
released immediately.
.LP
\fINote\ 5\fR
\ \(em\ In this case immediate action is not necessary. However,
rapid release of the circuit should occur if the incoming end simulates
answer by sending a
b\ =\ 0,\ b
b\ =\ 1.
.LP
\fINote\ 6\fR
\ \(em\ Under these conditions no action is taken.
.LP
\fINote\ 7\fR
\ \(em\ After clear\(hyforward signal is recognized and until the code
a
b\ =\ 1, b
b\ =\ 0 is sent, all transitions in the forward direction
shall be ignored.
.nr PS 9
.RT
.ad r
\fBTableau [4/Q.422] + Remarques,  p.8\fR 
.sp 1P
.RT
.ad b
.RT
.LP
.rs
.sp 7P
.ad r
\fBBlanc\fR 
.ad b
.RT
.LP
.bp
.sp 2P
.LP
3.2.5
	\fIAbnormal conditions\fR 
.sp 1P
.RT
.sp 1P
.LP
3.2.5.1
	\fISpecial release arrangements\fR \v'3p'
.sp 9p
.RT
.LP
	a)
	If an exchange where an outgoing R2 register is situated
recognizes a\db\u\ =\ 0, b\db\u\ =\ 1 (premature answer) before an
address\(hycomplete signal A\(hy6 or a Group\ B signal is received, the
connection must be released. Congestion information is then sent
backward or a repeat attempt is made to set up the call.
.LP
	b)
	 In the cases of non\(hyreceipt of the answer signal, of delay in clearing 
by the calling subscriber in automatic working and 
of non\(hyreceipt of the clear\(hyforward signal by the incoming
exchange after the clear\(hyback signal has been sent, the
provisions of Recommendation Q.118 apply.
.sp 1P
.LP
3.2.5.2
	\fISafeguard against failures\fR 
.sp 9p
.RT
.PP
The PCM equipment and the exchange line signalling equipment should be 
designed in such a way that at least those faults which are most likely 
to occur in this equipment or in the interconnecting cables, result in 
blocking of the circuit at the outgoing end and in the ultimate clearing 
of the connection beyond the incoming switching equipment. This can be 
achieved, as far as 
possible, by ensuring that a\ =\ 1, b\ =\ 1 is sent on line upon:
.RT
.LP
	\(em
	removal of PCM or switching equipment by maintenance
personnel;
.LP
	\(em
	occurrences of abnormal conditions (e.g.\ open wire, low
voltage) in switching equipment.
.LP
.sp 1P
.LP
3.2.6
	\fIAlarms for technical staff\fR 
.sp 9p
.RT
.PP
According to Recommendation Q.117, an alarm must in principle be
given to the technical staff upon recognition of abnormal conditions.
.PP
Arrangements for these alarms are to be specified by the
Administrations.
.PP
It is recommended that a delayed alarm be given at the outgoing end
for the procedure described under \(sc\ 3.2.3.7 above (blocking) and for the
following reasons:
.RT
.LP
	\(em
	when the abnormal conditions covered by Note\ 1 to
Table\ 3/Q.422 are applicable;
.LP
	\(em
	when the seizing acknowledgement signal is not recognized
within the time specified in Note\ 2 to Table\ 3/Q.422 after
sending the seizing signal;
.LP
	\(em
	 when, after recognition of the seizing acknowledgement signal and prior 
to recognition of the answer signal, b\db\u\ =\ 0 is 
received for 1\(hy2 seconds;
.LP
	\(em
	when the abnormal conditions covered by Note\ 4 to
Table\ 3/Q.422 are applicable.
.PP
It is also recommended that a delayed alarm be given under PCM
failure conditions specified in Recommendations\ G.732 and G.734.
.sp 1P
.LP
3.2.7
	\fIBoth\(hyway working\fR 
.sp 9p
.RT
.PP
System R2 is specified for one\(hyway working, but in principle the
line signalling code detailed in Recommendation\ Q.421 is also suitable 
for use on both\(hyway circuits. Where Administrations have undertaken, 
by bilateral 
agreement, to use both\(hyway working, the clauses and additional specifications 
for exchange signalling equipment detailed in \(sc\(sc\ 3.2.7.1 and 3.2.7.2 
below, 
must be observed.
.RT
.LP
.sp 1P
.LP
3.2.7.1
	\fIProcedures under normal conditions\fR \v'3p'
.sp 9p
.RT
.LP
	a)
	\fIDouble seizure\fR 
.LP
	 Double seizure is assumed if the outgoing equipment is in a seized state 
and the signalling code a\db\u\ =\ 0, b\db\u\ =\ 0 is recognized instead 
of 
a\db\u\ =\ 1, b\db\u\ =\ 1 (seizure acknowledgement). In such a situation the
connection must be released at both ends and congestion information sent 
to the calling subscriber or a repeat attempt must be made. On recognition 
of double seizure the line signalling equipment at both ends must maintain 
the seized 
state for a minimum of 100\ ms after which the clear\(hyforward signal 
a\df\u\ =\ 1, b\df\u\ =\ 0 must be sent. 
.bp
.LP
	 100 ms after sending the clear\(hyforward signal and on recognition of 
a\db\u\ =\ 1, b\db\u\ =\ 0 each end may assume the idle state. 
.LP
	The clear\(hyforward state a\df\u\ =\ 1, b\df\u\ =\ 0 must be maintained
for at least 100\ ms to ensure that it is recognized at the other end.
.LP
	In the sense of preventive action it is recommended
that an opposite order of circuit selection be used by each
exchange of a both\(hyway circuit group to minimize double
seizure.
\v'3p'
.LP
	b)
	\fIRequirements for circuit release\fR 
.LP
	When a both\(hyway circuit is released, the end which acted as
the incoming end must maintain the signalling code
a\db\u\ =\ 1, b\db\u\ =\ 0 for at least 100\ ms to ensure that
the signal is recognized at the other end after which the
circuit becomes idle.
\v'3p'
.LP
	c)
	\fIBlocking and unblocking procedure\fR 
.LP
	When a both\(hyway circuit is blocked manually in its idle
state at one end (e.g.\ end B) the blocking signal must be
sent to the other end (A). The circuit must then be kept blocked
locally (at end A) against all calls in the A to B traffic
direction as long as the blocked state persists in the B to A
direction.
.LP
	In order to avoid permanent blocking, end A should maintain the
signalling code a\ =\ 1, b\ =\ 0 in the direction A to B.
.PP
When the blocked state is removed, end B must send the
clear\(hyforward signal and must maintain that state for at least 100\ 
ms, before assuming the idle state. 
.sp 1P
.LP
3.2.7.2
	\fISpecial arrangement\fR 
.sp 9p
.RT
.PP
The physical realization of signalling equipment terminating a
bothway circuit may allow that part of the equipment concerned with outgoing
calls to be removed without preventing the remaining equipment from being 
used for incoming calls. In this case it is only necessary to block the 
circuit 
locally against outgoing calls and a blocking signal need not be sent to the
other end.
\v'2P'
.RT
.LP
.sp 2P
.LP
\fBRecommendation\ Q.424\fR 
.RT
.sp 2P
.sp 1P
.ce 1000
\fB3.3\ \fR \fBPROTECTION AGAINST THE EFFECTS OF FAULTY TRANSMISSION\fR 
.EF '%	Fascicle\ VI.4\ \(em\ Rec.\ Q.424''
.OF '''Fascicle\ VI.4\ \(em\ Rec.\ Q.424	%'
.ce 0
.sp 1P
.PP
Faulty transmission conditions in PCM systems can lead to
degradation of the speech channels and erroneous signalling. In the case of
primary PCM multiplex equipment operating at 2048\ kbit/s failures due 
to loss of frame or multi\(hyframe alignment and/or failure of any other 
important 
function results in both PCM terminals going into alarm condition in accordance 
with Recommendations\ G.732 and\ G.734. 
.sp 1P
.RT
.PP
Thus both PCM terminals apply the state corresponding to state\ 1 on the 
PCM line on each \*Qreceive\*U signalling channel at the interfaces with 
the switching equipment, as indicated in Table\ 4 of Recommendation\ G.732. 
In this way, the incoming switching equipment receives the equivalent of 
a\df\u\ =\ 1, 
.PP
b\df\u\ =\ 1 on the PCM line and the outgoing switching equipment receives the
equivalent of a\db\u\ =\ 1, b\db\u\ =\ 1.
.PP
These characteristics are taken into account in the present
specifications (see\ \(sc\ 3.2.4) so that:
.RT
.LP
	\(em
	 at the outgoing end (see Table 3/Q.422) a PCM fault results in a blocked 
state, seizure acknowledged state or clear\(hyback state. This means that 
all circuits in the idle state of a faulty PCM multiplex will be blocked 
against seizure and that seized circuits will go to or remain in the seizure 
acknowledged or clear\(hyback state;
.LP
	\(em
	at the incoming end (see Table 4/Q.422) a PCM
fault can be identified and appropriate actions can be taken.
.bp
.PP
When the signalling equipment is a part of a digital exchange, it may receive 
alarm indications in a form other than both signalling bits in 
state one.  The failure may be detected by the signalling equipment or an
indication be received from the PCM terminal according to
Recommendation\ G.734.
.PP
When the signalling equipment recognizes a failure it must:
.RT
.LP
	\(em
	block the detection of signalling transitions
to avoid recognition of erroneous signalling codes caused by the
failure. This action must be taken as soon as possible and at
least within 3\ ms as specified in Recommendation\ G.734 for a PCM
terminal,
.LP
	\(em
	react as specified in Tables 3/Q.422 and 4/Q.422 when a
signalling code a\ =\ 1, b\ =\ 1 is detected at the input of
signalling equipment situated at the analogue access of
a PCM terminal equipment complying with Recommendation\ G.732.
\v'2P'
.LP
.sp 2P
.LP
\fBRecommendation\ Q.430\fR 
.RT
.sp 2P
.ce 1000
\fB3.5\ \fR \fBCONVERSION BETWEEN ANALOGUE AND DIGITAL VERSIONS\fR 
.EF '%	Fascicle\ VI.4\ \(em\ Rec.\ Q.430''
.OF '''Fascicle\ VI.4\ \(em\ Rec.\ Q.430	%'
.ce 0
.sp 1P
.ce 1000
\fBOF SYSTEM R2 LINE SIGNALLING\fR 
.ce 0
.sp 1P
.PP
This Recommendation is applicable to a conversion equipment
placed on the circuit between two switching exchanges each using one of 
the two versions specified for System\ R2 line signalling. Owing to this 
particular use, all the specifications for the two versions of the line 
signalling may not be fully observed. Nevertheless, the diagrams which 
follow are based on the 
principles of CCITT Recommendations\ Q.411, Q.412 and Q.416 for the analogue
version and on Recommendations\ Q.421, Q.422 and Q.424, for the digital 
version. The only time conditions taken into account in this Recommendation 
are those 
set out in the aforementioned Recommendations. The operation of the 
.sp 1P
.RT
.LP
interruption control device is also, wherever possible, that specified in
Recommendation\ Q.416. As stated in that Recommendation, the receiver is 
blocked immediately whenever pilot tone off is detected: since this is 
a routine 
operation, it has not been represented explicitly in the diagrams.
.PP
The conversion diagrams have been divided into four parts:
.LP
	\(em
	 for conversion between the analogue version at the incoming end and the 
digital version at the outgoing end, into: 
.LP
	\(em
	incoming analogue,
.LP
	\(em
	outgoing digital;
.LP
	\(em
	for conversion between the digital version at the incoming
end and the analogue version at the outgoing end, into:
.LP
	\(em
	incoming digital,
.LP
	\(em
	outgoing analogue.
.PP
It should be noted, however, that this Recommendation can be
simplified with respect to alarm processing when the conversion equipment is
connected directly at the input or output of a switching exchange; the
processes necessary for this application are shown on the diagrams with
thickened lines.
.LP
.sp 2P
.LP
\fB1\fR 	\fBDrawing conventions\fR \v'3p'
.sp 1P
.RT
.LP
	\(em
	tone
.LP
	tf
	=\ 1 tone on forward
	
.sp 2P
.LP
	tf
	=\ 0 tone off forward
	
.RT
.sp 2P
.LP
	tb
	=\ 1 tone on backward
	
.RT
.sp 2P
.LP
	tb
	=\ 0 tone off backward
	
.RT
.sp 2P
.LP
	When recognized
.sp 2P
.LP
	p
	=\ 1 pilot tone on
	
.RT
.sp 2P
.IP
	p
	=\ 0 pilot tone off
	
.sp 1P
.RT
.LP
	\(em
	signalling bits
.PP
The conventions are those of Recommendation\ Q.421.
.bp
.sp 2P
.LP
\fB2\fR \fBConversion incoming analogue version to outgoing digital version\fR 
.sp 1P
.RT
.sp 1P
.LP
2.1
	\fIIncoming analogue\fR 
.sp 9p
.RT
.LP
.rs
.sp 11P
.ad r
\fBFigure CCITT\(hy55980, p.\fR 
.sp 1P
.RT
.ad b
.RT
.PP
List of timers:
.LP
	T2:
	Recommendation Q.412 (\(sc\ 2.2.2.7)
.LP
	T3:\ 2\ to\ 3\ mn
	Recommendation Q.118 (\(sc\ 4.3.3)
.PP
In sheets 2 and 4 the diagram for group pilot supervision is given.
.PP
In sheets 3 and 5 the diagram for supergroup pilot supervision is given.
.PP
Sheet 1 is for group and supergroup pilot supervision.
.RT
.LP
.rs
.sp 28P
.ad r
\fBBlanc\fR 
.ad b
.RT
.LP
.bp
.LP
.rs
.sp 47P
.ad r
\fBFIGURE CCITT\(hy60881 (feuillet 1), p.10\fR 
.sp 1P
.RT
.ad b
.RT
.LP
.bp
.LP
.rs
.sp 47P
.ad r
\fBFIGURE CCITT\(hy60891 (feuillet 2), p.11\fR 
.sp 1P
.RT
.ad b
.RT
.LP
.bp
.LP
.rs
.sp 47P
.ad r
\fBFIGURE T1115760\(hy88 (feuillet 3), p.\fR 
.sp 1P
.RT
.ad b
.RT
.LP
.bp
.LP
.rs
.sp 47P
.ad r
\fBFIGURE CCITT\(hy60901 (feuillet 4), p.12\fR 
.sp 1P
.RT
.ad b
.RT
.LP
.bp
.LP
.rs
.sp 47P
.ad r
\fBFIGURE T1115770\(hy88 (feuillet 5), p.\fR 
.sp 1P
.RT
.ad b
.RT
.LP
.bp
.sp 1P
.LP
2.2
	\fIOutgoing digital\fR 
.sp 9p
.RT
.LP
.rs
.sp 11P
.ad r
\fBFigure CCITT\(hy55990, p.\fR 
.sp 1P
.RT
.ad b
.RT
.PP
List of timers:
.LP
	T6:\ Recommendation Q.422 (\(sc\ 3.2.4.1, Note 2 to Table 3)
.LP
.rs
.sp 30P
.ad r
\fBBlanc\fR 
.ad b
.RT
.LP
.bp
.LP
.rs
.sp 47P
.ad r
\fR \fBFigure CCITT\(hy60911 (Sheet 1 of 3), p.\fR 
.sp 1P
.RT
.ad b
.RT
.LP
.bp
.LP
.rs
.sp 47P
.ad r
\fR \fBFigure CCITT\(hy60920 (Sheet 2 of 3), p.\fR 
.sp 1P
.RT
.ad b
.RT
.LP
.bp
.LP
.rs
.sp 47P
.ad r
\fBFigure CCITT\(hy60930 (Sheet 3 of 3), p.\fR 
.sp 1P
.RT
.ad b
.RT
.LP
.bp
.sp 2P
.LP
\fB3\fR \fBConversion incoming digital version to outgoing analogue version\fR 
.sp 1P
.RT
.sp 1P
.LP
3.1
	\fIIncoming digital\fR 
.sp 9p
.RT
.LP
.rs
.sp 11P
.ad r
\fBFigure CCITT\(hy56000, p.\fR 
.sp 1P
.RT
.ad b
.RT
.PP
List of timers:
.LP
	T3:\ 2 to 3 mn Recommendation Q.118 (\(sc\ 4.3.3)
.LP
.rs
.sp 30P
.ad r
\fBBlanc\fR 
.ad b
.RT
.LP
.bp
.LP
.rs
.sp 47P
.ad r
\fBFigure CCITT\(hy60940 (Sheet 1 of 3), p.\fR 
.sp 1P
.RT
.ad b
.RT
.LP
.bp
.LP
.rs
.sp 47P
.ad r
\fBFigure CCITT\(hy60950 (Sheet 2 of 3), p.\fR 
.sp 1P
.RT
.ad b
.RT
.LP
.bp
.LP
.rs
.sp 47P
.ad r
\fBFigure CCITT\(hy60960 (Sheet 3 of 3), p.\fR 
.sp 1P
.RT
.ad b
.RT
.LP
.bp
.sp 1P
.LP
3.2
	\fIOutgoing analogue\fR 
.sp 9p
.RT
.LP
.rs
.sp 11P
.ad r
\fBFigure CCITT\(hy50610, p.\fR 
.sp 1P
.RT
.ad b
.RT
.PP
List of timers:
.LP
	T1:
	Recommendation Q.412 (\(sc\ 2.2.2.7)
.LP
	T5:\ 100 ms
	Recommendation Q.412 (\(sc\ 2.2.2.1)
.PP
Automatic restoration of an abnormally blocked circuit
Recommendation\ Q.490 (\(sc\ 6.6)
.LP
	n:
	number of attempts made
.LP
	T4:
	30 s to 2\ mn
.LP
	T7:
	2 to 3\ s
.LP
.rs
.sp 27P
.ad r
\fBBlanc\fR 
.ad b
.RT
.LP
.bp
.LP
.rs
.sp 47P
.ad r
\fBFigure CCITT\(hy60971 (Sheet 1 of 5), p.\fR 
.sp 1P
.RT
.ad b
.RT
.LP
.bp
.LP
.rs
.sp 47P
.ad r
\fBFigure CCITT\(hy60981 (Sheet 2 of 5), p.\fR 
.sp 1P
.RT
.ad b
.RT
.LP
.bp
.LP
.rs
.sp 47P
.ad r
\fR \fBFigure CCITT\(hy60991 (Sheet 3 of 5), p.\fR 
.sp 1P
.RT
.ad b
.RT
.LP
.bp
.LP
.rs
.sp 47P
.ad r
\fBFigure CCITT\(hy70001 (Sheet 4 of 5), p.\fR 
.sp 1P
.RT
.ad b
.RT
.LP
.bp
.LP
.rs
.sp 47P
.ad r
\fBFigure, p.\fR 
.sp 1P
.RT
.ad b
.RT
.LP
.bp