Abstract: User equipment determines a transport block size column indicator representative of a number of resource blocks based on a number of allocated resource blocks, an adjustment factor, and a limiting factor. The transport block size column indicator is determined by applying the adjustment factor to the number of allocated resource blocks and comparing a result of applying the adjustment factor to the number of allocated resource blocks to the limiting factor. The transport block size column indicator is selected as either the result or the limiting factor as the based on the comparison.

Abstract: In a method of detecting a transmission bandwidth configuration, the method includes monitoring (610) a first set of control channel candidates in a subframe (424) using a first transmission bandwidth and includes monitoring (612) a second set of control channel candidates using a second transmission bandwidth. The method also includes detecting (614) a control channel (428) in one of the first set of control channel candidates and the second set of control channel candidates and includes determining (616) a transmission bandwidth (421, 423) configuration for the subframe based on the detected control channel of one of the first set of control candidates and the second set of control channel candidates.

Abstract: A base station communicates a positioning reference signal (PRS) to wireless communication devices over a downlink in a wireless communication system by encoding a PRS into a first set of transmission resources, encoding other information into a second set of transmission resources, multiplexing the two sets of resources into a subframe such that the first set of resources is multiplexed into at least a portion of a first set of orthogonal frequency division multiplexed (OFDM) symbols based on an identifier associated with the base station and the second set of resources is multiplexed into a second set of OFDM symbols. Upon receiving the subframe, a wireless communication device determines which set of transmission resources contains the PRS based on the identifier associated with the base station that transmitted the subframe and processes the set of resources containing the PRS to estimate timing (e.g., time of arrival) information.

Abstract: User equipment determines a transport block size column indicator representative of a number of resource blocks based on a number of allocated resource blocks, an adjustment factor, and a limiting factor. The transport block size column indicator is determined by applying the adjustment factor to the number of allocated resource blocks and comparing a result of applying the adjustment factor to the number of allocated resource blocks to the limiting factor. The transport block size column indicator is selected as either the result or the limiting factor based on the comparison.

Abstract: Disclosed are methods for codebook sub-sampling. In various implementations, a wireless terminal receives a reference signal, determines, based on the reference signal, a first precoding index i2 for a first subband and a second precoding index i?2 for a second subband. The wireless terminal transmits a representation of i2 and a representation of i?2 to a base station. In various implementations, i?2 belongs to the set Si2 which, in one implementation, equals {mod(i2?K1+k,K), k=0,1 , . . . , K2}, where K1>1, and where K2>1 and K>1 are integers. According to an implementation, the wireless terminal receives the reference signal from a first base station and transmits the representations of i2 and i?2 to a second base station.

Abstract: A communication system provides for adaptive rank determination, for example, a rank 2 transmission in instances where a rank 1 transmission may be indicated under supported feedback modes in current standards where no explicit power adaptation can be assumed, for example, where a user equipment (UE) is limited to reporting a rank 1 channel due to a large dynamic range of a signal or due to a signal received by the UE from one base station (BS) antenna port drowning out a signal received by the UE from another BS antenna port. The communication system provides for the UE to implement rank 2 transmission in such instances by using per-antenna port power control at a BS serving the UE. In one embodiment, the BS controls the rank determination at the UE by signaling transmit power or power offset related parameters to use for rank and transmission parameters determination and feedback.

Abstract: A multimode wireless communication terminal that communicates using a first radio access technology (RAT) and a second RAT determines whether the first and second RATs are in an active state, and modifies a maximum transmit power limit of the first RAT based on a voice codec rate of a voice transmission on the second RAT when the first RAT and the second RAT are in the active state concurrently, wherein the second RAT is conducting the voice transmission in the active state. In an alternative embodiment, the limit is modified based on a transmit power status of the second RAT or on a transmission type of the first RAT.

Abstract: The present invention provides a method of scheduling asynchronous transmissions for a plurality of subscriber units. The method includes receiving information associated with a plurality of subscriber units that have uplink data to transmit, the information including uplink timing offset information associated with each of the subscriber units. Two or more subscriber units are then selected from a set of subscriber units having a timing offset differential, that is below a predetermined threshold, where the timing offset differential is the difference between the timing offset of a first subscriber unit and the timing offset of a second subscriber unit further selectively offset by a multiple of the transmission segment size, which minimizes the difference.

Abstract: A method and apparatus is provided for transmitting an orthogonal frequency domain multiple access (OFDMA) signal including a synchronization channel signal transmitted including a plurality of sequence elements interleaved in time and frequency. The synchronization channel signal sequence elements enable an initial acquisition and cell search method with low computational load by providing predetermined time domain symmetry for common sequence elements in OFDMA symbol periods for OFDMA symbol timing detection and frequency error detection in an OFDMA system supporting multiple system bandwidths, both synchronized and un-synchronized systems, a large cell index and an OFDMA symbol structure with both short and long cyclic prefix length.

Abstract: Pursuant to at least some embodiments, the present invention relates to a method that includes equipping a peripheral device with an RFID tag. The RFID tag includes a memory device configured for electronically storing information, an RF receiver configured for receiving an interrogation signal, and an RF transmitter operatively coupled to the RF receiver and the memory device. The method further includes configuring the RF transmitter for: (a) modulating an RF carrier with the electronically stored information from the memory device, and (b) transmitting the modulated RF carrier, in response to the RF receiver receiving the interrogation signal; and displaying or outputting a message on the peripheral device using the received interrogation signal.

Abstract: Pursuant to at least some embodiments, the present disclosure relates to a peripheral device that is equipped with an RFID tag. The RFID tag includes a memory device configured for electronically storing information, an RF receiver configured for receiving an interrogation signal, and an RF transmitter operatively coupled to the RF receiver and the memory device. The RF transmitter is configured for: (a) modulating an RF carrier with the electronically stored information from the memory device, and (b) transmitting the modulated RF carrier, in response to the RF receiver receiving the interrogation signal. The received interrogation signal is used to control one or more operational states of the peripheral device. Illustratively, the one or more operational states include powering the peripheral device to an “on” state.

Abstract: Pursuant to at least some embodiments, the present disclosure relates to a method that includes configuring an RFID tag to store information related to a battery charge level of a battery of a peripheral device, reading the RFID tag, and disabling a subsequent reading of the RFID tag in response to determining that the RFID tag includes stored information indicative of the battery charge level being low or depleted.

Abstract: A downlink subframe on a single downlink carrier supports physical layer acknowledgment signaling for multiple physical uplink shared channel (PUSCH) transmissions. The physical layer acknowledgement signaling may take the form of physical hybrid ARQ indicator channel (PHICH) signaling. A base unit reserves resource elements groups (REGs) for default PHICH signaling of default PUSCH transmissions. The base unit reserves control channel elements (CCEs) for physical downlink control channel (PDCCH) signaling. A CCE contains multiple interleaved REGs. The base unit takes any unreserved CCEs and maps those CCEs for physical layer acknowledgement signaling of additional PUSCH transmissions.

Abstract: A method, telecommunication apparatus, and electronic device for detecting a status of a radio link are disclosed. A transceiver 302 may maintain a radio link with a network base station 104. A processor 304 may map channel state information to a synchronization status associated with the radio link based on the received signal and determine the synchronization status via a block error rate estimate in the radio link based on the channel state information.

Abstract: Disclosed are methods for codebook sub-sampling. In various implementations, a wireless terminal receives a reference signal, determines, based on the reference signal, a first precoding index i2 for a first subband and a second precoding index i2? for a second subband. The wireless terminal transmits a representation of i2 and a representation of i2? to a base station. In various implementations, i2? belongs to the set Si2 which, in one implementation, equals {mod(i2?K1+k,K), k=0, 1, . . . , K2}, where K1>1, and where K2>1 and K>1 are integers. According to an implementation, the wireless terminal receives the reference signal from a first base station and transmits the representations of i2 and i2? to a second base station.

Abstract: A multimode wireless communication terminal that communicates using a first radio access technology (RAT) and a second RAT determines whether the first and second RATs are in an active state, and modifies a maximum transmit power limit of the first RAT based on a voice codec rate of a voice transmission on the second RAT when the first RAT and the second RAT are in the active state concurrently, wherein the second RAT is conducting the voice transmission in the active state. In an alternative embodiment, the limit is modified based on a transmit power status of the second RAT or on a transmission type of the first RAT.

Abstract: A method and apparatus operate a user client wireless communication device on a wireless wide area network. A communication link can be established at the user client wireless communication device with a user wireless wide area network communication device. A random challenge and an authentication token can be received from a wireless wide area network. The random challenge and the authentication token can be sent to the user wireless wide area network communication device. The at least one temporary wireless wide area network communication security key can be received from the user wireless wide area network communication device, where the at least one temporary wireless wide area network communication security key is for the wireless wide area network.

Abstract: A method and apparatus operate a user client wireless communication device on a wireless wide area network. A communication link can be established at the user client wireless communication device with a user wireless wide area network communication device. At least one temporary wireless wide area network communication security key for a wireless wide area network can be requested from the user wireless wide area network communication device. The at least one temporary wireless wide area network communication security key can be received from the user wireless wide area network communication device. At least one count of a number of uplink non access stratum messages transmitted by the user wireless wide area network communication device can be received.

Abstract: A method includes: a wireless communication device (WCD) receiving information indicating that a second user device that is close-by is actively running a messaging application, which establishes an active communication channel with a communication service that is responsible for routing incoming voice and data communication to the WCD. The method also includes: establishing a short range communication between the communication device and the second user device; in response to receiving the information and establishing the short range communication, placing at least a first modem of the WCD in a sleep state; and in response to at least one subsequent trigger event, awakening the first modem to an active state to enable use of the first modem to complete communication. The messaging service is configured to redirect incoming calls to the second user device while the messaging service is active and the devices are within short-range communication of each other.

Abstract: A wireless terminal is capable of receiving a pilot signal from a base station; and determining a precoding matrix as a linear combination of two matrices V1 and V2 based on the received pilot signal. In one implementation, the two matrices V1 and V2 are sub-matrices of a matrix U of a codebook, the linear combination is u:=(V1+?V2)/?{square root over (1+|?|2)} and ? is one of a real-valued number and a complex-valued number. The wireless terminal is also capable of transmitting a representation of at least a portion of the precoding matrix to the base station.