A signal transmission circuit includes N signal transmission paths, a boost control module and a first feedback module; the signal transmission path includes two signal transmission terminals and a path switch connected between the two signal transmission terminals; the first feedback module is configured to feed back a voltage to be superimposed to the boost control module, the voltage to be superimposed is matched to the maximum voltage among voltages of the M signal transmission terminals; the boost control module is configured to boost the input voltage and output a target signal through a third terminal of the boost control module to drive the path switch into a first state by using the target signal when the input voltage is at a high level, where a voltage of the target signal is adapted to the sum of a boosted voltage of the input voltage and the voltage to be superimposed.

A signal transmission circuit includes N signal transmission paths, a boost control module and a first feedback module; the signal transmission path includes two signal transmission terminals and a path switch connected between the two signal transmission terminals; the first feedback module is configured to feed back a voltage to be superimposed to the boost control module, the voltage to be superimposed is matched to the maximum voltage among voltages of the M signal transmission terminals; the boost control module is configured to boost the input voltage and output a target signal through a third terminal of the boost control module to drive the path switch into a first state by using the target signal when the input voltage is at a high level, where a voltage of the target signal is adapted to the sum of a boosted voltage of the input voltage and the voltage to be superimposed.

A system which in some embodiments comprises a wireless smart device assembly that includes a smart device, wherein the smart device assembly is attachable or mountable against an unopened surface of a wall or other structure. In some embodiments, a system comprises a smart device assembly that includes a smart device; and a fastener that includes adhesive and is coupled to the smart device assembly and releasably attachable to a wall or other structure. Some embodiments include a level indicator configured to indicate the angular position or orientation of one or more other portion of the smart device assembly relative to parallel and/or plumb to the force of gravity. In some embodiments, a mount and/or a cover define a catch to releasably attach the cover to the mount.

A system which in some embodiments comprises a wireless smart device assembly that includes a smart device, wherein the smart device assembly is attachable or mountable against an unopened surface of a wall or other structure. In some embodiments, a system comprises a smart device assembly that includes a smart device; and a fastener that includes adhesive and is coupled to the smart device assembly and releasably attachable to a wall or other structure. Some embodiments include a level indicator configured to indicate the angular position or orientation of one or more other portion of the smart device assembly relative to parallel and/or plumb to the force of gravity. In some embodiments, a mount and/or a cover define a catch to releasably attach the cover to the mount.

A system, automobile, and method for implementing an electronic control function of an automobile. The system includes a first vehicle integration unit (VIU), an automobile control unit, and a plurality of automobile parts. The automobile control unit includes a first domain controller (DC) or a central computing platform (CCP). The automobile control unit is configured to send first control information to the first VIU. The first VIU is configured to control the plurality of automobile parts based on the first control information. In embodiments of this application, the first VIU controls the plurality of automobile parts.

The invention provides a sensor device for controlling an electrical device, wherein the sensor device comprises a controller and a range sensor; wherein sensor device is configured to be mounted in an orientation relative to gravity; wherein the range sensor is configured to: obtain the orientation of the sensor device relative to gravity; operate in a first detection mode for detecting an object within a first predetermined distance range from the range sensor when the orientation is in a first predetermined orientation; wherein the controller is configured to output a control signal arranged for controlling the electrical device upon the range sensor detecting the object.

A control system includes a control unit configured to control a target controlled apparatus, and at least one communication processing unit configured to execute communication processing in communication between the target controlled apparatus and the control unit, and in the control system, the communication processing unit sequentially measures a processing time of the communication processing and sequentially outputs delay information indicating the measured processing time to the control unit, and the control unit sequentially acquires the delay information from all of a plurality of the communication processing units, and sequentially updates delay information incorporated in a control algorithm for controlling the target controlled apparatus based on the acquired delay information.

A system configured to convert an output of a sensor for an application includes an analog input circuit and a processor. The analog input circuit is configured to receive the sensor output. The processor is configured to determine an analog input of the analog input circuit to read the sensor output, and based on one or more received sensor characteristics, and convert the read sensor output to a signal compatible with the application.

A system configured to convert an output of a sensor for an application includes an analog input circuit and a processor. The analog input circuit is configured to receive the sensor output. The processor is configured to determine an analog input of the analog input circuit to read the sensor output, and based on one or more received sensor characteristics, and convert the read sensor output to a signal compatible with the application.

The present invention reduces the time required by measuring a sensor object more than before. An input unit (10) includes an acquisition portion (11) that acquires a time sequence signal, a filter portion (12) that filters the time sequence signal according to a frequency, a forwarding portion (13) that forwards a filtered signal by frequency to a control device (90) and a filter switching portion (14). The filter switching portion (14) switches whether the filter portion (12) filters the time sequence signal according to a frequency in the process of acquiring the time sequence signal by the acquisition portion (11).