Abstract: Systems and methods for carrier aggregation based on subscriber category information, such as for New Radio Carrier Aggregation in a 5G Network. A call is placed via a calling device and detected at a node of a network. A user equipment capability check is performed, which determines whether the calling device supports carrier aggregation. Subscriber information is received associated with the calling device, including a quality of service (QOS) identifier associated with a subscriber category. Based on the QoS identifier, two or more carriers are selected and assigned. The QoS identifier is associated with a relative priority for assigning cells based on corresponding bandwidth. Call setup is initiated via the two or more carriers.

Abstract: An apparatus to facilitate compute optimization is disclosed. The apparatus includes a at least one processor to perform operations to implement a neural network and compute logic to accelerate neural network computations.

Abstract: Systems and methods for carrier aggregation based on subscriber category information, such as for New Radio Carrier Aggregation in a 5G Network. A call is placed via a calling device and detected at a node of a network. A user equipment capability check is performed, which determines whether the calling device supports carrier aggregation. Subscriber information is received associated with the calling device, including a quality of service (QoS) identifier associated with a subscriber category. Based on the QoS identifier, two or more carriers are selected and assigned. The QoS identifier is associated with a relative priority for assigning cells based on corresponding bandwidth. Call setup is initiated via the two or more carriers.

Abstract: Techniques for dynamically switching between waveforms are discussed herein. For example, a waveform selector (e.g., at a base station) may select a waveform for the UE to utilize to change data throughput. In some examples, the base station may select a DFT-s-OFDM or a CP-OFDM for the UE to utilize such that data throughput is reduced at certain times. The base station may determine which waveform to utilize based on data received from the UE, such as location data, signal data, and/or other data.

Abstract: Methods and systems for network operator controlled power update per PRB for new radio (NR) are provided. A method begins with determining that at least one frequency block controlled by a first network operator is adjacent or co-channel with at least one frequency block controlled by a second network operator. Next, it is determined that a second frequency block controlled by the first network operator is adjacent or co-channel with the at least one frequency block controlled by the first network operator. The power level assigned to the first network operator's frequency block is updated to reduce interference. To prevent interference, the power level of the second frequency block controlled by the first network operator uses a lower power level. This lower power level may be assigned on a resource block basis, such as PRBs and RBGs.

Abstract: An apparatus to facilitate compute optimization is disclosed. The apparatus includes a at least one processor to perform operations to implement a neural network and compute logic to accelerate neural network computations.

Abstract: Systems and method are provided for dynamic VoNR switching in NRCA scenarios. A user is conducting a VoNR call on a primary cell with the radio quality determined with respect to an operator defined threshold based on monitoring the radio quality of the call for a predetermined time duration. Voice quality may degrade, so radio quality is compared with at least one configured secondary cell using at least one operator defined radio condition. The radio condition may be a mean opinion score (MOS), or may be an RF signal quality measurement. The comparison between the primary cell and the secondary cell reveals if at least one of the configured secondary cells exceeds at least one operator defined radio condition. The UE may be dynamically instructed to transfer from the current serving primary cell to the at least one configured secondary cell that exceeds at least one operator defined radio condition.

Abstract: In one embodiment, the method includes determining that a traffic condition at a PCell used in New Radio Carrier Aggregation (NR CA) exceeds a congestion threshold.

Abstract: Systems and methods are provided for providing intelligent new radio carrier aggregation via a telecommunication network includes a cell site including a carrier aggregation system communicatively coupled to a user device. The carrier aggregation system is structured to provide a device capability request, receive a device capability indicator corresponding to a spectrum of a telecommunication network responsive to the device capability request, determine a first carrier cell corresponding to a first portion of the spectrum and a secondary carrier cell corresponding to a secondary portion of the spectrum based on the device capability indicator, and assign the first carrier cell from a first edge to a second edge of the first portion of the spectrum and the secondary carrier cell from a third edge to a fourth edge of the secondary portion of the spectrum based on the determined first carrier cell and the secondary carrier cell.

Abstract: A base station of a telecommunication network can determine whether a user equipment (UE) should use a two-layer uplink configuration or an uplink carrier aggregation (CA) configuration for uplink transmissions to the base station, based on radio condition metrics reported by the UE to the base station. If radio condition metrics reported by the UE satisfy two-layer uplink criteria, the base station can instruct the UE to switch to using the two-layer uplink configuration. If radio condition metrics reported by the UE do not satisfy the two-layer uplink criteria, the base station can instruct the UE to switch to using the uplink CA configuration.

Abstract: Solutions for early cellular offloading include: receiving, at a node of a wireless network, from a user equipment (UE), a first message (e.g., an A3, A5, B1, or B2 event report) containing information regarding a serving cell of a first wireless technology generation and information regarding a neighbor cell of the first wireless technology generation (e.g., reference signal receive power (RSRP), reference signal received quality (RSRQ), or signal to interference and noise ratio (SINR) measurement for fifth generation cellular technology (5G)); determining that a handover to the neighbor cell will not be performed; and based on at least the information regarding the serving cell and determining that the handover to the neighbor cell will not be performed, triggering an offload from the serving cell to a cell of a second wireless technology generation (e.g., fourth generation cellular technology (4G)).

Abstract: The disclosed technology provides a system and method for allocating frequency bands to a mobile device or user equipment (UE) based on priorities assigned to the different frequency bands. When no priority is assigned to the frequency bands, when a special or reserved priority is assigned, or when equal priority is assigned, the frequency band allocation to the UE is based on a default frequency allocation algorithm (e.g., based on a relative bandwidth of the different frequency bands). When a UE is capable of utilizing a first and a second frequency band, and the priority assigned to the first frequency band is higher than the priority assigned to the second frequency band, the network (e.g., eNB/gNB) overrides the default algorithm and preferentially allocates the first frequency band to UE even when the first frequency band has a smaller bandwidth than the second frequency band or when the default algorithm would otherwise prefer the first frequency band.

Abstract: The disclosed technology provides a system and method for allocating frequency bands to a mobile device or user equipment (UE) based on priorities assigned to the different frequency bands. When no priority is assigned to the frequency bands, when a special or reserved priority is assigned, or when equal priority is assigned, the frequency band allocation to the UE is based on a default frequency allocation algorithm (e.g., based on a relative bandwidth of the different frequency bands). When a UE is capable of utilizing a first and a second frequency band, and the priority assigned to the first frequency band is higher than the priority assigned to the second frequency band, the network (e.g., eNB/gNB) overrides the default algorithm and preferentially allocates the first frequency band to UE even when the first frequency band has a smaller bandwidth than the second frequency band or when the default algorithm would otherwise prefer the first frequency band.

Abstract: Systems and methods for carrier aggregation based on subscriber category information, such as for New Radio Carrier Aggregation in a 5G Network. A call is placed via a calling device and detected at a node of a network. A user equipment capability check is performed, which determines whether the calling device supports carrier aggregation. Subscriber information is received associated with the calling device, including a quality of service (QoS) identifier associated with a subscriber category. Based on the QoS identifier, two or more carriers are selected and assigned. The QoS identifier is associated with a relative priority for assigning cells based on corresponding bandwidth. Call setup is initiated via the two or more carriers.

Abstract: The disclosed technology provides a system and method for allocating resource blocks to a wireless device based on a power headroom of the wireless device as contained in a power headroom report (PHR) from the wireless device. The network allocates wireless devices with the highest power headroom (e.g., power headroom above a certain power threshold) with edge resource blocks, wireless devices with the lowest power headroom (e.g. power headroom below a certain power threshold) with inner resource blocks, and other wireless devices with outer resource blocks.

Abstract: A base station of a telecommunication network can determine whether a user equipment (UE) should use a two-layer uplink configuration or an uplink carrier aggregation (CA) configuration for uplink transmissions to the base station, based on radio condition metrics reported by the UE to the base station. If radio condition metrics reported by the UE satisfy two-layer uplink criteria, the base station can instruct the UE to switch to using the two-layer uplink configuration. If radio condition metrics reported by the UE do not satisfy the two-layer uplink criteria, the base station can instruct the UE to switch to using the uplink CA configuration.

Abstract: The disclosed technology provides a system and method for allocating resource blocks to a mobile device based on a traffic priority of wireless resources between the network and the mobile device. Traffic priority can be determined based on quality of service (QOS) identifiers or network slice identifiers. The highest priority users are allocated inner resource blocks with the lowest allowed maximum power reduction (MPR), the lowest priority users are allocated edge resource blocks with the highest allowed MPR, and the intermediate priority users are allocated outer resource blocks.

Abstract: The disclosed technology provides a system and method for allocating resource blocks to a mobile device based on a power headroom of the mobile device as contained in a power headroom report (PHR) from the mobile device. The network allocates mobile devices with the highest power headroom (e.g., power headroom above a certain power threshold) with edge resource blocks, mobile devices with the lowest power headroom (e.g. power headroom below a certain power threshold) with inner resource blocks, and other mobile devices with outer resource blocks.

Abstract: A user equipment (UE) may perform multiple searches within a specified search period to locate the wireless band that provides the most throughput. For instance, if the UE finds a low band with time remaining in the search period, the UE continues to search for a higher frequency wireless. In some examples, the UE attempts to locate a high band within a next portion of the search period. If the UE finds the high band, then the UE will use that band since it provides the most throughput of the available bands. If the UE does not find the high band, then the UE searches for a mid-band for another portion of the search time. By prioritizing higher bands over the first available band that is located in the initial search, the UE will connect to the band that provides the best user experience and the most throughput.

Abstract: The disclosed technology provides a system and method for allocating resource blocks to a mobile device based on a traffic priority of traffic between the network and the mobile device. Traffic priority can be determined based on quality of service (QOS) identifiers or network slice identifiers. The highest priority users are allocated inner resource blocks with the lowest allowed maximum power reduction (MPR), the lowest priority users are allocated edge resource blocks with the highest allowed MPR, and the intermediate priority users are allocated outer resource blocks.