An example apparatus includes: a first voltage source, a first amplifier having a noninverting input adapted to be coupled to a photodiode anode and coupled to the first voltage source, an inverting input adapted to be coupled to a photodiode cathode, and an output, a first resistor coupled to the first amplifier inverting input and to the first amplifier output, a first capacitor coupled to the inverting input of the first amplifier and the first amplifier output, and a second voltage source different from the first voltage source. There is a second amplifier having a noninverting input, an inverting input and an output. The noninverting input is coupled to the output of the first amplifier, the inverting input is coupled to the second voltage source, and there is a second resistor coupled to the inverting input and the output of the second amplifier.

A signal processing apparatus includes a first signal processing circuit configured to generate a first sound signal based on an input signal, and a second signal processing circuit configured to generate a second sound signal based on the first sound signal. In a case that a gain of the first signal processing circuit is switched, the second signal processing circuit generates, for a predetermined time after the gain of the first signal processing circuit is switched, a value of the second sound signal based on a value of the first sound signal at or before a timing of the gain of the first signal processing circuit being switched.

A capacitance detection circuit, a touch control chip and an electronic device are provided, which could reduce the influence of a display screen noise on capacitance detection. The capacitance detection circuit includes: an amplification circuit, connected to a detection capacitance in a touch screen, and configured to amplify a capacitance signal of the detection capacitance and convert the capacitance signal into a voltage signal, the voltage signal configured to determine the detection capacitance; and a control circuit, connected to the amplification circuit, and configured to control a magnification of the amplification circuit, where a period in which a noise peak of a noise signal of a display screen is located includes consecutive N sub-periods, and a magnification of the amplification circuit in the N sub-periods is inversely proportional to a magnitude of the noise signal in the N sub-periods, N>1.

In optical receivers, extending the transimpedance amplifier's (TIA) dynamic range is a key to increasing the receiver's dynamic range, and therefore increase the channel capacity. Ideally, the TIA requires controllable gain, whereby the receiver can modify the characteristics of the TIA and/or the VGA to process high power incoming signals with a defined maximum distortion, and low power incoming signals with a defined maximum noise. A solution to the problem is to provide TIA's with reconfigurable feedback resistors, which are adjustable based on the level of power, e.g. current, generated by the photodetector, and variable load resistors, which are adjustable based on the change in impedance caused by the change in the feedback resistor.

The present application provides a capacitance detection circuit, which could reduce the influence of screen noise on capacitance detection. The capacitance detection circuit includes: an amplification circuit connected to the capacitor to be detected, and configured to convert a capacitance signal of the capacitor to be detected into a voltage signal, the voltage signal being associated with the capacitance of the capacitor to be detected; and a control circuit connected to the amplification circuit, and configured to control an amplification factor of the amplification circuit to be a first amplification factor in a first period, and to control the amplification factor of the amplification circuit to be a second amplification factor in a second period, where noise generated by the screen in the first period is less than noise generated by the screen in the second period, and the first amplification factor is greater than the second amplification factor.

A filter includes multiple filter circuits. The filter circuits are coupled in series between an input terminal and an output terminal, to generate an output signal according to an input signal. One of the filter circuits operates as an active filter circuit or a passive filter circuit according to amplitude of the input signal.

According to one embodiment, a semiconductor device includes the following configuration. A detection circuit detects a state of a clock signal. An amplification circuit changes a gain based on the state of the clock signal detected by the detection circuit. An amplification circuit amplifies a first voltage with the gain and outputs a second voltage obtained as a result of amplification. A conversion circuit converts the second voltage output from the amplification circuit to first data. An isolation circuit includes a driver and a receiver electrically isolated from the driver. The driver transmits a signal corresponding to the first data to the receiver. The receiver outputs second data corresponding to the signal transmitted from the driver. The output circuit outputs the second data output from the isolation circuit.

A capacitance detection circuit, a touch control chip and an electronic device are provided, which could reduce the influence of a display screen noise on capacitance detection. The capacitance detection circuit includes: an amplification circuit, connected to a detection capacitance in a touch screen, and configured to amplify a capacitance signal of the detection capacitance and convert the capacitance signal into a voltage signal, the voltage signal configured to determine the detection capacitance; and a control circuit, connected to the amplification circuit, and configured to control a magnification of the amplification circuit, where a period in which a noise peak of a noise signal of a display screen is located includes consecutive N sub-periods, and a magnification of the amplification circuit in the N sub-periods is inversely proportional to a magnitude of the noise signal in the N sub-periods, N>1.

An integrated cinema amplifier comprises a power supply stage that distributes power over a plurality of channels for rendering immersive audio content in a surround sound listening environment. The amplifier automatically detects maximum and net power availability and requirements based on audio content by decoding audio metadata and dynamically adjusts gains to each channel or sets of channels based on content and operational/environmental conditions. A power supply stage provides power to drive a plurality of channels corresponding to speaker feeds to a plurality of speakers. The amplifier has a front panel having an LED array with each LED associated with a respective channel or group of channels of the multi-channel amplifier, and a control unit configured to light the LEDs according to display patterns based on operating status or error conditions of the amplifier.

An integrated cinema amplifier comprises a power supply stage that distributes power over a plurality of channels for rendering immersive audio content in a surround sound listening environment. The amplifier automatically detects maximum and net power availability and requirements based on audio content by decoding audio metadata and dynamically adjusts gains to each channel or sets of channels based on content and operational/environmental conditions. A power supply stage provides power to drive a plurality of channels corresponding to speaker feeds to a plurality of speakers. The amplifier has a front panel having an LED array with each LED associated with a respective channel or group of channels of the multi-channel amplifier, and a control unit configured to light the LEDs according to display patterns based on operating status or error conditions of the amplifier.