Mobile wireless networks provide a medium for the exchange of information amongst large populations of mobile devices and various devices connected to the public switched telephone network (PSTN) and the Internet. Mobile networks, such as a wireless wide area network (WWAN), are most commonly implemented as an aggregation of a plurality of individual cells. Each cell provides infrastructure through which signals are transmitted to and from mobile transceiver devices located within a particular coverage area. When joined together, the network of cells provides coverage to a large geographic area.
As mobile transceiver devices move geographically farther away from a transceiver of a cell, they may exit the coverage area provided by that cell and enter the coverage area provided by a neighboring cell. During such movement, it is necessary to perform a cellular handover in which the mobile transceiver device ceases to use the communication infrastructure provided by one cell and begins to use the infrastructure provided by the neighboring cell.
Furthermore, in some areas where the communication infrastructure provided by a first mobile network is of poor quality or of deficient capability with respect to an alternative mobile network, a mobile transceiver device, i.e. a mobile station (MS) or user equipment (UE), can cease to use the communication infrastructure provided by the first mobile network and begin to use the infrastructure provided by the alternative mobile network.
A method, executed by a mobile station (MS) attached to a supporting wireless wide area network (WWAN), is described herein for attaching to a target WWAN while maintaining the attachment to the supporting WWAN, the method comprising transmitting, via a physical uplink channel with a radio access network (RAN) of the supporting WWAN, an attach request message addressed to a network interface of a generic access network (GAN) of the target WWAN, and receiving, from the target WWAN via a physical downlink channel with the RAN of the supporting WWAN, an attach accept message.
A method, executed by a target wireless wide area network, for attaching a mobile station currently attached to a supporting wireless wide area network is described herein, the method including receiving, from the MS via a physical uplink channel between the MS and a transceiver of a supporting WWAN, an attach request message, and establishing a service uplink channel with the MS and a service downlink channel with the MS that both include a core network gateway of the supporting WWAN.
A method, executed by a supporting wireless wide area network (WWAN) to which a mobile station (MS) is attached, for supporting attachment of the MS to a target WWAN is described herein, the method comprising receiving, from the MS at a transceiver via a physical uplink channel between the transceiver and the MS, an attach request that is addressed to an access point of a generic access network (GAN) of the target WWAN, internally forwarding, from the transceiver to a gateway of a core network of the supporting WWAN, the attach request, transmitting, from the gateway to the access point of the GAN of the target WWAN, the attach request, and supporting a resource control connection between the MS and the target WWAN, wherein supporting a resource control connection between the MS and the target WWAN includes: receiving, from the target WWAN at the gateway of the core network, one or more network transmissions that are addressed to the MS, internally forwarding, from the gateway of the core network to the transceiver, the one or more network transmissions, transmitting, from the transceiver to the MS via the physical downlink channel, the one or more network transmissions, receiving, from the MS at the transceiver via the physical uplink channel, one or more MS transmissions that are addressed to the access point of the GAN of the target WWAN, internally forwarding, from the transceiver to the gateway of the core network, the one or more MS transmissions, and transmitting, from the gateway to the access point of the GAN of the target WWAN, the one or more MS transmissions.
A mobile station configured to connect to a generic access network (GAN) of a target WWAN via a radio access network (RAN) of a supporting WWAN is described herein, the mobile station comprising a processor configured to construct an attach request addressed to a network interface of the GAN of the target WWAN, a radio frequency (RF) transceiver configured to transmit the attach request to the RAN of the supporting network via a physical uplink channel with the RAN of the supporting network and receive an attach accept message from the target WWAN via a physical downlink channel with the RAN of the supporting network, the attach accept message including a packet data network (PDN) address, and a processor readable storage medium configured to store an association relationship between an identifier of a subscription with the target WWAN and the PDN address.
A system is described herein for attaching a mobile station (MS) that is attached to a supporting wireless wide area network (WWAN) to a target WWAN, the system comprising the MS, the MS including an MS transceiver configured to: transmit an attach request and resource control connection data to a supporting WWAN transceiver via a physical uplink channel between the MS and the supporting WWAN transceiver, and receive resource control connection data from the supporting WWAN transceiver via a physical downlink channel between the MS and the supporting WWAN transceiver; the supporting WWAN, including: the supporting WWAN transceiver, configured to: receive an attach request and resource control connection data from the MS via the physical downlink channel, forward the attach request and the resource control connection data to a supporting WWAN core network, and forward resource control connection data received from the supporting WWAN core network to the MS; the supporting WWAN core network, configured to: receive an attach request and resource control connection data from the supporting WWAN transceiver, forward the attach request and the resource control connection data through a supporting WWAN gateway to an access point of a target WWAN generic access network (GAN), receive resource control connection data from the target WWAN GAN through the supporting WWAN gateway, and forward the resource control connection data received from the WWAN GAN through the supporting WWAN gateway to the supporting WWAN transceiver; and the target WWAN, including: the target WWAN GAN, having a generic access network controller (GANC) configured to: receive the attach request through the supporting WWAN gateway, forward the attach request to a target WWAN core network, transmit resource control connection data to the MS through the supporting WWAN gateway, and receive resource control connection data from the MS through the supporting WWAN gateway.
The present invention will be described in even greater detail below based on the exemplary figures. The invention is not limited to the exemplary embodiments. All features described and/or illustrated herein can be used alone or combined in different combinations in embodiments of the invention. The features and advantages of various embodiments of the present invention will become apparent by reading the following detailed description with reference to the attached drawings which illustrate the following:
Methods are described herein that facilitate attachment of a mobile station (MS) to a target wireless network through a physical connection between the MS and a separate wireless network to which the MS has previously attached. A resource control connection is established between the MS and the target network during a procedure by which the MS is attached to the target wireless network. The resource control connection includes an uplink channel between the MS and the target wireless network that includes a physical uplink channel between the MS and the supporting network (i.e. the wireless network to which the MS had previously attached). Similarly, the resource control connection includes a downlink channel between the MS and the target wireless network that includes a physical downlink channel between the MS and the supporting network.
Methods are also described herein that utilize resource control connections between an MS and a target network to establish service uplink channels that include a physical uplink channel between the MS and a supporting network and service downlink channels that include a physical downlink channel between the MS and a supporting network. The service uplink channels and service downlink channels can be utilized to provide services from the target network to the MS. The service uplink channels and service downlink channels tunnel through the supporting network.
Methods are additionally described herein that facilitate a hand over of a MS from a first cell of a target wireless network to a second cell of the target wireless network by utilizing physical uplink and downlink channels between the MS and a supporting wireless network. A handover initiation message is transmitted through either the physical uplink channel between the MS and the supporting wireless network and the physical downlink channel between the MS and the supporting wireless network. The handover initiation message is tunneled across the supporting wireless network and triggers the establishment of one or more resource control connections between the MS and the target wireless network.
Wireless networks are described herein that establish uplink and downlink channels with a mobile station by utilizing physical uplink and downlink channels between the mobile station and a separate, supporting wireless network. Wireless networks establish uplink and downlink channels with a mobile station by utilizing a resource control connection that includes a tunnel through the supporting wireless network. Wireless networks that are described herein utilize the tunneled resource control connection to establish uplink and downlink channels that include tunnels through the supporting wireless network. The tunneled resource control connections and the tunneled uplink and downlink channels tunnel through both the core network portion and the access network portion of the supporting wireless network. The tunneled resource control connection and the tunneled uplink and downlink channels include physical uplink and downlink channels between the mobile station and the access network portion of the supporting wireless network.
Wireless networks are described herein that support uplink and downlink channels between a mobile station and one or more dependent networks. Support networks allocate resources to physical uplink and downlink channels with mobile stations upon which dependent networks depend for exchanging communications with the mobile stations. Support networks allocate resources to uplink and downlink channels that tunnel through their core networks and support connectivity between mobile stations and dependent networks.
MSs are described herein that utilize physical uplink and downlink channels with a first wireless network to attach to one or more additional wireless networks and to initiate hand over procedures within those one or more additional networks. MSs connected to the first wireless network transmit attachment requests across a physical uplink channel with an access network portion of the first wireless network. The MSs thereafter establish resource control connections with the one or more additional wireless networks in order to establish service uplink channels and service downlink channels with the one or more additional wireless networks. The service uplink and service downlink channels that are established tunnel through the core network and access network of the first wireless network and that utilize the physical uplink and physical downlink channels between the MS and the first wireless network. MSs are described herein that can utilize the service uplink channels and service downlink channels with the one or more additional wireless networks to execute hand over procedures on any of the one or more additional wireless networks.
MSs are described herein that include one or more data structures that store network interface information and network subscription information for multiple wireless networks. MSs described herein can utilize the information stored in such data structures in order to maintain simultaneous attachment to multiple wireless networks through a physical connection with only a single wireless network. In this manner, MSs described herein can maintain simultaneous attachment with multiple wireless networks despite being equipped with only a single RF transceiver. MSs described herein can further utilize the information stored in such data structures to simultaneously transmit information to multiple wireless networks through a single RF transceiver and to simultaneously receive information from multiple wireless networks through a single RF transceiver.
The physical layer of the network between the MSs and BSSs of embodiments described herein can be divided into a Physical Link sublayer (PLL) and a Physical RF sublayer (RFL). The RFL performs the modulation and demodulation of the physical waveforms. The carrier frequencies, radio channel structures, and raw channel data rates are specified, as well as transmitter and receiver characteristics and performance requirements. The PLL provides services for information transfer over a physical channel between the MS and the network. These functions include data unit framing, data coding, and the detection and correction of physical medium transmission errors. In alternative embodiments, the physical layer of the network between the MSs and BSSs described herein can be divided into additional sublayers that collectively perform the operations of the physical layer. The systems and methods described herein can be implemented in a variety of environments having physical layers with a variety of different means for transmitting information.
The data link layer of the network between the MSs and BSSs of embodiments described herein can also be separated into two distinct sublayers. The Radio Link Control/Medium Access Control (RLC/MAC) sublayer arbitrates access to the shared medium between a multitude of MSs and the network. The RLC/MAC layer encompasses the efficient multiplexing of data and signaling information, and performs contention resolution, QoS control(limited), and error handling. The MAC itself can be derived from a slotted reservation ALOHA protocol, and operates between the MS and BSS. For retransmission of erroneous frames, an automatic selective repeat request (SREJ-ARQ) mechanism can be applied. In alternative embodiments, the data link layer of the network between the MSs and BSSs of embodiments described herein can be divided into further sublayers that collectively perform the operations required of the data link layer.
Similarly, in
The first WWAN 100 includes a first access network 110 and a first core network 120, while the second WWAN 200 includes the second access network 210 and a second core network 220. The first access network 110 and the second access network 210 each include a plurality of transceivers. The first access network 110 includes transceivers 112A and 112B and the second access network 210 includes transceivers 212A and 212B. The transceivers are utilized by the access networks 110 and 210 to provide physical uplink and physical downlink channels with the mobile station 300 over an air interface. The access network 110 and 210 provide for uplink and downlink channel separation, which depending on the wireless communication standard upon which the WWANs 100 and 200 are based, can be implemented according to any of time-division multiple access (TDMA), frequency-division multiple access (FDMA), code-division multiple access (CDMA), and orthogonal frequency multiple division access (OFDMA). The access networks 110 and 210 can also implement downlink channel separation according to alternative schemes for dividing of resources, e.g. physical layer resources.
The MS 300 includes a mobile termination component that supports functions that include radio transmission and handover, signaling, and access to a universal integrated circuit card (UICC). The UICC stores an international mobile subscription identifier (IMSI) and additional data. The mobile termination component has an international mobile equipment identity (IMEI) code attached to it and also has access to a subscription information data store. The subscription information data store may be located at the UICC or may be located elsewhere at the MS 300. The subscription information data store contains data structures that include values corresponding to one or more network interface identifiers of one or more wireless network interfaces, e.g. network interfaces of WWANs 100 and 200. The subscription information data store also stores values that correspond to parameters of subscriptions with one or more wireless networks, e.g. WWANs 100 and 200. In addition, the subscription information data store stores relationships between network interface identifiers. For example, the subscription information data store can store mapping relationships between particular services provided by WWANs 100 and 200 and particular network gateway identifiers.
The access network 110 and the access network 210 further include generic access network controller (GANC) 114 and the GANC 214, respectively. The GANC 114 and the GANC 214 contribute to providing generic access networks that enable the MS 300 to establish uplink and downlink channels across the Internet 400 with the first WWAN 100 and the second WWAN 200, respectively. The GANCs 114 and 214 thereby enable the MS 300 to utilize services provided by the WWANs 100 and 200 without establishing physical uplink and downlink channels across an air interface. For example, the MS 300 can utilize a Wi-Fi connection to the Internet to execute an attachment procedure to register with the WWAN 100 and the WWAN 200 through the gateways supported by the GANC 114 and the GANC 214, respectively.
The core network 120 and the core network 220 provide gateways, i.e. first core network gateway 122 and second core network gateway 222, through which transmissions may sent to and across the Internet 400 and through which transmissions may be received from the Internet 400. The core networks 120 and 220 also provide services to mobile stations that are connected to the access networks 110 and 210, respectively. The services provided by the core networks 120 and 220 include authentication, network configuration, network provisioning, service invocation, routing, addressing, data hosting, and error reporting, among others. The core networks 120 and 220 include components that receive attach requests from the MS 300 and issue service requests in response to the receipt of the attach requests. The service requests issued by the core networks 120 and 220 in response to the receipt of attach requests and handover initiation requests from the MS 300 facilitate establishment and configuration of network resources. Specifically, components of the core networks 120 and 220 issue service requests that establish the assignment of mobile stations to physical uplink channels and physical downlink channels with the access networks 110 and 210, respectively.
In various embodiments, one or both of the first WWAN 100 and the second WWAN 200 are based on one of the GSM or UMTS standards. In such embodiments, one or both of the first access network 110 and the second access network 210 are UMTS radio access networks (UTRANs), and one or both of the first core network 120 and the second core network 220 are general packet radio service (GPRS) core networks (GPRS CNs). Network infrastructure components that form a UTRAN include a Node B, which would include the transceivers 112A and 112B (if the first WWAN is based on the GSM or UMTS standards) and the transceivers 212A and 212B (if the second WWAN is based on the GSM or UMTS standards). Network infrastructure components that form a GPRS CN include a Serving GPRS support node (SGSN) and a Gateway GRPS support node (GGSN). GPRS CNs support GPRS tunneling protocol (GTP) for the transmission of packets received by UTRANs to the Internet 400 and to components of the GPRS CN. For example, if WWAN 100 is based on the GSM or UMTS standard, a transmission received by the first access network 110 from the MS 300 can be forwarded, with GTP, to a gateway to the Internet 400 located in the first core network 120. GTP includes GTP-C, which is used within the GPRS CN for signaling between GGSNs and SGSNs, GTP-U, which is used for carrying user data within the GPRS CN and between the UTRAN and the GPRS CN, and GTP', which is used to deliver charging data to a network operator's billing center.
In various embodiments of the invention, one or both of the first WWAN 100 and the second WWAN 200 are based on the LTE standard. In such embodiments, one or both of the first access network 110 and the second access network 210 are evolved UMTS radio access networks (E-UTRANs), and one or both of the first core network 120 and the second core network 220 are evolved packet cores (EPCs), i.e. system architecture evolution (SAE) cores. Network infrastructure components that form an E-UTRAN include evolved Node Bs (eNBs), which would include the transceivers 112A and 112B (if the first WWAN is based on the LTE standard) and the transceivers 212A and 212B (if the second WWAN 200 is based on the LTE standard). Network infrastructure components that form an EPC include a ymobility management entity (MME), a serving gateway (SGW), and a packet data network (PDN) gateway (PGW). EPCs support the EPC protocol stack for transmission of packets received by E-UTRANs to the Internet 400 and to various components of the EPC. The EPC protocol stack includes MME protocols, SGW protocols, and PGW protocols. The MME protocols include the S1-MME protocol stack to support S1-MME interfaces with eNBs, the S11 protocol stack to support S11 interfaces with SGWs, stream control transmission protocol (SCTP), and S1 Application Part (S1AP). SGW protocols include the S11 control plane stack to support S11 interfaces with MMEs, the S5/S8 control and data plane stacks to support S5/S8 interfaces with PGWs, the S1 data plane stack to support S1 user plane interfaces with eNBs, and the S4 data plane stack to support S4 user plane interfaces between RNCs of UMTS and SGWs of eNBs. The PGW protocols include the S5/S8 control and data plane stacks to support S5/S8 interfaces with SGWs. The integrated data plane stack for the S5/S8 interface consists of IP, UDP, and eGTP-U protocols.
In various embodiments, the first WWAN 100 may be based upon the same wireless communication standard upon which the second WWAN 200 is based, or the first WWAN 100 may be based upon a different wireless communication standard than that upon which the WWAN network 200 is based. Thus, in various embodiments, network protocols supported by the first WWAN 100 are not supported by the second WWAN 200, while in other embodiments, the network protocols supported by the first WWAN 100 are also supported by the second WWAN 200. Similarly, the first WWAN 100 and the second WWAN 200 may be operated by different service providers.
In the configuration depicted in
In the configuration depicted in FIG.1, the MS 300 has a subscription information data store at which network interface identifiers corresponding to network interfaces of the WWAN 100 are stored and associated with subscription parameters corresponding to a subscription with the WWAN 100. The subscription information data store of the MS 300 can store an MIN, an MDN, and an MSISDN assigned to the MS 300 by the WWAN 100 and a relationship between the MSISDN and various access point names (APNs) or an address of a packet data network (PDN) of the WWAN 100. For example, the subscription information data store of the MS 300 can also store a variety of parameters related to the physical uplink channel 302 and the physical downlink channel 304 and an association relationship between such parameters and an MIN, MDN, or MSISDN assigned to the MS 300 by the WWAN 100. Certain portions of the subscription information data stored at the MS 300 can be information that is received following the execution of an attachment procedure between the MS 300 and the WWAN 100.
In the configuration depicted in
In the configuration depicted in FIG.2, the MS 300 has a subscription information data store at which network interface identifiers corresponding to network interfaces of the WWAN 100 are stored and associated with subscription parameters corresponding to a subscription with the WWAN 100. Furthermore, the subscription information data store at the MS 300 contains network interface identifiers corresponding to network interfaces of the WWAN 200 and an association between such interfaces and subscription parameters corresponding to a subscription with the WWAN 200. For example, the subscription information data store of the MS 300 can store an MSISDN assigned to the MS 300 by the WWAN 200 and an association relationship between the MSISDN assigned by the WWAN 200 and a network interface parameter corresponding to the GANC 214. Furthermore, the subscription information data store of the MS 300 can store an association relationship between the MSISDN assigned to the MS 300 by the WWAN 200 and a variety of parameters related to the physical uplink channel 302 and the physical downlink channel 304.
In the configuration depicted in
In the configuration depicted in FIG.3, the MS 300 has a subscription information data store at which network interface identifiers corresponding to network interfaces of the WWANs 100 and 200 are stored and associated with subscription parameters corresponding to subscriptions between the MS 300 and the WWANs 100 and 200. For example, the subscription information data store of the MS 300 can store an MSISDN assigned to the MS 300 by the WWAN 100 and an association relationship between the MSISDN assigned by the WWAN 100 and a network interface parameter corresponding to the GANC 114. Furthermore, the subscription information data store of the MS 300 can store an association relationship between the MSISDN assigned to the MS 300 by the WWAN 100 and a variety of parameters related to the physical uplink channel 308 and the physical downlink channel 310
In the configuration depicted in FIG.1, the MS 300 has a subscription information data store at which network interface identifiers corresponding to network interfaces of the WWAN 200 are stored and associated with subscription parameters corresponding to a subscription with the WWAN 200. For example, the subscription information data store of the MS 300 can also store a variety of parameters related to the physical uplink channel 308 and the physical downlink channel 310 and an association relationship between such parameters and an MSISDN assigned to the MS 300 by the WWAN 200.
The WWANs 100 and 200 can transition from the configuration depicted in
Systems and methods are described herein that contemplate transitions between the configurations depicted in
Systems and methods described herein that contemplate transitions between various configuration depicted in
Implementations described herein that provide for an automatic return to an initial configuration under such circumstances can also provide for a subsequent automatic return to the intermediate configuration or an automatic transition to a different intermediate configuration. Implementations that include more than two wireless networks can provide for an automatic transition to an intermediate configuration in which a GAN is accessed through a different network than it was accessed during a prior initial configuration from which an automatic return to the initial configuration was executed. The duration of an interval during which an initial configuration is maintained after an automatic return from an intermediate configuration and prior to a subsequent transition back to the intermediate condition or to a different intermediate condition (e.g. a return duration) can be determined according to a specified period of time or according to the satisfaction of a condition. A return duration can be determined according to an identity of a process being executed, a number of processes being executed, and a classification of a current executing process. A return duration can also be determined according to a duration of a time interval at which one of the WWAN 100 or the WWAN 200 requires the MS 300 to periodically transmit a location update request to avoid being considered switched off or unreachable.
The WWANs 100 and 200 and the MS 300 can transition from the configuration depicted in
Depending on the configuration of the first core network 120 and the second core network 220 and the specifics of the configuration and allocation of resources for providing bearer services to the MS 300 prior to the transmission of the handover initiation requests, it may not be possible for the WWANs 100 and 200 to transition directly from the configuration depicted in
The WWANs 100 and 200 and the MS 300 can also transition from the configuration provided by
At 500, the first WWAN 100, the second WWAN 200, and the MS 300 are configured as depicted in
The attach request also includes information pertaining to characteristics of a connection to be established between the WWAN 200 and the MS 300 or information pertaining to the services to be provided by the WWAN 200 to the MS 300. If the WWAN 200 conforms to the LTE standard, the attach request provides radio resource control (RRC) parameters that include, e.g., a Selected Network that indicates a selected public land mobile network (PLMN) and a globally unique mobility management entity identifier (GUMMEI) corresponding to a prior connection between the MS 300 and the WWAN 200.
Upon receiving the attach request at 500, the GANC 214 stores data included in the request in a data structure stored at a processor readable memory of the GANC 214 and also forwards the attach request or portions thereof to one or more components of the second core network 220. The second core network 220 utilizes data included in the request or the portions forwarded by the GANC 214 in order to perform various identification procedures and to begin the attachment procedure required to register the MS 300.
At 502 and 504, the configuration of the WWANs 100 and 200 transitions to that depicted by
At 504, the core network 220 allocates resources of the WWAN 200 to the MS 300, or establishes bearers for providing bearer services to the MS 300. The allocation, or assignment, of resources of the WWAN 200 to the MS 300 includes establishing and configuring data structures stored at various components of the core network 220. For example, if the WWAN 200 conforms to the LTE standard, data structures recording an assignment of network resources to the MS 300 are located at processor readable memories of a mobility management entity (MME), a serving gateway (SGW), and a packet data network (PDN) gateway (PGW). The data structures indicate an assignment of one or more resources of the WWAN 100 to one or more identifiers of the MS 300. For example, the data structures include a bearer table that maps an MEI of the MS 300 to the first core network gateway 122. The bearer table thereby effectively maps the MEI of the MS 300 to the physical uplink channel 302 and the physical downlink channel 304. The allocation, or assignment, of resources of the WWAN 200 to the MS 300 constitutes the establishment of a service uplink channel and a service downlink channel between the WWAN 200 and the MS 300. The service uplink and service downlink channels, which include the first core network gateway 122 and the physical uplink channel 302 and the physical downlink channel 304, respectively, are tunneled through the first WWAN 100.
Once the core network 220 has allocated the resources of the WWAN 200 to the MS 300 at 504, the core network 220 may periodically perform integrity checks with the MS 300. The performance of integrity checks with the MS 300 includes transmission of an integrity check request response from the core network 220 of the WWAN 200 to the MS 300 through the WWAN 100. The MS 300 transmits an integrity check response message, or integrity verification response, addressed to the GANC 214 through the WWAN 100 in order to remain actively parked on the WWAN 200. In the event that the MS 300 repeatedly fails to respond to integrity checks, the WWAN 200 may be configured to release resources allocated to the MS 300. However, the WWAN 200 may be configured not to release, but instead maintain the assignment of, resources allocated to the MS 300. Therefore, by responding to integrity check requests from the core network 220, the MS 300 is able to remain simultaneously attached to both the WWAN 100 and to the WWAN 200.
At 506, the GANC 214 receives a handover initiation request from the MS 300 through the first core network gateway 122. The handover initiation request received by the GANC 214 at 506 passes through the first core network gateway 122 as well as an access point of a generic access network (GAN) that is a component of the WWAN 200 and that is supported by the GANC 214. The handover initiation request provides for a handover of the MS from the GAN supported by the GANC 214 to a radio access network (RAN) that includes the transceiver 212A. The RAN that includes the transceiver is a component of the WWAN 200. The handover initiation request received at 506 includes a variety of information. The information included in the handover initiation request received at 506 includes a variety of information pertaining to the current location of the MS 300 and may further include the types of information that were included in the attach request received at 500.
At 508, the GANC 214 forwards the handover initiation request to various components of the core network 220 in order to facilitate the establishment and configuration of bearers for providing bearer services to the MS 300 through the RAN that includes the transceiver 212A. At 510, the core network 220 allocates resources of the WWAN 200, including the physical uplink channel 308 and the physical downlink channel 310 (or divisions thereof) to the MS 300 and further establishes and configures data structures stored at various components of the core network 220 in order to support service provision to the MS 300 via the transceiver 212A. For example, if the WWAN 200 conforms to the LTE standard, data structures recording an assignment of the MS 300 to network resources that include the physical uplink channel 308 and the physical downlink channel 310 are located at processor readable memories of a mobility management entity (MME), a serving gateway (SGW), and a packet data network (PDN) gateway (PGW).
At 510, the WWAN 200 transmits an indication that the handover has completed to the MS 300 via the physical downlink channel 310. At 512, the WWAN receives a transmission from the MS 300 via the physical uplink channel 308 that is addressed to the GANC 114 of the first WWAN 100. The transmission received by the WWAN at 512 can be, in different implementations, an attach request or a data transmission for facilitating a handover of the MS from the RAN that includes the transceiver 112A to the GAN that is supported by the GANC 114. The transmissions sent at 508, 510, and 512, and the operations of service requests included therein, result in the WWANs 100 and 200 assuming the configuration depicted in
At 600, the access network 110 of the WWAN 100 receives an attach request addressed to an access point of a GAN supported by the GANC 214 of the WWAN 200 from the MS 300 via the physical uplink channel 302 between the MS 300 and the transceiver 112A.
At 602, the first access network 110 forwards the attach request to the first core network 120. For example, if the WWAN 100 adheres to the LTE standard, the first access network 110 is an E-UTRAN that utilizes the EPC protocol stack to transmit the attach request through the EPC that is the first core network.
At 604, the first core network 120 forwards the attach request through the first core network gateway 122 to the GANC 214 via the Internet 400. At 606, the WWAN 100 receives a transmission addressed to the MS 300 from the GANC 214 through the first core network gateway 122 and supports a procedure to attach the MS 300 to the WWAN 200. Specifically, at 604 the WWAN 100 supports a resource control connection between the MS 300 and the second core network 220 by providing a tunnel between the core network gateway 122 and the transceiver 112A through which the second core network 220 can transmit data transmissions to and receive data transmissions from the MS 300 in order to provide various services, such as authentication, identification, verification, and protocol configuration, to the MS 300.
At 608, the WWAN 100 supports a service uplink channel and a service downlink channel between the MS 300 and the WWAN 200. Specifically, at 608, the WWAN 100 receives transmissions addressed to the MS 300 at the first core network gateway 122 and provides tunnels between the first core network gateway 122 and the transceiver 112A through which the WWAN 200 and the MS 300 exchange service transmissions.
At 610, the first access network 110 receives a handover initiation request addressed to the WWAN 200 from the MS 300 via the physical uplink channel 302 between the MS 300 and the transceiver 112A. At 612, the first access network 110 forwards the handover initiation request received at 610 to the first core network 120. At 614, the first core network 120 forwards the handover initiation request to the GANC 214.
At 616, the access network 110 receives a request to initiate a procedure for a handover of the MS 300 from a source access point of the WWAN 100 to a target access point of the WWAN 100. Specifically, the access network receives a request to reassign the MS 300 from the RAN that includes the transceiver 112A (the source access point) to an access point of a GAN supported by the GANC 114 (the target access point). At 618, the WWAN 100 establishes and configures bearers for providing services to the MS 300 through the GAN supported by the GANC 114. In alternative implementations, the WWAN 100 may not receive the request to initiate a procedure for a handover of the MS 300 at 616 but may instead receive an attach request from the MS 300 at the GANC 114 via the second core network gateway 222. Thereafter, the first core network 120 initiates a procedure to attach the MS 300 through the second core network gateway 222.
At 700, the MS 300, the first WWAN 100, and the second WWAN 200 are configured as depicted in
Additionally, the attach request can include a routing area identification (RAI) and various EPS security parameters. In some implementations, the EPS security parameters and other information received from the MS 300 by the WWAN 200 during the attachment procedure may not be included in the initial attach request message transmitted by the MS 300 to the WWAN 200. Instead, such additional information may be transmitted by the MS 300 in response to one or more replies to the attach request issued by the WWAN 200.
At 702 through 706, the configuration of the MS 300 and the WWANs 100 and 200 transitions to that depicted by
At 704, the MS 300 receives an attach accept message from the WWAN 200 via the first core network gateway 122. The attach accept message received by the MS 300 can include a variety of information corresponding to the bearers created by the WWAN 200 for providing bearer services to the MS 300. For example, if the WWAN 200 conforms to the LTE standard, the attach accept message may include data pertaining to one or more resources of the WWAN 200 that have been allocated by the WWAN 200 for providing services to the MS 300. The attach accept message received by the MS 300 at 704 can include one or more access point names (APNs) that correspond to various elements of the WWAN 200 that are used in the provision of bearer services to the MS 300. For example, the attach accept message received by the MS 300 at 704 can include an address of the GUTI 214 and addresses of one or more components of the second core network 220.
At 706, the MS 300 stores association relationships between various identifiers corresponding to a subscription with the WWAN 200 and various network interfaces corresponding to service uplink and service downlink channels identified for the provision of services to the MS 300 by the WWAN 200. For example, the MS 300 can store one or more identifiers of a subscription with the WWAN 200, e.g. an IMSI, an IMEI, and an MSISDN, one or more identifiers of a network gateways and interfaces utilized for communications supported by the WWAN 200. At 706, the MS 300 may store an association relationship between subscription identifiers that include an IMSI, an IMEI, and an MSISDN and network interface parameters that include identifiers for physical uplink channel 302, physical downlink channel 304, first network gateway 122, and GANC 214.
Upon completion of 706 but prior to the performance of 708, the MS 300 may periodically verify integrity checks requested by the WWAN 200. The verification of integrity checks requested by the WWAN 200 includes transmission of integrity verifications to the core network 220 of the WWAN 200 in response to integrity check requests received from the WWAN 200. In some implementations, the integrity verifications can be pushed to the WWAN 200 by the MS 300, i.e. the integrity verifications may not be responsive to a request from the WWAN 200. For example, the MS 300 can be configured to automatically send integrity verification transmissions to the WWAN 200. In the configuration of the WWANs 100 and 200 and the MS 300 contemplated upon completion of 706, the MS 300 transmits the integrity verifications to the core network 220 via the physical uplink channel 302. Verifying connection integrity by replying to integrity check requests transmitted by the WWAN 200 to the MS 300 via the physical downlink channel 304 allows the MS 300 to ensure that the WWAN 200 continues to dedicate resources to the provision of services to the MS 300. This ensures that the MS 300 can rapidly execute a handover to a radio access network of the WWAN 200 from a state in which the MS 300 is currently connected to a radio access network of the WWAN 100. In other words, responding to integrity checks issued by the WWAN 200 allows the transition from the configuration from that depicted in
At 708, the MS 300 transmits a handover initiation request to the GANC 214 through the first core network gateway 122. The handover initiation request transmitted by the MS 300 at 708 passes through the first core network gateway 122 as well as an access point of a generic access network (GAN) that is a component of the WWAN 200 and that is supported by the GANC 214. The handover initiation request provides for a handover of the MS 300 from the GAN supported by the GANC 214 to a radio access network (RAN) that includes the transceiver 212A. The RAN that includes the transceiver is a component of the WWAN 200. The handover initiation request transmitted by the MS 300 at 708 includes a variety of information. The information included in the handover initiation request received at 708 includes a variety of information pertaining to the current location of the MS 300 and signal strengths of one or more RANs of the WWAN 200 (including a signal strength of the RAN that includes the transceiver 212A) as measured by the MS 300. Furthermore, one or more identifiers/parameters that were included in the attach request transmitted by the MS 300 at 700 can also be included in the handover initiation request.
At 710, the MS 300 transmits a handover initiation request to the WWAN 100 via the physical uplink channel 302 in which the MS requests to be handed over from the radio access network supporting the physical uplink channel 302 and the physical downlink channel 304 to a GAN supported by the GANC 114. The handover initiation request transmitted by the MS 300 at 710 causes the WWAN 100 to execute a handover preparation procedure in which data pertaining to a subscription between the MS 300 and WWAN 100 is transmitted from network components that support the RAN connection with the MS 300 to the network components that will be utilized to support the GAN connection with the MS 300.
At 712, the MS 300 receives a handover confirming transmission from the RAN of the WWAN 200 via the physical downlink channel 310. The handover confirming transmission received at 712 can indicate various network interfaces used to provide services to the MS 300 via the RAN of the WWAN 200 subsequent to the handover. At 714, the MS 300 updates a subscription information data structure storing identifiers for a subscription with the WWAN 200 and network interfaces of the WWAN 200. For example, the MS 300 can store an association relationship between subscription identifiers that include an IMSI, an IMEI, and an MSISDN and network interface parameters that include identifiers for physical uplink channel 308 and physical downlink channel 310.
At 716, the MS 300 receives a handover confirming transmission from the GAN supported by the GANC 114 via the second core network gateway 222. The handover confirming transmission received at 716 can indicate various network interfaces used to provide services to the MS 300 via the GAN of the WWAN 100 subsequent to the handover. At 718, the MS 300 stores association relationships between various identifiers corresponding to a subscription with the WWAN 100 and various network interfaces corresponding to service uplink and service downlink channels identified for the provision of services to the MS 300 by the WWAN 100. For example, the MS 300 can store an association relationship between subscription identifiers that include an IMSI, an IMEI, and an MSISDN assigned by WWAN 100 and network interface parameters that include identifiers for the GANC 114, the second network gateway 222, the physical uplink channel 308, and the physical downlink channel 310.
In various implementations, the execution of the procedures referenced at 710 through 718 may not occur in the sequence in which they are presented herein. Instead, the sequence by which the procedures identified in 710 through 718 may be dictated by the ability of the MS 300 to remain attached to the WWAN 100 during the execution of the handover from the GAN supported by the GANC 214 to the RAN of the WWAN 200 that supports the physical uplink channel 308 and the physical downlink channel 310. In some implementations, the MS 300 may become detached from the WWAN 100 during the execution of the handover within the WWAN 200 and a subsequent reattachment procedure to the first WWAN 100 via the GANC 114 may be required.
While the invention has been illustrated and described in detail in the drawings and foregoing description, such illustration and description are to be considered illustrative or exemplary and not restrictive. It will be understood that changes and modifications may be made by those of ordinary skill within the scope of the following claims. In particular, the present invention covers further embodiments with any combination of features from different embodiments described above and below.
The terms used in the claims should be construed to have the broadest reasonable interpretation consistent with the foregoing description. For example, the use of the article “a” or “the” in introducing an element should not be interpreted as being exclusive of a plurality of elements. Likewise, the recitation of “or” should be interpreted as being inclusive, such that the recitation of “A or B” is not exclusive of “A and B,” unless it is clear from the context or the foregoing description that only one of A and B is intended. Further, the recitation of “at least one of A, B and C” should be interpreted as one or more of a group of elements consisting of A, B and C, and should not be interpreted as requiring at least one of each of the listed elements A, B and C, regardless of whether A, B and C are related as categories or otherwise. Moreover, the recitation of “A, B and/or C” or “at least one of A, B or C” should be interpreted as including any singular entity from the listed elements, e.g., A, any subset from the listed elements, e.g., A and B, or the entire list of elements A, B and C.
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