Abstract: A method for transmitting data from a source to a destination. The method includes: transmitting the data from the source to both the destination and a relay station within a first transmission; decoding the data in the first transmitting at both the relay station and the destination wherein the destination acknowledges success of the decoding by generating a ACK message or lack of success by generating either a NACK message or by failing to generate the ACK signal; retransmitting from the source information related to the first transmission in response to either the NACK message or the failure of the destination to generate the ACK message; and wherein when the relay station decodes the data sent by the source within the first transmission correctly, the relay station transmits a second transmission; or, on the other hand, if the relay station is unable to decode the data correctly from the first transmission sent by the source, the relay station remains silent. The destination may be another relay station.

Abstract: An H-ARQ system wherein the transmission of two consecutive, or sequential, blocks of information bits are considered jointly; i.e., one of the blocks of information being embedded within the other one of the blocks of information. If a retransmission for the first block is necessary, the system processes both blocks jointly. The system is provided with cross-packet coding which extends current H-ARQ schemes for point-to-point communications wherein the transmission of two consecutive block of information bits is considered jointly. If a retransmission for the first block is necessary, the system processes both blocks jointly. This allows both blocks to be decoded without errors at the receiver after the retransmission.

Abstract: An H-ARQ system wherein the transmission of two consecutive, or sequential, blocks of information bits are considered jointly; i.e., one of the blocks of information being embedded within the other one of the blocks of information. If a retransmission for the first block is necessary, the system processes both blocks jointly. The system is provided with cross-packet coding which extends current H-ARQ schemes for point-to-point communications wherein the transmission of two consecutive block of information bits is considered jointly. If a retransmission for the first block is necessary, the system processes both blocks jointly. This allows both blocks to be decoded without errors at the receiver after the retransmission.

Abstract: In a method for communicating by radio, a frequency band divided up into a plurality of subcarriers is used for the communication. Messages are sent from a base station to a user station and/or from the user station to the base station. Messages are processed at some times using a first FDMA method such as for example OFDMA and at other times using a second FDMA method such as for example IFDMA. A transmitter and a receiver implement the method.

Abstract: Various example embodiments are disclosed herein. According to an example embodiment, a method may include receiving at a mobile station from a base station in a wireless network, a message including a group switch instruction instructing the mobile station to switch from a current group to a new group, attempting, by the mobile station, to switch to the new group in response to receiving the group switch instruction, and sending, from the mobile station, an acknowledgement message that acknowledges either the success or failure of the attempting to switch to the new group.

Abstract: Various example embodiments are disclosed herein. According to an example embodiment, a method may include receiving, at a serving base station (BS) in a wireless network from a mobile station (MS), group preference information for the MS for each of one or more candidate BSs; obtaining, by the serving BS based on the group preference information, a group assignment for the MS from each of the one or more candidate BSs; and sending by the serving BS to the MS the group assignment from each of the candidate BSs.

Abstract: Various example embodiments are disclosed herein. According to an example embodiment, an apparatus may include a controller, and a wireless transmitter coupled to the controller, the wireless transmitter configured to the wireless transmitter configured to transmit a Map message as part of a first group downlink (DL) region, the Map message allocating, to a full-duplex (FD) mobile station (MS), a first resource in a first group UL region and a second resource in a second group UL region. The transmitter may also be configured to transmit a dummy information element (IE), for example, as part of a second group DL region, the dummy information element (IE) reflecting at least the allocating to the FD MS of the second resource in the second group UL region.

Abstract: A base station and a method for handover of a mobile station from a serving base station to a target base station of a mobile telecommunication network. Invitations may be sent from a base station to the mobile station, and the invitations may be invitations to send a request for a fast handover procedure from the mobile station to a base station.

Abstract: Various example embodiments are disclosed herein. According to an example embodiment, an apparatus may include a wireless interface, and a controller, the apparatus being configured to: transmit a downlink subframe of a frequency division duplex (FDD) frame to one or more mobile stations in a wireless network, each wireless station being assigned to one of a plurality of groups, such as, for example, one of group 1 or group 2, the downlink subframe including at least: a group 1 portion and a group 2 portion, wherein a group boundary between the group 1 portion and the group 2 portion of the downlink subframe is variable, at least one of the group 1 portion and the group 2 portion including a group boundary information identifying a location of the group boundary or a location of the group 2 portion in the downlink subframe.

Abstract: Various example embodiments are disclosed herein. According to an example embodiment, an apparatus may include a controller, and a wireless transmitter coupled to the controller, the wireless transmitter configured to the wireless transmitter configured to transmit at least a portion of a frame via wireless link to one or more mobile stations in a wireless network, the at least a portion of a frame including: an all-group downlink region directed to group 1 half-duplex (HD) mobile stations, group 2 HD mobile stations, and full-duplex (FD) mobile stations, a group 1 downlink region directed to the group 1 HD mobile stations and the FD mobile stations, and a group 2 downlink region directed to the group 2 HD mobile stations and the FD mobile stations.

Abstract: An H-ARQ system wherein the transmission of two consecutive, or sequential, blocks of information bits are considered jointly; i.e., one of the blocks of information being embedded within the other one of the blocks of information. If a retransmission for the first block is necessary, the system processes both blocks jointly. The system is provided with cross-packet coding which extends current H-ARQ schemes for point-to-point communications wherein the transmission of two consecutive block of information bits is considered jointly. If a retransmission for the first block is necessary, the system processes both blocks jointly. This allows both blocks to be decoded without errors at the receiver after the retransmission.

Abstract: Various example embodiments are discloses. According to one example embodiment, a method may include sending a packet to both a relay station and a destination station in a wireless network, receiving a relay station acknowledgment (ACK) or negative acknowledgment (NACK) from the relay station during an ACK/NACK frame, and receiving a destination station ACK or NACK from the destination station during the ACK/NACK frame. The relay station ACK or NACK may either acknowledge or negatively acknowledge successful receipt of the packet by the relay station. The destination station ACK or NACK may either acknowledge or negatively acknowledge successful receipt of the packet by the destination station.

Abstract: A method for transmitting data in a wireless network includes generating a packet of data having a connection identification (CID) indicating a connection to a final destination for the packet of data. A desired path for transmitting the packet of data to the final destination is determined. The desired path includes one or more relay stations. The generated packet of data is encapsulated in one or more capsules, each capsule having a CID indicating a connection to one of the one or more relay stations along the desired path. The packet of data is routed along the desired path using the CIDs of the one or more capsules and the packet of data to arrive at the final destination. At each of the one or more relay station, an outer-most capsule having a CID corresponding to the present relay station is stripped from the packet of data.

Abstract: A method for transmitting data in a wireless network includes wirelessly transmitting data from a base station to a plurality of spatially separated relay stations. The data is correlated according to space-time block coding (STBC) for transmission over multiple antennas. The STBC correlated data are wirelessly transmitted from the plurality of spatially separated relay stations to a mobile station. The plurality of spatially separated relay stations cooperate to provide a single multiple antenna transmission.

Abstract: An orthogonal frequency division multiple access (OFDMA) frame for transmitting data between a mobile station and a base station includes a downlink subframe including a region for transferring first data to the base station and second data to a relay station at substantially the same time and frequency, and an uplink subframe.

Abstract: A method for transmitting a signal in a wireless network includes sending a first signal from a first source to a first intermediate station. A second signal is sent from a second source to a second intermediate station. The first signal is additionally received by the second intermediate station. The second signal is encoded according to dirty paper coding (DPC) such that the first signal does not interfere with the transmission of the second signal. The first signal is sent from the first intermediate station to a first destination and simultaneously, the DPC encoded second signal is sent from the second intermediate station to a second destination.

Abstract: Connection ID (CID) assignment in multi-hop relay system can be used to perform routing. Using CID assignment as routing information in a multi-hop wireless relay system to maintain the routing structure is disclosed. In a CID cache scheme, a base station builds a CID cache based on the upstream packet and broadcasts the CID cache to a relay station. The CID cache comprises CIDs along with routing information. Based on CID cache the spanning tree of the routing can be reconstructed. A hierarchical CID assignment is disclosed wherein a base station assigns a range of CIDs to a relay station. A relay station can recognize its data packets and forward them to corresponding mobile stations. Maintaining routing automatically along with CID assignment is also disclosed.

Abstract: Methods and systems for multihop routing in wireless transmission are disclosed. Routing is initiated and grown from a Base Station by a Network Entry Process for Relays. A Route Report Messages structure is disclosed and a Route Maintenance Message structure and message sub-block structures are also disclosed. A Quality-of-Service model for multihop routing is also disclosed.

Abstract: A method is provided wherein communication channel conditions are communicated between a relay station and a mobile station to a base station, comprising: transmitting from the mobile station to the relay station information indicating the communication channel conditions between the relay station and the mobile station, such information including pilots with the uplink data message from the relay station to the base station, dedicated ranging codes from the relay station to the base station or contention-based initial ranging codes from the relay station to the base station; instructing, when either the dedicated ranging codes or contention-based initial ranging codes, the relay station by the base station of the dedicated ranging or contention-based initial ranging method used and having a relay station monitored the ranging method; processing the information received by the relay station in the relay station into a channel condition report; and transmitting from the relay station to the base station the ch

Abstract: A method for transmitting data from a source to a destination. The method includes: transmitting the data from the source to both the destination and a relay station within a first transmission; decoding the data in the first transmitting at both the relay station and the destination wherein the destination acknowledges success of the decoding by generating a ACK message or lack of success by generating either a NACK message or by failing to generate the ACK signal; retransmitting from the source information related to the first transmission in response to either the NACK message or the failure of the destination to generate the ACK message; and wherein when the relay station decodes the data sent by the source within the first transmission correctly, the relay station transmits a second transmission; or, on the other hand, if the relay station is unable to decode the data correctly from the first transmission sent by the source, the relay station remains silent. The destination may be another relay station.