A method of scheduling field devices in a wireless network of an industrial process system is provided. The method is performed in a scheduling device and includes scheduling one or more field devices on uplink resources and on downlink resources, such that, for at least one of the field devices, a periodicity of uplink resources is different than a periodicity of downlink resources.

A device includes an interface and Time Division Multiple Access (TDMA) Medium Access Control (MAC) circuitry coupled to the interface. The TDMA MAC circuitry detects a beacon in a frame having a defined frame duration and determines a frame compensation value based on a start time of the frame, a reference start time of the frame, and a number of elapsed frames. A current frame duration value is determined based on the frame compensation value and the defined frame duration.

A plurality of integrated antenna structures described herein may be formed in a flat panel antenna arrays which may be arranged in equally spaced grid and may be used in transmitters for sending focused RF waves towards a receiver for wireless power charging or powering. Each of the integrated antenna structures may include planar inverted-F antennas (PIFAs) integrated with artificial magnetic conductor (AMC) metamaterials. As a result of their high directionality and form factor, the integrated antenna structures may be placed very close together, thus enabling the integration of a high number of integrated antenna structures in a single flat panel antenna array which may fit about 400+ integrated antenna structures. Each integrated antenna structure in the flat panel antenna arrays may be operated independently, thus enabling an enhanced control over the pocket forming. In addition, the higher number of integrated antenna structures may contribute to a higher gain for the flat panel antenna arrays.

Systems and methods for providing virtual general purpose input/output (GPIO) (VGI) over a time division multiplex (TDM) bus are disclosed. While a SOUNDWIRE bus is particularly contemplated, other TDM buses may also be used to provide the benefits outlined herein. In particular, raw GPIO signals are placed into time slots on a TDM bus without requiring additional overhead or packaging. This arrangement allows all drops on a multi-drop bus to receive the GPIO signals substantially concurrently with latency measured in less than a frame period.

Systems and methods for providing virtual general purpose input/output (GPIO) (VGI) over a time division multiplex (TDM) bus are disclosed. While a SOUNDWIRE bus is particularly contemplated, other TDM buses may also be used to provide the benefits outlined herein. In particular, raw GPIO signals are placed into time slots on a TDM bus without requiring additional overhead or packaging. This arrangement allows all drops on a multi-drop bus to receive the GPIO signals substantially concurrently with latency measured in less than a frame period.

A communication unit according to the present disclosure includes: a communication circuit section that receives transmission data divided into head data and one or more subsequent data from an communicated unit over a period of a plurality of time-segments; a storage section having a storage region in which at least the transmission data received by the communication circuit section is stored; and a control section that places a limitation on an access period to cause a period of access to the storage region in a period of a time-segment in which the subsequent data is transmitted to become shorter than a period of access to the storage region in a period of a time-segment in which the head data is transmitted.

Systems or methods of the present disclosure may facilitate meeting connectivity demands between the dies of the modularized integrated circuits. Such an integrated circuit system may include a first die of programmable fabric circuitry that is communicatively coupled to a second die of modular periphery intellectual property (IP) tile via a modular interface. The modular interface may enable communication between a first microbump of the first die and a second microbump of the second die using a time-division multiplexing (TDM) technique. The modular interface may also enable communication between the first microbump and the second microbump using a wire-to-wire connection that does not comprise the TDM technique.

Systems or methods of the present disclosure may facilitate meeting connectivity demands between the dies of the modularized integrated circuits. Such an integrated circuit system may include a first die of programmable fabric circuitry that is communicatively coupled to a second die of modular periphery intellectual property (IP) tile via a modular interface. The modular interface may enable communication between a first microbump of the first die and a second microbump of the second die using a time-division multiplexing (TDM) technique. The modular interface may also enable communication between the first microbump and the second microbump using a wire-to-wire connection that does not comprise the TDM technique.

Embodiments herein relate to a method performed by a relay node for relaying user data from/to one or more communication devices to/from a radio access node in a wireless communication network. The relay node receives a first user data stream in a first time slot and/or a second user data stream in a second time slot from a first communication device and a second communication device respectively, or from the radio access node. The relay node independently applies a network coding on the received first and/or second user data streams. The relay node forwards the network coded first user data stream in a third time slot to the radio access node or the first communication device, and/or the second user data stream in another time slot to the radio access node or the second communication device.

Embodiments herein relate to a method performed by a relay node for relaying user data from/to one or more communication devices to/from a radio access node in a wireless communication network. The relay node receives a first user data stream in a first time slot and/or a second user data stream in a second time slot from a first communication device and a second communication device respectively, or from the radio access node. The relay node independently applies a network coding on the received first and/or second user data streams. The relay node forwards the network coded first user data stream in a third time slot to the radio access node or the first communication device, and/or the second user data stream in another time slot to the radio access node or the second communication device.