Abstract: An arrayed switch circuit includes a substrate, signal conductive pads and signal expansion pins. The signal conductive pads are disposed on the substrate at intervals, and the signal conductive pads are arranged to form a signal conductive pad array. Each of the signal conductive pads has a row position and a column position in the signal conductive pad array. A row signal switch is provided between any two adjacent signal conductive pads corresponding to the same row position, and a column signal switch is provided between any two adjacent signal conductive pads corresponding to the same column position. The signal expansion pins are connected to the signal conductive pads located on at least one side of the signal conductive pad array through signal expansion switches respectively.

Abstract: A nucleic acid detection kit includes a detection chip, an electrophoresis box, and a connection unit. The detection chip includes interconnected channel, outlet, and first opening. The electrophoresis box is disposed below the detection chip. The electrophoresis box includes an inlet corresponding to the channel and a second opening away from the channel. The outlet is connected to the inlet. One end of the connection unit is connected to the first opening, and the other end is connected to the second opening, so that the channel is further connected to the electrophoresis box for pressure equalization during transportation and sudden movements. A nucleic acid detection device able to receive the nucleic acid detection kit is also disclosed.

Abstract: A nucleic acid detection kit includes a kit body, a detection chip, an electrophoresis box, and a connector. The detection chip includes a channel for carrying a microbead sample of the acid. The detection chip is connected to the electrophoresis box. The connector is electrically connected to the detection chip and the electrophoresis box. The microbead undergoes a PCR amplification reaction to obtain a mixed microbead in the channel. The mixed microbead undergoes an electrophoretic detection in the electrophoresis box. A nucleic acid detection device includes the nucleic acid detection kit is also disclosed. The nucleic acid detection device has a simple structure, which is portable, flexible, and convenient, and can be used at home.

Abstract: A distributed amplifier with low supply voltage and low power consumption is provided. The distributed amplifier includes an input terminal inputting an input signal; an output terminal outputting an output signal; an amplifier unit; a gate line circuit connected to the input terminal, a first load circuit and the amplifier unit; a second load circuit; a drain line circuit connected to the second load circuit, the amplifier unit and the output terminal; and a bias voltage circuit connected between the drain line circuit and the output terminal, wherein the bias voltage circuit includes a voltage source; an inductor connected to the voltage source and a terminal of the drain line circuit; and a capacitor multiplier connected to the inductor, the drain line circuit and the output terminal.

Abstract: A distributed amplifier with low supply voltage and low power consumption is provided. The distributed amplifier includes an input terminal inputting an input signal; an output terminal outputting an output signal; an amplifier unit; a gate line circuit connected to the input terminal, a first load circuit and the amplifier unit; a second load circuit; a drain line circuit connected to the second load circuit, the amplifier unit and the output terminal; and a bias voltage circuit connected between the drain line circuit and the output terminal, wherein the bias voltage circuit includes a voltage source; an inductor connected to the voltage source and a terminal of the drain line circuit; and a capacitor multiplier connected to the inductor, the drain line circuit and the output terminal.

Abstract: A transconductance controlling circuit is provided. The transconductance controlling circuit includes a resonance circuit, a negative-resistance unit-circuit and a transconductance boosting circuit. The resonance circuit generates an oscillation signal. The negative-resistance unit-circuit is coupled to a resonance circuit and includes a first transistor and a second transistor. The transconductance boosting circuit is coupled to the negative-resistance unit-circuit and includes a third transistor and a fourth transistor. A first drain of the first transistor is coupled to a third drain of the third transistor, a first gate of the first transistor is coupled to a third gate of the third transistor, the first gate of the first transistor is coupled to a second drain of the second transistor, and a first base of the first transistor is coupled to a fourth base of the fourth transistor and to a fourth source of the fourth transistor.

Abstract: A transconductance controlling circuit is provided. The transconductance controlling circuit includes a resonance circuit, a negative-resistance unit-circuit and a transconductance boosting circuit. The resonance circuit generates an oscillation signal. The negative-resistance unit-circuit is coupled to a resonance circuit and includes a first transistor and a second transistor. The transconductance boosting circuit is coupled to the negative-resistance unit-circuit and includes a third transistor and a fourth transistor. A first drain of the first transistor is coupled to a third drain of the third transistor, a first gate of the first transistor is coupled to a third gate of the third transistor, the first gate of the first transistor is coupled to a second drain of the second transistor, and a first base of the first transistor is coupled to a fourth base of the fourth transistor and to a fourth source of the fourth transistor.

Abstract: A wideband transimpedance amplifier circuit is provided. The wideband transimpedance amplifier circuit includes a common-gate transistor, a bias current controlling circuit and an amplifier circuit. The bias current controlling circuit is coupled to a source of the common-gate transistor. The amplifier circuit is coupled to a drain of the common-gate transistor. The bias current controlling circuit adjusts the input impedance of the wideband transimpedance amplifier circuit according to the output signal of the amplifier circuit.

Abstract: A wideband transimpedance amplifier circuit is provided. The wideband transimpedance amplifier circuit includes a common-gate transistor, a bias current controlling circuit and an amplifier circuit. The bias current controlling circuit is coupled to a source of the common-gate transistor. The amplifier circuit is coupled to a drain of the common-gate transistor. The bias current controlling circuit adjusts the input impedance of the wideband transimpedance amplifier circuit according to the output signal of the amplifier circuit.

Abstract: The present invention relates to a substrate-transporting device, including a base, a substrate carrier unit and a shaft unit mounted between the base and the substrate carrier unit. The shaft unit has a supporting shaft and a shaft base to support and control rotation of the substrate carrier unit. The substrate carrier unit includes a bottom carrier seat connected to the supporting shaft, a plurality of first supporting components mounted on a surface of the bottom carrier seat, a top carrier seat having a plurality of vacuum suction nozzles and a plurality of second supporting components, and at least a retractable component sandwiched between the top carrier seat and the bottom carrier seat. The top carrier seat is used to affix and detect the substrate. The retractable component is capable of adjusting the distance between the top carrier seat and the bottom carrier seat.