The present disclosure provides techniques configuring channel state information (CSI) reporting for certain service types, such as the ultra-reliable low latency communications (URLLC) service type. In some cases, a UE may obtain information regarding a first set of channel state information (CSI) reporting configurations for a first service type separate from a second set of CSI reporting configurations for a second service type, receive a first downlink control information (DCI) scheduling a CSI report for the first service type on at least one physical uplink shared channel (PUSCH), generate at least one CSI report for the first service type based on one of the first set of CSI reporting configurations selected based on a field in the DCI, and transmitting the CSI report for the first service type on the PUSCH.

A computer device may include a memory storing instructions and processor configured to execute the instructions to generate a Radio Access Network (RAN) slice in a Fifth Generation (5G) New Radio (NR) base station designated for a particular type of service; determine requirements associated with the generated RAN slice; and reserve resources of the 5G NR base station for the generated RAN slice, wherein reserving the resources includes specifying one or more antenna beams generated by the 5G NR base station. The processor may be further configured to obtain criteria for categorizing user equipment (UE) device sessions as belonging to the generated RAN slice; identify UE device sessions as belonging to the RAN slice based on the obtained criteria; and apply the determined requirements to the identified UE device session using the reserved resources.

A computer device may include a memory storing instructions and processor configured to execute the instructions to generate a Radio Access Network (RAN) slice in a Fifth Generation (5G) New Radio (NR) base station designated for a particular type of service; determine requirements associated with the generated RAN slice; and reserve resources of the 5G NR base station for the generated RAN slice, wherein reserving the resources includes specifying one or more antenna beams generated by the 5G NR base station. The processor may be further configured to obtain criteria for categorizing user equipment (UE) device sessions as belonging to the generated RAN slice; identify UE device sessions as belonging to the RAN slice based on the obtained criteria; and apply the determined requirements to the identified UE device session using the reserved resources.

A wireless network device comprises a wireless signal driver, an application-driver framework that includes a bidirectional interface and an application interface. The application-driver framework is configured for application-agnostic and driver-agnostic communication. The bidirectional interface communicatively couples the wireless signal driver to the application-driver framework. The bidirectional interface includes an abstraction layer via which driver-agnostic command signals and driver-agnostic event signals are communicated with the application-driver framework and via which driver-specific command signals and driver-specific event signals are communicated with the wireless signal driver. The application interface is configured to interface with applications and with the application-driver framework. The application interface is configured to communicate application-agnostic command signals and application-agnostic event signals with the application-driver framework and to communicate application-specific event signals and application-specific command signals with the one or more applications and the application-driver framework.

A wireless network device comprises a wireless signal driver, an application-driver framework that includes a bidirectional interface and an application interface. The application-driver framework is configured for application-agnostic and driver-agnostic communication. The bidirectional interface communicatively couples the wireless signal driver to the application-driver framework. The bidirectional interface includes an abstraction layer via which driver-agnostic command signals and driver-agnostic event signals are communicated with the application-driver framework and via which driver-specific command signals and driver-specific event signals are communicated with the wireless signal driver. The application interface is configured to interface with applications and with the application-driver framework. The application interface is configured to communicate application-agnostic command signals and application-agnostic event signals with the application-driver framework and to communicate application-specific event signals and application-specific command signals with the one or more applications and the application-driver framework.

Systems and methods for operating a customer premise equipment (CPE) device with agile software stack integrated with OpenSync™ layer for command, control, and telemetry via the operator's cloud network. It includes the configuration of the CPE device to receive traffic from an access network in a first system on chip (SoC) of the CPE device, and to provide 5G edge computing services to a 5G NR user equipment (UE) device via a second SoC of the CPE device. The CPE device may also be configured to receive 5G New Radio (NR) mobile traffic, receive in-home Wi-Fi traffic, and use at least one service flow (or only one service flow) to support both the 5G NR mobile traffic and the in-home Wi-Fi traffic.

Methods and systems are provided for enhancing communications mobility in an enterprise using a distributed communication controller. The distributed communication controller identifies a user device, verifies the device and delivers enterprise communication services to the user via the user device without requiring the execution of an enterprise communication application by the wearable device. When the user device is a wearable device, a wireless message is sent from the wearable device in physical proximity to the distributed communication controller that contains identification information. Based on the identification information, user information associated with the user of the user device is retrieved and then used to determine whether enterprise communication services are available for the user. Next, the user is verified through an interaction with the user device and the distributed communication controller and the enterprise communication services are provided to the user by the distributed communication controller.

Methods and systems are provided for enhancing communications mobility in an enterprise using a distributed communication controller. The distributed communication controller identifies a user device, verifies the device and delivers enterprise communication services to the user via the user device without requiring the execution of an enterprise communication application by the wearable device. When the user device is a wearable device, a wireless message is sent from the wearable device in physical proximity to the distributed communication controller that contains identification information. Based on the identification information, user information associated with the user of the user device is retrieved and then used to determine whether enterprise communication services are available for the user. Next, the user is verified through an interaction with the user device and the distributed communication controller and the enterprise communication services are provided to the user by the distributed communication controller.

The present disclosure relates to a communication method and system for converging a 5th-Generation (5G) communication system for supporting higher data rates beyond a 4th-Generation (4G) system with a technology for Internet of Things (IoT). The present disclosure may be applied to intelligent services based on the 5G communication technology and the IoT-related technology, such as smart home, smart building, smart city, smart car, connected car, health care, digital education, smart retail, security and safety services. The disclosure provides a method for, if an activated BWP is changed in a wireless communication system in which a BWP is configured and operated, effectively measuring and reporting a channel state of the changed BWP. The method performed by a terminal includes receiving, from a base station, configuration information including channel state information (CSI) resource configuration information; receiving, from the base station, DCI including CSI request information; performing a measurement based on CSI resource configuration information corresponding to an activated BWP, in case that the CSI request information is associated with a plurality of CSI resource configuration information; and reporting a result of the measurement.

The present disclosure relates to a communication method and system for converging a 5th-Generation (5G) communication system for supporting higher data rates beyond a 4th-Generation (4G) system with a technology for Internet of Things (IoT). The present disclosure may be applied to intelligent services based on the 5G communication technology and the IoT-related technology, such as smart home, smart building, smart city, smart car, connected car, health care, digital education, smart retail, security and safety services. The disclosure provides a method for, if an activated BWP is changed in a wireless communication system in which a BWP is configured and operated, effectively measuring and reporting a channel state of the changed BWP. The method performed by a terminal includes receiving, from a base station, configuration information including channel state information (CSI) resource configuration information; receiving, from the base station, DCI including CSI request information; performing a measurement based on CSI resource configuration information corresponding to an activated BWP, in case that the CSI request information is associated with a plurality of CSI resource configuration information; and reporting a result of the measurement.