Abstract: A distributed wireless radio frequency-based charging system includes hardware and software platforms. The hardware platform includes adaptive energy harvesters and programmable energy transmitters. The software platform manages the hardware profiles, resources (e.g., energy waveforms and transmission powers), schedules the beams of the energy transmitters, and switches between modes of wireless charging and data access point. This allows the energy transmitters to be configured adaptively based on the ambient energy availability, energy needs and number of energy-requesting devices in the network. Under the software control, the energy transmitters can cooperatively form focused beams of energy and power for transmission to energy harvesters in the energy-receiving devices, such as sensors, Internet of Things (IoT) enabled appliances, and mobile/wearable equipment.

Abstract: The disclosed apparatus and methods can be used to provide an energy efficient Internet of Things (IoT) communication method that can be deployed on a city-wide scale using existing infrastructure and that can target individual sensors or devices. An example apparatus is a decoder including an energy detector and a processor. The energy detector is configured to detect average subframe energy levels of a plurality of subframes during reception of at least one frame of data defined by a first communications protocol (e.g., Long-Term Evolution (LTE)). The average subframe energy levels of the plurality of subframes form a pattern of relatively higher and lower energy levels. The processor is configured to interpret, according to a second communications protocol, the pattern of energy levels to decode a block of data represented by the pattern of energy levels. Another embodiment is a method producing index modulation signals of the second communications protocol.

Abstract: A distributed wireless radio frequency-based charging system includes hardware and software platforms. The hardware platform includes adaptive energy harvesters and programmable energy transmitters. The software platform manages the hardware profiles, resources (e.g., energy waveforms and transmission powers), schedules the beams of the energy transmitters, and switches between modes of wireless charging and data access point. This allows the energy transmitters to be configured adaptively based on the ambient energy availability, energy needs and number of energy-requesting devices in the network. Under the software control, the energy transmitters can cooperatively form focused beams of energy and power for transmission to energy harvesters in the energy-receiving devices, such as sensors, Internet of Things (IoT) enabled appliances, and mobile/wearable equipment.

Abstract: The disclosed apparatus and methods can be used to provide an energy efficient Internet of Things (IoT) communication method that can be deployed on a city-wide scale using existing infrastructure and that can target individual sensors or devices. An example apparatus is a decoder including an energy detector and a processor. The energy detector is configured to detect average subframe energy levels of a plurality of subframes during reception of at least one frame of data defined by a first communications protocol (e.g., Long-Term Evolution (LTE)). The average subframe energy levels of the plurality of subframes form a pattern of relatively higher and lower energy levels. The processor is configured to interpret, according to a second communications protocol, the pattern of energy levels to decode a block of data represented by the pattern of energy levels. Another embodiment is a method producing index modulation signals of the second communications protocol.

Abstract: A distributed wireless radio frequency-based charging system includes hardware and software platforms. The hardware platform includes adaptive energy harvesters and programmable energy transmitters. The software platform manages the hardware profiles, resources (e.g., energy waveforms and transmission powers), schedules the beams of the energy transmitters, and switches between modes of wireless charging and data access point. This allows the energy transmitters to be configured adaptively based on the ambient energy availability, energy needs and number of energy-requesting devices in the network. Under the software control, the energy transmitters can cooperatively form focused beams of energy and power for transmission to energy harvesters in the energy-receiving devices, such as sensors, Internet of Things (IoT) enabled appliances, and mobile/wearable equipment.

Abstract: A distributed wireless radio frequency-based charging system includes hardware and software platforms. The hardware platform includes adaptive energy harvesters and programmable energy transmitters. The software platform manages the hardware profiles, resources (e.g., energy waveforms and transmission powers), schedules the beams of the energy transmitters, and switches between modes of wireless charging and data access point. This allows the energy transmitters to be configured adaptively based on the ambient energy availability, energy needs and number of energy-requesting devices in the network. Under the software control, the energy transmitters can cooperatively form focused beams of energy and power for transmission to energy harvesters in the energy-receiving devices, such as sensors, Internet of Things (IoT) enabled appliances, and mobile/wearable equipment.