DK169647B1 - Differential detector for acoustic pressure - Google Patents

Abstract

Acoustic pressure differential detector for detecting the aperiodic wave resulting from the opening of a door or window in a closed room, comprising a microphone (1) and means for fixing a sensitivity threshold value, characterised in that it comprises means of regulation (6, 10) for varying said threshold value as a function of the microphone output. <IMAGE>

Description

in DK 169647 B1

The present invention relates to a differential pressure acoustic pressure detector according to the preamble of claim 1.

In prior art detectors of this type, the output of the microphone is first amplified, after which it is generally compared with a set reference voltage in a comparator whose output can assume one of two possible states according to the relative size of the signal which comes from the microphone, and the reference voltage.

Such detectors activate the alarm when affected by an aperiodic pressure wave, while not responding to a periodic signal such as an audible sound, the monitoring being exercised particularly on the shape and size of the intercepted signals.

In connection with these known differential detectors 15 and in connection with known equipment which is designed to warn against unimportant opening of doors and windows in closed environments, the threshold level must be manually adjusted in each case.

In practice, this setting is closely linked to any error that may occur in relation to how close the area in question is, as well as the pronounced flexibility of certain building materials, which in connection with strong wind can cause pressure variations to be produced in the area as a result of a pressure action or penetration. Thus, in order to avoid any risk of triggering the alarm for reasons other than intrusion, the threshold level of these detectors must be set to a relatively high magnitude so that they are not affected by atmospheric disturbances, which, however, are inevitable upon their accidental onset. since the disturbance is contingent upon the presence of a strong wind. This setting is detrimental to the efficiency of the detector in calm weather.

US-A-4,442,514 discloses a device for processing 35 signals emitted from a transducer intended to identify the nature of the intrusion and, in case 2, trigger an alarm and having it special feature, to operate with an undetermined triggering threshold and which is self-regulating as a function of the received signals.

5 The device processes signals from the transducer by generating signals that are unidirectional or not and which are emitted from high-pass filters and low-pass filters. Based on signals from the high-pass filter, the device detects whether it is a vehicle or a person penetration, while the signals from the low-pass filter act upon recognition of the cases where a real penetration occurs. These intrusions, when detected, are classified by a logic circuit to determine whether they are provided by vehicles or humans.

15 For identification of the nature of penetration, zero transitions are recorded in unidirectional signals from the high-pass filter, the energy of the unidirectional high-pass signals is recorded and the two sizes are compared.

The signals indicating an intrusion are processed by defining windows corresponding to the zero pass for the unidirectional low-pass signals, then measuring the energy in the unidirectional low-pass signals and comparing the energy sizes at a level threshold that is determined. based on the number of 25 zero-pass windows that have two or more zero-passes.

However, the circuit in question is very complex and is based on a sequence of processing of signals captured by the transducer. This complexity results in a decrease in the overall reliability of the system, which is further promoted by the initial operations intended to distinguish low-frequency and high-frequency components in the signal. The series of treatments results in a loss of the initial value due to abbreviations in the information. The risk here is that the loss caused by every 35 paragraphs eventually produces erroneous translations of the basic signal, which results in poor control and, in case of burglary, an adverse effect related to the level of the final logical step.

It is the object of the present invention to provide a differential acoustic pressure detector for detecting the opening of doors and windows in the closed room, which includes means for intercepting the wave produced by moving air masses adjacent to door openings. or windows, and also containing means for adjusting the threshold level size in accordance with the conditions of the surrounding environment. This object is achieved with a differential detector of the kind initially provided, which is designed according to the characterizing part of claim 1.

According to a preferred embodiment, atmospheric disturbances are intercepted by a microphone whose output signal is sent to a control means where the threshold value change is provided. Consequently, with such a detector, the threshold level at the control means can be continuously set to the maximum value through the signal emitted from the microphone.

The result is that the aforementioned atmospheric disturbances are intercepted as soon as they occur and before they reach the critical level of negligible activation, so that the threshold level is adjusted accordingly.

The control means may in a known manner include a control branch which receives at its input a signal from the microphone and whose output signal is transmitted to an input of a comparator whose second input receives another signal from the microphone.

Thus, the comparator receives, on the one hand, the signal that has actually emanated from the microphone and which is optionally amplified, and on the other hand a varying threshold signal developed from the microphone signal.

The control branch of the signal provided from the microphone includes several processing steps in accordance with the various phases of analysis and design of the signal, which phases are to be provided in such a manner as is understood in the system at the comparator level.

The device provided by the present invention includes a comparison means for comparing the output level of the microphone with said threshold, a free-flowing oscillator controlled by said comparison means, counting means for counting the pulses emitted from the oscillator, and the activating means for of an alarm when the contents of the counter exceed a predetermined size.

When the output of the comparator is considered to be active, ie. that the signal coming directly from the microphone is higher than the reference voltage, the oscillator on the load side is activated and each pulse is counted at the counting means. When the number of pulses counted reaches a predetermined size, the alarm is activated.

Such a detector does not respond to a periodic signal, such as an audible sound, since in this case the counter 20 does not have sufficient time to reach the predetermined magnitude during a half-period of the signal which will activate the alarm.

The invention has resulted in the production of a detector which, compared with the prior art, is more sensitive to the aperiodic influences it is to detect and which is automatically adapted to the existing environment and where error detections are largely avoided.

BRIEF DESCRIPTION OF THE DRAWINGS The invention will now be described in greater detail with reference to the accompanying drawings, in which: 1 is a block diagram showing the design and structure of the circuit; FIG. 2 shows a particular embodiment of the invention; FIG. 3 shows a possible change of embodiment.

Since FIG. 1 is a general diagram focusing on the different parts of the circuit, it is not described in detail here, since the references are set forth in DK 169647 B1 FIG. 2 and 3, which are clearer. Referring to FIG. 1 to provide an overall view of the device provided by the present invention. In order to provide the greatest possible clarity, an explanation of the FIG. 2.

Referring to FIG. 2, it is seen that an electret-type microphone has the output connected to a threshold comparator 5 over a suitable two-stage amplifier 2 and 3, where the step 3 can be set by potentiometer 4. The output of the amplifier stage 2 is also connected to the input of a low pass two stage amplifier filter circuit 6.

This filter circuit operates by retaining only the ripple portion of the signal captured by the microphone, which ripple portion is proportional to the magnitude of movement of the air masses within that range. Accordingly, the signal component which results from a sudden change in pressure is removed, such as e.g. provided by the breaking of a glass plate.

The output of the filter circuit is transmitted to a peak detector 7, which is designed as a window comparator, where the two voltage references VI and V3 are thus provided that V3 is greater than VI.

The output of the peak detector 7 works by modulating the setting voltage VI of a circuit 9 to provide the control signal.

The output of the circuit 9 is transmitted to a voltage integrator whose output signals are transmitted to a voltage follower 10.

The voltage follower 10 is finally used as the threshold level of comparator 5.

The output of comparator 5 acts by activating an oscillator counter 14. Through connection 13, this oscillator counter activates a monostable switch 16 when the predetermined number of pulses 35 has been counted. Upon switching, the circuit 16 causes magnetization of a relay 21 which controls the alarm means.

6 DK 169647 B1

The operating polarity of the relay, positive or negative, can be designated by the user using a switch 30 and a reverse circuit 19.

Accordingly, atmospheric 5 motions captured by the microphone 1 are represented on the output of the filter circuit 6 by changes in voltage which cause changes in the output state of the peak detector 7.

If the self-acting control switch 8 located at the output of the circuit 7 is in the closed position, the voltage VI is transmitted to the positive input of the modulator circuit 9 when the output voltage from the filter circuit is no longer between VI and V3, since a signal then emitted after the peak detector 7.

A light emitting diode (LED) 11 is located at the output of the voltage sensor 10, whereby the operating state of the self-acting control loop can be controlled.

When an aperiodic wave caused by an opening or break-in is intercepted by the microphone 1 and then amplified in the amplifier 2, 3, the comparator 5, if the signal exceeds the adjustable threshold level in the comparator 5, changes its logical state for a period which is proportional to the length of the wave mentioned. Another light emitting diode (LED) 12, which shows the threshold level, is then activated.

If the length of the detected aperiodic wave is sufficiently large, the oscillator counter 14 activates the alarm.

It should be noted that a detection switch 15 provides options for detecting the operation mode of the detector (shock or opening) by identifying the oscillation size required to activate the alarm.

The alarm signals provided by an LED 17 and acoustic vibrator 18 enable the operation of the detector to be monitored when actual alarm means are not provided, said vibrator being further controlled by a display switch 23.

While in the embodiment shown in FIG. 2, three reference voltages, VI, V2 and V3, which are determined by a voltage bridge, where V2 is located in the middle of the interval between VI and V3 of the size 0.1V, is the second embodiment shown. in FIG. 3, based on a system with a set of 5 four reference voltages VI to V4.

The control branch is based on the same principle as in fig. 2, including a low-pass two-stage filter 6, which is slightly altered in connection with the input voltage, followed by a window comparator 7, a self-acting control switch 8, and an independent adjustment circuit 9. In this embodiment, the reference voltage to be modulated , V4, the size of which is greater than VI, V2 and V3.

The filter circuit 6, which takes into account the ripple signal received by cell 1, amplifies the filtered information before passing it to the detector stage of the peak detector circuit with two thresholds 7. The two reference voltages VI and V3 constitute the limits beyond which they rip pelvic variations caused by atmospheric disturbance 20 or turbulence will inevitably result in a change in the state of comparator 5 over amplifiers 2 and 3, thereby activating the final alarm stages if the threshold value of the comparator 5 was set and predetermined.

Three switching signal lights 11, 12 and 17 respectively indicate the operating state of the self-acting control loop, the threshold level of the device and the activation of the final alarm steps. The first tp, which indicates the constant operating sequence in a standby mode, is provided with a green and a yellow color respectively. The signal light 17, which indicates an alarm phase, is of a red color. A switch 22 can deactivate all signal lights simultaneously.

Of course, one of the basic elements of the explained circuit is the microphone, whose role is to capture the significant signals. As can be seen, the waves which can be used by a device of this kind are aperiodic and as a result devices are required which

Jean is affected at very low frequencies at a hertz or even lower. Therefore, the microphones must be selected extremely carefully since the entire detector is dependent on the quality of the recording device.

In relation to the foregoing explanation, alterations and modifications may be made without departing from the spirit and scope of the present invention.

Claims (2)

An acoustic pressure differential detector for detecting the aperiodic wave following the opening of a door or window in a closed room, including a microphone (1) and adjusting means (6,7,9,10) for setting a threshold level size, which means includes a branch for adjusting the voltage of a first input of a comparator (5), which setting branch of its input receives a first signal from the microphone (1) which is changed by a filter circuit (6) and which after this change, a predetermined voltage (9) modulates which voltage at the first input of the comparator (5) is derived from the changed voltage and wherein the second input of the comparator receives a second signal from the microphone (1). characterized in that the differential detector includes an oscillator counter (14) controlled by the comparator (5) for counting the output pulses of a free oscillator, and triggering means (16) for triggering an all arm when the content of the counter exceeds a predetermined size. 20 Differential detector according to claim 1, characterized in that the triggering means include a monostable branch (16) which provides magnetization of a relay (21) which controls the alarm means.