SE520898C2 - Packetized data forwarding method in data communication system, involves forwarding packetized data associated with different application, based on threshold traffic level - Google Patents

Abstract

When determining whether forwarding a packetized data associated with two different applications exceeds threshold traffic level of second priority, the packetized data associated with first application is forwarded first. After forwarding the first application, the second application is forwarded, depending on the comparison made between applications. The first priority represents a lower level of quality of service (QOS) than the second priority. The packetized data are received from both the applications associated with a subscriber, and at least a threshold traffic level associated with the subscriber is provided. Depending on received packetized data, the data is forwarded by the applications having desired second priority. A best effort service that does not guarantee timely delivery by packetized data is used for forwarding packetized data at first priority. The packetized data includes information with at least one protocol includes information with at least one protocol selected from set of protocols including transmission control protocol (TCP), an internet protocol (IP), an user deltagram protocol (UDP), a real time transport protocol (RTP), a real time streaming protocol (RSTP) and a reservation protocol (RSVP). An Independent claim is also included for packetized data forwarding arrangement.

Description

25 30 520 898 considerably. The variation of QOS for VoIP connections is typically a function of the level of traffic on the network, compared to available sources.

To provide real-time communication, as is the case with VolP connections, the datagrams that contain audio and / or video information have an inherent time sensitivity. Then the datagrams must arrive at the receiving node in an appropriate order. Thus, e.g. the information contained in late-arriving or otherwise delayed datagrams was not transmitted to or used by the application of the receiving node. It is this "lost" or delayed information that tends to significantly reduce the QoS provided. I A conventional set of TCP / IP protocols includes fl your protocols that are configured to increase QoS for selected datagrams. For example, a "user datagram protocol" (UDP) is provided for use instead of TCP. UDP can be used for real-time audio and video traffic where lost datagrams are simply ignored because there is no time to retransmit (which is typically A real-time transport protocol (RTP) is further provided for use with audio and video transmissions. RTP provides additional information for marking and synchronizing time used in the reconstruction of audio and / or video information at the receiving node. Other protocols are also known, such as e.g. a "real-time streaming protocol" (RTSP) used to transmit audio and / or video over IP, and a "reservation protocol" (RSVP) used by the network to reserve bandwidth to control nodes in real-time audio and video transmission.

If one uses these different protocols and associated techniques, there are mainly two methods that currently are available to achieve an expected QoS in an IP data communication network. The first method is a connection-oriented method where new sessions or applications, which require more than the typical "best effort" QoS (ie no guaranteed QoS), need to reserve capacity or bandwidth from the source node to the RSVP used for to reserve bandwidth over a network. The reservation of the receiving node or the destination node. Thus, e.g. However, network bandwidth tends to reduce the efficiency of the network.

The second method is an unconnected oriented method, where the datagrams are associated with a desired priority setting or label and the various control nodes in the network are configured to control the datagrams in a manner related to the priority label of each datagram. Thus, e.g. certain special separate services of the Internet Engineering Task Force (IETF) where a priority label is included in the type of service (ToS) switch in Internet Protocol Version 4 (lpv4).

This non-connection-oriented method can be realized in several ways.

WO 97/36405, with "Prioritization of Data to be Transmitted in a Router", shows e.g. that the international Patent Application Number title radio-transmitted packets can be selectively controlled in a radio-accessed network by using data queuing techniques associated with the desired QoS (eg priority tag) or a subscriber's identity. Such queuing techniques mean that higher priority datagrams are sent before lower priority datagrams (eg best effort datagrams). This tends to increase the QoS for higher priority datagrams, such as datagrams containing audio and / or video information. Unfortunately, there is still a possibility of lost audio and voice information in such systems, if the various data queues with higher priority are affected by overflow. and Therefore, improved data transmission methods arrangements for distinguishing between different priority data, reducing lost data are needed and providing a reliable QoS for selected transmissions of priority data. DESCRIPTION OF THE INVENTION The present invention provides improved data transfer methods and arrangements that differentiate between different classes and levels of priority data and manages the different data classes in a manner that reduces the possibility of losing higher priority data. whereby a more reliable "quality of service" (QoS) is provided for selected data transmissions with selected priority.

In accordance with certain aspects of the present invention, data packets are marked with a priority identifier and processed accordingly. However, if a forwarding node cannot handle further higher priority data, e.g. p.g.a. high traffic volume and data queues that are affected by overflow, then the data packet with a higher priority is handled as a data packet with a lower priority. This means that the higher-priority data packets have an opportunity to be forwarded rather than simply lost. In some situations, this monitoring system significantly increases the QoS. In addition, the service provider has increased control over the resources that handle data packets with higher priority.

In accordance with certain embodiments of the present invention, there is provided e.g. a method of transmitting packetized data in a data communication system. The method includes the steps of receiving packetized data and forwarding packetized data with a first priority if it is not identified as the holder of a desired second priority. In which case, the method includes forwarding the packetized data with the desired second priority provided that the traffic level threshold associated with the second priority has not been exceeded or will not be exceeded by the subscriber. Otherwise, the method includes forwarding this packetized data with the first priority rather than the second priority.

A number of priority levels can be provided and higher priority data can be handled at any of the lower priority levels. The packaged 10 15 20 25 30 520 898 data can e.g. contain data formatted in accordance with a "transmission control protocol" (TCP), an "internet protocol" (IP), a "use datagram protocol" (UDP), a "realtime transport protocol" (RTP), a "realtime streaming protocol" "(RTSP), a" reservation protocol "(RSVP), and / or other similar protocols. The method may also be operatively associated with a forwarding node in a network such as a gateway, a switch, a bridge, a server, a router, or other similar node.

In accordance with certain further embodiments of the present invention, the method further includes the steps of determining the application associated with received packetized data, and selectively forwarding the packetized data associated with a first application before forwarding data associated with a second application. Thus, specific applications can be provided with a specific QoS. This is especially useful for applications that require time-critical packaged data.

The needs described above and also others are also met by a data communication network, in accordance with certain embodiments of the arrangement for forwarding packaged data in the present invention. The arrangement includes a source node having at least one application connected to a subscriber and configured to output packetized data. Profile data is also included in the arrangement, the profile data is associated with a specific subscriber and includes at least one traffic level threshold associated with the subscriber. The cut-off threshold thresholds an agreed amount of packaged data traffic service to be provided for packaged data forwarded according to at least one priority.

The arrangement further includes a monitoring module, which is connected to the source node and configured to receive packaged data from the application and have access to profile data, e.g. by using a source node address or other identifier. The monitoring module is further configured to forward the packaged data with a first priority, unless the application identifies that the packaged data has a desired second priority. In any case, the monitoring module forwards the packetized data with the desired second priority provided that the traffic level threshold associated with the second priority is not exceeded or is not to be exceeded by the subscriber. Otherwise, the monitoring module forwards the packetized data with the first priority. In accordance with certain further embodiments of the present invention, the monitoring module further includes a number of data queues and a prioritizer.

The set of data queues includes at least a first queue configured to save the packetized data to be forwarded with the first priority, and a second queue configured to save the packetized data to be forwarded with the second priority.

The prioritizer receives the packetized data, selectively places the packetized data in at least one of the data queues, and forwards at least a portion of stored packetized data in the second queue before forwarding stored packetized data in the first queue. In accordance with yet another embodiment of the present invention, another arrangement is provided. This arrangement includes at least one source node, one network, at least one destination node and one monitoring module.

The source node is configured to output at least two classes of packaged data, including "top-priority" (TP) data and "best effort" (BE) data. u. H 10 15 20 25 30 520 898 The network is connected to the source node and configured to receive, queue, and forward each of the classes of packetized data, including the TP data and the BE data.

The destination node is connected to the network and configured to receive at least one of the classes of packetized data, including either the TP data and / or the BE data transmitted by the network. The monitoring module is configured to monitor and dynamically control the queuing of at least the TP data and BE data in the network. The monitoring module is configured to selectively return at least a portion of the TP data with the BE data to the queue when a TP data traffic level associated with the TP data from the source node to the destination node exceeds at least one traffic level threshold. The traffic level threshold can be a traffic level threshold for TP data at a source node and / or a traffic level threshold for TP at a destination node.

DESCRIPTION OF THE DRAWINGS A more complete understanding of the method and arrangements of the present invention can be obtained by means of the following detailed description taken in conjunction with the accompanying drawings in which: Fig. 1 is a block diagram describing a conventional data communication system having at least one routing node configured to take receive and forward packaged data, e.g. in the form of a datagram; Fig. 2 is a block diagram describing an improved control node to be used in a communication system, e.g., as in Fig. 1, in accordance with certain typical embodiments of the present invention; and 10 15 20 25 30 520 898 F ig. Fig. 3 is a datagram suitable for use with an improved control node, e.g., as in Fig. 2, in accordance with certain further embodiments of the present invention.

PREFERRED EMBODIMENTS Fig. 1 is a block diagram describing a conventional data communication system 10. The data communication system 10 is configured to allow bidirectional (or multidirectional) data communication between two or more communicating nodes. For the sake of simplicity, only two communicating nodes have been described in Fig. 1, each marked with respect to its function during a typical, one-way data communication session. Thus, as described in Fig. 1, there is a source 12 and a destination 28 associated with a one-way data communication for a datagram 16 from the source 12 through several interconnected resources to the destination 28.

Source 12 is configured to output information in the form of data. The data output from the source 12 is packaged or arranged in another way in the form of a datagram 16. The datagram 16 can e.g. include an IP-configured data packet. The source 12 may include any device capable of outputting the datagram 16. Thus, the source 12 may e.g. include a telecommunication terminal or other computing device configured to convert the user's inputs, audio signals, still video images, and / or the like to one or more datagrams.

The source 12 is connected to the network 14 and configured to output the datagram 16 through the network 14 to a gateway 18. The network 14 may include any type of data network that may transport the datagram 16. Thus, e.g. the network 14 include a LAN, WAN, intranet, PSTN, network for mobile telecommunications and the like. Gateway 18 provides connectivity between the network 14 and the network 20. The network 20 may include any type of data network that can transport the datagram 16. Thus, e.g. network 20 LAN, WAN, PSTN, mobile telecommunications and the like. include an intranet, Internet, network for the Network 20 'includes a number of interconnected routing nodes, such as those having the routers 22A-N. Control nodes are preferably packet-switched nodes, configured to store and forward various datagrams 16. As such, routers 22A-N may include any communication resource / device configured to receive and selectively output datagrams 16. Routers 22A-N may e.g. include routers, switches, gateways, bridges, servers, etc.

According to what is described in fi g. 1, a first router 22A is connected to gateway 18 and configured to selectively receive datagram 16 and direct datagram 16 to one or more connected routers 22B to 22N. In this example, datagram 16 is output from router 22A to router 22B. Router 22B is connected to a second gateway 24. Router 22B outputs datagram 16 to gateway 24.

Gateway 24 provides connectivity between network 20 and network 26. Network 26 may include any type of data network that may transport datagrams 16. Thus, e.g. networks 26 include a LAN, WAN, intranet, PSTN, network for mobile data communication and the like. As described in Fig. 1, destination node 28 is connected to network 26 and configured to receive the datagram 16 therefrom.

Destination node 28 is configured to process the information contained in the datagram 16. As such, destination node 28 may include any device capable of outputting the datagram 16. Thus, e.g. destination node 28 include a telecommunication terminal or other computing device configured to convert the datagram 16 to corresponding outputs to the user, audio signals, still / video images, etc.

A monitoring module 38 is described in Fig. 2 in accordance with certain embodiments of the present invention. Monitoring module 38, which may be incorporated into any interface, switch or control node in a communication system or network, is configured to receive, prioritize and output datagrams. Thus, e.g. monitoring module 38 is included in any of gateways 18/24, and / or routers 22A-N. The monitoring module 38 can also be used elsewhere in the network 14 and / or 26, as appropriate. Preferably, monitoring module 38 is included in each control node.

Control node 38 is configured to receive a datagram 16 'and to selectively output datagram 16'. As described in the typical embodiment of Fig. 2, the monitoring module 38 includes a prioritizer 30, a number of data queues 32 and user profiles 34. Alternatively, all or parts of the user profiles 34 may be located outside the monitoring module 38, and may then be centrally located or on otherwise provided for use by a number of nodes configured in a similar manner. In some configurations, the user profiles 34 are only data associated with subscribers that can be stored / retrieved, e.g. in / from a database connected to the network 20 or otherwise connected to a control node therein.

In the examples below, it is assumed that the datagram 16 'can be marked as either a "top priority" (TP) datagram, or a "best effort" (BE) datagram.

For IP, e.g. ToS switches can be modified, or another part of the protocol header can be used. Continuing with the above example, we can assume that a TP datagram has a higher priority than a BE datagram, taking into account control decisions in the network and the desired / resulting QOS. 10 15 20 25 30 520 898 11 Thus, e.g. real-time or time-critical data, such as audio or video data, are preferably transported using TP datagrams rather than BE datagrams. Although this example uses only two different priorities, it should be clarified that more than two priorities can be defined.

The user profiles 34 provide information about the various users or subscribers who can send / receive the datagram 16 ”. In accordance with certain preferred embodiments of the present invention, e.g. the user profiles 34 include information in the form of data defining the subscriber's capacity to send / receive datagrams with different priorities and (as an option) the different applications that can be used by the subscriber.

Thus, the user profiles 34 may, as a minimum, include at least one identifier defining a TP threshold level 36 associated with an agreed level of service to be provided by the provider of the communication service to a given subscriber. If multiple priority levels are to be provided, the user profiles 34 may include a number of corresponding threshold levels.

As described in more detail below, the threshold level 36 is used to determine whether a subscriber (either transmitter or receiver) is using the service as agreed. Should a subscriber exceed the agreed service, e.g. by attempting to send / receive a number of TP datagrams (over a period of time) greater than the TP threshold level 36, the monitoring module 38 will dynamically change the handling of such TP datagrams. Furthermore, the monitoring module 36 can report this condition and other monitored information to other network resources for further processing. This provides additional control over the network and its subscribers.

The prioritizer 30 is configured to receive datagram 16 'and at least the threshold level 36 from the user profile 34. The prioritizer 30 determines the priority of the datagram 16' (eg TP or BE) by examining a priority identifier 40. in the datagram 16 '(see Fig. 3). The prioritizer 30 is further configured to monitor the status of the data queues 32A-K and to determine an appropriate data queue for the received datagram 16 '. Each of the data queues 32A-K is associated with at least one datagram priority level, and is preferably configured as a "first-in-first-out" (FIFO) configuration, and data queues serving higher priority datagrams are emptied first.

Thus, in the above example, data queue 32A may be associated with TP datagrams and data queue 32B may be associated with BE datagrams.

Therefore, in this example, the following possible scenarios need to be handled by the monitoring module 38: 1.) If a BE datagram 16 '(i.e. a lower priority queue) does not overflow, then the prioritizer 30 places the BE datagram 16' in the data queue 32B; 2.) If a BE datagram 16 'is received and the BE data queue 32B has overflow, then the prioritizer 30 (i.e. does not forward) the received BE datagram 16'; 3.) If a TP datagram 16 '(ie a higher priority datagram) is received and the TP data queue 32A (ie a higher priority data queue) does not overflow, then the prioritizer 30 compares the amount of TP tracts transmitted / received of the subscriber (s) during a previous time period with the TP threshold level 36, a.) if the TP threshold level 36 has not been exceeded by the subscriber (s), then the received TP datagram 16 'is placed in the TP data queue 32A, annafS 10 15 20 25 30 520 898 13 b.) If the TP threshold level 36 has been exceeded (or will be exceeded) by the subscriber (s), then the received TP datagram 16 'is treated as having a lower priority, in this example, it is treated according to scenarios 1.) or 2.), as above.

When the higher priority threshold level 36 is exceeded (or should be exceeded), the priority marking of the datagram 16 'is largely ignored, and the datagram 16' is temporarily re-prioritized to a lower priority. If there are more than two priority levels, the reprioritization (i.e. new location in the queue) can be reduced or otherwise configured appropriately to allow the next highest available priority data queue to be used.

In accordance with yet another embodiment of the present invention, the monitoring module 38 is configured to allow certain subscribers to exceed the threshold level 36, provided that the resources required to handle such an additional higher priority traffic are available. Thus, e.g. the user profile 34 further specifies that the subscriber may exceed the threshold 36 at times. Furthermore, the priority identifier 40 or other data in the datagram may be used by the application to identify that the datagram should not be re-prioritized, if possible. Subscribers who exceed their agreed threshold 36 can accordingly be charged for this additional service / opportunity.

Fig. 3 graphically describes a datagram 16 'in accordance with certain embodiments of the present invention. The datagram 16 'includes at least one priority identifier 40 which identifies the desired priority level for the data concerned therein. Thus, in accordance with certain embodiments of the present invention, e.g. the datagram 16 'is an IP datagram and the priority identifier 40 is included in the ToS bytes. Real-time data 44 can also be included in the 16 ”datagram. Real-time data includes any time-critical data, such as audio, video or other image data. In accordance with yet another embodiment of the present invention, an application identifier 42 may also be provided in the datagram 16 '. The application identifier 42 identifies the type of application used at the source / destination nodes. Thus, e.g. the application identifier 42 identifies that the datagram 16 "is associated with an audio signal, a video signal, etc., and / or that the datagram is associated with a critical application, non-critical application, etc. In this way, the prioritizer 30 can gain additional information about the current communication and can further change the handling of the datagram 16 'accordingly. The application identifier 42 may be combined with or separated from the priority identifier 40.

The prioritizer 30 can e.g. use the information transmitted from the application identifier 42 to further determine how to handle the received datagram 16 '. Thus, a TPP datagram 16 'of a VolP application can be assigned priority over a TP datagram 16' of a non-VoIP application in the TP data queue 32A whereby the TP datagram of the non-VoIP application will be re-prioritized (or assigned a new queue) if TP data queue 32A would be full. Further improvements may include the provision of additional data queues 32 for use with different applications, where each additional data queue 32 has at least one corresponding priority level.

In this way, the prioritizer 30 can be fine-tuned to increase the QoS for selected priorities / applications and / or maximize system usage. By selectively, dynamically and temporarily re-prioritizing or assigning new space in the queue for the datagrams, the monitoring module 38 significantly reduces the possibility of dropping higher-priority datagrams.

By including the monitoring module 38 at a number of interconnected nodes in a data communication system / network, the overall control of the system / network can be increased. In this way, the providers can provide incentives for the communication services further 10 15 520 898 15 the subscribers to either choose certain services, and / or to avoid exceeding the agreed services. The monitoring module 30 may be performed in hardware or software, and where applicable it may be free or distributed or otherwise arranged along the various nodes as required to further enhance the additional features supported.

Although certain preferred embodiments of the methods and arrangements of the present invention have been illustrated in the accompanying drawings and described in the foregoing preferred embodiment, it is to be understood that the invention is not limited to the embodiments shown, but is capable of your various rearrangements. modifications and substitutions without departing from the spirit of the invention as set forth and defined by the following claims.

Claims (11)

10 15 20 25 30 520 898 16 PATE NTKRAV A method of transmitting packaged data in a data communication system, the method comprising the steps of: receiving packaged data from at least a first application and a second application associated with a subscriber; providing at least one traffic knife threshold associated with said subscriber, said traffic threshold denying an agreed amount of packet data traffic service to be provided for packaged data forwarded according to at least one priority; determining an application type for said first application and said second application associated with said received packetized data; forwarding the packetized data with a first priority unless the first and said second applications identify that they have a desired second priority; determining whether the transmission of said packetized data associated with said first application and said second application exceeds said traffic level threshold for said second priority; and if so, forwarding said packaged data associated with said first application with said desired second priority before forwarding with said packaged data associated with said second application, based on a comparison between said application type of said first application and said second application. The method of claim 1, wherein said first priority represents a lower level of "quality of service" (Qos) than said second priority, and said step of forwarding said packaged data with said first priority further includes that a best effort service which does not guarantee that the delivery of said packaged data takes place in time has been used. The method of claim 1, wherein said second priority represents a higher level of quality of service (QoS) than said first priority does, and said method further comprises the steps of: storing said packaged data to be forwarded with said first priority in a first queue; storing said packaged data to be forwarded with said second priority in a second queue; and forwarding at least a portion of stored packet data in said second queue before forwarding stored packet data in said first queue. The method of claim 1, wherein said packaged data includes information associated with at least one protocol selected from a set of protocols including a transmission control protocol (TCP), an internet protocol (IP), a user datagram protocol ”(UDP), a“ realtime transport protocol ”(RTP), a“ realtime streaming protocol ”(RTSP), and a“ reservation protocol ”(RSVP). The method of claim 1, wherein said method is operatively associated with at least one forwarding node selected from a set of forwarding nodes including a gateway, a switch, a bridge, a server and a router. The method of claim 1, further comprising the steps of, for certain subscribers, forwarding said packaged data associated with said first application and said second application having said desired second priority when said traffic level threshold associated with said second priority is exceeded by said subscriber, as long as as the network resources are available and the profile information associated with said certain subscribers allows said certain subscribers to exceed said traffic level threshold. An arrangement for transmitting packetized data in a data communication network, the arrangement comprising: a source node having at least one application associated with a subscriber and configured to output packetized data; profile data associated with said subscriber, wherein said profile data includes at least one traffic level threshold associated with said subscriber, and wherein said traffic level threshold defines an agreed amount of packeted data traffic service to be provided for forwarding packaged data according to at least one priority; a monitoring module connected to said source node and configured to receive packaged data from said application and access said profile data, said monitoring module further configured to: forward said packaged data with a first priority unless by means of said application therein it is identified that they has a desired second priority, forwarding said packaged data with said desired second priority, as identified therein by said application, provided that said threshold threshold associated with said second priority is not exceeded by said subscriber, [and] forwarding said packaged data with said subscriber desired second priority, as identified therein by said application, when said traffic level threshold associated with said second priority is exceeded by said subscriber, provided that network resources are available and said profile data associated with said subscriber allows said traffic level threshold to exceed and otherwise forwarding said packaged data with said first priority, and wherein said monitoring module is further configured to determine an application type for said application associated with said received packaged data, and selectively forwarding said packetized data associated with a first application before data associated with a second application is forwarded based on said application type and whether said traffic level threshold associated with said second priority is exceeded by said subscriber. The arrangement of claim 7, wherein said first priority represents a lower level of "quality of service" (QoS) than said second priority, and wherein said monitoring module forwards said packaged data with said first priority and then uses a "best effort" - service that does not guarantee the timely delivery of said packaged data. The arrangement of claim 7, wherein said second priority represents a higher level of quality of service (QoS) than said first priority does, and wherein said monitoring module further includes: a plurality of data queues including at least one first queue configured to store said packetized data to be forwarded with said first priority, and a second queue configured to store said packetized data to be forwarded with said second priority, and a prioritizer connected to the data queues and configured to receive said packetized data, selectively placing said packaged data in at least one of said data queues, and forwarding at least a portion of stored packet data in said second queue before forwarding packaged data in said first queue is forwarded. The arrangement of claim 7, wherein said packaged data includes information associated with at least one protocol selected from a set of protocols that includes a "transmission control protocol" (TCP), an "Internet protocol" (IP), a "user datagram protocol" "(UDP), a" real-time transport protocol "(RTP), a" real-time streaming protocol "(RTSP), and a" reservation protocol "(RSVP). 520 898 20 The arrangement of claim 7, wherein said monitoring module is operatively coupled to at least one forwarding node selected from a set of forwarding nodes including a gateway, a switch, a bridge, a server, and a router.