An impact detection device includes an impact detector, a wireless communication device, an energy storage device, an autonomous electrical energy generation device, a device for receiving energy by radio frequency, the device being configured to adopt the following two modes: a first mode, referred to as autonomous mode, in which the autonomous electrical energy generation device is configured to supply the impact detector and the wireless communication device; a second mode, referred to as external mode, in which the device for receiving energy by radio frequency is configured to supply the impact detector and the wireless communication device.

A device controls a safety-relevant electronic system and has a power supply. The power supply is supplied with a battery voltage at a first input terminal and supplies a first supply voltage at a first output terminal which is lower than the battery voltage. A microcontroller for generating a first control signal, provided at a first control output of the microcontroller for processing by way of a control unit, is supplied with the first supply voltage at a second input terminal. A monitoring unit for generating a second control signal, provided at a second control output of the monitoring unit for processing by the control unit, is supplied with the first supply voltage at a third supply potential input terminal. The third supply potential input terminal, the second control output and the second data port of the monitoring unit are configured to be voltage-proof with respect to the battery voltage.

Electronic devices include: a first electronic device capable of being always supplied with power; and a second electronic device capable of being supplied with the power through an operation by an occupant. Each of power supply hubs is located near the first electronic device, and connected to a battery or another one of the power supply hubs by one of main power supply lines. Each of the first and second electronic devices is connected to nearby one of the power supply hubs. Each of zone ECUs outputs a control signal to one of power supply ICs so as to distribute, to the first and second electronic devices, the power supplied to one of the power supply hubs by one of the main power supply lines.

A switch arrangement for providing alternative distribution paths in a system for distributing electrical power in a vehicle including electrical power supplies and electrical loads. The switch arrangement includes a first switch configured to be connected to a first electrical element, a second switch configured to be connected to the first electrical element and a second electrical element, and a third switch configured to be connected to the second electrical element and a third electrical element. Each of the first, second, and third switches is independently controllable, and selective operation of each of the first, second, and third switches to its open or closed state interconnects at least two of the first, second, and third electrical elements to establish one of multiple alternative distribution paths to connect one of the power supplies and one of the loads or to connect two of the power supplies.

A selection circuit architecture makes it possible to perform upward and/or downward transitions in sets of sequences of slow and fast phases so as at the same time to solve the problems of inductive switching noise and the problems of currents in the supply rails. This solution has multiple advantages linked to the ease of implementation and flexibility of configurations that are possible for adapting to the specific constraints when designing the circuit.

A photovoltaic system includes an inverter and a plurality of photovoltaic units connected to the inverter. Each photovoltaic unit includes a controller and one or more photovoltaic modules connected to the controller. The controller in each photovoltaic unit is further configured to obtain a power carrier signal sent by a controller in another photovoltaic unit of the plurality of photovoltaic units, determine an attenuation reference factor of the power carrier signal based on the obtained power carrier signal, and send the attenuation reference factor to the inverter. The inverter is further configured to group the plurality of photovoltaic units based on the attenuation degree of the power carrier signal obtained by each photovoltaic unit. This application can implement automatic grouping of photovoltaic units.

A system for power management of an electronic device. The system comprises a programmable system microcontroller; power ports configured to sink or source electrical power; and a programmable power multiplexor connected between the power ports and the system microcontroller. The system further comprises bi-directional load switches connected between the power port and a bi-directional voltage convertor, and configurable to allow electrical power to flow through the bi-directional load switch. The bi-directional voltage convertor converts a first voltage supplied by the bi-directional load switch to a second voltage and supplies power at the second voltage to the electronic device or external device through the power ports. The programmable system microcontroller controls the direction in which each bi-directional load switch allows power to flow and the second voltage, such that the system sinks or sources power at each of the power ports according to programming of the system microcontroller.

A power supply switching control system switches a power supply for supplying power to a load between a first power supply and a second power supply in a power supply system. The power supply switching control system includes a first switch provided between the first power supply and the load in the power supply path and configured to cut off a current flowing from the second power supply to the first power supply in an off state of the first switch, a second switch provided between the second power supply and the load in the power supply path and configured to cut off a current flowing from the first power supply to the second power supply in an off state of the second switch, and a control unit configured to set the second switch in an on state when the second power supply is charged.

An example computing device includes a power switch, a power management device to control a power state change of the computing device based on a command from a power control device, and a controller. The controller is to, in response to receiving a power control request message from an external device, change the power control device from the power switch to the external device.

Systems, methods and devices for a coaxial cable transmission system. A power supply receives a primary power signal from a power source. The power supply generates a switched direct current power signal from the primary power signal. A power gateway receives the switched direct current power signal over a coaxial cable from the power supply. The power gateway generates a secondary power signal from the switched direct current power signal. A load device receives the secondary power signal from the power gateway. In some implementations, the power supply generates the switched direct current power signal at a positive direct current voltage level for a first part of a time period and at a negative direct current voltage level for a second part of the time period.