Systems, methods, and software for controlling transmissions of User Equipment (UE) on an unlicensed spectrum. In one embodiment, a base station communicates with the UE through radio communications on a licensed spectrum of a carrier. The base station transmits a query to a policy control element requesting spectrum selection criteria for the UE over a direct interface. The base station receives a response from the policy control element that includes the spectrum selection criteria for the UE, and processes the spectrum selection criteria to allocate resources for transmissions involving the UE on the licensed spectrum and on the unlicensed spectrum. The base station then provides a control message including the allocated resources towards the UE to enable the UE to perform the transmissions on the unlicensed spectrum, the licensed spectrum, or a combination of the two.

Methods, systems, and devices for wireless communication are described. Methods, systems, and devices provide for different tone spacing schemes for different channels. Methods, systems, and devices also provide for different tone spacing schemes for different stages of communication between a UE and a base station. The base station may indicate, to the UE, the tone spacing scheme in a control channel, a synchronization signal, or a reference signal and the tone spacing scheme may be selected by the base station from available tone spacing schemes for communication. Tone spacing schemes may also be referred to as numerologies.

A mobile communications system including: at least one base station configured to communicate data to/from different terminal devices via respective of plural logically separate carriers of a wireless access interface; first and second terminal devices operable to camp-on to first and second carriers of plural carriers and to subsequently communicate data with the at least one base station via the first and second carriers. The first and second carriers support compatible synchronization signaling such that the first and second terminal devices both can synchronize with the first and second carriers to begin a camp-on procedure. Following synchronization with one of the first or second carriers to begin the camp-on procedure, the second terminal device is configured to determine whether or not to continue with the camp-on procedure in dependence on an aspect of physical layer signaling associated with a control channel of the carrier with which it has synchronized.

The present invention discloses a frequency band resource scheduling method and apparatus, where the method includes: first, selecting, according to transmission quality of each to-be-selected sub-band, a sub-band to be allocated to a user terminal; and then, determining whether a transmission quality decreasing amplitude of the user terminal exceeds a first preset value after the selected sub-band is allocated to the user terminal; and if yes, skipping allocating the selected sub-band to the user terminal; otherwise, allocating the selected sub-band to the user terminal.

A wireless communication network controls Carrier Aggregation (CA), a donor base station wirelessly serves a wireless relay and the donor base station and the wireless relay wirelessly serve User Equipment (UE). The wireless relay wirelessly exchanges user data with a UE using CA based on an initial relay to UE (R2UE) CA threshold. The donor base station determines a donor base station utilization amount and processes the donor base station utilization amount to determine a modified R2UE CA threshold. The donor base station wirelessly transfers an instruction to the wireless relay indicating the modified R2UE CA threshold. The wireless relay wirelessly receives the modified R2UE CA threshold and exchanges additional user data with the UE using CA based on the modified R2UE CA threshold.

Embodiments of this application provide an uplink transmission control method and an apparatus. A micro base station sends an uplink resource configuration request to a macro base station, the macro base station sends, to the micro base station, an uplink resource configuration indication that is used to allocate an uplink resource to the micro base station, and then the micro base station instructs user equipment to transmit uplink information by using the uplink resource. It can be seen that, after the macro base station allocates the uplink resource to the micro base station, the micro base station may use the uplink resource to receive the uplink information transmitted by the user equipment.

The base station sends control area indication information of an (N+1).sup.th timeslot to the user equipment by using a physical control channel of an N.sup.th timeslot in a control area of the N.sup.th timeslot, where the control area indication information includes frequency domain control indication information and time domain control indication information, the frequency domain control indication information is used to indicate a frequency domain resource block area occupied by a control area of the (N+1).sup.th timeslot in the (N+1).sup.th timeslot, and the time domain control indication information is used to indicate a time domain time unit area occupied by the control area of the (N+1).sup.th timeslot in the (N+1).sup.th timeslot; and the base station sends, in the control area of the (N+1).sup.th timeslot, a physical control channel of the (N+1).sup.th timeslot to the user equipment.

A multi-carrier communication system such as an OFDM or DMT system has nodes which are allowed to dynamically change their receive and transmit symbol rates, and the number of carriers within their signals. Changing of the symbol rate is done by changing the clocking frequency of the nodes' iFFT and FFT processors, as well as their serializers and deserializers. The nodes have several ways of dynamically changing the number of earners used. The selection of symbol rate and number of earners can be optimized for a given channel based on explicit channel measurements, a priori knowledge of the channel, or past experience. Provision is made for accommodating legacy nodes that may have constraints in symbol rate or the number of carriers they can support. The receiver can determine the correct symbol rate and number of earners through a priori knowledge, a first exchange of packets in a base mode that all nodes can understand, or an indication in the header of the data packet which is transmitted in a base mode of operation that all nodes can understand.

Provided is a method of receiving a physical layer convergence procedure (PLCP) protocol data unit (PPDU) by an access point (AP) in a wireless local area (LAN) system. The method includes: allocating a first transmission channel bandwidth to a first station (STA) which is multiple input multiple output (MIMO)-paired with the AP; allocating a second transmission channel bandwidth to a second STA which is MIMO-paired with the AP; transmitting to the first STA and the second STA a sync trigger for determining a time point at which the first STA transmits a first PPDU and a time point at which the second STA transmits a second PPDU; and receiving simultaneously the first PPDU and the second PPDU from the first STA and the second STA.

An apparatus and method providing feedback on channel conditions in a wireless telecommunications system including a base station to communicate with plural terminals device using frequencies spanning a system frequency bandwidth. At least one terminal device is a reduced capability terminal device including a tuneable transceiver configured to receive downlink transmissions from the base station using only a restricted frequency bandwidth smaller than and within the system frequency bandwidth. The reduced capability terminal device is configured to communicate information derived from measurements of channel conditions to the base station. The information may include an indication of measured channel conditions for different frequency locations, or an indication of one or more frequency locations for which corresponding measurement of channel conditions meet a pre-defined selection criterion. The base station subsequently schedules downlink transmissions for the terminal device in a manner that takes account of the information received from the terminal device.