KR940000450B1 - Tone detector - Google Patents

Abstract

The tone detector includes a zero crossing circuit for converting an analog tone signal into a digital square wave, an edge detector for detecting an edge signal from the zero crossing circuit, monostable multivibrators for generating a logic signal, a logic AND for logically AND-operating the outputs of the edge detector and monostable multivibrator, and a logic signal generator for generating a tone detection signal using the output of the logic AND, thereby simplifying the configuration of circuit and facilitating the integration thereof.

Description

Tone detector

1 is a block diagram of a conventional tone detection device.

2 is a block diagram of a tone detection device of the present invention.

3 is an operating waveform diagram of each part of FIG.

* Explanation of symbols for main parts of the drawings

20: zero crossing circuit 21, 22, 25: monostable oscillator

23: edge detector 24: gate

The present invention relates to an apparatus for detecting a tone signal having a certain frequency, and more particularly, to an apparatus capable of digitally detecting a tone signal by predicting a tone signal of a next period.

In general, in order to detect a tone having a constant frequency, a band pass filter and a rectifier are used as shown in FIG. 1, and a method using a phase locked loop is widely used. Known. At this time, in the former tone detection method as shown in FIG. 1, the band of the corresponding tone is detected through the band pass filter 10, and the precision of the tone detection device is determined according to the pass bandwidth of the band pass filter 10. Therefore, in order to make a precise band pass filter 10, the order is increased, which increases the complexity of the required parts and configuration for the filter configuration, and it is difficult to manufacture an ideal filter with a pass bandwidth.

In the latter case, when the accuracy of the tone detection is improved, the response time until the tone detection is long, and when the response time is faster, the accuracy is deteriorated. In addition, the above-described tone detection methods are inferior in accuracy because they detect a tone using an analog method.

Accordingly, an object of the present invention is to provide a device capable of detecting a tone signal by determining whether a tone signal is generated within a prediction period using a monostable multivibrator.

Another object of the present invention is to provide a tone detection device that is easy to integrate by digitally detecting an input tone signal.

Hereinafter, the present invention will be described in detail with reference to the drawings.

2 is a configuration diagram of a tone detection apparatus according to the present invention, and includes a zero crossing circuit 20 for converting an input tone signal into a square wave, and a first pulse having a predetermined width at a rising edge of the square wave. The first single-stable oscillator 21 for generating a second, the second single-stable oscillator 22 for generating a second pulse having a predetermined width at the falling edge of the first pulse and the rising edge signal for detecting the square wave Tone is generated by an edge detector 23, an AND gate 24 that passes an edge signal only when a rising edge occurs in the second pulse period, and an edge signal through the AND gate 24. And a third single-stable oscillator 25 for generating a logic signal indicating that it has been detected. In FIG. 2, the first and second single-stable oscillators 21 and 22 are means for generating a pulse representing a period for predicting the generation of the next edge signal, and the AND gate 24 and the third single-stable oscillator ( 25 is means for generating a constant logic signal indicating tone detection when the edge signal occurs periodically for each prediction period pulse.

FIG. 3 is an operation waveform diagram of each part of FIG. 2, wherein the analog input waveform of a tone signal having a constant frequency is converted into a square wave, and then the logic indicating the tone detection when the rising edge of the square wave occurs periodically at each prediction cycle pulse is shown in FIG. "Shows the process of generating a signal.

Based on the above configuration, the present invention will be described in detail with reference to FIG. When an analog tone signal having a constant period To is input as shown in (a), the zero crossing circuit 20 converts it into a square wave signal having a To period as shown in (b) according to the zero crossing of the tone signal. At this time, the edge detector 23 detects a rising edge of the square wave as shown in (b) and generates an edge signal as shown in (e). First and second single-stable oscillators 21 and 22 are used to predict the generation interval of the edge signal. The first monostable oscillator 21 may be a retriggerable monostable multivibrator, and has a first pulse Ta having a constant width at a moment when a rising edge of a square wave such as (b) occurs. Generates a pulse signal such as The first pulse Ta is adjusted to have a width narrower than the period To of the tone to be detected (Ta <To). The second single-stable oscillator 22 inputting the output of the first single-stable oscillator 21 always has a second pulse Tb of a constant width at the falling edge of the signal as shown in (c) ( Generate a pulse signal as in d). At this time, the second pulse Tb of the pulse as described above (d) becomes an interval signal for predicting the edge signal generated at the rising edge of the next square wave in the edge detector 23. That is, the second pulse Tb is a periodic signal that predicts the edge change of the next square wave using the current square wave and has a width of Tb = 2 (To-Ta).

For example, if the period of the input signal is equal to the period To of the tone signal to be detected, the rising edge is always generated in the second pulse Tb representing the prediction period. If the / period of the input signal is greater than the signal period To to be detected, the rising edge occurs at a point beyond the second pulse Tb. In addition, if the period of the input signal is less than the signal period (To) to be detected, the falling edge is not generated at the output of the first single-stable oscillator 21 because the first single-stable oscillator 21 is triggered again. As a result, the second single-stable oscillator 22 does not trigger the second pulse Tb. The AND gate 24, which inputs the outputs of the second single-stable oscillator 22 and the edge detector 23, has a second pulse Tb of which a rising edge signal such as (e) generated from a square wave is equal to (d). Determine if it occurs in the cycle. Therefore, if the input signal is equal to the signal period To to be detected, the AND gate 24 outputs a rising edge signal as shown in (f). The third single-stable oscillator 25 which inputs the AND gate output can be retriggered, and the trigger pulse width Tc which is set larger than the tone period To is set by the tone period To Set greater than) (Tc> To). The third single-stable oscillator 25 performs a function of maintaining a logic " high " signal indicating tone detection when a desired signal is detected. Therefore, since the pulse width Tc is greater than the tone period To, if an edge signal occurs at the constant period in the AND gate 24, it is retriggered in the triggered state to maintain a logic "high" state. In this case, a tone signal having a desired frequency is detected.

As described above, the analog-type tone signal is converted into a square wave so that the tone signal can be detected digitally regardless of the magnitude of the input signal, and the next continuous edge is generated after one edge is generated from the square wave of the input signal. The accuracy of the tone detector can be adjusted by adjusting the width of the pulse signal indicating the prediction interval to be generated. By narrowing the pulse width, the accuracy of the tone detector can be increased, and the tone signal is input regardless of the precision of the tone detection time. Since it is equal to one cycle of the instant, the tone detection time can be made faster, the configuration is simple, and since the digital circuit is used, it is easy to integrate.

Claims (4)

1. A tone signal detecting apparatus having a constant frequency, comprising: a zero crossing circuit 20 for inputting an analog tone signal and converting it into a digital square wave, and an edge for detecting a predetermined edge signal in the zero crossing circuit 20; A series-configured monostable oscillator (21, 22) for generating a predetermined logic signal for each occurrence of the output signal of the edge detector (23) by inputting the detector (23) and the output of the zero-cross circuit (20); Means 24 for logically multiplying the outputs of the edge detector 23 and the monostable oscillator 22, and a logic signal generating means 25 for generating a tone detection signal based on the output signal of the logical multiplication means 24; Tone detection apparatus, characterized in that. 2. The tone detection device according to claim 1, wherein the monostable oscillator (21, 22) is configured such that the output pulse width satisfies the following equation. Ta <To <Ta + Tb To: Input tone period Ta: output pulse width of the monostable oscillator 21 Tb: output pulse width of the monostable oscillator 22 The tone detection device according to claim 1 or 2, wherein the monostable oscillator (21) is configured to be retriggerable. 2. The tone detection device according to claim 1, wherein the logic signal generating means (25) is constituted by a restable monostable oscillator whose output pulse width (Tc) is larger than the input tone period (To).

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