DE19600593C1 - Amplifier especially for generating high voltage signals - Google Patents

Abstract

The amplifier includes two high voltage sources (18,19) and two controlled current sources (1,20) which are connected together in a circuit. The potential reference point (24) lies between the two high voltage sources and the potential tapping point (17) for the high voltage signal lies between the two current sources. The current sources each have at least one controlled, elementary current source (22) corresponding to the desired high voltage from n successive similar elementary current sources. Each elementary current source is controlled by a controllable voltage divider that has a fixed divider resistor (3) and a variable resistor formed by a phototransistor at the output of a photocoupler (2). An adjustable network (5) is connected in front of each photocoupler to operate, i.e. bias and control, the input photodiode of the photocoupler. To control the positive part of the signal the respective network has its output connected to the anode of the input photodiode. To control the negative part of the signal, the network lies at the cathode of the diode.

Description

The invention relates to an amplifier for generating high voltage signals of high voltage amplitude and almost any Waveform.

On function generators that like voltage curves over time a sawtooth shape, triangle shape, sine shape or any other un Generating different pulse formations is a wide one Choice of palette. The output signals are in the Usually well below 100 V. Operati are on the market onsamplifier available with which such voltage curves can be proportionally amplified. But even then it is Limit still below 1000 V.

Functional curves over time, the voltage amplitudes of which indicate are higher than 1000 V, according to the state of the art nik only solved with an electron tube amplifier. Because of the Power balance must with the high voltage tube amplifiers Working resistances can be chosen very high. Such a ver amplifier circuit also requires an impedance converter direction to reduce the output resistance - ie white principle tubes.

The circuit effort increases enormously, should such High voltage amplifier also signals of both polarities deliver. The effort in heating and grid supply, which at Driving tubes for 5 or even 10 kV is substantial and takes up a lot of space.

A high voltage amplifier can be partially replaced by a scarf device, as can be seen from DE 40 40 164 A1, solved will. With this device, however, only staircase signals are in the Generate range of ± 5 kV.  

In DE 26 49 718 B2 a circuit arrangement for the control the deflection coil of a picture tube described. You be stands on the high voltage side from the circle of two high voltage sources and an amplifier that consists of two connected in series Darlington levels. The direct connection of the High voltage sources form the reference potential and the di right connection of the two Darlington stages the high chip tap. The amplifier is powered by a power source controls, which in turn are operated by an operational amplifier becomes. The load on the high-voltage side exists in each case a voltage and current feedback to the negative input of the operational amplifier, which simultaneously Signal input is. For cascading in the amplifier area and this circuit is therefore not suitable for higher high voltages is suitable.

The invention has for its object a reliable Amplifier for generating high-voltage signals on semi-conductors Provide base with almost any signal shapes can be linearly reinforced. The space requirement and the Supply performance of a conventional tube device correspond performance should also be considerably lower be paced.

The object is achieved by the features of the An spell 1 solved. Two high voltage sources are together with two controlled current sources connected to a circuit. Of the Potential reference point lies on the direct connection of the two high voltage sources, the high voltage signal is from the direct connection of the two power sources.

The two power sources exist depending on which can be controlled High voltage each from a cascade of n elementary Power sources, each of which has its own control channel. All elementary power sources are controlled in the same way. In each control channel there is an optocoupler, which has a  adjustable network is controlled and that with its Tran sistor output Part of a controllable voltage divider is whose fixed resistance at the control input of the elementary Power source is. A channel-specific voltage source feeds the Voltage divider.

All control inputs of the adjustable networks are off gang of a modulator summarized, so that depending on the Vori Chen the modulator output signal a simultaneous control the elementary power sources for the positive or the nega tive part of the high voltage signal.

The modulator consists of a differential amplifier with after switched driver stage.

In addition to the internal gain of the differential amplifier a feedback from the high-voltage section via a resistor reached here so that there is a low impedance dynami output resistance. This also activates errors caused by non-linearities in the optocouplers arise, corrected.

In claim 2 is the circuit of an elementary current source featured, which is an almost arbitrary cascading of many such allowed without cross-talk when driving.

Claims 3 and 4 characterize the circuit measures for Control of every elementary power source.

Claim 5 finally identifies the internal, proportional Gain on the modulator amplifier with the feedback acts on the negative input from the high voltage tap. The control signal input on the modulator is the positive connection on the differential amplifier.  

In terms of control technology, it is advantageous to use the internal feedback development from the feedback from the high voltage tap keep separate. This arrangement is less vibration-sensitive due as the simple feedback only via the high voltage potential. This can be explained with the Bode diagram tern.

The negative feedback from the High voltage point across the divider resistor on the Diffe limit amplifier works. Through this feedback, the ge Entire circuit configuration to a controlled voltage source. It has a low dynamic output resistance. This also ensures good frequency behavior very high resistance load, d. H. the cutoff frequency remains high. In addition, it is advantageous that this feedback the inaccuracies or non-linearities of the optocouple be corrected in wide areas. It is with this Amplifier easily possible the usual signal functions such as sine, rectangle, triangle, sawtooth and other pulse sequences to drive in the high voltage range of 5 to 10 kV and above.

The circuit of the amplifier will be explained below with reference to the circuit diagram in the single figure of the drawing. The embodiment is designed for an output voltage between the two high-voltage taps of 5000 V, more precisely ± 2500 V. With an input voltage of max. ± 5 V, two times four field effect transistors 12 are cascaded with their wiring to the elementary current source 22 . (Instead of the field effect transistors, IGBT transistors or bipolar transistors could also be used.) The circuit diagram shows the better overview because of the two current sources 1 and 20 , each with two cascaded, elementary current sources 22 .

The basic elements of the amplifier are the two controllable current sources 1 and 20 , one for the positive signal part, current source 1 and the other for the negative signal part, current source 20 . The elementary current source 22 consists of the field effect transistor 12 and the Ge gene coupling resistor 9 connected to the S contact. To the field effect transistor 12 and the negative feedback resistor 9 , the second negative feedback resistor 11 is in parallel, which is a voltage-dependent by pass. Between the G and S contact of the field effect transistor 12 is the protective element 10 , which derives an overvoltage that occurs.

Each elementary current source 22 is operated by its associated, controllable voltage divider, which consisted of the opposing 3 and the phototransistor in the output of the optocoupler 2 . The voltage divider loads the voltage source 4, which development of the ring core transformer 8, the geschleif th through it highly insulated current loop 21 a and 21 b as a primary wick and the secondary winding consists of four coils with in this embodiment. The toroidal transformer 8 is dimensioned so that it works as a current-voltage converter (differentiating transformer). Connected to the secondary winding is the capacitor 26 , with the voltage-limiting Zenerdi ode 27 and the diode 28 , which charges the capacitor in accordance with the forward direction. As a result, each elementary current source 22 at the control input G is always kept at a defined potential, although the toroidal core transformer 8 is operated in pulsed fashion via the two current loops 21 a and 21 b.

Current pulses of a few microseconds duration flow through the current loops 21 a and 21 b at a repetition frequency of approximately 100 kHz. Due to the winding direction of the secondary winding and the wiring, the toroidal core transformer 8 works with the trailing edge, with the falling edge of the current signal, ie with the energy stored in the core. The power supply provides a voltage of 8 V. The load capacity is around 80 mW. The two current loops 21 a and 21 b have an insulation of more than 20 kV.

The optocoupler 2 , which has an insulation of about 15 kV, is controlled via the adjustable network 5 for the upper and lower region of the coupler diode (photodiode at the input) by the modulator circuit 6 . The modulator circuit 6 consists of the differential amplifier 23 with the following driver circuit 25 . At the positive input of the differential amplifier 23 is the input for the signal to be linearly amplified. At the ne negative input, the internal gain is set via the connected resistors 14 and 16 . In addition, the feedback signal from the high-voltage tap 17 via the divider resistor 13 is coupled.

The following difference exists between the two power sources 1 and 20 :
In the case of the current source 1 , the networks 5 are connected to the respective anode of the input photodiode of the optocoupler 2 . The cathode is on ground. With the current source 20 , the input photodiode of the respective optocoupler 2 is closed in reverse. Thus, only the positive signal part for the current source 1 and exclusively the negative signal part of the control signal at the output of the modulator 6 or the driver stage 25 can be used for the current source 20 .

The current source 1 with its two cascaded, elementary current sources 22 is connected to the positive high-voltage source 18 . The current source 20 with two cascaded, elementary current sources 22 to the negative voltage 19th Both high-voltage sources 18 and 19 are here connected to earth potential, the potential reference point 24 .

The elementary current sources 22 all have the negative feedback resistance 9 to compensate for the component tolerances. The voltage-dependent resistor 11 , which is a zinc oxide varistor, enhances the effect of the negative feedback resistor 9 as a bypass with negative feedback effect and thus creates stable cascading conditions.

The gain of the high-voltage amplifier 7 is 500. The loop gain of the feedback is significantly higher.

The exemplary embodiment was for the common signal function NEN operated up to a cutoff frequency of 10 kHz without Deviations in the high-voltage signal curve occurred.

Reference list

1 power source
2 optocouplers
3 resistance
4 voltage source
5 network
6 modulator circuit
7 high voltage amplifiers
8 toroid
9 negative feedback resistance
10 protective element
11 resistance
12 transistor
13 feedback resistor
14 resistance
15 entrance
16 resistance
17 Potential tap
18 high voltage source
19 high voltage source
20 power source
21 a current loop
21 b current loop
22 elementary power source
23 differential amplifier
24 potential reference point
25 driver stage
26 capacitor
27 zener diode
28 diode

Claims (5)

1. amplifier for generating high-voltage signals, consisting of two high-voltage sources ( 18 , 19 ) and two ge-controlled current sources ( 1 , 20 ), which are connected together to form a circuit, sources between the two high-voltage ( 18 , 19 ) the electrical Potential reference point ( 24 ) and between the two current sources ( 1 , 20 ) the potential tap ( 17 ) for the high-voltage signal, characterized in that
the two controlled current sources ( 1 , 20 ) each consist of at least one controlled, elementary current source ( 22 ), but, in accordance with the high voltage to be controlled, consist of n identical elementary current sources ( 22 ) connected in series,
each elementary current source ( 22 ) is controlled via a controllable voltage divider fed by a voltage source ( 4 ), consisting of a fixed divider resistor ( 3 ) and a variable resistor which is formed by a photo transistor at the output of an optocoupler ( 2 ), the connection point of the divider resistors being located at the control input (G) of the associated elementary current source ( 22 ),
Each optocoupler ( 2 ) is preceded by an adjustable network ( 5 ) for operating (biasing and controlling) the input photodiode of the optocoupler, the respective network ( 5 ) with its output being connected to the anode of the input photodiode for driving the positive part of the high-voltage signal and to control the negative part of the high voltage signal, the respective network ( 5 ) is connected to the cathode of the input photodiode,
the respective control input of the networks ( 5 ) is connected to the output of a modulator ( 6 ) which consists of a differential amplifier ( 23 ) with a subsequent driver stage ( 25 ),
from the potential tap ( 17 ) via a resistor ( 13 ) a feedback to the negative input of the differential amplifier ( 23 ) is set up, whereby a dynamic output resistor of low impedance at the Potentialab handle ( 17 ) and control errors caused by non-linearities of the optocoupler ( 2 ) arise, be corrected. 2. Amplifier according to claim 1, characterized in that each elementary current source ( 22 ) from a transistor ( 12 ) with an at its output (S) subsequent coupling resistance ( 9 ) and one of the input (D) of the transistor stors ( 12 ) and the negative feedback resistor ( 9 ) consists of a bridging, voltage-dependent resistor ( 11 ) and a protective element ( 10 ) connecting the control input (G) to the output (S) of the transistor ( 12 ). 3. Amplifier according to claim 2, characterized in that each voltage source ( 4 ) consists of a ring core ( 8 ) through which an electrically highly insulated current loop ( 21 a or 21 b) is guided as a primary winding, and this ring core ( 8 ) has a secondary winding with a predetermined number of turns, which is connected via a diode ( 28 ) to a capacitor ( 26 ) with a voltage-limiting Zener diode ( 27 ) connected in parallel. 4. Amplifier according to claim 3, characterized in that the bias voltage on the photodiode of each optocoupler ( 2 ) via the network ( 5 ) is adjustable, and for control purposes for the positive part of the high-voltage signal, this is connected to a positive voltage supply and for control is connected to a negative voltage supply for the negative part of the high-voltage signal. 5. Amplifier according to claim 4, characterized in that the differential amplifier ( 23 ) of the modulator ( 6 ) via resistors ( 14 , 16 ) is set to a predetermined internal amplification.