Abstract: A resistive memory apparatus including a memory cell array, at least one dummy transistor and a control circuit is provided. The memory cell array includes a plurality of memory cells. Each of the memory cells includes a resistive switching element. The dummy transistor is electrically isolated from the resistive switching element. The control circuit is coupled to the memory cell array and the dummy transistor. The control circuit is configured to provide a first bit line voltage, a source line voltage and a word line voltage to the dummy transistor to drive the dummy transistor to output a saturation current. The control circuit is further configured to determine a value of a second bit line voltage for driving the memory cells according to the saturation current. In addition, an operating method and a memory cell array of the resistive memory apparatus are also provided.

Abstract: A semiconductor structure includes a substrate, a conductive via and a first insulation layer. The conductive via is through the substrate. The first insulation layer is between the substrate and the conductive via. A first surface of the first insulation layer facing the substrate and a second surface of the first insulation layer facing the conductive via are extended along different directions.

Abstract: An acute kidney injury predicting system and a method thereof are proposed. A processor reads the data to be tested, the detection data, the machine learning algorithm and the risk probability comparison table from a main memory. The processor trains the detection data according to the machine learning algorithm to generate an acute kidney injury prediction model, and inputs the data to be tested into the acute kidney injury prediction model to generate an acute kidney injury characteristic risk probability and a data sequence table. The data sequence table lists the data to be tested in sequence according to a proportion of each of the data to be tested in the acute kidney injury characteristics. The processor selects one of the medical treatment data from the risk probability comparison table according to the acute kidney injury characteristic risk probability.

Abstract: A wrist worn RFID device with security protection includes a wrist worn body, a control circuit, a sensing circuit, a safety circuit, a RFID module and a processing circuit. When the control circuit detects that two connecting ends of the control circuit are electrically conducted due to two combined portions of the wrist worn body are fastened together, an enable signal is generated. The processing circuit controls the sensing circuit and the safety circuit according to the enable signal. When detecting the physiological signal, the sensing circuit generates a first validation signal. When the inputted user information is accepted by the identity verification program, the safety circuit generates a second validation signal. The processing circuit generates a control signal according to the first validation signal and the second validation signal, so that the RFID module implements a wireless transmission based on the control signal.

Abstract: A wrist worn RFID device with security protection includes a wrist worn body, a control circuit, a sensing circuit, a safety circuit, a RFID module and a processing circuit. When the control circuit detects that two connecting ends of the control circuit are electrically conducted due to two combined portions of the wrist worn body are fastened together, an enable signal is generated. The processing circuit controls the sensing circuit and the safety circuit according to the enable signal. When detecting the physiological signal, the sensing circuit generates a first validation signal. When the inputted user information is accepted by the identity verification program, the safety circuit generates a second validation signal. The processing circuit generates a control signal according to the first validation signal and the second validation signal, so that the RFID module implements a wireless transmission based on the control signal.

Abstract: The present invention proposes an implantable bone-vibrating hearing aid, including a transmitting coil for receiving an audio-converted signal and generating a corresponding magnetic field, a magnetic conducting element for sensing the corresponding magnetic filed to generate a driving force, and a vibrating module for receiving the driving force and generating a vibration, wherein the magnetic conducting element and the vibrating module are implanted beneath a skin of a user, and the vibration generated by the vibrating module knocks on the temporal bone of the ear of the user, which generates mechanical waves that propagate to the inner ear of the user, creating a sense of hearing thereto.