There is disclosed a method performed by a wireless device for performing active bandwidth part switching, the method comprising: performing a first active bandwidth part switching on a first link for the wireless device; determining that a second active bandwidth part switching on a second link for the wireless device is to be performed while the first active bandwidth part switching is ongoing; and adapting at least one of the first and second active bandwidth part switching based on a rule.

A user equipment (UE) includes first and second subscriber identity modules (SIMs), possibly subscribed to different carriers. When the first SIM is in a connected state and the second SIM is in an idle state, the UE may need to periodically tune away a radio from a first frequency used for communication under the first SIM to a second frequency used for idle mode activity under the second SIM. The UE may provide to the network of the first SIM the second SIMs traffic activity pattern and/or serving frequency so that the network may provide coordinated configuration and/or scheduling for the UE device, e.g., in order to make the action of tuning away (and tuning back) the radio more efficient and/or to decrease the network impact of such radio tune aways (e.g., to decrease wasted uplink scheduling and wasted downlink transmissions for the first SIM).

Disclosed are a method and apparatus for determining a resource location, and a device and a storage medium, which belong to the technical field of communications. The method comprises: where a BWP is reactivated, determining the location of a CG resource according to first information, wherein the first information comprises frame number information used for determining the location of the CG resource. Provided is a method for determining or calculating the location of a CG resource corresponding to a BWP after the BWP is reactivated.

Systems and methods for managing interference in a communication network include transmitting a first downlink signal (50) from a first transmit/receive point (TRP) (46) to an electronic device (14) using a beam (62). The electronic device (14) can also receive a second downlink signal (52) from a second TRP (48), where a portion (54) of the first downlink signal (50) from the first TRP (46) interferes with the second downlink signal (52). The first TRP (46) then receives a series of uplink pilot signals (66, 68) from the electronic device (14). Using the received uplink pilot signals (66, 68), the first TRP (46) can then estimate the angle of departure (AoD) for the intended signal (first downlink signal (50)), and the AoD for the interference signal (54). The first TRP (46) can then reconfigure the beam (62) used to transmit the first downlink signal (50) based on the estimated AoDs for the intended signal and interference signal to manage the interference effect that the first leakage signal (54) has on the second downlink signal (52).

Systems and methods for managing interference in a communication network include transmitting a first downlink signal (50) from a first transmit/receive point (TRP) (46) to an electronic device (14) using a beam (62). The electronic device (14) can also receive a second downlink signal (52) from a second TRP (48), where a portion (54) of the first downlink signal (50) from the first TRP (46) interferes with the second downlink signal (52). The first TRP (46) then receives a series of uplink pilot signals (66, 68) from the electronic device (14). Using the received uplink pilot signals (66, 68), the first TRP (46) can then estimate the angle of departure (AoD) for the intended signal (first downlink signal (50)), and the AoD for the interference signal (54). The first TRP (46) can then reconfigure the beam (62) used to transmit the first downlink signal (50) based on the estimated AoDs for the intended signal and interference signal to manage the interference effect that the first leakage signal (54) has on the second downlink signal (52).

The present application describes a communication system including a first apparatus including a single application processor operably coupled to a non-transitory memory including instructions and a local group of discrete radio resources each including a modem. The single application processor of the first apparatus is configured to at least execute the instructions of sending a request for capacity information to a second, remote apparatus. The second apparatus includes a single application processor, a non-transitory memory operably coupled to the single application processor, and a local group of discrete radio resources each including a modem operably coupled to the single application processor. The first apparatus is also configured to execute the instructions of determining, from the local group of discrete radio resources of the first and second apparatuses, a dedicated resource to handle a communication request.

The present application describes a communication system including a first apparatus including a single application processor operably coupled to a non-transitory memory including instructions and a local group of discrete radio resources each including a modem. The single application processor of the first apparatus is configured to at least execute the instructions of sending a request for capacity information to a second, remote apparatus. The second apparatus includes a single application processor, a non-transitory memory operably coupled to the single application processor, and a local group of discrete radio resources each including a modem operably coupled to the single application processor. The first apparatus is also configured to execute the instructions of determining, from the local group of discrete radio resources of the first and second apparatuses, a dedicated resource to handle a communication request.

Embodiments of this application disclose a method and a device for wireless communication. The method includes: obtaining access stratum context identifier information of a first terminal device, where the access stratum context identifier information of the first terminal device is used to identify access stratum context information of the first terminal device that is related to the first terminal device on a first access network device; and determining the first access network device according to the access stratum context identifier information of the first terminal device, so that a second access network device providing a network service to the first terminal device obtains the access stratum context information of the first terminal device from the first access network device. The method and the device in the embodiments of this application help reduce network overheads.

Disclosed herein are system, method, and computer program product embodiments for synchronizing the switching of different wireless platforms to different portions of a frequency band. An embodiment, at a first wireless platform, operates by receiving a band switch request message from a second wireless platform, wherein the band switch request message comprises a band switch delay period for the second wireless platform. The embodiment calculates a band switch time based on a band switch delay period for the first wireless platform and the band switch delay period for the second wireless platform. The embodiment transmits a band switch accept message comprising the band switch time to the second wireless platform. The embodiment sets a first filter to operate on a second portion of the frequency band based on the band switch time. The embodiment then operates on the second portion of the frequency band.

Disclosed herein are system, method, and computer program product embodiments for synchronizing the switching of different wireless platforms to different portions of a frequency band. An embodiment, at a first wireless platform, operates by receiving a band switch request message from a second wireless platform, wherein the band switch request message comprises a band switch delay period for the second wireless platform. The embodiment calculates a band switch time based on a band switch delay period for the first wireless platform and the band switch delay period for the second wireless platform. The embodiment transmits a band switch accept message comprising the band switch time to the second wireless platform. The embodiment sets a first filter to operate on a second portion of the frequency band based on the band switch time. The embodiment then operates on the second portion of the frequency band.