The present invention relates to a cable unit for connecting devices in a system, in particular in a patient monitoring system, to enable wireless exchange of data and/or power between them. The proposed cable unit comprises a cable (510) and a connector (520, 530) arranged at each end of said cable, said connector comprising a data transmission unit (522, 532) for transmitting data to and/or receiving data from a device having a counterpart connector and a magnetic coupling unit (521, 531) for transmitting power to and/or receiving power from another device of the system having a counterpart connector by use of inductive coupling.

The present invention relates to a cable unit for connecting devices in a system, in particular in a patient monitoring system, to enable wireless exchange of data and/or power between them. The proposed cable unit comprises a cable (510) and a connector (520, 530) arranged at each end of said cable, said connector comprising a data transmission unit (522, 532) for transmitting data to and/or receiving data from a device having a counterpart connector and a magnetic coupling unit (521, 531) for transmitting power to and/or receiving power from another device of the system having a counterpart connector by use of inductive coupling.

Systems and methods consistent with the present disclosure may be utilized to negate the distinction between a display device operating in video and command modes in that commands associated with either mode are prioritized and executed according to a command scheduler consistent with the present disclosure. A command scheduler consistent with the present disclosure includes a display driver stack and a scheduler coupled to the display driver stack. The scheduler is configured to receive commands from the driver stack. Further, the scheduler is configured to queue and schedule the commands to be executed during a boot environment and during runtime. A host controller may also be coupled to the scheduler and may receive at least one of the commands from the scheduler. In time, the host controller transfers the commands to a device for execution.

A vehicle includes a first display circuit and a second display circuit. The first display circuit is disposed at a position capable of being visually checked by a driver. The second display circuit is disposed at a position capable of being visually checked by a driver. The first display circuit can display at least information about autonomous driving. The second display circuit can display at least information other than the information about the autonomous driving. First display circuit has first redundancy. The second display circuit has second redundancy lower than the first redundancy.

A system on a chip (SOC) and an integrated circuit device having the same are disclosed. The SOC has a chip controller and a first chip element which do not need to operate according to a reference clock signal, and the SOC has a second chip element which needs to operate according to the reference clock signal. During resetting of a main system processor, the chip controller of the SOC is reset simultaneously. After the chip controller finishes resetting, the first chip element is then reset. After the main system processor finishes resetting, the second chip element of the SOC starts to reset. Accordingly, during the resetting of the main system processor, the SOC is reset simultaneously, thereby reducing the boot time of the integrated circuit device.

Circuits and methods for determining a majority vote from a plurality of inputs. An example circuit includes a voting input stage, a transfer stage, and an accumulating stage. The voting input stage includes at least three input switched capacitors. The transfer stage includes transfer switched capacitors corresponding to the input switched capacitors. The transfer switched capacitors charge a voting capacitor corresponding to each input switched capacitor during a state of a clock signal. The accumulating stage includes accumulating switched capacitors connecting the voting capacitors in series. The accumulating switched capacitors cause the charges of the voting capacitors to be accumulated during an alternate state of the clock signal. The accumulated charge of the voting capacitors represents a majority vote of the input switched capacitors.

The present invention relates to a cable unit for connecting devices in a system, in particular in a patient monitoring system, to enable wireless exchange of data and/or power between them. The proposed cable unit comprises a cable (510) and a connector (520, 530) arranged at each end of said cable, said connector comprising a data transmission unit (522, 32) for transmitting data to and/or receiving data from a device having a counterpart connector and a magnetic coupling unit (521, 531) for transmitting power to and/or receiving power from another device of the system having a counterpart connector by use of inductive coupling.

A safety booting method for an embedded controller is applied in a laptop. The embedded controller is installed in the laptop, and the laptop includes a central processor unit (CPU). The safety booting method for the embedded controller includes steps of: connecting the embedded controller with a power; determining whether a safety verification for a booting read only memory (ROM) is passed or not; and initializing the power of the laptop by the embedded controller to normally provide the power to the laptop and boot the laptop when the safety verification for the booting ROM is passed.

Systems and methods for trusted integration of untrusted components. An example system includes at least three electrical components and voting (consensus) circuitry. The components have varied hierarchical implementations for providing common output given common input. The voting circuitry is configured to receive, as input, outputs from the components and provide a consensus output that is a majority of the outputs received from the components. Such a diversity of multiple untrusted system components (hardware and/or software) engaged in redundant operation can be integrated to as a consensus-based trusted system with a high degree of fault tolerance to unforeseen environmental interference, cyber-attack, supply chain counterfeit, inserted Trojan logic, or component design flaws. The degree of fault tolerance can be increased by increasing the degree of diversity of redundant operational nodes or by increasing the number of diversely implemented operational nodes.

Circuits and methods for determining a majority vote from a plurality of inputs. An example circuit includes a voting input stage, a transfer stage, and an accumulating stage. The voting input stage includes at least three input switched capacitors. The transfer stage includes transfer switched capacitors corresponding to the input switched capacitors. The transfer switched capacitors charge a voting capacitor corresponding to each input switched capacitor during a state of a clock signal. The accumulating stage includes accumulating switched capacitors connecting the voting capacitors in series. The accumulating switched capacitors cause the charges of the voting capacitors to be accumulated during an alternate state of the clock signal. The accumulated charge of the voting capacitors represents a majority vote of the input switched capacitors.