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Corr. MEP Insertion des tableaux (tabulateurs...) BAT du 6/6/89 07.07.89 PV MAJ s/disquettes 2.07.89 CD 2 Fascicle VI.7 -- Rec. Q.704 |
13.1 General
National option. The purpose of the signalling route management function is to ensure a reliable exchange of information between the signalling points about the availability of the signalling routes.
The unavailability, restriction and availability of a signalling route is communicated by means of the transfer-prohibited, transfer-restricted and transfer allowed procedures, respectively in §§ 13.2, 13.4 and 13.3.
Recovery of signalling route status information is made by means of the signalling-route-set-test procedure specified in § 13.5.
In the international signalling network, congestion of a route set is communicated by means of the transfer-controlled (TFC) messages specified in § 13.6.
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In national networks, congestion of a signalling route set may be communicated by means of the TFC as specified |
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in §§ 13.2 |
13.7 and 13.8 and the signalling route set congestion test procedure specified in § 13.9. Transfer prohibited 13.2.1 The transfer-prohibited procedure is performed at a signalling point acting as a signalling transfer point for |
messages relating to a given destination, when it has to notify one or more adjacent signalling points that they must no longer route the concerned messages via that signalling transfer point.
13 Signalling route management
Fascicle VI.7 -- Rec. Q.704 3
The transfer-prohibited procedure makes use of the transfer-prohibited message which contains:
-- the label, indicating the destination and originating points;
-- the transfer-prohibited signal; and
-- the destination for which traffic transfer is no longer possible.
Format and code of these messages appear in § 15.
Transfer prohibited messages are always addressed to an adjacent signalling point. They may use any available signalling route that leads to that signalling point.
13.2.2 A transfer-prohibited message relating to a given destination X is sent from a signalling transfer point Y in the following cases:
i) When signalling transfer point Y starts to route (at changeover, changeback, forced or controlled rerouting) signalling destined to signalling point X via a signalling transfer point Z not currently used by signalling transfer point Y for this traffic. In this case the transfer-prohibited message is sent to signalling transfer point Z.
ii) When signalling transfer point Y recognizes that it is unable to transfer signalling traffic destined to signalling point X (see §§ 5.3.3 and 7.2.3). In this case a transfer-prohibited message is sent to all accessible adjacent signalling points (Broadcast method).
iii) When a message destined to signalling point X is received at signalling transfer point Y and Y is unable to transfer the message. In this case the transfer prohibited message is sent to the adjacent signalling point from which the message concerned was received (Response Method).
iv) When an adjacent signalling point Z becomes accessible, STP Y sends to Z a transfer prohibited message concerning destination X, if X is inaccessible from Y (see § 9).
v) When a signalling transfer point Y restarts, it broadcasts to all accessible adjacent signalling points transfer prohibited messages concerning destination X, if X is inaccessible from Y (see § 9).
As long as transfer-prohibited messages for a destination are being transmitted according to criteria i), ii), iv), or v) above, and also within T8 (see § 16) after the last transfer-prohibited message was transmitted, no transfer-prohibited messages will be sent via the Response Method (criterion iii) above) referring to that destination.
Examples of the above situation appear in Recommendation Q.705.
13.2.3 When a signalling point receives a transfer-prohibited message from signalling transfer point Y it performs the actions specified in § 7 (since reception of transfer-prohibited message indicates the unavailability of the concerned signalling route, see § 3.4.1). In other words, it may perform forced re-routing and, if appropriate, generate additional transfer-prohibited messages.
13.2.4 In some circumstances it may happen that a signalling point receives either a repeated transfer-prohibited message relating to a nonexistent route (i.e. there is no route from that signalling point to the concerned destination via signalling transfer point Y, according to the signalling network configuration) or to a destination which is already inaccessible, due to previous failures; in this case no actions are taken.
13.3 Transfer allowed
13.3.1 The transfer-allowed procedure is performed at a signalling point, acting as signalling transfer point for messages relating to a given destination, when it has to notify one or more adjacent signalling points that they may start to route to it, if appropriate, the concerned messages.
The possibility of referring to a more general destination than a single signalling point (e.g. a signalling
region), or more restrictive destination than a signalling point is for further study.
4 Fascicle VI.7 -- Rec. Q.704
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The transfer-allowed procedure makes use of the transfer-allowed message which contains: -- the label, indicating the destination and originating points; -- the transfer-allowed signal; and -- the destination for which transfer is now possible. |
Fascicle VI.7 -- Rec. Q.704 5
The format and code of these messages appear in § 15.
Transfer allowed messages are always addressed to an adjacent signalling point. They may use any available signalling route that leads to that signalling point.
13.3.2 A transfer-allowed message relating to a given destination ``X'' is sent from signalling transfer point ``Y'' in the following cases:
i) When signalling transfer point ``Y'' stops routing (at changeback or controlled rerouting) signalling traffic destined to signalling point ``X'' via a signalling transfer point ``Z'' (to which the concerned traffic was previously diverted as a consequence of changeover or forced rerouting). In this case the transfer-allowed message is sent to signalling transfer point ``Z''.
ii) When signalling transfer point ``Y'' recognizes that it is again able to transfer signalling traffic destined to signalling point ``X'' (see §§ 6.2.3 and 8.2.3). In this case a transfer-allowed message is sent to all accessible adjacent signalling points. (Broadcast method).
Examples of the above situations appear in Recommendation Q.705.
13.3.3 When a signalling point receives a transfer-allowed message from signalling transfer point ``Y'', it performs the actions specified in § 8 (since reception of a transfer-allowed message indicates the availability of the concerned signalling route, (see § 3.4.2)). In other words, it may perform controlled re-routing and, if appropriate, generate additional transfer-allowed messages.
13.3.4 In some circumstances it may happen that a signalling point receives either a repeated transfer-allowed message or a transfer-allowed message relating to a non-existent signalling route (i.e. there is no route from that signalling point to the concerned destination via signalling transfer point Y according to the signalling network configuration); in this case no actions are taken.
13.4 Transfer-restricted (National option)
13.4.1 The transfer restricted procedure is performed at a signalling point acting as a signalling transfer point for messages relating to a given destination, when it has to notify one or more adjacent signalling points that they should, if possible, no longer route the concerned messages via the signalling transfer point.
The transfer-restricted procedure makes use of the transfer-restricted message which contains:
-- the label, indicating the destination and originating points;
-- the transfer-restricted signal, and
-- the destination for which traffic is no longer desirable.
Formats and codes of this message appear in § 15.
Transfer restricted messages are always adressed to an adjacent signalling point. They may use any available signalling route that leads to that signalling point.
Note -- Undesirable situations result in increased signalling delays, possibly overloading portions of the network. These inefficiencies could be avoided if the traffic can be appropriately diverted.
13.4.2 A transfer-restricted message relating to a given destination ``X'' is sent from a signalling transfer point ``Y'' when the normal link set (combined link set) used by signalling point ``Y'' to route to destination ``X'' experiences a long-term failure such as an equipment failure, or there is congestion on an alternate link set currently being used to destination ``X''. In this case, a transfer-restricted message is sent to all accessible adjacent signalling points.
The possibility of referring to a more general destination than a single signalling point (e.g. a signalling
region), or a more restrictive destination than a single signalling point is for further study.
6 Fascicle VI.7 -- Rec. Q.704
When an adjacent signalling point ``X'' becomes accessible, the STP ``Y'' sends to ``X'' transfer-restricted messages concerning destinations that are restricted from ``Y'' (see § 9).
When a signalling point Y restarts, it broadcasts to all accessible adjacent signalling points transfer restricted messages concerning destinations restricted from ``Y'' (see § 9).
Note -- Characterization of long term failure remains for further study.
Fascicle VI.7 -- Rec. Q.704 7
13.4.3 When a signalling point receives a transfer-restricted message from signalling transfer point ``Y'' and has an alternative equal priority link set available and not restricted to destination ``X'', it performs the actions in § 8.2. In other words, it performs controlled rerouting to maintain the sequence of messages while diverting them to the alternative link set. If it cannot perform alternate routing to destination ``X'' because no alternative link set is available, it may generate additional transfer-restricted messages.
13.4.4 In some circumstances, it may happen that a signalling point receives either a repeated transfer-restricted message or a transfer-restricted message relating to a non-existent route (i.e. there is no route from that signalling point to the concerned destination via signalling transfer point ``Y'', according to the signalling network configuration); in this case, no actions are taken.
13.4.5 When a transfer-restricted message is received updating a transfer-prohibited status, signalling traffic management decides if an alternative route is available or restricted; if it is not (i.e. no alternative route exists), the concerned traffic is restarted towards the signalling point from which the transfer-restricted message was received. Otherwise, no other actions are taken.
13.5 Signalling-route-set-test
13.5.1 The signalling-route-set-test procedure is used at a signalling point to test whether or not signalling traffic towards a certain destination may be routed via an adjacent signalling transfer point.
The procedure makes use of the signalling-route-set-test message, and the transfer-allowed and the transfer-prohibited procedures.
The signalling-route-set-test message contains:
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-- -- -- -- |
the label, indicating the destination and originating points; the signalling-route-set-test signal; the destination, the accessibility of which is to be tested; and the current route status of the destination being tested. |
Format and coding of this message appear in § 15.
13.5.2 A signalling-route-set-test message is sent from a signalling point after a transfer-prohibited or transfer-restricted message is received from an adjacent signalling transfer point. In this case, a signalling-route-set-test message is sent to that signalling transfer point referring to the destination declared inaccessible or restricted by the transfer-prohibited or transfer-restricted message, every T10 period (see § 16) until a transfer-allowed message, indicating that the destination has become accessible, is received.
This procedure is used in order to recover the signalling route availability information that may not have been received because of some signalling network failure.
13.5.3 A signalling-route-set-test message is sent to the adjacent signalling transfer point as an ordinary signalling network management message.
13.5.4 At the reception of a signalling-route-set-test message, a signalling transfer point will compare the status of the destination in the received message with the actual status of the destination. If they are the same, no further action is taken. If they are different, one of the following messages is sent in response, dictated by the actual status of the destination:
-- a transfer-allowed message, referring to the destination the accessibility of which is tested, if the signalling transfer point can reach the indicated destination via a signalling link not connected to the signalling point
The possibility of referring to a more general destination than a single signalling point (e.g. a signalling
region), or a more restrictive destination than a single signalling point is for further study.
8 Fascicle VI.7 -- Rec. Q.704
from which the signalling-route-set-test message was originated, and via the normal routing;
-- a transfer-restricted message when access to the destination is possible via an alternative to the normal routing which is less efficient, but still not via the signalling point from which the signalling route-set-test was originated;
-- a transfer-prohibited message in all other cases (including the inaccessibility of that destination).
Fascicle VI.7 -- Rec. Q.704 9
13.5.5 At the reception of the transfer-prohibited or transfer-allowed message, the signalling point will perform the procedures specified in §§ 13.2.3 or 13.2.4 and 13.3.3 or 13.3.4 respectively.
13.6 Transfer controlled (International network)
The only use made of the transfer controlled procedure in the international signalling network is to convey the congestion indication from the SP where congestion was detected to the originating SP (see § 11.2.3) in a transfer-controlled message.
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The transfer-controlled message contains: -- the label, indicating the destination and originating points; -- the transfer controlled signal; -- the identity of the congested destination. The format and coding of the transfer controlled message appear in § 15. |
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13.7 |
Transfer controlled (National option with congestion priorities) 13.7.1 The transfer-controlled procedure is performed at a signalling transfer point for messages relating to a |
given destination, when it has to notify one or more originating signalling points that they should no longer send to the concerned destination messages with a given priority or lower.
The transfer-controlled procedure makes use of the transfer-controlled message which contains:
-- the label, indicating the destination and originating points,
-- the transfer-controlled signal,
-- the destination for which messages with a congestion priority lower than the specified congestion status should no longer be sent, and
-- the current congestion status encountered in routing a particular message towards the concerned destination.
The format and coding of this message appear in § 15.
13.7.2 A transfer-controlled message relating to a given destination ``X'' is sent from a signalling transfer point ``Y'' in response to a received message originating from signalling point ``Z'' destined to signalling point ``X'' when the congestion priority of the concerned message is less than the current congestion status of the signalling link selected to transmit the concerned message from ``Y'' to ``X''.
In this case, the transfer-controlled message is sent to the originating point ``Z'' with the congestion status field set to the current congestion status of the signalling link.
13.7.3 When the originating signalling points ``Z'' receive a transfer-controlled message relating to destination ``X'', if the current congestion status of the signalling route set towards destination ``X'' is less than the congestion status in the transfer-controlled message, it updates the congestion status of the signalling route set towards destination ``X'' with the value of the congestion status carried in the transfer-controlled message.
13.7.4 If within T15 (see § 16) after the receipt of the last transfer-controlled message relating to destination ``X'', signalling point ``Z'' receives another transfer-controlled message relating to the same destination, the following action is taken: If the value of the congestion status carried in the new transfer-controlled message is greater than the current value of the congestion status of the signalling route set towards destination ``X'', then the current value is updated by the new value.
10 Fascicle VI.7 -- Rec. Q.704
13.7.5 If T15 (see § 16) expires after the last update of the signalling route set towards destination ``X'' by a transfer-controlled message relating to the same destination, the signalling-route-set-congestion-test procedure is invoked (see § 13.9).
13.7.6 In some circumstances it may happen that a signalling point receives a transfer-controlled message relating to a destination which is already inaccessible due to previous failures; in this case the transfer-controlled message is ignored.
Fascicle VI.7 -- Rec. Q.704 11
13.8 Transfer controlled (National option without congestion priorities)
The only use made of the TFC procedure by the national signalling network, using multiple congestion states without congestion priorities, is to convey the congestion indication primitive from the SP where congestion was detected to the originating SP (see § 11.2.5) in a transfer-controlled message.
The transfer-controlled message contains:
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-- -- -- -- |
the label, indicating the destination and originating points; the transfer-controlled signal; the identity of the congested destination; the current congestion status encountered in routing a particular message towards the concerned |
The format and coding of this message appear in § 15.
13.9 Signalling-route-set-congestion-test (National Option)
13.9.1 The signalling-route-set-congestion-test procedure is used at an originating signalling point to update the congestion status associated with a route set towards a certain destination. The purpose is to test whether or not signalling messages destined towards that destination with a given congestion priority or higher may be sent.
In the case of a processor restart the congestion status of all signalling route sets will be initialized to the zero value. The response mechanism within the transfer-controlled procedure will correct signalling route sets whose congestion status does not have the zero value.
The procedure makes use of the signalling-route-set-congestion-test message, and the transfer-controlled procedure.
The signalling-route-set-congestion-test message contains:
-- the label, indicating the destination and originating points, and
-- the signalling-route-set-congestion-test signal.
The format and coding of this message appear in § 15.
13.9.2 The signalling-route-set-congestion-test message differs from other signalling network management messages in that it is not assigned the highest congestion priority. Instead, the congestion priority assigned to a signalling-route-set-congestion-test message to be sent to a given destination is equal to one less than the current congestion status associated with the signalling route set towards the destination.
13.9.3 If within T16 (see § 16), after sending a signalling-route-set-congestion-test message, a transfer-controlled message relating to the concerned destination is received, the signalling point updates the congestion status of the signalling route set towards the concerned destination with the value of the congestion status carried in the transfer-controlled message. Following this, the procedures specified in §§ 13.9.4 and 13.9.5 are performed.
If T16 (see § 16) expires after sending a signalling-route-set-congestion-test message without a transfer-controlled message relating to the concerned destination having been received, the signalling point changes the congestion status associated with the signalling route set towards the concerned destination to the next lower status.
13.9.4 Provided that the signalling route set towards destination ``X'' is not in the ``unavailable'' state, a signalling-route-set-congestion-test message is sent from an originating signalling point to destination ``X'' in the following cases:
12 Fascicle VI.7 -- Rec. Q.704
i) When T15 (see § 16) expires after the last update of the congestion status of the signalling route set toward destination ``X'' by a transfer-controlled message relating to the same destination.
ii) When T16 (see § 16) expires after sending a signalling-route-set-congestion-test message to destination
``X'' without a transfer-controlled message relating to the same destination having been received. After the congestion status has been decremented by one, the test is repeated, unless the congestion status is zero.
Fascicle VI.7 -- Rec. Q.704 13
13.9.5 At the reception of a signalling-route-set-congestion-test message, a signalling transfer point will route it as an ordinary message, i.e. according to the procedure specified in § 2.3.5.
13.9.6 When a signalling-route-set-congestion-test message reaches its destination, it is discarded.
14.1 General
The basic signal unit format which is common to all message signal units is described in Recommendation Q.703, § 2. From the point of view of the Message Transfer Part level 3 functions, common characteristics of the message signal units are the presence of:
-- the service information octet;
-- the label, contained in the signalling information field, and, in particular, the routing label.
14.2 Service information octet
The service information octet of message signal units contains the service indicator and the sub-service field. The structure of the service information octet is shown in Figure 13/Q.704.
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14.2.1 |
Service indicator |
Figure 13/Q.704, p. |
The service indicator is used by signalling handling functions to perform message distribution (see § 2.4) and, in some special applications, to perform message routing (see § 2.3).
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14 |
The service indicator codes for the international signalling network are allocated as follows: bits D C B A 0 0 0 0 Signalling network management messages 0 0 0 1 Signalling network testing and maintenance messages 0 0 1 0 Spare 0 0 1 1 SCCP 0 1 0 0 Telephone User Part Fascicle VI.7 -- Rec. Q.704 |
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0 0 0 1 1 1 1 1 |
1 1 1 0 0 0 0 1 |
0 1 1 0 0 1 1 0 |
1 0 1 0 1 0 1 0 |
ISDN User Part Data User Part (call and circuit related messages) Data User Part (facility registration and cancellation messages) Reserved for MTP Testing User Part spare |
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1 1 1 |
1 1 1 |
0 1 1 |
1 0 1 |
.bp |
The allocation of the service indicator codes for national signalling networks is a national matter. However, it is suggested to allocate the same service indicator code to a User Part which performs similar functions as in the international network.
14.2.2 Sub-service field
The sub-service field contains the network indicator (bits C and D) and two spare bits (bits A and B).
The network | ndicator is used by signalling message handling functions (e.g., in order to determine the relevant version of a User Part), see §§ 2.3 and 2.4.
If the network indicator is set to 00 or 01, the two spare bits, coded 00, are available for possible future needs that may require a common solution for all international User Parts.
If the network indicator is set to 10 or 11, the two spare bits are for national use. They may be used, for example, to indicate message priority, which is used in the optional flow control procedure in national applications.
The network indicator provides for discrimination between international and national messages. It can also be used, for example, for the discrimination between functionally two national signalling networks, each having different routing label structures and including up to 16 User Parts defined by the 16 possible codes of the service indicator.
In the case of only one national signalling network the spare code of the network indicator reserved for national use can be used, for example, to define an additional 16 User Parts (making a total of 32 User Parts) for that national signalling network.
The network indicator codes are allocated as follows:
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bits 0 |
0 |
D |
C International network |
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0 1 1 |
1 0 1 |
Spare (for international use only) National network Reserved for national use |
The international spare code (01) should not be used for implementing features which are to be provided both internationally and nationally.
In national applications, when the discrimination provided by the network indicator between international and national messages is not used, i.e. in a closed national signalling network seen from the signalling point of view, the whole sub-service field can be used independently for different User Parts.
Fascicle VI.7 -- Rec. Q.704 15
14.3 Label
The structure and content of the label is defined for each User Part and is defined in the relevant specification. The common part of the label used for signalling message handling, the routing label, is specified in § 2.2.
15.1 General
15.1.1 The signalling network management messages are carried on the signalling channel in message signal units, the format of which is described in § 14 and in Recommendation Q.703, § 2. In particular, as indicated in § 14.2 these messages are distinguished by the configuration 0000 of the service indicator (SI). The sub-service field (SSF) of the messages is used according to the rules indicated in § 14.2.2.
15.1.2 The signalling information field consists of an integral number of octets and contains the label, the heading code and one or more signals and indications. The structure and function of the label, and of the heading code, are described in §§ 15.2 and 15.3 respectively; the detailed message formats are described in the following sections. For each message the sequence of fields is shown in the corresponding figure, including fields that may or may not be present.
16 Fascicle VI.7 -- Rec. Q.704
In the figures, the fields are shown starting from the right to the left (i.e. the first field to be transmitted is at the right). Within each field the information is transmitted least significant bit first. Spare bits are coded 0 unlesss otherwise indicated.
15.2 Label
For signalling network management messages the label coincides with the routing label and indicates the destination and originating signalling points of the message; moreover, in the case of messages related to a particular signalling link, it also indicates the identity of the signalling link among those interconnecting the destination and originating points. The standard label structure of Message Transfer Part level 3 messages appears in Figure 14/Q.704; the total length is 32 bits.
Figure 14/Q.704, p.
The meaning and use of the destination point code (DPC) and of the originating point code (OPC) fields are described in § 2. The signalling link code (SLC) indicates the signalling link, connecting the destination and originating points, to which the message is related. If the message is not related to a signalling link, or another particular code is not specified, it is coded 0000.
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15.3 |
Heading code (H0) The heading code (H0) is the 4 bit field following the label and identifies the message group. The different heading codes are allocated as follows: 0000 Spare 0001 Changeover and changeback messages 0010 Emergency changeover message 0011 Transfer controlled and signalling route set congestion messages 0100 Transfer-prohibited-allowed-restricted messages 0101 Signalling-route-set-test messages 0110 Management inhibit messages 0111 Traffic restart allowed message 1000 Signalling-data-link-connection messages Fascicle VI.7 -- Rec. Q.704 |
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1001 Spare
1010 User part flow control messages
The remaining codings are spare.
The synopsis of singalling network management messages is given in Table 1/Q.704. 18 Fascicle VI.7 -- Rec. Q.704
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15.4 |
Changeover message 15.4.1 The format of the changeover message is shown in Figure 15/Q.704. |
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Figure 15/Q.704, p. |
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15.4.2 The changeover message is made up of the following fields: -- Label (32 bits): see § 15.2 -- Heading code H0 (4 bits): see § 15.3 -- Heading code H1 (4 bits): see § 15.4.3 -- Forward sequence number of last accepted message signal unit (7 bits) -- A filler bit coded 0 15.4.3 The heading code H1 contains signal codes as follows: bit D C B A 0 0 0 1 Changeover order signal 0 0 1 0 Changeover acknowledgement signal |
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15.5 |
Changeback message 15.5.1 The format of the changeback message is shown in Figure 16/Q.704. |
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Figure 16/Q.704, p. |
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15.5.2 The changeback message is made up of the following fields: -- Label (32 bits) see § 15.2 Fascicle VI.7 |
-- Rec. Q.704 19 |
-- Heading code H0 (4 bits): see § 15.3
-- Heading code H1 (4 bits): see § 15.5.3
-- Changeback code (8 bits): see § 15.5.4 20 Fascicle VI.7 -- Rec. Q.704
15.5.3 The header code H1 contains signal codes as follows:
bit D C B A
0 1 0 1 Changeback declaration signal
0 1 1 0 Changeback acknowledgement signal
15.5.4 The changeback code is an 8 bit code assigned by the signalling point which sends the message according to the criteria described in § 6.
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15.6 |
Emergency changeover message 15.6.1 The format of the emergency changeover message is shown in Figure 17/Q.704. |
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Figure 17/Q.704, p. |
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15.6.2 The emergency changeover message is made up of the following fields: -- Label (32 bits): see § 15.2 -- Heading code H0 (4 bits): see § 15.3 -- Heading code H1 (4 bits): see § 15.6.3 15.6.3 The header code H1 contains signal codes as follows: bit D C B A 0 0 0 1 Emergency changeover order signal 0 0 1 0 Emergency changeover acknowledgement signal |
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15.7 |
Transfer-prohibited message 15.7.1 The format of the transfer-prohibited message is shown in Figure 18/Q.704. Fascicle VI.7 -- Rec. Q.704 |
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Figure 18/Q.704, p. 22 Fascicle VI.7 -- Rec. Q.704
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15.7.2 The transfer-prohibited message is made up of the following fields: -- Label (32 bits): see § 15.2 -- Heading code H0 (4 bits): see § 15.3 -- Heading code H1 (4 bits): see § 15.7.3 -- Destination (14 bits): see § 15.7.4 -- Spare bits (2 bits) code 00 15.7.3 The heading code H1 contains one signal code as follows: bit D C B A 0 0 0 1 Transfer-prohibited signal 15.7.4 The destination field contains the identity of the signalling point to which the message refers. |
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15.8 |
Transfer-allowed message 15.8.1 The format of the transfer-allowed message is shown in Figure 19/Q.704. Figure 19/Q.704, p. 15.8.2 The transfer-allowed message is made up of the following fields: -- Label (32 bits): see § 15.2 -- Heading code H0 (4 bits): see § 15.3 -- Heading code H1 (4 bits): see § 15.8.3 -- Destination (14 bits): see § 15.7.4 -- Spare bits (2 bits) coded 00 Note -- For the use of the 2 spare bits in the national option for a SIF compatibility mechanism, see |
Recommendation Q.701, § 7.2.6.
15.8.3 The heading code H1 contains one signal code as follows:
bit D C B A
0 1 0 1 Transfer-allowed signal
Fascicle VI.7 -- Rec. Q.704 23
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15.9 |
Transfer restricted message (national option) 15.9.1 The format of the transfer restricted message is shown in Figure 18/Q.704. 15.9.2 The transfer restricted message is made up of the following fields: -- Label (32 bits): see § 15.2 -- Heading code H0 (4 bits): see § 15.3 -- Heading code H1 (4 bits): see § 15.9.3 -- Destination (14 bits): see § 15.9.4 -- Spare (2 bits) coded 00 |
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24 |
Fascicle VI.7 -- Rec. Q.704 |
15.9.3 The heading code H1 contains one signal code as follows:
bit D C B A
0 0 1 1 Transfer restricted
15.9.4 The destination field contains the identity of the signalling point to which the message refers.
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15.10 Signalling-route-set-test message 15.10.1 The format of the signalling-route-set-test message is shown in Figure 20/Q.704. |
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Figure 20/Q.704, p. |
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15.10.2 This message is made up of the following fields: |
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-- -- -- -- -- |
Label (32 bits): see § 15.2 Heading code H0 (4 bits): see § 15.3 Heading code H1 (4 bits): see § 15.10.3 Destination (14 bits): see § 15.7.4 Spare bits (2 bits) coded 00 |
15.10.3 The heading code H1 contains signal codes as follows:
bit D C B A
0 0 0 1 Signalling-route-set-test signal for prohibited destination
0 0 1 0 Signalling-route-set-test signal for restricted destination (national option)
15.11 Management inhibit message
15.11.1 The format of the management inhibit message is shown in Figure 20a/Q.704.
Fascicle VI.7 -- Rec. Q.704 25
Figure 20a/Q.704, p. 26 Fascicle VI.7 -- Rec. Q.704
15.11.2 The management inhibit message is made up of the following fields:
-- Label (32 bits): see § 15.2
-- Heading code H0 (4 bits): see § 15.3
-- Heading code H1 (4 bits): see § 15.11.3
15.11.3 The header code H1 contains signal codes as follows:
|
bit 0 |
D 0 |
0 |
C |
1 |
B |
A Link inhibit signal |
||||||||
|
0 0 0 0 0 0 1 |
0 0 1 1 1 1 0 |
1 1 0 0 1 1 0 |
0 1 0 1 0 1 0 |
Link uninhibit signal Link inhibited acknowledgement signal Link uninhibited acknowledgement signal Link inhibit denied signal Link force uninhibit signal Link local inhibit test signal Link remote inhibit test signal |
|
15.12 Traffic restart allowed message 15.12.1 The format of the traffic restart allowed message is shown in Figure 21/Q.704. |
|
|
Figure 21/Q.704, p. |
|
|
15.12.2 The traffic restart allowed message is made up of the following fields: |
-- Label (32 bits): see § 15.2
-- Heading code H0 (4 bits): see § 15.3
-- Heading code H1 (4 bits): see § 15.12.3
15.12.3 The heading code H1 contains one signal code as follows:
bit D C B A
Fascicle VI.7 -- Rec. Q.704 27
0 0 0 1 Traffic restart allowed signal
15.13 Signalling-data-link-connection-order message
15.13.1 The format of the signalling-data-link-connection-order message is shown in Figure 22/Q.704.
Figure 22/Q.704, p. 28 Fascicle VI.7 -- Rec. Q.704
15.13.2 The signalling-data-link-connection-order message is made up of the following fields:
|
-- -- -- -- -- |
Label (32 bits): see § 15.2 Heading code H0 (4 bits): see § 15.3 Heading code H1 (4 bits): see § 15.13.3 Signalling data link identity (12 bits): see § 15.13.4 Spare bits (4 bits) coded 0000. |
15.13.3 The heading code H1 contains one signal code as follows:
bit D C B A
0 0 0 1 Signalling-data-link-connection-order signal
15.13.4 The signalling data link identity field contains the circuit identification code (CIC), or the bearer identification code (BIC) in case of a 64 kbit/s channel used to carry submultiplex data streams, of the transmission link corresponding to the signalling data link.
15.14 Signalling-data-link-connection-acknowledgement message
15.14.1 The format of the signalling-data-link-connection-acknowledgement message is shown in Figure 22a/Q.704.
Figure 22a/Q.704, p. 15.14.2 The signalling-data-link-connection acknowledgement message is made up of the following fields:
-- Label (32 bits): see § 15.2
Fascicle VI.7 -- Rec. Q.704 29
-- Heading code H0 (4 bits): see § 15.3
-- Heading code H1 (4 bits): see § 15.14.3
15.14.3 The heading code H1 contains signal codes as follows:
|
bit D 0 0 |
D 0 |
1 |
1 |
C |
B 0 |
B |
A Connection-successful signal |
||||||
|
30 |
0 0 0 1 Fascicle |
0 1 VI.7 |
1 0 -- |
1 0 |
Rec. |
1 0 Q.704 |
Connection-not-successful signal Connection-not-possible signal |
|
15.15 Transfer controlled message 15.15.1 The format of the TFC message is shown in Figure 22b/Q.704. |
|
|
Figure 22b/Q.704, p. |
|
|
15.15.2 The transfer controlled message is made up of the following fields: -- Label (32 bits): see § 15.2 |
|
-- -- -- -- |
Heading code H0 (4 bits): see § 15.3 Heading code H1 (4 bits): see § 15.15.3 Destination (14 bits): see § 15.15.4 Spare (2 bits): see §15.15.5 |
15.15.3 The heading code H1 contains one signal code as follows:
bit D C B A
0 0 1 0 Transfer controlled signal
15.15.4 The destination field carries the address of the destination to which the message refers.
15.15.5 In national signalling networks using multiple congestion states, the spare bits in the transfer controlled message are used to carry the congestion status associated with the destination.
15.16 Signalling-route-set-congestion-test message (national option)
15.16.1 The format of the signalling-route-set-congestion-test message is shown in Figure 22c/Q.704.
Fascicle VI.7 -- Rec. Q.704 31
Figure 22c/Q.704, p. 32 Fascicle VI.7 -- Rec. Q.704
15.16.2 The signalling-route-set-congestion test message is made up of the following fields:
-- Label (32 bits): see § 15.2
-- Heading code H0 (4 bits): see § 15.3
-- Heading code H1 (4 bits): see § 15.16.3
15.16.3 The heading code H1 contains one signal code as follows:
bit D C B A
0 0 0 1 Signalling-route-set-congestion-test signal
|
15.17 User part unavailable message 15.17.1 The format of the user part unavailable message is shown in Figure 22d/Q.704. |
|
|
Figure 22d/Q.704, p. |
|
|
15.17.2 The user part unavailable message is made up of the following fields: |
|
-- -- -- -- -- -- -- |
Label (32 bits): see § 15.2 Heading code H0 (4 bits): see § 15.3 Heading code H1 (4 bits): see § 15.17.3 Destination (14 bits): see § 15.15.4 Spare (2 bits): coded 00 User part identity (4 bits): see § 15.17.4 Spare (4 bits) coded 0000 |
15.17.3 The heading code H1 contains signal codes as follows:
bit D C B A
0 0 0 1 User part unavailable
15.17.4 The user part identity is coded as follows:
Fascicle VI.7 -- Rec. Q.704 33
|
bit 0 0 0 0 0 0 0 0 1 1 |
D 0 0 0 0 1 1 1 1 0 0 |
0 0 1 1 0 0 1 1 0 0 |
C |
0 1 0 1 0 1 0 1 0 1 |
B |
A Spare Spare Spare SCCP TUP ISUP DUP Spare MTP Testing User Part |
to Spare
1 1 1 1
34 Fascicle VI.7 -- Rec. Q.704
H.T. [1T1.704]
TABLE 1/Q.704
Heading code allocation of signalling network
management messages
center box; cw(24p) | lw(12p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) . Message Group H1 H0 0000 0001 0010 0011 0100 0101 0110 0111
1000 1001 1010 1011 1100 1101 1110 1111 _ cw(24p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) .
0000 _ lw(24p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) . CHM 0001 COO COA CBD CBA _ lw(24p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) . ECM 0010 ECO ECA _ lw(24p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) . FCM 0011 RCT TFC _ lw(24p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) . TFM 0100 TFP * TFR TFA * _ lw(24p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) . RSM 0101 RST RSR _ lw(24p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) . MIM 0110 LIN LUN LIA LUA LID LFU LLT LRT _ lw(24p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) . TRM 0111 TRA _ lw(24p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) . DLM 1000 DLC CSS CNS CNP _ lw(24p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) . 1001 _ lw(24p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) . UFC 1010 UPU _ lw(24p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) . 1011 _ lw(24p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) .
1100 _ lw(24p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) . 1101 _ lw(24p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) . 1110 _ lw(24p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) | cw(12p) . 1111
|
Note -- Values marked * should not be used (codes used in the Yellow Book for TFP and TFA acknowledgement). CBA Changeback-acknowledgement signal CBD Changeback-declaration signal CHM Changeover and changeback messages CNP Connection-not-possible signal CNS Connection-not-successful signal COA Changeover-acknowledgement signal COO Changeover-order signal CSS Connection-successful signal DLC Signalling-data-link-connection-order signal |
Fascicle VI.7 -- Rec. Q.704 35
DLM Signalling-data-link-connection-order message
ECA Emergency-changeover-acknowledgement signal
|
ECM Emergency-changeover message |
||
|
Table 1/Q.704 + Notes [1T1.704], p. |
||
|
36 Fascicle VI.7 -- Rec. Q.704 |
H.T. [2T1.704]
|
ECO Emergency-changeover-order signal FCM Signalling-traffic-flow-control messages RCT Signalling-route-set-congestion-test signal RSM Signalling-route-set-test message RSR Signalling-route-set-test signal for restricted destination (national option) RST Signalling-route-set-test signal for prohibited destination TFR Transfer-restricted signal (national option) TFA Transfer-allowed signal TFC Transfer-controlled signal TFM Transfer-prohibited-transfer-allowed-transfer-restricted messages TFP Transfer-prohibited signal TRA Traffic-restart-allowed signal TRM Traffic-restart-allowed message MIM Management inhibit messages LID Link inhibit denied signal LFU Link forced uninhibit signal LIN Link inhibit signal LIA Link inhibit acknowledgement signal LUA Link uninhibit acknowledgement signal LUN Link uninhibit signal LLT Link local inhibit test signal LRT Link remote inhibit test signal UFC User part flow control messages UPU User part unavailable signal |
Notes to Table 1/Q.704 (cont.) [2T1.704], p. 16 State transition diagrams
16.1 General
§ 16 contains the description of the signalling network functions described in §§ 2 to 13 in the form of state transition diagrams according to the CCITT Specification and Description Language (SDL).
A set of diagrams is provided for each of the following major functions:
-- signalling message handling (SMH), described in § 2;
Fascicle VI.7 -- Rec. Q.704 37
-- signalling traffic management (STM), described in §§ 4 to 11;
-- signalling route management (SRM), described in § 13;
-- signalling link management (SLM), described in § 12.
16.1.1 For each major function a figure illustrates a subdivision into functional specification blocks, showing their functional interactions as well as the interactions with the other major functions. In each case this is followed by figures showing state transition diagrams for each of the functional specification blocks.
The detailed functional breakdown shown in the following diagrams is intended to illustrate a reference model and to assist interpretation of the text in the earlier sections. The state transition diagrams are intended to show precisely the behaviour of the signalling system under normal and abnormal conditions as viewed from a remote location. It must be emphasized that the functional partitioning shown in the following diagrams is used only to facilitate understanding of the system behaviour and is not intended to specify the functional partitioning to be adopted in a practical implementation of the signalling system.
38 Fascicle VI.7 -- Rec. Q.704
16.2 Drafting conventions
16.2.1 Each major function is designated by its acronym (e.g. SMH = signalling message handling).
16.2.2 Each functional block is designated by an acronym which identifies it and also identifies the major function to which it belongs (e.g. HMRT = signalling message handling-message routing; TLAC = signalling traffic management-link availability control).
16.2.3 External inputs and outputs are used for interactions between different functional blocks. Included within each input and output symbol in the state transition diagrams are acronyms which identify the functions which are the source and destination of the message, e.g.:
L2 ñ | 3 indicates that the message is sent between functional levels:
from: functional level 2,
to: functional level 3.
RTPC ñ | SRC indicates that the message is sent within a functional level (3 in this case):
from: signalling route management-transfer prohibited control,
to: signalling traffic management-signalling routing control.
16.2.4 Internal inputs and outputs are only used to indicate control of time-outs.
16.2.5 Notations for national operations
National options are included in the main body of the state transition diagrams (STDs) with dotted or dashed lines; if their use should exclude or modify some of the international logic, the relevant sections are marked ``t'' and a note is added to the figure. Also, the options are marked as follows:
|
Transfer restricted -- dashed lines. Multiple congestion states -- dotted lines (with the hatched symbols removed where shown). |
||
|
16.3 |
Signalling message handling Figure 23/Q.704 shows a subdivision of the signalling message handling (SMH) function into smaller functional specification blocks and also |
shows the functional interactions between them. Each of these functional specification blocks is described in detail in a state transition diagram as follows:
|
16.4 |
a) b) c) d) |
message discrimination (HMDC) is shown in Figure 24/Q.704; message distribution (HMDT) is shown in Figure 25/Q.704; message routing (HMRT) is shown in Figure 26/Q.704; handling of messages under signalling link congestion is shown in Figure 26a/Q.704. Signalling traffic management |
Figure 27/Q.704 shows a subdivision of the signalling traffic management (STM) function into smaller functional specification blocks and also shows functional interactions between them. Each of these functional specification blocks is described in detail in a state transition diagram as follows:
a) link availability control (TLAC) is shown in Figure 28/Q.704;
b) signalling routing control (TSRC) is shown in Figure 29/Q.704;
c) changeover control (TCOC) is shown in Figure 30/Q.704;
Fascicle VI.7 -- Rec. Q.704 39
|
40 |
d) changeback e) forced f ) controlled g) signalling h) signalling i) signalling Fascicle |
changeback control (TCBC) is shown in Figure 31/Q.704; forced rerouting control (TFRC) is shown in Figure 32/Q.704; controlled rerouting control (TCRC) is shown in Figure 33/Q.704; signalling traffic flow control (TSFC) is shown in Figure 34a/Q.704; signalling route set congestion control (TRCC) is shown in Figure 29a/Q.704; signalling point restart control (TPRC) is shown in Figure 34b/Q.704. VI.7 -- Rec. Q.704 |
16.5 Signalling link management
Figure 35/Q.704 shows a subdivision of the signalling link management function (SLM) into smaller functional specification blocks and also shows functional interactions between them. Each of these functional specification blocks is described in detail in a state transition diagram as follows:
|
16.6 |
a) b) c) d) e) f ) g) |
link set control (LLSC) is shown in Figure 36/Q.704; signalling link activity control (LSAC) is shown in Figure 37/Q.704; signalling link activation (LSLA) is shown in Figure 38/Q.704; signalling link restoration (LSLR) is shown in Figure 39/Q.704; signalling link deactivation (LSLD) is shown in Figure 40/Q.704; signalling terminal allocation (LSTA) is shown in Figure 41/Q.704; signalling data link allocation (LSDA) is shown in Figure 42/Q.704. Signalling route management |
Figure 43/Q.704 shows a subdivision of the signalling route management (SRM) function into smaller functional specification blocks and also shows functional interactions between them. Each of these functional specification blocks is described in detail in a state transition diagram as follows:
|
16.7 |
a) b) c) d) e) f ) |
transfer prohibited control (RTPC) is shown in Figure 44/Q.704; transfer allowed control (RTAC) is shown in Figure 45/Q.704; transfer restricted control (RTRC) is shown in Figure 46c/Q.704; transfer controlled control (RTCC) is shown in Figure 46a/Q.704; signalling route set test control (RSRT) is shown in Figure 46/Q.704; signalling-route-set-congestion-test control (RCAT) is shown in Figure 46b/Q.704. Abbreviations used in Figures 23/Q.704 onwards |
|
BSNT DPC FSNC HMCG HMDC HMDT HMRT L1 L2 L3 L4 LLSC |
Backward sequence number of next signal unit to be transmitted Destination point code Forward sequence number of last message signal unit accepted by remote level 2 Signalling link congestion Message discrimination Message distribution Message routing Level 1 Level 2 Level 3 Level 4 Link set control |
Fascicle VI.7 -- Rec. Q.704 41 |
|
42 |
LSAC LSDA LSLA LSLD LSLR LSTA MGMT RCAT RSRT Fascicle |
Signalling Signalling Signalling Signalling Signalling Signalling Signalling-route-set-congestion-test Signalling VI.7 |
Signalling link activity control Signalling data link allocation Signalling link activation Signalling link deactivation Signalling link restoration Signalling terminal allocation Management system Signalling-route-set-congestion-test control Signalling route set test control -- Rec. Q.704 |
|
RTAC RTCC RTPC RTRC SLM SLS SLTC SMH SRM STM TCBC TCOC TCRC TFRC TLAC TPRC TRCC TSFC TSRC |
Transfer allowed control Transfer controlled control Transfer prohibited control Transfer restricted control Signalling link management Signalling link selection Signalling link test control Signalling message handling Signalling route management Signalling traffic management Changeback control Changeover control Controlled rerouting control Forced rerouting control Link availability control Signalling point restart control Signalling route set congestion control Signalling traffic flow control Signalling routing control |
16.8 Timers and timer values
The following timers have been defined. The ranges are given below. The values, in brackets, are the minimum values for use when routes with long propagation delays are used (e.g., routes including satellite sections).
|
T1 Delay to avoid message mis-sequencing on changeover. 500 (800) to 1200 ms. T2 Waiting for changeover acknowledgement. 700 (1400) to 2000 ms. |
|
T3 Time controlled diversion-delay to avoid mis-sequencing on changeback. 500 (800) to 1200 ms. T4 Waiting for changeback acknowledgement (first attempt). 500 (800) to 1200 ms. |
|
T5 Waiting for changeback acknowledgement (second attempt). 500 (800) to 1200 ms. T6 Delay to avoid message mis-sequencing on controlled rerouting. 500 (800) to 1200 ms. |
T7 Waiting for signalling data link connection acknowledgement.
Fascicle VI.7 -- Rec. Q.704 43
1 to 2 seconds.
T8 Transfer prohibited inhibition timer (transient solution). 800 to 1200 ms.
T9 Not used.
T10 Waiting to repeat signalling route set test message.
30 to 60 seconds.
44 Fascicle VI.7 -- Rec. Q.704
T11 Transfer restricted timer. (This is one way of implementing the function described in § 13.4 and mainly intended to simplify STPs.) 30 to 90 seconds.
|
T12 Waiting for uninhibit acknowledgement. 800 to 1500 ms. T13 Waiting for force uninhibit. 800 to 1500 ms. |
|
T14 2 to 3 seconds. T15 |
Waiting for inhibition acknowledgement. Waiting to start signalling route set congestion test. |
||
|
2 to 3 seconds. T16 |
Waiting for route set congestion status update. |
1.4 to 2 seconds.
|
T17 Delay to avoid oscillation of initial alignment failure and link restart. 800 to 1500 ms. T18 Timer at restarting STP, waiting for signalling links to become available. 20 seconds (provisional value). |
|
T19 Timer at restarting STP, started after T18, waiting to receive all traffic restart allowed messages. 4 seconds (provisional value). T20 Timer at restarting STP, started after T19, waiting to broadcast traffic restart allowed messages, |
and restart remaining traffic. |
|
4 seconds (provisional value). |
|
T21 Timer at restarting signalling point having no STP function, waiting to restart traffic routed through adjacent SP; AND timer at STP adjacent to restarting STP, waiting for traffic restart allowed message; AND timer at SP having no STP function adjacent to restarting SP, waiting to restart any traffic to route through adjacent SP. 30 seconds (provisional value). |
|
T22 Local inhibit test timer. 3 min to 6 min (provisional value). T23 Remote inhibit test timer. 3 min to 6 min (provisional value). |
T24 Stabilising timer after removal of local processor outage, used in LPO latching to RPO (national option).
500 ms (provisional value).
Fascicle VI.7 -- Rec. Q.704 45
Blanc
46 Fascicle VI.7 -- Rec. Q.704
Figure 23/Q.704, p.18 Fascicle VI.7 -- Rec. Q.704 47
Figure 24/Q.704, p.19 48 Fascicle VI.7 -- Rec. Q.704
Figure 25/Q.704 (feuillet 1 sur 2), p.20 Fascicle VI.7 -- Rec. Q.704 49
Figure 25/Q.704 (feuillet 2 sur 2), p.21 50 Fascicle VI.7 -- Rec. Q.704
Figure 26/Q.704 (feuillet 1 sur 2), p.22 Fascicle VI.7 -- Rec. Q.704 51
Figure 26/Q.704 (feuillet 2 sur 2), p.23 52 Fascicle VI.7 -- Rec. Q.704
Figure 26a/Q.704, p.24 Fascicle VI.7 -- Rec. Q.704 53
Figure 27/Q.704 (feuillet 1 sur 3), p.25 54 Fascicle VI.7 -- Rec. Q.704
Figure 27/Q.704 (feuillet 2 sur 3), p.26 Fascicle VI.7 -- Rec. Q.704 55
Figure 27/Q.704 (feuillet 3 sur 3), p.27 56 Fascicle VI.7 -- Rec. Q.704
Figure 28/Q.704 (feuillet 1 sur 17), p.28 Fascicle VI.7 -- Rec. Q.704 57
Figure 28/Q.704 (feuillet 2 sur 17), p.29 58 Fascicle VI.7 -- Rec. Q.704
Figure 28/Q.704 (feuillet 3 sur 17), p.30 Fascicle VI.7 -- Rec. Q.704 59
Figure 28/Q.704 (feuillet 3bis sur 17), p.31 60 Fascicle VI.7 -- Rec. Q.704
Figure 28/Q.704 (feuillet 4 sur 17), p.32 Fascicle VI.7 -- Rec. Q.704 61
Figure 28/Q.704 (feuillet 5 sur 17), p.33 62 Fascicle VI.7 -- Rec. Q.704
Figure 28/Q.704 (feuillet 5bis sur 17), p.34 Fascicle VI.7 -- Rec. Q.704 63
Figure 28/Q.704 (feuillet 6 sur 17), p.35 64 Fascicle VI.7 -- Rec. Q.704
Figure 28/Q.704 (feuillet 6bis sur 17), p.36 Fascicle VI.7 -- Rec. Q.704 65
Figure 28/Q.704 (feuillet 7 sur 17), p.37 66 Fascicle VI.7 -- Rec. Q.704
Figure 28/Q.704 (feuillet 8 sur 17), p.38 Fascicle VI.7 -- Rec. Q.704 67
Figure 28/Q.704 (feuillet 9 sur 17), p.39 68 Fascicle VI.7 -- Rec. Q.704
Figure 28/Q.704 (feuillet 10 sur 17), p.40 Fascicle VI.7 -- Rec. Q.704 69
Figure 28/Q.704 (feuillet 11 sur 17), p.41 70 Fascicle VI.7 -- Rec. Q.704
Figure 28/Q.704 (feuillet 12 sur 17), p.42 Fascicle VI.7 -- Rec. Q.704 71
Figure 28/Q.704 (feuillet 13 sur 17), p.43 72 Fascicle VI.7 -- Rec. Q.704
Figure 28/Q.704 (feuillet 14 sur 17), p.44 Fascicle VI.7 -- Rec. Q.704 73
Figure 28/Q.704 (feuillet 15 sur 17), p.45 74 Fascicle VI.7 -- Rec. Q.704
Figure 28/Q.704 (feuillet 16 sur 17), p.46 Fascicle VI.7 -- Rec. Q.704 75
Figure 28/Q.704 (feuillet 17 sur 17), p.47 76 Fascicle VI.7 -- Rec. Q.704
Fascicle VI.7 -- Rec. Q.704 77