A medium processing apparatus includes: an ultrasonic oscillator; an ultrasonic sensor arranged at a position that opposes the ultrasonic oscillator interposing a transport path of a medium; an amplification circuit configured to amplify an output signal of the ultrasonic sensor; an integration circuit configured to integrate an output signal of the amplification circuit; a discharge circuit configured to perform discharge of an electric charge of a power storage circuit included in the integration circuit; and a determination circuit configured to determine whether or not multi-feed of the medium occurs on the basis of an output signal of the integration circuit, in which the discharge circuit stops, after performing discharge over a first period or more, the discharge, and after a second period has passed, the determination circuit performs a first (an initial) determination whether or not the multi-feed of the medium occurs.

A circuit for monitoring an output voltage of a voltage supply is shown. The circuit comprises a microcontroller for controlling a system, a shift register and a diagnostic circuit. The microcontroller has an input for receiving serial output data of the shift register, wherein the input is connected to the serial output of the shift register. The diagnostic circuit is designed to diagnose the voltage supply and has a diagnostic output which is connected to a data input of the shift register for inputting a diagnostic bit.

Provided is a dynamic control method that turns off a primary-side switching transistor when an output voltage exceeds an upper limit, and control the switching of a secondary-side synchronous rectification transistor with a fixed cycle and a fixed duty cycle. During the time that the synchronous rectification transistor is turned on, the energy of a load capacitor at the output end is extracted to the primary side, which causes the output voltage to drop rapidly and the overshoot voltage to decrease greatly.

A dual-output port charging circuit includes a primary switching circuit, a secondary first switching circuit, a secondary second switching circuit, a transformer connected to the three circuits, and a controller. The controller receives and samples an output voltage and an output current of the secondary second switching circuit, the output voltage and the output current are compared with a reference value, and a compensation is made, so as to eventually control an on-off time of a switch in the primary switching circuit; and the controller receives and samples an output current of the primary switching circuit, a zero-cross delay is calculated through a zero detection, so as to control an on-off time of a rectification switch in the secondary second switching circuit. One controller is used to flexibly control voltages of two direct current output ports with accurate voltage regulation and strong antijamming capability.

A waveform separator system for determining DC leakage current flowing through an insulating structure in a high voltage direct current power system, wherein the DC leakage current is a composite DC current comprising one or more high magnitude momentary spikes, and having a DC component and an AC component includes: (1) a waveform separator configured to receive the composite DC current flowing through the insulating structure and to separate the composite DC current into corresponding direct current (DC) and alternating current (AC) components wherein the AC component has a first rate of change, and wherein the DC component has a second rate of change, and wherein the first rate of change is greater than the second rate of change; (2) at least one comparator configured to receive the AC component and produce at least one corresponding digital signal; and (3) a processor configured to: (a) receive the at least one corresponding digital signal and the DC component, (b) analyze the at least one corresponding digital signal and the DC component, and; (c) determine a resultant leakage current flowing through the insulating structure.

A method for discharging a capacitor of an input or output circuit arrangement of an inverter for supplying current to a power supply grid is disclosed. The method includes determining a supply voltage at connections of the input or output circuit arrangement, determining a DC link voltage of a DC link capacitor of the inverter; and calculating an upper limit voltage value of the DC link capacitor based on the measured supply voltage and the measured DC link voltage. The method also includes operating an input-side DC/DC converter or an output-side bridge arrangement of the inverter such that energy from the capacitor of the input or output circuit arrangement is transferred to the DC link capacitor, wherein the voltage across the DC link capacitor is monitored; and ending the method if the voltage across the DC link capacitor exceeds the upper limit voltage value. Otherwise the method continues to transfer energy from the capacitor of the input or output circuit arrangement to the DC link capacitor until the capacitor is discharged to or below a lower limit voltage value.

The present invention relates to a battery module and cell configuration recognition system for ID assignment, and more specifically, to a battery module and cell configuration recognition system for ID assignment that recognizes the number of battery cells and battery modules connected in series in order to assign an ID to a BMS and a battery cell of each of the battery modules.

A diagnostic system includes a microcontroller having a first A/D converter, first and second applications, and a first analog multiplexer electrically between a first voltage regulator and the first A/D converter. The first application sets a first overvoltage diagnostic flag to a first fault value if a first voltage of the first voltage regulator that is measured by the first A/D converter is greater than a first voltage, and in response further transitions a contactor to an open operational state. The second application sets a second overvoltage diagnostic flag to a second fault value if a second voltage of the first voltage regulator that is measured by the first A/D converter is greater than a second voltage, and in response further transitions the contactor to the open operational state.

A frequency variable oscillator generates a clock having a frequency according to a control signal. A reference current source generates a reference current. A path selector distributes the reference current to a first path and a second path in a time-sharing manner in synchronization with the clock. An F/V conversion circuit includes a capacitor connected to the first path, and charges or discharges the capacitor with the reference current and generates a detection voltage. The reference voltage source includes a resistor connected to the second path, and outputs a reference voltage according to a voltage across the resistor. A feedback circuit adjusts a control signal so that the detection voltage approaches the reference voltage.

Circuits and methods are disclosed for determining a ground path impedance difference in a vehicle having master and slave control. An example circuit for detecting a difference in ground path impedance in a vehicle includes a master ground terminal and a slave ground terminal. The circuit also includes a first shunt resistor electrically coupled between the master ground terminal and a common internal ground, and a second shunt resistor electrically coupled between the slave ground terminal and the common internal ground. The circuit further includes a bi-directional current sense amplifier having as inputs the master ground terminal and the slave ground terminal.