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5 Changeover
5.1 General
5.1.1 The objective of the changeover procedure is to ensure that signalling
traffic carried by the unavailable signalling link is diverted to the alternative
signalling link(s) as quickly as possible while avoiding message loss,
duplication or mis-sequencing. For this purpose, in the normal case the
changeover procedure includes buffer updating and retrieval, which are performed
before reopening the alternative signalling link(s) to the diverted traffic.
Buffer updating consists of identifying all those messages in the retransmission
buffer of the unavailable signalling link which have not been received by the far
end. This is done by means of a hand-shake procedure, based on changeover
messages, performed between the two ends of the unavailable signalling link.
Retrieval consists of transferring the concerned messages to the transmission
buffer(s) of the alternative link(s).
5.1.2 Changeover includes the procedures to be used in the case of
unavailability (due to failure, blocking or inhibiting) of a signalling link, in
order to divert the traffic pertaining to that signalling link to one or more
alternative signalling links.
These signalling links can be carrying their own signalling traffic and
this is not interrupted by the changeover procedure.
The different network configurations to which the changeover procedure may
be applied are described in S 5.2.
The criteria for initiation of changeover, as well as the basic actions to
be performed, are described in S 5.3.
Procedures necessary to cater for equipment failure or other abnormal
conditions are also provided.
5.2 Network configurations for changeover
5.2.1 Signalling traffic diverted from an unavailable signalling link is routed
by the concerned signalling point according to the rules specified in S 4. In
summary, two alternative situations may arise (either for the whole diverted
traffic or for traffic relating to each particular destination):
i) traffic is diverted to one or more signalling links of the same link
set, or
ii) traffic is diverted to one or more different link sets.
5.2.2 As a result of these arrangements, and of the message routing function
described in S 2, three different relationships between the new signalling link
and the unavailable one can be identified, for each particular traffic flow.
These three basic cases may be summarized as follows:
a) the new signalling link is parallel to the unavailable one (see Figure
9/Q.704);
b) the new signalling link belongs to a signalling route other than that
to which the unavailable signalling link belongs, but this signalling
route still passes through the signalling point at the far end of the
unavailable signalling link (see Figure 10/Q.704);
c) the new signalling link belongs to a signalling route other than that
to which the unavailable signalling link belongs, and this signalling
route does not pass through the signalling point acting as signalling
transfer point, at the far end of the unavailable signalling link (see
Figure 11/Q.704).
Figure 9/Q.704 - CCITT 35830
Fascicle VI.7 - Rec. Q.704 PAGE27
Figure 10/Q.704 - CCITT 35840
Figure 11/Q.704 - CCITT 35850
Only in the case of c) does a possibility of message mis-sequencing exist:
therefore its use should take into account the overall service dependability
requirements described in Recommendation Q.706.
5.3 Changeover initiation and actions
5.3.1 Changeover is initiated at a signalling point when a signalling link is
recognized as unavailable according to the criteria listed in S 3.2.2.
The following actions are then performed:
a) transmission and acceptance of message signal units on the concerned
signalling link is terminated;
b) transmission of link status signal units or fill in signal units, as
described in Recommendation Q.703, S 5.3, takes place;
c) the alternative signalling link(s) are determined according to the
rules specified in S 4;
d) a procedure to update the content of the retransmission buffer of the
unavailable signalling link is performed as specified in S 5.4 below;
e) signalling traffic is diverted to the alternative signalling link(s) as
specified in S 5.5 below.
In addition, if traffic toward a given destination is diverted to an
alternative signalling link terminating in a signalling transfer point not
currently used to carry traffic toward that destination, a transfer-prohibited
procedure is performed as specified in S 13.2.
5.3.2 In the case when there is no traffic to transfer from the unavailable
signalling link action, only item b) of S 5.3.1 is required.
PAGE1 Fascicle VI.7 - Rec. Q.704
5.3.3 If no alternative signalling link exists for signalling traffic towards
one or more destinations, the concerned destination(s) are declared inaccessible
and the following actions apply:
i) the routing of the concerned signalling traffic is blocked and the
concerned messages already stored in the transmission and
retransmission buffers of the unavailable signalling link, as well as
those received subsequently, are discarded10);
ii) a command is sent to the User Part(s) (if any) in order to stop
generating the concerned signalling traffic;
iii) the transfer-prohibited procedure is performed, as specified in S
13.2;
iv) the appropriate signalling link management procedures are performed, as
specified in S 12.
5.3.4 In some cases of failures or in some network configurations, the normal
buffer updating and retrieval procedures described in SS 5.4 and 5.5 cannot be
accomplished. In such cases, the emergency changeover procedures described in S
5.6 apply.
Other procedures to cover possible abnormal cases appear in S 5.7.
5.4 Buffer updating procedure
5.4.1 When a decision to changeover is made, a changeover order is sent to the
remote signalling point. In the case that the changeover was initiated by the
reception of a changeover order (see S 5.2) a changeover acknowledgement is sent
instead.
A changeover order is always acknowledged by a changeover acknowledgement,
even when changeover has already been initiated in accordance with another
criterion.
No priority is given to the changeover order or changeover acknowledgement
in relation to the normal traffic of the signalling link on which the message is
sent.
5.4.2 The changeover order and changeover acknowledgement are signalling network
management messages and contain the following information:
- the label, indicating the destination and originating signalling points
and the identity of the unavailable signalling link;
- the changeover-order (or changeover-acknowledgement) signal; and
- the forward sequence number of the last message signal unit accepted
from the unavailable signalling link.
Formats and codes of the changeover order and the changeover
acknowledgement appear in S 15.
5.4.3 Upon reception of a changeover order or changeover acknowledgement, the
retransmission buffer of the unavailable signalling link is updated (except as
noted in S 5.6), according to the information contained in the message. The
message signal units successive to that indicated by the message are those which
have to be retransmitted on the alternative signalling link(s), according to the
retrieval and diversion procedure.
5.5 Retrieval and diversion of traffic
When the procedure to update the retransmission buffer content is
completed, the following actions are performed:
- the routing of the signalling traffic to be diverted is changed;
- the signal traffic already stored in the transmission buffers and
retransmission buffer of the unavailable signalling link is sent
directly towards the new signalling link(s), according to the modified
routing.
The diverted signalling traffic will be sent towards the new signalling
link(s) in such a way that the correct message sequence is maintained. The
diverted traffic has no priority in relation to normal traffic already conveyed
on the signalling link(s).
10) The adequacy of this procedure to meet the acceptable dependability objective in
terms of loss of messages requires further study.
Fascicle VI.7 - Rec. Q.704 PAGE27
5.6 Emergency changeover procedures
5.6.1 Due to the failure in a signalling terminal it may be impossible for the
corresponding end of the faulty signalling link to determine the forward sequence
number of the last message signal unit accepted over the unavailable link. In
this case, the concerned end accomplishes, if possible, the buffer updating
procedures described in S 5.4 but it makes use of an emergency changeover order
or an emergency changeover acknowledgement instead of the corresponding normal
message; these emergency messages, the format of which appears in S 15, do not
contain the forward sequence number of the last accepted message signal unit.
Furthermore, the signalling link is taken out of service, i.e. the concerned end
initiates, if possible, the sending of out-of-service link status signal units on
the unavailable link (see Recommendation Q.703, S 5.3).
When the other end of the unavailable signalling link receives the
emergency changeover order or acknowledgement, it accomplishes the changeover
procedures described in SS 5.4 and 5.5, the only difference being that it does
not perform either buffer updating or retrieval. Instead, it directly starts
sending the signalling traffic not yet transmitted on the unavailable link on the
alternative signalling link(s).
The use of normal or emergency changeover messages depends on the local
conditions of the sending signalling point only, in particular:
- an emergency changeover order is acknowledged by a changeover
acknowledgement if the local conditions are normal; and
- a changeover order is acknowledged by an emergency changeover
acknowledgement if there are local fault conditions.
5.6.2 Time-con changeover is initiated when
the exchange of changeover messages is not possible or not
desirable, i.e., if any (or several) of the following cases apply:
i) No signalling path exists between the two ends of the unavailable link,
so that the exchange of changeover messages is impossible.
ii) Processor outage indication is received on a link. In this case, if the
remote processor outage condition is only transitory, sending of a
changeover order could result in failure of the link.
iii) A signalling link currently carrying traffic has been marked
(locally or remotely) inhibited. In this case, time controlled
changeover is used to divert traffic for the inhibited link without
causing the link to fail.
When the concerned signalling point decides to initiate changeover in such
circumstances, after the expiry of a time T1 (see S 16.8), it starts signalling
traffic not yet transmitted on the unavailable signalling link on the alternative
link(s); the purpose of withholding traffic for the time T1 (see S 16.8) is to
reduce the probability of message mis-sequencing.
An example of such a case appears in Recommendation Q.705, Annex A.
In the abnormal case when the concerned signalling point is not aware of
the situation, it will start the normal changeover procedure and send a
changeover order; in this case it will receive no changeover message in response
and the procedure will be completed as indicated in S 5.7.2. Possible reception
of a transfer-prohibited message (sent by an involved signalling transfer point
on reception of the changeover order, see S 13.2) will not affect changeover
procedures.
5.6.3 Due to failures, it may be impossible for a signalling point to perform
retrieval even if it has received the retrieval information from the far end of
the unavailable signalling link. In this case, it starts sending new traffic on
reception of the changeover message (or on time-out expiry, see SS 5.6.2 and
5.7.2); no further actions in addition to the other normal changeover procedures
are performed.
5.7 Procedures in abnormal conditions
5.7.1 The procedures described in this section allow the completion of the
changeover procedures in abnormal cases other than those described in S 5.6.
5.7.2 If no changeover message in response to a changeover order is received
within a timer T2 (see S 16.8), new traffic is started on the alternative
signalling link(s).
PAGE1 Fascicle VI.7 - Rec. Q.704
5.7.3 If a changeover order or acknowledgement containing an unreasonable value
of the forward sequence number is received, no buffer updating or retrieval is
performed, and new traffic is started on the alternative signalling link(s).
5.7.4 If a changeover acknowledgement is received without having previously sent
a changeover order, no action is taken.
5.7.5 If a changeover order is received relating to a particular signalling link
after the completion of changeover from that signalling link, an emergency
changeover acknowledgement is sent in response, without any further action.
6 Changeback
6.1 General
6.1.1 The objective of the changeback procedure is to ensure that signalling
traffic is diverted from the alternative signalling link(s) to the signalling
link made available as quickly as possible, while avoiding message loss,
duplication or mis-sequencing. For this purpose (in the normal case), changeback
includes a procedure to control the message sequence.
6.1.2 Changeback includes the basic procedures to be used to perform the
opposite action to changeover, i.e. to divert traffic from the alternative
signalling link(s) to a signalling link which has become available (i.e., it was
uninhibited, restored or unblocked). The characteristics of the alternative
signalling link(s) from which changeback can be made are described in S 5.2. In
all the cases mentioned in S 5.2 the alternative signalling links can be carrying
their own signalling traffic and this is not interrupted by the changeback
procedures.
Procedures necessary to cater for particular network configuration or
other abnormal conditions are also provided.
Note - The term "alternative signalling link(s)" refers to signalling
link(s) terminating in the signalling point at which a changeback is initiated
(see also S 4).
6.2 Changeback initiation and actions
6.2.1 Changeback is initiated at a signalling point when a signalling link is
restored, unblocked or uninhibited, and therefore it becomes once again
available, according to the criteria listed in SS 3.2.3 and 3.2.7. The following
actions are then performed:
a) the alternative signalling link(s) are determined, to which traffic
normally carried by the signalling link made available was previously
diverted (e.g., on occurrence of a changeover);
b) signalling traffic is diverted (if appropriate, according to the
criteria specified in S 4) to the concerned signalling link by means of
the sequence control procedure specified in S 6.3; traffic diversion
can be performed at the discretion of the signalling point initiating
changeback, as follows:
i) individually for each traffic flow (i.e., on destination basis);
ii) individually for each alternative signalling link (i.e., for all
the destinations previously diverted on that alternative
signalling link);
iii) at the same time for a number of, or for all the alternative
signalling links.
On occurrence of changeback, it may happen that traffic towards a given
destination is no longer routed via a given adjacent signalling transfer point,
towards which a transfer-prohibited procedure was previously performed on
occurrence of changeover (see S 5.3.1); in this case a transfer-allowed procedure
is performed, as specified in S 13.3.
In addition, if traffic towards a given destination is diverted to an
alternative signalling link terminating in a signalling transfer point not
currently used to carry traffic toward that destination, a transfer-prohibited
procedure is performed as specified in S 13.2.
Fascicle VI.7 - Rec. Q.704 PAGE27
6.2.2 In the case when there is no traffic to transfer to the signalling link
made available, none of the previous actions are performed.
6.2.3 In the case that the signalling link made available can be used to carry
signalling traffic toward a destination which was previously declared
inaccessible, the following actions apply:
i) the routing of the concerned signalling traffic is unblocked and
transmission of the concerned messages (if any) is immediately started
on the link made available;
ii) a command is sent to the User Part(s) (if any) in order to restart
generating the concerned signalling traffic;
iii) the transfer-allowed procedure is performed, as specified in S
13.3. However, in national networks, when the recovered link is not on
the normal route for that destination, the transfer-restricted11)
procedure may be performed as specified in S 13.5.
6.2.4 In the case that the signalling link made available is used to carry
signalling traffic towards a destination which was previously declared
restricted, the following actions apply:
i) the concerned signalling traffic is rediverted and transmission of the
concerned messages (if any) is immediately started on the link made
available;
ii) when the recovered link is on the normal route for that destination,
the status of the route is changed to available; otherwise, the status
of the route remains unchanged.
6.2.5 If the signalling point at the far end of the link made available
currently is inaccessible, from the signalling point initiating changeback (see S
9 on Signalling Point Restart), the sequence control procedure specified in S 6.3
(which requires communication between the two concerned signalling points) does
not apply; instead, the time-controlled diversion specified in S 6.4 is
performed. This is made also when the concerned signalling points are accessible,
but there is no signalling route to it using the same outgoing signalling link(s)
(or one of the same signalling links) from which traffic will be diverted.
6.3 Sequence control procedure
6.3.1 When a decision is made at a given signalling point to divert a given
traffic flow (towards one or more destinations) from an alternative signalling
link to the signalling link made available, the following actions are performed
if possible (see S 6.4):
i) transmission of the concerned traffic on the alternative signalling
link is stopped; such traffic is stored in a changeback buffer;
ii) a changeback declaration is sent to the remote signalling point of the
signalling link made available via the concerned alternative signalling
link; this message indicates that no more message signal units relating
to the traffic being diverted to the link made available will be sent
on the alternative signalling link.
6.3.2 The concerned signalling point will restart diverted traffic over the
signalling link made available when it receives a changeback acknowledgement from
the far signalling point of the link made available; this message indicates that
all signal messages relating to the concerned traffic flow and routed to the
remote signalling point via the alternative signalling link have been received.
The remote signalling point will send the changeback acknowledgement to the
signalling point initiating changeback in response to the changeback declaration;
any available signalling route between the two signalling points can be used to
carry the changeback acknowledgement.
6.3.3 The changeback declaration and changeback acknowledgement are signalling
network management messages and contain:
- the label, indicating the destination and originating signalling
points, and the identity of the signalling link to which traffic will
be diverted;
- the changeback-declaration (or changeback-acknowledgement) signal, and
- the changeback code.
Formats and codes of the changeback declaration and changeback
acknowledgement appear in S 15.
11) National option.
PAGE1 Fascicle VI.7 - Rec. Q.704
6.3.4 A particular configuration of the changeback code is autonomously assigned
to the changeback declaration by the signalling point initiating changeback; the
same configuration is included in the changeback acknowledgement by the
acknowledging signalling point. This allows discrimination between different
changeback declarations and acknowledgements when more than one sequence control
procedures are initiated in parallel, as follows.
6.3.5 In the case that a signalling point intends to initiate changeback in
parallel from more than one alternative signalling link, a sequence control
procedure is accomplished for each involved signalling link, and a changeback
declaration is sent on each of them; each changeback declaration is assigned a
different configuration of the changeback code. Stopped traffic is stored in one
or more changeback buffers (in the latter case, a changeback buffer is provided
for each alternative signalling link). When the changeback acknowledgement
relating to that alternative signalling link is received, traffic being diverted
from a given alternative signalling link can be restarted on the signalling link
made available, starting with the content of the changeback buffer;
discrimination between the different changeback acknowledgements is made by the
changeback code configuration, which is the same as that sent in the changeback
declaration.
This procedure allows either reopening the recovered signalling link to
traffic in a selective manner (provided that different changeback buffers are
used) as soon as each changeback acknowledgement is received, or only when all
the changeback acknowledgements have been received.
6.4 Time-controlled diversion procedure
6.4.1 The time-controlled diversion procedure is used at the end of the
signalling point restart procedure (see S 9) when an adjacent signalling point
becomes available, as well as for the reasons given in S 6.2.5. An example of
such a use appears in Figure 12/Q.704.
Figure 12/Q.704 - CCITT 35860
In this example, on failure of signalling link AB, traffic towards the
destination D was directed to signalling link AC. When AB becomes available, the
point A considers itself as the neighbour of a point which restarts and applies
the signalling point restart procedure (see S 9).
6.4.2 When changeback is initiated after the signalling point restart procedure,
the adjacent signalling point of the point which is restarting stops traffic to
be directed from the alternative signalling link(s) for a time T3, after which it
starts traffic on the signalling link(s) made available. The time delay minimizes
the probability of out-of-sequence delivery to the destination point(s).
6.5 Procedures in abnormal conditions
6.5.1 If a changeback acknowledgement is received by a signalling point which
has not previously sent a changeback declaration, no action is taken.
Fascicle VI.7 - Rec. Q.704 PAGE27
6.5.2 If a changeback declaration is received after the completion of the
changeback procedure, a changeback acknowledgement is sent in response, without
taking any further action. This corresponds to the normal action described in S
6.3.2 above.
6.5.3 If no changeback acknowledgement is received in response to a changeback
declaration within a time T4 (see S 16.8), the changeback declaration is repeated
and a new timer T5 (see S 16.8), is started. If no changeback acknowledgement is
received before the expiry of T5, the maintenance functions are alerted and
traffic on the link made available is started. The changeback code contained in
the changeback acknowledgement message makes it possible to determine, in the
case of parallel changebacks from more than one reserve path, which changeback
declaration is unacknowledged and has therefore to be repeated.
7 Forced rerouting
7.1 General
7.1.1 The objective of the forced rerouting procedure is to restore, as quickly
as possible, the signalling capability between two signalling points towards a
particular destination, in such a way as to minimize the consequences of a
failure. However, since the unavailability of a signalling route is, in general,
caused by the fact that the concerned destination has become inaccessible to a
signalling transfer point, a probability of message loss exists (see S 5.3.3).
Therefore, the structure of the signalling network should be such as to reduce
the probability of signalling route unavailability to limits compatible with the
overall dependability requirements (see Recommendation Q.706).
7.1.2 Forced rerouting is the basic procedure to be used in the case where a
signalling route towards a given destination becomes unavailable (due to, for
example, remote failures in the signalling network) to divert signalling traffic
towards that destination to an alternative signalling route outgoing from the
concerned signalling point. Signalling links pertaining to the alternative
signalling route can be carrying their own signalling traffic (relating to
different signalling routes), and this is not interrupted by the forced rerouting
procedure.
7.2 Forced rerouting initiation and actions
7.2.1 Forced rerouting is initiated at a signalling point when a
transfer-prohibited message, indicating a signalling route unavailability is
received.
The following actions are then performed:
a) transmission of signalling traffic towards the concerned destination on
the link set(s) pertaining to the unavailable route is immediately
stopped; such traffic is stored in a forced rerouting buffer;
b) the alternative route is determined according to the rules specified in
S 4;
c) as soon as action b) is completed, the concerned signalling traffic is
restarted on a link set pertaining to the alternative route, starting
with the content of the forced rerouting buffer;
d) if appropriate, a transfer-prohibited procedure is performed (see S
13.2.2).
7.2.2 In the case when there is no signalling traffic to be diverted from the
unavailable route, action b) and d) apply.
7.2.3 If no alternative route exists for signalling traffic towards the
concerned destination, that destination is declared inaccessible, and the actions
specified in S 5.3.3 apply.
8 Controlled rerouting
8.1 General
8.1.1 The objective of the controlled rerouting procedure is to restore the
optimal signalling routing and to minimize mis-sequencing of messages. Therefore,
controlled rerouting includes a time-controlled traffic diversion procedure,
which is the same as that used in some cases of changeback (see S 6.4).
PAGE1 Fascicle VI.7 - Rec. Q.704
8.1.2 Controlled rerouting is the basic procedure to be used in the following
two cases:
a) when a signalling route towards a given destination becomes available
(due to, for example, recovery of previous remote failures in the
signalling network), to divert back signalling traffic towards that
destination from the alternative to the normal signalling route
outgoing from the concerned signalling point;
b) when a transfer-restricted message is received, after signalling
traffic management has decided that alternative routing is appropriate
(e.g., because it would be more efficient than routing via the link set
over which the transfer-restricted message was received).
Signalling links pertaining to the alternative signalling route can be
carrying their own signalling traffic (relating to different routes) and this is
not interrupted by the controlled rerouting procedure.
8.2 Controlled rerouting initiation and actions
8.2.1 Controlled rerouting is initiated at a signalling point when a
transfer-allowed message, indicating that the signalling route has become
available, is received; also when a transfer-restricted message12) is received.
The following actions are then performed:
a) transmission of signalling traffic towards the concerned destination on
the link set belonging to the alternative route or the route over which
the transfer-restricted12) message was received is stopped; such
traffic is stored in a "controlled rerouting buffer"; a timer T6 (see S
16.8), is started;
b) if the signalling point serves as a signalling transfer point, a
transfer-prohibited procedure is performed for the route made available
(or the alternative route in the case of reception of a
transfer-restricted12) message, if the alternative route was not
previously used), and a transfer-allowed procedure for the alternative
one (or on the restricted route in the case of the reception of a
transfer-restricted12) message) (see SS 13.2.2 and 13.3.2,
respectively);
c) at the expiry of T6, the concerned signalling traffic is restarted on
an outgoing link set pertaining to the signalling route made available,
or the alternative route in the case of reception of the
transfer-restricted12) message, starting with the content of the
controlled rerouting buffer; the aim of the time delay is to minimize
the probability of out-of-sequence delivery to the destination
point(s).
8.2.2 In the case when there is no signalling traffic to be diverted from the
route made available, only action b) applies.
8.2.3 If the destination was inaccessible or restricted12), when the route is
made available, then the destination is declared accessible and actions specified
in SS 6.2.3 and 6.2.4 apply (if appropriate).
9 Signalling point restart
This procedure uses the Traffic Restart Allowed message (TRA) which
contains:
- the label indicating the originating signalling point and adjacent
destination signalling point;
- the traffic restart allowed signal.
The format and coding of this message appear in S 15.
9.1 Actions in a signalling point (having the transfer function) which
restarts
A signalling point restarts when it becomes available (see S 3.6.2.1). A
signalling point which restarts starts a timer T18 and starts activating all its
signalling links (see S 12).
When the first signalling link of a signalling link set is available,
message traffic terminating at the far end of the linkset is immediately
restarted (see also S 9.5).
The restarting signalling point takes into account any transfer
prohibited, transfer restricted (see S 13) and traffic restart allowed messages
received.
When all signalling links are available T18 is stopped.
12) National option.
Fascicle VI.7 - Rec. Q.704 PAGE27
When T18 is stopped or expires, the following actions are taken:
- the signalling point starts a timer T19 during which it expects to
receive additional transfer prohibited, transfer restricted (see S 13)
and traffic restart allowed messages;
- when all traffic restart allowed messages are received T19 is stopped.
When T19 is stopped or expires, the signalling point starts a timer T20
during which:
- it broadcasts eventually transfer prohibited and transfer restricted13
messages (see S 13), taking into account signalling links which are not
available a d any transfer prohibited and transfer restricted13)
messages eventually received;
- when all these operations are completed, timer T20 is stopped.
When T20 is stopped or expires, the signalling point broadcasts traffic
restart allowed messages to all adjacent signalling points and restarts the
remaining traffic.
9.2 Actions in a restarting signalling point (having no transfer function)
An SP which restarts starts a timer T21 and starts activating all its
signalling links (see S 12).
When the first signalling link of a signalling linkset is available,
message traffic terminating at the far end of the linkset is immediately
restarted (see also S 9.5).
The restarting signalling point takes into account transfer prohibited and
transfer restricted messages13) (see S 13). If a traffic restart allowed message
is received T21 is stopped. When T21 is stopped or expires, the signalling point
restarts the remaining traffic.
9.3 Actions in a signalling point X adjacent to a restarting signalling point
Y
Signalling point X knows that signalling point Y is restarting when
signalling point Y becomes accessible (see S 3.6.2.2). There are three cases to
consider:
i) Signalling points X and Y have the transfer function
a) When signalling point Y becomes accessible because a direct
linkset becomes available, signalling point X takes the
following action:
- starts a timer T21
- immediately restarts traffic terminating in signalling point Y
(see also S 9.5)
- sends any eventual transfer prohibited and transfer
restricted13) messages to signalling point Y (see S 13)
- sends a traffic restart allowed message to signalling point Y
- takes into account the eventual transfer prohibited and
transfer restricted13) messages received from SP Y (see S 13).
When a traffic restart allowed message is received from
signalling point Y, timer T21 is stopped. When T21 is stopped or
expires, signalling point X restarts any remaining traffic to Y,
and broadcasts transfer allowed messages concerning Y, and all SPs
made accessible via Y.
b) When signalling point Y becomes accessible on reception of a
transfer allowed or transfer restricted13) message (s e S 13),
signalling point X sends to signalling point Y any required
transfer prohibited and transfer restricted messages1 ) on the
available route.
13) National option.
PAGE1 Fascicle VI.7 - Rec. Q.704
ii) Signalling point X has a transfer function and signalling point Y has
not
a) When signalling point Y becomes accessible because a direct
signalling linkset becomes available, signalling point X takes
the following actions:
- immediately restarts traffic terminating in signalling point Y
(see also S 9.5)
- eventually sends to signalling point Y any transfer prohibited
and transfer restricted messages (see S 13)
- broadcasts transfer allowed messages concerning signalling
point Y and sends a traffic restart allowed message to it.
b) When signalling point Y becomes accessible on reception of a
transfer allowed or transfer restricted1 ) message, signalling
point X sends to signalling point Y any required transfer
prohibited and transfer restricted14) messages on t e available
route.
iii) Signalling point X does not have the transfer function and
signalling point Y does or does not have the transfer function.
Signalling point X takes the following action:
- immediately restarts traffic terminating at signalling point Y
(see also S 9.5)
- starts a timer T21
- takes into account any eventual transfer prohibited and transfer
restricted14) message received.
On the receipt of a traffic restart allowed message, timer T21 is
stopped. When T21 is stopped or expires, signalling point X restarts
any remaining traffic.
9.4 Actions in signalling point X on receipt of unexpected TRA message
If X has no STP function, no further action is taken.
If X has the STP function, then X sends to the adjacent point Y, from
which the TRA message was received, the appropriate TFP and TFR messages. X then
operates normally.
9.5 General rules
When a signalling point restarts, it considers, at the beginning of the
point restart procedure, all signalling routes to be allowed. A signalling route
set test message received in a restarting signalling point (during the point
restart procedure) is ignored.
Signalling route set test messages received in a signalling point adjacent
to a restarting signalling point (before T21 expires) are handled, but the
replies consider that all signalling routes using the restarting point are
prohibited. When T21 is stopped or expires these signalling routes are allowed
unless a transfer prohibited or transfer restricted14) message has been received
from the restarting signalling point during T21.
The procedure includes the general rule that late events [e.g.,
restoration of a link after T18 expires, transfer prohibited or transfer
restricted14) messages received after T19 expires, etc.] are treated outside the
restart procedure.
All messages concerning another destination received in a restarting
signalling point are treated normally during the point restart procedure. All
messages concerning a local MTP user received in a restarting signalling point
(Service Indicator != 0000) are treated normally. All messages received with
Service Indicator = 0000 in a restarting signalling point, for the signalling
point itself, are treated as described in the signalling point restart procedure;
those messages not described elsewhere in the procedure are discarded and no
action is taken (message groups CHM, ECM, FCM, RSM, MIM and DLM).
10 Management inhibiting
10.1 General
Signalling link management inhibiting is requested by management when it
becomes necessary e.g., for maintenance or testing purposes (for example, if the
link experiences too many changeovers and changebacks in a short time, or there
is a significant link error rate), to make or keep a signalling link unavailable
to User Part-generated signalling traffic. Management inhibiting is a signalling
traffic management action, and does not cause any link status changes at level 2.
A signalling link is marked "inhibited" under the management inhibiting
14) National option.
Fascicle VI.7 - Rec. Q.704 PAGE27
procedure. In particular, a signalling link that was active and in service prior
to being inhibited will remain so, and will thus be able to transmit maintenance
and test messages.
Inhibiting of a signalling link may be requested by management functions
at either end of the link. The request is granted, provided that the inhibiting
action does not cause any previously accessible destinations to become
inaccessible at either end of the signalling link. The request may also be
refused under certain circumstances such as congestion.
A signalling link normally remains inhibited until uninhibiting is invoked
in the signalling point at which inhibiting was initiated. Uninhibiting is
initiated either at the request of a management function or by routing functions
at either end of the signalling link when it is found that a destination has
become inaccessible for signalling traffic and the link sets associated with
routes to that destination contain inhibited links. Unless unavailable for other
reasons, uninhibiting causes the signalling link to enter the available state and
changeback to be initiated.
Periodic tests are made on the inhibit status of inhibited links. Such
periodic tests should not add significantly to the traffic load on the signalling
network, and remove the need for a signalling point to perform inhibit tests at
signalling point restart.
If a test on the inhibit status of a link reveals discrepancies between
the signalling points at each end of the link, the link is either uninhibited or
force uninhibited as appropriate, to align the inhibit status at each end of the
link.
10.2 Inhibiting initiation and actions
When at signalling point "X" a request is received from a management
function to inhibit a signalling link to signalling point "Y", the following
actions take place:
a) A check is performed at signalling point "X" to determine whether, in
the case of an available link, inhibiting will result in a destination
becoming inaccessible, or in the case of an unavailable link,
signalling point "Y" is inaccessible. If either is the case, management
is informed that the inhibiting request is denied.
b) If inhibiting is permitted, signalling point "X" sends an inhibit
message to signalling point "Y" indicating that it wishes to inhibit
the signalling link identified in the message.
c) Signalling point "Y", on receiving the inhibit message from "X", checks
whether, in the case of an available link, inhibiting will result in a
destination becoming inaccessible and, if so, an inhibit denied message
is returned to signalling point "X". The latter then informs the
management function which requested inhibiting that the request cannot
be granted.
d) If the signalling point "Y" finds that inhibiting of the concerned link
is permissible, it sends an inhibit acknowledgement to signalling point
"X" and marks the link remotely inhibited.
If the link concerned is currently carrying traffic, signalling point
"Y" sends the inhibit acknowledgement via that link and diverts
subsequent traffic for it, using the time controlled changeover
procedure. "Y" then starts inhibit test timer T23.
e) On receiving an inhibit acknowledgement message, signalling point "X"
marks the link locally inhibited and informs management that the link
is inhibited.
If the link concerned is currently carrying traffic, signalling point
"X" diverts subsequent traffic for that link, using the time-controlled
changeover procedure. "X" then starts inhibit test timer T22.
f) When changeover has been completed, the link while inhibited, will be
unavailable for the transfer of user-generated traffic but still
permits the exchange of test messages.
g) If, for any reason, the inhibit acknowledgement message is not
received, a timer T14 expires and the procedure is restarted including
inspection of the status of the destination of the inhibit message. If
the destination is not available, management is informed.
PAGE1 Fascicle VI.7 - Rec. Q.704
At most two consecutive automatic attempts may be made to inhibit a
particular signalling link.
A signalling point may not transmit an inhibit message for a particular
signalling link if it has already transmitted an uninhibit message for that link,
and neither an acknowledgement for that uninhibit message has been received nor
has the uninhibit procedure finally timed out.
10.3 Uninhibiting initiation and actions
Signalling link uninhibiting is initiated at the signalling point which
originally caused the link to be inhibited, upon receipt of an uninhibit or
forced uninhibit request.
In a given signalling point, an uninhibit request may be initiated for a
locally inhibited link by the management or signalling routing control function,
while a forced uninhibit request may be initiated for a remotely inhibited link
by the signalling routing control function only.
Signalling routing control will initiate signalling link uninhibit if an
inhibited link is found to be a member of a link set in a route to a destination
which has become inaccessible.
If such signalling routing control uninhibiting were unsuccessful because
of a failed or blocked inhibited link, and if that link later recovers or becomes
unblocked with the destination still unavailable, uninhibiting is re-attempted.
A signalling point may not transmit an uninhibit message for a particular
signalling link if it has already transmitted an inhibit message for that link,
and neither an acknowledgement for that inhibit message has been received nor has
the inhibit procedure finally timed out.
10.3.1 Management-initiated uninhibiting
Upon receipt of an uninhibiting request from the management function of
signalling point "X" regarding an inhibited link to signalling point "Y", the
following actions take place:
a) A check is performed at signalling point "X" to determine whether an
uninhibit message can be sent to signalling point "Y", either over an
available route, or if all routes to signalling point "Y" are
unavailable, over the concerned inhibited link. If all routes to
signalling point "Y" are unavailable and the concerned inhibited link
is marked failed or processor outage, management is informed that
uninhibiting is not possible.
b) If uninhibiting is possible, signalling point "X" sends an uninhibit
signalling link message to signalling point "Y" indicating that the
link identified in the message should be uninhibited.
c) Upon receipt of the uninhibit link message, signalling point "Y"
returns an uninhibit acknowledgement message to signalling point "X"
and cancels the remote inhibit indication. If no local inhibited,
failed or blocked condition exists on the link, it is put in the
available state and changeback is initiated.
d) On receipt of the uninhibit acknowledgement message, signalling point
"X" cancels the local inhibit indication and informs management that
the link has been uninhibited. If no remote inhibited, failed or
blocked condition exists on the link, it is put in the available state
and changeback is initiated.
e) If, for any reason, the uninhibit acknowledgement message is not
received, a timer T12 expires. If this is the first expiry of T12 for
this uninhibition attempt on this link, the procedure is restarted
including inspection of the status of the destination of the unhibit
message. If the destination is not available, or T12 has expired for
the second time during the uninhibition attempt on this link,
management is informed, and the uninhibition is abandoned.
10.3.2 Signalling routing control initiated uninhibiting
Upon receipt of an uninhibit request from signalling routing control at
signalling point "X" regarding an inhibited link to signalling point "Y", the
following actions take place:
a) A check is performed at signalling point "X" to determine whether the
concerned inhibited link is marked failed or blocked. If it is, then
signalling point "X" is unable to transmit an uninhibit message to
signalling point "Y", uninhibiting is therefore not possible, and the
uninhibiting attempt is abandoned.
b) If uninhibiting is possible, a further check is performed by signalling
Fascicle VI.7 - Rec. Q.704 PAGE27
point "X" to determine whether inhibiting initiated by "X" (local
inhibiting) or inhibiting initiated by "Y" (remote inhibiting) is in
effect.
c) If local inhibiting is in effect, then the actions described in SS
10.3.1 b), c), d) and e) take place. If uninhibition is abandoned, step
f) below is taken.
PAGE1 Fascicle VI.7 - Rec. Q.704
d) If remote inhibiting is in effect, then signalling point "X" requests
forced uninhibiting of the signalling link by sending a force uninhibit
signalling link message to signalling point "Y", which will then
initiate uninhibiting in accordance with the description given in SS
10.3.1 b), c), d) and e).
The force uninhibit signalling link message is transmitted down the link
to be uninhibited.
e) If, for any reason, an uninhibit signalling link message is not
received in response to the force uninhibit message, a timer T13
expires. If this is the first expiry of T13 for this uninhibition
attempt on this link, the procedure is restarted including inspection
of the status of the inhibited link. If the link is marked failed or
blocked, or timer T13 has expired for the second time during
uninhibition of this link, management is informed and the uninhibition
is abandoned.
f) If an attempt to uninhibit a signalling link is abandoned, signalling
routing control attempts to uninhibit the next inhibited link to
signalling point "Y", starting from a) above. The search continues
until either a link is successfully uninhibited or all possible links
to "Y" in the routing table have been exhausted, or the destination has
become available for other reasons.
10.4 Receipt of unexpected management inhibition messages
a) An inhibit signalling link message concerning an inhibited signalling
link is answered with an inhibit acknowledgement message without taking
any further action.
b) An uninhibit signalling link message concerning an uninhibited
signalling link is answered with an uninhibit acknowledgement message
without taking any further action.
c) A force uninhibit signalling link message concerning an uninhibited
link is answered with an uninhibit signalling link message without
taking any further action.
d) If an inhibit acknowledgement message is received and no inhibit
signalling link message is outstanding for the concerned link, no
action is taken.
e) If an uninhibit acknowledgement message is received and no uninhibit
signalling link message is outstanding for the concerned link, no
action is taken.
10.5 Management inhibited link status and processor recovery
a) After a local processor recovery that involves loss of inhibit status
information, the signalling point will mark all links as uninhibited,
and message traffic will be restarted.
b) If messages for Level 4 are received on an inhibited signalling link,
the messages will be discriminated and distributed.
10.6 Inhibit test procedure
When a signalling link becomes management inhibited, periodic tests are
started to guard the inhibition status at each end of the link.
10.6.1 A local inhibit test is performed when timer T22 expires at signalling
point X and the concerned link is marked locally inhibited. In this case a local
inhibit test message is sent to the signalling point Y at the other end of the
link, and timer T22 is restarted.
Reception of a local inhibit test message causes:
i) no action, if the concerned link is marked remotely inhibited at the
receiving signalling point Y or:
ii) the force uninhibit procedure to be invoked at the receiving signalling
point Y, if the concerned link is not marked remotely inhibited at Y.
This procedure causes the locally inhibited status of the link at X to
be cancelled.
If a timer T22 expires and the concerned link is not locally inhibited, no
further action is taken.
10.6.2 A remote inhibit test is performed when timer T23 expires at signalling
point Y and the concerned link is marked remotely inhibited. In this case a
remote inhibit test message is sent to signalling point X at the other end of the
link, and timer T23 is restarted.
Fascicle VI.7 - Rec. Q.704 PAGE27
Reception of a remote inhibit test message causes:
i) no action, if the concerned link is marked locally inhibited at the
receiving signalling point X or:
ii) the uninhibit procedure to be invoked at the receiving signalling point
X, if the concerned link is not marked locally inhibited at X. This
procedure causes the remotely inhibited status of the link at Y to be
cancelled.
If a timer T23 expires and the concerned link is not remotely inhibited,
no further action is taken.
11 Signalling traffic flow control
11.1 General
The purpose of the signalling traffic flow control function is to limit
signalling traffic at its source in the case when the signalling network is not
capable of transferring all signalling traffic offered by the user because of
network failures or congestion situations.
Flow control action may be taken as a consequence of a number of events;
the following cases have been identified:
- Failure in the signalling network (signalling links or signalling
points) has resulted in routeset unavailability. In this situation,
flow control may provide a short term remedy until more appropriate
actions can be taken.
- Congestion of a signalling link or signalling point has resulted in a
situation where reconfiguration is not appropriate.
- Failure of a part has made it impossible for the user to handle
messages delivered by the Message Transfer Part.
When the normal transfer capability is restored, the flow control
functions initiate resumption of the normal traffic flow.
11.2 Flow control indications
The need for the following indications has been identified.
11.2.1 Signalling route set unavailability
In the case when no signalling route is available for traffic towards a
particular destination (see SS 5.3.3 and 7.2.3) an indication is given from the
Message Transfer Part to the local user parts informing them that signalling
messages destined to the particular signalling point cannot be transferred via
the signalling network. Each user then takes appropriate actions in order to stop
generation of signalling information destined for the inaccessible signalling
point.
11.2.2 Signalling route set availability
In the case when a signalling route becomes available for traffic to a
previously unavailable destination (see SS 6.2.3 and 8.2.3), an indication is
given from the Message Transfer Part to the local user parts informing them that
signalling messages destined to the particular signalling point can be
transferred via the signalling network. Each user then takes appropriate actions
in order to start generation of signalling information destined for the now
accessible signalling point.
11.2.3 Signalling route set congestion (International signalling network)
11.2.3.1 When the congestion status of a signalling route set changes to
congested, the following actions will be taken:
i) When a message signal unit from a local User Part is received for a
congested route set the following actions are performed:
a) The MSU is passed to level 2 for transmission.
b) A congestion indication primitive will be returned to each level
4 User Part, for the initial message and for at least every n
messages (n = 8) received for the congested destination. The
congestion indication primitive contains as a parameter the DPC
of the affected destination.
PAGE1 Fascicle VI.7 - Rec. Q.704
ii) When a message signal unit is received at an STP for a congested route
set, the following actions take place:
a) The MSU is passed to level 2 for transmission.
b) A transfer controlled message is sent to the originating point
for the initial message and for every n messages (n = 8)
received from any originating point for the congested route set
or for every link of the congested route set or for every
linkset of the congested route set.
11.2.3.2 After the reception of a transfer controlled message, the receiving
signalling point informs each level 4 User Part of the affected destination by
means of a congestion indication primitive specified in S 11.2.3.1 i).
11.2.3.3 When the status of a signalling route set changes to uncongested,
normal operation is resumed. Resumption of message transmission towards the
concerned destination is the responsibility of the level 4 User Parts.
11.2.4 Signalling route set congestion (National option with congestion
priorities)
In the case when the congestion status of a signalling route set changes
as a result of either the receipt of a transfer controlled message relating to a
particular destination (see S 13.7) or an indication of local signalling link
congestion, or due to the signalling route-set-congestion-test procedure (see S
13.9) an indication is given from the Message Transfer Part to the local level 4
informing it about the current congestion status of the signalling route set.
Each user then takes appropriate actions in order to stop generation of
signalling messages destined for the affected signalling point with congestion
priorities lower than the specified congestion status. Messages received from the
local level 4 with congestion priorities lower than the current signalling route
set congestion status are discarded by the Message Transfer Part.
11.2.5 Signalling route set congestion (National options without congestion
priorities)
For national signalling networks using multiple signalling link congestion
states without congestion priority, S + 1(1 ú S ú 3) levels of route set
congestion status are provided.
The procedure is the same as that specified in S 11.2.3, except that the
congestion indication primitive contains the congestion status as a parameter in
addition to the DPC of the affected destination.
11.2.6 Signalling point/signalling transfer point congestion
The detection of congestion onset and abatement in a signalling point or
signalling transfer point should, if required, be implementation dependent. Any
resulting action taken, and messages and primitives sent, should align with those
procedures, messages and primitives specified for signalling route set
congestion.
11.2.7 MTP user flow control
If the Message Transfer Part is unable to distribute a received message to
a local User Part because that User Part is unavailable, (User Part
unavailability is an implementation dependent notion), the Message Transfer Part
sends a User Part Unavailable (UPU) message to the Message Transfer Part at the
originating signalling point.
When the originating signalling point's Message Transfer Part receives a
User Part Unavailable message, it:
a) informs the management process,
b) sends an indication (MTP-STATUS with the appropriate parameters) to the
affected local User Part informing it that that User Part at the
particular remote signalling point is unavailable.
Fascicle VI.7 - Rec. Q.704 PAGE27
The user should then take appropriate action in order to stop generation
of signalling information for the unavailable User Part.
The User Part Unavailable message contains:
- the label, indicating the destination and originating points;
- the user part unavailable signal;
- the identity of the unavailable user part.
The format and coding of this message appear in S 15.
When the Message Transfer Part is again able to distribute received
messages to a previously unavailable local User Part, that Message Transfer Part
delivers the received messages to that User Part.
11.2.8 User part congestion
User part congestion procedures in the MTP are for further study.
12 Signalling link management
12.1 General
12.1.1 The signalling link management function is used to control the locally
connected signalling links. The function provides means for establishing and
maintaining a certain predetermined capability of a link set. Thus, in the event
of signalling link failures the signalling link management function controls
actions aimed at restoring the capability of the link set.
Three sets of signalling link management procedures are specified in the
following sections. Each set corresponds to a certain level of automation as
regards allocation and reconfiguration of signalling equipment. The basic set of
signalling link management procedures (see S 12.2) provides no automatic means
for allocation and reconfiguration of signalling equipment. The basic set
includes the minimum number of functions which must be provided for international
application of the signalling system.
Two alternative sets of signalling link management procedures are provided
as options and include functions allowing for a more efficient use of signalling
equipment in the case when signalling terminal devices have switched access to
signalling data links.
12.1.2 A signalling link set consists of one or more signalling links having a
certain order of priority as regards the signalling traffic conveyed by the link
set (see S 4). Each signalling link in operation is assigned a signalling data
link and a signalling terminal at each end of the signalling data link.
The signalling link identity is independent of the identities of the
constituent signalling data link and signalling terminals. Thus, the identity
referred to by the Signalling Link Code (SLC) included in the label of messages
originated at Message Transfer Part level 3 is the signalling link identity and
not the signalling data link identity or the signalling terminal identity.
Depending on the level of automation in an application of the signalling
system, allocation of signalling data link and signalling terminals to a
signalling link may be made manually or automatically.
In the first case, applicable for the basic signalling link management
procedures, a signalling link includes predetermined signalling terminals and a
predetermined signalling data link. To replace a signalling terminal or
signalling data link, a manual intervention is required. The signalling data link
to be included in a particular signalling link is determined by bilateral
agreement (see also Recommendation Q.702).
In the second case for a given signalling point, a signalling link
includes any of the signalling terminals and any of the signalling data links
applicable to a link group. As a result of, for example, signalling link failure,
the signalling terminal and signalling data link included in a signalling link,
may be replaced automatically. The criteria and procedures for automatic
allocation of signalling terminals and signalling data links are specified in SS
12.5 and 12.6 respectively. The implementation of these functions requires that
for a given link group any signalling terminal can be connected to any signalling
data link.
Note - A link group is a group of identical signalling links directly
connecting two signalling points. A link set may include one or more link groups.
PAGE1 Fascicle VI.7 - Rec. Q.704
12.1.3 When a link set is to be brought into service, actions are taken to
establish a predetermined number of signalling links. This is done by connecting
signalling terminals to signalling data links and for each signalling link
performing an initial alignment procedure (see Recommendation Q.703, S 7.3). The
process of making a signalling link ready to carry signalling traffic is defined
as signalling link activation.
Activation of a signalling link may also be applicable, for example when a
link set is to be extended or when a persisting failure makes another signalling
link in the link set unavailable for signalling traffic.
In the case of signalling link failure, actions should be taken to restore
the faulty signalling link, i.e. to make it available for signalling again. The
restoration process may include replacement of a faulty signalling data link or
signalling terminal.
A link set or single signalling link is taken out of service by means of a
procedure defined as signalling link deactivation.
The procedures for activation, restoration and deactivation are initiated
and performed in different ways depending on the level of automation applicable
for a particular implementation of the signalling system. In the following,
procedures are specified for the cases when:
a) no automatic functions are provided for allocation of signalling
terminals and signalling data links (see S 12.2).
b) an automatic function is provided for allocation of signalling
terminals (see S 12.3).
c) automatic functions are provided for allocation of signalling terminals
and signalling data links (see S 12.4).
12.2 Basic signalling link management procedures
12.2.1 Signalling link activation
12.2.1.1 In the absence of failures, a link set contains a certain predetermined
number of active (i.e. aligned) signalling links. In addition, the link set may
contain a number of inactive signalling links, i.e. signalling links which have
not been put into operation. Predetermined signalling terminals and a signalling
data link are associated with each inactive signalling link.
The number of active and inactive signalling links in the absence of
failures, and the priority order for the signalling links in a link set, should
be identical at both ends of the link set.
Note - In the typical case, all signalling links in a link set are active
in the absence of failures.
12.2.1.2 When a decision is taken to activate an inactive signalling link,
initial alignment starts. If the initial alignment procedure is successful, the
signalling link is active and a signalling link test is started. If the
signalling link test is successful the link becomes ready to convey signalling
traffic. In the case when initial alignment is not possible, as determined at
Message Transfer Part level 2 (see Recommendation Q.703, S 7), new initial
alignment procedures are started on the same signalling link after a time T17
(delay to avoid the oscillation of initial alignment failure and link restart.
The value of T17 should be greater than the loop delay and less than timer T2,
see Recommendation Q.703, S 7.3). If the signalling link test fails, link
restoration starts until the signalling link is activated or a manual
intervention is made.
12.2.2 Signalling link restoration
After a signalling link failure is detected, signalling link initial
alignment will take place. In the case when the initial alignment procedure is
successful, a signalling link test is started. If the signalling link test is
successful the link becomes restored and thus available for signalling.
If initial alignment is not possible, as determined at Message Transfer
Part level 2 (see Recommendation Q.703, S 7), new initial alignment procedures
may be started on the same signalling link after a time T17 until the signalling
link is restored or a manual intervention is made e.g. to replace the signalling
data link or the signalling terminal.
If the signalling link test fails, the restoration procedure is repeated
until the link is restored or a manual intervention made.
Fascicle VI.7 - Rec. Q.704 PAGE27
12.2.3 Signalling link deactivation
An active signalling link may be made inactive by means of a deactivation
procedure, provided that no signalling traffic is carried on that signalling
link. When a decision has been taken to deactivate a signalling link the
signalling terminal of the signalling link is taken out of service.
12.2.4 Link set activation
A signalling link set not having any signalling links in service is
started by means of a link set activation procedure. Two alternative link set
activation procedures are defined:
- link set normal activation,
- link set emergency restart.
12.2.4.1 Link set normal activation
Link set normal activation is applicable when a link set is to be put into
service for the first time (link set initial activation) or when a link set is to
be restarted (link set normal restart); the latter is applicable for example in
the case when:
- all signalling links in a link set are faulty,
- a processor restart in a signalling point makes it necessary to
re-establish a link set,
- a signalling point recognizes other irregularities concerning the
interworking between the two signalling points,
provided that none of the above events create an emergency situation.
When link set normal activation is initiated, signalling link activation
starts on as many signalling links as possible. (All signalling links in the link
set are regarded as being inactive at the start of the procedure.)
The signalling link activation procedures are performed on each signalling
link in parallel as specified in S 12.2.1 until the signalling links are made
active.
Signalling traffic may, however, commence when one signalling link is
successfully activated.
12.2.4.2 Link set emergency restart
Link set emergency restart is applicable when an immediate reestablishment
of the signalling capability of a link set is required, (i.e. in a situation when
the link set normal restart procedure is not fast enough). The precise criteria
for initiating link set emergency restart instead of normal restart may vary
between different applications of the signalling system. Possible situations for
emergency restart are, for example:
- when signalling traffic that may be conveyed over the link set to be
restarted is blocked,
- when it is not possible to communicate with the signalling point at the
remote end of the link set.
When link set emergency restart is initiated, signalling link activation
starts on as many signalling links as possible, in accordance with the principles
specified for normal link set activation. In this case, the signalling terminals
will have emergency status (see Recommendation Q.703, S 7) resulting in the
sending of status indications of type "E" when applicable. Furthermore, the
signalling terminals employ the emergency proving procedure and short time-out
values in order to accelerate the procedure.
When the emergency situation ceases, a transition from emergency to normal
signalling terminal status takes place resulting in the employment of the normal
proving procedure and normal time-out values.
12.2.4.3 Time-out values
The initial alignment procedure (specified in Recommendation Q.703, S 7.3)
includes time-outs the expiry of which indicates the failure of an activation or
restoration attempt.
PAGE1 Fascicle VI.7 - Rec. Q.704
12.3 Signalling link management procedures based on automati
allocation of signalling terminals
12.3.1 Signalling link activation
12.3.1.1 In the absence of failures a link set contains a certain predetermined
number of active (i.e. aligned) signalling links. The link set may also contain a
number of inactive signalling links.
An inactive signalling link is a signalling link not in operation. A
predetermined signalling data link is associated with each inactive signalling
link; however, signalling terminals may not yet be allocated.
The number of active and inactive signalling links in the absence of
failures, and the priority order for the signalling links in a link set, should
be identical at both ends of the link set.
12.3.1.2 Whenever the number of active signalling links is below the value
specified for the link set, actions to activate new inactive signalling links
should be taken automatically. This is applicable, for example, when a link set
is to be brought into service for the first time (see S 12.3.4) or when a link
failure occurs. In the latter case, activation starts when the restoration
attemps on the faulty link are considered unsuccessful (see S 12.3.2).
The signalling link(s) to activate is the inactive link(s) having the
highest priority in the link set.
Generally, if it is not possible to activate a signalling link, an attempt
to activate the next inactive signalling link (in priority order) is made. In the
case when an activation attempt performed on the last signalling link in the link
set is unsuccessful, the "next" signalling link is the first inactive signalling
link in the link set (i.e. there is a cyclic assignment).
Activation of a signalling link may also be initiated manually.
Activation shall not be initiated automatically for a signalling link
previously deactivated by means of a manual intervention.
12.3.1.3 When a decision is taken to activate a signalling link, the signalling
terminal to be employed has to be allocated at each end.
The signalling terminal is allocated automatically by means of the
function defined in S 12.5.
In the case when the automatic allocation function cannot provide a
signalling terminal the activation attempt is aborted.
The predetermined signalling data link which may be utilized for other
purposes when not connected to a signalling terminal must be removed from its
alternative use (e.g. as a speech circuit) before signalling link activation can
start.
12.3.1.4 The chosen signalling terminal is then connected to the signalling data
link and initial alignment starts (see Recommendation Q.703, S 7).
If the initial alignment procedure is successful, the signalling link is
active and a signalling link test is started. If the signalling link test is
successful the link becomes ready to convey signalling traffic.
If initial alignment is not possible, as determined at Message Transfer
Part level 2 (see Recommendation Q.703, S 7), the activation is unsuccessful and
activation of the next inactive signalling link (if any) after a time T17 is
initiated. Successive initial alignment attempts may, however, continue on the
previous (faulty) signalling link after a time T17 until it is restored or its
signalling terminal is disconnected (see S 12.5).
In view of the fact that if it is not possible to activate a signalling
link an attempt is made to activate the next inactive signalling link in a link
set, it may be that the two ends of a link set continuously attempt to activate
different signalling links. By having different values of initial alignment time
out T2 at the two ends of the link set (see S 12.3.4.3) it is ensured that
eventually both ends of the link set will attempt to activate the same signalling
link.
Fascicle VI.7 - Rec. Q.704 PAGE27
12.3.2 Signalling link restoration
12.3.2.1 After a signalling link failure is recognized, signalling link initial
alignment will take place (see Recommendation Q.703, S 7). In the case when the
initial alignment is successful, a signalling link test is started. If the
signalling link test is successful the link becomes restored and thus available
for signalling. If the initial alignment is unsuccessful or the test fails, the
signalling terminals and signalling link may be faulty and require replacement.
12.3.2.2 The signalling terminal may be automatically replaced in accordance
with the principles defined for automatic allocation of signalling terminals (see
S 12.5). After the new signalling terminal has been connected to the signalling
data link, signalling link initial alignment starts. If successful, the
signalling link is restored.
If initial alignment is not possible or if no alternative signalling
terminal is available for the faulty signalling link, activation of the next
signalling link in the link set (if any) starts. In the case when it is not
appropriate to replace the signalling terminal of the faulty signalling link
(e.g. because it is assumed that the signalling data link is faulty) activation
of the next inactive signalling link (if any) is also initiated. In both cases
successive initial alignment attempts may continue on the faulty signalling link
after a time T17 until a manual intervention is made or the signalling terminal
is disconnected (see S 12.5).
Note - In the case when a signalling terminal cannot be replaced,
activation of the next signalling link is only initiated if the link set includes
an alternative link group having access to signalling terminals other than the
one used by the signalling link for which restoration is not possible.
12.3.3 Signalling link deactivation
In the absence of failures a link set contains a specified number of
active (i.e. aligned) signalling links. Whenever that number is exceeded (e.g. as
a result of signalling link restoration), the active signalling link having the
lowest priority in the link set is to be made inactive automatically provided
that no signalling traffic is carried on that signalling link.
Deactivation of a particular signalling link may also be initiated
manually, for example in conjunction with manual maintenance activities.
When a decision has been taken to deactivate a signalling link, the
signalling terminal and signalling data link may be disconnected.
After deactivation, the idle signalling terminal may become part of other
signalling links (see S 12.5).
12.3.4 Link set activation
A signalling link set not having any signalling links in service is
started by means of a link set activation procedure. The objective of the
procedure is to activate a specified number of signalling links for the link set.
The activated signalling links should, if possible, be the signalling links
having the highest priority in the link set. Two alternative link set activation
procedures are defined:
- link set normal activation,
- link set emergency restart.
12.3.4.1 Link set normal activation
Link set normal activation is applicable when a link set is to be put into
service for the first time (link set initial activation) or when a link set is to
be restarted (link set normal restart); the latter is applicable, for example, in
the case when:
- all signalling links in a link set are faulty;
- a processor restart in a signalling point makes it necessary to
re-establish a link set;
- a signalling point recognizes other irregularities concerning the
interworking between the two signalling points, e.g. that a certain
signalling data link is associated with different signalling links at
the two ends of the link set;
provided that none of the above events create an emergency situation.
PAGE1 Fascicle VI.7 - Rec. Q.704
When link set normal activation is initiated, signalling link activation
starts on as many signalling links as possible. (All signalling links in the link
set are regarded as being inactive at the start of the procedure). If activation
cannot take place on all signalling links in the link set (e.g., because a
sufficient number of signalling terminals is not available), then the signalling
links to activate are determined in accordance with the link priority order.
Note - All idle signalling terminals may not necessarily be made available
for link set activation. Thus making possible, for example, restoration of faulty
signalling links in other link sets at the same time.
The signalling link activation procedures are performed as specified in S
12.3.1.
If the activation attempt for a signalling link is unsuccessful (i.e.
initial alignment is not possible), activation of the next inactive signalling
link, if any, in the priority order is initiated. (Inactive links exist in the
case when the number of signalling terminals available is less than the number of
signalling links defined for the link set). According to the principles for
automatic allocation of signalling terminals defined in S 12.5, the signalling
terminal connected to the unsuccessfully activated signalling link will typically
be connected to the signalling data link of that signalling link for which the
new activation attempt is to be made.
When a signalling link is successfully activated, signalling traffic may
commence.
After the successful activation of one signalling link, the activation
attempts on the remaining signalling links continue in accordance with the
principles defined in S 12.3.1, in such a way that the signalling links having
the highest priorities are made active. This is done in order to obtain, if
possible, the normal configuration within the link set. Signalling link
activation continues until the predetermined number of active signalling links is
obtained.
12.3.4.2 Link set emergency restart
Link set emergency restart is applicable in the case the link set normal
restart procedure is not fast enough. Emergency restart is performed in the same
way as link set normal activation except that, in the case of emergency restart,
the emergency proving procedure and the short emergency time-out values (see
Recommendation Q.703, S 7) are employed in order to accelerate the procedure (see
further S 12.2.4.2).
12.3.4.3 Time-out values
The values of the initial alignment time-out T2 (see Recommendation Q.703,
S 7) will be different at the two ends of the link set, if automatic allocation
of signalling terminals or signalling data links is applied at both ends of a
signalling link set.
12.4 Signalling link manageme t procedures based on automatic
allocation of signalling data links and signalling terminals
12.4.1 Signalling link activation
12.4.1.1 In the absence of failures a link set contains a certain predetermined
number of active (i.e. aligned) signalling links. The link set may also contain a
number of inactive signalling links.
An inactive signalling link is a signalling link currently not in
operation. It is not associated with any signalling terminal or signalling data
link (i.e. the signalling link is only identified by its position in the link
set).
The number of active and inactive signalling links (in the absence of
failures), and the priority order for the signalling links in a link set, should
be identical at both ends of the link set.
12.4.1.2 Whenever the number of active signalling links is below the value
specified for the link set, actions to activate new inactive signalling links
should be taken automatically. This is, for example, applicable when a link set
is to be brought into service for the first time (see S 12.4.4) or when a link
failure occurs. In the latter case, activation starts when the restoration
attempts on the faulty link are considered unsuccessful (see S 12.4.2).
The signalling link(s) to activate is the inactive link(s) having the
highest priority in the link set.
Fascicle VI.7 - Rec. Q.704 PAGE27
If it is not possible to activate a signalling link an attempt to activate
the next inactive signalling link (in priority order) is made. In the case when
an activation attempt performed on the last signalling link in the link set is
unsuccessful, the "next" signalling link is the first inactive link in the link
set (i.e. a cyclic assignment).
Note - Activation of the next signalling link is only initiated if the
link set includes an alternative link group, having access to other signalling
terminals and/or other signalling data links than the signalling link for which
activation is not possible.
Activation of a particular signalling link may also be initiated upon
receiving a request from the remote signalling point, or by a manual request.
Activation shall not be initiated automatically for a signalling link
previously inactivated by means of a manual intervention.
12.4.1.3 When a decision is taken to activate a signalling link, the signalling
terminals and signalling data link to be employed have to be allocated.
A signalling terminal is allocated automatically by means of the function
defined in S 12.5.
The signalling data link is allocated automatically by means of the
function defined in S 12.6. However, in conjunction with link set activation the
identity of the signalling data link to use may be predetermined (see further
S 12.4.4). A signalling data link which is not connected to a signalling terminal
may be utilized for other purposes, e.g. as a speech circuit. When the data link
is to be employed for signalling, it must be removed from its alternative use.
In the case when the automatic allocation functions cannot provide a
signalling terminal or a signalling data link, the activation attempt is aborted.
12.4.1.4 When the signalling data link and signalling terminal to be used for a
particular signalling link are determined, the signalling terminal is connected
to the signalling data link and signalling link initial alignment starts (see
Recommendation Q.703, S 7). If the initial alignment procedure is successful, the
signalling link is active and a signalling link test is started. If the
signalling link test is successful the link becomes ready to convey signalling
traffic.
If initial alignment is not possible, as determined at Message Transfer
Part level 2 (see Recommendation Q.703, S 7), alternative signalling data links
are automatically connected to the signalling terminal, until an initial
alignment procedure is successfully completed. In the case when the function for
automatic allocation of signalling data links cannot provide an alternative
signalling data link, the activation is regarded as unsuccessful and activation
of the next inactive signalling link (if any) is initiated (see, however, the
Note to S 12.4.1.2 above). Successive initial alignment attempts may continue on
the previous signalling link after a time T17 until it is activated or its
signalling terminal is disconnected (see S 12.5).
12.4.2 Signalling link restoration
12.4.2.1 After a signalling link failure is recognized, signalling link initial
alignment will take place (see Recommendation Q.703, S 7). In the case when the
initial alignment is successful, a signalling link test is started. If the
signalling link test is successful the link becomes restored and thus available
for signalling.
If the initial alignment is unsuccessful or if the test fails the
signalling terminal and signalling data link may be faulty and require
replacement.
12.4.2.2 The signalling data link may be automatically replaced by an
alternative, in accordance with the principles defined in S 12.6. After the new
signalling data link has been connected to the signalling terminal, signalling
link initial alignment starts. If successful, the signalling link is restored. If
not, alternative data links are connected to the signalling terminal, until an
initial alignment procedure is successfully completed.
If the automatic allocation function cannot provide a new signalling data
link, activation of the next inactive signalling link (if any) is initiated (see,
however, the Note to S 12.4.1.2). Successive initial alignment attempts may,
however, continue on the previous (faulty) signalling link after a time T17 until
it is restored or its signalling terminal is disconnected.
PAGE1 Fascicle VI.7 - Rec. Q.704
12.4.2.3 The signalling terminal may be automatically replaced in accordance
with the principles defined in S 12.5. After the new signalling terminal has been
connected to the signalling data link, signalling link initial alignment starts.
If successful, the signalling link is restored. If not, activation of the next
signalling link in the link set (if any) starts (see, however, the Note to S
12.4.1.2).
Successive initial alignment attempts may, however, continue on the
previous (faulty) signalling link after a time T17 until it is restored or, for
example, the signalling terminal or signalling data link is disconnected.
Note - Activation of the next signalling link in the link set should not
be initiated as long as one of the activities described in SS 12.4.2.2 and
12.4.2.3 above is taking place.
12.4.3 Signalling link deactivation
In the absence of failures, a link set contains a specified number of
active (i.e. aligned) signalling links. Whenever that number is exceeded (e.g. as
a result of signalling link restoration) the active signalling link having the
lowest priority in the link set is to be made inactive automatically, provided
that no signalling traffic is carried on that signalling link.
Deactivation of a particular signalling link may also be initiated
manually, e.g. in conjunction with manual maintenance activities.
When a decision has been taken to deactivate a signalling link, the
signalling terminal and signalling data link may be disconnected. After
deactivation the idle signalling terminal and signalling data link may become
parts of other signalling links (see SS 12.5 and 12.6).
12.4.4 Link set activation
Link set activation is applicable in the case when a link set not having
any signalling links in service is to be started for the first time or after a
failure (see S 12.3.4). The link set activation procedure is performed as
specified in S 12.3.4, also as regards the allocation of signalling data links,
i.e. signalling data links are allocated in accordance with predetermined list
assigning a signalling data link to some or all of the signalling links in the
link set. This is done in order to cater for the situation when it is not
possible to communicate with the remote end of the link set (see S 12.6).
However, when a signalling link has become active, signalling data link
allocation may again be performed automatically (i.e. activation of a signalling
link takes place as specified in S 12.4.1).
12.5 Automatic allocation of signalling terminals
In conjunction with the signalling link activation and restoration
procedures specified in SS 12.3 and 12.4, signalling terminals may be allocated
automatically to a signalling link. A signalling terminal applicable to the link
group is allocated in accordance with the following principles:
a) an idle signalling terminal (i.e. a signalling terminal not connected
to a signalling data link) is chosen if possible;
b) if no idle signalling terminal is available, a signalling terminal is
chosen which is connected to an unsuccessfully restored or activated
signalling link.
Note - Activation and restoration is regarded as unsuccessful when it is
not possible to complete the initial alignment procedure successfully (see SS
12.3 and 12.4).
Measures should be employed to ensure that signalling terminal to be
allocated to signalling links are able to function correctly (see Recommendation
Q.707).
A link set may by assigned a certain number of signalling terminals. A
signalling terminal may be transferred from a signalling link in one link set to
a signalling link in another set [in accordance with b) above] only when the
remaining number of signalling terminals in the link set is not below the
specified value.
Note - From a link set with a minimum number of signalling terminals, only
one signalling terminal and signalling data link may be removed at a time (e.g.
for testing, see Recommendation Q.707).
Fascicle VI.7 - Rec. Q.704 PAGE27
PAGE1 Fascicle VI.7 - Rec. Q.704