Abstract: For flexible radio resource allocation, a processor receives a numerology scheme. The numerology scheme specifies one or more of at least frequency region definition and a sub-carrier spacing for the at least one frequency region. The method configures sub-carriers for at least one frequency region based on the numerology scheme.

Abstract: Apparatuses, methods, and systems are disclosed for efficient cross-carrier scheduling of multiple slots. One apparatus includes a transceiver and a processor coupled with the transceiver, the processor configured to cause the apparatus to transmit a first control signal to a remote unit, the first control signal indicating a maximum number of HARQ processes, and to transmit a second control signal to the remote unit, where the second control signal is transmitted on a first carrier and where the second control signal schedules a first number of slots on a second carrier. The processor aggregates every two or more of the scheduled first number of slots to a single HARQ process in response to the first number being larger than the maximum number of HARQ processes.

Abstract: Techniques described herein determine positioning of synchronization signal blocks. One or more implementations receive at least one synchronization signal in a synchronization signal block from a first network entity, and an indication from a second network entity. The indication from the second network entity can be used to determine synchronization signal block positioning, such as time location(s). In turn, various implementations communicate with the first network entity based, at least in part, on the determined synchronization signal block(s).

Abstract: Apparatuses, methods, and systems are disclosed for communicating HARQ-ACK feedback for a plurality of carrier groups of a downlink slot set. One apparatus includes a transmitter that transmits, to a remote unit, multiple downlink transmissions in a downlink slot set. The downlink slot set comprises a first number of reference slots and a second number of carriers grouped into a plurality of carrier groups based on a subcarrier spacing value of each carrier, such that each carrier in a carrier group has the same subcarrier spacing value. The apparatus includes a receiver that receives a HARQ-ACK codebook from the remote unit for the downlink slot set, wherein the HARQ-ACK codebook for the downlink slot set corresponds to all downlink transmissions in the downlink slot set.

Abstract: For flexible radio resource allocation, a processor receives a numerology scheme. The numerology scheme specifies one or more of at least frequency region definition and a sub-carrier spacing for the at least one frequency region. The method configures sub-carriers for at least one frequency region based on the numerology scheme.

Abstract: Apparatuses, methods, and systems are disclosed for efficient cross-carrier scheduling of multiple slots. One apparatus includes a transceiver and a processor coupled with the transceiver, the processor configured to cause the apparatus to transmit a first control signal to a remote unit, the first control signal indicating a maximum number of HARQ processes, and to transmit a second control signal to the remote unit, where the second control signal is transmitted on a first carrier and where the second control signal schedules a first number of slots on a second carrier. The processor aggregates every two or more of the scheduled first number of slots to a single HARQ process in response to the first number being larger than the maximum number of HARQ processes.

Abstract: For flexible radio resource allocation, a processor receives a numerology scheme. The numerology scheme specifies one or more of at least frequency region definition and a sub-carrier spacing for the at least one frequency region. The method configures sub-carriers for at least one frequency region based on the numerology scheme.

Abstract: Apparatuses, methods, and systems are disclosed for efficient cross-carrier scheduling of multiple slots. One apparatus includes a receiver that receives, from a base unit, a first control signal that indicates a maximum number of hybrid automatic repeat request (“HARQ”) processes. The receiver also receives a second control signal on a first carrier from the base unit that schedules a first number of slots on a second carrier. The apparatus includes a processor that aggregates every two or more of the scheduled first number of slots into a single HARQ process in response to the first number being larger than the maximum number of HARQ processes.

Abstract: Techniques described herein determine positioning of synchronization signal blocks. One or more implementations receive at least one synchronization signal in a synchronization signal block from a first network entity, and an indication from a second network entity. The indication from the second network entity can be used to determine synchronization signal block positioning, such as time location(s). In turn, various implementations communicate with the first network entity based, at least in part, on the determined synchronization signal block(s).

Abstract: Apparatuses, methods, and systems are disclosed for communicating HARQ-ACK feedback for a plurality of carrier groups of a downlink slot set. One apparatus (400) includes a transmitter (430) that transmits (1605) transmits, to a remote unit, multiple downlink transmissions in a downlink slot set. The downlink slot set comprises a first number of reference slots and a second number of carriers grouped into a plurality of carrier groups based on a subcarrier spacing value of each carrier, such that each carrier in a carrier group has the same subcarrier spacing value. The apparatus includes a receiver (435) that receives (1610) receives a HARQ-ACK codebook from the remote unit for the downlink slot set, wherein the HARQ-ACK codebook for the downlink slot set corresponds to all downlink transmissions in the downlink slot set.

Abstract: For flexible radio resource allocation, a processor receives a numerology scheme. The numerology scheme specifies one or more of at least frequency region definition and a sub-carrier spacing for the at least one frequency region. The method configures sub-carriers for at least one frequency region based on the numerology scheme.

Abstract: For flexible radio resource allocation, a processor 405 monitors for a transmission control 150/155 in a given Orthogonal Frequency-Division Multiplexing (OFDM) symbol 10 of a first slot 11 based on a transmission control policy 290. The processor 405 further receives the transmission control 150/155 in the given OFDM symbol 10. The processor 405 determines available time frequency resources (TFR) 16 for a data transmission based on at least a symbol position 203 of the given OFDM symbol 10 and the transmission control policy 290, wherein the TFR 16 comprise at least one OFDM symbol 10 and at least one frequency range 15.

Abstract: Apparatuses, methods, and systems are disclosed for efficient cross-carrier scheduling of multiple slots. One apparatus (300) includes a receiver (335) that receives (1005), from a base unit (110), a first control signal that indicates a maximum number of hybrid automatic repeat request (“HARQ”) processes. The receiver (335) also receives (1010) a second control signal on a first carrier from the base unit (110) that schedules a first number of slots on a second carrier. The apparatus (300) includes a processor (305) that aggregates (1015) every two or more of the scheduled first number of slots into a single HARQ process in response to the first number being larger than the maximum number of HARQ processes.

Abstract: Techniques described herein determine positioning of synchronization signal blocks. One or more implementations receive at least one synchronization signal in a synchronization signal block from a first network entity, and an indication from a second network entity. The indication from the second network entity can be used to determine synchronization signal block positioning, such as time location(s). In turn, various implementations communicate with the first network entity based, at least in part, on the determined synchronization signal block(s).

Abstract: For flexible radio resource allocation, a processor receives a numerology scheme. The numerology scheme specifies one or more of at least frequency region definition and a sub-carrier spacing for the at least one frequency region. The method configures sub-carriers for at least one frequency region based on the numerology scheme.

Abstract: Systems and methods modify the behavior and operation of an electronic device and also enable a server to intercept and process incoming communications for the electronic device, based on whether the electronic device is communicating with a network via a high data rate mode or a low data rate mode. According to certain aspects, whether the electronic device is communicating with the network via a high data rate mode or a low data rate mode may be determined by calculating a delay index based on the amount of repeated data received by the electronic device. The electronic device may be able to maintain a more consistent connection with the network and improve the experience and satisfaction of users.

Abstract: Techniques described herein determine positioning of synchronization signal blocks. One or more implementations receive at least one synchronization signal in a synchronization signal block from a first network entity, and an indication from a second network entity. The indication from the second network entity can be used to determine synchronization signal block positioning, such as time location(s). In turn, various implementations communicate with the first network entity based, at least in part, on the determined synchronization signal block(s).

Abstract: Systems and methods modify the behavior and operation of an electronic device and also enable a server to intercept and process incoming communications for the electronic device, based on whether the electronic device is communicating with a network via a high data rate mode or a low data rate mode. According to certain aspects, whether the electronic device is communicating with the network via a high data rate mode or a low data rate mode may be determined by calculating a delay index based on the amount of repeated data received by the electronic device. The electronic device may be able to maintain a more consistent connection with the network and improve the experience and satisfaction of users.

Abstract: For flexible radio resource allocation, a processor 405 monitors for a transmission control 150/155 in a given Orthogonal Frequency-Division Multiplexing (OFDM) symbol 10 of a first slot 11 based on a transmission control policy 290. The processor 405 further receives the transmission control 150/155 in the given OFDM symbol 10. The processor 405 determines available time frequency resources (TFR) 16 for a data transmission based on at least a symbol position 203 of the given OFDM symbol 10 and the transmission control policy 290, wherein the TFR 16 comprise at least one OFDM symbol 10 and at least one frequency range 15.

Abstract: For flexible radio resource allocation, a processor receives a numerology scheme. The numerology scheme specifies one or more of at least frequency region definition and a sub-carrier spacing for the at least one frequency region. The method configures sub-carriers for at least one frequency region based on the numerology scheme.