A method and device for wireless data transmission are described. A device receives sets of sensor data associated with respective sensor measurements for a vehicle. The device determines a priority for each of the sets of sensor data based on an amount of data stored for that sensor measurement in a number of data queues, and selectively stores each of the sets of sensor data in one of the data queues based on a threshold data throughput rate of a wireless network and the priority of each set of sensor data. The device transmits, to a second computing device via the wireless network, at least some of the sets of sensor data from the data queues based on a current data throughput rate of the wireless network and a priority level of each of the data queues.

In a case where an external charging start time is set in an external charging timer when a charging plug is connected to a charging connector, a charging controller is configured to perform standby setting of external charging before the external charging start time and transits to a pause state. The charging controller is intermittently activated during a timer charging setting period from a pause period start time when transition is made to the pause state to the external charging start time, and when a battery temperature at the time of activation of the charging controller is equal to or lower than a predetermined temperature, execute a temperature increase mode in which a heater is operated to increase the temperature of a main battery.

An embodiment of the present disclosure relates to a power supply interface comprising: a converter delivering a first DC voltage; a resistor connected between the converter and an output terminal of the interface delivering a second DC voltage; a first circuit delivering a second signal representative of a difference between the second DC voltage and a voltage threshold when a first signal is in a first state, and at a default value otherwise; a second circuit delivering a third signal representative of a value of a current in first resistor multiplied by a gain of the third circuit, and modifying the gain based on the second signal; and a third circuit configured to deliver a signal for controlling the converter based at least on the third signal.

A modular system for autonomous food assembly includes: a skid operable in a first configuration configured to transiently install on a vehicle and in a second configuration configured to transiently install in a kiosk; a set of food dispensing modules configured to transiently install on the skid and store and dispense food based on food orders; and a fixed infrastructure configured to distribute power from a first power source in the truck to the set of food dispensing modules in the first configuration, from a second power source in the fixed kiosk to the set of food dispensing modules in the second configuration, and to the set of food dispensing modules; a controller installed on the skid and configured to receive food orders and control the set of food dispensing modules to dispense food orders from the truck in the first configuration and from the kiosk in the second configuration.

A battery charging system of an electronic device includes: a battery having a first nominal voltage and including: battery cells each having a second nominal voltage that is less than the first nominal voltage; and electrical connectors that electrically connect ones of the battery cells to provide the battery with the first nominal voltage; a first charge port configured to electrically connect to a first type of connector; a charging module configured to: receive power via the first charge port; and when a voltage of the received power is less than the first nominal voltage at least one of: charge ones of the battery cells individually; and charge groups of two or more of the battery cells.

Embodiments of the present invention disclose a method for managing wiredly and wirelessly charging at least one of a fixed, portable and wearable computing and communications device. The method may comprise wirelessly charging a first of the at least one of fixed, portable and wearable computing and communications device serving as sink consuming power, when subjected to charging, using a wireless receiver detachably coupled to a smart adaptor subsystem via a first pair of magnetic connectors, detachably magnetically coupling a USB cable via second and third pairs of magnetic connectors correspondingly to a second of the at least one of fixed, portable and wearable computing and communications device serving as source supplying power, when subjected to charging, and the smart adaptor subsystem for facilitating wiredly charging the first of the at least one of fixed, portable and wearable computing and communications device, upon detachably magnetically coupling the USB cable, generating a cable detection signal using at least one of the wireless receiver and smart adaptor subsystem, upon successfully detecting the USB cable, generating an enable signal facilitating initiation of the smart adaptor subsystem using at least one of the wireless receiver and smart adaptor subsystem and upon generating the enable signal, automatically disabling the wireless receiver using the smart adaptor subsystem, thereby facilitating wiredly charging the first of the at least one of fixed, portable and wearable computing and communications device.

A power management apparatus configured to control charge and discharge of the battery, power discharged from the battery being supplied to a power consumption apparatus, the power management apparatus includes a memory, and a processor coupled to the memory and configured to receive, from the power consumption apparatus, first information indicating a first power amount which is predicted to be used in the power consumption apparatus, determine, based on the first power amount, a first value that is a value regarding a residual amount of the battery and is used for determining which of the charge and the discharge of the battery is to be preferentially executed, and control, based on the determined first value and the residual amount of the battery, the charge and the discharge of the battery.

A battery control system includes a plurality of battery cells that are separately controllable as units of individual cells or groups of cells. Each controllable unit may be switchably activated or deactivated in the overall battery circuit, and one or more conditions of each controllable unit may be individually measured. Various techniques are disclosed for operating the battery control system to optimize or improve system performance and longevity.

An AC-DC converter may include three phase terminals, two DC terminals, a first converter stage to convert between an AC current at the phase terminals and a first DC current at the first and second intermediate nodes, a second converter stage operable to convert between a first DC signal at third and fourth intermediate nodes and a second DC signal at the DC terminals, a first filter stage comprising a capacitor network having a star-point, a DC link connecting the first intermediate node to the third intermediate node and the second intermediate node to the fourth intermediate node. The second converter stage includes a middle voltage node between the DC terminals and a boost circuit having a midpoint node at the same electrical potential as the middle voltage node. The DC link includes a common mode filter having a common mode capacitor connecting the middle voltage node to the star-point.

Systems and apparatus may carry out analysis of battery physical phenomena, and characterize batteries based on phenomena occurring in particular time and/or frequency domains. These systems may be additionally responsible for charging and/or monitoring a rechargeable battery. Examples of battery physical phenomena include mass transport (e.g., diffusion and/or migration) in battery electrolytes, mass transport in battery electrodes, and reactions on battery electrodes.