CN103884894A - Improved shunting linear isolation circuit and oscilloscope thereof - Google Patents

Abstract

The invention provides an improved shunting linear isolation circuit which includes a low-frequency amplification circuit, a linear optocoupler circuit, a frequency compensation circuit, a buffer circuit, a transformer and an add circuit. Low-frequency components in input signals are linearly isolated through use of the linear optocoupler circuit and a frequency-response compensation circuit is added to compensate for amplitude-frequency response recess caused by delay of a linear optocoupler. The input signals are connected to one end of a primary coil of the transformer after passing the buffer circuit and the low-frequency components are connected to the other end of the primary coil so as to offset the low-frequency components in the input signals. Current change in a primary winding of the transformer reflects high-frequency components in the input signals. The transformer performs coupling isolation on the high-frequency components and the isolated low-frequency signals and high-frequency signals are input to the add circuit for an addition operation. Output signals after the isolation and input signals before the isolation have plat amplitude-frequency responses and liner phases so that linear isolation is realized.

Description

A kind of improved shunt circuit linearity insulating circuit and oscillograph thereof

Technical field

The present invention relates to electronic metering equipment, particularly a kind of improved shunt circuit linearity insulating circuit and oscillograph thereof.

Background technology

Buffer circuit can arrive outgoing side by the electrical signal transfer of input side, but on electric, isolates between input side and outgoing side, insulate in other words conj.or perhaps, only has a less electric capacity between input side and outgoing side.Buffer circuit can improve the common-mode rejection ratio while measurement, reduces and disturbs, and improves signal quality, also can insulation risks voltage, and protection equipment and personal safety.In the time that hyperchannel oscillograph is measured simultaneously, channel separation can also be measured the signal of multiple different common mode voltages, prevents from causing altogether short circuit accident because of interchannel.

From the frequency response of processed signal and buffer circuit, buffer circuit can be divided into digital buffer circuit and linear or simulation buffer circuit.Numeral buffer circuit can only be isolated high and low level signal, i.e. digital signal, belongs to switching signal, technical easy realization.Circuit linearity insulating circuit is sometimes also referred to as isolated amplifier, and its output signal and input signal are linear, can transfer die analog signal, and the frequency response of circuit can be from DC to very high frequency.The technical more difficult realization of circuit linearity insulating circuit of high bandwidth (more than hundreds of MHz).And realize the circuit linearity insulating circuit with very high DC precision, and can on oscillograph, realize voltage table or function of multimeter, there is good using value, but there is technically higher difficulty.

Circuit linearity insulating circuit, conventional have following several mode:

Linear optical coupling buffer circuit, separation principle and the common optical coupler of linear optical coupling do not have difference, just the single-shot list of common optical coupler are received to pattern and change a little, increase by one and accept circuit for feedback for the light feeding back.Like this, be all nonlinear although two light are accepted circuit, the nonlinear characteristic that two light is accepted circuit is all the same.Like this, just can offset the non-linear of through path by the non-linear of feedback network, thereby reach the object that realizes linear isolation.Linear optical coupling can be realized the very high linearity, can isolate direct current signal, but signal bandwidth maximum can only arrive several MHz.

Transformer isolation circuit, utilizes electromagnetic induction principle, makes the electric insulation completely of primary side and secondary side, makes loop isolation.Transformer, according to the difference of the difference of core material and winding method, can be realized very high frequency is isolated.But due to electromagnetic induction, transformer can not be isolated direct current and low frequency signal, general transformer can be isolated minimumly can get at kHz rank.

Isolated amplifier device, has some integrated isolated amplifier chips at present, on the market as the AD203 of ADI company, AD215.Such devices use transformer is isolated, and input is carried out to linear modulation and become digital signal, then utilizes transformer to isolate digital signal, and the signal after isolation passes through demodulation again, generates the simulating signal after isolation.This class has the higher linearity, but bandwidth is generally very low, and maximum only have hundreds of kHz at present.

For solving the shortcoming of above-mentioned device, prior art has also provided multiple solution, below just several solutions are wherein introduced:

The patent that A, the patent No. are CN96101007.X, provides a solution, realizes block diagram as shown in Figure 1.

The amplifier that it uses two different bandwidths, is divided into high-frequency path and low frequency path by input signal, and low frequency path is used linear optical coupling to isolate, and high-frequency path uses transformer to isolate.Transformer time limit is used two windings, produce single spin-echo differential signal+Vout and-Vout.Low frequency signal after isolation is adjusted and single-ended transfer difference amplifier through gain, and the signal of output is as the biasing on transformer time limit.Low frequency channel, due to the time delay of linear optical coupling, causes the signal after stack, and in high and low frequency junction, amplitude-frequency response subsides, adopt circuit 48,52,50,54 to compensate, make amplitude-frequency response in high and low frequency junction, suitable lifting, has realized the flatness of amplitude-frequency response.

This patent can realize the circuit linearity insulating circuit of large bandwidth, but has following shortcoming:

1, because transformer time limit has adopted two windings, as the both positive and negative polarity of output difference sub-signal, be difficult to ensure the same phase of card both positive and negative polarity, increase the difficulty of transformer winding.

2, adopt the isolation of linear optical coupling as low frequency path, the time delay in low frequency path causes frequency response unevenness, has adopted circuit 48,52,50,54 to compensate, and because capacitor element is discrete, is difficult to ensure that card differential signal both positive and negative polarity is in full accord.

3, because transformer should meet low-limit frequency and low frequency path can superpose, meet again highest frequency as far as possible large, due to the restriction of transformer, the bandwidth that can realize is little, and maximum can get at 100MHz left and right.

The patent that B, the patent No. are US5834973, does not have the shortcoming of patent CN96101007.X, and it realizes block diagram as shown in Figure 2.

This patent is used the amplifier of two different bandwidths, and low bandwidth amplifier is realized low frequency path, and low frequency path is used linear optical coupling to isolate.The output of low bandwidth amplifier is through 124,126 dividing potential drop, be connected to subtraction circuit one end that high bandwidth amplifier forms, subtraction circuit deducts input signal the signal in low frequency path, the high-frequency signal of output is connected to the former limit of transformer, and the signal plus in this high-frequency signal and low frequency path is input signal.The linear optical coupling circuit in low frequency path has certain gain, to offset the damping capacity of low frequency signal of subtraction circuit input.High-frequency signal uses transformer to isolate, and the output of transformer time limit output and linear optical coupling, through adding circuit, produces the signal after isolation, thereby realizes the linear isolation to signal.

This patent preferably resolves the problem of transformer winding, but has following shortcoming:

1, adopt the isolation of linear optical coupling as low frequency path, there is certain time delay in low frequency path, and direct and high frequency road strength output is added, and can make low-and high-frequency frequency junction amplitude-frequency response subside, this patent is not introduced compensating circuit, the amplitude-frequency response unevenness of output signal.

2,, because transformer should meet low-limit frequency and low frequency path can superpose, meet again highest frequency as far as possible large.Due to the restriction of transformer, the bandwidth that can realize is little, and maximum can get at 200MHz left and right.

The patent that C, the patent No. are CN200610154738.9, has carried out concrete refinement by the implementation method of patent US5834973, and has solved its shortcoming, and delay compensating chain is provided, and it realizes block diagram as shown in Figure 3.

The realization approach of this patent and US5834973 is consistent, but has carried out circuit refinement, has increased the delay compensating chain 102,103,104 in low frequency path.Input signal is through low-frequency amplifier circuit 100, and output is connected to subtraction circuit 101, and subtraction output is high-frequency signal.High-frequency signal is isolated through transformer 26, and the signal after isolation is connected to circuit 105.Low frequency signal is isolated through linear optical coupling circuit 102, after low frequency signal isolation, carry out compensation of delay through delay compensating chain 103,104, and carry out necessary amplification, make the amplitude in low frequency path consistent with high-frequency path, signal after output and high-frequency isolation after compensation is through adding circuit 105, and the signal after synthetic isolation, realizes the linear isolation to signal.

This patent circuit is more detailed, the shortcoming of patent before can solving, but also there is following shortcoming:

1, because transformer should meet low-limit frequency and low frequency path can superpose, meet again highest frequency as far as possible large, due to the restriction of transformer, the bandwidth that can realize is little, and maximum can get at 200MHz left and right.

2, the delay compensating chain 103 or 22,24,29,30 of mentioning in patent, the actual amplitude-frequency depression that can not solve low frequency and high-frequency path crossover frequency place.Because electric capacity 24,30 shown in amplifier circuit, played the effect of low pass, can only allow low frequency path high frequency relatively and low frequency become lower, and can not play the effect of suitable lifting high frequency.Circuit 103, reality is also RC low pass circuit, can not play equally the effect of suitable lifting high frequency.

3, because the delay compensating chain providing is inoperative, the output amplitude-frequency response unevenness of circuit linearity insulating circuit.

4, low frequency path circuit complexity.

In sum, currently available technology major defect is subtraction formula frequency dividing circuit complexity, and high frequency frequency response debugging is difficult, and cannot compensate the frequency response depression problem of bringing due to linear optical coupling circuit.

Summary of the invention

Fundamental purpose of the present invention is to solve problems of the prior art, and a kind of improved shunt circuit linearity insulating circuit and oscillograph thereof are provided.

The object of the invention is to be achieved by following technical proposals:

A kind of improved shunt circuit linearity insulating circuit, is characterized in that, comprising: low-frequency amplifier circuit, linear optical coupling circuit, transformer and adding circuit;

Described low-frequency amplifier circuit, for input signal is carried out to filtering, the low frequency signal in output input signal;

Described linear optical coupling circuit, is connected with described low-frequency amplifier circuit, for the low frequency signal of low-frequency amplifier circuit input is isolated, and the low frequency signal of exporting after isolation is inputted to described adding circuit;

Winding one end, former limit access input signal of described transformer, the low frequency signal of other end access low-frequency amplifier circuit output, forms the high-frequency signal in input signal; Described transformer, isolates for the high-frequency signal to input signal, and the high-frequency signal of exporting after isolation is inputted to described adding circuit;

Described adding circuit, is added for low frequency signal and high-frequency signal that the isolation of input is exported afterwards, generates the rear output signal of isolation, and output.

The front end that accesses the former limit winding terminal of input signal at described transformer is also connected with buffer circuit; Described buffer circuit, for strengthening described input signal.

The output terminal of described linear optical coupling circuit is also provided with frequency compensated circuit;

Described frequency compensated circuit, for increasing the high frequency response of the low frequency signal of exporting after described linear optical coupling circuit isolation.

Described frequency compensated circuit is by amplifier U3, resistance R 4, R5, R6, R7, and capacitor C 2 forms;

The positive input terminal of the low frequency signal input amplifier U3 of output after described linear optical coupling circuit isolation;

Resistance R 4, R5 are serially connected with between the output terminal and ground connection of amplifier U3; The negative input end of the tie point of resistance R 4, R5 and amplifier U3 joins;

R6, R7 are serially connected with between the output terminal and ground connection of amplifier U3;

Capacitor C 2 is connected between the tie point of the tie point of described resistance R 4, R5 and described resistance R 6, R7.

Described transformer adopting line transformer winding method; The armature winding of this transformer and secondary winding adopt twisted-pair feeder, parallel lines or coaxial cable.

The gain of described adding circuit is adjusted according to the gain in described linear optical coupling circuit and transformer.

Described adding circuit adopts Full differential operational amplifier; Two lead-out terminals of this transformer secondary output winding are connected to two input ends of the fully-differential amplifier of adding circuit; Between described linear optical coupling circuit output end and adding circuit, set up a single-ended transfer difference circuit; This single-ended transfer difference circuit, is converted to difference channel signal for the single-end circuit signal that makes the output of linear optical coupling circuit.

An oscillograph with improved shunt circuit linearity insulating circuit, comprising: decay switching module, input stage buffering and adding circuit, programmable amplifier, high-speed ADC, control processing module and D/A modular converter; Input signal is sent to control processing module through decay switching module, input stage buffering and adding circuit, programmable amplifier, high-speed ADC successively; Control processing module gain control signal is sent to this programmable amplifier; Control processing module and also offset signal is sent to input stage buffering and adding circuit through D/A modular converter; It is characterized in that:

Any one improved shunt circuit linearity insulating circuit be serially connected with claim 1 to 7 between described programmable amplifier and high-speed ADC in, to realize signal isolation object;

Between described control processing module and programmable amplifier, and control between processing module and D/A modular converter, be also serially connected with digital isolator.

Described programmable amplifier is output as differential signal; Between this programmable amplifier and described improved shunt circuit linearity insulating circuit, be serially connected with difference and turn single-end circuit, so that described differential signal is converted to single-ended signal.

Beneficial effect of the present invention is:

1, use transformer directly to produce the high fdrequency component in input signal, carry out the isolation of high frequency channel, circuit is simple, without computing circuits such as subtracters.

2, can realize circuit linearity insulating circuit, after isolation, signal and input signal are basically identical.

3, can realize the isolation of large bandwidth signal, more than isolation bandwidth can reach 200MHz.

4, transformer adopting line transformer mode, coiling is convenient.

5, the frequency compensated circuit of linear optical coupling circuit is simple, and debugging is convenient.

6, carry out the compensation of linear optical coupling without increasing delay circuit at high-frequency circuit.

7, can utilize easily in isolation oscillograph front end, realize isolation oscillograph function.

Brief description of the drawings

Accompanying drawing described herein is used to provide a further understanding of the present invention, forms the application's a part, does not form limitation of the invention.In the accompanying drawings:

Fig. 1 is existing buffer circuit example one structural drawing;

Fig. 2 is existing buffer circuit example two structural drawing;

Fig. 3 is existing buffer circuit example three structural drawing;

Fig. 4 is improved shunt circuit linearity insulating circuit structural representation;

Fig. 5 (A) is input signal schematic diagram;

Fig. 5 (B) is output signal schematic diagram;

Fig. 6 is amplitude-frequency depression principle explanation schematic diagram after signal frequency stack;

Fig. 7 is frequency compensation process schematic diagram;

Fig. 8 is improved shunt circuit linearity insulating circuit embodiment 1 structural representation;

Fig. 9 is improved shunt circuit linearity insulating circuit embodiment 2 structural representations;

Figure 10 is the structured flowchart of existing oscilloscope analog front end;

Figure 11 is the oscilloscope architecture schematic diagram of the shunt circuit linearity insulating circuit of application enhancements.

Embodiment

For making the object, technical solutions and advantages of the present invention clearer, below in conjunction with embodiment and accompanying drawing, the present invention is described in further details.At this, exemplary embodiment of the present invention and explanation thereof are used for explaining the present invention, but not as a limitation of the invention.

For existing problem in aforementioned prior art, the present invention is by being connected to input signal one end of transformer, low frequency component is connected to the other end of primary coil, for the low frequency component of offset input signal, curent change in primary winding has reacted the high fdrequency component in input signal, different frequency part is isolated by different independent paths respectively, thereby realizes high bandwidth linear isolation.Fig. 4 is the improved shunt circuit linearity insulating circuit structural representation of the present invention.As shown in the figure, this improved shunt circuit linearity insulating circuit, comprising: low-frequency amplifier circuit, linear optical coupling circuit, transformer and adding circuit.

Described low-frequency amplifier circuit, for input signal is carried out to filtering, the low frequency signal in output input signal;

Described linear optical coupling circuit, is connected with described low-frequency amplifier circuit, for the low frequency signal of low-frequency amplifier circuit input is isolated, and the low frequency signal of exporting after isolation is inputted to described adding circuit;

Winding one end, former limit access input signal of described transformer, the low frequency signal of other end access low-frequency amplifier circuit output; Like this, the low frequency signal in the input signal of input signal and low-frequency amplifier circuit output is cancelled out each other, and has formed the high-frequency signal in input signal in this former limit winding side; Described transformer, isolates for the high-frequency signal to input signal, and the high-frequency signal of exporting after isolation is inputted to described adding circuit;

Described adding circuit, is added for low frequency signal and high-frequency signal that the isolation of input is exported afterwards, generates the rear output signal of isolation, and output.

In above-mentioned improved shunt circuit linearity insulating circuit, input signal is connected to low-frequency amplifier circuit, and low-frequency amplifier has the effect of low pass, and the direct current tremendously low frequency part that the frequency content of output signal is input signal is called for short low frequency signal.Use linear optical coupling circuit to carry out linear isolation the low frequency component in input signal.Input signal is connected to one end of transformer primary side winding, low frequency component is connected to the other end of former limit winding, for the low frequency component of offset input signal, curent change in primary winding has reacted the high fdrequency component in input signal, transformer is by the high fdrequency component isolation that is coupled, low frequency signal and high-frequency signal after isolation are input to adding circuit, carry out additive operation, before output signal after isolation and isolation, input signal has smooth amplitude-frequency response, linear phase, has realized linear isolation.Because medium and low frequency of the present invention, high-frequency signal carry out respectively independent isolating, therefore can realize very high isolation bandwidth.And, because transformer directly produces input signal medium-high frequency component signal, and there is no subtraction formula frequency dividing circuit of the prior art, do not produce high frequency signal by subtracter, greatly simplify circuit.Also error simultaneously that avoided subtracter gain to cause due to resistance precision, amplifier input biasing, bias current.

In addition, in order to strengthen the driving force of input signal to transformer.As shown in Figure 4, this buffer circuit is also connected with buffer circuit at the front end of the former limit winding terminal of transformer access input signal.Described buffer circuit, for strengthening described input signal.By this buffer circuit is set, strengthen on the one hand the driving force of input signal, on the other hand input signal is played the effect of buffering, the load that has alleviated signal source.Certainly, if input signal driving force is enough strong, buffer circuit can omit, and does not affect patentability of the present invention.

In the present invention, between input signal, low frequency signal and high-frequency signal, relation is illustrated in fig. 5 shown below.Fig. 5 (A) is input signal schematic diagram, supposes that input signal is ideal pulse, and having amplitude is A, the frequency response of infinite bandwidth.Fig. 5 (B) is output signal schematic diagram.Wherein, low frequency signal at frequency domain representation as shown in the figure, the cutoff frequency that f1 is low frequency signal.High-frequency signal as shown in the figure, the cutoff frequency that f2 is high-frequency signal.They the two be directly added, the signal after addition is the same with input signal.

High-frequency signal is isolated through transformer, and transformer need to have enough large bandwidth, and meets the cutoff frequency f2 of high-frequency signal, and the low cutoff frequency of transformer should be less than f2.Near component of signal frequency f 2 like this, could substantially unattenuated isolating, and the high-frequency signal after isolation and low frequency signal are added could go back original input signal.

The highest frequency of transformer and low-limit frequency are contradictions, have lower frequency of operation, just need magnetic core to have larger saturation flux, larger volume, or the number of turn of coil are more; There is higher frequency of operation, just need magnetic core to have higher magnetoconductivity, less volume and coil turn still less.So it is very large that the passband of range transformer (higher cutoff frequency deducts low cutoff frequency) cannot be done, generally also with regard to hundreds of MHz.In circuit linearity insulating circuit, low cutoff frequency wants to meet the bandwidth of linear optical coupling buffer circuit, be generally a few kHz to tens kHz, the higher cutoff frequency of transformer generally can be accomplished 200MHz so, being more just difficult to of high bandwidth, can cause amplitude-frequency response flatness variation, rising and falling appears in amplitude-frequency response.

High frequency transformation in the present invention is in order to realize large as far as possible bandwidth, and its low cutoff frequency need to meet the cutoff frequency of linear optical coupling circuit, is generally a few kHz to tens kHz.So adopt line transformer winding method, can realize high as far as possible bandwidth.

Armature winding and secondary winding are passed through twisted-pair feeder by line transformer, parallel lines, the modes such as coaxial cable, form transmission line, primary and secondary wire abuts against together, the line capacitance of arbitrfary point is all very large, and be to be uniformly distributed on whole line, because wire is on high permeability magnetic core, therefore the inductance value of the every segment of wire is also very large, and be evenly distributed on whole line, therefore transmission line can be regarded numerous inductance as, the coupled chain of electric capacity composition, complete the transmission of energy, therefore the electric capacity between line transformer line does not only affect the transmission of high-frequency energy, but the necessary condition of electromagnetic energy conversion, because electromagnetic wave is mainly the Propagation between wire, the loss of magnetic core will greatly reduce the impact of signal transmission, so the maximum operation frequency of line transformer just can improve greatly, can arrive several GHz.In the present invention, select the soft magnetic property of high permeability, as FERRITE CORE.In the present invention, transformer can be realized higher isolation bandwidth, more than reaching 200MHz.

Magnetic core in the present invention generally can be selected round magnet ring, winds the line simple and convenient.Certainly Fang Huan needs to use other shapes, as also can.

In the present embodiment, transformer all adopts former the limit winding of 1:1, signal is carried out to the isolation of 1:1.Certainly, select the transformer of other ratios, also do not affect creativeness of the present invention.Accordingly, only the gain of described adding circuit need be adjusted according to the gain in linear optical coupling circuit and transformer, be made both signal amplitude balances unanimously.

The pull-up resistor of transformer output is R8, and the circuit conversion in secondary winding is become to voltage.Output voltage is connected to the input end of adding circuit.

As shown in the figure, described linear optical coupling circuit comprises operational amplifier U1, resistance R 1, resistance R 2, capacitor C 1, linear optical coupling, operational amplifier U2 and resistance R 3.Linear optical coupling inside is packaged with the photodiode of a light emitting diode and two couplings, one for feedback, one for isolation coupling signal.Linear optical coupling is preferably selected HCNR200 or the HCNR201 of Avago company.Amplifier U1 has completed the driving of light emitting diode and the detection of feedback light electric diode.Amplifier U2 has formed current/voltage varying circuit, and the current signal of photodiode coupling is converted to Voltage-output by R3.In circuit, R2 is as the current-limiting resistance of light emitting diode.Resistance R 1, R3 have determined the gain of linear optical coupling circuit, and R3/R1 equals gain, and C1 electric capacity is used for improving circuit stability, has played certain low-pass effect simultaneously.Reference power source-Vref ,+Vref, for making the input and output biasing of linear optical coupling circuit the same, input the voltage of 0V, and output is also 0V.

Linear optical coupling circuit has certain time delay, and C1 also has certain low-pass effect simultaneously, while causing linear optical coupling output and the stack of medium-high frequency signal, and the amplitude-frequency depression occurring in the place of low frequency signal and the stack of intermediate-freuqncy signal frequency.As shown in Figure 6, input signal is square-wave signal, and output signal is divided into low frequency signal and high-frequency signal.If low frequency signal does not have time delay, the waveform after being directly added is consistent with input waveform.But if low frequency signal has time delay t, the signal after being directly added is as figure below, behind edge, there is depression in square wave, be embodied in frequency domain, the amplitude-frequency that is exactly the frequency crossover place of high-frequency signal and low frequency signal has reduced, and this frequency is near the cutoff frequency in low frequency signal.Same capacitor C 1 has certain low-pass effect to low frequency signal, also can make the high fdrequency component amplitude-frequency step-down in low frequency signal, occurs equally amplitude-frequency depression.

According to the problems referred to above, as shown in Figure 4, the present invention is also provided with frequency compensated circuit at the output terminal of described linear optical coupling circuit.Described linear optical coupling circuit, for increasing the high frequency response of the low frequency signal of exporting after described linear optical coupling circuit isolation.

Specifically, described frequency compensated circuit is by amplifier U3, resistance R 4, R5, R6, R7, and capacitor C 2 forms.The positive input terminal of the low frequency signal input amplifier U3 of output after described linear optical coupling circuit isolation.Resistance R 4, R5 are serially connected with between the output terminal and ground connection of amplifier U3.The negative input end of the tie point of resistance R 4, R5 and amplifier U3 joins.R6, R7 are serially connected with between the output terminal and ground connection of amplifier U3.Capacitor C 2 is connected between the tie point of the tie point of described resistance R 4, R5 and described resistance R 6, R7.

In this frequency compensated circuit, R4, R5 form amplifier gain, and gain equals R5/R4, the gain that linear optical coupling circuit is multiplied by this gain equals the full gain of low frequency channel, need to equal 1, make the isolation of low frequency signal 1:1, the addition of signal after realization and the isolation of medium-high frequency path.If gain is not equal to 1, the isolation gain of corresponding medium-high frequency path also needs to be not equal to 1, needs equal with low frequency channel full gain.R6, R7 and the C2 response that is used for adjusting frequency, wherein the product of C2, R4 has determined the Frequency point of compensation, if R6/R7 equals R5/R4, the high fdrequency component of frequency compensated circuit output signal does not increase, does not also reduce; If R6/R7 is greater than R5/R4, the high fdrequency component of output signal increases.The frequency depression that this frequency compensated circuit can bring linear optical coupling circuit delay and low pass compensates.

This frequency compensation process as shown in Figure 7.Frequency compensated circuit increases the frequency response of the low frequency signal medium-high frequency part of exporting after isolation, is to reduce above-mentioned depression in essence, makes this depression of signal after superposition substantially can't see or be submerged in noise.Because after signal lag, no matter how lifting high fdrequency component of low frequency signal, within the t moment, low frequency signal is minimum level all the time, so still have a very little depression after superposition.But because the time delay of photoelectric coupled circuit is very little, so the time of this depression is very little, substantially can ignore.So the present invention can solve the amplitude-frequency response depression problem that time delay and low pass are brought.

The signal of low frequency channel is after frequency compensated circuit, be connected to adding circuit input end with transformer output signal, be added, output signal after addition, there is smooth amplitude-frequency response, linear phase with input signal, be that output signal can be reacted input signal, realized linear isolation.

Insulation isolation voltage of the present invention, is determined by the winding conducting wire of linear optical coupling, transformer, can realize the isolation strength of 5000Vrms.

With several specific embodiments, the invention will be further described below:

Embodiment 1

Fig. 8 is the present embodiment structural representation.The present embodiment is applicable to single-ended signal input, the application of single-ended signal output.

In the present embodiment, low-frequency amplifier circuit uses R, C low-pass filtering, and amplifier follow circuit.Resistance and electric capacity have determined the bandwidth of low-frequency amplifier circuit, need to meet the bandwidth of linear optical coupling circuit, and selecting resistance is 10k Ω, electric capacity 1.5nF, and the bandwidth of low-frequency amplifier circuit is 10kHz.Amplifier can be selected any high-precision amplifying, to meet the requirement to low-frequency sampling precision, certainly select precision, low noise, low distortion, Low-bias Current, these more excellent amplifiers of Low Drift Temperature, can be conducive to the realization to low frequency high precision technology effect.For example select AD823, the AD8639 etc. of ADI company.

The amplifier of linear optical coupling circuit, frequency compensated circuit can be selected the amplifier identical with low-frequency amplifier circuit.

The resistance capacitance value of linear optical coupling circuit is that R2 gets 150 Ω, for current limliting.R1 gets 10k Ω, and R3 gets 5k Ω, and the gain of linear optical coupling circuit is that 0.5, C1 recommends 3pF.

The gain of frequency compensated circuit is 2, gets R4=R5=1k Ω, and the frequency depression causing according to actual optocoupler, selects suitable electric capacity, in the present embodiment, and C2=100pF.The ratio of R6, R7, for the degree of regulating frequency depression, regulates suitable value, and basic disappearance makes to cave in.In the present embodiment, R6=1.5k Ω, R7=1k.

High frequency buffer circuit is selected high speed operation amplifier, and the present embodiment need to be realized at least buffer circuit of 200MHz bandwidth.Amplifier forms follow circuit, and gain is 1.High speed amplifier can be selected AD8038, AD8000, AD8001, the AD8009 etc. of ADI company.

Adding circuit can be selected the operational amplifier identical with buffer circuit, composition adding circuit, and circuit gain is 1, wherein 4 resistance equate.

Transformer in the present embodiment, in order to realize the bandwidth of 200MHz, and its lowest operating frequency need to be as far as possible low, at least extends to and be less than 10kHz.And withstand voltage between primary and secondary will meet design and expect.In the present embodiment, transformer winding mode has adopted line transformer mode, can realize good frequency response.Other forms of transformer can be passable, but frequency response response is slightly poor.

Transformer magnetic is most preferably used high permeability soft magnetic ferrite bead, as the R10K series of Beijing QiXing flying Electronics Co., Ltd, and as R10K-H13x7x5, diameter 13mm, internal diameter 7mm.As the A10 series of Yue Feng electronic material incorporated company, as A10-T12x6x4, diameter 12mm, internal diameter 6mm.

Wire rod adopts three layer insulation wire, can realize very high withstand voltage, as the TEX-E three layer insulation wire of electronics industry Co., Ltd. of Furukawa Electronic, wire diameter Ф 0.20mm.As directly weldering type of the TIW-B three layer insulation wire along positron company limited, wire diameter Ф 0.20mm.

Winding method is primary and secondary wire, twists into twisted-pair feeder every 5mm, is wound on magnet ring coiling 15 circles.

The line transformer of the present embodiment can be realized minimum 1kHz, the frequency of operation of the highest 200MHz, and in frequency band range, amplitude-frequency response fluctuation is very little.

The dielectric strength of transformer is determined by the insulation between primary and secondary winding conducting wire, in the present embodiment, can select multilayer insulated wire, as 3 layers of insulated wire, can realize voltage device isolation more than 5000V.

The present embodiment can be realized and be with the circuit linearity insulating circuit that is wider than 5200MHz, has voltage isolation more than 5000V.

Embodiment 2

Fig. 9 is the present embodiment structural representation.The present embodiment is applicable to single-ended signal input, the application of differential signal output.

The difference of the present embodiment and embodiment 1 is that adding circuit adopts Full differential operational amplifier, difference output.Composition adding circuit, two lead-out terminals of transformer secondary output winding are connected to two input ends of difference adding circuit, and 6 resistance of adding circuit are selected identical resistance, and adding circuit gain is 1.Full differential operational amplifier can be selected the ADA4927 of ADI company or LMH6552, the LMH6554 of TI company.

Former low frequency channel is still single-end circuit.Only need between described linear optical coupling circuit output end and adding circuit, set up a single-ended transfer difference circuit.This single-ended transfer difference circuit, uses Full differential operational amplifier, so that single-end circuit signal is converted to difference channel signal, and input adding circuit.Particularly, can select the fully-differential amplifier that meets low frequency channel bandwidth, as the AD8476 of ADI company, AD8275.

The buffer circuit that the present embodiment provides is differential signal by the isolation signals of the final output of adding circuit.

The invention provides improved shunt circuit linearity insulating circuit, can be applicable to the measuring equipments such as oscillograph.Figure 10 is the structured flowchart of existing oscilloscope analog front end.As shown in the figure, this oscillograph, comprising: decay switching module, input stage buffering and adding circuit, programmable amplifier, high-speed ADC, control processing module and D/A modular converter.Input signal is sent to control processing module through decay switching module, input stage buffering and adding circuit, programmable amplifier, high-speed ADC successively.Control processing module gain control signal is sent to this programmable amplifier.Control processing module and also offset signal is sent to input stage buffering and adding circuit through D/A modular converter.

Figure 11 is the oscilloscope architecture schematic diagram of the designed improved shunt circuit linearity insulating circuit of application the present invention.As shown in the figure, this oscillograph, on the basis of above-mentioned existing oscilloscope architecture, is connected in series the designed improved shunt circuit linearity insulating circuit of the present invention between described programmable amplifier and high-speed ADC, to realize signal isolation object., also between described control processing module and programmable amplifier, and control between processing module and D/A modular converter meanwhile, be serially connected with digital isolator.This digital isolator is prior art, is mainly used in isolating digital signal.Digital isolator generally has photoelectric coupling mode, magnetic coupling mode and capacitive coupling etc.As the photoisolator of Avgao company, the digital isolator of the iCoupler series magnetic coupling mode of ADI company, the capacitance digital isolator of TI company.

In addition, if the output of described programmable amplifier is differential signal, between this programmable amplifier and shunt circuit linearity insulating circuit, is connected in series difference and turns single-end circuit, so that its differential signal is converted to single-ended signal, for shunt circuit linearity insulating circuit.

Improved shunt circuit linearity insulating circuit and oscillograph thereof that the present invention is designed, by input signal being connected to one end of transformer, low frequency component is connected to the other end of primary coil, for the low frequency component of offset input signal, curent change in primary winding has reacted the high fdrequency component in input signal, different frequency part is isolated by different independent paths respectively, thereby realizes high bandwidth linear isolation.And, because transformer directly produces input signal medium-high frequency component signal, and there is no subtraction formula frequency dividing circuit of the prior art, do not produce high frequency signal by subtracter, greatly simplify circuit.Also error simultaneously that avoided subtracter gain to cause due to resistance precision, amplifier input biasing, bias current.And the new frequency compensated circuit of the embodiment of the present invention can solve prior art and can not realize the shortcoming of linear optical coupling compensation of delay.Persons skilled in the art any not creative transformation of doing under this design philosophy, all should be considered as within protection scope of the present invention.

Claims (9)

1. an improved shunt circuit linearity insulating circuit, is characterized in that, comprising: low-frequency amplifier circuit, linear optical coupling circuit, transformer and adding circuit;

Described low-frequency amplifier circuit, for input signal is carried out to filtering, the low frequency signal in output input signal;

Described linear optical coupling circuit, is connected with described low-frequency amplifier circuit, for the low frequency signal of low-frequency amplifier circuit input is isolated, and the low frequency signal of exporting after isolation is inputted to described adding circuit;

Winding one end, former limit access input signal of described transformer, the low frequency signal of other end access low-frequency amplifier circuit output, forms the high-frequency signal in input signal; Described transformer, isolates for the high-frequency signal to input signal, and the high-frequency signal of exporting after isolation is inputted to described adding circuit;

Described adding circuit, is added for low frequency signal and high-frequency signal that the isolation of input is exported afterwards, generates the rear output signal of isolation, and output.

2. improved shunt circuit linearity insulating circuit as claimed in claim 1, is characterized in that: the front end that accesses the former limit winding terminal of input signal at described transformer is also connected with buffer circuit; Described buffer circuit, for strengthening described input signal.

3. improved shunt circuit linearity insulating circuit as claimed in claim 1, is characterized in that: the output terminal of described linear optical coupling circuit is also provided with frequency compensated circuit;

Described frequency compensated circuit, for increasing the high frequency response of the low frequency signal of exporting after described linear optical coupling circuit isolation.

4. improved shunt circuit linearity insulating circuit as claimed in claim 3, is characterized in that: described frequency compensated circuit is by amplifier U3, resistance R 4, R5, R6, R7, and capacitor C 2 forms;

The positive input terminal of the low frequency signal input amplifier U3 of output after described linear optical coupling circuit isolation;

Resistance R 4, R5 are serially connected with between the output terminal and ground connection of amplifier U3; The negative input end of the tie point of resistance R 4, R5 and amplifier U3 joins;

R6, R7 are serially connected with between the output terminal and ground connection of amplifier U3;

Capacitor C 2 is connected between the tie point of the tie point of described resistance R 4, R5 and described resistance R 6, R7.

5. improved shunt circuit linearity insulating circuit as claimed in claim 1, is characterized in that:

Described transformer adopting line transformer winding method; The armature winding of this transformer and secondary winding adopt twisted-pair feeder, parallel lines or coaxial cable.

6. improved shunt circuit linearity insulating circuit as claimed in claim 1, is characterized in that: the gain of described adding circuit is adjusted according to the gain in described linear optical coupling circuit and transformer.

7. improved shunt circuit linearity insulating circuit as claimed in claim 1, is characterized in that: described adding circuit adopts Full differential operational amplifier; Two lead-out terminals of this transformer secondary output winding are connected to two input ends of the fully-differential amplifier of adding circuit; Between described linear optical coupling circuit output end and adding circuit, set up a single-ended transfer difference circuit; This single-ended transfer difference circuit, is converted to difference channel signal for the single-end circuit signal that makes the output of linear optical coupling circuit.

8. an oscillograph with improved shunt circuit linearity insulating circuit, comprising: decay switching module, input stage buffering and adding circuit, programmable amplifier, high-speed ADC, control processing module and D/A modular converter; Input signal is sent to control processing module through decay switching module, input stage buffering and adding circuit, programmable amplifier, high-speed ADC successively; Control processing module gain control signal is sent to this programmable amplifier; Control processing module and also offset signal is sent to input stage buffering and adding circuit through D/A modular converter; It is characterized in that:

Any one improved shunt circuit linearity insulating circuit be serially connected with claim 1 to 7 between described programmable amplifier and high-speed ADC in, to realize signal isolation object;

Between described control processing module and programmable amplifier, and control between processing module and D/A modular converter, be also serially connected with digital isolator.

9. the oscillograph with improved shunt circuit linearity insulating circuit as claimed in claim 8, is characterized in that: described programmable amplifier is output as differential signal; Between this programmable amplifier and described improved shunt circuit linearity insulating circuit, be serially connected with difference and turn single-end circuit, so that described differential signal is converted to single-ended signal.

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