SE508566C2 - Short and long-term connection control in telecommunication system - Google Patents

Abstract

User terminals (4, 5) are connected to a telecommunication system, with a control system (3) operating to set up, release and/or modify connections between the terminals. Many operating functions are common to both short-term, flexibly dynamic connections and long-term, semi-permanent connections. Connection control may be initiated from any user terminal. Controlling data may be stored in different types of storage resources in the system, e.g. volatile memories (20, 21) or a permanent, persistent memory (24). Different types of resource carry different degs. of reliability.

Description

508 566 maximum data rate can be obtained at any time.

US 4,821,256 describes a method for monitoring information transmission in semi-permanently connected 4-wire connections in digital time division multiplexed exchanges. The monitoring takes place by comparing bitstreams and parity tests.

US 5,046,183 describes an arrangement such that in a call to be debited to the recipient or a third party, or a call specifically addressed to a person, a telephone operator need only be involved when the call is already connected, the call type being the operator to assist the same.

A telecommunication system according to an initially defined type provides telecommunication services in which different types of connections between user terminals can be controlled, for example connected, disconnected and changed.

In the case of a first type of connection, said control can be initiated from a user terminal, for example telephone or computer. A user can initiate the control himself without the intervention of an operator.

The number of connections of this type usually varies greatly over time, as does the duration of the connections, which duration is often short, for example a few minutes or hours.

The connections thus show a great mobility. Hereinafter, these connections are therefore referred to as dynamic connections. An advantage of dynamic connections is the speed and simplicity with which they can be controlled.

In a second type of connection, said control is initiated from an operating support terminal, belonging to an operating support system, by an operator. Connections to this other type of telecommunications service often have a long duration, eg several months. They are more static in nature than dynamic connections. Hereinafter, these connections are called semipermanent connections. An advantage of semi-permanent connections is that they have a lower risk of interference, such as unwanted disconnections, than She 566 ~ dynamic connections. The ability not to interfere with connections is called robustness.

The higher robustness of semipermanent connections compared to dynamic connections is achieved by storing control data related to semipermanent connections more reliably than control data related to dynamic connections.

The said more reliable storage of çtyr data is called non-volatile storage.

The telecommunication system can comprise several selector nodes connected in a network. The robustness is low in a dynamic connection which, for example, passes through many such selector nodes. Increased robustness of dynamic connections is achieved in the prior art at a considerable additional cost, for example through more reliable hardware such as processors and selectors. The higher cost is a problem.

Description of the invention The invention aims to eliminate the above problems which exist in a telecommunication system. User terminals can be connected to the telecommunication system. The telecommunication system comprises a control system for controlling, such as connection, disconnection and change, of connections between the mentioned user terminals. The control system includes both control resources and storage resources. The storage resources store control data related to connections in the telecommunication system.

More particularly, the invention intends to combine in a simple manner the advantages of dynamic connections with the advantages of semi-permanent connections, so that: (a) the robustness of connections can be controlled and (b) the robustness of dynamic connections can be chosen as for semi-permanent connections, ie. the robustness becomes dimensionable.

These objects are achieved by giving the invention the features set forth in claims 508,566.

The invention allows a connection, regardless of the type of connection to which said connection relates, simultaneously acquires several of the good properties which in the prior art are either associated with dynamic connections, or with semi-permanent connections. Control of a robust connection can be initiated from a user terminal, without a traditional operating support system. This is done by users themselves, or by an operator. The need for a special operational support terminal or an operational support system for handling semi-permanent connections is eliminated.

Semi-permanent connections are controlled in essentially the same way as dynamic connections. In contrast to dynamic connections, however, control data related to the semi-permanent connections is stored non-volatile, in order to obtain a robustness of semi-permanent connections that is higher than that of dynamic connections. Functions for controlling dynamic connections are largely reused for controlling semi-permanent connections. The robustness of a connection is changeable. Changing the robustness of a connection is either initiated directly from a user terminal, or initiated by the control system based on user behaviors. In the latter case, the control system stores the connection-related control data in the various storage forms so that a certain robustness average value is achieved. Sufficient robustness is thus obtained without unnecessary uptake of scarce resources, whereby either the cost can be reduced or the capacity of the control system can be increased.

Brief description The invention will now be described in more detail with reference to the drawings, in which Fig. 1 schematically shows a telecommunication system to which the invention is applied, Fig. Fig. Fig. Fig. Fig. Fig. Fig. 508 566 H schematically shows a telecommunication system and associated operating support system, wherein the telecommunication system comprises several nodes, schematically shows a control system belonging to the telecommunication system in Fig. 1 or 2, comprising control functions and storage resources, schematically shows a method according to the invention, where the method is applied in the control system according to Fig. 3, process according to the invention for connecting a semi-permanent connection from a user terminal, shows a process according to the invention for user-initiated change of the robustness of a connection, shows a process according to the invention for changing the robustness of a connection after a certain calculated time, shows a process for changing the robustness of a connection in case of lack of resources, simplified shows a flow chart of the handling of a connection.

Description of the embodiments of the invention An embodiment of the invention is applied in the control system of a telecommunication system 1. The telecommunication system is shown schematically in Fig. 1. It comprises a selector 2, eg a digital circuit-switching timer, and a control system 3. The telecommunication system has user terminals, e.g. 4.5. computers 6 or external cables 7, so-called trunks, connected.

The telecommunication system to which the invention can be applied may in a known manner comprise a network with several interconnecting nodes 8, as shown in Fig. 2. Fig. 2 also shows an operating support system 9.

Connections between the user terminals 4,5 are controlled, as connected, disconnected or changed, by the control system by operating the selector 2 in Fig. 1 or the selectors 2 in Fig. 2. 508 566 In Fig. 3 the control system is shown in more detail. The control system includes control functions 10.1-10.6 and storage resources. The storage resources consist of primary memories of a first type 11 and of a second type 12, and of a secondary memory 13. The control functions can directly or indirectly use the different types of storage resources.

A significant proportion of the control functions in the control system for controlling connections are directly or indirectly common for controlling all types of connections. These types of connections include those that are traditionally called dynamic connections, and those that are traditionally called semi-permanent connections. A telephone 14 and a computer 15 represent the different types of connection, the telephone a dynamic connection and the computer a semi-permanent connection.

The arrows indicate the interaction between the user terminals 14.1E. control functions 10.1-10.6 and storage resources 11-13. As an example, both user terminals cooperate directly with common control functions 10.2,10 3, and partly indirectly with 2 »other control functions 10.4-10.6 and storage resources 11-13.

Control, such as connection, disconnection and modification, of fo: connections of the semi-permanent connection type can initiate: U users by using the common control functions. To this end, the common control functions must allow law:;: of connection-related control data in storage resources which give: the connections the right properties. This will be shown below.

The primary memory 11 of the first type has a comparatively low reliability, while the primary memory 12 of the second type has a higher reliability, due to the fact that it has per se known hardware support for write protection. The secondary memory 13, which consists of a disk memory, has the highest reliability.

Compounds of the semi-permanent type must generally have high robustness. Consequently, the control data for such can be stored in šbe 566 ~ primary memory of the second type, and / or in the secondary memory, whereby this desired property is obtained.

Primary memory of the said second type, and secondary memory are only available through the function 10.6, depending on the above-mentioned hardware support. Because the said memories are only accessible through the function 10.6, the reliability of these storage resources increases. This is one of many possible, per se known, ways that contribute to storage resources with high reliability.

The invention is further described for the sake of simplicity in a system with only two types of data storage resources. These are called volatile and non-volatile, respectively. It is obvious to the person skilled in the art that more than these two types of data storage resources can exist, the types mutually showing different degrees of reliability.

The control system also includes control resources, which the control functions can use. The control resources consist of processing capacity in a processor (not shown). After non-volatile storage of connection-related data for a connection, control resources can be released. Thus, these can be used for another connection. Volatile data storage resources can also be released, and used for another connection.

According to an important feature of the invention, control data for connections of all types can be moved between the volatile and non-volatile data storage resources. Thus, control data can be moved from volatile to non-volatile data storage resources, and from non-volatile to volatile data storage resources. In this way, a needs adjustment can take place of the properties of connections, and the utilization of resources in the control system can be optimized at these properties.

The optimization consists of only consuming resources that are necessary for sufficiently good properties to be achieved. 508 566 I '..

If control data is not stored in non-volatile memory, in the described embodiment, the volatile data storage resources are limiting for how many simultaneous connections can be handled by the telecommunication system. In addition, the control resources are limiting for the extent to which control data can be moved between volatile and non-volatile data storage resources.

Namely, the transfer of control data takes up processing capacity. Control data relating to connections which show high mobility should thus not be unconditionally stored in non-volatile memory, as this would involve extensive transfer of control data between the volatile and the non-volatile data storage resources.

With reference to Figs. 4 and 5, a first process according to the invention will now be described. Characteristic of the process is that a connection is initiated from a user terminal, that control data for the connection is stored in non-volatile memory, and that the connection thereby obtains high robustness.

A user terminal 4 initiates a connection to a user terminal 5 of a connection which is to have the same robustness which is characteristic of a traditional semi-permanent connection. When ordering connection, dynamic processes 16,17 are created. The processes constitute a representation of a control function.

In the processes, connection control data is manipulated through procedures 18,19 which are implemented in program logic. The connection control data belonging to each process is stored in separate volatile memory 20 resp. 21. Through the processes, the connection, box 22 in Fig. 4, is taken care of by the connection in a manner known per se, after which the connection-related control data is copied over, box 23, from the volatile memories 20,21 to the non-volatile memory 24. There after, volatile storage resources, box 25, are released by stopping the dynamic processes 16,17. A second process will now be described with reference to Fig. 6.

Characteristic of this process is that a connection is first connected between two user terminals, and that the connection's robustness is subsequently changed on the initiative of one of the user terminals. A connection with a robustness lower than the highest is connected from a user terminal, box 26. From one of the user terminals 4,5, a change in the properties of the connection is then requested. More specifically, it is desired that the robustness of the connection be increased.

Orders are awaited from a user terminal, box 27. The connection-related control data is copied over from volatile memories to non-volatile memories, box 28. Thereafter, control resources and volatile storage resources, box 29, are released by ceasing dynamic processes.

A third process will now be described with reference to Fig. 7. The requirement for robustness sometimes means that a statistical mean value for the probability of interference for several connections must not exceed a predetermined value. One way, according to the invention, of meeting said requirements is to store connection-related control data for the connection in volatile memory during certain phases during control of a connection, such as during connection phase, and to store it during other phases, such as during data phase. bond-related control data in non-volatile memory. After a certain time, eg 15 min. in the data phase, which time is calculated so that sufficiently high robustness is to be obtained, the connection-related control data is stored in non-volatile memory. When stored in non-volatile memory, the connection is likely to be quite static in nature, and thus extensive processing capacity will not be used for the connection.

The said time is either calculated in advance during system configuration, or is calculated during operation.

It is characteristic that a connection is connected, box 30, that the said calculated time is awaited, box 31, that subsequent storage in non-volatile memory of connection-related data, box 508 566 10 32, takes place, and that resources are thereby released, box 33.

A fourth process will now be described with reference to Fig. 8. When the amount of scarce resources used for connections exceeds a predetermined size, a function in the control system selects which control data of the connections is to be stored in another type of storage resource. After storing the connection-related control data, control resources and storage resources are released in the manner specified above. The said function selects the connections according to various criteria, including the duration of a connection and the type of connection. If, for example, a connection has lasted more than 10 minutes, it is likely that it will last longer than a good time, and therefore it is appropriate that its connection-related control data is stored in another type of storage resources so that resources can be released for connection connections. In this case, connections are thus selected taking into account user behavior.

In order to maintain a fixed minimum robustness of dynamic connections passing through many selector nodes, control data for these connections is stored non-volatile.

A flow chart is shown in Fig. 9. The flow chart shows simplified handling of a connection in accordance with the invention. The control system is receptive to signals from the user terminals.

A "hang up" signal indicates that a user terminal is initiating a connection. Another "connection type" signal notifies the control system whether the connection is to be semi-permanent or dynamic. Another "hang up" signal indicates that the connection should end.

Functions which are previously known per se measure the availability of resources in the control system, free up processing capacity in a processor, free up data storage resources, perform time measurement, count nodes through which the connection runs, store connection-related control data non-volatile and move connection-related control data from non-volatile storage to šos see ll volatile storage. These functions are therefore not described in more detail.

The flow chart will now be described in more detail.

At selection box 38, the signal "hang up" is expected. If the resource availability is high, box 39, the connection is dynamic, box 40, and the connection runs through only one node, box 41, then "the control data for the connection is stored in volatile memories, box 42. If, on the other hand, the resource availability is low, option" low "at selection box 39, the connection is semi-permanent, selection box 40, or the connection runs through several nodes, selection box 41, then the control data for the connection is stored non-volatile, whereby processing capacity of the processor, ie control resources, and volatile memories are released, box 43. If a dynamic connection lasts a certain predetermined time, selection box 44, eg 10 min, the control data for the connection is stored non-volatile, whereby the processing capacity of the processor and volatile memories are released, box 43.

If the "handset" signal is detected, box 45, then processing capacity and volatile memories, box 50, are released, after which the signal "handset off" is awaited again, box 38. After non-volatile data storage, box 43, "handset" is selected, box 46. If the availability of resources is low, alternative "low" at box 47, then resources, box 4É, belonging to other connections are released after receiving the "hang up" signal, box 46. In this case, control data is stored non-volatile for these connections. then resources are selected according to duration, then resources are used again which are released at box 48, and the control data is stored fleetingly, box 49. At box 50 resources are released after which the signal "hang on" is again waited, box 38.

It will be apparent to one skilled in the art that the telecommunication system to which the invention is applied may in a known manner comprise a control system which is physically distributed over several nodes (distributed control system), for example the nodes shown in Fig. 2.

Claims (9)

508 566 l2 Patent claims A method for increasing the robustness of a dynamic connection in a telecommunication system (1), to which user terminals (4-6, 14-15) are connectable, which telecommunication system comprises a control system (3) comprising program-controlled functions for control, such as connection, disconnection and change, of the connection, characterized in that the robustness of the connection is first selected low, and after a certain time is increased by first storing the control data for the connection in a first type of storage resource (11; 20, 21) with low supply reliability, to be later moved to a second type of storage resource (12, 13; 24) with higher reliability. Method according to Claim 1, characterized in that the robustness of the connection is changed on the initiative of one of the user terminals or on the initiative of the control system. Method according to claim 1 or 2, characterized in that the robustness of a dynamic connection is selected by storing control data for this in a type of storage resources which provides the desired robustness. Method according to claim 3, characterized in that the robustness of a connection is changed by moving the control data for the connection between the first and second types of storage resources. Method according to claim 1, characterized in that the first type of storage resource (11) consists of RAM memory, that the second type of storage resource consists of RAM memory (12) with hardware support for write protection or of disk memory (13). Device for increasing the robustness of a dynamic connection in a telecommunication system (1) comprising user terminals (4,5; 14), a control system (3) with functions for controlling connections between the user terminals and functions for storing control data , 508 566 13 and storage resources (11, 12, 13; 20, 21,24) comprising at least one volatile memory (11; 20, 21) and at least one non-volatile memory (12, 13; 24), characterized by a mechanism (18, 19) which is sensitive to instructions generated at the user terminals (4, 5, 6) or at a terminal (15) of a telecommunication system operating operator for moving control data regarding a certain connection from the volatile memory (11; 20, 21 ) to the non-volatile memory (12, 13; 24). Method for assigning dynamic connections in a telecommunication system different degrees of robustness, characterized in that control data for said connections are stored in different types of storage resources (20, 21 and 24, respectively) in a control system to the telecommunication system, which different types have different degree of reliability. Method according to claim 7, characterized in that the robustness of a dynamic connection is selected by storing connection data for connection: in a type of storage resources which gives the desired robustness Method according to claim 7 or 8, characterized in that the robustness of a connection is changed by moving the control data for the connection between said different types of storage resources (20, 21 and 24, respectively).