Techniques are disclosed that dynamically allocate communications resources in a wireless communications network, such as a wireless personal area network (WPAN). For instance, a wireless communications device may obtain a resource allocation. This resource allocation includes a time slot (e.g., a TDMA time slot) within a wireless communications medium. The device determines a first portion of the time slot in which it intends to transmit data. Also, the wireless communications device relinquishes a second portion of the time slot that occurs after the first portion of the time slot. Based on this relinquishment, a central controller device may reallocate the second portion of the time slot.

Disclosed is a base station which transmits and retransmits to a terminal first and second downlink data in first and second component carriers, respectively, wherein a first configuration pattern of UL (uplink) and DL (downlink) subframes is set for the first component carrier and a second configuration pattern of UL and DL subframes is set for the second component carrier. The base station receives from the terminal in the first component carrier an ACK/NACK for the first and second downlink data received by the terminal, which stores retransmission data of the first and second downlink data in a soft buffer, wherein the soft buffer for the second downlink data is sized according to a maximum number of downlink HARQ retransmission processes executable in a reference configuration pattern of UL and DL subframes, and the reference configuration pattern is determined according to the first and second configuration patterns.

Disclosed is a base station which transmits and retransmits to a terminal first and second downlink data in first and second component carriers, respectively, wherein a first configuration pattern of UL (uplink) and DL (downlink) subframes is set for the first component carrier and a second configuration pattern of UL and DL subframes is set for the second component carrier. The base station receives from the terminal in the first component carrier an ACK/NACK for the first and second downlink data received by the terminal, which stores retransmission data of the first and second downlink data in a soft buffer, wherein the soft buffer for the second downlink data is sized according to a maximum number of downlink HARQ retransmission processes executable in a reference configuration pattern of UL and DL subframes, and the reference configuration pattern is determined according to the first and second configuration patterns.

A communication terminal that transmits device data output by a communication device via a wireless communication circuit. The communication terminal includes at least one memory configured to store instructions, and at least one processor configured to execute the instructions. The instructions include receiving the device data output by the communication device, storing the received device data into the at least one memory, and transmitting, to the wireless communication circuit, the stored device data after the device data is stored in the at least one memory until a prescribed amount, which is set in association with at least either the communication device outputting the device data or an attribute of the device data, has been reached.

A communication terminal that transmits device data output by a communication device via a wireless communication circuit. The communication terminal includes at least one memory configured to store instructions, and at least one processor configured to execute the instructions. The instructions include receiving the device data output by the communication device, storing the received device data into the at least one memory, and transmitting, to the wireless communication circuit, the stored device data after the device data is stored in the at least one memory until a prescribed amount, which is set in association with at least either the communication device outputting the device data or an attribute of the device data, has been reached.

This application provides a cache decision method and apparatus. The method includes: receiving, by a policy control function PCF, first cache information sent by at least one local analytic function LAF. The first cache information includes a base station identifier, identifiers of first N1 pieces of application information that are accessed for a maximum quantity of times, and content corresponding to the identifiers of the N1 pieces of application information, where N1 is a positive integer. The method further includes determining, by the PCF, local cache content based on the first cache information and a capacity of a local cache. In this way, the cache hit rate can be effectively improved, transmission bandwidth and data transmission overheads can be greatly reduced, and users' experience improved.

A communication control method includes by a Radio Link Control (RLC) entity of a communication apparatus being either of a user equipment or a relay node, transmitting a data packet to a parent node and then receiving a first acknowledgment corresponding to the data packet from the parent node, by the RLC entity, updating a transmission window managed at the RLC entity in response to the receiving the first acknowledgment, and by the communication apparatus, controlling, in response to receiving a second acknowledgment corresponding to the data packet from the parent node after the receiving the first acknowledgment, retransmission related to the data packet based on the second acknowledgment.

In switching a radio base station (SeNB) from a radio base station (SeNB#1) to a radio base station (SeNB#2) in an “Inter-node UP aggregation”, the occurrence of transmission delay of downlink data to a mobile station (UE) is avoided. A mobile communication method according to the present invention includes: stopping, by the radio base station (SeNB#1), scheduling of downlink data to the mobile station (UE), and sending an “SeNB change command” to the mobile station (UE), when receiving an “SeNB change request ack” from the radio base station (SeNB#2); notifying, by the mobile station (UE), a radio base station (MeNB) of at least one of already received downlink data and unreceived downlink data; and resending, by the radio base station (MeNB), the mobile station the downlink data that is not received by the mobile station (UE) in response to the notification.

In switching a radio base station (SeNB) from a radio base station (SeNB#1) to a radio base station (SeNB#2) in an “Inter-node UP aggregation”, the occurrence of transmission delay of downlink data to a mobile station (UE) is avoided. A mobile communication method according to the present invention includes: stopping, by the radio base station (SeNB#1), scheduling of downlink data to the mobile station (UE), and sending an “SeNB change command” to the mobile station (UE), when receiving an “SeNB change request ack” from the radio base station (SeNB#2); notifying, by the mobile station (UE), a radio base station (MeNB) of at least one of already received downlink data and unreceived downlink data; and resending, by the radio base station (MeNB), the mobile station the downlink data that is not received by the mobile station (UE) in response to the notification.

In an embodiment, there is provided a method for support of mobile-terminated communication in an Evolved Packet System, towards a User Equipment UE in idle mode using a power saving mechanism whereby the UE is transiently not reachable, the method includes allowing one or more Downlink DL packets received for the UE to be buffered in a Serving Gateway SGW, upon request, for up to a duration referred to as DL buffering duration.