Abstract: The present disclosure advantageously provides a system, a computer-readable medium and a method for synthesizing a Network-on-Chip (NoC). A plurality of route feature vectors are determined based on a network configuration for the NoC. The network configuration includes bridge ports, routers, connections and routes. A link size is determined for each router by providing route feature vectors to a supervised learning-based (SLB) model. The SLB model generates a plurality of route label vectors based on the route feature vectors. Each route label vector is associated with a route feature vector, and includes the link size and a route position for each router. A resizer is added between a bridge and a router with different link sizes or between adjacent routers with different link sizes. Pipeline and retiming components are added based on timing. An output specification is then generated for the NoC.

Abstract: A user equipment (UE) is provided. The UE includes one or more non-transitory computer-readable media having computer-executable instructions embodied thereon and at least one processor coupled to the one or more non-transitory computer-readable media. The at least one processor is configured to execute the computer-executable instructions to perform following actions: Receive, from a base station, a block error rate (BLER) related restriction for each of a plurality of configured logical channels. Receive, from the base station, an uplink (UL) grant. Obtain a BLER related characteristic of the UL grant. Select, among the plurality of configured logical channels, one or more logical channels for the UL grant, according to the BLER related characteristic of the UL grant and the BLER related restriction for each of the plurality of configured logical channels when a first condition is met. Allocate the UL grant to the selected one or more logical channels.

Abstract: Disclosed are embodiments related to implementing a dynamic resource allocation and transmission scheme for a fifth generation (5G) physical uplink control channel (xPUCCH) in a 5G system. In particular, embodiments include mechanisms to dynamically allocate resources for the transmission of xPUCCH, and resource mapping schemes for 5G systems supporting more than one symbol allocated for an xPUCCH transmission.

Abstract: An aspect of the disclosure provides a method of network slice management performed by a Communication Service Management Function (CSMF). The method includes receiving service requirements and receiving capability exposure information. The method further includes transmitting network slice requirements in accordance with the service requirements and capability exposure information. In some embodiments the capability exposure information is received from a Network Slice Management Function (NSMF). In some embodiments the network slice requirements are transmitted to the NSMF. Other aspects are directed to methods implemented by an NSMF and a Network Sub-Slice Management Function (NSSMF). Other aspects are directed to the network functions themselves.

Abstract: Bandwidth part (BWP) switching may benefit a wireless communications system. Such BWP switching may include indication of one or more timing parameters used for time domain resource allocation. For example, the timing parameters may be indicated based on an index to a look-up table (e.g., a bit field in a control transmission). In some cases, one or more tables may be configured for a given BWP, and different tables may contain a different number of rows. The size of the bit field indexing the table may in turn depend on the number of rows. When switching from a first BWP to a second BWP, the size of the bit field may be based on the table of the first BWP, but the bit field may index the table of the second BWP. Techniques supporting improved timing parameter management during BWP switching are discussed herein.

Abstract: Priority handling in a communications system. The system comprises one or more data bearers and a priority handling module. Each of the one or more bearers is configured to transport one or more of the data flows. The priority handling module is configured to prioritize between data flows, and is further configured to: receive a request for priority configuration or re-configuration of a first data flow; obtain a priority sharing identifier of the first data flow; identify other data flows in the communication system having the priority sharing identifier of the first transport data flow; and update priority rules associated with the first data flow and also with any other identified data flows in the communication system having the priority sharing identifier of the first transport data flow to agree with a shared priority rule.

Abstract: A method and apparatus for synchronization in an orthogonal frequency division multiplexing (OFDM) network is disclosed. A wireless transmit/receive unit (WTRU) is configured to receive a primary synchronization signal and a secondary synchronization signal from a cell. The primary synchronization signal and the secondary synchronization signal are spaced by a known number of OFDM symbols. The primary synchronization signal and the secondary synchronization signal are received in a same number of subcarriers in their respective OFDM symbol. A location of at least the secondary synchronization signal in the system bandwidth is variable.

Abstract: A method, an apparatus, and a computer program product for wireless communication are provided. According to one embodiment, a method of operating a device includes: selecting a signal format from a plurality of signal formats, each of the plurality of signal formats corresponding to a respective coding and modulation scheme of a plurality of coding and modulation schemes; and sending a request for random access to a base station according to the selected signal format.

Abstract: A high throughput satellite (HTS) and a method of operating the HTS for relaying data between a low earth orbit (LEO) satellite and a target ground station, where the HTS provides spot beams for a spot beam coverage area. The method of operating the HTS includes: determining an estimated trajectory of an orbiting LEO satellite; assigning a plurality of assigned spot beams having a matching color re-use polarization; and transmitting assignments of the plurality of assigned spot beams to the high throughput satellite to cause the high throughput satellite to maintain the inter-satellite link via a first spot beam and one or more assigned subsequent spot beams having the matching color re-use polarization.

Abstract: An aspect of the disclosure provides a method of network slice management performed by a Communication Service Management Function (CSMF). The method includes receiving service requirements and receiving capability exposure information. The method further includes transmitting network slice requirements in accordance with the service requirements and capability exposure information. In some embodiments the capability exposure information is received from a Network Slice Management Function (NSMF). In some embodiments the network slice requirements are transmitted to the NSMF. Other aspects are directed to methods implemented by an NSMF and a Network Sub-Slice Management Function (NSSMF). Other aspects are directed to the network functions themselves.

Abstract: Disclosed are a method and device for eliminating inter-cell interference, which are applicable to elimination of inter-cell interference cancellation. The method comprises: a first transceiving node obtains interference information of a potential interference cell, wherein the potential interference cell belongs to a second transceiving node, and the interference information of the potential interference cell comprises at least one of the following items: duplex mode information of the potential interference cell, multiple access technique information of the potential interference cell, a physical layer parameter of the potential interference cell in each of at least one first transmission resource pool, and resource allocation information of the potential interference cell in each of at least one second transmission resource pool; and the first transceiving node transmits the interference information of the potential interference cell to a first terminal device.

Abstract: A wireless device can perform Out-of-Order packet processing and block acknowledgement. Multiple packets may be received at a lower layer of the wireless device. Identifying information may be determined for the received packets. It may be determined that the packets were received out of sequential order, based at least in part on the identifying information. Despite being received out of sequential order, payload information from the packets may be provided to a higher layer of the wireless device in a non-sequential order, such as the order of receipt.

Abstract: Provided are a data processing method, device and node. The method includes: a second node determines that a first data sent from a first node exhibits data erasure; the second node sends feedback information to the first node, where the feedback information includes one of the following: an erasure rate, an erasure rate and an erasure position, the erasure rate is a proportion of resources that exhibit data erasure in resources corresponding to the first data, and the erasure position is a position of the resources that exhibit data erasure in the resources corresponding to the first data; the second node receiving a second data as determined according to the feedback information by the first node; the second node performs decoding according to the first item of data and the second data.

Abstract: A first communication device determines assignment of at least a first orthogonal frequency division multiplex (OFDM) tone block and a second OFDM tone block for communication with a second communication device in a wireless local area network (WLAN). The first OFDM tone block is separated from the second OFDM tone block by a gap in frequency. The first communication device generates a physical layer (PHY) data unit for transmission to the second communication device, including generating a data portion of the PHY data unit that spans the first OFDM tone block and the second OFDM tone block. The first communication device transmits the PHY data unit to the second communication device via the first OFDM tone block and the second OFDM tone block such that no data is transmitted in the third OFDM tone block for the data portion of the PHY data unit.

Abstract: The present disclosure relates to a pre-5th-Generation (5G) or 5G communication system to be provided for supporting higher data rates Beyond 4th-Generation (4G) communication system such as Long Term Evolution (LTE). A method for preventing a loss of data packets of a transmission end is provided.

Abstract: Techniques for implementing deadlock avoidance in a leaf-spine network are described. In one embodiment, a method includes monitoring traffic of a plurality of packets at a leaf switch in a network having a leaf-spine topology. The method includes marking a packet with an identifier associated with an inbound uplink port of the leaf switch when the packet is received from one of a first spine switch and a second spine switch. The method includes detecting a valley routing condition upon determining that the packet marked with the identifier is being routed to an outbound uplink port of the leaf switch to be transmitted to the first spine switch or the second spine switch. Upon detecting the valley routing condition, the method includes dropping packets associated with a no-drop class of service when a packet buffer of the inbound uplink port reaches a predetermined threshold.

Abstract: A communication apparatus compatible with an IEEE 802.11ax standard that enables multi-user communication in which signals for one or more other communication apparatuses are multiplexed and transmitted, the communication apparatus determines, in a case where the multi-user communication is uplink communication, whether an incompatible apparatus exists around the communication apparatus, the incompatible apparatus being compatible with any of standards of an IEEE 802.11 series that precede the IEEE 802.11ax standard and incompatible with the IEEE802.11ax standard, and transmits, in a case where it is determined that the incompatible apparatus exists around the communication apparatus, an MU-RTS (Multi User Request To Send) frame before data communication through the multi-user communication.

Abstract: Systems, methods, and software can be used to detect resource access. In some aspect, a monitoring period for monitoring resource access on an electronic device is determined. A number of accesses to a resource on the electronic device made by an application during the monitoring period is determined. Information associated with at least one access to the resource is outputted on the electronic device.

Abstract: A method for controlling handover of a user equipment device (UE) between a first access node and a second access node. The first access node could select a handover process with the selecting being based on whether (i) the source access node and target access nodes are both dual-connectivity capable or both not dual-connectivity capable or rather (ii) one of the access nodes is dual-connectivity capable and the other of the access nodes is not dual-connectivity capable. For example, if both are dual-connectivity capable or not dual-connectivity capable, then the source access node could opt for X2 handover. Whereas if one is dual-connectivity capable and the other is not dual-connectivity capable, then the source access node could opt for S1 handover.

Abstract: Certain aspects relate to methods and apparatus for latency reduction for UEs in a RRC connected mode. During contention-based uplink access by groups of UEs within a subframe, an eNB may decode the received uplink transmission based, at least in part, on the assigned group of resources assigned to the UE and used for transmission. Additional orthogonalization techniques such as reduced TTI size can be used to reduce collisions among different users performing contention-based transmissions. Furthermore, when the eNB fails to successfully decode the uplink transmission, the eNB may identify the UE that sent the uplink transmission based on a detected reference signal and may transmit an uplink assignment to the identified UE.