Architecture and methods for traffic management by tunneling in hierarchical cellular networks

1 - 28 . (canceled) 29 . Apparatus for use in conjunction with a hierarchical cellular network system having a core and a plurality of nodes, the apparatus comprising: a mobile relay having functionalities including both base station functionality and mobile communicator functionality and operative to serve mobile communicators, including at least one relay other than said mobile relay, and to be served by the at least one relay other than said mobile relay; and wherein the at least one relay other than said mobile relay includes: a tunneling subsystem; and a backhauling link subsystem Backhauling Link Subsystem interfacing between the tunneling subsystem and a closer node from among said nodes which is closer to the core than said mobile relay; the base station functionality interfacing between the tunneling subsystem and a mobile station or a further node from among said nodes which is further from the core than said mobile relay, wherein the tunneling subsystem is operative to perform the following, on data arriving from the base station functionality: collecting said data including analyzing to identify, within said data, results to be sent; and encapsulating the results to be sent into packets and sending said packets to said Backhauling Link Subsystem. 30 . A system according to claim 29 and wherein said tunneling subsystem is also operative for: sorting the results, at least by user ID; and queuing the results as sorted by said sorting. 31 . A system according to claim 30 and wherein said tunneling subsystem is also operative for: sorting the results, at least by data type (control/user); and queuing the results as thus sorted. 32 . A system according to claim 31 wherein said queuing employs rules based on user priority. 33 . A system according to claim 32 wherein said queuing employs rules based on service type. 34 . A system according to claim 31 wherein said tunneling subsystem is also operative for: partitioning the results as queued by said queuing including deciding which of the results are to be transmitted in each of a sequence of upcoming communication sessions. 35 . A system according to claim 29 wherein the core comprises an S1 tunneling server. 36 . A system according to claim 29 wherein a Tunneling Application Server is provided for integrating Tunneling management at the Core Segment. 37 . A system according to claim 29 wherein both a Tunneling Application Server, for integrating Tunneling management at the Core Segment, and an S1 Tunneling Server are provided, and wherein each encapsulated transmission is sent, depending on at least one of: user priority, required latency, user type, service type, to the Tunneling Application Server, to the S1 Tunneling Server, or to both. 38 . A system according to claim 35 wherein the S1 Tunneling Server is located between a base station and a Core Segment defined by the core and interfaces the base station using a standard S1 interface. 39 . A system according to claim 35 wherein a first block in an Inbound flow may be a mobile base station filter which sorts incoming user-plane packets of an S1-U interface. 40 . A system according to claim 29 wherein the core comprises an S1 tunneling server and wherein a first block in an Inbound flow comprises a mobile base station filter operative to sort incoming user-plane packets of an S1-U interface and wherein the filter, by using a known list of mobile base stations, is operative to detect the mobile base stations' packets, to filter said packets from the S1-U stream and to send the stream without the mobile base stations' packets directly to a Core segment defined by the core, wherein the filter is operative to send the stream without the mobile base stations' packets directly to a Core segment defined by the core using a standard Inbound S1-U interface and to send the stream of only mobile base stations packets to the Tunneling Subsystem using an S1-U protocol interface. 41 . Apparatus for use with a hierarchical cellular network system having a core and comprising a plurality of nodes, the apparatus comprising: at least one node which comprises a mobile relay having both base station and mobile communicator functionalities and operative to serve mobile communicators, including at least one relay other than said mobile relay, and to be served by at least one relay other than said mobile relay, and a Virtual Radio Access Network Manager which resides in a tunneling application server residing in the core, and which is operative to reflect each mobile base station back to a core segment defined by the core as a real base station, and wherein at least said mobile relay includes: a tunneling subsystem; and a backhauling link subsystem interfacing between the tunneling subsystem and a closer node from among said plurality of nodes which is closer to the core than said mobile relay; the base station functionality interfacing between the tunneling subsystem and a mobile station or a further node from among said plurality of nodes which is further from the core than said mobile relay, wherein the tunneling subsystem is operative to perform the following, on data arriving from the base station functionality: collecting said data including analyzing to identify, within said data, results to be sent; and encapsulating the results to be sent into packets and sending said packets to said Backhauling Link Subsystem, wherein the Tunneling Subsystem is operative to process incoming mobile base station only packets stream for every sole mobile base station detected, in a recursive manner in order to decapsulate tunnel-inside-tunnel cases and wherein, after mobile base stations' packets have been unfolded, to generate unfolded data, the Tunneling Subsystem is operative to transfer said unfolded data to a Virtual Radio Access Network Manager that reflects each of the mobile base stations to a core segment. 42 . Apparatus according to claim 41 wherein the Virtual Radio Access Network Manager is operative to reflect each mobile base station back to the Core Segment defined by the core as a real base station using a standard RAN-to-Core interface. 43 . Apparatus according to claim 41 wherein the Virtual Radio Access Network Manager reflects each of the mobile base stations to a Core segment which is defined by the core as a virtual base station. 44 . The system according to claim 41 wherein the Virtual Radio Access Network Manager is operative, using data arriving at the Virtual Radio Access Network Manager from all mobile base stations, to build a topology of all mobile base station sub-networks including a list of all users attached to the Virtual Radio Access Network Manager. 45 . A system according to claim 41 wherein the Virtual Radio Access Network Manager is also operative to function as a proxy of the MeNBs interfacing the core by “reflecting” each of the mobile base stations to a Core segment defined by the care as a “virtual” base station using a standard S1 interface such that a multi-S1 interface is created. 46 . The system according to claim 41 wherein the Virtual Radio Access Network Manager is operative to function as a proxy of MeNBs interfacing the core by reflecting each of the mobile base stations using a standard S1 interface thereby to create a multi-S1 interface. 47 . The system according to claim 41 wherein the Virtual Radio Access Network Manager is also operative to pass packets and attached instructions, at least said attached instructi