KR940002101B1 - Alternate current generating system - Google Patents

Abstract

The apparatus has a switched capacitor filter employing an exact cut off frequency and a digital synthesis function. It comprises the following: a sinusoidal generator (1) for generating a constant frequency; a frequency divider (2); a PROM for outputting the stored data; a D/A converter; a current/voltage converter (8); a switching capacitor filter for periodically switching and eliminating the switching noise; a level control for controlling the magnitude of voltage; a multiplexer (11).

Description

AC voltage generator

1 is a configuration diagram of a conventional AC voltage generation system.

2 is a configuration diagram of an AC voltage generating system of the present invention.

3 is an output waveform diagram of each part of FIG. 2;

* Explanation of symbols for main parts of the drawings

1: Sine wave generator 2: Frequency divider unit

3: Frequency selector 4: Binary counter

5: P-ROM 6: Digital / Analog Converter

7: final address detection unit 8: current / voltage conversion unit

9: switch capacitor filter unit 10: level control unit

The present invention relates to an AC voltage generator for measuring an AC element in an insert kit test or a function circuit tester. In particular, the frequency setting control and the sine wave level using a digital synthesized sine wave generator that is easy to generate and control a stable sine wave. The present invention relates to an AC voltage generator for facilitating control and removing noise generated during AC voltage interruption and measurement of other measurement objects.

Conventional AC voltage generating system is a voltage input according to the selection of the frequency selection switch (SW1-SWn), as shown in Figure 1 attached to the oscillation in the Wien Bridge (Af1-Afn), respectively A frequency setting switch LC1-LCn for outputting a different frequency and amplifying the selected frequency by the amplifier OP1 to a predetermined level and feeding the frequency back from the bin bridge oscillator 1 and the frequency generated from the bin bridge oscillator 1; A level controller (2) for selecting and transmitting the selected frequency through the attenuator (2a), a power amplifier (3) for amplifying and outputting a signal of a voltage selected and output from the level controller (2), It is composed of a switch (SW1) for switching the power AC voltage source output from the power amplifier 3 and applied to the measurement object through the output terminal (out).

In the conventional AC voltage generation system configured as described above, in order to select a frequency suitable for the measurement object, when one of the select switches SW1-SWn configured in the empty bridge oscillator 1 is turned on, the corresponding AC voltage generation system is applicable. The empty bridge Af1-Afn oscillates with respect to the voltage fed back from the amplifier OP1 to output different frequencies, and the oscillation of the empty bridge Af1-Afn selected by the selection switches SW1-SWn. The frequency is amplified to a predetermined level by the amplifier OP1 and fed back to the empty bridge Af1-Afn and applied to the level controller 2. At this time, the level setting switch LC1-LCn of the level control unit 2 sets the signal amplitude applied to the measurement object. One of the level setting switches LC1-LCn is turned on to select the amplitude of the AC voltage source. Then, the power amplifier 3 is applied to the power amplifier 3 through the attenuator 2a. The power amplifier 3 amplifies the signal of the voltage selected and output from the level controller 2 to switch SW and the output terminal ( out), the measurement object is applied.

However, in the conventional AC voltage generating system, the frequency is not stabilized because the empty bridge element of the empty bridge oscillation unit is affected by the environmental conditions, and noise is generated by selecting the frequency, signal interruption, and level regardless of the position of the signal amplitude. There was a problem that not only occurs, but also affects when measuring other measuring objects.

SUMMARY OF THE INVENTION In view of the above-described problems, the present invention uses a digital capacitor to easily generate and control a stable sinusoidal wave and an accurate cutoff frequency by using a switch capacitor filter to accurately filter the frequency setting and amplitude to control sinusoidal level control. In order to facilitate, and to eliminate the noise generated when the AC voltage source is interrupted and the measurement of the other measuring object was created an AC voltage generator, will be described in detail below with reference to the accompanying drawings of the present invention.

2 is a configuration diagram of an AC voltage generation system according to the present invention. As shown in this figure, a sinusoidal wave generator 1 for generating a constant sinusoidal frequency and a frequency divider for splitting a frequency generated from the sinusoidal wave generator 1 are shown in FIG. A unit 2, a frequency selector 3 for selecting a frequency divided and output from the frequency divider 2, and a binary counter unit 4 for counting a frequency selected from the frequency selector 3 And a final address detection unit 7 which detects the final value of the binary counter unit 4 and applies the strobe signal STRB to the frequency selector 3, and outputs in parallel from the binary counter unit 4. A P-ROM 5 for storing the data to be stored and outputting the stored data, and a digital / analog converter 6 for converting the sine wave data output from the P-ROM 5 into an analog signal and outputting it as a current signal. ) And the digital / ah A current / voltage converter 8 for converting the current signal output from the log converter 6 into a voltage, and a switch for periodically switching and filtering the output voltage of the current / voltage converter 8 to remove noise. A level control unit comprising a capacitor filter unit 9 and a variable resistor VR1-VR8 and a resistor r1-r8 for outputting different voltages by adjusting the amplitude of the voltage output from the switch capacitor filter unit 9. (10), a multiplexer (11) which selects and outputs a voltage among the voltages output from the level controller (9), and amplifies a signal of a voltage selected from the multiplexer (11) to output an AC voltage source (out) It consists of a power amplifier 12 to be applied to the measurement object through the). In the above description, the final address detection unit 7 includes a NAND gate NAND for digitizing the output data of the binary counter unit 4, and an output signal of the NAND gate NAND as a clock to the input terminal D. The flip-flop F / F for synchronizing the measurement time with the input measurement gate signal GT and the output signal and the measurement gate signal GT of the flip-flop F / F are ORed together to generate the strobe signal STRB. In the drawing, reference numerals R1-R4 denote resistors connected to the switch capacitor filter unit 9, and R5 denotes resistors connected to the output terminal of the multiplexer 11.

If described in detail with reference to Figures 2 to 3 attached to the operation and effects of the present invention configured as described above are as follows.

First, the sinusoidal wave generator 1 oscillates at a predetermined frequency f, that is, at a sinusoidal wave frequency f _s and f = 2 ^{n + 1} * k. Where n + 1 is the number of address bits of the P-ROM 5, and k is the maximum frequency division number of the frequency divider unit 2. FIG. As an example, if the address of the P-ROM 5 is 8 bits (n + 1 = 8 bits), and a sinusoidal frequency f _a is desired from 10 Hz to 100 Hz, k at the highest k is "1", 100 10 ㎐ at ㎐ is 100 times, so k at the lowest is 100. At the highest, that is, when k = 1, the sinusoidal wave oscillator 1 oscillates at f = 2 ⁸ * 1 * f _s to generate a frequency. Therefore, the frequency f generated from the sinusoidal wave generator 1 is 2.56 MHz, and the frequency divider unit 2 divides the frequency f / 100 to output a frequency of 25 kHz to the frequency selector 3. The selector 3 selects each frequency divided by the frequency divider 2 and applies it to the binary counter 4. Accordingly, the binary counter unit 4 binary-counts the input frequency and stores the binary frequency in the P-ROM 5, and the sine wave data stored in the P-ROM 4 is a digital / analog converter 6. The analog signal is converted into an analog signal and output as a current signal. The current / voltage converter 8 converts the input current signal into a voltage and applies it to the switch capacitor filter unit 9. That is, the sinusoidal data f ( _x ) stored in the P-ROM 4 is obtained by the following equation.

f ( _x ) = (2 ^n-1 ) {1 + Sin (2 ^{n /} 2π _{* X} )} + 0.5, wherein the binary counter portion 4 converts only the integer part to binary number, Will be stored in (5). Since the number of data is 2 ^n-1 , the number of steps of the full scale in the digital / analog converter 6 is 2 ^{n + 1} . Based on the above formula, the final address data of the P-ROM 5 becomes OV when converted into an analog signal through the digital / analog converter 6, and thus the NAND gate configured in the final address detection unit 7. When the final value of the binary counter unit 4 is 1 1 1 1-1 1 1 as shown in FIG. 3a, the output of the binary counter unit 4 outputs a low signal as shown in FIG. 3b. Therefore, the NAND gate NAND generates a low signal, that is, OV, every one period of the sine wave, and this signal is inputted to the clock terminal CLK of the flip-flop F / F and flip-flop as shown in FIG. 3C. The measurement gate signal GT input to the input terminal D of F / F is synchronized with the measurement time, and the NOR gate NOR of the final address detection unit 7 is a high signal when both inputs are low signals. The output terminal Q of the flip-flop F / F maintains a high signal as shown in FIG. 3d until the final address even when the measurement gate signal GT is input as a low signal. Inverted, the output of the NOA gate NOR becomes a high signal as shown in FIG. 3E in synchronization with zero crossing. The high signal output from the NOR gate NOR is a strobe signal STRB that stops the operation of the frequency selector 3 and latches it at the final value of the binary counter unit 4. At this time, the output value of the analog signal converted by the digital / analog converter 6 becomes OV. Accordingly, the initial value and the final value of the sine wave at the time of measuring the measurement object are maintained at OV. The current signal output from the digital / analog converter 6 is converted into a voltage through the current / voltage converter 8, and the converted voltage is periodically switched through the switch capacitor filter 9 and noise is generated. It is removed and output.

That is, the switch capacitor filter unit 9 is used as the low pass filter unit, and is a fourth order filter. It is a variable filter of two secondary orders in one element of Winrae. When two are used in series, it can be used as a 4th order filter. When the S terminal of the switch capacitor filter unit 9 is connected to + V, the switch capacitor is operated in the second order. Here, + V _A and -V _A are analog power supplies, + V _D and -V _D are digital power supplies, and the hold terminal (HOLD) shows the proportional relationship between the frequency clock terminal (F _CLK ) and the cutoff frequency. 1 = 100 = f ₀ : f _CLK . Accordingly, since the clock of the switch capacitor filter unit 9 is proportionally used from the frequency selector 3 according to the frequency of the sine wave, F _{0 is} also easy according to the frequency selection. The output terminal LP1 of the first low pass filter is connected to the input terminal S2 of the second low pass filter, that is, two filters are connected in series. The amplitude of the AC voltage output from the output terminal LP2 of the second low pass filter is adjusted through each of the variable resistors VR1-VR8 configured in the level controller 10 and then multiplexer 11 through the resistors r1-r8. Input to the multiplexer 11 selects and outputs each AC voltage input through the level controller 10, and the power amplifier 12 amplifies the signal of the required AC voltage to output the output terminal (out). It is applied to the measuring object through). Here, the AC voltage amplitude of the output terminal out becomes, for example, the output amplitude = R5 / VR1 + r1 + R5 * (output amplitude of the switch capacitor filter unit) when the variable resistor VR1 is viewed.

As described in detail above, the present invention utilizes a digital synthesized sinusoidal wave generator that is easy to generate and control a stable sinusoidal wave and a switch capacitor filter unit having an accurate cutoff frequency to precisely control the frequency setting and filter the amplitude to facilitate sinusoidal wave level control. In addition to detecting the zero cross pointer of the sine wave and switching, the initial, final, and switching noises can be removed from the measurement, resulting in faster and more accurate measurements.

Claims (3)

A sinusoidal wave generator 1 for generating a constant sinusoidal frequency in an AC voltage generator that amplifies a frequency of the selected oscillator through a power amplifier 12 and applies an alternating voltage to a measurement object, and the sinusoidal wave generator 1 A frequency divider unit 2 for dividing a frequency generated from the < RTI ID = 0.0 > 1) < / RTI > and a frequency selector 3 for selecting a frequency divided by the frequency divider unit 2, and a frequency selected from the frequency selector 3. A binary counter unit 4 for counting, a final address detection unit 7 for detecting the final value of the binary counter unit 4, and applying a strobe signal STRB to the frequency selector 3, and 2 A P-ROM 5 for storing the data output in parallel from the GIN counter 4 and outputting the stored data, and converting the sinusoidal data of the P-ROM 5 into an analog signal and outputting the analog signal as a current signal. Digital / Analog Converter (6) And the current / voltage converter 8 for converting the current signal of the digital / analog converter 6 into a voltage and the output voltage of the current / voltage converter 8 periodically to filter and noise. A voltage is selected from the switch capacitor filter unit 9 to be removed, the level control unit 10 for controlling the amplitude of the voltage output from the switch capacitor filter unit 9, and the output voltage of the level control unit 9 AC voltage generator, characterized in that composed of a multiplexer (11) applied to the measuring object through the amplifier (12). 2. The terminal of claim 1, wherein the final address detection unit 7 uses a NAND gate NAND for digitizing the output data of the binary counter unit 4, and an output terminal of the NAND gate NAND as a clock. (D) A flip-flop (F / F) for synchronizing the measurement gate signal (GT) inputted with the measurement time, the output signal and the measurement gate signal (GT) of the flip-flop (F / F) by the logical sum of the strobe signal An alternating current voltage generator comprising: a no-gate NOR for generating (STRB). The method of claim 1, wherein the level control unit 10 controls the amplitude of the AC voltage output from the switch capacitor filter unit 9 to the variable resistors VR1-VR8 and resistors r1-r8 connected in parallel, respectively. AC voltage generator, characterized in that.