Abstract: Femto nodes provide Local IP Access (LIPA) which allows terminals to communicate with local area networks that the femtocells reside in using cellular air-interfaces (such as cdma2000, UMTS or LTE). Femto nodes also enable Remote IP Access (RIPA) service, which allows the terminals to access the local area network from the Internet as if they were present in the local area networks. Further, to avoid degradation of standby time of the terminals or the capacity of the femto node, or both, apparatus and methods are described herein in which a femto node consolidates received Broadcast/Multicast IP packets from a local area network prior to delivering the packets to terminals over a cellular air-interface. In other aspects, a femto node may deliver the received Broadcast/Multicast IP packets via a cellular one-to-many transmission, either with or without consolidation.

Abstract: Femto nodes provide Local IP Access (LIPA) which allows terminals to communicate with local area networks that the femtocells reside in using cellular air-interfaces (such as cdma2000, UMTS or LTE). Femto nodes also enable Remote IP Access (RIPA) service, which allows the terminals to access the local area network from the Internet as if they were present in the local area networks. Further, to avoid degradation of standby time of the terminals or the capacity of the femto node, or both, apparatus and methods are described herein in which a femto node consolidates received Broadcast/Multicast IP packets from a local area network prior to delivering the packets to terminals over a cellular air-interface. In other aspects, a femto node may deliver the received Broadcast/Multicast IP packets via a cellular one-to-many transmission, either with or without consolidation.

Abstract: According to some wireless network standards the size of a neighbor cell list is restricted to a maximum size. The limited size of a neighbor cell list may not reflect the realities of a wireless network deployment, especially for deployments including numerous femto cells clustered in close proximity. Accordingly, as the concentration of macro cells and/or femto cells in an area increases, there lies a challenge to identify and communicate neighbor lists to user devices that reflect the arrangement of a particular portion of the deployment and the needs of the user devices. Various systems, methods and apparatus described herein are configured to provide a user device or a group of user devices a neighbor cell list that includes neighbor cell identifiers chosen from a candidate list.

Abstract: A heterogeneous communication system enables femto Access Points (APs) to advertise handoff related information on a first Radio Access Technology (RAT), such as for receipt by a multi mode mobile device (e.g., a mobile device capable of operation on a plurality of RATs), wherein the handoff related information permits the multi mode mobile device to identify the femto access point on a second RAT. The multi mode mobile device can be connected to a macro node (e.g., a macro base station, an evolved Base Node, etc.) using the first RAT via a Wireless Wide Area Network (WWAN) air-interface (e.g., 1×, HRPD, eHRPD), while independently reading/decoding overhead messages on the second RAT for connection thereto (e.g., connection to the femto access point on the second RAT.) The second RAT can be another WWAN, a Wireless Local Access Network (WLAN) or a Personal Access Network.

Abstract: An access point is identified based on a plurality of pilot signatures. Here, in addition to transmitting a pilot signal that is encoded (e.g., spread/scrambled) using a particular pilot signature, an access point transmits a message that includes at least one indication of at least one other pilot signature. For example, an access point may use one PN offset to generate a pilot signal and transmit a message that identifies at least one other PN offset. An access terminal that receives the pilot signal and the message may then generate a pilot report that identifies all of these pilot signatures. Upon receiving a handover message including this pilot-related information, a target network entity with knowledge of the pilot signatures assigned to that access point may then accurately identify the access point as a target for handover of the access terminal.

Abstract: An access point is identified based on a plurality of pilot signatures. Here, in addition to transmitting a pilot signal that is encoded (e.g., spread/scrambled) using a particular pilot signature, an access point transmits a message that includes at least one indication of at least one other pilot signature. For example, an access point may use one PN offset to generate a pilot signal and transmit a message that identifies at least one other PN offset. An access terminal that receives the pilot signal and the message may then generate a pilot report that identifies all of these pilot signatures. Upon receiving a handover message including this pilot-related information, a target network entity with knowledge of the pilot signatures assigned to that access point may then accurately identify the access point as a target for handover of the access terminal.

Abstract: Access by a mobile station to a femto access point (FAP) of a wireless communication system is controlled by an enforcement point in response to mobile station authorization data provided from a storage point that is remote from the FAP. The authorization data is provided in response to FAP authentication data. The authentication data may include a FAP identifier and a message authenticator that the FAP generates by hashing shared secret information. The storage point may provide the authorization data in response to determining that the message authenticator is a hash of the shared secret information.