巴西专利BR112012006121A2 method and apparatus for multicast mobility

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METHOD AND APPLIANCE FOR MULTIDIFUSION MOBILITY.A method and apparatus for a protocol are providedmobile internet via proxy (PMlP - Proxy Mobile Internet Protocol) support a dedicated local multicast mobility anchor (LMA - Local Mobility Anchor) and a mobile access portal (MAG - Mobile Access Gateway). The LMA assigns aInternet Protocol (IP) for a wireless transmission and reception unit (WTRU - Wireless Transmit Receive Unit), which processes the IP address and sends a routing request message to a server MAG. The WTRU isconfigured to receive a first IP address which is for multicast services, and a second IP address which is for multicast services. In general, the method and apparatus propose an architecture, interfaces and procedures to allow multicast mobility using a mobile proxy (proxy) IP. More specifically, the operations of aggregated PMIP tunnels for multicast services are described. Multicast mobility is enabled when mobile nodes move from one MAG to another MAG, intra-LMA, and inter-LMA. And, multicast mobility is enabled between the bidirectional network and the downlink-only multicast network in a hybrid network.
公开号:BR112012006121A2
申请号:R112012006121-6
申请日:2010-09-17
公开日:2020-08-11
发明作者:Guang Lu；Shamim Akbar Rahman；Juan Carlos Zunga；Michelle Perras；Catherine M. Livet
申请人:Interdigital Patent Holdings, Inc；
IPC主号:

专利说明:

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I b. · E g Method and apparatus for multicast mobility.
CROSS REFERENCE WITH PATENT APPLICATIONS y 4 ~ W · e
RELATED This claim claims the benefit of Provisional Order 5 Serial No. US, 61 / 243,810 filed on September 18, 2009, and Provisional Order No. Serial US 61 / 315,459 filed on March 19, 2010, all being here incorporated as a reference in their entirety, as stated herein. FIELD OF THE INVENTION "This order is related to the field of mobile communications 10,
BACKGROUND OF THE INVENTION The existing multicast networks (multicast) with only down / ink »(link or data download connection), such as Digital Video Broadcasting (DVB - Digital Video Bmadcasting), or only with link (l / nk) ) direct media (MediaFLO - Media Forward Link On / y), and the like, have significant limitations. The network coverage is generally regional, and therefore a wireless transmission and reception unit (WTRU - Wireless Transmit Receive Un / t), or a mobile node, loses access to the multicast service when the WTRU moves beyond the coverage area - While a WTRU may be able to re-subscribe and receive the service - 20 via a two-way communication network, all session continuity is lost. In existing mobile bidirectional communication networks (such as the third generation partnership program [3GPP - Third Generation Partnership Progran), ncj multimedia broadcasting and multicast service 25 (MBMS - Mu / timedia Broadcast Mu / ticast Service), and so on], mobility is only addressed within each respective standard. Mobility between technologies also does not support multicast services. In existing hybrid networks, such as bidirectional and overlapping down / ink only networks, mobility can be supported at the application level with the open mobile association digital mobile broadcasting enabler (OMA BCAST - Open Mobi / e A // / ance Digital Mobi / and Broadcast Enab / er). These types of hybrid networks typically use a pause-before-to-do service, which often results in long service interruptions. Figure 1 illustrates the architecture of a mobile internet protocol 35 domain via proxy (lP) v6 (PMlPv6 - F'roxy Mobi / and Internet Protoco /) - PMlP was introduced for network-based mobility management. The central functional entities in the network based localized mobility management infrastructure (NETLMM - Network based Loca / ized Mob // ity Management)
3 are an Iocal mobility anchor (LMA - Local Mobi7ity Anchor) and an access portal. mobile (MAG - Mobi / e Access Gateway) 106. There are perhaps multiple mobility anchors f.
local (LMAs) 102 in a PMlPv6 domain, each serving a different group of WTRUS. LMA 102 is responsible for maintaining the accessibility status of WTRU 108 5 and is the topological anchoring point for local network prefixes (HNP - Home Network Prehk) of WTRU 108. MAG 106 is the entity that performs mobility management on behalf of WTRU 108, and resides on the link where the WTRU 108 is anchored. MAG 106 is responsible for detecting the movement of WTRU 108 to, and from, the access link, and for starting the connection registration with LMA 102 of 10 WTRU 108. WTRU 108 can be an IPv4 only node , a lPv6 node only, or a double stacking node- The WTRU LAN prefix (VVTRU-HNP) 110 is a prefix assigned to the link between WTRU 108 and MAG 106. More than one prefix can be assigned to the link between WTRU 108 and MAG 106. The address in charge of proxy 15 (Proxy-CoA - Proxy Care-Of Address) 112 is the global address configured on the exit interface of MAG 106, and is the end point of transport of the tunnel between LMA 102 and MAG
106. The LMA address (LMAA - LMA Address) 114 is the global address that is configured on the LMA 102 interface, and is the end point of transport for the bidirectional tunnel established between the 102 LMA and the MAG 106. The IPv4 / lPv6 104 refers to the network where, 20 the mobility management of a WTRU 108 is done using PMIPv4 / PMIPv6. PMIPv4 / PMIPv6 104 includes LMAS 102 and MAG 106, among which the associated security can be defined, and authorization to send proxy binding updates (proxy) on behalf of WTRUS 108 can be ensured. These types of existing Layer 3 mobility protocols 25, for example, PMlP, Session Initiation Protocol (SlP), and the like] are designed for unicast (unicast) traffic. They are not supported for multicast services. In addition, current multicast protocols, such as the Internet Group Management Protocol (IGMP - Internet Group Management Pmtocol) or Multicast Listener Discovery (MLD - Mu / ticast 30 Listener Discovery), need to be strengthened to reduce the inherent latency to reestablish multicast services after the handover. Thus, a method and apparatus is desired to allow greater mobility for existing and under development multicast services, such as those for multicast multimedia [eg mobile TV, radio, presence, micro-35 b / ogging (publication short messages), file sharing, podcast (publishing digital media files), social networks, and the like].
SUMMARY OF THE INVENTION A method and apparatus are provided for a PMIP
·. support a dedicated multicast LMA, including an option for a first LMA to assign an IP address to a subscribed WTRU for both "" unidifusion and mulfidifusion services; a WTRU that processes a received IP address and that sends a routing request message to a MAG server; and a MAG server that triggers a proxy binding update (PBU - Proxy Binding Update) message for the first LMA. In another option, a method implemented in a WTRU includes a receiver configured to receive two sets of IP addresses, where one set of IP addresses is for unicast services and the other set of 10 IP addresses is for multicast services ; a processor configured to use a set of IP addresses for the broadcast services and q another set of addresses from [ for the broadcast services: and a transmitter configured to * transmit a routing request message to a server MAG, triggering two PBU messages, one from the MAG server to the 15 multicast LMA, and one from the MAG server to the multicast LMA. In general, the proposed method and device include an architecture, an interface and procedures to allow mobility of multicast using IP Mobile via Attorney. More specifically, several solutions are described in the following areas. The operations of aggregated PMlP tunnels for services, 20 of multicast, are described. A new architecture is introduced to have a dedicated LMA as a multicast anchor, and a new PMIP procedure for assigning IP addresses, MAG features and for WTRU profile- Multicast mobility that is enabled when mobile nodes move from one MAG to another MAG, intra-LMA and inter-LMA, and MLD / IGMP improvements are described to reduce latency in resuming multicast services. And, multicast mobility is enabled between the bidirectional network and the down / ink only multicast network, in a hybrid network.
BRIEF DESCRIPTION OF THE DRAWINGS A more detailed understanding can be obtained from the following description given, by way of example, together with the accompanying drawings, in which: - Figure 1 illustrates a mobile lPv6 domain architecture via proxy ( proxy); - Figure 2A is a diagram of an exemplary communication system in which one or more of the described forms of incorporation can be implemented; 35 - Figure 2B is a block diagram of an exemplary wireless transmission and reception unit (WTRU) that can be used within the communications system illustrated in figure 2A: - Figure 2C is a block diagram of a network exemplary radio access in · from an exemplary central network that can be used within the communications system illustrated in figure 2A; - - Figure 2D is an exemplary block diagram comprising components of a multicast mobility network; 5 - Figure 3 shows an architecture of a PMlP multi-tunnel tunnel aggregation; - Figure 4 illustrates a dedicated multicast LMA architecture; - Figures 5A and 5B show a flow chart of the dedicated multicast services, according to what is illustrated in figure 4; - Figure 6 shows the PMlP 10 intra-LMA multicast mobility enabling architecture; - Figures 7A and 7B show a communication between network entities for iMra-LMA multicast mobility, according to d which is illustrated in figure 6; ~ - Figure 8 shows the inter-LMA PMlP multicast mobility enabling architecture; and 15 - Figure 9 shows the multicast mobility architecture in a hybrid network.
DETAILED DESCRIPTION When mentioned hereinafter, the terminology "wireless transmission / reception unit (WTRU)" includes, but is not limited to, one. user equipment (UE - Us'er Equipment), a mobile station, a unit, 20 fixed or mobile subscriber, a pager, a cell phone, a personal digital assistant (PDA), a computer , a mobile node (MN - Mobile Node), or any other type of device capable of operating in a wireless environment. When mentioned hereinafter, the terminology "base station" inc | Lli, but not limited to, a node B, an internet site controller, an access point (AP - Access 25 Point), an evolved NODE B (eNB - Evo / ved Node B), a router, a portal, or any other type of device interface capable of operating in a wireless environment. The methods and apparatus described here increase the mobility of layer 3 for PMlP, and can be applied to different access technologies, regardless of the connection layer or the physical layer. 30 single and multicast can be used for transmissions. However, using multicast in the lower layers, together with multicast mobility support in the L3 layer, can increase the overall efficiency of the system. The forms of incorporation presented here allow the advantages of multicast transmissions in the lower layers. For example, MBMS can be used in long-term evolution (LTE - Long 35 Term Evo / ution), in a physical multicast channel (PMCH - Physical Mu / ticast Channel), in a multicast control channel (MCCH - Mu // icast Control Channel), and a multicast traffic channel (MTCH - Mu / ticast Tra / tic Channef) can be used to transport the multicast data.
~ Figure 2A is a diagram of an exemplary communications system 200 in which one or more of the disclosed embodiments can be "implemented. Communications system 200 can be a multiple access system providing content, such as voice, data, video, messaging, broadcasting, 5 etc. for multiple wireless users The communications system 200 can allow multiple wireless users to access this content by sharing system resources, including wireless bandwidth. For example, the communication system 200 may employ one or more methods for channel access, such as code division multiple access (CDMA - Code Division Multip / e Acess), multiple access per time division (TDMA - Time Division Mu / tip / e Access), multiple access by frequency division (FDMA - Frequency Div / s / on Mu / tip / e Access), orthogonal FDMA (OFDMA - Orthogonal FDMA), single carrier FDMA (SC-FDMA - Sing / and Camer
N FDMA), and so on. As shown in fig. 2A, the communications system 15 200 may include wireless transmit / receive unity (WTRUs) 108a, 108b, 108C and 108d, a radio access network (RAN - Radio Access Network) 204, a central network 206, a network public switched telephone network (PSTN - Pub / ic Switcbed Te / ephone Network) 208, the internet 210, and other networks 212, although it is appreciated that the forms of disclosure included any number of WTRUS, base stations,. 20 networks, and / or network elements, Each of the WTRUS 108a, 108b, 108C, 108d can be any type of device configured to operate and / or communicate in a wireless environment. For example, VVTRUs 108a, 108b, 108c, 108d can be configured to transmit and / or receive signals, wirelessly, and can include user equipment (UE), mobile station, fixed or mobile subscriber unit , a pager 25, a cell phone, a personal digital assistant (PDA), a smart phone (smartphone), a laptop or netbook, a personal computer, a wireless sensor, electronic devices and the like. Communications system 200 may also include a base station 214a and a base station 214b. Each of the base stations 214a, 214b 30 can be any type of device configured to be a non-fic interface with at least one of the WTRUS 108a, 108b, 108C, 108d, to facilitate access to one or more communication networks, such as the central network 206, the internet 210, and / or the networks 212. For example, base stations 214a, 214b can be a transceiver station
W base (BTS - Base Transceiver Station), a B node, an e-Node B, a Node B base, an e-Node B 35 base, a site controller, an access point (AP - Access Po / nt) , a wireless router, and so on. Although base stations 214a, 214b are each described as a single element, it should be appreciated that base stations 214a, 214b can include any number of interconnected base stations and / or network elements.
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The base station 214a may be part of RAN 204, which may also include other base stations and / or network elements (not shown), such as "a base station controller (BSC - Base Station Contro / ler), a radio network (RNC - Radio Network Contro // er), relay nodes, etc. The base station 214a 5 and / or the base station 214b can be configured to transmit and / or receive signals wirelessly within a region in particular, which can be referred to as a cell (not shown) .The cell can further be divided into cell sectors.
For example, the cell associated with base station 214a can be divided into three sectors.
Thus, in an embodiment, the base station 214a can include three 10 transceivers, that is, one for each cell sector.
In another form of incorporation, the base station 214a can employ multiple input, multiple output (MIMO - Mu / tiple lnput, Multip / e Output) technology and, therefore, can use multiple transceivers for each. cell sector.
Base stations 214a, 214b can communicate with one or more WTRUS 108a, 108b, 108C, 108d over an air interface 216, which can be any appropriate wireless communication link [e.g. via radio frequency ( RF), microwave, infrared light (IR - lnfra Red), utravioteta (UV), visible light, etc.]. The interface via air 216 can be established using any suitable radio access technology (RAT - Radio Access Techno / ogy). 20 More specifically, as noted above, the - system. communications 200 may be a multiple access system and may employ one or more access channel schemes, such as CDMA, TDMA, FDMA, OFDMA, SC-FDMA and the like.
For example, base station 214a on RAN 204 and WTRUS 108a, 108b, 108C can implement radio technology, such as terrestrial radio access 25 (UTRA - UMTS Terrestrial Radio Access) from a universal mobile telecommunications system (UMTS) - Universal Mobi / e Te / ecommunications System). which can establish the interface via air 216 using broadband CDMA (WCDMA - Wideband CDMA). WCDMA can include communication protocols, such as high speed packet access (HSPA) and / or HSPA evuido (HSPA + - Evo / ved 30 HSPA), HSPA can include data download packet access high speed (HSDPA - H / gh Speed Down / ink Packet Access) and / or high speed data load packet access (HSUPA - High Speed Uplink Packet Access). In another form of incorporation, base station 214a and WTRUs 108a, 108b, 108C can implement radio technology, such as Evolved UMTS Terrestrial Radio Access (E-UTRA), which can establish the interface via air 216 using long term evolution (LTE - Long Term Evo / ution) and / or advanced LTE (LTE-A - LTE-AdvanceQ In other forms of incorporation, the base station 214a and we "the WTRUS 108a, 108b, 108C can implement radio technologies, such as IEEE
802.'16 jisto é, Worldwide Interoperability for Microwave Access (WÍMAX - Wor / dwide / nteroperabi / ity for Microwave Access)], CDMA2000, CDMA2000 1X,
P CDMA2000 EV-DO, interim standard 2000 (lS-2000 - lnten'm Standard 2000), interim standard 5 (lS-95 - lnten'm Standard 95), interim standard 856 (lS-856 - lnterim Standard 856), global system for mobile communications (GSM - Gbbal System for Mobi / e), advanced data rates for GSN evolution (EDGE - Enhanced Data rates for GSM Evo / ution), GSM EDGE (GERAN), and so on. Base station 214b in fig. 2A can be a wireless 10 router, a base NODE B, an e-Node B base, or an access point, for example, and can use any suitable RAT to facilitate wireless connectivity in a localized area, such as in a workplace, at home, in a vehicle, on a campus, and so on. In one form of incorporation, the base station 214b and WTRUS 108C, 108d can implement radio technology, such as IEEE 802.11, to establish a wireless local area network (VVLAN - Wireless Local Area Netwõrk) - In another form of incorporation, base station 214b and WTRUs 108c, 108d can implement radio teenology, such as IEEE 802.15, to establish a wireless personal area network (WPAN - Wire / ess Personal Area Network). In yet another form of incorporation, the base station 214b and the WTRUS 108C, 108d, can use a RAT. 20 cell based (for example, WCDMA, CDMA2000, GSM, LTE, LTE-A, etc.) for. establish a picocell or a femtocell, As shown in fig. 2A, the base station 214b may have a direct connection to the internet 210. Thus, the base station 214b may not be necessary for access to the internet 210 via the central network 206. RAN 204 may be in communication with the central network 25 206, which can be any type of network configured to provide voice, data, application and / or voice over internet protocol (volp - Voice over internet protocol) services for one or more WTRUs 108a, 108b, 108C, 108d . For example, the central network 206 can provide call control, billing services, mobile location-based services, prepaid calls, internet connectivity, addiction distribution, etc., and / or perform high-level functions. security, such as user authentication. Although not shown in fig. 2A, it should be appreciated that RAN 204 and / or central network 206 may be in direct or indirect communication with other RANS that employ the same RAT, such as RAN 204, or a different RAT. For example, . in addition to being connected to RAN 204, which may be using 35 E-UTRA radio technology, central network 206 may also be in communication with another RAN (not shown). employing GSM radio technology. Central network 206 can also serve as a portal for WTRUS 108a, 108b, 108C, 108d, for access to PSTN 208, internet 210 and / or others
F 8/24 'e.% - 212 networks. The PSTN 208 may include telephone networks with circuit switching, which provide Kaditional telephone service (POTS - P / ain O / d Te / ephone Service). The Internet "210 may include a global system of computer networks and interconnected devices that use common communication protocols, such as the Transmission Control Protocol (TCP), the user data diagram protocol ( UDP - User Datagram Protocol) and the Internet Protocol (lP - Internet Protocol) in the TCP / IP Internet Protocol Package. 212 networks can include wired or wireless communication networks, being owned by, and / or operated by, other service providers, for example, networks 212 may include 10 another central network) connected to one or more RANs, which may employ the same RAT as RAN 204 or a different RAT.
B Some or all of the WTRUS 108a, 108b, 108C, 108d in communications system 200 may include multi-mode capabilities, that is, WTRUs 108a, 108b, 108c, 108d may include multiple transceivers for communication with 15 different wireless networks over different wireless links. For example, the WTRU 108c shown in fig. 2A can be configured to communicate with base station 214a, which can employ cellular based radio technology, and with base station 214b, which can employ IEEE 802 radio technology. FIG. 2B is an example diagram of an Á 20 system and a WTRU 108. As shown in fig. 2B, WTRU 108 may include a processor. a transmit / receive element 222, a speaker / 218, a transceiver 220,
F microphone 224, keyboard 226, display / touch screen 228, non-removable memory 206, removable memory 232, power supply 234, chipset (chip set) of a global positioning system (GPS - G / oba / Positioning System) 25 236, and other peripherals 238. It should be appreciated that WTRU 108 can include any subcombination of the elements mentioned, while remaining consistent with a form of incorporation. The 218 processor may be a general purpose processor, a special purpose processor, a conventional processor, a digital signal processor (DSP - Digital Signa / Processor), a plurality of microprocessors, one or more microprocessors in association with a DSP central, a controller, a microconfroller, integrated circuits of specific application (ASlCs - App / ication Specific lntegrated Circuits), circuits with programmable field gate arrangement (FPGA - F / eld Programmab / and Gate Array), any other type of integrated circuit (Cl), a 35 state machine, and so on. The 218 processor can reassign signal encoding, data processing, power control, input / output processing, and / or any other functionality that allows the WTRU 108 to operate in a wireless environment. The processor 218 can be coupled to the transceiver 220, which can be coupled to the transmit / receive element 222. While fig. 2B illustrates processor 218 and transceiver 220 as separate components, it should be appreciated that processor 218 and transceiver 220 can be integrated together in an electronic package or as a chjo. The transmit / receive element 222 can be configured to transmit signals to, or receive signals from, a base station (for example, the base station 214a) over the interface via air 216. For example, in an embodiment, the transmitting / receiving element 222 may be an antenna configured to transmit and / or receive RF signals. In another form of embodiment, the transmitting / receiving element 222 may be a transmitter / detector configured to transmit and / or receive signals of IR, UV or visible light, for example. In yet another
In form of incorporation, the transmitting / receiving element 222 can be configured to transmit and receive both RF and light signals. It will be appreciated that the transmit / receive element 222 can be configured to transmit and / or receive any combination of wireless signals. Furthermore, although the transmitting / receiving element 222 is shown in fig. 2B as a single element, WTRU 108 can include any number of transmit / receive elements 222. More specifically, WTRU 108 can employ MIMO technology. Thus, in a form of incorporation, the
Õ .. 20 WTRU 108 can include two or more transmit / receive elements 222 (eg, multiple antennas) for transmitting and receiving wireless signals over the interface via air 216. Transceiver 220 can be configured to modulate the signals that are transmitted by the transmit / receive element 222, and to demodulate the signals that are received by the transmit / receive element 222. As seen above, WTRU 108 can have multi-mode capabilities. Thus, transceiver 220 may include multiple transceivers, to allow wrRU 108 to communicate through multiple RATS, such as UTRA and IEEE 802.11, for example. Processor 218 from WTRU 108 can be coupled to, and 30 can receive user input data from, speaker / microphone 224, keyboard 226 and / or display / touch screen 228 [for example, a display unit of the type "crystal display | Liquid (LCD - Liquid C / j / Stà / Display) or organic light emitting diode (OLED - Organic Light Emitting Diode)]. The 218 processor can also output user data to the speaker / microphone 224, for the keyboard 226 and / or 35 for the display / touch screen 228. In addition, the processor 218 can access information from, and store data in, any type of suitable memory, such as such as non-removable memory | 206 and / or removable memory 232. Non-removable memory 206 may include a random access memory (RAM)
- Memory), a read-only memory (ROM - Read On / y Memo / y), a hard disk, or any other type of memory storage device. The "removable memory 232 can include a subscriber identity module card (SIM - Subscriber ldentity Modu / e). A memory card, a secure digital memory card 5 (SD - Secure Digital), and so on. In other forms of incorporation, processor 218 can access information from, and store data in, a memory q | je not physically located on WTRU 108, such as on a server or on a home computer (not shown). 218 can receive power from power supply 234, and can be configured to distribute and / or control power to the other components in WTRU 108. Power supply 234 can be any
In a device suitable for powering WTRU 108, For example, power supply 234 may include one or more dry batteries [for example, nickel-cadmium (NiCd), nickel-zinc (NiZn), nickel metal hydride (N1MH) , ion ions (Li-ion), etc.-], 15 solar cells, fuel cells, and the like. The 218 processor can also be coupled with the GPS 236 chipset, which can be configured to provide location information (for example, longitude and latitude) with respect to the current location of WTRU 108. Also, instead of, the chipset information GPS 236, the WTRU 108 can receive information
Balancing V - 20 over the air interface 216 from a base station (for example, from base stations 214a, 214b), and / or determining their location based on the time interval of the signals being received from two or more neighboring base stations. It should be appreciated that WTRU 108 can acquire lQca | ization information by any suitable method of location or determination, while remaining consistent with a form of incorporation. The processor 218 can also be coupled with other peripherals 238, which may include one or more so / Mare and / or hardware modules that provide additional features and functionality, and / or wired or wireless connectivity. For example, 238 peripherals may include an accelerometer, an electronic compass 30, a satellite transceiver, a digital camera (for photos or video), a universal serial bus port (USB - Universal Serial Bus), a vibration device, a television transceiver, a headphone / microphone set attached to the head to leave hands free, a B / uetooth ® module, a frequency modulated radio (FM) unit, a digital music player, a media player, a module for 35 video games, a browser (internet, and so on. Fig. 2C is a block diagram of RAN 204 and central network 206, according to a form of incorporation. RAN 204 can be an Access Service Network (ASN) that employs radio technology
# - IEEE 802.16 to communicate with WTRUS 108a, 108b, 108C through the interface via air 216. As will be discussed below, the communication links between the "different functional entities of VVTRUS 108a, 108b, 108C, RAN 204, and central network 206 can be defined as reference points.
5 As shown in fig. 2C, RAN 204 may include base stations 240a, 240b, 240c, and an ASN gateway 242, although it should be appreciated that RAN 204 may include any number of base stations and ASN portals, while remaining consistent with a form of incorporation. Base stations 240a, 240b, 240C can be associated with each particular cell (not shown) in RAN 204 and can each include one or more transceivers for communication with WTRUS 108a, 108b, 108C via the interface via air 216. In an embodiment, base stations 240a, 240b, 240C can implement MIMO technology. Thus, base station 240a, for example, can use multiple antennas to transmit wireless signals to, and receive wireless signals from, WTRU 108a. The 15 base stations 240a, 240b, 240C can also provide mobility management functions, such as transition triggering, tunneling, radio resource management, traffic classification, application of quality of service (QoS - Wed / ity) policies of Service), and so on. The ASN 242 .g portal can serve as a traffic aggregation point, and can be responsible for services. 20 paging, by caching subscriber profiles, by routing to the central network 206, and so on.
The route via air 216 between WTRUS 108a, 108b, 108C and RAN 204 can be defined as a reference point R1 that implements the IEEE 802.16 specification. In addition, each of the WTRUS 108a, 108b, 108c can establish a logical interface (not shown) with the central network 206, The logical interface between the WTRUS 108a, 108b, 108c and the central network 206 can be defined as a point R2, which can be used for authentication, authorization, management of IP host configuration and / or mobility management.
The communication link between each of the base stations 30a 240a, 240b, 240c can be defined as a reference point R8 that includes protocols for facilitating WTRU transitions and data transfer between base stations. The communication link between base stations 240a, 240b, 240C and the ASN portal 242 can be defined as a reference point R6. The point of
Reference R6 may include protocols to facilitate mobility management based on the mobility events associated with each of the VVTRUS 108a, 108b, 108C.
As shown in fig. 2C, RAN 204 can be connected to central network 206. The communication link between RAN 204 and central network
206 can be defined as an R3 reference point that includes protocols to facilitate data transfer and mobility management capabilities, for example. Central network 206 may include a local mobile IP agent (MIP-HA - Mobi / e lP Home Agent) 244, an authentication, authorization and counting server (AAA - 5 Authentication, Authorization, Accounting) 246, and a portal 248 MIP-HA 244 can be a proxy MIP-HA (PMIP-HA - Proxy M / P-HA). Although each of the above elements is described as part of the base network 206, it should be appreciated that any of these elements may be owned and / or operated by an entity other than that of the base network operator. 10, PMIP-HA 244 may be responsible for managing IP addresses, and may allow VVTRUS 108a, 108b, 108C to transit between different ASNs and / or different central networks. The PMIP-HA 144 can provide wrRUs
W 108a, 108b, 108C with access to packet-switched networks, such as lntemet 210, to facilitate communications between WTRUS 108a, 108b, 108C and devices with lP 15 enabled, AAA server 246 may be responsible for authentication user and user support services, Portal 148 can facilitate interoperability with other networks. For example, portal 248 can provide WTRUS 108a, 108b, 108C with access to circuit switched networks, such as PSTN 208, to facilitate communications between WTRUs 108a, 108b, 108C and communication devices, 20 traditional land lines. In addition, portal 248 can provide WTRUS 108a, 108b, 108C with access to networks 212, which may include other wired or wireless networks that are owned by. and / or are operated by, other service providers, Although not illustrated in fig. 2C, it should be appreciated that RAN 204 can be connected to other ASNS, and central network 206 can be connected to 25 other central networks. The communication link between RAN 204 and other ASNs can be defined as an R4 reference point that can include protocols for coordinating the mobility of WTRUS 108a, 108b, 108C between RAN 204 and the other ASNS. The communication link between the central network 206 and other central networks can be defined as a reference point R5, which can include protocols to facilitate the inter-operation 30 between the base central networks and the visited central networks. Figure 2D is an example block diagram 250 comprising WTRU 108, eNB 240, and the mobility management entity (MME - Mobl / ity Management Entity) / server portal (S-GW - Serving Gateway) 142. As shown in figure 2D, WTRU 108, eNB 240 and MME / S-GW 142 are 35 configured to carry out a method for multicast mobility. In addition to the components that can be found in a typical WTRU, WTRU 108 includes a processor 316 with an optional linked memory 322, at least one transceiver 314, an optional battery 320, and an antenna 318. Processor 316 is configured to run a method for multicast mobility. Transceiver 314 is in communication with processor 316 and antenna 318, to facilitate the transmission and reception of wireless communications. In the event that a battery 320 is used in WTRU 108, it powers the transceiver 314 and processor 316. In addition to the components that can be found in a typical eNB, the eNB 240 includes a processor 317 with an optional linked memory 315, transceivers 319, and antennas 321. Processor 317 is configured 10 to perform a method for multicast mobility. Transceivers 319 are in communication with processor 317 and antennas 321, to facilitate the transmission and reception of wireless communications. The eNB 240 is connected to the mobility management entity / server portal (MME / S-GW) 142, (including a processor 333 with a linked memory option) 334. Referring to figure 3, the PMlP tunnels can be added to multicast WTRUSs, such as multicast group 340 and multicast group 350. If the existing proxy binding (proxy) (PBU) update message is used, a new multicast length field of variable length (that is, a portion or segment) can be added to the update binding message. existing proxy (PBU). The PBU is a request message sent by MAG 380 to the respective LTR of the WTRU, to establish a link between the HNP of the WTRU assigned to a predefined interface of a WTRU 340, 350, or 360 and its current CoA (ie Proxy-25 CoA). The respective WTRU LMA can be connected to both unicast services 310 and multicast services 320. The multicast options field can contain a multichannel COA, A specific multicast COA is associated with the aggregate multicast tunnel 334 or 332 ending at MAG 380. Alternatively, a multicast flag (f / ag) can be added to the PBU message. 30 Alternatively, a Mvâ message can be used to signal multicast information. The aggregated multicast tunnels 332 and 334 can be preconfigured. For example, they may pre-exist between LMA (local agent) 370 and the
L MAG 380, even before any 340, 350 or 360 WTRUs subscribe to 35 multicast services. LMA 370 and MAG 380 can exchange information, indicating that both support multicast services, using the messages described above. The multicast WTRUS 340 and 350 are added to the tunnel the moment they are attached to the mobile network 330.
W b 14/24 b "4 1« Alternatively, the aggregate multicast tunnels 332 and 334 can be dynamic. The aggregated multicast tunnels do not exist before and some multicast section is requested. When multiple WTRUS 360 establish multicast tunnels 336 for multicast services, LMA 370 and MAG 380 5 can combine these 336 multicast tunnels into an aggregate multicast tunnel, 332 or 334. A WTRU can indicate a request for multicast services for a MAG in several ways. The WTRU can use MLD / IGMP messages to indicate a multicast request for a MAG. Or, WTRU 10 can include multicast information in a routing request message. Both LMA 370 and MAG 380 can initiate the creation.
Q for aggregated tunnels for multicast services. To initiate tunnel aggregation from MAG 380 to LMA 370, a PBU message can be used 15 to start the process, by adding a flag (f / ag) in the multicast options field, or a new one message can be used. Multicast information can be stored in either LMA 370, MAG 380, or both. Such multicast information can be: multicast channels, the WTRUSs subscribed to each multicast service, and each respective WTRU network attachment. A multicast tunnel can be unidirectional for traffic, 20 «data download connection only (down / ink), or bidirectional like, up / ink communication (data loading connection) and down // nk], Control information, such as MLD / IGMP messages, can be sent through unicast tunnels or through aggregated multicast tunnels. For multicast and multicast services 25, the aggregated multicast and multicast tunnels can coexist between LMA 370 and MAG 380. A 360 WTRU with a multicast tunnel can also be associated with a multicast COA. For example, a WTRU can have 336 multicast tunnels and aggregate multicast tunnels 332, 334. In addition, one or more multicast tunnels can exist. These options can include a multicast tunnel with a multicast COA to serve all multicast services, multiple multicast tunnels that provide different separate multicast services, or a combination of them. > MAG 380 can indicate whether the multicast service is supported and available, for
V through a routing announcement message- 35 Figure 4 illustrates a dedicated multicast LMA architecture 400. In this embodiment, there is a dedicated LMA 470 for multicast services 410 and a dedicated LMA 480 for multicast services 420. The multiple LMAS 470 and 480 can be used for each type of service, depending on the
- implementation of the respective network.
The WTRU 460 can have multiple interfaces.
Thus, WTRU "460 can establish a unidiffusion tunnel 432, 436 with unidifusion LMA 470, and a multicast tunnel 434, 438 with multicast LMA 480, respectively, in 5 parallel.
The WTRU 460 can have more than one local agent (HA - Home Agent). In this architecture, the LMAS division is based on a specific service required.
In figure 4, a WTRU 460 moves from p-MAG 440 to n-MAG 450. Referring to figure 5A and figure 5B, additional details for multicast services are described.
In this example, at least two 10 methods are described, one in figure 5A and one in figure 5B, in which IP address assignment is used to support multicast services.
As seen in figure 5A, a set of IP addresses is assigned 510 from the LMA HA for unicast 470 to the WTRU 460. The IP addresses are used by the WTRU 460 for both the 410 and 15 multicast 420 services. The WTRU 460 transmits the routing request message 520 to the server MAG, which triggers a PBU message from the separate MAG to the broadcast LMA 470. As seen in figure 5B, two sets of IP addresses
.. 525 are assigned to the WTRU 460. A set of IP addresses is assigned to r. 20 from unicast LMA HA 470 to unicast 410, and a different set of IP addresses from multicast LMA HA 480 to multicast 420. The WTRU 460 transmits the photo request message 530 to the server MAG, which will trigger dL | the PBU messages, one from the server MAG to the unicast LMA 470, and the other to the multicast LMA 480. 25 In the case that the WTRU 460 does not require unidiffusion services, the WTRU 460 receives the IP addresses from the LMA from multicast 480 to multicast services 420 through a single PBU message from the server MAG to the multicast LMA 480. The link update list maintained by a MAG is updated to have entries for a WTRU link with both the LMA Unidifluence 470 for unicast traffic as well as with multicast LMA 480 for multicast traffic. B
The forwarding of multicast traffic and unidifusion traffic "can be done by MAG. By discrimination between received multicast and multicast traffic received telated to a specific WTRU.
The MAG may be able to discriminate by looking at the source or destination addresses.
MAG can route traffic on the correct interface.
For example, in figure 5A, when there is up / ink traffic (this
"W rfm 16/24 is, from WTRU 460 to the MAG server), the MAG server is able to determine whether it should be forwarded to unicast LMA 470 for unicast traffic or multicast LMA 480 for signaling For down / ink traffic, since there is only one interface on the WTRU 460, the MAG 5 server only needs to have a mapping of the multicast and multicast tunnels to the VVTRU 460. As another example, on Figure 5B, when different IP addresses are used for unidifusion services 410 and multicast services 420, the MAG server needs to map the tunnels with the interfaces of the WTRU 460, in a similar way to what happens in the case of mu PMLP / ti-homing (multi-homing) PMlP allows mobile nodes to connect to a mobile lPv6 domain
V via proxy (proxy) through multiple simultaneous access interfaces. When a mobile node connects to a mobile IPv6 domain via a proxy through multiple simultaneous access interfaces, the local mobility anchor allocates a mobility session for each of the attached interfaces. Each mobility session is managed according to a separate Binding Cache | cache entry and with its own lifetime. When there are only multicast services, the server MAG maps the multicast tunnel with the WTRU 460, in a similar way to unicast traffic. . 20 The policy profile of the WTRU 460 stored on the policy server can be updated to store the LMA lPv6 addresses for the unified broadcast LMA 470 and for the multicast LMA 480 LMA. Using this information, the WTRU server MAG 460 is able to obtain the addresses of the multicast LMA. 25 Alternatively, MAG can maintain a multicast policy profile, which can map one or many LMA addresses to certain multicast groups, multicast options, or link (link). A MAG may be able to attach to multiple LMAS, For example, a MAG may have a mandatory connection to the unicast LMA, and optionally connect to the multicast LMA, if the IP address assignment is in accordance with described in figure 5A is used. In this case, connection to the broadcast LMA 470 is mandatory, because that is where the WTRU's jp address is assigned. A MAG can optionally have a connection to the LMA of unicast 470 or multicast LMA 480 if address assignment of lP, m as described in figure 5B, is used. In this example, the IP addresses of the WTRU 35 460 can be assigned from any of the LMAS, depending on the type of service (single-channel or multicast) required. Figure 6 shows the PMlP intra-LMA 600 multicast mobility enabling architecture. The form of incorporation shown in figure 6 is substantially the same as that shown in figure 3, except that in this form of incorporation of all or some of the WTRUS 630 they move from a previously attached MAG (p-. MAG) 610 to a newly attached MAG (n-MAG) 620. The triggering of an impending HO (handover) transition can come from the 5 WTRU or the network as a result of lower layer signaling, such as degraded signal strength, increased packet loss, and the like. An example of lower layer signaling is a link message
802.21. Figures 7A and 7B show a communication path 10 for intra-LMA PMlP multicast mobility 700 and 750, respectively. As seen in figure 7A, the LMA 650 sends multicast packets 710 to the p-MAG 610. The p-
U MAG 610 sends multicast packets 712 to WTRU 630. WTRU 630 informs p-MAG 610 about impending HO 714, PmMAG 610 informs n-MAG 620 about multicast HO via a new interface, IF1 716 , between p-MAG 610 and n-MAG 620. 15 Alternatively, the onset of the impending HO and the IF1 interface also apply to unidiffusion services. The n-MAG 620 sends a PBU message to the LMA 650, to establish a tunnel! aggregate 718. Multicast options with a multicast CoA are provided to the LMA 650 by n-MAG 620. The LMA 650 sends multicast packets to the n-MAG 620, prior to the actual HO 720. The WTRU 630 that is. 20 associated with the pre-established aggregate tunnel moves to n-MAg 620, and receives. 'aggregate tunnel 722 multicast packets, In a condition where the aggregate tunnel between the LMA and p-MAG is not required, the aggregate tunnel can be removed. Referring to figure 7B, the LMA 650 sends multicast packets 752 to the p-MAG 610. The p-MAG 610 sends multicast packets 754 to the 25 WTRU 630. The WTRU 630 informs the p-MAG 610 about the impending HO 756. The p-MAG 610 passes the information 758 about the impending HO to the LMA 650. The LMA 650 starts the creation of an aggregated broadcasting tunnel 760 between the LMA 650 and the n-MAG 620. The LMA sends a lP message mobile via proxy (proxy) for n-MAG, to establish the new multicast tunnel 762. In a condition where the LMA is aware of the impending HO 30 received, the LMA 650 can start the creation of an aggregate multicast tunnel 762 between LMA 650 and n-MAG 620. LMA 650 sends multicast packets to n-MÁG 620, before the actual HO 764, WTRU 630 which is associated with the pre-established aggregate tunnel moves to n- MAG 620, and receives multicast packets. from the aggregate tunnel 766. In a condition where the aggregate tunnel between LMA 650 and 35 p-MAG 610 is not required, the aggregate tunnel can be removed. Alternatively, the onset of impending HO may come from the network. The trigger can be caused by the load balancing of the network, CJlj for a maintenance purpose (for example, the p-MAG will be turned off). O
W 18/24 T
3. ~ '- ,. network triggering can come to LMA 650 or p-MAG 610. In one - m
In the condition that the p-MAG 610 is aware of the impending HO received, the p-MAG 610 can
U inform LMA 650 directly about HO, or inform n-MAG 620 about HO. This form of incorporation proceeds in a similar way to the form of incorporation 5 related above to Figures 7A and 7B, where the handover is triggered by a WTRU. Alternatively, after the establishment of aggregate tunnel 762, multicast traffic is sent from LMA 650 to n-MAG 620. n-MAG 620 can send a PBU message to LMA 650 after WTRU 630 is detected 10 on the network . However, this can cause a longer delay compared to the method mentioned above, in which the tunnel is first pre-established and then the multicast is started. 0 In another alternative form of incorporation, a "join" message from the multicast group is transmitted on the target network before 15 HO. The multicast information obtained by the n-MAG 620 before the actual HO, as described above in figures 7A and 7B, can facilitate the enabling of the multicast services of the n-MAG 620 before attaching the WTRU. The multicast information obtained by n-access routing (n-AR - n-Access Routet), in a condition where the PMlP is not used, before the real HO, can facilitate the enabling of n-T '. . ¢ 20 AR of the multicast services before the annexation of the WTRU. In another alternative, a mobility management entity on the network is informed of the impending HO. The mobility management entity joins the multicast group heard by the WTRU with the routing of
And appropriate multicast on the target network, before triggering HO. 25 Another alternative uses a "join" message from: · a fast trigger, multicast group, then a Tier 3 HO. The mobility management entity, which controls the HO, triggers the sending of an MLD report / IGMP to join the multicast group, once the HO is complete. This is done immediately, instead of waiting for a query coming from the multicast routing, thus reducing the delay before resuming the multicast services. These forms of incorporation can be used f independently or together. For example, when they are used together, and the -, multicast group 'joins' before the HO that didn't work, the message "join-35 if" of rapid triggering, from the multicast group, after HO, may be able to reduce service delay. Figure 8 shows the PMIP inter-LMA 800 multicast mobility enabling architecture. In this form of incorporation, the VVTRU 730
- moves from p-MAG 710 to n-MAG 720. p-MAG 710 and n-MAG 720 belong to different LMAs, LMA 750 and LMA 760, respectively. Each LMA 750 and 'LMA 760 can provide both unicast and multicast services. The method described in figure 6 for a single LMA multicast mobility is used in conjunction with additional interfaces to inform the target LMA 750 and 760, to enable the required multicast services. The IF1 interface is used to exchange multicast information between the source and target MAGS, 710 and 720. The IF2 interface is used to exchange multicast information between the source and target LMAs, 750 and 760. The IF3 interface is used to exchange multicast information between the MAG 710 from 10 source and the target LMA 760. The | F4 interface is used to exchange ml | broadcast information between the source LMA 750 and the target MAG 720. These interfaces are
Alternatives and may not be available at the same time. Figure 9 shows a single type of network for a hybrid network, for mobility 900. Referring to figure 9, a bidirectional mobile network 15 combined with a down / ink 925 only multicast network is shown. In such a hybrid network, an HO can occur from the bidirectional network to a downh'nk 925 only multicast network. In a first example, the HO is triggered by the WTRU 930, using the IF3 interface and the IF4 interface. A mobility client 932 on WTRU 930 detects the impending HO. The feasibility client. 20 932 informs a multicast services entity 934 (for example, OMA BCAST 934 functionalities in the WTRU) through the IF3 interface. The multicast service entity 934 informs its counterpart 916 on the 915 network (for example, adaptation / distribution functionalities of OMA services on the network) about the impending HO through the IF4 interface, and requires the distribution of services on the network only. down / ink 925. The IF4 interface may be a new interface, or it may be an existing OMA BCAST-5 interface with improvements to support HO information. In another example, HO is triggered by WTRU 930 using interfaces IF1 and IF2. A mobility aware entity 932 on WTRU 930 detects the impending HO- Mobility aware entity 932 informs the mobility server 912 on network 910 [for example, a media independent connection transition server (MIH - Media lndependent Handover) is an example of a
Q mobility] about imminent HO through the IF2 interface. The IF2 interface can be a new interface, or it can use an existing interface ok! as an MIH protocol. The mobility server 912 can be located in the 910, 35 unicast services network in the 915 multicast service network, or in a different domain from the unicast or multicast networks. The Mobility Sender 912 informs the BCMA 916 OMA server about the impending HO, and requires the distribution of services in the network of only down / ink 925 through the IF1 interface. The IF1 interface is a new interface.
. In a third example, network 920 triggers an HO using the IF1 interface. In this case, the mobility server 912 can inform OMA 0 BCAST 916 through the interface IF1. In a fourth example, the 920 network triggers an HO using the IF2 interface, the IF3 interface, and the IF4 interface. In a condition at 5 that the IF1 interface does not exist, the mobility server 912 can inform the mobility client 932 using the IF2 interface. The mobility client 932 informs the OMA BCAST 934 client using the IF3 interface, and the OMA BCAST 934 client informs the OMA BCAST 916 server using the IF4 interface. In a fifth example, mobility is supported from MAG 940 or LMA 935 in the distribution network. 10 MAG (AR or PMlP) 940 and an LMA (portal) 935 can obtain information about a plurality of WTRUS 930, including the respective information from mobility and multicast services. The MAG 940 and LMA 935 can interface with the multicast services network 915, or with the multicast distribution network (down / lnk only) 925, to ensure the distribution of the 15 multicast services when a WTRU 930 is connected. moves to the down / ink 925 only multicast network. HO can occur from a down / ink 925 only multicast network to a 920 bidirectional network. The network triggers HO. The "WTRU is informed of the HO in the down / ink control information. An indication - 20 (ie information) of impending HO is passed to the bidirectional network via interfaces on the network side, such as If1. Alternatively , the WTRU 930 triggers the HO. A data upload connection (up / ink) is required for the WTRU 930 to inform the network about the impending HO. The interfaces described above for the HO from a 920 bi-directional network to an only down / ink 925 networks can be used 25 to pass HO information from WTRU 930 to the network The methods, examples and forms of incorporation described for mobility in hybrid networks, related to figure 9, do not assume no method.of mobility of L3 or L2, and PMlP may or may not be used -.-
INCORPORATIONS OF THE INVENTION 30 1. A wireless transmission and reception unit (WTRU), comprising: L a receiver configured to receive a first internet protocol address (lP) which is for unidiffusion services, and a second address. IP which is for multicast services. 35 2. The WTRU according to incorporation 1, further comprising: a processor configured to use the first IP address for unidiffusion services and the second IP address for multicast services; and a transmitter configured to transmit a routing request message to a mobile access server (MAG) portal that triggers proxy binding update (PBU) messages that include the second IP address.
3. The WTRU according to IncQration 2, in which the transmitter is additionally configured to inform the server MAG about the impending connection transition (HO).
4. The WTRU according to any of the incorporations 2 to 10 3, where the WTRU is configured to move from the MAG server to a next MAG through a pre-defined interface.
5. The WTRU according to any of the incorporations 1 to 4, in which the processor is still configured to update the WTRU policy profile according to the lPv6 addresses of local mobility anchors (LMAS). "15 6. The WTRU pursuant to any of embodiments 1 to 5, in which the WTRU uses multicast listener discovery messages / Internet group management protocol (MLD / IGMP) to indicate to the semester MAG its request for multicast. W
7. A method for a mobile internet protocol via. 20 proxy (PMlP) support dedicated local multicast mobility anchors (LMAs), in which the method comprises: a first LMA that assigns a first set of internet protocol (lP) addresses to a wireless transmission and reception unit ( WTRU), dedicated to both single and multicast services. 25 8. The method according to incorporation 7, further comprising: the first LMA receiving a trigger from a mobile access portal (MAG), indicating a proxy binding update message (PBU). '30 9. The method confirms incorporation 8, in which the first LMA assigns the first set of IP addresses to the WTRU for the services of. unidifusion, and a second LMA assigns a second set of IP addresses for multicast services
10. The method according to any of the embodiments 8 to 35 9, in which the first LMA receives a trigger from a first MAG, indicating a first PBU message from the first MAG, and the second LMA receives a trigger from a second MAG , indicating a second PBU message from the second MAG.
. 11. The method according to incorporation 10, where in a condition where an existing PBU message is used, a new variable length broadcasting options field is added to the existing PBU message, and a multicast signal (Aag) is added to the PBU message. 5 12. The method according to any of the incorporations 9 to 11, in which the first LMA and the second LMA start the establishment of a single-channel tunnel and a multi-channel tunnel.
13. The method according to incorporation 12, in which the multicast tunnel is unidirectional for traffic of only 10 data download connection (down / ink) or is for bidirectional traffic.
14. A method for a mobile Internet protocol via proxy (PMlP) to support mobile access portals (MAGS), in which the method «comprises: a first MAG forwarding a first set of 15 internet protocol (lP) addresses to a wireless transmission and reception unit (WTRU) dedicated to both single and multicast services.
15. The method according to incorporation 14, further comprising: L the first MAG to receive a request message from. 20 WTRU routing; and the first MAG to trigger a proxy binding update (PBU) message, which includes multicast information for a first local mobility anchor (LMA).
16. The method according to incorporation 15, in which the first MAG 25 forwards a first set of IP addresses to the WTRU dedicated to the broadcast services, and the first MAG forwards a second set of IP addresses to the WTRU dedicated to the broadcast services. multicast,
17. The method, as per any of embodiments 15 to 16, in which the first MAG triggers an indication of a first PBU message 30 for a first LMA, and a second PBU message for a second LMA-
18. The method according to incorporation 17, in which the first MAG maintains a new list of PBU messages that includes the connection of the WTRU with the first LMA and with the second LMA. 35 19. The method according to any of the incorporations 14 to 18, in which the first MAG discriminates between a traffic of unidifusion services and a traffic of multicast services, to route the traffic to an appropriate interface.
4e ¥.
20. The cQnforTne method any of the incorporations 14 to 19, in which the first MAG initiates the establishment of a unidifusion tunnel and a 'multicast tunnel.
21. The method according to incorporation 20, in which the multicast tunnel 5 is unidirectional for down / ink only traffic or is for bidirectional traffic. Although the features and elements are described above in particular combinations, those of ordinary skill in the art will appreciate that each feature or element can be used alone or in any combination with other features and elements. In addition, the aqL | i methods described can be implemented in a computer program, in software or q hrmware incorporated in a computer-readable medium, to be executed by a computer or processor. Examples of computer-readable media include electronic signals ( transmitted via wired or wireless connections) and computer-readable storage media. Examples of computer-readable storage media include, but are not limited to, a read-only memory (ROM), a random access memory (RAM), a register, a cache memory, semiconductor memory devices, magnetic media such as internal hard disks and removable disks, magneto-optical media and optical media such as
P - 20 CD-ROM discs and digital versatile discs (DVDS). A processor in association with so / tware can be used to implement a radio frequency transceiver for use in a WTRU, UE, terminal, base station, RNC, or any host computer. Suitable processors include, by way of example, a general purpose processor, a special purpose processor, a conventional processor, a digital signal processor (DSP), a plurality of microprocessors, one or more microprocessors -processors in association with a DSP core, a controller, a micro-controller, integrated circuits for specific applications (ASlCs - App / ication Specific lntegrated Circu / ts), circuits with programmable field gate arrangement (FPGAS - Field Programmab / and Gate 30 Arrays), qLja | or another type of integrated circuit (Cl), and / or a state machine. A processor in association with a soMare can be. used to deploy a radio frequency transceiver for use in a wireless transmission / reception unit (WTRU), user equipment (UE), terminal, base station, mobility management entity (MME) - 35 Mobi / ity Management Entity) or an evolved package center (EPC m Evo / ved Packet Core), or any host computer (host). The WTRU can be used in conjunction with modules, implemented in hardware and / or sMware, including software defined radio (SDR - Software Defined Radio), and other components, such as a camera,
You see a video camera module, a videophone, a headset, a vibrating device, a speaker, a microphone, a television transceiver, a portable headset set, a keyboard, a Bluetooth® module, a frequency modulated radio (FM) unit, a liquid crystal display unit (LCD - Liquid Cristal Display), a 5 organic LED light unit (OLED - Organic Light Emitting Diode), a player (player) digital music player, a media player, a video game player module, an Internet browser, and / or any wireless local area network (WLAN) olj ultra-broadband module (UWB - U / tra Wide Band).

权利要求:
Claims (18)
[1]
1. Device for multicast mobility, characterized by the fact that it comprises a mobile access gateway (MAG), comprising: a first receiver configured to receive a first packet with a first internet protocol (IP) address from a first local mobility anchor (LMA) and a second packet with a second IP address from a second LMA, where the first LMA is a multicast LMA for multicast traffic and the second LMA is a unicast LMA for traffic from unidiffusion; a router providing routing, configured to route the first 10 packet and the second packet to a wireless transmission and reception unit (WTRU), using both single and multicast services:
[2]
A second receiver configured to receive a routing request message from the WTRU; a processor configured to trigger a proxy binding update (proxy) message (PBU) that includes multicast information for the first LMA: and the processor being further configured to maintain a binding update list including entries for binding the WTRU with the "first LMA and the second LMA.. 20 2- Multicast mobility device, according to claim 1, characterized by the fact that the router is still configured to route or forward the first packet with a first address IP for the WTRU used for the unicast services, and to route or forward the second packet with a second IP address to the WTRU used for the multicast services.
[3]
Apparatus for multicast mobility, according to claim 2, characterized by the fact that the processor is still configured to trigger an indication of a first PBU message for the first LMA and a second PBU message for the second LMA.
[4]
4, Apparatus for multi-broadcast mobility, according to claim 1, characterized by the fact that the processor is still configured to discriminate between a single-traffic traffic service and a multi-traffic traffic service, to route traffic to a appropriate interface.
[5]
5. Device for multicast mobility, according to. claim 4, characterized by the fact that the processor is still configured 35 to start the establishment of a unidifusion tunnel and a multicast tunnel.
[6]
6. Device for multicast mobility, according to claim 5, characterized by the fact that the multicast tunnel is unidirectional for traffic only for data download connection (down / ink), or q tunnel is for bidirectional traffic.
[7]
7. Method for multicast mobility, characterized
[8]
B because it comprises a method for a mobile Internet protocol via proxy (PMlp) mobile access gateways (MAG), the method comprising: 5 receiving a first packet with a first lntemet (lP) protocol address from a first local mobility anchor (LMA) and a second packet with a second IP address from a second LMA, where the first LMA is a multicast LMA for multicast traffic and the second LMA is a unWifusion LMA for unicast traffic; 10 route or forward the first packet and the second packet to a wireless transmission and reception unit (WTRU), using both services
[9]
P for unidiffusion as for multicast; receive a routing request message from the WTRU: 15 trigger a proxy proxy (PBU) link update message that includes multicast information for the first LMA; and maintain a link update list including · entries for linking the WTRU with the first LMA and the second LMA. . 8. Method for multicast mobility, according to claim 7, characterized by the fact that it comprises the routing of the first packet with a first IP address to the WTRU used for the unidiffusion services, and the routing of the second packet with a second IP address for the WTRU used for multicast services. 9. Broadcast mobility method according to claim 8, characterized in that it comprises the triggering of an indication of a first PBU message for the first LMA, and the triggering of a second PBU message for the second LMA .
[10]
10. Method for multicast mobility, according to claim 7, characterized by the fact that it also understands the discrimination between a traffic of unidifusion services and a traffic of multicast services, in order to route the traffic to an appropriate interface.
[11]
11. Method for multicast mobility, according to claim 10, characterized by the fact that it also comprises the beginning of the establishment of a unidifusion tunnel and a multicast tunnel.
[12]
12. Method for multicast mobility, according to claim 11, characterized in that the multicast tunnel is unidirectional for down / ink only traffic, or q tunnel is for bidirectional traffic.
G.
[13]
13. Device for multicast mobility, characterized by the fact that it comprises a local unidifusion 1 mobility anchor (LMA) comprising: a processor configured to assign a packet with 5 internet protocol (lP) addresses to a transmission and reception unit wireless (WTRU), used for unidiffusion services: a first receiver configured to receive a trigger from a mobile access portal (gateway) (MAG), indicating a proxy binding update (proxy) (PBU) message; 10 the processor being still configured to start the establishment of an aggregated multicast tunnel; a second receiver being configured to receive
P data from a server; and a transmitter configured to transmit the received data to the WTRU through the MAG, using the aggregated multicast tunnel.
[14]
14. Multicast mobility apparatus according to claim 13, characterized in that in a condition in which an existing PBU message is used, a new multichannel option group with "variable length is added to the PBU message existing, where a multicast flag - 20 (flag) is added to the PBU message.
[15]
15. Device for multicast mobility, according to claim 13, characterized by the fact that the multicast tunnel is unidirectional for down / ink only traffic, or the tunnel is for bidirectional-
[16]
16. Multicast mobility apparatus, characterized by the fact that it comprises a multicast local mobility anchor (LMA) comprising: a processor configured to assign a packet with an internet protocol address (lP) to a transmitting and receiving unit wireless (WTRU), used for broadcasting services: 30 a first receiver configured to receive a trigger from a mobile access gateway (MAG), indicating an E proxy proxy update message (proxy) ( PBU); the processor being still configured to start the establishment of an aggregated multicast tunnel; 35 a second receiver being configured to receive data from a server; and a transmitter configured to transmit the received data to the WTRU through the MAG, using the aggregated multicast tunnel.
W "!«
[17]
17. Multicast mobility apparatus according to claim 16, characterized by the fact that in a condition in which an existing PBU message is used, a new field of variable length multicast options is added to the PBU message existing, where a multicast flag 5 (i¶ag) is added in the PBU message.
[18]
18. Device for multicast mobility, according to claim 16, characterized by the fact that the multicast tunnel is unidirectional for traffic of only downh'nk, or the tunnel is for bidirectional traffic.

类似技术:

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US9386424B2|2016-07-05|Method for multicast mobility

US10015643B2|2018-07-03|Managing multicast traffic

JP5890507B2|2016-03-22|Method and apparatus for inter-user device transfer | in a network-based mobility domain

US20110274041A1|2011-11-10|Dynamic peer discovery and inter-unit transfer | using mobile internet protocol |

同族专利:

公开号 | 公开日

KR20130042038A|2013-04-25|

TWI526025B|2016-03-11|

US20110110286A1|2011-05-12|

RU2012115447A|2013-10-27|

KR20120090068A|2012-08-16|

EP2478719B1|2017-06-28|

KR101442933B1|2014-09-22|

JP2013505643A|2013-02-14|

EP2478719A1|2012-07-25|

TW201119296A|2011-06-01|

KR101617501B1|2016-05-02|

JP6178275B2|2017-08-09|

CN102630387B|2015-08-05|

US8804591B2|2014-08-12|

US9386424B2|2016-07-05|

EP3177049B1|2019-12-11|

JP2014168233A|2014-09-11|

JP5519794B2|2014-06-11|

RU2524846C2|2014-08-10|

US9191224B2|2015-11-17|

TW201436506A|2014-09-16|

WO2011035168A1|2011-03-24|

CN105119729A|2015-12-02|

US20160050543A1|2016-02-18|

CN102630387A|2012-08-08|

US20140286228A1|2014-09-25|

EP3177049A1|2017-06-07|

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法律状态:
2020-08-18| B08F| Application dismissed because of non-payment of annual fees [chapter 8.6 patent gazette]|Free format text: ARQUIVADO O PEDIDO DE PATENTE, NOS TERMOS DO ARTIGO 86, DA LPI, E ARTIGO 10 DA RESOLUCAO 113/2013, REFERENTE AO NAO RECOLHIMENTO DA 9A RETRIBUICAO ANUAL, PARA FINS DE RESTAURACAO CONFORME ARTIGO 87 DA LPI 9.279, SOB PENA DA MANUTENCAO DO ARQUIVAMENTO CASO NAO SEJA RESTAURADO DENTRO DO PRAZO LEGAL, CONFORME O DISPOSTO NO ARTIGO 12 DA RESOLUCAO 113/2013. |

2020-12-08| B08K| Patent lapsed as no evidence of payment of the annual fee has been furnished to inpi [chapter 8.11 patent gazette]|Free format text: EM VIRTUDE DO ARQUIVAMENTO PUBLICADO NA RPI 2589 DE 18-08-2020 E CONSIDERANDO AUSENCIA DE MANIFESTACAO DENTRO DOS PRAZOS LEGAIS, INFORMO QUE CABE SER MANTIDO O ARQUIVAMENTO DO PEDIDO DE PATENTE, CONFORME O DISPOSTO NO ARTIGO 12, DA RESOLUCAO 113/2013. |

2021-04-20| B25H| Request for change of headquarter rejected|Owner name: INTERDIGITAL PATENT HOLDINGS, INC (US) Free format text: INDEFERIDO O PEDIDO DE ALTERACAO DE SEDE CONTIDO NA PETICAO 18130024569 DE 19/07/2013, EM VIRTUDE DA MANUTENCAO DO ARQUIVAMENTO (8.11) PUBLICADO NA RPI2605 DE 08/12/2020. |

2021-11-03| B350| Update of information on the portal [chapter 15.35 patent gazette]|

优先权:

申请号 | 申请日 | 专利标题

US24381009P| true| 2009-09-18|2009-09-18|

US61/243,810|2009-09-18|

US31545910P| true| 2010-03-19|2010-03-19|

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PCT/US2010/049349|WO2011035168A1|2009-09-18|2010-09-17|Method and apparatus for multicast mobility|

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