Patent Document

FIELD OF THE INVENTION 
     The invention generally relates to call control processing in a communications network and more specifically to a method and apparatus for implementing subscriber permissions and restrictions for switched connections in a digital communications network. 
     BACKGROUND OF INVENTION 
     Differing communication systems employ various methods for partitioning bandwidth amongst calls routed through a network. In asynchronous transfer mode (ATM) networks, for instance, when a switched connection such as a switched virtual circuit (SVC) is established the call set-up message carries a number of information elements (IEs) which specify various traffic and quality of service (QoS) parameters. This information is processed by call control software resident on each network node which determines the type or service category of the requested connection as well as the bandwidth required by the connection. The connection admission control (CAC) function of the node is then executed in order to determine whether the node has sufficient internal resources such as bandwidth and buffer space to support the requested call. If so, the node reserves internal bandwidth and buffer space for that connection and the call set-up message is progressed to the next node along the path of the switched connection. 
     Once the switched connection has been established, the ingress node (of the network) typically applies a usage parameter control (UPC) function to the connection in order to monitor and police it. More specifically, if the source or customer premise equipment (CPE) misbehaves by transmitting data packets at a rate or with a variability outside of the parameters that the connection was initially set up for, the network may then drop such data packets since they do not conform to the “traffic contract” which was established during call set up. 
     While the foregoing methodology is effective in policing misbehaving sources once the connection is established. it does not prevent a subscriber from requesting and establishing a switched connection which may require network resources greater than that which has been pre-agreed to via a business or legal arrangement between a subscriber and a network service provider. In other words, no mechanism exists for preventing a subscriber from establishing a switched connection in the first instance using a quantum of network resources beyond that which the subscriber has agreed to pay for. 
     There are many reasons why subscribers may request service outside of the parameters of a service agreement, including human error in equipment configuration, and wilful intent to defraud. Such erroneous connections, even ones innocently requesting inordinate amounts of bandwidth, are likely to be accepted by the network given the lack of a subscriber enforcement mechanism and the fact that network policies typically permit capacity to be overbooked, often by a 2:1 or 3:1 ratio. Nevertheless, despite such policies, these erroneously configured connections can have a deleterious effect, even if the subscriber equipment is not transmitting data beyond that provided for in the service agreement. This is because high bandwidth connections require large blocks of bandwidth to be reserved for the duration of the connection, independent of how the subscriber uses the available bandwidth. This may result in lost opportunity costs since new traffic may have to be refused if too many erroneous, bandwidth-excessive, connections are provisioned by the network. 
     SUMMARY OF THE INVENTION 
     The invention enables networking service providers to optionally place limitations on the switched connection requests that subscribers may place on a network. This is accomplished by enabling node administrators to configure, on a per subscriber basis, the throughput limits for all incoming and outgoing switched connections a subscriber may attempt to establish or receive. 
     One aspect of the invention relates to a method for establishing connections in a switched connection network. The method includes (a) provisioning throughput limitations in respect of network subscribers; (b) requesting the establishment of a switched connection call; (c) filtering the call based on the subscriber throughput limitations; and (d) establishing or refusing to establish the switched connection based on the outcome of the filtering step. 
     Another aspect of the invention relates to a method of establishing connections in a switched connection communications network. The method includes: (a) provisioning a throughput limitation database in respect of one or more subscribers to the network; (b) signaling a call set-up message in order to establish a switched connection associated with a given subscriber; (c) receiving the call set-up message at an edge network node associated with customer premise equipment of the given subscriber and comparing at least one throughput request provided by the call set-up message against at least one corresponding throughput limitation stored in the database with respect to the given subscriber; and (d) progressing the call set-up message or refusing to establish the switched connection based on the outcome of the comparison. 
     In the embodiments described herein, the throughput limitation database is stored on an edge network node which carries out the limit checking on a per subscriber basis. 
    
    
     BRIEF DESCRIPTION OF DRAWINGS 
     The foregoing and other aspects of the invention will become more apparent from the following description of an embodiment thereof and the accompanying drawings which illustrate, by way of example, the embodiment. In the drawings: 
     FIG. 1 is a schematic diagram of a reference network; 
     FIGS. 2A-2C are schematic diagrams showing the architecture of an edge network node and the processing functions carried out by it; and 
     FIGS. 3 and 4 are diagrams of input screens for enabling node administrators to configure various throughput limitations. 
    
    
     DETAILED DESCRIPTION OF PREFERRED EMBODIMENTS 
     FIG. 1 shows a reference switched connection network  10  which includes edge network nodes  12  and  14 . (For simplicity, and since the particular configuration of the network is not material to this description, the remaining network nodes are not shown.) The edge network nodes  12  and  14  are connected via conventional interface lines (not shown) to customer premise equipment (CPE)  16  and  18 . 
     Generally speaking, calls in switched connection network  10  are dynamically established and cleared in substantially real time by the network in accordance with standard signalling protocols. In order to initiate an end-to-end call, a call originating device such as CPE  16  or  18  signals a “call set-up” message over a user-to-network interface (UNI) to an ingress node of network  10  indicating the destination address and desired, foe example, bandwidth and quality of service parameters. The ingress node decides whether or not to accept the call based on its internal resource availability. If the ingress node has sufficient resources it propagates the call set-up message to the next network node towards the destination address via known signalling and routing means. The call set-up message is thus steered through the network, and each node which receives the call set-up message establishes a bearer channel cross-connect (not shown). Ultimately, the call set-up message is relayed by the network to the terminating device at the destination address, and the terminating device is thus informed as to the identity of the bearer channel upon which data will be received or may be transmitted. Once the call set-up message is received at the terminating device, a “connect” message is signalled back to the call originating device. At this point (depending upon the particular signalling protocol employed) the call is deemed to have been established and the call originating device, as well as the terminating device in the event of a bidirectional connection, may transmit user data over the recently established bearer channel path. 
     For the purpose of this description, CPE  16  is associated with a first party (hereinafter “subscriber”) who has entered into a service agreement or other business or legal arrangement with the provider of network services and CPE  18  is associated with a second party who may or may not privy to the same agreement as the first party. 
     CPE  16  may originate or receive calls to or from CPE  18 , as shown by arrows  20  and  22 . For switched calls, such as a switched virtual circuit (SVC), the path any given call assumes through the network is variable, depending on a variety of factors such as trunk availability, etc. However, every call and call set-up message originating from or destined for CPE  16  will pass through the associated edge node  12  since CPE  16  is physically connected thereto. Thus, when a call originates from CPE  16 , the edge node  12  functions as a network ingress node; and when a call is destined for or terminates at CPE  16  the associated edge node  12  functions as a network egress node. 
     The service agreement between the network service provider and the subscriber at CPE  16  typically includes a number of throughput limitations, such as the maximum permissible bandwidth the subscriber may access per connection. Referring additionally to FIGS. 2A-2C, the throughput limitations for CPE  16  connected to edge node  12  are contained in a database  38  provisioned by the service provider. The database is preferably indexed by subscriber address, code or key in order to enable quick lookup of pertinent information on a per subscriber basis. Such a database may be configured via a node terminal interface or other known manner of configuring a network node. Other potential throughput limitations are discussed below with reference to ATM standards, but for the moment it should be appreciated that the subscriber may be subject to at least one throughput limitation, such as maximum permissible bandwidth. 
     As noted above, the call set-up message will pass through the edge network node  12  irrespective of whether subscriber CPE  16  originates or terminates a call. For purposes of description, however, CPE  16  is randomly selected to be the calling or originating party and CPE  18  the called or destination party. The processing which occurs at edge (or ingress) network node  12  in these circumstances is discussed with reference to FIGS. 2A-2C wherein node  12  is illustrated as a model 36170™ ATM switch or node commercially available from Newbridge Networks Corporation of Kanata, Ontario, Canada. As shown, node  12  includes line cards  28  which feature physical interface ports  30  for transmitting and receiving data packets to and from the network or customer premise equipment. The line cards  28  are connected to a switching fabric  40  which provides a means for transferring or copying packets between the line cards  28  and other cards or boards in the switch. 
     As shown in FIG. 2A, CPE  16  signals a call set-up message, schematically designated by arrow  32  which consists of a number of packets associated with a signalling VC  34   a  in accordance with a signalling plane of the communication protocol. The line cards  28  provide an interface function for forwarding the packets of the call set-up message  32  to an SVC service card  36 . The SVC service card  36  terminates the signalling link between the node and CPE  16  and provides a call control function  37  for processing the call set-up message  32 . More specifically, call control function  37  interprets traffic and quality of service parameters included in the call set-up message  32  and determines throughput demands, such as bandwidth, requested of the network by CPE  16 . The call control function  37  then filters the call by consulting the subscriber throughput limitation database  38  in order to determine whether the throughput requests can be accommodated as per the service agreement between the subscriber at CPE  16  and the service provider. 
     If the throughput requests have not exceeded the corresponding throughput limitations, the edge node  12  then invokes a connection admission control (CAC) function  42  of control card  44  to determine whether the node or network has sufficient internal resources to support and establish the requested connection. If so, then as shown in FIG. 2B the edge node  12  establishes a bearer channel cross-connect  46  (schematically shown) between the input and output ports and progresses the call set-up message  32  over signalling VC  34   b  as per the communication protocol employed to the next node in the path of the call. (In the event the CPE  16  terminates the call the set-up message would be progressed to CPE  16  over the UNI therebetween.) However, if any of the throughput demands requested of the network exceed the corresponding threshold limitations, then the edge node  12  does not establish a bearer channel cross-connect or progress the call set-up message forward. Instead, depending on the particular signalling protocol employed, the edge node  12  as shown in FIG. 2C transmits a call release message  46  with a suitable failure code back to CPE  16  (or CPE  18  if it originated the call), or alternatively some other type or format of signalling message specifying failed call establishment. The same actions occur if the approval from the CAC function  42  is negative. 
     Note also that the edge node may invoke the CAC processing prior to filtering the call on a per subscriber basis. This is, however, less efficient than the order described above and hence less preferred. 
     In the alternative, the call set-up message  32  may be deficient in specifying some necessary parameters required to establish a connection. For instance, when frame relay service is provided over an ATM platform, the call set-up message of a frame relay SVC connection request may not specify the committed burst size for the connection. In this case, in addition to any committed burst size throughput limitation, the preferred embodiment provides a default committed burst size value per subscriber, and database  38  may be configured accordingly. In this manner, the connection may established based on unique default traffic parameters provided on a per subscriber basis. 
     The throughput limitations and default parameters provided by one embodiment of the invention is discussed next. In what follows, reference is made to an asynchronous transfer mode (ATM) network and to native ATM services, as well as frame relay (FR) services offered from an ATM platform, and the reader is referred to “ATM User-Network Interface (UNI) Signalling Specification, Version 4.0”, doc. no. af-sig-0061.000, ATM Forum Technical Committee, July, 1996; “Network to Network FR/ATM Service Interworking Implementation Agreement”, Frame Relay Forum doc. no. frftc.106r1, Jan. 13, 1997, all of which is incorporated herein, for further particulars of these standards. 
     FIG. 3 shows an input screen  50  employed in a node terminal interface program for configuring throughput limitations for a subscriber. The node administrator may enter throughput limitations for ATM service and/or frame relay service carried over an ATM platform. FIG. 4 shows an input screen  52  wherein the node administrator is able to configure which ATM service categories a subscriber may request when placing an outgoing call. The throughput limitations and related functionality are summarised below. In what follows the term “incoming call” means a call which originates from customer premise equipment directly connected to the node and the term outgoing call means a call which terminates at the customer premise equipment directly connected to the node. 
     Throughput Limitations 
     1. SVC Throughput Limit Provisioning for Frame Relay Over ATM 
     The throughput limit provisioning for FR over ATM is provided on a per subscriber basis. For the maximum allowed, parameters that follow, the maximum valid value is independent of the access rate of the physical interface that the subscriber is assigned to. 
     Maximum Allowed Committed Information Rate (Max CIR) 
     This selection allows the node administrator to assign the maximum committed information rate for frame relay SVCs. 
     Valid Values: From 0 to 2**30−1Kbps; and ‘no limit’. 
     Default Value: ‘no limit’ 
     Conditions: If the limits for incoming or outgoing calls is enabled, then any incoming or outgoing call requesting an incoming or an outgoing committed information rate in excess of the configured maximum allowed value will be rejected with a cause code value of #49, which represents ‘Quality of Service not available’. If ‘no limit’ is configured then no limit checking is done. 
     Maximum Allowed Excess Burst Size (Max Be) 
     This selection allows the node administrator to assign the maximum allowed excess burst size for frame relay SVCs. 
     Valid Values: From 0 to 2**30−1Kbits; and ‘no limit’. 
     Default Value: ‘no limit’ 
     Conditions: If the limits for incoming or outgoing calls is enabled, then any incoming or outgoing call requesting an incoming or an outgoing excess burst size greater than the configured maximum allowed value will be rejected with a cause code value of #49, which represents ‘Quality of Service not available’. If ‘no limit’ is configured then no limit checking is done. 
     Maximum Allowed Committed Burst Size (Max Bc) 
     This selection allows the node administrator to assign the maximum committed burst size for frame relay SVCs. 
     Valid Values: From 0 to 2**30−1Kbits; and ‘no limit’. 
     Default Value: ‘no limit’ 
     Conditions: If the limits for incoming or outgoing calls is enabled, then any incoming or outgoing call requesting an incoming or an outgoing committed burst size in excess of the configured maximum allowed value will be rejected with a cause code value of #49, which represents ‘Quality of Service not available’. If ‘no limit’ is configured then no limit checking is done. 
     Default Committed Information Rate (Def CIR) 
     This selection allows the node administrator to assign the default committed information rate for frame relay SVCs. 
     Valid Values: From 0 to 2**30−1Kbps 
     Default Value: 0 Kbps 
     Conditions: If the incoming FR SVC call does not explicitly request a specific committed information rate then the default CIR value is used as the requested CIR. 
     Default Excess Burst Size (Def Be) 
     This selection allows the node administrator to assign the default excess burst size for frame relay SVCs. 
     Valid Values: From 0 to 2**30−1Kbits 
     Default Value: 56 Kbits 
     Conditions: If the incoming FR SVC call does not explicitly request a specific excess burst size then the default Be is used as the requested Be. 
     Default Committed Burst Size (Def Bc) 
     This selection allows the node administrator to assign a default committed burst size for frame relay SVCs. 
     Valid Values: From 0 to 2**30−1Kbits 
     Default Value: 0 Kbits 
     Conditions: If the incoming FR SVC call does not explicitly request a specific committed burst size then the default Bc is used as the requested Bc. 
     Default Service Category 
     This selection allows the node administrator to assign the default ATM service category for frame relay SVCs. 
     Valid Values: ‘nrt VBR’, ‘UBR’ and ‘ABR’. 
     Default Value: ‘nrt VBR’. (nrt VBR is the default selected by the Frame Relay Forum for FR SVCs; see document frftc. 106r1, supra). 
     Conditions: Since FR SVC calls may not request a specific service category at call set-up time, the default service category is used for all incoming calls originating from the subscriber. 
     2. SVC Throughput Limit Provisioning for Native ATM 
     Maximum Allowed Peak Information Rate (Max PIR). 
     This selection allows the node administrator to assign the maximum peak information or data transmission rate for SVCs in the ABR, nrt-VBR and rt-VBR service categories. (The PIR limit corresponds to the PCR traffic descriptor parameter formally specified in the ATM standards.) 
     Valid Values: From 0 to 2**30−1Kbps; and ‘no limit’. 
     Default Value: ‘no limit’ 
     Conditions: If the limit for incoming or outgoing calls is enabled, then any incoming or outgoing call requesting a forward or backward peak information or data transmission rate greater than the configured maximum allowed value will be rejected with a cause code value of #49, which represents ‘Quality of Service not available’. If ‘no limit’ is configured then no limit checking is done. The PIR applies to the following ATM service categories: ABR, nrt-VBR and rt-VBR. 
     Maximum Allowed Sustained/Minimum Information Rate (Max SIR/MIR) 
     This selection allows the node administrator to assign the maximum allowed sustained or minimum information or data transmission rate for ATM SVCs in the rt-VBR, nrt-VBR and ABR service categories. (The SIR./MIR limit corresponds to the SCR and MCR parameters formally specified in the ATM standards.) 
     Valid Values: From 0 to 2**30−1Kbps; and ‘no limit’. 
     Default Value: ‘no limit’ 
     Conditions: If the limits for incoming or outgoing calls is enabled, then any incoming or outgoing call requesting a forward or backward SIR or MIR in excess of the configured maximum allowed value will be rejected with a cause code value of #49, which represents Quality of Service not available. If ‘no limit’ is configured then no limit checking is done. The SIR/MIR applies to the following service categories: rt-VBR(SIR), nrt-VBR(SIR) and ABR(MIR). 
     Maximum Allowed Peak Information Rate for CBR (Max PIR for CBR) 
     This selection allows the node administrator to assign the maximum allowed peak information or data transmission rate (corresponding to the PCR parameter) for ATM SVCs requesting a service category of CBR. 
     Valid Values: From 0 to 2**30−1Kbps; and ‘no limit’. 
     Default Value: ‘no limit’ 
     Conditions: If the limits for incoming or outgoing calls is enabled, then any incoming or outgoing call requesting a forward or backward PIR for CBR in excess of the configured maximum allowed value will be rejected with a cause code value of #49, which represents ‘Quality of Service not available’. If ‘no limit’ is configured then no limit checking is done. This limit only applies to ATM SVCs requesting a CBR service category. 
     Maximum Allowed Peak Information Rate for UBR (Max PIR for UBR) 
     This selection allows the node administrator to assign the maximum allowed PIR (corresponding to the PCR parameter) for ATM SVCs requesting a service category of UBR. 
     Valid Values: From 0 to 2**30−1Kbps; and ‘no limit’. 
     Default Value: ‘no limit’ 
     Conditions: If the limit for incoming or outgoing calls is enabled, then any incoming or outgoing call requesting a forward or backward PIR for UBR in excess of the configured maximum allowed value will be rejected with a cause code value of #49, which represents ‘Quality of Service not available’. If ‘no limit’ is configured then no limit checking is done. This limit only applies to ATM SVCs requesting a UBR service category. 
     Maximum Allowed Maximum Burst Size (Max MBS) 
     This selection allows the node administrator to assign the MBS for ATM SVCs in the rt VBR or nrt VBR service categories. 
     Valid Values: An integer value or ‘no limit’. 
     Default Value: ‘no limit’ 
     Conditions: If the limit for incoming or outgoing calls is enabled, then any incoming or outgoing call requesting a forward or backward MBS in excess of the configured maximum allowed value will be rejected with a cause code value of #49, which represents ‘Quality of Service not available’. If ‘no limit’ is configured then no limit checking is done. This limit only applies to ATM SVCs requesting a rt VBR or a nrt VBR service category. 
     3. Limits Administration 
     Limits for Incoming Calls 
     This selection allows the node administrator to enable or disable the verification that incoming calls are requesting throughput that falls within the configured throughput limits. 
     Valid Values: ‘Enabled’ or ‘Disabled’ (Boolean values) 
     Default Value: ‘Disabled’ 
     Conditions: Limit checking is carried out on incoming calls only when this parameter is enabled; otherwise no checks on incoming calls are carried out. 
     Limits for Outgoing Calls 
     This selection allows the node administrator to enable or disable the verification that outgoing calls are requesting throughput that falls within the configured limits. 
     Valid Values: ‘Enabled’ or ‘Disabled’ (Boolean values) 
     Default Value: ‘Disabled’ 
     Conditions: Limit checking on outgoing calls is carried out only when this parameter is enabled; otherwise no checks on outgoing calls are carried out. 
     As shown, these limits are invoked on a global basis in that all previously described incoming or outgoing limits are checked or not. However, the enablement/disablement mechanism may be implemented on a per limitation basis, if desired. 
     4. SVC Permission Based on Requested Service Category 
     These selections. as shown in FIG. 4, allow the node administrator to accept or reject SVCs based solely on the requested service category of the call. All five service categories CBR, rt VBR, nrt VBR, ABR and UBR are individually configurable. This throughput limitation applies only to incoming calls. 
     Valid Values: ‘Y’ or ‘N’. 
     Default Value: ‘Y’ (meaning accept the call) 
     Conditions: If the ‘accept SVCs based on requested service category’ limitation is ‘N’ for a given service category and a call originates from the subscriber requesting the given service category, the call will be rejected with a cause code value of #57 which represents ‘Bearer capability not authorized’. 
     For ease of reference, the following table 1 illustrates the concordance or relationship between the foregoing ATM throughput limits and service categories. 
     
       
         
               
               
               
               
               
               
             
           
               
                 TABLE 1 
               
               
                   
               
               
                 Service 
                 PIR 
                 SIR/MIR 
                 MBS 
                 PIR for 
                 PIR for 
               
               
                 Category 
                 Support 
                 Support 
                 Support 
                 CBR 
                 UBR 
               
               
                   
               
             
             
               
                 ABR 
                 Yes 
                 Yes(MIR) 
                 n/a 
                 n/a 
                 n/a 
               
               
                 nrt VBR 
                 Yes 
                 Yes(SIR) 
                 Yes 
                 n/a 
                 n/a 
               
               
                 rt VBR 
                 Yes 
                 Yes(SIR) 
                 Yes 
                 n/a 
                 n/a 
               
               
                 CBR 
                 n/a 
                 n/a 
                 n/a 
                 Yes 
                 n/a 
               
               
                 UBR 
                 n/a 
                 n/a 
                 n/a 
                 n/a 
                 Yes 
               
               
                   
               
             
          
         
       
     
     In the foregoing, the throughput limitations are specifiable on a per subscriber/per connection basis. That is, each time the subscriber attempts to originate or terminate a switched connection the limit checking, if enabled, is performed for that particular connection. however, in alternative or additional embodiments the throughput limitations may be cumulative per subscriber. In such an embodiment the edge node  12  maintains throughput limitation accumulators for each subscriber. Thus. for instance, if a particular subscriber has a cumulative PCR limitation of 10 Mbs, then in circumstances where the subscriber has established connections reserving 9 Mbs and is requesting an additional connection requiring 2 Mbs, the new connection would be refused. Similarly other modifications and variations may be made to the preferred embodiment without departing from the spirit of the invention.

Technology Category: 5