The present disclosure relates to methods for control of power source usage of a multi power source radio device 7. A method performed by a server 30 comprises obtaining information B 5 about a plurality of power sources available for the radio device. The method also comprises, based on the obtained information, determining criteria for when to use at least one of the plurality of power sources. The method also comprises sending a power source configuration message C towards the radio device, comprising information about the determined criteria, for enabling the radio device to use said at least one of the plurality of power sources in 10 accordance with the determined criteria.

The present invention relates to a data communication device and method for recording and transmitting data concerning conditions within or pertaining to a transportation container, such as a controlled environment transportation container. The communication device includes a processor, a memory, a port for receiving the data, a first power source, a communication module operatively coupled to the first power source, and a computer program stored in the memory. The program is operative, when executed on the processor, to store the received data in the memory and to cause the communication module to periodically power on, attempt for a specified time period to establish a network connection, and in the event of a successful connection, communicate data stored in the memory over the network, and to power off. The processor independently operates to switch between sleep and active modes in accordance with a system timer or receipt of data, and to determine whether the communication module is to be activated.

A wireless communication apparatus includes a first control unit operating with power supplied from a secondary battery and operable in a case where a detected voltage of the secondary battery is greater than or equal to a second threshold voltage, a second control unit operating independent from the first control unit and with power supplied from the secondary battery, and a wireless communication unit controlled by the second control unit operating with power supplied from the secondary battery to communicate with a different wireless communication apparatus, wherein, in a case where a detected voltage of the secondary battery is lower than a first threshold voltage that is lower than the second threshold value, the second control unit ends transmission of a packet and communication connection.

An electronic device includes: a location measurement circuitry; a rechargeable battery; a memory configured to store instructions; and at least one processor. The at least one processor may be configured to execute the instructions to: monitor a usage pattern of the battery while the electronic device operates in a first power management state; acquire, based on determining that the usage pattern of the battery is different from a reference pattern derived from a model, information on a location in which the battery is estimated to be charged and information on a time at which the battery is estimated to be charged using the model; and switch, partially based on the information on the location and the information on the time, the first power management state to a second power management state based on a second maximum driving frequency lower than the first maximum driving frequency.

This disclosure provides systems, methods and apparatus, including computer programs encoded on computer storage media, for fast role switching between master and slave roles among wireless nodes. In one aspect, wireless nodes, such as wireless earbuds, coupled to a wireless source, may dynamically and intelligently swap master and slave roles to optimize battery life in the wireless nodes.

A radio-power distribution controller (300) for controlling far-field radio-power delivery from an external radio-power-supply-device (302) to at least one external radio-power receiving device (300) that has a power-converter for converting a received radio-energy amount into an electrical operation power amount for operating the radio-power receiving device is provided and comprises a radio-power monitoring unit (306), which is configured to determine a duration of a received power-delivering radio signal, to determine, an estimate of a received radio-energy amount, which has been received by the radio-power receiving device (300). Upon determining that the estimate of the received radio-energy amount is below a threshold energy amount, it provides a radio-power-shortage signal.

A cellular modem is configured for low power applications. In some instances, the cellular modem includes a transceiver, a processor to control the transceiver, a memory device in communication with the processor, and a general-purpose input/output (GPIO) pin, controlled by the processor. In an example, the cellular modem receives an appointed time for an upcoming communication and determines a time to activate a power supply. The determination may be based at least in part on the appointed time for the communication, so that the power supply is ready to supply power at a level consistent with use of the transceiver at the appointed time of the communication. At the determined time, a signal from the GPIO pin is used to activate the power supply, resulting in an increase in power supplied to the cellular modem in a just-in-time manner.

The present disclosure is directed systems, methods, and apparatus for light enabled indoor positioning and reporting. In some embodiments, a device of the present disclosure includes a housing that includes a processor and a wireless radio. The device includes a clip that secures the housing adjacent to and a predetermined distance from a portion of a light tube that produces light. The device includes a solar cell that is configured to be exposed to the light from the light tube upon the housing being securely attached via the one or more clips adjacent to the portion of the light tube. The device includes a circuit by which power is converted from the solar cell to the processor and the wireless radio via at least one switch. The wireless radio can broadcast a beacon provided by the processor.

A node within a wireless network is powered by a solar hybrid battery system. The solar hybrid battery system includes a solar panel, a primary cell, and a secondary cell. The secondary cell includes only enough power storage to be capable of powering the node during the longest daily interval of darkness in the region where the node is deployed. The solar panel is sized relative to the secondary cell to be capable of fully recharging the secondary cell during the shortest daily interval of daylight in the region where the node is deployed, even under conditions of limited solar irradiance (e.g. due to clouds). The primary cell can charge the secondary battery if the node is shelved or malfunctioning to prevent the secondary cell from becoming overly depleted. The primary cell can also provide the node with additional power during times of peak demand or to perform status reports.

According to various embodiments, an electronic device comprises: a near-field communication unit; and a control unit electrically connected to the near-field communication unit, wherein the control unit can be configured to detect whether a foreign object is located between the electronic device and a first electronic device by using the near-field communication unit before performing wireless charging with the first electronic device which provides power wirelessly.