| 摘要 |
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. |
| 主权项 |
1. A sample and hold switch circuit, comprising a clock generation sub-circuit, a gate voltage bootstrap unit, a sampling Field Effect Transistor, a holding capacitor and a substrate selection sub-circuit,
the clock generation sub-circuit having a first output terminal and a second output terminal which are connected with the gate voltage bootstrap unit respectively, and the first output terminal and the second output terminal outputting two complementary clock pulses; the gate voltage bootstrap unit being connected with an external power source and having an output terminal connected with a gate of the sampling Field Effect Transistor and an input terminal connected with either of a drain and a source of the sampling Field Effect Transistor to provide a fixed gate-source voltage for the sampling Field Effect Transistor; either of the drain and the source of the sampling Field Effect Transistor being connected with a signal input terminal to input an analog signal, and the other of the drain and the source of the sampling Field Effect Transistor being connected with a signal output terminal to output a sampled analog signal; one terminal of the holding capacitor being connected with the signal output terminal, and the other terminal of the holding capacitor being grounded, for holding the sampled analog signal; and the substrate selection sub-circuit being connected with the signal input terminal, the signal output terminal, and a substrate of the sampling Field Effect Transistor respectively, 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, thereby eliminating bulk effect of the sampling Field Effect Transistor; wherein the substrate selection sub-circuit comprises a comparator, a follower, an inverter, a first switch, and a second switch; the comparator has an inverting input terminal connected with the signal input terminal, a non-inverting input terminal connected with the signal output terminal, and an output terminal connected with input terminals of the follower and the inverter; one terminal of the first switch is connected with the signal input terminal, one terminal of the second switch is connected with the signal output terminal, and the other terminals of the first switch and the second switch are connected with the substrate of the sampling Field Effect Transistor; and an output terminal of the follower is connected with a control terminal of the first switch, and an output terminal of the inverter is connected with a control terminal of the second switch; the gate voltage bootstrap unit comprises a first Field Effect Transistor, a second Field Effect Transistor, a third Field Effect Transistor, a fourth Field Effect Transistor, a fifth Field Effect Transistor, a sixth Field Effect Transistor, a seventh Field Effect Transistor, an eighth Field Effect Transistor and a bootstrap capacitor, and the first output terminal of the clock generation sub-circuit is connected with gates of the second Field Effect Transistor and the third Field Effect Transistor, the second output terminal of the clock generation sub-circuit is connected with gates of the first Field Effect Transistor and the eighth Field Effect Transistor; one terminal of the bootstrap capacitor is connected with a drain of the first Field Effect Transistor and a source of the second Field Effect Transistor respectively, and the other terminal of the bootstrap capacitor is connected with a drain of the fourth Field Effect Transistor and a source of the fifth Field Effect Transistor respectively, a drain of the fifth Field Effect Transistor is grounded via a leakage protection sub-circuit and the eighth Field Effect Transistor, the external power source is connected with sources of the third Field Effect Transistor and the fourth Field Effect Transistor, a drain of the sixth Field Effect Transistor and a source of the seventh Field Effect Transistor are connected with either of the drain and the source of the sampling Field Effect Transistor, and a gate of the sampling Field Effect Transistor is connected with a drain of the fifth Field Effect Transistor and a gate of the fourth Field Effect Transistor respectively; and the gate voltage bootstrap unit further comprises the leakage protection sub-circuit which is connected between the bootstrap capacitor and the ground, and the leakage protection sub-circuit is connected with the clock generation sub-circuit and the external power source respectively, and arranged for cutting a connection between the bootstrap capacitor and the ground when the sample and hold switch circuit is switched from holding to sampling. |
