Abstract: A multi-sensor data fusion-based self-powered online monitoring system for a transmission line includes a plurality of detection nodes, an optical communication receiving and demodulation module, and a data processing module. The detection nodes each include a vibration energy harvesting module, a sensing module, and an optical communication modulation and transmitting module. The detection node uses a triboelectric nanogenerator (TENG) to convert and harvest energy, uses the sensing module to acquire a plurality of types of sensing data, and uses the optical communication modulation and transmitting module to modulate and transmit the sensing data. The optical communication receiving and demodulation module correspondingly receives and demodulates the sensing data, and transmits the sensing data to the data processing module for processing.

Abstract: Embodiments of the present disclosure provide a signal acquisition circuit. The signal acquisition circuit includes a differential amplifier, a first electrode, a second electrode, a first negative capacitance circuit, and a second negative capacitance circuit. The first electrode is connected to a first input terminal of the differential amplifier through a first lead, and the second electrode is connected to a second input terminal of the differential amplifier through a second lead. The first negative capacitance circuit is electrically connected to the first lead and ground, and the second negative capacitance circuit is electrically connected to the second lead and the ground. Both the first negative capacitance circuit and the second negative capacitance circuit exhibit a negative capacitance effect.

Abstract: A multi-sensor data fusion-based self-powered online monitoring system for a transmission line includes a plurality of detection nodes, an optical communication receiving and demodulation module, and a data processing module. The detection nodes each include a vibration energy harvesting module, a sensing module, and an optical communication modulation and transmitting module. The detection node uses a triboelectric nanogenerator (TENG) to convert and harvest energy, uses the sensing module to acquire a plurality of types of sensing data, and uses the optical communication modulation and transmitting module to modulate and transmit the sensing data. The optical communication receiving and demodulation module correspondingly receives and demodulates the sensing data, and transmits the sensing data to the data processing module for processing.

Abstract: The present disclosure provides a hot-plugging control method, device, and retimer. The hot-plugging control method includes: receiving data from a pluggable device through a second end, sending the data to an RC through a first end; sending a detection signal to the second end to detect the connection status between the pluggable device and the second end; and stopping sending the data to the RC, and sending the first control signal to the RC, when it is detected that the pluggable device is hot-unplugged from the second end, so that the RC handles the abnormal state of the data not being sent according to the first control signal. The hot-plugging control method provided by the present disclosure does not require presence signals to implement hot-plugging of a pluggable device, and thus can avoid the problem that the device cannot implement hot-plugging without presence signals.

Abstract: The present disclosure provides a hot-plugging control method, device, and retimer. The hot-plugging control method includes: receiving data from a pluggable device through a second end, sending the data to an RC through a first end; sending a detection signal to the second end to detect the connection status between the pluggable device and the second end; and stopping sending the data to the RC, and sending the first control signal to the RC, when it is detected that the pluggable device is hot-unplugged from the second end, so that the RC handles the abnormal state of the data not being sent according to the first control signal. The hot-plugging control method provided by the present disclosure does not require presence signals to implement hot-plugging of a pluggable device, and thus can avoid the problem that the device cannot implement hot-plugging without presence signals.