According to one configuration, a wireless communication system includes one or more wireless communication devices and gateway hardware. The gateway hardware can be configured to notify the one or more wireless communication devices of a change associated with frequency hopping settings (such as switchover from first frequency hopping settings to second frequency hopping settings). Further, the gateway hardware can include a first radio frequency interface and a second radio frequency interface. In accordance with the frequency hopping settings, the gateway hardware: i) fixedly tunes the first radio frequency interface to a first wireless channel; and ii) while the first radio frequency interface is fixedly tuned to the first wireless channel, the gateway hardware dynamically tunes the second radio frequency interface to hop amongst multiple different wireless channels. The frequency hopping settings support different wireless power levels depending on a number of pseudorandom wireless channels that are hopped.

According to one configuration, a wireless communication system includes one or more wireless communication devices and gateway hardware. The gateway hardware can be configured to notify the one or more wireless communication devices of a change associated with frequency hopping settings (such as switchover from first frequency hopping settings to second frequency hopping settings). Further, the gateway hardware can include a first radio frequency interface and a second radio frequency interface. In accordance with the frequency hopping settings, the gateway hardware: i) fixedly tunes the first radio frequency interface to a first wireless channel; and ii) while the first radio frequency interface is fixedly tuned to the first wireless channel, the gateway hardware dynamically tunes the second radio frequency interface to hop amongst multiple different wireless channels. The frequency hopping settings support different wireless power levels depending on a number of pseudorandom wireless channels that are hopped.

Methods, apparatus, and systems are described relating to wireless communications. A base station may transmit a message comprising a subframe allocation bitmap indicating a plurality of subframes. The indicated subframes may correspond to Almost Blank Subframes transmitted by the base station. The base station may transmit a message to a wireless device indicating measurement subframe allocation bitmaps. A first measurement subframe allocation bitmap may exclude the plurality of subframes. A second measurement subframe allocation bitmap may exclude subframes of the first measurement subframe allocation bitmap. These and other features are described.

Methods, apparatus, and systems are described relating to wireless communications. A base station may transmit a message comprising a subframe allocation bitmap indicating a plurality of subframes. The indicated subframes may correspond to Almost Blank Subframes transmitted by the base station. The base station may transmit a message to a wireless device indicating measurement subframe allocation bitmaps. A first measurement subframe allocation bitmap may exclude the plurality of subframes. A second measurement subframe allocation bitmap may exclude subframes of the first measurement subframe allocation bitmap. These and other features are described.

A transmitter device in a wireless communication system is provided. The transmitter device comprises a processor configured to: generate an extType field indicating a section extension; generate a mcScaleReMask field indicating a set of resource elements; generate a mcScaleOffset field indicating a power offset value; generate an extLen field indicating a number of a pair of the mcScaleReMask and the mcScaleOffset fields included in the section extension; and generate a downlink and uplink (DL/UL) control message including the extType field, the mcScaleReMask field, and the mcScaleOffset field, and the extLen field. The transmitter device further comprises a transceiver operably connected to the processor, the transceiver configured to transmit, to a receiver, the DL/UL control message.

A transmitter device in a wireless communication system is provided. The transmitter device comprises a processor configured to: generate an extType field indicating a section extension; generate a mcScaleReMask field indicating a set of resource elements; generate a mcScaleOffset field indicating a power offset value; generate an extLen field indicating a number of a pair of the mcScaleReMask and the mcScaleOffset fields included in the section extension; and generate a downlink and uplink (DL/UL) control message including the extType field, the mcScaleReMask field, and the mcScaleOffset field, and the extLen field. The transmitter device further comprises a transceiver operably connected to the processor, the transceiver configured to transmit, to a receiver, the DL/UL control message.

A power control method and a base station are provided. The base station obtains a first resource block (RB) set and a second RB set after a power control cycle arrives, wherein the first RB set is an RB set that is allocated by the first base station to first user equipment (UE) in a first cell at each transmission time interval (TTI) in the power control cycle, and the second RB set is an RB set that is allocated by a second base station to second UE in a second cell at each TTI in the power control cycle. Then the base station performs power control on the first UE based on the first RB set and the second RB set.

A power control method and a base station are provided. The base station obtains a first resource block (RB) set and a second RB set after a power control cycle arrives, wherein the first RB set is an RB set that is allocated by the first base station to first user equipment (UE) in a first cell at each transmission time interval (TTI) in the power control cycle, and the second RB set is an RB set that is allocated by a second base station to second UE in a second cell at each TTI in the power control cycle. Then the base station performs power control on the first UE based on the first RB set and the second RB set.

According to one configuration, a wireless communication system includes one or more wireless communication devices and gateway hardware. The gateway hardware can be configured to notify the one or more wireless communication devices of a change associated with frequency hopping settings (such as switchover from first frequency hopping settings to second frequency hopping settings). Further, the gateway hardware can include a first radio frequency interface and a second radio frequency interface. In accordance with the frequency hopping settings, the gateway hardware: i) fixedly tunes the first radio frequency interface to a first wireless channel; and ii) while the first radio frequency interface is fixedly tuned to the first wireless channel, the gateway hardware dynamically tunes the second radio frequency interface to hop amongst multiple different wireless channels. The frequency hopping settings support different wireless power levels depending on a number of pseudorandom wireless channels that are hopped.

According to one configuration, a wireless communication system includes one or more wireless communication devices and gateway hardware. The gateway hardware can be configured to notify the one or more wireless communication devices of a change associated with frequency hopping settings (such as switchover from first frequency hopping settings to second frequency hopping settings). Further, the gateway hardware can include a first radio frequency interface and a second radio frequency interface. In accordance with the frequency hopping settings, the gateway hardware: i) fixedly tunes the first radio frequency interface to a first wireless channel; and ii) while the first radio frequency interface is fixedly tuned to the first wireless channel, the gateway hardware dynamically tunes the second radio frequency interface to hop amongst multiple different wireless channels. The frequency hopping settings support different wireless power levels depending on a number of pseudorandom wireless channels that are hopped.