KR20030037477A - Oscillating apparatus for micom - Google Patents

Abstract

PURPOSE: An oscillation device of a micro computer is provided to operate a plurality of micro computers and reduce a fabricating cost by using only one crystal oscillator. CONSTITUTION: The first micro computer(113) is connected with an output side of a crystal oscillation portion(111). A waveform shaping portion(115) is connected with an output side of the first micro computer(113). The second micro computer(117) is connected with an output side of the waveform shaping portion(115). The crystal oscillation portion(111) is oscillated according to a reference frequency signal in order to generate an oscillation frequency signal of a sine wave. The crystal oscillation portion(111) is formed with the first capacitor(C1), a crystal oscillator(X1), a resistance(R1), and the second capacitor(C2).

Description

Oscillator of MICOM {OSCILLATING APPARATUS FOR MICOM}

The present invention relates to a microcomputer oscillator, and more particularly, to a microcomputer oscillator for operating a plurality of microcomputers using one crystal oscillator.

First, a microcomputer refers to a microcomputer, and refers to a microcomputer system centered on a CPU microprocessor configured as one or several LSIs. Next, the microcomputer's structure is usually composed of CPU, memory (ROM, RAM), input / output interface circuit (I / O section), input / output device, auxiliary memory device and control circuit, and they are called data (BUS). It is assembled by connecting with line and control signal line.

In order to operate the microcomputer M1, an oscillation circuit including a crystal oscillator 11, capacitors 13 and 15, and a resistor 17 is mounted outside the microcomputer M as shown in FIG. 1. .

That is, the oscillating signal S1 of the capacitor 11 oscillating in response to the reference frequency signal S2 and the crystal oscillator 11 is provided to the microcomputer M1, and the sinusoidal oscillating signal S1 is provided. The microcomputer M1 receives the input data provided from the outside according to the oscillation signal S1 of the sinusoidal wave and performs calculation and control operations, and generates the reference frequency signal S2 of the square wave to generate the resistance 17 and It is provided to the crystal oscillator 11 through a capacitor 15. Therefore, the crystal oscillator 11 is oscillated by the reference frequency signal S2 of this square wave.

However, since the conventional microcomputer oscillator circuit is provided for each microcomputer, when a plurality of microcomputers are installed in one IC chip, the number of microcomputers and the number of oscillator circuits are settled. The number of these microcomputer oscillator circuits is a factor of cost increase and obstruction of light and thinning.

The present invention has been made to solve the above problems of the prior art, the object of which is to reduce the number of oscillation circuits by operating a plurality of microcomputers in accordance with the oscillation signal of one oscillation circuit, thereby reducing the cost An object of the present invention is to provide a microcomputer's oscillation device that can achieve light and small reduction.

According to the first feature of the microcomputer oscillation apparatus according to the present invention for solving the above problems,

A crystal oscillator for oscillating according to a reference signal to generate an oscillation signal of a first sinusoidal wave;

A first micom that performs an operation and a control operation on input data provided from the outside according to the first sinusoidal wave oscillation signal, generates a reference frequency signal of the square wave, and transmits the reference frequency signal to the crystal oscillator;

A plurality of shaping parts which generate oscillation signals of a plurality of second sinusoids by removing a DC component of a reference signal of a square wave output from the first microcomputer; And

And a plurality of microcomputers connected to the plurality of shaping sections, respectively, to receive input data from outside according to the oscillation signals of the plurality of second sinusoidal waves and to perform arithmetic and control operations.

According to a second aspect of the present invention, each of the plurality of shaping units may include a resistor and a capacitor connected in series to an output pin of the first microcomputer in order to remove a DC component of the reference signal of the first microcomputer. Include.

According to the present invention, by operating a plurality of microcomputers by using one oscillation circuit, it is possible to reduce the weight and thinness of the original chip including the plurality of microcomputers and to reduce the cost.

1 is a view showing the configuration of a microcomputer oscillation apparatus according to the prior art.

2 is a diagram illustrating a configuration of an oscillation apparatus of a microcomputer according to the present invention.

<Explanation of symbols about main part of drawing>

111: crystal oscillation unit 113: the first microcomputer

115: shaping unit 117: second microcomputer

R1-R2: Resistor C1-C3: Capacitor

X1: crystal oscillator

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

First, Figure 2 is a block diagram showing the oscillation apparatus of the microcomputer according to the present invention.

Next, the microcomputer (M) of the present invention is applied to all devices, the microcomputer oscillator according to the present invention, as shown in Figure 2, of the crystal oscillator 111 oscillating in accordance with the reference frequency signal (S1) A first microcomputer 113 connected to the output side, a shaping unit 115 connected to the output side of the first microcomputer, and a second microcomputer 117 connected to the output side of the shaping unit 115 are included.

Here, the crystal oscillator 111 is oscillated according to a reference signal to generate the oscillation frequency signal S1 of the sine wave, and the crystal oscillator 111 is disposed between the input pin of the first microcomputer 113 and the ground. A capacitor C1 and a crystal oscillator X1 connected in series, and a resistor R1 and a capacitor C2 connected in series between the output pin of the first microcomputer 113 and ground are included. The output side of the capacitor C1 is connected to the output side of the crystal oscillator X1 and the first microcomputer 113, and the output side of the resistor R1 is connected to the input side of the crystal oscillator X1 and the capacitor C2. The input side is connected.

The first microcomputer 113 calculates and controls an input data provided from the outside according to the first sinusoidal oscillation frequency signal S1 of the crystal oscillator 111 and performs a reference frequency signal S1 of the square wave. Is generated to be transmitted to the crystal oscillator 111.

The shaping unit 115 connected to the output pin of the first microcomputer 113 forms the reference frequency signal S1 of the square wave output from the first microcomputer to generate the oscillation signal S3 of the second sinusoidal wave. A resistor R2 and a capacitor C3 are connected in series with the output pin of the first microcomputer 113. The oscillation signal C3 of the second sinusoidal wave having a frequency necessary for the second microcomputer 117 is generated according to the values of the resistor R2 and the capacitor C3.

In addition, the second microcomputer 117 connected to the output side of the X-shaped portion 115 is provided to receive the input data provided from the outside in accordance with the oscillation signal S3 of the sinusoidal wave to perform arithmetic and control operations.

In the exemplary embodiment of the present invention, two microcomputers are operated by using one crystal oscillator, but a plurality of microcomputers connected to the output pins of the first microcomputer and the plurality of microcomputers are connected to the plurality of microcomputers, respectively. It may be configured to be provided to operate a plurality of microcomputers using a single crystal oscillator.

In the oscillation apparatus of the microcomputer according to the present invention provided as described above, the crystal oscillator X1 of the crystal oscillator 111 receiving the reference signal S1 of the square wave provided from the first microcomputer 113 is oscillated to generate the first. An oscillation signal S2 of one sinusoidal wave is generated, and the oscillation signal S2 of the first sinusoidal wave is provided to the first microcomputer 113.

The first microcomputer 113 receiving the oscillation signal S2 of the first sinusoidal wave calculates and controls an input data provided from the outside in accordance with the first sinusoidal oscillation frequency signal S1 and performs a reference signal of the square wave. S1 is generated and transmitted to the crystal oscillation unit 111.

In this case, the amount of current of the reference signal S1 of the square wave is limited according to the values of the resistor R1 and the capacitor C2.

Meanwhile, the reference signal S1 of the square wave output from the first microcomputer 113 is provided to the shaping unit 115, and the resistor R2 and the capacitor (R2) of the shaping unit 115 receiving the reference signal S1 are provided. C3) removes the direct current component of the reference frequency signal S1 and outputs the oscillation signal S3 of the second sinusoidal wave.

In addition, the second microcomputer 117 that receives the second sinusoidal wave oscillation signal S3 of the shaping unit 115 receives an input data provided from the outside in response to the oscillation signal S3 of the second sinusoidal wave and operates an operation and a control operation. Run

As described above, the microcomputer oscillation apparatus according to the present invention can operate a plurality of microcomputers using one oscillation circuit, thereby making it possible to reduce the cost and thinness of one chip including a plurality of microcomputers and to reduce costs. Get an effect.

While the invention has been shown and described with respect to specific preferred embodiments thereof, the invention is not limited to the embodiments described above, and is commonly used in the art to which the invention pertains without departing from the spirit of the invention as claimed in the claims. Anyone with knowledge will be able to make various variations.

Claims (2)

A crystal oscillator for oscillating according to a reference signal to generate an oscillation signal of a first sinusoidal wave; A first micom that performs an operation and a control operation on input data provided from the outside according to the first sinusoidal wave oscillation signal, generates a reference frequency signal of the square wave, and transmits the reference frequency signal to the crystal oscillator; A plurality of shaping parts which generate oscillation signals of a plurality of second sinusoids by removing a DC component of a reference signal of a square wave output from the first microcomputer; And And a plurality of microcomputers each connected to an output side of the plurality of shaping units and configured to receive arithmetic signals of the plurality of second sinusoids and receive input data from the outside to perform arithmetic and control operations. The method of claim 1, wherein each of the shaping portion, And a resistor and a capacitor connected in series with the output pin of the first microcomputer to remove the DC component of the reference signal of the first microcomputer.