CN203747798U - Sampling switch circuit - Google Patents

Abstract

The utility model discloses a sampling switch circuit. The sampling switch circuit comprises a sampling field-effect transistor and a holding capacitor. An external signal is input to the source electrode of the sampling field-effect transistor, the grid electrode of the sampling field-effect transistor is connected with an external power supply, the drain electrode of the sampling field-effect transistor is connected with one end of the holding capacitor, and the other end of the holding capacitor is connected to the ground. The sampling switch circuit further comprises an offset voltage generating sub circuit, an addition sub circuit and a grid voltage bootstrap sub circuit, wherein the offset voltage generating sub circuit generates a fixed voltage and inputs the fixed voltage to the addition sub circuit, the external signal is input to the addition sub circuit, the addition sub circuit is used for adding the fixed voltage and the voltage of the external signal together and outputting an overlaid voltage to the grid voltage bootstrap sub circuit, and the grid voltage bootstrap sub circuit is respectively connected with the output end of the addition sub circuit, the grid electrode of the sampling field-effect transistor and the external power supply and is used for loading the voltage output by the grid voltage bootstrap sub circuit to the grid electrode of the sampling field-effect transistor. According to the sampling switch circuit, the linearity of the sampling field-effect transistor is improved, the equivalent output impedance of the sampling field-effect transistor is reduced, and the sampling speed and the sampling output precision are guaranteed.

Description

Sampling switch circuit

Technical field

The utility model relates to integrated circuit fields, relates more specifically to a kind of sampling switch circuit.

Background technology

In the situation that digital circuit processing speed greatly improves, how to accelerate sampled analogue signals and it is quantized, be the important step that system can be highly integrated.Sampling switch circuit is the important interface realizing from analog to digital conversion, traditional sampling switch circuit is by MOS(metal-oxide semiconductor (MOS)) switch and maintenance electric capacity formation, and MOS switch is as the vital unit of sampling switch circuit, its performance height has limited the accuracy and runtime of analog-to-digital conversion.Along with increasing of sample frequency, the linearity of the MOS switch of traditional structure constantly declines, and has restricted the dynamic range of sampling switch circuit, cannot meet at a high speed the requirement of high-performance analog to digital converter to sampled signal dynamic property.Particularly, the equiva lent impedance of sampling switch (being MOS switch) in the time of sampling is

$R_{\mathrm{MS}}=\frac{1}{k{(W/L)}_{\mathrm{MS}}(\mathrm{VGS}-\mathrm{VTH})}---\left(1\right)$

Wherein k is the constant relevant to technique, (W/L) _mSfor the breadth length ratio of MOS switch, VTH is the threshold voltage of MOS switch, and VGS is the gate source voltage of MOS switch.In order to improve sampling switch precision and the speed in when sampling, needing (1) formula be a relatively constant value, and equiva lent impedance has high linearity, simultaneously settling time constant R _mScS (CS is the capacitance that keeps electric capacity) is as much as possible little, to ensure fast sample rate, is constant, so need equiva lent impedance R because keep the capacitance Cs of electric capacity _mSas far as possible little.After the breadth length ratio of technique and MOS switch is selected, the k in (1) formula, (W/L) _mS, VTH changes very little value, therefore in order to ensure the equiva lent impedance R of sampling switch _mSconstant and as far as possible little, in needs (1) formula, gate source voltage is constant and large as far as possible.Traditional sampling switch circuit, because source electrode connects vicissitudinous input signal, grid connects supply voltage in the time of sampling, and the gate source voltage of MOS switch changes with the variation of input signal, sampling switch impedance in the time of sampling, with the variation that do not coexist of signal, has had a strong impact on precision and the speed of sampling.

Therefore, be necessary to provide a kind of improved sampling switch circuit to overcome above-mentioned defect.

Utility model content

The purpose of this utility model is to provide a kind of sampling switch circuit, and sampling switch circuit of the present utility model has improved the linearity of sampling field effect transistor, has reduced its equivalent output impedance, has ensured the precision of sample rate and sampling output.

For achieving the above object, the utility model provides a kind of sampling switch circuit, comprise sampling field effect transistor and keep electric capacity, external signal is inputted the source electrode of described sampling field effect transistor, the grid of described sampling field effect transistor is connected with external power source, its drain electrode is connected with the one end that keeps electric capacity, and exports the signal after sampling, the other end ground connection of described maintenance electric capacity, wherein, also comprise that bucking voltage produces electronic circuit, addition electronic circuit and Bootstrap electronic circuit, described bucking voltage produces a fixing voltage of electronic circuit generation and inputs to described addition electronic circuit, external signal is inputted described addition electronic circuit, and described bucking voltage is produced the extremely described Bootstrap electronic circuit of voltage after the fixed voltage of electronic circuit output and voltage phase adduction output one stack of external signal by described addition electronic circuit, described Bootstrap electronic circuit respectively with the output of described addition electronic circuit, grid and the external power source of sampling field effect transistor connect, to make the voltage-drop loading of described Bootstrap electronic circuit output to the grid of described sampling field effect transistor.

Preferably, described sampling switch circuit also comprises clock generating electronic circuit, and described clock generating electronic circuit is connected with described Bootstrap electronic circuit, the work schedule of Bootstrap electronic circuit described in described clock generating electronic circuit output clock pulse control.

Preferably, described clock generating electronic circuit has the first output terminal of clock and second clock output, and described the first output terminal of clock and second clock output are exported complementary clock pulse.

Preferably, described addition electronic circuit comprises the first resistance, the second resistance, the 3rd resistance, the 4th resistance, the 5th resistance and amplifier, one end of described the first resistance produces electronic circuit with described bucking voltage and is connected, the other end is connected with the positive input of described amplifier, external signal is inputted one end of described the second resistance, the other end of described the second resistance is connected with the positive input of described amplifier, described the 3rd one end of resistance and the positive input of described amplifier are connected, other end ground connection, described the 4th one end of resistance and the reverse input end of described amplifier are connected, other end ground connection, described the 5th one end of resistance and the reverse input end of described amplifier are connected, the other end is connected with the output of described amplifier.

Preferably, described the first resistance, the second resistance and the 5th resistance have identical resistance, and resistance value after described the 5th resistance, the 4th resistance parallel connection equates with the resistance value after described the first resistance, the second resistance and the 3rd resistance parallel connection.

Preferably, described Bootstrap electronic circuit comprises the first switch, second switch, the 3rd switch, the 4th switch, the 5th switch and the first electric capacity, described first switch one end is connected with the output of described amplifier, the other end is connected with one end of described the first electric capacity, described second switch one end is connected with one end of described the first electric capacity, other end ground connection, the other end of described the first electric capacity is connected with one end of described the 3rd switch and the 4th switch, the other end of described the 3rd switch is connected with external power source, the other end of described the 4th switch is connected with the grid of described sampling field effect transistor, one end of described the 5th switch is connected with the grid of described sampling field effect transistor, other end ground connection.

Preferably, the control end of described second switch, the 3rd switch and the 5th switch is all connected with described the first output terminal of clock, the control end of described the first switch and the 4th switch is all connected with described second clock output, and all closures in the time that the clock pulse of its control end is high level of switch described in each.

Compared with prior art, sampling switch circuit of the present utility model also comprises that bucking voltage produces electronic circuit, addition electronic circuit and Bootstrap electronic circuit, described bucking voltage is produced the extremely described Bootstrap electronic circuit of voltage after the fixed voltage of electronic circuit output and voltage phase adduction output one stack of external signal by described addition electronic circuit, described Bootstrap electronic circuit respectively with the output of described addition electronic circuit, grid and the external power source of sampling field effect transistor connect, to make the voltage-drop loading of described Bootstrap electronic circuit output to the grid of described sampling field effect transistor, the input voltage of described Bootstrap electronic circuit is the stack of fixed voltage and external signal voltage in addition, thereby the voltage-drop loading of described Bootstrap electronic circuit output is to the grid of described sampling field effect transistor, the impact of the change in voltage that can balance out external signal on described sampling field effect transistor, the gate source voltage that has ensured described sampling field effect transistor is fixed, improve the linearity of sampling field effect transistor, reduce its equivalent output impedance, ensure the precision of sample rate and sampling output.

By following description also by reference to the accompanying drawings, it is more clear that the utility model will become, and these accompanying drawings are used for explaining the utility model.

Brief description of the drawings

Fig. 1 is the structure chart of the utility model sampling switch circuit.

Embodiment

With reference now to accompanying drawing, describe embodiment of the present utility model, in accompanying drawing, similarly element numbers represents similar element.As mentioned above, the utility model provides a kind of sampling switch circuit, and sampling switch circuit of the present utility model has improved the linearity of sampling field effect transistor, has reduced its equivalent output impedance, has ensured the precision of sample rate and sampling output.

Please refer to Fig. 1, Fig. 1 is the structure chart of the utility model sampling switch circuit.As shown in the figure, sampling switch circuit of the present utility model comprises sampling field effect transistor MS and keeps capacitor C S, bucking voltage to produce electronic circuit, addition electronic circuit and Bootstrap electronic circuit, external signal VIN inputs the source electrode of described sampling field effect transistor MS, the drain electrode of described sampling field effect transistor MS and one end of sampling capacitance CS are connected and form the output of described sampling switch circuit, the grid of described sampling field effect transistor MS is connected with described Bootstrap electronic circuit, the other end ground connection of described maintenance capacitor C S, thereby described sampling field effect transistor MS samples to the external signal VIN of input, and the signal VOUT obtaining after output sampling, described maintenance capacitor C S keeps the signal VOUT obtaining after described sampling field effect transistor MS sampling, be further processed so that transfer to subsequent conditioning circuit, described bucking voltage produces a fixing voltage VC of electronic circuit generation and inputs to described addition electronic circuit, and described bucking voltage generation electronic circuit can be power circuit or the equivalent electric circuit of any one exportable stable fixed voltage, and the large I of the voltage VC of its output is set by the needs of the actual use of circuit, external signal VIN inputs described addition electronic circuit, and described bucking voltage is produced the extremely described Bootstrap electronic circuit of voltage after the voltage VC of circuit output and voltage phase adduction output one stack of external signal VIN by described addition electronic circuit, described Bootstrap electronic circuit is connected with the output of described addition electronic circuit, grid and the external power source VDD of sampling field effect transistor MS respectively, to make the voltage-drop loading of described Bootstrap electronic circuit output to the grid of described sampling field effect transistor, because the input voltage of described Bootstrap electronic circuit is the stack of fixed voltage VC and external signal VIN voltage, thereby the voltage-drop loading of described Bootstrap electronic circuit output is to the grid of described sampling field effect transistor MS, the impact of the change in voltage that balances out external signal VIN on described sampling field effect transistor MS, the gate source voltage that has ensured described sampling field effect transistor MS is fixed, and has improved the linearity of sampling field effect transistor MS and the precision of sampling.In preferred implementation of the present utility model, described switch sample circuit also comprises clock generating electronic circuit, described clock generating electronic circuit is connected with described Bootstrap electronic circuit, the work schedule of Bootstrap electronic circuit described in described clock generating electronic circuit output clock pulse control.

Particularly, please again in conjunction with reference to figure 1.Described clock generating electronic circuit has the first output terminal of clock Φ 1 and second clock output Φ 2, described the first output terminal of clock Φ 1 exports complementary clock pulse with second clock output Φ 2, when the clock pulse of exporting as described the first output terminal of clock Φ 1 is high level, the clock pulse that described second clock output Φ 2 exports is low level, and vice versa.Described addition electronic circuit comprises the first resistance R 1, the second resistance R 2, the 3rd resistance R 3, the 4th resistance R 4, the 5th resistance R 5 and amplifier OP; One end of described the first resistance R 1 produces electronic circuit with described bucking voltage and is connected, the other end is connected with the positive input of described amplifier OP, and the fixed voltage VC that makes described bucking voltage produce electronic circuit output inputs to the positive input of described amplification along device OP by described the first resistance R 1; External signal VIN inputs one end of described the second resistance R 2, and the other end of described the second resistance R 2 is connected with the positive input of described amplifier OP, thereby the voltage of external signal VIN is by putting the positive input of device OP described in described the second resistance R 2 inputs; Described the 3rd resistance R 3 one end are connected with the positive input of described amplifier OP, other end ground connection; One end of described the 4th resistance R 4 is connected with the reverse input end of described amplifier OP, other end ground connection; Described the 5th resistance R 5 one end are connected with the reverse input end of described amplifier OP, and the other end is connected with the output of described amplifier OP, thereby described the 5th resistance R 5 forms the feedback resistance of described amplifier OP; In preferred implementation of the present utility model, described the first resistance R 1, the second resistance R 2 and the 5th resistance R 5 have identical resistance, and the resistance value after described the 5th resistance R 5, the 4th resistance R 4 parallel connections equates with the resistance value after the first resistance R 1, the second resistance R 2 and the 3rd resistance R 3 parallel connections, thereby makes the output voltage V n1 of described amplifier OP be:

Vn1=VC+VIN （2）

Be the stack of voltage and the fixed voltage VC of described external signal VIN.Described Bootstrap electronic circuit comprises the first K switch 1, second switch K2, the 3rd K switch 3, the 4th K switch 4, the 5th K switch 5 and the first capacitor C 1, described first K switch 1 one end is connected with the output of described amplifier OP, the other end is connected with one end of described the first capacitor C 1, described second switch K2 one end is connected with one end of described the first capacitor C 1, other end ground connection, the other end of described the first capacitor C 1 is connected with one end of described the 3rd K switch 3 and the 4th K switch 4, the other end of described the 3rd K switch 3 is connected with external power source VDD, the other end of described the 4th K switch 4 is connected with the grid of described sampling field effect transistor MS, one end of described the 5th switch M5 is connected with the grid of described sampling field effect transistor MS, other end ground connection, the grid of described sampling field effect transistor MS is connected with external power source VDD by described the 3rd K switch 3 and the 4th K switch 4, the control end of described second switch K2, the 3rd K switch 3 and the 5th K switch 5 is all connected with described the first output terminal of clock Φ 1, the control end of described the first K switch 1 and the 4th K switch 4 is all connected with described second clock output Φ 2, and all closures in the time that the clock pulse of its control end is high level of switch described in each, thereby control closure and the opening time of switch described in each by described the first output terminal of clock Φ 1 and second clock output Φ 2, the time with controlled loading to voltage on described sampling field effect transistor MS grid.

The course of work below in conjunction with Fig. 1 technology the utility model sampling switch circuit:

In the maintenance stage: the clock pulse that the first output terminal of clock Ф 1 exports is high level, and when the clock pulse that second clock output Ф 2 exports is low level, the second switch K2 of the clock pulse control that now described the first output terminal of clock Ф 1 exports, the 3rd K switch 3, the 5th K switch 5 closures, the first K switch 1 of the clock pulse control that second clock output Ф 2 exports, the 4th K switch 4 disconnects, the grounded-grid of sampling field effect transistor MS, the field effect transistor of sampling MS cut-off, and node n2 ground connection, node n3 connects external power source VDD, now the voltage of the first capacitor C 1 right pole plate is VDD, the voltage of its left pole plate is 0, being that electric capacity left and right polar plate voltage is poor is-VDD.

In sample phase: the clock pulse that the first output terminal of clock Ф 1 exports is low level, and the clock pulse that second clock output Ф 2 exports is high level, the second switch K2 of the clock pulse control that now described the first output terminal of clock Ф 1 exports, the 3rd K switch 3, the 5th K switch 5 disconnects, the first K switch 1 of the clock pulse control that second clock output Ф 2 exports, the 4th K switch 4 closures, now node n1, n2 connects by the first K switch 1 of conducting, voltage equates and is voltage shown in (2) formula, be that node n2 voltage is also VC+VIN, node n3 is connected with the grid of sampling field effect transistor MS by the 4th K switch 4 of conducting, the grid voltage of the field effect transistor of now sampling MS is the voltage of node n3.When circuit is when keeping the moment to switch to sampling instant, the left polar plate voltage of the first capacitor C 1 becomes VC+VIN from 0, because the voltage difference of electric capacity left and right pole plate can not be suddenlyd change, so the right polar plate voltage of the first capacitor C 1 becomes VC+VIN+VDD from VC+VIN, the i.e. voltage of sampling field effect transistor MS grid now, because the source voltage of sampling field effect transistor MS is the voltage of input signal VIN, therefore at the gate source voltage VGS=VDD+VC of sampling instant sampling field effect transistor MS, substitution (1) formula,

$R_{\mathrm{MS}}=\frac{1}{k{(W/L)}_{\mathrm{MS}}(\mathrm{VDD}+\mathrm{VC}-\mathrm{VTH})}---\left(3\right)$

(3), in formula, k is the constant relevant to technique, (W/L) _mSfor the breadth length ratio of sampling field effect transistor MS, VTH is the threshold voltage of sampling field effect transistor MS, above-mentioned each parameter is in the technique of same batch, parameter value variation is very little, and VDD, voltage VC is again relatively constant value, the equiva lent impedance of the field effect transistor of therefore sampling MS is constant, eliminate the impact of external signal VIN change in voltage on described sampling field effect transistor MS impedance, improved the linearity of sampling field effect transistor MS; Meanwhile, the fixed voltage VC that bucking voltage produces electronic circuit output can need to select larger value according to circuit, to ensure that VDD+VC-VTH is large as far as possible, to reduce the value of equiva lent impedance, improves sample rate.

In conjunction with most preferred embodiment, the utility model is described above, but the utility model is not limited to the embodiment of above announcement, and should contains the various amendments of carrying out according to essence of the present utility model, equivalent combinations.

Claims (7)

1. a sampling switch circuit, comprise sampling field effect transistor and keep electric capacity, external signal is inputted the source electrode of described sampling field effect transistor, the grid of described sampling field effect transistor is connected with external power source, its drain electrode is connected with the one end that keeps electric capacity, and signal after output sampling, the other end ground connection of described maintenance electric capacity, it is characterized in that, also comprise that bucking voltage produces electronic circuit, addition electronic circuit and Bootstrap electronic circuit, described bucking voltage produces a fixing voltage of electronic circuit generation and inputs to described addition electronic circuit, external signal is inputted described addition electronic circuit, and described bucking voltage is produced the extremely described Bootstrap electronic circuit of voltage after the fixed voltage of electronic circuit output and voltage phase adduction output one stack of external signal by described addition electronic circuit, described Bootstrap electronic circuit respectively with the output of described addition electronic circuit, grid and the external power source of sampling field effect transistor connect, to make the voltage-drop loading of described Bootstrap electronic circuit output to the grid of described sampling field effect transistor.

2. sampling switch circuit as claimed in claim 1, it is characterized in that, also comprise clock generating electronic circuit, described clock generating electronic circuit is connected with described Bootstrap electronic circuit, the work schedule of Bootstrap electronic circuit described in described clock generating electronic circuit output clock pulse control.

3. sampling switch circuit as claimed in claim 2, is characterized in that, described clock generating electronic circuit has the first output terminal of clock and second clock output, and described the first output terminal of clock and second clock output are exported complementary clock pulse.

4. sampling switch circuit as claimed in claim 3, it is characterized in that, described addition electronic circuit comprises the first resistance, the second resistance, the 3rd resistance, the 4th resistance, the 5th resistance and amplifier, one end of described the first resistance produces electronic circuit with described bucking voltage and is connected, the other end is connected with the positive input of described amplifier, external signal is inputted one end of described the second resistance, the other end of described the second resistance is connected with the positive input of described amplifier, described the 3rd one end of resistance and the positive input of described amplifier are connected, other end ground connection, described the 4th one end of resistance and the reverse input end of described amplifier are connected, other end ground connection, described the 5th one end of resistance and the reverse input end of described amplifier are connected, the other end is connected with the output of described amplifier.

5. sampling switch circuit as claimed in claim 4, it is characterized in that, described the first resistance, the second resistance and the 5th resistance have identical resistance, and resistance value after described the 5th resistance, the 4th resistance parallel connection equates with the resistance value after described the first resistance, the second resistance and the 3rd resistance parallel connection.

6. sampling switch circuit as claimed in claim 5, it is characterized in that, described Bootstrap electronic circuit comprises the first switch, second switch, the 3rd switch, the 4th switch, the 5th switch and the first electric capacity, described first switch one end is connected with the output of described amplifier, the other end is connected with one end of described the first electric capacity, described second switch one end is connected with one end of described the first electric capacity, other end ground connection, the other end of described the first electric capacity is connected with one end of described the 3rd switch and the 4th switch, the other end of described the 3rd switch is connected with external power source, the other end of described the 4th switch is connected with the grid of described sampling field effect transistor, one end of described the 5th switch is connected with the grid of described sampling field effect transistor, other end ground connection.

7. sampling switch circuit as claimed in claim 6, it is characterized in that, the control end of described second switch, the 3rd switch and the 5th switch is all connected with described the first output terminal of clock, the control end of described the first switch and the 4th switch is all connected with described second clock output, and all closures in the time that the clock pulse of its control end is high level of switch described in each.