1. Field of the Invention
The present disclosure relates to processing data. In particular, but not exclusively, the present disclosure relates to processing data in a telecommunication network.
2. Description of the Related Technology
Internet Protocol (IP) telephony networks, such as those conforming to the IP Multimedia Subsystem (IMS) are currently experiencing an increase in prevalence. In such networks, telephony services are typically provided according to the Session Initiation Protocol (SIP). An IP telephony network may contain a number of network nodes, such as Call Session Control Function (CSCF) entities in the case of IMS, which are responsible for conducting registration procedures, handling routing requests and/or handling service requests in the network. In the context of SIP, such a network node may fulfill the roles of a SIP server and/or SIP proxy. Network nodes should therefore maintain state information (for example routing data, authentication data etc.) for each subscriber that they serve. For relatively small numbers of subscribers, it may be possible for each network node to maintain state information for every subscriber. However, for large numbers of subscribers, the memory requirements for storing state information for every subscriber at each network node and the requirement for replicating the state information between all network nodes in the network can become prohibitive.
In order to cater for larger numbers of subscribers, sharding techniques are known to be employed in IMS networks. Sharding involves allocating a longstanding responsibility for a subset of the subscribers in the telecommunications network to each network node in the network. Each network node therefore need only maintain state information for its allocated subset of subscribers. In a typical example, when a subscriber device registers with the network, it may be allocated to a network node, such as a Serving CSCF (S-CSCF) in the case of IMS, which is thereafter responsible for maintaining the appropriate state information for that subscriber until such time as the device unregisters from the network. However, this approach suffers from increased routing complexity because any messages (for example, requests) relating to a given subscriber that are handled after the initial registration must be routed via the appropriate, sharded network node. Further, the complexity of providing redundancy between sharded network nodes in order to handle failure of an individual network node in the network is increased.
Hence, it would be desirable to provide improved and/or alternative techniques for handling potentially large numbers of subscribers and/or providing the required network scalability to do so.
According to a first embodiment, there is a method of processing data in a telecommunications network, the network comprising: a cluster of network nodes responsible for conducting registration procedures for subscriber devices and/or processing routing data relating to communication sessions conducted in the network; and a shared registration data store comprising registration data for a plurality of subscriber devices, the shared registration data store being accessible by each of the network nodes in the cluster of network nodes, the method comprising, at a first network node in the cluster of network nodes: receiving a communication session setup request requesting setup of a communication session with a subscriber device in the plurality of subscriber devices; in response to receipt of the communication session setup request, retrieving registration data relating to the subscriber device from the shared registration data store; and routing the communication session setup request according to the retrieved registration data, the retrieved registration data relating to the subscriber device having been previously stored in the shared registration data store by a second network node in the cluster of network nodes in relation to a registration procedure conducted for the subscriber device by the second network node, the second network node being a different network node to the first network node in the cluster of network nodes.
According to a second embodiment, there is a system for processing data in a telecommunications network, the system comprising a first network node in a cluster of network nodes the system comprising at least one processor, and at least one memory including computer program code, the at least one memory and the computer program code being configured to, with the at least one processor, cause the system at least to, at a first network node in the cluster of network nodes responsible for conducting registration procedures for a plurality of subscriber devices and/or processing routing data relating to communication sessions conducted in the network: receive a communication session setup request requesting setup of a communication session with a subscriber device in the plurality of subscriber devices; retrieve, in response to receipt of the communication session setup request, registration data relating to the subscriber device from a shared registration data store, wherein the shared registration data store comprises registration data for the plurality of subscriber devices and is accessible by each of the network nodes in the cluster of network nodes; and route the communication session setup request according to the retrieved registration data, the retrieved registration data relating to the subscriber device having been previously stored in the shared registration data store by a second network node in the cluster of network nodes in relation to a registration procedure conducted for the subscriber device by the second network node, the second network node being a different network node to the first network node in the cluster of network nodes.
According to a third embodiment, there is a system for processing data in a telecommunications network, the system comprising: a first network node in a cluster of network nodes responsible for conducting registration procedures for subscriber devices and/or processing routing data relating to communication sessions conducted in the network, the first network node comprising at least a first processor, and at least a first memory including first computer program code, the at least first memory and the first computer program code being configured to, with the at least first processor, cause the system at least to: receive a registration request requesting registration of a subscriber device in the plurality of subscriber devices; and store, in response to receipt of the registration request, registration data relating to the subscriber device in a shared registration data store, wherein the shared registration data store comprises registration data for a plurality of subscriber devices and is accessible by each of the network nodes in the cluster of network nodes; and a second network node in the cluster of network nodes, the second network node comprising at least a second processor, and at least a second memory including second computer program code, the at least second memory and the second computer program code being configured to, with the at least second processor, cause the system at least to: receive a communication session setup request requesting setup of a communication session with the subscriber device in the plurality of subscriber devices; retrieve, in response to receipt of the communication session setup request, the registration data relating to the subscriber device from the shared registration data store; and route the communication session setup request according to the retrieved registration data.
According to a fourth embodiment, there is a method of processing data in a telecommunications network, the network comprising: a cluster of network nodes responsible for conducting registration procedures for subscriber devices and/or processing routing data relating to communication sessions conducted in the network; a shared registration data store comprising registration data for a plurality of subscriber devices, the shared registration data store being accessible by each of the network nodes in the cluster of network nodes, the method comprising, at a first network node in the cluster of network nodes: receiving a registration request requesting registration of a subscriber device in the plurality of subscriber devices with the network; and in response to receipt of the registration request, determining that registration data relating to the subscriber device already exists in the shared registration data store, the existing registration data relating to the subscriber device having been previously stored in the shared registration data store by a second network node in the cluster of network nodes in relation to a registration procedure conducted for the subscriber device by the second network node, the second network node being a different network node to the first network node in the cluster of network nodes; and in response to the determination, updating the existing registration data relating to the subscriber device in the shared registration data store.
Embodiments comprise a computer program product comprising a non-transitory computer-readable storage medium having computer readable instructions stored thereon, the computer readable instructions being executable by a computerised device to cause the computerised device to perform the method of the first or fourth embodiments.
Further features of embodiments will become apparent from the following description of preferred embodiments, given by way of example only, which is made with reference to the accompanying drawings.
In order to provide efficient scalability of a telephony network, embodiments do not employ a longstanding assignment of a given subscriber to a given network node. Instead, any network node among a plurality of network nodes is enabled to process messages relating to any given subscriber.
Subscriber device 102 is configured to conduct telephony sessions via telecommunications network 100. Subscriber device 102 communicates with telecommunications network 100 via edge proxy node 104. The communication link between subscriber device 102 and edge proxy node 104 may further comprise one or more intermediate entities, such as wireless access points, routing devices etc. Edge proxy node 104 may be further responsible for interfacing between telecommunications network 100 and one or more further subscriber devices (not shown). Telecommunications network 100 may also comprise one or more further edge proxy nodes (not shown), each responsible for interfacing between telecommunications network 100 and a number of yet further subscriber devices (not shown). For example, each further edge proxy node may provide access to telecommunications network 100 for subscriber devices in different geographic locations.
The network nodes in the plurality of network nodes in cluster 106 are each configured to access shared registration data store 108 for reading and writing registration data relating to subscribers in telecommunications network 100. Shared registration data store 108 comprises registration data for a plurality of subscriber devices registered with telecommunications network 100, including subscriber device 102, and is accessible by each of the plurality of network nodes in cluster 106. Network nodes 106 are also configured to communicate with entities outside of telecommunications network 100 (i.e. entities in different telecommunications networks; not shown) via border entity 110. In the context of IMS, border entity 110 may, for example, comprise one or more of a Media Gateway Control Function (MGCF) or Interconnection Border Control Function (IBCF).
In response to receiving registration request message 2a, edge proxy 104 allocates the registration request to one of the plurality of network nodes 106, in this case network node 106a. In some embodiments, the choice of network node is made randomly by edge proxy 104. In further embodiments, the choice of network node is made according to one or more load balancing criteria in order to distribute network load across the plurality of network nodes in the cluster 106. In embodiments, the one or more load balancing criteria allow the registration request message to be handled by any of the plurality of network nodes in the cluster 106. The registration request message is then forwarded to the allocated network node 106a as registration request message 2b. Edge proxy 104 may modify the registration request message prior to forwarding it by adding identification information for edge proxy 104 to registration request message 2b. Upon receipt of registration request message 2b, network node 106a may perform an authentication procedure as shown by step 200. Such an authentication procedure may comprise contacting a subscriber configuration network node responsible for authenticating subscriber devices in telecommunications network 100. In the case of IMS, the subscriber configuration network node may, for example, comprise a Home Subscriber Server (HSS).
Having authenticated (if appropriate) the subscriber device 102, network node 106a writes the registration data from the received registration request message 2b into shared registration data store 108 at step 2c. In alternative embodiments, prior to writing the registration data into shared registration data store 108, network node 106a may first retrieve registration data for the given subscriber from the shared data store, update the retrieved registration data with the received registration data for that subscriber, and then write the updated registration data back to the shared data store.
Having written the subscriber data to the shared data store, registration confirmation (or ‘registration response’) message 2d is transmitted from network node 106a to edge proxy 104 (which may be identified by the added identification information in registration request message 2b). The registration confirmation message is then forwarded by edge proxy 104 to subscriber device 102 as registration confirmation message 2e, thereby completing the registration procedure.
In embodiments, the registration procedure is used to establish a relationship (or “binding”) between a subscriber identifier and a network address for subscriber device 102. In embodiments, the subscriber identifier comprises a SIP address. In embodiments, the network address comprises one or more of an Internet Protocol (IP) address and a port associated with the subscriber device. Routing path information may also be registered during a registration procedure if required to successfully reach subscriber device 102 (for example to traverse any intermediate network address translation (NAT) entities). The registration data comprised in registration request message 2a may, for example, comprise one or more of the subscriber identifier, the network address for subscriber device 102 and path information.
In embodiments, the subscriber device may be required to perform a periodic re-registration procedure in order to maintain its registration. In some such embodiments, the stored registration data may expire after a predetermined period of time (for example after a previous registration procedure). The re-registration procedure may, for example, comprise the same steps as the aforementioned registration procedure. In embodiments, the authentication procedure is performed during the initial registration procedure, but omitted in each subsequent re-registration procedure. In alternative embodiments, the authentication procedure is performed during both the initial registration and one or more subsequent re-registration procedures. In embodiments, since the registration information for subscriber device is stored in shared data store 108, subsequent re-registration requests relating to subscriber device 102 may be handled by any network node in the cluster of network nodes 106. In arrangements where the registration request message 2b is handled by network node 106a, a subsequent re-registration request is handled by a different network node in the cluster 106 (for example, network node 106b).
In some embodiments, multiple subscriber devices may be registered against the same subscriber identifier simultaneously. In some such embodiments, shared registration data store 108 comprises registration and/or binding information for each registered subscriber device. In some embodiments, two or more of the multiple registered subscriber devices correspond to two or more clients located on the same client device; in such embodiments, the two or more clients located on the same client device may be referred to as collocated.
Having received dialog request message 3a, network node 106b inspects the received dialog request to determine which subscriber device the dialog request relates to (in this case subscriber device 102). Network node 106b may determine one or more filter criteria to apply to the dialog request (for example, to determine whether application servers should be invoked), as shown by step 300. Determination of any such filter criteria may comprise contacting a subscriber configuration network node responsible for storing subscriber configuration data in telecommunications network 100. In the case of IMS, the subscriber configuration network node may, for example, comprise an HSS.
Having determined and/or applied any necessary filter criteria, the routing proxy queries shared registration data store 108 for registration data for subscriber device 102 via request message 3b. As a result of a previous registration procedure (for example, as described in relation to
Hence, it can be seen that by utilizing shared registration data store 108, the requirement for a longstanding association between subscriber device 102 and a given network node in the cluster of network nodes 106 is removed, and request messages may be routed to/from subscriber device 102 by any available network node in the cluster 106.
In embodiments, the retrieved registration data listing the appropriate edge proxy 104 may be out of date (for example, if the subscriber device has since disconnected form the network). In such embodiments, the edge proxy 104 may respond to dialog request message 3d by sending a request rejection message (not shown) back to network node 106b indicating that the registration information is out of date. In some such embodiments, in response to receipt of the request rejection message, network node 106b updates the registration data for subscriber device 102 in shared registration data store 108.
In embodiments, shared registration data store 108 further comprises registration data for one or more further subscriber devices associated with the subscriber of subscriber device 102. In such embodiments, registration data for each further subscriber device associated with the subscriber of subscriber device 102 is returned to network node 106b in the response message from shared data store 108. Dialog request messages may then be forwarded to each of these further subscriber devices in addition to subscriber device 102 (via the appropriate edge proxies).
In some arrangements, shared registration data store 108 comprises a clustered registration data store, wherein the data store is distributed among a number of nodes in telecommunications network 100. In embodiments, the registration data stored in shared registration data store 108 is distributed among the cluster of network nodes 106. In such embodiments, a portion of the registration data stored in shared registration data store 108 is stored in memory at two or more or each network node in the cluster of network nodes 106. In embodiments, a first portion of the registration data is stored in memory at network node 106a, and a second, different portion of the registration data is stored in memory at network node 106b.
Hence, during processing at a given network node in the cluster of network nodes 106, any registration data that may be required can be stored either locally at the given network node or remotely on a different network node in the cluster 106. Hence the aforementioned write, request and/or response messages sent to and received from shared registration data store 108 may be sent and received within the given network node, or transmitted externally from the given network node to another node in the cluster, depending on the location of the required registration data. In embodiments, the shared registration data store comprises a distributed memory system such as Memcached™, Infinispan™ or Cloudbase™.
As described in relation to
In response to receiving registration request message 5a, edge proxy 104 allocates the registration request to one of the plurality of network nodes 106, in this case network node 106a. In some embodiments, the choice of network node is made randomly by edge proxy 104. In further embodiments, the choice of network node is made according to one or more load balancing criteria in order to distribute network load across the plurality of network nodes in the cluster 106. In embodiments, the one or more load balancing criteria enable handling of the registration request message by any of the plurality of network nodes in the cluster 106. The registration request message is then forwarded to the allocated network node 106a as registration request message 5b. In embodiments, edge proxy 104 maintains a pool of TCP connections each corresponding to one of the plurality of network nodes in cluster 106, where registration request message 5b is transmitted via the TCP connection corresponding to the allocated network node 106a. In embodiments, edge proxy 104 modifies the registration request message 5b prior to forwarding it by adding identification information for edge proxy 104. Upon receipt of registration request message 5b, network node 106a is configured to perform an authentication procedure, which may, for example, comprise issuing one or more authentication challenge messages to subscriber device 102 and receiving one or more authentication responses from subscriber device 102 (not shown), depending on the authentication scheme chosen. In some embodiments, the authentication procedure comprises a SIP digest authentication. In further embodiments, the authentication comprises IMS Authentication and Key Agreement (AKA) authentication. In order to complete the authentication procedure, network node 106a requires subscriber configuration data for subscriber device 102. Network node 106a transmits a subscriber configuration data request 5c to cache 112 in relation to subscriber device 102, on the basis of information received in registration request message 5b.
In response to receipt of subscriber configuration data request 5c, cache 112 determines whether the shared cache store contains subscriber configuration data for subscriber device 102 at step 500. In the embodiments depicted in
In embodiments, the subscriber configuration data for subscriber device 102 comprises authentication data for subscriber device 102. Having received the authentication data for subscriber device 102, network node 106a can complete the authentication procedure with subscriber device 102 as described above. Having completed the authentication procedure for subscriber device 102, the registration procedure may be continued by network node 106a, for example by updating registration information for subscriber device 102 on the basis of the contents of received registration request message 5b (as described previously in relation to
Hence, subscriber configuration network node 116 need only be contacted if the required subscriber configuration data is not contained in shared cache store 114. In some embodiments, prior to transmitting subscriber configuration data retrieval response 5f, cache 112 writes the subscriber configuration data for subscriber device 102 received in subscriber configuration data retrieval response 5e into shared cache store 114, as shown by step 502. Hence, a subsequent request for subscriber configuration data for subscriber device 102 may be fulfilled without having to re-query subscriber configuration network node 116. In this manner, the number of queries to subscriber configuration network node 116 is reduced, thereby alleviating any negative impact on the performance of subscriber configuration network node 116 which may for example result from overloading of access resources to/from and/or processing capabilities of the subscriber configuration network node 116.
Whilst in the embodiments described in relation to
In embodiments, subscriber device 102 may be required to perform a periodic re-registration procedure in order to maintain its registration. In some such embodiments, the authentication procedure is not performed during re-registration procedure following an initial registration procedure in which the authentication procedure was successfully completed. In alternative embodiments, the authentication procedure is performed during both the initial registration and subsequent re-registration procedures.
In some embodiments, such as when the interface between cache 112 and subscriber configuration network node 116 is a Cx interface according to the IMS specifications, the interface between cache 112 and subscriber configuration network node 116 facilitates a registration in relation to the requested subscriber registration data. In such embodiments, after subscriber data for subscriber device 102 is retrieved from subscriber configuration network node 116 by cache 112, any updates made to the subscriber configuration data stored in subscriber configuration network node 116 are notified to cache 112 through the transmission of a notification from subscriber configuration network node 116 to cache 112. In embodiments, the notification comprises the updated subscriber configuration data for subscriber 102. In alternative embodiments, cache 112 retrieves the updated subscriber configuration data for subscriber 102 from subscriber configuration network node 116 in response to receipt of the notification. In embodiments the updated subscriber configuration data comprises one or more of subscriber profile information and one or more initial filter criteria. In embodiments, in response to receipt of the updated subscriber configuration data for subscriber 102, cache 112 stores the updated subscriber configuration data for subscriber 102 in shared cache store 114. Hence, subsequent requests for subscriber configuration data for subscriber 102 received at cache 112 return the updated subscriber configuration data for subscriber 102. In some embodiments, there is a limited period of time in which subscriber configuration network node 116 will notify cache 112 of changes made to the subscriber configuration data stored at subscriber configuration network node 116 in relation to subscriber device 102 following the retrieval of the subscriber configuration data. In embodiments, the expiry time of this time period is stored alongside the corresponding subscriber configuration data in shared cache store 114. According to embodiments, after the expiration of this registration, the corresponding subscriber configuration data in the shared cache store 114 is also expired, such that any subsequent request for that subscriber configuration data results in a new query being sent from cache 112 to subscriber configuration network node 116, and does not return the potentially outdated (i.e. expired) subscriber configuration data from shared cache store 114.
In embodiments, the subscriber configuration data retrieved from subscriber configuration network node 116 and/or stored in shared cache store 114 comprises one or more initial filter criteria (IFC). An initial filter criteria represents a subscription of a subscriber to a given application, and may, for example, define a specific application server that should be invoked in relation to communication sessions with the given subscriber device. In embodiments, the subscriber configuration data retrieved from subscriber configuration network node 116 and/or stored in shared cache store 114 comprises subscriber profile information. Subscriber profile information may for example include user related data, group lists, user service related information, user location information and/or charging information.
Having received dialog request message 6b, network node 106b inspects the received dialog request to determine which subscriber the dialog request relates to (in this case the subscriber of subscriber device 102). Network node 106c then performs a filtering procedure to determine and/or apply one or more initial filter criteria to the dialog request. In order to complete the filtering procedure, network node 106c requires subscriber configuration data for subscriber device 102. Network node 106c transmits a subscriber configuration data retrieval request 6c to cache 112 in relation to subscriber device 102, on the basis of information received in dialog request message 6b.
In response to receipt of subscriber configuration data retrieval request 6c, the cache determines whether the shared cache store contains subscriber configuration data for subscriber device 102 at step 600. In the embodiments depicted in
In embodiments, the retrieved subscriber configuration data for subscriber device 102 comprises initial filter criteria for subscriber device 102. Having received the initial filter criteria for subscriber device 102, network node 106c can complete the filtering procedure for the dialog request by applying any necessary filters and/or invoking any required application servers etc. as described above. Having completed the filtering procedure for subscriber device 102, processing of the communication session setup can be continued by network node 106c, for example through transmission of dialog request message 6e from network node 106c to border entity 110 (which may then forward the dialog request message to one or more further entities within or outside of telecommunications network 400, including the remote subscriber device).
Hence, as the required subscriber configuration data for subscriber device 102 is contained in shared cache store 114, a further query to subscriber configuration network node 116 is avoided. Whilst in the embodiments described in relation to
Having received dialog request message 7a, network node 106b inspects the received dialog request to determine which subscriber the dialog request relates to (in this case the subscriber of subscriber device 102). Network node 106b then performs a filtering procedure to determine and/or apply one or more initial filter criteria to the dialog request. In order to complete the filtering procedure, network node 106b requires subscriber configuration data for subscriber device 102. Network node 106b transmits a subscriber configuration data retrieval request 7b to cache 112 in relation to subscriber device 102, on the basis of information received in dialog request message 7a.
In response to receipt of subscriber configuration data retrieval request 7b, cache 112 determines whether the shared cache store contains subscriber configuration data for subscriber device 102 at step 700. In the embodiments depicted in
In embodiments, the subscriber configuration data for subscriber device 102 comprises initial filter criteria for subscriber device 102. Having received the initial filter criteria for subscriber device 102, network node 106b can complete the filtering procedure for the dialog request by applying any necessary filters and/or invoking any required application servers etc. as described above. Having completed the filtering procedure for subscriber device 102, processing of the communication session setup can be continued, by retrieving registration data for subscriber device 102 (for example as described previously in relation to
Again, as the required subscriber configuration data for subscriber device 102 is contained in shared cache store 114, a query to subscriber configuration network node 116 has been avoided. Whilst in the embodiments described in relation to
In embodiments, shared cache store 114 comprises a clustered cache store, wherein the subscriber configuration data comprised in shared cache store 114 is distributed among a number of nodes in telecommunications network 400. In embodiments, the subscriber configuration data stored in shared cache store 114 is distributed among the cluster of network nodes 106. In such embodiments, a portion of the subscriber configuration data stored in shared cache store 114 is stored in memory at two or more or each network node in the cluster of network nodes 106. In embodiments, a first portion of the registration data stored in memory at network node 106a, and a second, different portion of the registration data is stored in memory at network node 106b.
Hence, during processing at a given network node in the cluster of network nodes 106, any subscriber configuration data that may be required may be stored either locally at the given network node or remotely on a different network node in the cluster 106. Hence the aforementioned write, request and/or response messages sent to and received from shared cache store 114 may be sent and received within the given network node, or transmitted externally from the given network node to another node in the cluster, depending on the location of the required registration data. In embodiments, the shared registration data store comprises a key-value data store, for example Apache Cassandra™.
One or more of the aspects of the embodiments described herein with reference to the drawings comprise processes performed by one or more network nodes 106 and/or cache 112. In embodiments, the one or more network nodes 106 and/or cache 112 comprise one or more processing systems or processors configured to carry out these processes. In this regard, embodiments may be implemented at least in part by computer software stored in (non-transitory) memory and executable by the processor, or by hardware, or by a combination of tangibly stored software and hardware (and tangibly stored firmware). Embodiments also extend to computer programs, particularly computer programs on or in a carrier, adapted for putting the above described embodiments into practice. The program may be in the form of non-transitory source code, object code, or in any other non-transitory form suitable for use in the implementation of processes according to embodiments. The carrier may be any entity or device capable of carrying the program, such as a RAM, a ROM, or an optical memory device; etc.
The distributed nodes discussed in the above embodiments, such as clustered network nodes 100, the distributed shared registration data store and/or the distributed shared cache store may be distributed across a number of systems, either real physical systems or virtual machines, such as those comprised within a virtualized data center or public or private cloud. In this way the system can scale horizontally to support a large number of users. In embodiments, each network node in cluster 106 may each provide both SIP registrar and SIP routing proxy functions. In alternative embodiments, separate subsets of nodes may be provided for each of these functions, wherein both subsets are configured to access the shared registration data store. Cache 112 may similarly comprise a real physical system, a virtual machine such as those comprised within a virtualized data center or public or private cloud, or a computerized function or service component comprised within another node in the telecommunications network. Memory, as referred to in the context of shared registration data store 104 and/or the shared cache store 114 may comprise any suitable storage medium, including solid-state drives (SSD) or other semiconductor-based RAM; a ROM, for example a CD ROM or a semiconductor ROM; or a magnetic recording medium, for example a floppy disk or hard disk.
The above embodiments are to be understood as illustrative examples. Further embodiments are envisaged. For example, whilst the above embodiments have been described in the context of an IMS network, the present disclosure may be similarly applied to other telecommunications networks, in particular those utilizing the Internet Protocol (IP). It is to be understood that any feature described in relation to any one embodiment may be used alone, or in combination with other features described, and may also be used in combination with one or more features of any other of the embodiments, or any combination of any other of the embodiments. Furthermore, equivalents and modifications not described above may also be employed without departing from the scope of embodiments, which is defined in the accompanying claims.
Number | Date | Country | Kind |
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1307811.8 | Apr 2013 | GB | national |
1308078.3 | May 2013 | GB | national |
1308080.9 | May 2013 | GB | national |
1400841.1 | Jan 2014 | GB | national |
This application claims priority under 35 U.S.C. §119(a) to each of GB Patent Application No. 1307811.8, filed Apr. 30, 2013, GB Patent Application No. 1308080.9, filed May 3, 2013, GB Patent Application No. 1308078.3, filed May 3, 2013, and GB Patent Application No. 1400841.1, filed Jan. 17, 2014. This application is also a continuation-in-part of U.S. patent application Ser. No. 14/166,819, filed on Jan. 28, 2014, which claims priority under 35 U.S.C. §119(a) to each of GB Patent Application No. 1307811.8, filed Apr. 30, 2013, GB Patent Application No. 1308080.9, filed May 3, 2013, GB Patent Application No. 1308078.3, filed May 3, 2013, and GB Patent Application No. 1400841.1, filed Jan. 17, 2014. Each of the above-referenced patent applications is hereby incorporated by reference in its entirety.
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Parent | 14166819 | Jan 2014 | US |
Child | 14266662 | US |