SIGNALLING BETWEEN CIRCUIT MULTIPLICATION EQUIPMENTS (CME) AND
INTERNATIONAL SWITCHING CENTRES (ISC)
1. Introduction
This Recommendation contains principles and examples of signalling
between ISC (exchanges) and their associated circuit multiplication
equipments. (In call modification is for further study.)
Circuit multiplication equipments may have integral echo control and
A/u law converter functions.
The information in this Recommendation is compatible with the control
procedures for such devices.
2. Definitions relating to CME
2.1 Digital circuit multiplication equipment (DCME) and CME
DCME and CME constitute a general class of equipment which permits
concentration of a number of trunks on a reduced number of transmission channels.
DCME in particular permits concentration of a number of 64 kbit/s PCM encoded
trunks on a reduced number of digital transmission channels.
2.2 Speech interpolation; digital speech interpolation (DSI)
A method of profiting from the time instants when a speaker is not
active, which is indicated by a speech detector. The channel is then used by
another speaker. The signals carried by a transmission channel therefore represent
interleaved bursts of speech signals derived from a number of different trunks.
2.3 Low rate encoding (LRE)
Speech coding methods with bit rates less than 64 kbit/s, e.g. the
32 kbit/s transcoding process defined in G.721 applied to speech coded according to
G.711.
2.4 Speech activity
The ratio of the time speech and corresponding hangover occupies the
trunk to the total measuring time, averaged over the total number of trunks
carrying speech.
2.5 CME gain
The trunk channel to transmission channel multiplication ratio, which
is achieved through application of CME, including LRE and/or speech
interpolation (DSI).
- 3 -
COM XI-R 74-E
FIGURE 1/Q.50
CME gain
Note - For a complete discription of bearer channels, see
Recommendation G.dcme.
2.6 Trunk
A bidirectional connection consisting of a forward channel and a
backward channel between the ISC and CME not subject to LRE or DSI operation.
2.7 Transmission channel - bearer channel
One channel of the connection between the transmit unit and receive
unit of corresponding CME.
2.8 Freeze-out
The condition when a trunk channel becomes active and cannot
immediately be assigned to a transmission channel, due to lack of available transmission
capacity.
2.9 Freeze-out fraction
The ratio of the sum of the individual channel freeze-outs to the sum
of the active signals and their corresponding hangover times and front end
delays, for all trunk channels over a fixed interval of time, e.g. one minute.
2.10 Transmission overload
The condition when the freeze-out fraction or average bits per sample
goes beyond the value set in accordance with speech quality requirements.
2.11 Operating modes
2.11.1 Point-to-point mode (see Figures 2a/Q.50 and 2b/Q.50)
Point-to-point - Using Figure 2a/Q.50 for reference, the transmit side
CME concentrates N trunks into N/G transmission channels, where G is the CME
gain.
- 4 -
COM XI-R 74-E
At the receive side, the receiving CME simply reconstitutes the
N trunks from the N/G transmission channels.
FIGURE 2a/Q.50
Point-to-point unidirectional
FIGURE 2b/Q.50
Point-to-point two origins unidirectional
FIGURE 2/Q.50
Multi-clique for two origins and two destinations unidirectional
The example in Figure 2b/Q.50 also shows a point-to-point mode. From
the switching point of view there could be a difference between the
configurations in Figures 2a/Q.50 and 2b/Q.50.
For transmission of alarms it has also to be considered, that different
exchanges may be connected to one CME.
2.11.2 Multi-clique mode (see Figure 3/Q.50)
Multi-clique mode - in this mode the pool of transmission channels is
sub-divided into several independent pools (cliques) or fixed capactiy, each
being for an individual destination. If a part of the cliques capacity is not
used, it cannot be used for another destination.
- 5 -
COM XI-R 74-E
FIGURE 3/Q.50
Multi-clique mode (only one direction shown)
2.11.3 Multi-destination mode
A DCME operational mode where input trunk channel traffic is
interpolated over a pool of available transmission channels for all destinations having
traffic in the pool. The transmit trunk channels are designated to receive trunk
channels at corresponding locations.
Figure 4/Q.50 shows a unidirectional system block diagram for a multi-
destination mode with two transmit and two receive DCME units.
- 6 -
COM XI-R 74-E
FIGURE 4/Q.50
Multi-destination mode (only one direction shown)
3. Requirements for control
3.1 Reasons for use of circuit multiplication equipments (CME)
Circuit multiplication equipments are used in order to reduce the
3.2 Integration of CMEs into the telephone network
Normally, when an exchange needs an outgoing circuit, the only question
is whether or not a circuit is available. In this example, the call may be
blocked if all of the circuits are unavailable through traffic or maintenance. If
the same call encounters a CME, the possible outcomes are more complex.
- 7 -
COM XI-R 74-E
(and for 3.1 kHz audio, if appropriate) through DSI systems
(i.e., not through internal pre-assignment), the
establishment and disestablishment of connections between
the CMEs have to be initiated from the outgoing
exchange.
3.3 Factors for signalling functions determination
The functional requirements for signalling between CMEs and exchanges
are determined by the type of CME with its capabilities and limitations, and
by the types of bearer services it supports.
The remote control of echo control devices and A/u-law converters, if
they are integrated into the CME, is accomplished either by the terminal or test
equipment or directly from the ISC (based on call set up information/signalling
information).
Requirements and actions for control of ECD are described in CCITT
Recommendation Q.115.
- 8 -
COM XI-R 74-E
3.3.1 Circuit multiplication equipment and physical location
There are different types of CME which are being used or will most
likely be used in the international telephone network, each with its own
capabilities and limitations:
a) 32 kbit/s low rate encoding (LRE);
b) analogue speech interpolation equipment;
c) digital speech interpolation (DSI) with 64 kbit/s PCM;
d) combined 32 kbit/s LRE and DSI
e) 16 kbit/s LRE.
The location of certain types of CME relative to the exchange
determines the choice of signalling interface. These CMEs can be
located at the ISC or remote from the ISC (e.g., at an earth station).
Certain types of signalling interfaces may be more practical when these CMEs
are co-located with the ISC, and others may be more practical when they
are remote from the ISC. Therefore, the location of the CME needs to be
considered when choosing the signalling between ISC and CME.
When the CME is remote from the ISC, the link between the ISC and CME
could be composed of digital or analogue transmission path. Both conditions
have different equipment configurations and different signalling requirements
(see section 7).
3.3.2 Bearer services supported on CME links
Up to four basic bearer service types are supported or will likely be
supported by CMEs in the international network:
- speech bearer service (full duplex, analogue or digital);
- 3.1 kHz audio bearer service (full duplex);
- 64 kbit/s unrestricted bearer service (full duplex);
- alternate speech/64 kbit/s unrestricted bearer service (full
duplex);
- 9 -
COM XI-R 74-E
TABLE 1/Q.50
Bearer services supported in CMEs in relation to CME-exchange signalling
4. Bearer services and CME techniques in the context of signalling
Table 1/Q.50 gives the relationship between CME techniques and the four
bearer services identified in 3.3.2 with regard to their supportability and
the need for CME-exchange message transfer.
The signalling function requirements are categorized on the basis of
bearer services supported by the different CME techniques. For speech bearer
services, only transmission resource management (TRM) information alone is adequate
especially for CMEs employing speech interpolation. The objective of this provision is
to maintain the reduction of transmission quality within tolerable limits. In
addition to TRM information, external call set-up message (CSM) exchange is needed
for bearer services involving on-demand 64 kbit/s unrestricted service in
contemporary digital circuit multiplication equipment (32 kbit/s LRE and DSI).
- 10 -
COM XI-R 74-E
5. Division of functionality between the exchange and the CME
5.1 CME dynamic load control process
TRM information is based on traffic load measurements at the local and
distant CMEs. Therefore in the multi-destination and multi-clique mode of
operation, TRM information is provided for each destination/clique separately.
A universal arrangement is proposed for handling transmission resource
management (TRM) information between CME and an exchange. The TRM information is
dynamically presented to the exchange in one of two states for each bearer service.
The states are called "available" and "not available". Logic within the CME is
used to determine which of the two states should be indicated to the exchange
regardless of any condition at the exchange.
When a CME encounters a "not available" state for a bearer service
(either locally or remotely), it presents this indication to the exchange so it will
stop routing new calls to the CME for that bearer service even if there are free,
unseized circuits available. The exchange will continue to prohibit calls to the
CME until it receives an "available" indication for the bearer service which will
be sent by the CME when both, locally and remotely, there is no overload.
This DLC information is therefore directly influencing the circuit
selection process in the exchange during call set-up for each bearer service
separately.
The circuit selection in the exchange is a check whether or not a free
unseized circuit is suitable for a certain bearer service type, for which a new
call is to be accommodated. For example, the exchange would select a free circuit
for a speech call if "speech capacity available" is indicated, irrespective of the
indications for other bearer service types. If the DCME link is unable to
accommodate additional new 64 kbit/s calls, all free unseized circuits within the
exchange will be marked accordingly. Even though the generation of bearer service
related TRM information with DCMEs may be in part mutually dependent (i.e., no
capacity for speech implies no capacity for any other bearer service types but not
necessarily vice-versa), separate signalling and processing for each bearer service
type are necessary to allow different future CMEs to develop independently.
5.2 Call set-up process
According to Table 1/Q.50, the contemporary digital circuit
multiplication equipment, having the capability to support on-demand all four identified
bearer services, in addition to providing TRM to the exchange, requires call set-up
messages (CSM) (from the exchange) for selecting bearer services.
For the 64 kbit/s unrestricted bearer service, a circuit is selected if
"unrestricted capacity available" is indicated, and a CSM in the form of
Seizure/Select request is forwarded to the DCME. An acknowledgement (positive or negative)
is set as soon as possible even if capacity is available, to account for possible
call set-up rejects other than due to capacity limitations on the DCME link.
- 11 -
COM XI-R 74-E
The positive acknowledgement will be used by the ISC to initiate the
interexchange signalling to the next ISC (e.g. transmission of the IAM of Signalling
System No. 7). A failure to establish a 64 kbit/s circuit between CMEs must be
reported to the DSG as soon as the condition has been identified by the CME to the
ISG by using an out-of-service message.
The out-of-service message is considered by the ISC to be equivalent to
the alarm signal defined in Recommendation Q.33. The ISC will take release actions
(if appropriate) as specified in Recommendation Q.33, 4.
The released 64 kbit/s message from the ISC will be positively
acknowledged after proper completion of the DCME circuit disestablishment process. Failure
to complete this process shall be notified to the ISC using an out-of-service
message and the DCME will put the circuit in a blocked condition. After the failure
condition is removed, this circuit will be in idle condition and a back-in-service message shall be sent to the ISC.
Under a 64 kbit/s unrestricted dual seizure situation, the non-
controlling ISC will initiate a release of the DCME connection using procedures defined in
the appropriate inter ISC signalling system protocol. If the DCME is unable to re-establish a remotely released 64 kbit/s duplex connection, it shall indicate
this abnormal situation to the appropriate ISC by out-of- service.
The information elements and procedures necessary to support the
alternate 64 kbit/s speech bearer services are for further study.
FIGURE 5/Q.50
Typical ISC/CME information flows
- 12 -
COM XI-R 74-E
5.3 Inter-dependency between dynamic load control and call set-up process
To allow a standard method of interworking with inter-exchange signalling
systems it is important to adopt the functional interdependency between TRM and
CSM as described above.
6. Control information elements between exchange and CME
The amount of control information elements utilized between the exchange
and the CME depends on the capabilities of the CME and the exchange. Two
categories of CME signalling capabilities are recognized. The first category of CME (Type
1) is capable of only transmitting signals from the CME to the exchange (e.g. DLC
see Table 3/Q.50). The second category of CME (Type 2) is able to transmit and
receive signals to/from the exchange. Tables 2/Q.50, 3/Q.50 and 4/Q.50 give a set
of information elements and their flow on the control link between the exchange
and the CME for the second category of CME.
6.1 Information elements for Type 1 CME
Type 1 CME only should use the following information elements