Abstract: A power gating circuit includes inverters and a voltage divider sub-circuit, a latch comparator, and a gated switch sub-circuit connected to an external power supply circuit of 5V, respectively. The voltage divider sub-circuit is configured to divide a voltage of 5V and output a first voltage and a second voltage to the latch comparator and the gated switch sub-circuit, both voltage values of the first voltage and the second voltage are smaller than a withstand voltage value of a field effect transistor, and the voltage value of the first voltage is greater than that of the second voltage; the latch comparator is configured to compare two signals output by the inverters and latch a comparison result; and the gated switch sub-circuit is further connected with the latch comparator to control an output voltage, thereby improving the stability of the circuit, and extending the using life of the entire circuit.

Abstract: A power gating circuit includes inverters and a voltage divider sub-circuit, a latch comparator, and a gated switch sub-circuit connected to an external power supply circuit of 5V, respectively. The voltage divider sub-circuit is configured to divide a voltage of 5V and output a first voltage and a second voltage to the latch comparator and the gated switch sub-circuit, both voltage values of the first voltage and the second voltage are smaller than a withstand voltage value of a field effect transistor, and the voltage value of the first voltage is greater than that of the second voltage; the latch comparator is configured to compare two signals output by the inverters and latch a comparison result; and the gated switch sub-circuit is further connected with the latch comparator to control an output voltage, thereby improving the stability of the circuit, and extending the using life of the entire circuit.

Abstract: A sample and hold switch circuit includes a clock generation sub-circuit, a gate voltage bootstrap unit, a sampling Field Effect Transistor, a holding capacitor and a substrate selection sub-circuit which is connected with a signal input terminal, a signal output terminal and a substrate of the sampling Field Effect Transistor and arranged for selecting the signal input terminal or the signal output terminal to connect with the substrate of the sampling Field Effect Transistor according to the voltages of the analog signal inputted and the analog signal outputted. The sample and hold switch circuit reduces nonlinearity of the sampling Field Effect Transistor caused by its gate-source voltage changing with input signal, and eliminates bulk effect of the sampling Field Effect Transistor, thereby improving linearity of the sampling Field Effect Transistor, and extending dynamic range of the sample and hold switch circuit.

Abstract: A quick comparison circuit includes a cascaded N-stage operational amplifier, a flip-latch, a biasing circuit, and a control signal generating circuit, with N?2, and two differential signals to be compared being inputted to an input terminal of a first stage operational amplifier, an output terminal of a Nth stage operational amplifier being connected with an input terminal of the flip-latch, the biasing circuit supplying a biasing current to each stage operational amplifier, the control signal generating circuit being connected with the N-stage operational amplifier and the flip-latch respectively to supply a working time sequence and a reset control signal for them, and each stage operational amplifier having the same structure. This circuit has high gain and improved comparison speed.

Abstract: A POP noise suppression circuit includes a power source terminal, a clock signal input terminal, a charge unit, a discharge unit, a common-mode voltage judging and switching control unit, a charge and discharge capacitor, and a ground terminal. The charge unit includes a first clock generation circuit for generating a first pair of non-overlapped clock signal, and a first equivalent resistor. The discharge unit includes a second clock generation circuit for generating a second pair of non overlapped clock signals, and a second equivalent resistor. The charge unit generates a charge voltage changing slowly to the charge and discharge capacitor. The discharge unit generates a discharge voltage changing slowly to the charge and discharge capacitor. A POP noise suppression system is further provided.

Abstract: A quick comparison circuit includes a cascaded N-stage operational amplifier, a flip-latch, a biasing circuit, and a control signal generating circuit, with N?2, and two differential signals to be compared being inputted to an input terminal of a first stage operational amplifier, an output terminal of a Nth stage operational amplifier being connected with an input terminal of the flip-latch, the biasing circuit supplying a biasing current to each stage operational amplifier, the control signal generating circuit being connected with the N-stage operational amplifier and the flip-latch respectively to supply a working time sequence and a reset control signal for them, and each stage operational amplifier having the same structure. This circuit has high gain and improved comparison speed.

Abstract: A sample and hold switch circuit includes a clock generation sub-circuit, a gate voltage bootstrap unit, a sampling Field Effect Transistor, a holding capacitor and a substrate selection sub-circuit which is connected with a signal input terminal, a signal output terminal and a substrate of the sampling Field Effect Transistor and arranged for selecting the signal input terminal or the signal output terminal to connect with the substrate of the sampling Field Effect Transistor according to the voltages of the analog signal inputted and the analog signal outputted. The sample and hold switch circuit reduces nonlinearity of the sampling Field Effect Transistor caused by its gate-source voltage changing with input signal, and eliminates bulk effect of the sampling Field Effect Transistor, thereby improving linearity of the sampling Field Effect Transistor, and extending dynamic range of the sample and hold switch circuit.

Abstract: A sampling circuit for ADC includes an external input terminal, a sampling circuit and an auxiliary circuit which are connected with the external input terminal, a clock circuit and an external output terminal which are connected with the sampling circuit, and a clock feedthrough circuit connected with the auxiliary circuit, wherein the clock feedthrough circuit is respectively connected with the clock circuit and the external output terminal. The sampling circuit for ADC of the present invention decreases the impact of clock feedthrough on signal sampling, improves linearity of sampling FET, reduces harmonic distortion of the sampling circuit and improves sampling speed thereof, and improves sampling accuracy of the sampling circuit for ADC.

Abstract: A sampling circuit for ADC includes an external input terminal, a sampling circuit and an auxiliary circuit which are connected with the external input terminal, a clock circuit and an external output terminal which are connected with the sampling circuit, and a clock feedthrough circuit connected with the auxiliary circuit, wherein the clock feedthrough circuit is respectively connected with the clock circuit and the external output terminal. The sampling circuit for ADC of the present invention decreases the impact of clock feedthrough on signal sampling, improves linearity of sampling FET, reduces harmonic distortion of the sampling circuit and improves sampling speed thereof, and improves sampling accuracy of the sampling circuit for ADC.

Abstract: A POP noise suppression circuit includes a power source terminal, a clock signal input terminal, a charge unit, a discharge unit, a common-mode voltage judging and switching control unit, a charge and discharge capacitor, and a ground terminal. The charge unit includes a first clock generation circuit for generating a first pair of non-overlapped clock signal, and a first equivalent resistor. The discharge unit includes a second clock generation circuit for generating a second pair of non overlapped clock signals, and a second equivalent resistor. The charge unit generates a charge voltage changing slowly to the charge and discharge capacitor. The discharge unit generates a discharge voltage changing slowly to the charge and discharge capacitor. A POP noise suppression system is further provided.