CN101414487B - Device and method for holding sampling - Google Patents

Abstract

The invention discloses a sample-and-hold amplifier which comprises a primary sample-and-hold circuit and a secondary sample-and-hold circuit. The input positive terminal and the input negative terminal of the primary sample-and-hold circuit receive an external signal, the output positive terminal and the output negative terminal of the primary sample-and-hold circuit are coupled to the input positive terminal and the input negative terminal of the secondary sample-and-hold circuit, the primary sample-and-hold circuit is provided with a primary operational amplifier with the amplification being less than a multiple, and the secondary sample-and-hold circuit is provided with a secondary operational amplifier which realizes the amplification more than the multiple; after the external signal is sampled, held and amplified, by the primary sample-and-hold circuit and the secondary sample-and-hold circuit, the external signal is output from the output positive terminal and the output negative terminal of the secondary sample-and-hold circuit. Meanwhile, the invention discloses a sample-and-hold method. The sample-and-hold amplifier, as a basic signal processing module, is used for front end processing of the external input signal; and the sample-and-hold amplifier ensures the speed and the precision of the signal conversion with the simple structure on the premise of realizing high reliability.

Description

A kind of sampling holder and sample hold method

[technical field]

The present invention relates to analog and digital signal and handle, be specifically related to a kind of sampling holder and sample hold method.

[background technology]

Sampling hold circuit (sampling holder) is called sample/hold amplifier again.When simulating signal is carried out analog/digital conversion, need certain switching time, in this switching time, it is constant substantially that simulating signal will keep, and could guarantee conversion accuracy like this.Sampling hold circuit is the circuit of realizing this function.

Fig. 1 a is depicted as a kind of traditional sampling holding circuit, and capacitor C s wherein is a sampling capacitance, is again to keep electric capacity.Be in sampling phase when (sampling time), the input and output short circuit of switch control operational amplifier, two inputs are short circuit simultaneously also, the switch conduction that is connected with external signal, the electric capacity external signal level of sampling at this moment.The switch of input and output short circuit is broken earlier, and the switch that then is communicated with two inputs breaks, and the level of storing on the electric capacity is influenced by external signal no longer.Keeping phase when (retention time) electric capacity to be directly connected to output terminal, output is set up.This mode is short Time Created, but only can realize one times of amplification.

Fig. 1 b is depicted as another kind of traditional sampling holding circuit, and wherein one group two capacitor C s are sampling capacitances, and two capacitor C f of another group keep electric capacity.At the sampling phase time, sampling phase clock gauge tap is the input and output short circuit of operational amplifier, two inputs also simultaneously short circuit producing the common mode ground level, the switch conduction that is connected with external signal, the two groups of electric capacity external signal level of sampling simultaneously at this moment.The switch of input and output short circuit is broken earlier, and the switch that then is communicated with two inputs breaks, and the level of storing on the electric capacity is influenced by external signal no longer, and the sampling end of sampling capacitance and maintenance electric capacity no longer links together simultaneously.Keeping phase time, the sampling capacitance electric charge is changed to zero, keeps electric capacity to receive output terminal simultaneously, produces electric charge and shifts and set up output level.This structure can realize the amplification greater than a times, but Time Created is longer relatively because being subjected to the electric charge transfer impact.

Because the lifting of application demand faces harsh designing requirement as influence great sampling hold circuit module for overall performance, and is high-speed, high precision, high linearity, big dynamic range, LVPS power supply and low-power consumption all become the important indicator of design.And these performances depend on operational amplifier to a great extent, and it is high that final result is exactly that the design parameter of operational amplifier requires, gain bandwidth product, and slew rate, the isoparametric high target of output voltage range and power consumption make the design difficulty that becomes.And in a single day in the flow process deviation appears, very big to Effect on Performance.

The overall performance index request of the harshness of traditional sampling hold circuit has been determined the high standard of operational amplifier itself, and in this case, operational amplifier need satisfy the requirement of high-gain, high-speed, big output area or the like factor simultaneously.And generally speaking, in order to reach these design objects, cost is very big in the operational amplifier design, and difficulty is not little.Therefore, need seek new solution.

[summary of the invention]

Fundamental purpose of the present invention solves the problems of the prior art exactly, a kind of sampling holder and sample hold method are provided, can utilize existing simple operation amplifier module to realize in the sampling hold circuit, to satisfying of the high-gain of amplifier harshness, high-speed, big output area and high precision and reliability requirement.

For achieving the above object, the invention provides a kind of sampling holder, it is characterized in that: comprise first order sampling hold circuit and second level sampling hold circuit, the input of described first order sampling hold circuit just, negative terminal inserts external signal, the output of described first order sampling hold circuit just, the input that negative terminal is coupled to described second level sampling hold circuit just, negative terminal, described first order sampling hold circuit has realizes being lower than the first order operational amplifier that a multiple amplifies, described second level sampling hold circuit has realizes being higher than the second level operational amplifier that a multiple amplifies, external signal is via described first, the sampling that the secondary sampling hold circuit matches, keep and amplification after, from the output of described second level sampling hold circuit just, negative terminal output.

The positive and negative end of the output of described first order sampling hold circuit directly is connected with the positive and negative end of input of described second level sampling hold circuit respectively, is serially connected with switching device between the positive and negative end of input of described second level sampling hold circuit.

Described first order sampling hold circuit comprises that also the first positive sampling capacitance, the first negative sampling capacitance, first are just keeping the electric capacity and the first negative maintenance electric capacity;

One end of the described first positive sampling capacitance is with first output terminal coupling of the mode of controlled break-make and the first input end of described first order sampling hold circuit, described first order operational amplifier, and the first input end coupling of the other end and described first order operational amplifier is also just keeping first output terminal of electric capacity and described first order operational amplifier to be coupled through described first;

One end of the described first negative sampling capacitance is with second output terminal coupling of the mode of controlled break-make and second input end of described first order sampling hold circuit, described first order operational amplifier, and second input end coupling of the other end and described first order operational amplifier also is coupled through second output terminal of the described first negative maintenance electric capacity and described first order operational amplifier;

The two ends may command short circuit of the described first positive and negative maintenance electric capacity.

First, second input end of described first order operational amplifier is by the switching device cross-over connection.

Described second level sampling hold circuit comprises that also the second positive sampling capacitance, the second negative sampling capacitance, second are just keeping the electric capacity and the second negative maintenance electric capacity;

One end of the described second positive sampling capacitance and the coupling of first output terminal of described first order operational amplifier, the first input end of the other end and described second level operational amplifier, described second is just keeping the end coupling of electric capacity, and with the mode of controlled break-make and the coupling of described second level operational amplifier first output terminal, described second is just keeping the other end of electric capacity to be coupled with first output terminal of described first order operational amplifier, first output terminal of second level operational amplifier in the mode of controlled break-make respectively;

One end of the described second negative sampling capacitance and the coupling of second output terminal of described first order operational amplifier, the one end coupling of second input end of the other end and described second level operational amplifier, the described second negative maintenance electric capacity, and with the mode of controlled break-make and the coupling of described second level operational amplifier second output terminal, the other end of the described second negative maintenance electric capacity is coupled with second output terminal of described first order operational amplifier, second output terminal of second level operational amplifier in the mode of controlled break-make respectively.

First, second input end of described second level operational amplifier is by the switching device cross-over connection.

Describedly be lower than a multiple and be enlarged into 1/2nd times of amplifications, the described multiple that is higher than is enlarged into two times of amplifications.

Described first order operational amplifier is telescopic single-stage fully differential operational amplifier, and described second level operational amplifier is a two-stage fully differential operational amplifier.

The present invention provides a kind of sample hold method simultaneously, it is characterized in that: comprise first order sampling maintenance stage and second level sampling maintenance stage, the retention time of the first order in the sampling maintenance stage is corresponding to the sampling time of the second level in the sampling maintenance stage, in the sampling maintenance stage external signal being lower than a multiple in the described first order amplifies, amplify the superimposed amplitude requirement that satisfies outside signal sampling maintenance of two-stage signal enlargement factor in the sampling maintenance stage to be higher than a multiple by the signal that obtains on last stage in the described second level.

The output that distributes for the first order sampling maintenance stage is shorter than the output Time Created of distributing into the second level sampling maintenance stage Time Created.

The retention time in first order sampling maintenance stage equals or equals substantially the second level sampling time in sampling maintenance stage, and the sampling time in first order sampling maintenance stage equals or equal substantially the second level retention time in sampling maintenance stage.

The described sampling time of the first order in the sampling maintenance stage finishes in such a way: the DC channel by output one side with sampling capacitance disconnects earlier, follow connection disconnection, and then the DC channel by input one side of sampling capacitance is disconnected first and second input end of first order operational amplifier; The sampling time of the described second level in the sampling maintenance stage finishes in such a way: the DC channel by output one side with sampling capacitance disconnects earlier, follow connection disconnection, and then sampling capacitance is connected the DC channel disconnection that keeps electric capacity first and second input end of second level operational amplifier.

The present invention's beneficial effect compared with prior art is:

The present invention adopts the two-stage sampling hold circuit that matches, because the first order operational amplifier in the first order sampling hold circuit adopts the single-stage telescoping structure, enlargement factor is low, focus on and realize at a high speed, and the second level operational amplifier in the sampling hold circuit of the second level adopts two-stage structure, amplify with high multiple, focus on and realize high-gain and big output area.Like this, just can be by the requirement of two-part collaborative work realization to the sampling hold circuit overall performance, thus avoided going to design highly difficult operational amplifier, improved the circuit whole reliability.

Preferably, first order operational amplifier adopts telescopic single-stage fully differential operational amplifier, second level operational amplifier adopts two-stage fully differential operational amplifier, the speed of telescopic single stage operational amplifier is fast, noise is little, simple in structure, the reliability height is suitable for low voltage designs, the two stage operational amplifier gain is big, output area is wide, and noise is little, and is simple in structure, the reliability height, be suitable for low voltage designs,, promptly can realize satisfying the high request of sampling holder design with the operational amplifier of simple structure by this structural design of the present invention.And two-stage calculation amplifier all is a low-noise structural, thereby has also guaranteed high linearity on the whole.

Because two parts directly connect with the flowing water working method, and especially, make the retention time of the first order equal the partial sampling time, and the sampling time of the first order equals the retention time of second portion, the first order is because low enlargement factor and high speed operation amplifier, can in very short time, set up output, mean that its retention time can be extremely short, and it is corresponding with it, because the direct connection between two parts circuit, its RC (resistance capacitance) value is minimum, means that the second level sampling time can be extremely short.Therefore, can be assigned to more time the sampling time and the partial retention time of the first order, thereby guarantee the high precision and the reliability of sampling hold circuit integral body.

[description of drawings]

Fig. 1 a and Fig. 1 b are the prior art circuits schematic diagrams;

Fig. 2 is the circuit theory diagrams of the embodiment of the invention;

Fig. 3 is the circuit timing diagram of the embodiment of the invention;

Fig. 4 a and Fig. 4 b are the circuit theory diagrams of first order operational amplifier of the present invention;

Fig. 5 a and Fig. 5 b are the circuit theory diagrams of the second level of the present invention operational amplifier.

Feature of the present invention and advantage will be elaborated in conjunction with the accompanying drawings by embodiment.

[embodiment]

Embodiment one:

Please refer to Fig. 2, whole sampling holder is divided into two parts: first order sampling hold circuit and second level sampling hold circuit.First order sampling hold circuit and second level sampling hold circuit are by the control of sequential control circuit, make the sampling of first order sampling hold circuit mutually corresponding with the maintenance of second level sampling hold circuit, and the maintenance of first order sampling hold circuit is mutually corresponding with the sampling of second level sampling hold circuit, thereby makes both collaborative works.When first order sampling hold circuit is in the sampling phase time, its positive and negative two output terminal short circuits (not influencing sampling), second level sampling hold circuit enters the maintenance phase simultaneously.When first order sampling hold circuit is in the maintenance phase time, the output signal of the second level sampling hold circuit sampling first order.Form streamline work between the two-stage.

First order sampling hold circuit is made up of first order operational amplifier A 1, peripheral four electric capacity and seven switches.Peripheral electric capacity is respectively the first positive sampling capacitance C1sp, the first negative sampling capacitance C1sn, first and is just keeping the capacitor C 1hp and the first negative maintenance capacitor C 1hn, peripheral seven switches adopt CMOS (Complementary Metal-Oxide Semiconductor, complementary metal oxide semiconductor) switching device comprises two switch 1tt, two switches 1 and a switch 1t.Wherein, the end of the first positive sampling capacitance C1sp and the first negative sampling capacitance C1sn is connected respectively to first, second input end of first order operational amplifier A 1, the other end of the first positive sampling capacitance C1sp is through the input anode coupling of switch 1 with first order sampling hold circuit, simultaneously through the first output terminal coupling of switch 2 with first order operational amplifier A 1, the other end of the first negative sampling capacitance C1sn is through the input negative terminal coupling of switch 1 with first order sampling hold circuit, simultaneously through the second output terminal coupling of switch 2 with first order operational amplifier A 1.First is just keeping the capacitor C 1hp and the first negative maintenance capacitor C 1hn then to be connected across respectively between first input end, output terminal and second input end, the output terminal of first order operational amplifier A 1.First is just keeping the two ends of capacitor C 1hp and is meeting switch 1tt, and the two ends of the first negative maintenance capacitor C 1hn also meet switch 1tt.Be coupled by switch 1t cross-over connection between first and second input end of first order operational amplifier A 1, so that produce common mode ground at the sampling phase time.

The break-make of the switch 1 that switch controlling signal control is connected with the input anode of first order sampling hold circuit, so that the input of external signal Vip is controlled, the break-make of the switch 1 that the input negative terminal of control signal control first order sampling hold circuit connects, so that the input of external signal Vin is controlled, another group switch 2 is keeping phase time to jump to first input of first order operational amplifier A 1 respectively the first positive sampling capacitance C1sp and the first negative sampling capacitance C1sn under the switch controlling signal effect, the output two ends and second input, the output two ends, two two ends that each controlled cross-over connection first of switch ltt is just keeping the capacitor C 1hp and the first negative maintenance capacitor C 1hn are realized the sampling phase and are kept filling of relative first order operational amplifier A 1 input and output two ends electric capacity, discharge.

The first order operational amplifier A 1 of present embodiment is telescopic single-stage fully differential operational amplifier, and its inner switched-capacitor circuit that adopts makes up the common mode negative feedback network.

Second level sampling hold circuit is made up of second level operational amplifier A 2, peripheral four electric capacity and seven switches.Second level operational amplifier A 2 adopts a simple two-stage fully differential operational amplifier, peripheral electric capacity is respectively the second positive sampling capacitance C2sp, the second negative sampling capacitance C2sn, second and is just keeping the capacitor C 2hp and the second negative maintenance capacitor C 2hn, and peripheral seven switches comprise two switch 2tt, two switches 2 and a switch 2t.Wherein, the end of the second positive sampling capacitance C2sp and the coupling of first output terminal of first order operational amplifier A 1, the first input end of the other end and second level operational amplifier A 2, second is just keeping the end coupling of capacitor C 2hp, and by switch 2tt and the coupling of second level operational amplifier A 2 first output terminals, second is just keeping the other end of capacitor C 2hp to be coupled through first output terminal of switch 2 with first order operational amplifier A 1, and through the first output terminal coupling of switch 1 with second level operational amplifier A 2; The end of the second negative sampling capacitance C2sn and the coupling of second output terminal of first order operational amplifier A 1, the end coupling of second input end of the other end and second level operational amplifier A 2, the second negative maintenance capacitor C 2hn, and by switch 2tt and the coupling of second level operational amplifier A 2 second output terminals, the other end of the second negative maintenance capacitor C 2hn is coupled through second output terminal of switch 2 with first order operational amplifier A 1, and through the second output terminal coupling of switch 1 with second level operational amplifier A 2.Be coupled by switch 2t cross-over connection between first and second input end of second level operational amplifier A 2, to produce the common mode ground level.

Constant second level operational amplifier A 2 first, second input ends that are connected on of the second positive sampling capacitance C2sp and the second negative sampling capacitance C2sn; Under the switch controlling signal effect, second is just keeping capacitor C 2hp and the second negative maintenance capacitor C 2hn, and each is connected to the two ends of the second positive sampling capacitance C2sp and the second negative sampling capacitance C2sn through a switch 2 mutually in sampling, keep mutually each through a switch 1 be connected across that first of second level operational amplifier A 2 is imported, between the output terminal and second import, between the output terminal.Two switch 2tt first input of control second level operational amplifier A 2, the connection of output terminal and being connected of second input, output terminal under the switch controlling signal effect respectively.Export the output signal Vop and the Von of this sampling holder by first, second output terminal of second level operational amplifier A 2.

The second level operational amplifier A 2 of present embodiment is a twin-stage fully differential operational amplifier, and the first order wherein adopts the transistor divider resistance to form the common mode negative feedback, and switched capacitor network is adopted in the second level wherein.

First order sampling hold circuit connects with second level sampling hold circuit in such a way: corresponding respectively second level operational amplifier A 2 first, second input ends that are coupled to of first, second output terminal of first order operational amplifier A 1, what adopt between first and second grade sampling hold circuit is direct connection, and reality operates with flowing structure.In addition, also through switch 1 cross-over connection, this switch 1 can be communicated with first order operational amplifier A 1 under the switch controlling signal effect first, second output terminal also is two input ends of short circuit second level sampling hold circuit between first, second output terminal of first order operational amplifier A 1.Because when first order sampling hold circuit is sampled, second level sampling hold circuit just in time is in hold mode, for present embodiment, the foundation of second level sampling hold circuit output signal requires its two input ends short circuit, and the closure of this switch 1 has just in time realized this requirement.In addition, the closure of this switch 1 also can make the output differential signal of first order sampling hold circuit make zero.

Relative traditional sampling holding circuit, advantage of the present invention embodies in the following areas.

Sampling hold circuit only has simultaneously as sampling capacitance and two capacitor C s that keep electric capacity as shown in Figure 1a.This structure only can realize one times of amplification.First order sampling hold circuit has as shown in Figure 2 added one group and has been connected across first of operational amplifier two ends and is just keeping the capacitor C 1hp and the first negative maintenance capacitor C 1hn on the basis of circuit shown in Fig. 1 a.In the sampling phase stage, first just keeping capacitor C 1hp and the first negative maintenance capacitor C 1hn each by switch 1tt by short circuit, do not have electric charge on the electric capacity.Arrived the maintenance phase stage, first is just keeping capacitor C 1hp to share electric charge together and make up output level with the first positive sampling capacitance C1sp, the first negative sampling capacitance C1sn with the first negative maintenance capacitor C 1hn, thereby realizes that by first order operational amplifier A 1 multiple is less than one amplification.Identical on the sampling hold circuit structure of the second level with the sampling hold circuit shown in Fig. 1 b.The two-stage sampling hold circuit adopts above-mentioned two kinds of circuit structures, and existence owing to switch 1 between front stage circuits two output terminals, late-class circuit two inputs, make to be in the sampling phase time at first order sampling hold circuit, second level sampling hold circuit can be exported foundation.Therefore, under the effect of switch controlling signal, first and second grade sampling hold circuit is achieved the flowing water operation of sampling, maintenance effect, produces final output.

The needed enlargement factor of sampling holder of the present invention can realize by the size of regulating the many places electric capacity in the two-stage sampling hold circuit.When having different enlargement factor to require, owing to there is the many places electric capacity can be for regulating in the circuit, so the whole enlargement factor one of sampling holder of the present invention both can be greater than one, also can be less than one.Comparatively speaking, traditional structure can only be realized greater than the adjusting in the scope or less than the adjusting of a scope singlely.In enlargement factor is one application, first order operational amplifier A 1 in the first order sampling hold circuit of the present invention adopts 1/2nd multiple operational amplifiers, second level operational amplifier A 1 adopts the diploidy number operational amplifier, can make all the capacitance size unanimities in the circuit, the electric capacity that does not need additional size is for circuit structure brings convenience.And, do not include big enlargement factor and make the easier realization of its designing requirement for second level sampling hold circuit.Particularly the enlargement factor of first 1/2nd makes that the input range of the output area of first and second portion is all less, thereby has reserved bigger space for the compromise design that realizes each performance parameter index.

Generally speaking, first order sampling hold circuit simple in structure, speed is fast, but enlargement factor is little, in the sampling hold circuit of the second level, adopt two stage operational amplifier, make that gain and output area are all very big, when first order enlargement factor be 1/2nd, when second level enlargement factor is two, final output result's amplitude is consistent with external input signal.Though the operational amplifier of two-stage structure is slower, but because the input signal amplitude of second level sampling hold circuit only is the external input signal amplitude half, and, because what first order operational amplifier A 1 adopted is telescoping structure operational amplifier at a high speed, the structure of adding first order sampling hold circuit makes the output response time short, so first order sampling hold circuit can reach the very high speed of setting up.Therefore, first and second grade combination can realize large-signal was set up with the short period on the whole, has shortened the whole Time Created when adopting traditional design.

Be first order operation amplifier circuit figure of the present invention shown in Fig. 4 a, Fig. 4 b.Wherein, Fig. 4 a is the primary module of operational amplifier, and Fig. 4 b is the biasing circuit of operational amplifier.The speed of tube-in-tube structure operational amplifier is fast, and noise is little, and simplicity of design is suitable for low voltage designs, the reliability height.Switched capacitor network writes down desirable biasing mutually in sampling, feedback compensation when amplifying phase, and no quiescent dissipation, range of adjustment is wide.The biasing circuit that mirror current source is formed can guarantee constant under big external voltage fluctuations.

Be second level operation amplifier circuit figure of the present invention shown in Fig. 5 a, Fig. 5 b.Wherein, Fig. 5 a is the primary module of operational amplifier, and Fig. 5 b is the biasing circuit of operational amplifier.The two-stage structure gain is big, and output area is wide, and noise is little.And the twin-stage fully differential operational amplifier that this circuit preferably adopts is suitable for low voltage designs, reliability height.What the first order wherein adopted is to be in the transistor divider resistance of linear zone as feedback circuit, simple in structure, and what adopted the second level wherein is switched capacitor network, function admirable.

Just because of two-part operational amplifier type difference, stress different performance index respectively, so it is very simple to make design get up, particularly under low voltage configuration, still can keep high reliability.And the preferred operational amplifier of sampling holder circuit of the present invention all is a low-noise structural, from and guaranteed high linearity on the whole.

In addition, in first and second grade sampling hold circuit, each switch of operational amplifier periphery preferably adopts cmos switch, and its conducting resistance resistance is less with the fluctuation of sampled signal change in voltage, so make that whole linear property is better.

As another aspect of the present invention, the present invention also proposes a kind of sample hold method, this method comprises first order sampling maintenance stage and the second level sampling maintenance stage that continuous-flow type is connected, the retention time of the first order in the sampling maintenance stage is corresponding to the sampling time of the second level in the sampling maintenance stage, in the sampling maintenance stage external signal being hanged down multiple in the first order amplifies, amplify the superimposed amplitude requirement that satisfies outside signal sampling maintenance of two-stage signal enlargement factor in the sampling maintenance stage to carry out high multiple by the signal that obtains on last stage in the second level.

Figure 3 shows that the circuit timing diagram of present embodiment.Accordingly, the first order sampling maintenance stage carries out on first order sampling hold circuit of the present invention, the second level sampling maintenance stage carries out on the sampling hold circuit of the second level of the present invention, by two-stage flowing water working method, make retention time of first order sampling hold circuit equal sampling time of second level sampling hold circuit, and the sampling time of first order sampling hold circuit equal the retention time of second level sampling hold circuit.First order sampling hold circuit means that its first order retention time can be extremely short because low enlargement factor and high speed operation amplifier can be set up in very short time.And the identical with it second level sampling time, owing to directly connect between first and second grade sampling hold circuit, minimum RC (resistance capacitance) value means that the sampling time can be extremely short.Therefore, can be assigned to more time the sampling time and the partial retention time of the first order, thereby guarantee that sampling keeps high precision on the whole.

Because it is fast that speed is set up in the output of first order sampling hold circuit of the present invention, and the output of second level sampling hold circuit is set up relatively slow and be related to final output, can further the time in whole cycle be carried out not waiting all and distribute.By regulating clock signal, control distributes short output Time Created to the first order, and long output Time Created is distributed in the second level, by to the two-stage reasonable distribution of Time Created, realizes sampling, the high speed that keeps on the whole.The for example application that is 40MHz for a sample frequency, one-period are 25ns.Considering that the rising edge of clock and negative edge and clock are non-overlapped, the sampling phase time of first order sampling hold circuit can be made as 15.5ns, is 6.5ns and keep the phase time.Corresponding, the sampling phase time of second level sampling hold circuit is made as 6.5ns, is 15.5ns and keep the phase time.

Simultaneously,, also further connect the switch of sampling capacitance, make to guarantee that the electric charge in the sampling capacitance was not subjected to external action before externally signal disconnects with specific sequential control in order to eliminate the influence of electric charge injection effect.Referring to the sequential relationship of each switch on and off of control among Fig. 3, and this relation has guaranteed the elimination of electric charge injection effect.Set up with first order sampling hold circuit output below, promptly the first order is by the sampling switches set 1 when keeping phase transformation, the control signal phase1 of 1t, 1tt mutually, phase1t, and phase1tt illustrates.Because being communicated with two switches 1 of the phase1 control of external signal can be owing to the electric charge injection effect causes nonideal differential signal when disconnecting, therefore disconnect two switch 1tt of phase1tt control before this earlier, make that the DC channel of sampling capacitance one end disconnects in the first order.And the impulse electricity of electric capacity needs two ends that DC channel is arranged simultaneously, and therefore the capacitance charge of this moment begins conservation, and the disconnection of two switches 1 of phase1 control also can't influence.And in the disconnection process of two switch 1tt that phase1tt controls, in theory because the consistance of two switch 1tt of phase1tt control is only introduced common-mode signal, but actual difference can make a small amount of difference mode signal exist.The disconnection of two switch 1t of phase1t control still guarantees to be communicated with after phase1tt gauge tap 1tt disconnects between phase1 and phase1tt, has eliminated the possibility that difference mode signal exists.

The present invention is a kind of basic module of signal Processing, can carry out front-end processing to the simulating signal of outside input. it is used at some, particularly bring into play important effect in the analog-digital converter, determining the linearity and the dynamic range of entire circuit to a great extent.The circuit of using the present invention's proposition can effectively guarantee the speed and the precision of analog digital conversion.

Above content be in conjunction with concrete preferred implementation to further describing that the present invention did, can not assert that concrete enforcement of the present invention is confined to these explanations.For the general technical staff of the technical field of the invention, without departing from the inventive concept of the premise, can also make some simple deduction or replace, all should be considered as belonging to protection scope of the present invention.

Claims (9)

1. sampling holder, it is characterized in that: comprise first order sampling hold circuit and second level sampling hold circuit, the input of described first order sampling hold circuit just, negative terminal inserts external signal, the output of described first order sampling hold circuit just, the input that negative terminal is coupled to described second level sampling hold circuit just, negative terminal, described first order sampling hold circuit has realizes the first order operational amplifier of multiple less than one amplification, described second level sampling hold circuit has realizes the second level operational amplifier of multiple greater than one amplification, external signal is via described first, the sampling that the secondary sampling hold circuit matches, keep and amplification after, from the output of described second level sampling hold circuit just, negative terminal output; The positive and negative end of the output of described first order sampling hold circuit directly is connected with the positive and negative end of input of described second level sampling hold circuit respectively, is serially connected with switching device between the positive and negative end of input of described second level sampling hold circuit.

2. sampling holder as claimed in claim 1 is characterized in that:

Described first order sampling hold circuit comprises that also the first positive sampling capacitance, the first negative sampling capacitance, first are just keeping the electric capacity and the first negative maintenance electric capacity;

One end of the described first positive sampling capacitance is with first output terminal coupling of the mode of controlled break-make and the input anode of described first order sampling hold circuit, described first order operational amplifier, and the first input end coupling of the other end and described first order operational amplifier is also just keeping first output terminal of electric capacity and described first order operational amplifier to be coupled through described first;

One end of the described first negative sampling capacitance is with second output terminal coupling of the mode of controlled break-make and the input negative terminal of described first order sampling hold circuit, described first order operational amplifier, and second input end coupling of the other end and described first order operational amplifier also is coupled through second output terminal of the described first negative maintenance electric capacity and described first order operational amplifier;

The two ends may command short circuit of the described first positive and negative maintenance electric capacity.

3. sampling holder as claimed in claim 2 is characterized in that: first, second input end of described first order operational amplifier is by the switching device cross-over connection.

4. as each described sampling holder of claim 1 to 3, it is characterized in that:

Described second level sampling hold circuit comprises that also the second positive sampling capacitance, the second negative sampling capacitance, second are just keeping the electric capacity and the second negative maintenance electric capacity;

One end of the described second positive sampling capacitance and the coupling of first output terminal of described first order operational amplifier, the first input end of the other end and described second level operational amplifier, described second is just keeping the end coupling of electric capacity, and with the mode of controlled break-make and the coupling of described second level operational amplifier first output terminal, described second is just keeping the other end of electric capacity to be coupled with first output terminal of described first order operational amplifier, first output terminal of second level operational amplifier in the mode of controlled break-make respectively;

One end of the described second negative sampling capacitance and the coupling of second output terminal of described first order operational amplifier, the one end coupling of second input end of the other end and described second level operational amplifier, the described second negative maintenance electric capacity, and with the mode of controlled break-make and the coupling of described second level operational amplifier second output terminal, the other end of the described second negative maintenance electric capacity is coupled with second output terminal of described first order operational amplifier, second output terminal of second level operational amplifier in the mode of controlled break-make respectively.

5. sampling holder as claimed in claim 4 is characterized in that: first, second input end of described second level operational amplifier is by the switching device cross-over connection.

6. sampling holder as claimed in claim 4 is characterized in that: described multiple is less than one 1/2nd times of amplifications that are enlarged into, and described multiple is greater than one the two times of amplifications that are enlarged into.

7. sampling holder as claimed in claim 4 is characterized in that: described first order operational amplifier is telescopic single-stage fully differential operational amplifier, and described second level operational amplifier is a two-stage fully differential operational amplifier.

8. sample hold method, it is characterized in that: comprise first order sampling maintenance stage and second level sampling maintenance stage, the retention time of the first order in the sampling maintenance stage is corresponding to the sampling time of the second level in the sampling maintenance stage, in the sampling maintenance stage external signal is carried out multiple less than one amplification in the described first order, in the described second level in the sampling maintenance stage to carrying out multiple by the signal that obtains on last stage greater than one amplification, two-stage signal enlargement factor superimposed satisfied the amplitude requirement that outside signal sampling is kept; The output that distributes for the first order sampling maintenance stage is shorter than the output Time Created of distributing into the second level sampling maintenance stage Time Created.

9. sample hold method as claimed in claim 8, it is characterized in that: the retention time in first order sampling maintenance stage equals or equals substantially the second level sampling time in sampling maintenance stage, and the sampling time in first order sampling maintenance stage equals or equal substantially the second level retention time in sampling maintenance stage.

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