Abstract: Encoding/decoding method comprising the derivation of the elements of base matrices for Quasi-Cyclic LDPC, codes using different lifting sizes to obtain variable code lengths. The cyclic shift values of smaller lifting sizes Z are derived from stored elements a base matrix corresponding to a maximal lifting sizes Zmax by applying right shifting (ceil(log 2Z/Zmax) times) to a binary vector representation of all non-negative stored elements of the base matrix corresponding to Zmax. The right shifting operation may be applied only when the stored cyclic shift value corresponding to Zmax is larger than the smaller lifting size Z. Application to an encoder/decoder within a wireless communications network, a magnetic storage system or a solid-state drive system.

Abstract: According to some embodiments, a method for use in a wireless receiver comprises determining a transport block size, TBS, for a transport block to be communicated between the wireless transmitter and a wireless receiver via a physical channel transmission. The TBS determination uses a formula accounting for cyclic redundancy check, CRC, bits. The method further comprises transmitting the transport block according to the determined TBS. In particular embodiments the formula is based on an approximate transport block size, a number of code blocks, at least one of a number of CRC bits attached to the transport block, and a number of CRC bits added to each of the C code blocks.

Abstract: Systems and methods are disclosed that relate to signaling of Time Division Duplexing (TDD) subframe use to short Transmit Time Interval (sTTI) wireless devices. In some embodiments, a method of operation of a network node in a cellular communications network comprises signaling, to a wireless device, an indication of a TDD subframe set to use, where the TDD subframe set specifies subframe selection for legacy transmissions and sTTI, transmissions. In this manner, both sTTI transmissions can be made in selected legacy TDD subframes, which provides latency reduction in frame alignment and Hybrid Automatic Repeat Request (HARQ) Round Trip Time (RTT) for TDD.

Abstract: The present disclosure relates to a spare wheel cavity for a vehicle. The spare wheel cavity is configured to store a collision-sensitive object and comprises a bottom wall and a side wall. The spare wheel cavity further comprises a carrier plate directly or indirectly attached to the bottom wall and a reinforcement structure located in or at the bottom wall in front of the carrier plate and/or below a front portion of the carrier plate. The carrier plate is configured to carry the collision-sensitive object on an object carrying portion of the carrier plate. The disclosure further relates to an arrangement comprising the spare wheel cavity, as well as a collision-sensitive object and/or a spare wheel. The disclosure also relates to a method of reducing a risk of a stack-up problem in case of a rear collision.

Abstract: Systems and methods for collision handling between transmissions using a first Transmission Time Interval (TTI) and transmissions using a second TTI, such as a legacy TTI and a short TTI (sTTI), are provided. In some embodiments, the proposed solution helps the UE handle collisions between transmissions using legacy TTI in UL and overlapping transmissions using short TTI in UL. In some embodiments, this is accomplished by a wireless device adapted for uplink transmissions using a first TTI or a second TTI where the second TTI is shorter than the first TTI. The method includes altering at least one transmission of a first transmission using the first TTI and a second transmission using the second TTI based on a determination that a collision is to occur between the first transmission and the second transmission.

Abstract: A method of producing a set of coded bits from a set of information bits for transmission between a first node (110, 115) and a second node (110, 115) in a wireless communications system (100), the method comprises generating (904) a codeword vector by encoding the set of information bits with a low-density parity-check code, wherein the codeword vector is composed of systematic bits and parity bits. The method comprises performing (908) circular buffer-based rate matching on the generated codeword vector to produce the coded bits for transmission, wherein the circular buffer-based rate matching comprises puncturing a first plurality of systematic bits.

Abstract: There is disclosed a method for adapting HARQ buffers in a wireless device (90), said device is adapted for HARQ communication, the method comprising determining (10) a size of a HARQ buffer, the HARQ buffer size being based on a TTI. There is also disclosed a wireless device (90) adapted for HARQ communication, the wireless device comprising a processing circuitry and a memory, said memory containing instructions executable by said processing circuitry, whereby said wireless device is operative to determine a size of a HARQ buffer, the HARQ buffer size being based on a TTI.

Abstract: A wireless device, network node and method for communication between wireless devices and network nodes are provided. According to one aspect, a wireless device configured to communicate with a network node in a wireless communication system is provided. The wireless device includes processing circuitry configured to form at least one of an uplink, UL, signal and a downlink, DL, signal during at least one short transmission time interval, sTTI, in a special sub-frame of a radio frame to create an sTTI-containing special subframe. The wireless device further includes a transceiver configured to communicate with the network node by one of sending the uplink signal and receiving the downlink signal during the at least one sTTI.

Abstract: The disclosure pertains to selecting a Transport Block Size (TBS) in a communication system. An aspect is directed to an apparatus for selecting a Transport Block Size (TBS) for a transmitter of a communication system. The communication system supports variable Transmission Time Interval (TTI) lengths regarding the number of symbols to be transmitted in one TTI. The apparatus is configured to receive first information indicative of a TTI length, receive second information indicative of a number of reference symbols included in the TTI, decode, from the first information, the TTI length, and decode, from the second information, the number of reference symbols included in the TTI.

Abstract: The invention relates to a method for controlling the operation of a submersible power plant (1) and a submersible power plant (1). The submersible power plant (1) comprises a structure (2) and a vehicle (3). The vehicle (3) comprises at least one wing (4). The vehicle (3) is arranged to be secured to the structure (2) by means of at least one tether (5). The vehicle (3) is arranged to move in a predetermined trajectory by means of a fluid stream passing the vehicle (3). The vehicle (3) is arranged to change the angle of attack of the at least one wing (4). The method comprises: I: determining if the speed of the fluid passing the vehicle (3) is higher than a predetermined value; or II: determining if the speed of the fluid passing the vehicle (3) is lower than the predetermined value. The vehicle (3) changes the angle of attack for different situations depending on if the speed is higher or lower than the predetermined trajectory.

Abstract: A motive system for a patient lifting assembly, a patient lifting assembly and a method of operating a patient lifting assembly. The motive system includes an electric motor, numerous sensors and an adaptive control unit cooperative with one another so that a memory and processor that are part of the control unit that can respectively store and execute a computer readable and executable instruction set. By comparing collected data from the sensors during operation of the motor to corresponding reference values associated with one or more motor operational parameters—such as accumulated motor wear over time or differences in operating temperature of the motor—the system can selectively adjust the maximum amount of current available for use by the motor. In this way, changes in motor efficiencies that arise with these parametric changes can be taken into consideration when determining an upper limit on how much electrical current may be delivered to the motor for a given load.

Abstract: In one aspect, a wireless device receives a first data transmission from a base station in a first subframe interval and transmits HARQ feedback and/or CSI to the base station in a subsequent subframe interval, within a duration that is less than a maximum transmission duration that is possible within the subsequent subframe interval. In another aspect, a base station transmits a first data transmission to a wireless device in a first subframe interval and receives HARQ feedback and/or CSI from the wireless device in a subsequent subframe interval, within a duration that is less than a maximum transmission duration that is possible within the subsequent subframe interval.

Abstract: The present disclosure relates to packaging of feedback information bits in a wireless communication system. Some embodiments are applicable to both Frequency Division Duplexing (FDD) and Time Division Duplexing (TDD) systems, whereas other embodiments are particularly well-suited for TDD systems. In some embodiments, a method of operation of a wireless device in a cellular communications network comprises receiving, from the cellular communications network, an indication of one of a plurality of predefined sets of feedback information codebook sizes, the plurality of predefined sets of feedback information codebook sizes being disjoint subsets of a plurality of predefined feedback information codebook sizes. In some embodiments, the indication enables the wireless device to return an expected number of feedback information bits to the cellular communications network, particularly in a saturation where the wireless device misses one or more downlink assignments.

Abstract: According to one aspect of the teachings herein, a base station (20) schedules the transmission of uplink reference signals by a wireless device (16) separately from scheduling uplink data transmissions by the device (16). The separate scheduling may be done at specific times, under specific conditions, and with respect to specific devices (16) or groups of devices (16). Separate scheduling allows, for example, the base station (20) to use smaller scheduling intervals that are possible when uplink reference signals are integrally included in any scheduled uplink data transmission. As a further advantage, the density or number of uplink reference signal transmissions by a given device (16) can be adapted, e.g., based on channel conditions, data transmission formats, etc.

Abstract: An embodiment herein discloses a method performed by a Base Station, BS. The BS determines a Hybrid Automatic Repeat Request-Acknowledgement, HARQ-ACK, codebook size for a User Equipment, UE, based on data to be transmitted in a data transmission to the UE. The HARQ-ACK codebook size indicates the number of HARQ-ACK bits that the UE encodes for transmitting Hybrid Automatic Repeat Request, HARQ, feedback for the data transmission to the BS. The BS further transmits an indication of the HARQ-ACK codebook size in a Downlink Assignment Index, DAI, field of a Downlink, DL, assignment to the UE.

Abstract: In one aspect, a wireless device receives a first data transmission from a base station in a first subframe interval and transmits HARQ feedback and/or CSI to the base station in a subsequent subframe interval, within a duration that is less than a maximum transmission duration that is possible within the subsequent subframe interval. In another aspect, a base station transmits a first data transmission to a wireless device in a first subframe interval and receives HARQ feedback and/or CSI from the wireless device in a subsequent subframe interval, within a duration that is less than a maximum transmission duration that is possible within the subsequent subframe interval.

Abstract: In one aspect, a wireless device receives a first data transmission from a base station during a predetermined subframe interval and within a duration that is less than a maximum data transmission duration that is possible within the predetermined subframe interval, and determines a transmission time for transmitting HARQ feedback to the base station such that the determined transmission time depends on which subset of symbols within the predetermined subframe interval was used for the first data transmission. The wireless device transmits HARQ feedback for the first data transmission at the determined transmission time. In another aspect, a base station transmits the first data transmission and determines a reception time for receiving HARQ feedback such that the determined transmission time depends on which subset of symbols within the predetermined subframe interval was used. The base station receives HARQ feedback for the first data transmission at the determined transmission time.

Abstract: A method in a communication system comprising a radio device and radio access network node, the method comprising and/or initiating a step of setting, in the radio device, a length of a transmission time interval (TTI) in a physical uplink control channel; a step of transmitting control information, by the radio device, over the physical uplink control channel with the set transmission time interval length; and a step of changing the transmission time interval length to be set by said radio device based on a channel or payload characteristic between said radio device and said radio access network node.

Abstract: The present disclosure relates to a gate system for an overhead lifting rail system, comprising: a first gate comprising: a rail portion for supporting a lifting carriage; and a bridging element pivotally coupled adjacent a proximal end to the rail portion; and a second gate comprising: a rail portion for suspending a lifting carriage; and a bridging element support portion. Upon the first gate engaging with the second gate, a distal end of the bridging element of the first gate engages with the bridging element support portion of the second gate to form a bridge between the first gate and the second gate; and the distal end of the bridging element and the bridging element support portion are configured such that the ends of the bridging element are substantially aligned with the respective ends of the rail portions of the first and second gates.

Abstract: Methods of operating a network node in a RAN may include transmitting control information for a subframe from the network node to a wireless terminal. The control information may include a Time Domain Split (TDS) indication defining a sub-subframe of the subframe, and a duration of the sub-subframe may be less than a duration of the subframe. Moreover, communication of data may be provided between the network node and the wireless terminal during the sub-subframe of the subframe. Methods of operating the wireless terminal may include receiving the control information for the subframe at the wireless terminal from the network node. The control information may include the TDS indication, and communication of the data may be provided between the wireless terminal and the network node during the sub-subframe of the subframe. Related network nodes and wireless terminals are also discussed.