An orthogonal frequency-division multiplexing (OFDM) base station operative to transmit a sequence of OFDM signals simultaneously using at least two separate twisted pairs, in which each of the OFDM signals is modulated by a plurality of sub-carriers. At least two converters are connected to the OFDM base station using the at least two twisted pairs, respectively, in which each of the converters, and simultaneously with the other converters, is configured to receive each of the OFDM signals from the OFDM base station using the respective twisted pair, up-convert the OFDM signal into a radio-frequency (RF) band, and re-transmit wirelessly the OFDM signal, in conjunction with the RF band, from at least one antenna associated with each converter.

Techniques are disclosed for increasing the sum spectral efficiency (SE) of cellular networks including Hybrid In Band Full Duplex (IBFD) cellular networks. These techniques include using various constraints to identify UEs that qualify to be included as part one or more frequency sharing groups. The qualification process may use, as one of the constraints, a distance between served UEs such that UEs that are too close to one another are disqualified. The UE frequency sharing groups may include at least two UEs that use the same shared frequency as an upload channel frequency one UE as the other UE uses for a downlink channel frequency. Techniques are also disclosed for the allocation of frequencies and to determine when the current groupings and/or allocated frequencies are invalid.

Aspects are described for use in wireless communications. Nodes may provide wireless access to wireless devices in different coverage areas. The nodes may transmit messages having time interval allocation bitmaps that indicate reduced transmission power time intervals. The reduced transmission power time intervals may be different for different nodes.

Aspects are described for use in wireless communications. Nodes may provide wireless access to wireless devices in different coverage areas. The nodes may transmit messages having time interval allocation bitmaps that indicate reduced transmission power time intervals. The reduced transmission power time intervals may be different for different nodes.

An information processing device includes: a first reception unit that receives first information regarding a first communication device that primarily uses a predetermined frequency band; a setting unit that sets information regarding protection of the first communication device on the basis of the first information; and a calculation unit that calculates a communication parameter related to radio wave transmission of a second communication device that secondarily uses the predetermined frequency band on the basis of the information regarding the protection of the first communication device set by the setting unit.

An information processing device includes: a first reception unit that receives first information regarding a first communication device that primarily uses a predetermined frequency band; a setting unit that sets information regarding protection of the first communication device on the basis of the first information; and a calculation unit that calculates a communication parameter related to radio wave transmission of a second communication device that secondarily uses the predetermined frequency band on the basis of the information regarding the protection of the first communication device set by the setting unit.

A system operative to synchronize wireless transmissions between a base station and a plurality of wireless client devices using a plurality of twisted pairs. The system includes a base station located in a first area and comprising a medium access controller (MAC) functionality; a plurality of twisted pairs; and a plurality of converters located in other areas, in which the plurality of twisted pairs are operative to connect the base station with the plurality of converters, thereby forming a star topology. The base station is configured to determine a transmission plan to be followed by the base station and a plurality of wireless client devices associated with the base station. The base station is configured to distribute the transmission plan via the plurality of twisted pairs and converters to the wireless client devices, thereby synchronizing wireless transmissions between the base station and at least some of the wireless client devices.

A system operative to synchronize wireless transmissions between a base station and a plurality of wireless client devices using a plurality of twisted pairs. The system includes a base station located in a first area and comprising a medium access controller (MAC) functionality; a plurality of twisted pairs; and a plurality of converters located in other areas, in which the plurality of twisted pairs are operative to connect the base station with the plurality of converters, thereby forming a star topology. The base station is configured to determine a transmission plan to be followed by the base station and a plurality of wireless client devices associated with the base station. The base station is configured to distribute the transmission plan via the plurality of twisted pairs and converters to the wireless client devices, thereby synchronizing wireless transmissions between the base station and at least some of the wireless client devices.

A method for ubiquitously covering a selected area with a single wireless communication channel. At least two wireless converters are placed at different locations to provide an aggregated wireless coverage area, the wireless converters covering wirelessly only a respective portion of a selected area with least two portions at least partially overlapping. An OFDM base station transmits a sequence of OFDM signals simultaneously via at least two distribution lines, each OFDM signal modulated by sub-carriers. The wireless converters simultaneously receive, via respective distribution lines, the OFDM signals from the OFDM base station, and up-convert a respective OFDM signal into an RF band to re-transmit wirelessly the respective OFDM signal. At least two re-transmissions of each OFDM signal arrive at a wireless client device. Each sub-carrier from each OFDM signal re-transmission can combine with the respective sub-carrier of the other re-transmissions of said respective OFDM signal, thereby facilitating said ubiquitous coverage.

A method for ubiquitously covering a selected area with a single wireless communication channel. At least two wireless converters are placed at different locations to provide an aggregated wireless coverage area, the wireless converters covering wirelessly only a respective portion of a selected area with least two portions at least partially overlapping. An OFDM base station transmits a sequence of OFDM signals simultaneously via at least two distribution lines, each OFDM signal modulated by sub-carriers. The wireless converters simultaneously receive, via respective distribution lines, the OFDM signals from the OFDM base station, and up-convert a respective OFDM signal into an RF band to re-transmit wirelessly the respective OFDM signal. At least two re-transmissions of each OFDM signal arrive at a wireless client device. Each sub-carrier from each OFDM signal re-transmission can combine with the respective sub-carrier of the other re-transmissions of said respective OFDM signal, thereby facilitating said ubiquitous coverage.