DE3523429A1 - Integrating electronic multiplying circuit - Google Patents

Abstract

To multiply analog quantities A and B, the quantity A is supplied to an analog/digital converter (2), the numerical output values of which are input into an accumulator (8). The analog quantity B is converted by means of an analog frequency converter (4) into a switching signal which triggers with the frequencies proportional to the quantity B an addition or subtraction of the numerical values input into the accumulator. The information on the sign of the product of the analog quantities A and B is obtained by means of comparators (5) and (6) and of a gate (7). The content of the accumulator (8) corresponds to the time integral of the product of the analog quantities A and B. <IMAGE>

Description

The invention relates to an integrating electronic multiplier circuit for multiplying analog variables A and B , each with a converter that outputs digitally processed signals for each analog variable and with an accumulator for storing the time-integral product of the analog variables with the correct sign.

The analog input variables to be multiplied can largely be any physical quantities, which if necessary after conversion into an electrical signal in the known Circuits are each fed to an analog-to-digital converter. At the output of these converters, the input variables are proportional digital values supplied, which are used to create a product Microprocessor or a digital multiplier circuit supplied will. For multiplication of input variables that change over time is a multiple sampling of instantaneous values required, so that it is a in the known circuits discrete procedure. A disadvantage of the aforementioned Circuits that are comparatively expensive for product formation Components are required.

The invention has for its object a multiplier circuit of the type mentioned in the introduction so that the Multiplication with simpler and cheaper components possible is.

The object is characterized according to the invention in that one of the converters as analog-to-digital converter is formed, and A is connected to the converter constants C ₁ to the accumulator to supply the proportional to the analog quantity A number values Z = C ₁ *, is formed while the other converters as an analog-frequency converter whose output signal with the analog quantity B proportional frequencies f _o = 1 / T _o = C _{2 *} B with the converter constants C ₂ during the integration time T as a switching signal for adding the Numerical values Z are fed to the accumulator, the content of which corresponds to the numerical value K = T *.

In the solution according to the invention, an analog-to-digital converter is replaced by an analog-to-frequency converter compared to the known circuit. A particular advantage of the new circuit is that neither a microprocessor nor a digital multiplier circuit is required for the multiplication. The analog input quantities are formed by adding or subtracting the numerical values in the accumulator. This process can be carried out faster and with less programming or circuitry complexity than a multiplication. In addition, an analog-to-frequency converter is cheaper than an analog-to-digital converter that is equivalent in terms of accuracy. Because of the largely digital signal processing in the new circuit, only a small number of setting elements are required. The circuit according to the invention can thus be integrated particularly easily on a semiconductor chip. If A and / or B are time-dependent quantities, the corresponding integrals must be taken into account.

An expedient embodiment results when the analog-to-digital converter and the analog-frequency converter each Bipolar-unipolar converter is connected upstream, and if the analog Variables for determining the sign and the phase position are each fed to a comparator, the outputs of which the inputs of an exclusive-OR gate, which is connected on the output side to the accumulator. Here unipolar signals are fed to the converter and the converter. The information about the sign of the two signals will be  obtained by means of the comparators, the output signals of which Gates are fed to the accumulator.

A simple embodiment results when the bipolar-unipolar converter is designed as a rectifier. Thus receives one simple circuit to generate the unipolar analog Signals for the inputs of the converter and the converter.

An alternative embodiment results if the unipolar signal for the analog-digital converter by adding a constant offset of known size to the input signal becomes and by digital subtraction one accordingly large number C from the output value of the analog-digital converter correct ratio of input to output size restored becomes. The value thus created by invoice also includes the information about the sign of the input signal, so that the comparator becomes dispensable.

A particularly advantageous embodiment of the circuit is characterized by a microprocessor, of which an interrupt input with the output of the analog-frequency converter connected is. It is advantageous that the processor is not works in real time mode, but operated in interrupt mode becomes. This enables the processor during the integration and so that the multiplication process can perform further functions. Here the accumulator is not a discrete digital circuit, but realized by the microprocessor program.

A further embodiment results if, in order to form a digital electricity counter with the electric current and the voltage as analog variables A and B to be measured, the accumulator is followed by a pulse counter for registering and displaying the pulses generated when the accumulator overflows. The content of the accumulator is proportional to the measured energy. When the accumulator content reaches a predetermined number, it emits a pulse so that an overflow frequency can be defined. The functionality of the digital electricity counter is obtained by summing the pulses in the pulse counter.

The invention is illustrated schematically in the drawing illustrated embodiment explained below.

Show it:

Fig. 1: a block diagram of the electronic multiplier circuit in the embodiment as a digital electricity meter,

Fig. 2 is a circuit gem. Fig. 1 with an additional subtractor.

In the block diagram according to FIG. 1, the analog input variables A and B , which can be time-variable, are derived from the voltage to be measured and the current to be measured. Analog variable A , which is bipolar as an alternating variable, is converted into a unipolar variable by means of a bipolar-unipolar converter 1 . This unipolar signal is available at the input of an analog-to-digital converter 2 , which on the output side supplies numerical values Z = C ₁ * A proportional to the input variable A , where C _{1 is} the converter constant of the analog-to-digital converter 2 . The second analog variable B is also converted via a further bipolar-unipolar converter 3 and is passed to an analog-frequency converter 4 , the output frequencies f _{O of which} are proportional to the analog variable B. The equation f _o = C ₂ * B applies here, with the converter constant C ₂ .

Comparators 5 and 6 , the output signals of which are passed to the input of an exclusive-OR gate 7 , are used to determine the sign and phase position of the analog variables A and B. The information about the sign of the product of the measured variables is thus transmitted to an accumulator 8 .

The numerical values Z generated by the analog-digital converter 2 are also input into the accumulator 8 . Furthermore, the signals output by the analog-digital converter 4 are supplied to the accumulator 8 as switching signals. As soon as signal edges with the same sign appear at the output of the analog-to-frequency converter, the numerical value Z present at the output of the analog-to-digital converter is added or subtracted from the content of the accumulator 8 , taking into account the information output at the exclusive-OR gate 7 .

For the simple case that the measured variables A and B are constant and their product has a positive sign, the following applies:

If the content of the accumulator after the time T is the number K , then the number Z T / T _{o has been} added, so that the following equation applies: K / T = Z / T _o = Z * f ₀ = C ₁ * C ₂ * A * B

If the size A corresponds to the voltage and the size B corresponds to the current, the content of the accumulator is proportional to the energy. If the accumulator is constructed in such a way that it emits a pulse each time the contents of the accumulator reach a predetermined number K , then the following applies to the overflow frequency thus generated: f = 1 / T = C ₁ * C ₂ * A * B / K

The digital electricity counter is obtained by summing the pulses with a counter 9 connected downstream of the accumulator 8 . The higher the maximum output frequency of the analog-to-frequency converter and the higher the resolution of the analog-to-digital converter, the lower its systematic error, which can also be improved by adding a superposition signal which corresponds to the input signal of the analog-to-digital Converter 2 is superimposed.

Defined properties of the superposition signal ensure that the mean value of the quantization error of the analog-digital converter tends towards zero with increasing integration time. The superposition signal takes on all possible instantaneous values during the integration time with the same frequency within the interval (- S , + S ). Once an assignment has occurred, the instantaneous value of the signal derived from the measured variable and the instantaneous value of the superposition signal must not be repeated during the integration time. S is a value that is greater than or equal to half a quantization unit of the digitizing analog-to-digital converter.

The superposition signal can be, for example, noise, the instantaneous values of which all values pass through the same interval with the same frequency. Furthermore, the superposition signal can be a periodic function with the amplitude S , the instantaneous values being linearly dependent on time.

The aforementioned measure can be used, for example, with an 8-bit converter a measurement uncertainty can be achieved that otherwise only through higher resolution and therefore more expensive implementers or through complex and expensive devices for area switching can be achieved.

The circuit shown in FIG. 2 differs from the arrangement in FIG. 1 by an additional subtractor 10 and by the absence of the comparator 5 and the gate 7 . Here, the biopolar-unipolar converter 1 is designed as an adder, with the aid of which a constant unipolar offset signal is added to the analog signal A to be measured. The amount of the offset signal should be chosen so that the sum signal is unipolar at all times. The error generated in this way is corrected by appropriate subtraction of a constant C in the subtractor 10 . Thus, the comparator 5 present in FIG. 1 and the gate 7 are not required in the circuit according to FIG. 2.

Claims (9)

1.Integrating electronic multiplier circuit for multiplying analog variables A and B , each with a converter that outputs digitally processed signals, for each analog variable and with an accumulator for storing the time-integral product of the analog variables with the correct sign, characterized in that one of the converters as Analog-digital converter ( 2 ) is formed and is connected to the accumulator ( 8 ) for feeding the analog variable A proportional numerical values Z = C ₁ * A with the converter constant C ₁ , while the other converter as an analog frequency converter (4) is formed, whose output signal is proportional to the analog quantity B frequencies f _o = 1 / T _o = C ₂ * B with the converter constants C ₂ during the integration time T as a switching signal for addition of the numerical values Z to the accumulator (8 ) is supplied, the content of which corresponds to the numerical value K = T * 1 / T _o * Z. 2. Circuit according to claim 1, characterized in that the analog-to-digital converter ( 2 ) and the analog-to-frequency converter ( 4 ) each have a bipolar-unipolar converter ( 1 , 3 ) connected upstream, and that the analog variables To determine the sign and the phase position, a comparator ( 5 , 6 ) is supplied, the outputs of which are connected to the inputs of an exclusive-OR gate ( 7 ) which is connected on the output side to the accumulator ( 8 ). 3. A circuit according to claim 2, characterized in that the bipolar-unipolar converter ( 1 , 3 ) is designed as a rectifier. 4. A circuit according to claim 2, characterized in that the unipolar signal for the analog-to-digital converter ( 2 ) is generated by adding a constant offset of known size to the input signal and by digitally subtracting a correspondingly large number C from the output value of the analog Digital converter ( 2 ) the correct ratio of input to output size is restored. 5. Circuit according to one of the preceding claims, characterized by a microprocessor, of which an interrupt input with the output of the analog-frequency converter connected is. 6. Circuit according to one of the preceding claims, characterized in that to form a digital electricity meter with the electric current and voltage as the analog quantities A and B to be measured, the accumulator ( 8 ) has a pulse counter ( 9 ) for registration and display of the overflow the accumulator ( 8 ) generated pulses is connected downstream. 7. Circuit according to one of the preceding claims, characterized in that in order to achieve a mean quantization error of the analog-digital converter ( 2 ) which tends towards zero with increasing integration time, a signal is added to the analog variable A which is within the interval (- S , + S ) assumes all possible instantaneous values during the integration time with the same frequency, S being a value greater than or equal to half a quantization level of the analog-digital converter ( 2 ). 8. A circuit according to claim 7, characterized in that the signal added to the analog variable A is uniformly distributed noise with the maximum value S. 9. A circuit according to claim 7, characterized in that the signal added to the analog variable A is a periodic function with the amplitude S , the instantaneous values of which depend linearly on time, and assignments of the instantaneous value of the measured variable A and instantaneous value of the added signal during the Do not repeat the integration time.