KR0152344B1 - Pwm signal generating circuit - Google Patents

Abstract

1. TECHNICAL FIELD OF THE INVENTION

MICOM's interface circuit

2. Technical problem to be solved by the invention

The present invention provides a pulse width modulated signal generation circuit that converts data processed by a microcomputer into precise data regardless of the period of a system clock of the microcomputer and transmits the data to a peripheral circuit.

3. Summary of Solution to Invention

Comprising a first register and a second register, among the data processed by the microcomputer, predetermined upper bit data is stored in the first register, and the remaining lower bit data except the upper bit data are stored in the second register. Register means; A counter for generating counting data in synchronization with the system clock of the microcomputer and generating a set signal when the counting operation is completed; Comparison means for comparing the higher bit data with the counting data and generating a match signal when they match; Digital / analog conversion means for converting the lower bit data into analog data; Triangular wave generating means for generating triangular waves in synchronization with the system clock; Voltage comparing means for comparing a level of said triangular wave with an analog signal to generate a reset signal; And pulse width modulation signal control means for receiving the set signal, the coincidence signal, and the reset signal to generate a pulse width modulation control signal.

4. Important uses of the invention

Used for microcomputer interface circuit.

Description

Pulse width modulated signal generator

1 is a block diagram of a conventional pulse width modulated signal generating circuit.

2A-2F are operational waveform diagrams according to a conventional circuit.

3 is a configuration diagram of a pulse width modulated signal generating circuit according to the present invention.

4A-4H are operational waveform diagrams according to the present invention.

* Explanation of symbols for main parts of the drawings

120: register section 140: first register

160: second register 180: digital / analog converter

200: triangle wave generator 220: voltage comparison unit

240: pulse width modulated signal controller 260: 12-bit counter

280: 12-bit comparison unit 300: reset signal generator

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an interface circuit of a microcomputer, and more particularly to a pulse width modulated signal generating circuit for an interface for converting a large amount of data processed inside a microcomputer into precise data for a limited time and providing the peripheral circuit.

The interface circuit is used to transfer the processed data from the microcomputer, which is used for driving a motor or other various control purposes, to the microcomputer peripheral circuit. As the interface circuit, a digital / analog converter (hereinafter referred to as D / A) and a pulse width modulated signal controller are mainly used.

The D / A transfers the data processed by the microcomputer to the peripheral circuit without loss regardless of the microcomputer system cycle. However, when noise is introduced, the signal / noise ratio (hereinafter referred to as S / N ratio) is degraded, which causes a problem in that the data cannot be normally transmitted to the peripheral circuit. In addition, the size of D / A should be increased in response to the increase of data processed in microcomputer. However, the D / A has a disadvantage that the price is expensive. Therefore, in general, a pulse width modulated signal controller is adopted in configuring an interface circuit.

In the pulse width modulated signal generating circuit employing the pulse width modulated signal controller, as shown in FIG. 1 of the accompanying drawings, the 12-bit data processed inside the microcomputer is shown in FIG. 2A via the internal bus 10. It is stored in the 12-bit register 20 in synchronization with the falling edge of the system clock CLK.

12 bit counter 40 is synchronized with the falling edge of the system clock CLK and is shown in FIG. 2B when the counting operation is completed again from 0 to 4095 as shown in FIG. 2B. The same set signal S is generated. In addition, the 12-bit counter 40 generates 12-bit counting data by the counting operation.

The 12-bit comparator 30 inputs the 12-bit counting data and 12-bit data, compares each falling edge of the system clock CLK, and if it matches, generates a reset signal R as shown in FIG. 2D. do.

The pulse width modulated signal controller 60 generates a pulse width modulated signal PWM set in the set signal S as shown in FIG. 2F, and the pulse width modulated signal in response to the reset signal R. FIG. Reset (PWM).

As described above, the pulse width modulated signal controller 60 has an advantage of transferring the data processed in the microcomputer to the peripheral circuit without deterioration of the S / N ratio. When the data processed by the microcomputer increases, the pulse width modulation signal period of the pulse width modulation signal controller is also limited due to the limited system clock cycle of the microcomputer, so that the data processed by the microcomputer is not converted into a precise data in a short time to the peripheral circuit. The relation between the system clock cycle and the pulse width modulation signal cycle of the microcomputer is as follows.

Period of pulse width modulated signal = system clock period x2 ^{Number of bits of data processed by the microcomputer}

In general, the system clock cycle of the microcomputer is set to a constant value.

Therefore, an object of the present invention is to use the advantages of the above-described D / A and pulse width modulation signal controller to convert the data processed in the microcomputer to precise data regardless of the limited microcomputer system clock period to provide to the peripheral circuit pulse width modulation It is to provide a signal generating circuit.

A pulse width modulation signal generation circuit for achieving the above object comprises a first register for storing modified upper bit data among the data processed by the microcomputer and a second register for storing the remaining lower bit data except the upper bit data. When the counting operation is performed at each falling edge of the system clock of the microcomputer and counting data is generated, and a counter that generates a set signal when the counting operation is completed, the upper bit data and the counting data are compared and matched. A comparator for generating a coincidence signal, a reset signal generator for inputting the lower bit data to generate a reset signal, and a pulse width for generating a pulse width modulation signal by inputting the coincidence signal and the reset signal to the set signal; Characterized in that the modulation signal controller.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

3 is a configuration diagram of a pulse width modulated signal generating circuit for a microcomputer interface according to the present invention.

The 16-bit data processed inside the microcomputer is input to the 16-bit register unit 120 through the internal bus 100.

The upper 12 bit data (bit 15-bit 4) of the 16 bit data is stored in the first register 140, and the lower 4 bit data (bit 3-bit 0) is stored in the second register 160.

The 12-bit counter 260 performs 0 to 4095 counting operations as shown in FIG. 4B for each falling edge of the system clock CLK of the microcomputer as shown in FIG. 4A. At this time, the 12-bit counter 260 generates 12-bit counting data by the counting operation, and generates the set signal S as shown in FIG. 4D when the counting operation is completed.

The 12-bit comparator 280 compares the 12-bit counting data with the upper 12-bit data. At this time, the 12-bit comparator 280 generates a matching signal C as shown in FIG. 4E when the 12-bit counting data and the upper 12-bit data match.

The lower 4 bit data is converted into analog data by the digital / analog converter 180.

The triangular wave generator 200 generates a triangular wave in synchronization with the falling edge of the system clock CLK.

The voltage comparator 220 inputs the analog data to the inverting terminal and the triangular wave to the non-inverting terminal. The voltage comparator 220 inputs the level of the triangular wave and the level of analog data as shown in FIG. 4F. Are compared to generate the reset signal R as shown in FIG. 4G.

Thus, the pulse width modulated signal controller 240 generates the pulse width modulated signal PWM set in the set signal S as shown in FIG. 4H, and the time point T at which the coincidence signal C is generated. The pulse width modulated signal PWM which is reset by the first rising edge B after the (K) time point of the reset signal R corresponding to is generated.

As described above, the 16-bit data is transferred to the peripheral circuit regardless of the limited system clock cycle of the microcomputer. And if you want to transfer more data to the peripheral circuit, you can increase the storage capacity of the second register. That is, the number of D / As may increase as the storage capacity of the second register increases.

As described above, the present invention has an advantage of converting a large amount of data processed by the microcomputer into precise data regardless of the limited system clock period and transferring the data to the peripheral circuit.

Claims (3)

In the interface circuit for transferring the data processed by the microcomputer to the peripheral circuit regardless of the system clock cycle, Comprising a first register and a second register, among the data processed by the microcomputer, predetermined upper bit data is stored in the first register, and the remaining lower bit data except the upper bit data is stored in the second register. Register means; A counter for generating counting data in synchronization with the system clock of the microcomputer and generating a set signal when the counting operation is completed; Comparison means for comparing the higher bit data with the counting data and generating a match signal when the same is matched; Reset signal generation means for inputting the lower bit data to generate a reset signal; And a pulse width modulation signal control means for inputting the set signal, the coincidence signal, and the reset signal to generate a pulse width modulation control signal. 2. The apparatus according to claim 1, wherein said reset signal generating means comprises: digital / analog conversion means for converting said low-bit data into analog data; Triangular wave generating means for generating triangular waves in synchronization with the falling edge of the system clock; And a voltage comparing means for comparing the level of the triangle wave and the analog signal to generate a reset signal. The pulse width modulation signal control means generates a pulse width modulation signal set by the set signal, and the pulse is generated by the rising edge of the first reset signal after the coincidence signal is generated. A pulse width modulated signal generator circuit for resetting and outputting a width modulated signal.