KR100629941B1 - A Source of Electric Power Noise Detector Circuit - Google Patents

Abstract

In the power supply noise detection circuit, the power supply noise detection circuit is characterized in that the microcomputer operates only within a predetermined reference range by excluding the sensor output stage and the power noise amplifier stage if it is determined that the signal noise exceeds a predetermined reference level. About

A first power amplifier stage 100; A second power amplifier stage 200; A two-end limit detector (300) configured by two comparators (310, 320) to set a width of noise to extract a noise signal from the signal passing through the second power amplifier stage (200); A reverse flow blocking diode (610, 620) connected to an output terminal of the both ends limit detector to block a reverse flow of current; A sensor circuit unit 400 for detecting an external physical quantity and converting the same into an electrical signal and outputting the electrical signal; When a signal is input from the sensor circuit unit 400 and both ends of the limit detector 300 and a noise signal is input from the limit detector 300 at both ends, the signal output from the sensor circuit unit 400 is ignored, and both ends of the limit detector 300 are provided. When the noise signal is not input from the signal processing unit 500 for processing the signal of the sensor circuit 400 is characterized in that it comprises a configuration.

Power, noise, detection

Description

A source of electric power noise detector circuit

1 is a general noise detection circuit diagram.

2 is a power supply noise detection circuit of the present invention.

Explanation of symbols on the main parts of the drawings

100: first power supply noise amplification stage

200: second power supply noise amplification stage

300: both ends limit detector

400: sensor circuit

500: signal processor

1000: power supply noise amplification stage

The present invention relates to a power supply noise detection circuit, and in particular, by comparing the sensor output stage and the power noise amplification stage, if it is determined that the signal noise exceeds a predetermined standard, the power supply noise detection circuit is characterized in that the microcomputer operates only within a predetermined reference range. It is about.

Since various semiconductor sensors amplify and use a small current change amount due to their characteristics, they are significantly influenced by external power supply noise.

For example, in the case of products using sensors such as light sensors, ultrasonic sensors, or water level sensors, the power noise generated when the power of the same line is used to turn on or off the power of other electronic devices nearby may cause high voltage in a very short time. The power noise affects the sensor products connected to the line and is the main cause of malfunction.

In order to reduce the influence of power supply noise, most of them solve the problem by reducing the sensor sensitivity or using a choke or a capacitor, but it is not a fundamental countermeasure.

FIG. 1 illustrates a general sensor. When noise is applied to the output terminal of the sensor 1, the noise is loaded on the variable frequency signal output from the sensor 1 and applied to the noise filter unit.

Here, the noise filter unit 2 operates as a bandpass filter to filter noise of high frequency components.

Therefore, the noise carried in the variable frequency signal is filtered through the resistor and the capacitor of the noise filter unit, and the microcomputer 3 receives the normal frequency signal from the sensor.

That is, general noise removing circuits remove high frequency noise by combining resistance elements and capacitor elements, but it is not a fundamental countermeasure. Especially, if the sensitivity of the sensor is reduced to reduce the influence of noise, the performance of the sensor is maximized. There was a problem that could not be utilized.

Accordingly, an object of the present invention is to solve the above problems and to amplify the noise coming from the power source and the idle phenomenon so that the microcomputer recognizes the noise unconditionally and removes it from the microcomputer.

As a means for achieving the above object,

The present invention comprises a first power amplifier stage (100) for first amplifying a noise signal coming on the power line consisting of a resistor element, a capacitor element and an amplification element (110); A second power amplifier amplifying stage (200) comprising a resistance element, a capacitor element, and an amplifying element (210) for second amplifying the noise signal passing through the first power amplifier stage (100); A two-end limit detector (300) configured by two comparators (310, 320) to set a width of noise to extract a noise signal from the signal passing through the second power amplifier stage (200); A reverse flow blocking diode (610, 620) connected to an output terminal of the both ends limit detector to block a reverse flow of current; A sensor circuit unit 400 for detecting an external physical quantity and converting the same into an electrical signal and outputting the electrical signal; When the signal is input from the sensor circuit unit 400 and both ends of the limit detector 300, when a noise signal is input from the both ends limit detector 300, the signal output from the sensor circuit unit 400 is ignored, and both ends of the limit detector 300 are provided. When the noise signal is not input from the signal processing unit 500 for processing the signal of the sensor circuit 400 is characterized in that it comprises a configuration.

In addition, the amplifying stage of the both ends limit detector 300 is characterized in that it has a higher amplification rate than the amplifying stage of the sensor circuit unit 400.

Other objects, specific advantages and novel features of the present invention will become more apparent from the following detailed description and the preferred embodiments associated with the accompanying drawings.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings. First of all, in adding reference numerals to the components of each drawing, it should be noted that the same reference numerals are used as much as possible even if displayed on different drawings. In addition, in the following description of the present invention, if it is determined that a detailed description of a related known function or configuration may unnecessarily obscure the subject matter of the present invention, the detailed description thereof will be omitted.

1 is a configuration circuit diagram of the present invention, as shown, a signal processing unit for receiving a signal from the power supply noise amplifier stage 1000, the sensor circuit unit 400, the sensor circuit unit 400 and the both ends limit detector 300 ( 500); The power source noise amplifier stage 1000 may include a first power amplifier stage 100, a second power amplifier stage 200, a limiting detector 300 at both ends, and a reverse current blocking diode 610 and 620.

The first power amplifier amplification stage 100 is composed of a resistor element, a capacitor element and an amplification element 110 to first amplify the noise signal coming on the power line.

Like the first power amplifier amplification stage 100, the second power amplifier stage 200 is composed of a resistor element, a capacitor element, and an amplification element 210 to amplify the second noise signal.

The both ends limit detector 300 is composed of two comparators 310 and 320 to set the width of the noise to output a signal corresponding to the reference range of the noise width.

The backflow blocking diodes 610 and 620 are configured as unidirectional diodes to prevent current from flowing back.

The sensor circuit unit 400 refers to various sensors such as an optical sensor, an ultrasonic sensor, or a water level sensor and an amplifying circuit for amplifying the sensor. The signal processing unit 500 processes an output signal of a sensor such as a microcomputer. Refers to.

Hereinafter, the operation of the present invention will be described in more detail.

First, the electrical noise may be generated through various paths. In the related art, when the signal is applied to the signal processor 500 by being generated by various elements, sensors, or revolving phenomena, the signal processor 500 may normalize the electrical noise. It is determined by the signal and processed according to the predetermined program.

If the sensor circuit 400 sends a signal in response to an external object, such as an optical sensor, and a signal processor for turning on a lamp according to the signal, a noise signal generated by a cause other than a signal of a normal optical sensor may be detected. Even if the ride signal is output to the signal processing unit, the signal processing unit determines that the normal signal is applied and outputs a signal for turning on the lamp. If the sensor circuit unit 400 is a water level related measurement element, a noise signal is generated from the water level sensor. When it is input, it recognizes it as a normal signal, and the microcomputer determines that the water level has fallen below the reference level, and outputs a signal for resupplying water.

Since the noise generally penetrates in a very short time, noise blocking circuits cannot be connected to the elements of all the sensor circuit units 400, and the causes of noise are so diverse that all noises can be calculated to design a circuit. It's impossible.

Therefore, in the present invention, if the power signal applied through the both ends limit detector 300 is over-amplified and the noise signal enters the reference range set in both comparators 310 and 320 and detects and outputs the noise signal, the sensor circuit unit 400 Since noise is also included in the output, the signal processing unit 500 causes all signals input through the sensor circuit unit 400 to be recognized as noise unconditionally so as to fundamentally block an occurrence of noise.

That is, since power supply noise is simultaneously transmitted through the sensor circuit unit or various elements, in the present invention, when the power supply noise is input to the power supply noise amplifier 1000 by branching the power supply noise in parallel to the power supply noise amplifier 1000. In order to ignore the signal coming from the sensor circuit unit 400 is to block itself to recognize the noise as a normal signal.

In the present invention, the amplification stage having a higher amplification level than the amplifying stage of the sensor circuit part is designed in the power supply noise amplifying stage 1000 in order to detect the power supply noise more reliably. Multi-stage amplification and noise detection element with main components of both ends limit detection comparators 310 and 320 are added to the power output terminal for accurate detection of power supply noise.

Of course, one or three amplification stages can be designed, but various experiments have proved to be the most desirable to install two noise amplification stages.

Accordingly, the signal passing through the two-stage power amplifier circuit passes through the limit detector 300 at both ends to determine whether to apply a preset noise setting range. Therefore, the comparators 310 and 320 are connected in parallel to different reference ranges. By setting the lowest reference range and the highest reference range respectively, it is possible to detect an accurate noise signal.

Subsequently, when there is no power noise or noise noise in the sensor circuit unit 400, only a predetermined value is different in comparison with the power noise amplifier stage 1000, and power noise does not come in when the signal processor 500 is determined later. You can judge.

In this case, since the signal applied through the sensor circuit unit 400 outputs a signal to a normal external object or in response to a physical quantity, the signal processor 500 operates another device according to a pre-programmed content.

However, when power noise is generated from the outside, the output of the amplifier stage included in the sensor circuit unit 400 will appear as a larger signal than usual. In this case, the power noise detection signal is output through the output terminal of the power noise amplifier stage 1000. Thus, the signal processing unit 500 determines that a signal due to power supply noise is generated instead of a normal signal to the sensor circuit unit 400 and ignores any signal transmitted from the sensor circuit unit 400 so that the operation of the device does not occur. do.

That is, when it is determined that the power supply noise is input, the sensor signal input at this time can be ignored so that the lamp can be blocked in advance in the case of the lamp output circuit, and in the case of the water level sensor, the water supply is suspended.

As a result, the present invention configures a power supply noise amplification circuit having a higher amplification than the sensor amplifying stage, and receives the sensor input and the noise input through a logic circuit such as a signal detector or a microcomputer to control the noise by ignoring the sensor input.

As described above, the present invention constitutes a power noise amplification circuit having a higher amplification than the sensor amplifying stage, and compares the noise amplifying circuit with a sensor input to ignore the sensor output when the noise stage input is output. Can be blocked at source, and can also block commanding an operation according to an erroneous noise signal.

Although the present invention has been described in connection with the above-mentioned preferred embodiments, various other modifications and variations may be made without departing from the spirit and scope of the invention. Accordingly, it is intended that the appended claims cover such modifications and variations as fall within the true scope of the invention.

Claims (2)

A first power amplifier amplifying stage (100) consisting of a resistance element, a capacitor element, and an amplification element (110) for first amplifying a noise signal coming on a power line; A second power amplifier amplifying stage (200) comprising a resistance element, a capacitor element, and an amplifying element (210) for second amplifying the noise signal passing through the first power amplifier stage (100); Two comparator (310, 320) to set the width of the noise to extract the noise signal from the signal passing through the second power amplifier stage 200, both ends of the limit detector (300); A reverse flow blocking diode (610, 620) connected to an output terminal of the both ends limit detector to block a reverse flow of current; A sensor circuit unit 400 for detecting an external physical quantity and converting the same into an electrical signal and outputting the electrical signal; When a signal is input from the sensor circuit unit 400 and both ends of the limit detector 300 and a noise signal is input from the limit detector 300 at both ends, the signal output from the sensor circuit unit 400 is ignored, and both ends of the limit detector 300 are provided. If the noise signal is not input from the power supply noise detection circuit comprising a signal processing unit 500 for normal processing the signal of the sensor circuit unit 400. delete

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