DE2831734C3 - Signal generator for generating sinusoidal output signals with a predetermined mutual phase position - Google Patents

Description

The invention relates to a signal generator the type mentioned in the preamble of claim 1.

Such a signal generator is already known (DE-OS 23 58 009). A part of the phase step signals is used to create a to add a constant value to these phase step signals, so that on the one hand a selectable frequency multiplication and on the other hand result in a selectable phase. The number generator consists of one Large number of electronic assemblies, in particular from several different registers and switching elements.

In addition, a signal generator is known (IEEE Transactions on Audio and Electroacoustics, Vol. AU-19, No 1, March 1971, pp. 48-57) which generates two output signals which are phase-shifted by 90 ° from one another. A computer with an RGM memory serves as a function generator and an accumulator serves as a number generator. For each phase step marked by the number generator, the associated sine value and cosine value are simultaneously calculated in the computer and output to a digital / analog converter. This solution requires a complex function generator.

Furthermore, a signal generator is known (DE-OS 22 31458), in which the number generator consists of a Frequency register for the selection of the output frequency and a modulo 10 "accumulator consists and periodically emits binary coded phase step signals to a permanent memory working as a function generator. Of the Read-only memory is connected to a digital / analog converter via an output register and a complementing device connected. The modulo 10 "accumulator is made up of adders and registers, which receive a clock signal from a clock is supplied so that the input signals are linked to one another in the correct temporal relationship. However, this signal generator only generates a single sinusoidal output signal.

It is also known (DE-AS 2118 065), a

to convert sinusoidal signal into amplitude-modulated pulses by repeated sampling and from this to form sinusoidal multiphase signals.

A known signal generator (DE-OS 23 58 009) uses a part of phase step signals by means of an adder to add a constant value to the phase step signals, so that on the one hand result in a selectable frequency multiplication and, on the other hand, a selectable phase.

The invention specified in claim 1 is the

The object is to improve a signal generator of the type mentioned in that it is characterized by a simpler circuit structure.

Further developments of the invention are claimed in the subclaims and in the description of the figures described.

The signal generator according to the invention is provided with a simpler number generator. The technical one The effort is therefore comparatively low, especially when there is a larger number of output signals with the same frequency but different phase

senlage is generated.

Two exemplary embodiments of the invention are explained below with reference to the drawing F i g. i a block diagram of a Signa! «enerator, F i g. 2 a diagram and

3 shows a basic circuit diagram of a further signal generator.

The one shown in FIG. 1 generates three alternating voltages Ur, i / s and i / r, each phase shifted by 120 °, as well as three alternating currents Ir, Is and It, each phase shifted by 120 °. The current triangle Ir, Is, It is opposite the voltage triangle Ur, Us, ίΛ shifted by the phase angle φ , which can be preselected at an angle input element 10 and is output by this in binary-coded form. In the example shown, a second angle input member 11 outputs an angle value of 121 ° in a likewise binary-coded form. Depending on the position of a switch <2, which is shown symbolically in the drawing and can consist of several gates corresponding to the number of bits of the binary coded Winkelwcrie, either the angle input member 10 or the angle input member 11 is connected to a first input 13 of an adder 14, whose second input 15 is connected to the output of an accumulator 16 and the output of which is connected on the one hand to the input of the accumulator 16 and on the other hand to the input of a function generator 17. The function generator 17 is followed by a digital / analog converter 18, which is connected on the output side to the memory inputs of six sample-and-hold circuits 19 to 24. A low-pass filter 25 to 30 is connected to each of the sample-and-hold circuits 19 to 24, and an amplifier 31 to 36 is connected downstream of each filter. The amplifiers 31, 33 and 35 are voltage amplifiers and emit the output voltage Ur or Us or Uy . The amplifiers 32, 34 and 36, which operate as current amplifiers, supply the output current / «or. / s or It-

A clock generator 37 generates clock pulses with the frequency to. These arrive at a clock distributor 38,

which on the one hand clocks the accumulator 16 with clock pulses of the frequency / j = 4 and controls the switch 12 and on the other hand clock signals f \ to 4 with the frequency ~

outputs the clock inputs of the sample-and-hold circuits 19 to 24, whereby these are clocked cyclically.

The accumulator 16 and the adder 14 together with the angle input members 10 and 11 and the switch 12 form a number generator which outputs binary-coded phase step signals Ph to the function generator 17, which is converted into binary-coded instantaneous value signals from the function generator 17 and from the digital / analog converter 18 in an analog signal can be converted. The number generator generates, as will be explained in more detail below, for each of the output signals Ur, Ir, Us, Is, Ut and h in cyclic order phase step signals Ph, which are binary-coded instantaneous value signals from the function generator 17 and from the digital / analog converter 18 in a corresponding to a reference voltage Ute! converted proportional analog signal and stored in the assigned sample and hold circuits 19 to 24 in analog form until the next cycle. The function generator 17 therefore only outputs an instantaneous value within each phase step and can accordingly be of simple construction; For example, a ROM memory is suitable as function generator 17, in which the associated instantaneous value of the sine function is stored for each phase step signal 1. Quadrants can be obtained, a relatively small storage capacity is sufficient

In the following, based on the diagram of Fi g. 2 ίο the mode of operation of the signal generator described is explained in detail. 2, the numbers 0 to 7 denote individual phase steps. The various clock signals are again denoted f _a f _s \ md / j to f _6. The line labeled S shows the position of switch 12 for the individual phase steps. In the line Ph of the respective value of the phase step signal Ph is added is stored in the respective accumulator 15 value at the output of the adder 14 and in the A line.

To make it easier to understand, it is initially assumed that the switch 12 is permanently in the 121 ° position. With a clock pulse of the clock signal / ₅ at phase step 1, the phase step signal Ph assumes the value 0 °, this value is stored in the accumulator 16, the function generator 17 forms the associated sine value in binary-coded form and the digital / analog converter 18 in analog Form, a clock pulse of the clock signal i \ appears at the clock input of the sample-and-hold memory 19, and the analog value assigned to the output voltage Ur is stored in the sample-and-hold circuit 19. At the next clock pulse of the clock signal f _s , ie at phase step 3, the value 12Γ of the angle input member 11 is added to the old V / ert 0 ° of the accumulator 16 in the adder 15, the new value 12Γ is transferred to the accumulator 16, and the corresponding The sine value assigned to the output voltage Us is stored in the sample-and-hold circuit 21. In phase step 5, the sine value of 242 ° assigned to the output voltage Ut is stored in the sample-and-hold circuit 23, in phase step 7 the sine value of 363 ° = 3 ° assigned to the output voltage Ur is stored in the sample-and-hold circuit 19, and so on For example, the formation of the output voltage Ur on its own, it seems that the number generator would do nothing other than increase the value of the phase step signal Ph by 3 ° for every sixth phase step. So the works for every initial saving Ur, Us and Ut

so number generator as a separate triangle number generator. At the output of the sample and hold circuits 19, 21 and 23 step-shaped output voltages appear, which approximate a sinusoidal curve and reverse each other are each exactly 120 ° out of phase. With the

With 5 low-pass filters 25, 27 and 29, the stepped output voltages are smoothed and amplified to the required V / ert with the voltage amplifiers 31, 33 and 35.
The assigned to the output currents In, / 5 and It

bO sine values are formed in the next phase step after the calculation of the sine value of the output voltage Ur, Us or Ut of the corresponding phase, i.e. with phase steps 0, 2, 4, 6 ... In the example shown, switch 12 changes to phase step 2 Position φ, the adder 12 performs the addition 0 ° +91, the phase step signal Ph thus assumes the value φ , the function generator 17 outputs the associated sine value at the clock input of

A clock pulse of the clock signal f ₂ appears in the sample-and-hold circuit 20, and the analog value assigned to the output current Ir is stored in the sample-and-hold circuit 20. At the clock input of the accumulator 16, in phase step 2, no clock pulse of the clock signal 4 appears so that the value φ is not stored in the accumulator 16. In the phase step 4, as can be seen from the drawing, the output current Is associated sine value of 12Γ + φ hold circuit sample-22 in which the phase-stepping 6 assigned to the output current It sine value of 242 ° + φ in the sample-hold Circuit 24 stored, etc. The resulting stepped output voltages of the sample-and-hold circuits 20, 22 and 24 are smoothed with the low-pass filters 26, 28 and 30 and converted with the current amplifiers 32, 34 and 36 into corresponding currents of the required strength.

The signal generator described thus forms a voltage triangle Ur, Us, £ / around a current triangle Ir, Is, ITt which rotate counterclockwise and are twisted against each other by the angle ψ. Although the number generator executes steps of 121 ° and not 120 °, the triangles are exactly equilateral, since the corresponding sine value is sampled correspondingly later. As a result of the delayed sampling of the sinusoidal values of the output currents Ir, Is and It compared to the sinusoidal values of the assigned output voltages Ur, t / s and i / r, the current triangle compared to the voltage triangle is not around the angle ψ, but in the example described it is around the angle φ-0.5 ° twisted. This fact must be taken into account when preselecting the angle φ in the angle input element 10.

The mentioned angle value of 121 ° of the angle input member 11 is only to be understood as an example depends on the desired fineness of the stepped curve of the analog signals at the output of the Sample and hold circuits 19 to 24. Of course the angle value of the angle input member 11 can also be smaller than 120 °, so that the voltage and Turn current triangles clockwise. In a binary 8-bit system, this angle value is e.g. B. by the binary number 01010101 is shown, which corresponds to an angle of - «119.5".

In the example shown, the digital / analog converter 18 has a reference _voltage input 39 which is connected to a reference voltage source U rc \. The analog signal at the output of the digital / analog converter 18 is proportional to the reference voltage, so that the amplitude values of all output voltages and output currents can be influenced jointly by changing the reference voltage. If the reference voltage input 39 can be connected to several adjustable reference voltage sources via a multiple switch controlled by the clock distributor 38, the amplitude values of the output voltages Ur, Us and Ut and each of the output currents Ir, Is and It can be set independently of one another by changing the reference voltages. Automatic readjustment of the output signals based on their effective values is possible if the voltage amplifiers 31, 33 and 35 and the current amplifiers 32, 34 and 36 are connected to an effective value measuring device whose output signal controls the reference voltage sources. Automatic readjustment of the phase angle is also possible by connecting a voltage amplifier 31, 33, 35 and a current amplifier 32, 34, 36 of the same phase to a phase angle measuring device whose output signal controls the angle input element 10.

In FIG. 3 have the same reference numerals as in FIG F i g. 1 towards equal parts. Instead of the sample-and-hold circuits 19 to 24 (FIG. 1), the signal generator according to FIG. 3 digital read-write memories (RAM) 39 to 44, the memory inputs of which are connected to the Function generator 17 and their clock inputs are connected to the clock distributor 38. Each of the read / write memories 39 to 44 are followed by a digital / analog converter 45 to 50, the output of which is closed one of the low-pass filters 25-30 leads.

The signal generator according to FIG. 3 is in comparison with that according to FIG. 1 a little more elaborate, draws however, has the advantage that the operating speed of the digital / analog converters 45 to 50 must be less than that of the digital / analog converter 18 (after the circuit of FIG. 1).

The digital / analog converters 45 to 50 advantageously have reference voltage inputs for connecting a reference voltage with which the amplitude values of the output voltages and output currents can be set or regulated. Furthermore, it is advantageous to connect an adder upstream of the function generator 17, which allows an angle signal to be added to the phase step signal Ph in order to additionally influence or readjust the phase angle of the output voltages and output currents.

The signal generators described are advantageously used as three-phase voltage and three-phase current generators used to calibrate electricity meters.

For this purpose 2 sheets of drawings

Claims (7)

Patent claims: 1. Signal generator for generating sinusoidal output signals with predetermined mutual Phase position, with a number generator controlled by a clock, which consists of angle input members, a switch controlled by the clock, an adder, at the first input of which the Switch is connected, and there is an accumulator and cyclically assigned to each of the output signals, outputs binary-coded phase step signals to a function generator, which is provided by the function generator into binary coded instantaneous value signals and from at least one digital / analog converter into one Output signal can be converted at which each output signal is sent to the digital / analog converter or at the. Function generator connected memory is assigned, one connected to the clock generator Clock distributor clocks the memory cyclically and the output of the accumulator (16) to one second input of the adder is connected, characterized in that the angle input members (10; 11) connected to the first input (13) of the adder (14) via the switch (12) are that the switch (12) the angle input members (10; 11) alternating with the first input (13) of the adder (14) connects and that the output of the adder (14) with the input of the accumulator (16) clocked by the clock generator (37) is connected. 2. Signal generator according to claim 1, in which each output signal is assigned a memory connected to the digital / analog converter, characterized in that the memories (19 to 24) are sample-and-hold circuits and that the digital / analog converter ( 18) is assigned to all output signals (Ur; Ir; Us; Is; Ur, / ^ in common. 3. Signal generator according to claim 2, characterized in that a reference voltage input (39) of the digital / analog converter (18) via a multiple switch controlled by the clock distributor (38) can be connected to at least two adjustable reference voltage sources. 4. Signal generator according to one of claims 1 to 3, characterized by three, each with a low-pass filter (25; 27; 29) to one of the memories (19; 21; 23) or one of the digital / analog converters (45; 47; 49) connected voltage amplifiers (31; 33; 35) for generating a voltage triangle and through three each via a low-pass filter (26; 28; 30) to one of the memories (20; 22; 24) or one of the digital / analog converters (46; 48; 50) connected current amplifiers (32; 34; 36) for generating a current triangle. 5. Signal generator according to claim 3 or 4, characterized in that the voltage amplifier (31; 33; 35) and the current amplifier (32; 34; 36) are connected to an effective value measuring device whose Output signal controls the reference voltage sources. 6. Signal generator according to claim 4, characterized in that in each case a voltage amplifier (31; 33; 35) and a current amplifier (32; 34; 36) are connected to a phase angle measuring device whose Output signal controls the angle input member (10). 7. Use of the signal generator according to one of claims 1 to 6 as a three-phase voltage and Three-phase generator for calibrating electricity meters.