FR2488429A1 - Light operated burglar detector - uses light sensitive resistor to control switching of transistor in circuit responding only to rapid changes - Google Patents

Abstract

The light detection circuit for a burglar alarm includes a light sensitive resistor (Rx) in series with a load resistor (R1) which may be selected in the range 470 kilo-ohms to approx. 2 mega-ohms. The common point of these two resistors is connected via a capacitor (C1) to the base of a transistor (T1). When the variation in potential of the capacitor is negative, it is connected to earth, by a diode (D1), but when it is positive it is applied to the transistor base making the transistor conduct. A resistor (R2) ensures that very slow changes in potential do not affect the transistor since current leaks to earth, but rapid changes are effective in making the transistor conduct. The conduction of the transistor (T1) is used in turn to control a second transistor (T11). This controls operation of a relay (10) to initiate an alarm signal. The circuit is not sensitive to slow changes in ambient lighting during the day and night.

Description

Method and device for detecting and reporting an intrusion into a protected place.

 The invention relates to the devices for protection against theft, attack, malicious activity. It relates more particularly to means for detecting the action of an intruder or a person not authorized to perform certain acts.

 Numerous devices are known which use the interception of a light beam for this purpose, the infrared radiation emitted by the human body or that of animals, the Doppler effect, variations in the magnetic field or even magnetic contacts. .

 Most of these known devices have various drawbacks such as the cost of the installation, the volume of the devices, frequent maintenance, questionable reliability, relatively high electrical consumption.

 The object of the invention is a method and a device which overcomes the drawbacks of known methods.

 The subject of the invention is a method for detecting and reporting an intrusion into a protected place. We constantly control the lighting of the place, we detect only the sudden increases in said lighting to the exclusion of any slow variation in increasing or decreasing said lighting, pn materializes in the form of an electrical signal each of said sudden increases exceeding a minimum predetermined, and said signal is applied to the triggering of a signaling device.

The lighting can be controlled remotely from the signaling device and transmit the signal of sudden increase in lighting by air to the signaling device;
The invention also relates to an intrusion detector-signaling device implementing such a method.

This device comprises a light sensor disposed in said place, an electrical circuit controlled by the sensor and comprising a supply of electric current, means for ensuring a predetermined permanent leakage of current against by the sensor, the abruptly triggering means which emit a signal in response to a predetermined minimum value of said counter current and at least one signaling device actuated by said signal.

 The light sensor can be an electronic component, the conductivity of which varies as a function of the illumination, of the group comprising in particular the cells with cadmium sulfide or selenide, photodiodes, phototransistors.

 Such a device can comprise a transmitter transmitting the signal by air to at least one receiver actuating a signaling device.

 Thus, the transmitter can transmit the signal to the signaling device in the form of radio waves, infrared radiation or ultrasound.

 The signaling device can emit a sound or light signal, establish a telephone call or release a chemical substance.

 A timer device advantageously extends a fleeting signal for a predetermined period of time sufficient to ensure a good alarm.

 A particularly advantageous characteristic of the device according to the invention is that it can comprise a supply of automatic electric current because it can be produced for example in the form of an electric circuit of the monostable type so that its consumption is practically zero in the state Eve.

 The device according to the invention can obviously be coupled in a conventional manner to any other known intrusion detection device and in particular to a magnetic detection device.

 A device according to the invention must be placed in the standby state in the dark or half-light. Ure slow evolution of the light has no effect on the device, it takes a rapid change from one intensity of light to another brighter to trigger the alert. The more or less rapid passage from light to dark has no effect.

The light variation detector of a device according to the invention can be produced in a very small volume, of the order of a pack of cigarettes or less with its battery power and a radio transmitter. Its extremely low consumption in the standby state in the dark ensures power for more than a year with a 9V battery
3 of the trade with a volume of a few cm
If a device according to the invention is placed in an ordinary living room, the succession of day and night remains without effect, but if an intruder lights up at night, if only with a lamp pocket to examine the places, it triggers the alert. It is the same if the device is installed in the standby state in a room whose shutters or curtains create sufficient darkness: their opening or the use of a complementary light source triggers the alert.

 The device according to the invention can be placed in the standby state in a cupboard, a drawer, a safe or another closed place. It will trigger the alert when it opens, when it receives the light.

 An apparatus according to the invention can also be placed under an opaque object such as a book, a file; and it will trigger the alert as soon as the object protecting it from light is removed.

The invention will be better understood on reading the detailed description which follows and on examining the appended drawings which represent, without limitation, several embodiments of the invention. On these drawings
- Figure 1 is a schematic view of a detection and alarm device according to the invention
- Figures 2, 3 and 4 are diagrams of electrical circuits of the detector of a device according to the invention.

 The device shown in FIG. 1 comprises a light variation detector 1 comprising a photoelectric cell 2 which, under the influence of a light beam 3 emits a radio signal 4 which is received by a signaling device 5. This is equipped an indicator light 6 and a siren 7 emitting an audible signal 8 in response to the radio signal 4.

 A switch 9 enables the signaling device to be switched off at will.

 For the practical realization of a device according to the invention, it is possible to use any commercial signaling device, but the important part is the electrical circuit of the detector.

This circuit must be sensitive but simple and inexpensive. It must react to a sudden gain in light while res
or both passive in a stable light environment / evolving slowly or decreasing in intensity Its consumption must be almost zero in standby state. It must deliver its information for a sufficient duration, of the order of 3 & 15 seconds in practice, regardless of the brevity of the command pulse.

 One could use a conventional monostable transistor arrangement. However, such a circuit comprises two flip-flop transistors, one of which constantly flows, which does not make it possible to obtain the advantage of almost zero consumption in standby state.

 Monostable integrated circuits in M.O.S.

(Metal, Oxide, Semiconductors) have a very low consumption in the standby state but have a relatively high triggering threshold which does not allow to reach a good sensitivity.

 The three circuits shown diagrammatically in FIGS. 2, 3 and 4 all have the originality of combining a photoelectric cell with very high resistance in darkness and low resistance in strong light, in series with a load resistance with connection of a leakage circuit. between the cell and its load resistance. In the three circuits, the voltage produced is used with fixing of the operating time constant.

 In these diagrams, RX designates a light sensor that becomes more or less conductive depending on the illumination it receives. It is thus possible to use a cell with cadmium sulphide or sdlenide, a photodiode, a phototransistor or any other known photoelectronic component meeting the technical criteria of conductivity, for example a dark resistance of the order of 10 megoms and of order of 500 ohms in strong light.

 R1 denotes the load resistance of this sensor which provides a point representative of the ambient brightness and its variations at point A. The value of R1 can vary depending on the factors from approximately 470-kilo ohms to approximately 2 megohms. The consumption in this branch of the circuit is thus always less than around 18 rA.

 The voltage available at A, due to any stable illumination, is stopped by a capacitor C1, but a variation corresponding to a variation in light is transmitted. When this variation is negative (decrease in illumination), it is evacuated to ground by a diode Dl.

 When this variation is positive, it requests the conduction of a transistor T1.

 Conduction occurs as soon as the opening threshold is reached, ie approximately 0.5 V. The contribution of voltage variations by the capacitor C1 is also constantly purged by a resistor R2. Thus, a slow variation of the light does not allow reaching the operating threshold of 0.5 V.

 It should be noted that in the standby state, the transistor T1 delivers only its leakage current of the order of 50 nA (nanoampere), therefore almost zero.

The use of the voltage collected requires a
seems whose consumption in the standby state remains almost
nothing. This condition is found in the form of three
variants in the diagrams of Figures 2, 3 and 4.

In the circuit of figure 2, the conduction of the transis
tor T1 causes a voltage drop on the resistor R3 and
the capacitor Cîl discharges through the diode Dll.

T1 conduction stops quickly and Cîl recharges
gradually by crossing the base of a transistor Tll, this
which ensures the conduction of this transistor and its action on the
output receiver. We set the signal hold time
by adapting the value of Cîl according to the gain of Tll and the con
summons the receiver.

The receiver is shown here as a small re
leave 10.

A diode D2 protects the transistor Tll against the ten
relay coil winding voltage. l0. A D3 diode
light emitting shows operation.

The circuit of the diagram of figure 3 works so
similar to that in Figure 2, but with reverse polarities.

 The capacitor C21 is not charged in the standby state.

As soon as the light pulse appears, it charges
through the base of a transistor T21; causing its conduction.

The receiver relay 10, on a break contact. 11, charges a capacitor C22, through a resistor R23, but from the start of the activity of transistor T21, the capacitor
C22 is discharged through a resistor R22, in the base of transistor T21, thus extending its conduction time. By
thereafter, the capacitor C21 discharges through a diode
T22. A diode D21 prevents the charging of the capacitor C22 from enriching the capacitor C21.

The circuit of figure 3 is better suited than that of
Figure 2 for a long delay.

 In the circuit of FIG. 4, the conduction of the transistor T1 immediately causes that of the transistor T32 which activates the receiver. The voltage appearing on an electrode of a capacitor C31 requests its charge through a resistor R33 and the base of a transistor T31 which becomes conductive.

 The conduction of the transistor T31 supplements that of the transistor T1 to ensure the voltage drop on the resistor R3. The phenomenon persists until the capacitor C31 is fully charged.

 The circuit then returns to the standby state and the capacitor C31 discharges through the diode D31.

 A resistor R31 increases the input impedance of the transistor T1, which makes it possible to use less conductive cells, a resistor R32 ensuring the purging of the leakage current of the transistor T31.

 Such a receiver can be connected directly to a radio transmitter 12, and / or, as in the diagram in FIG. 2, to a relay associated with the diodes D2 and D3 (dotted connection).

This circuit of Figure 4 is well suited for a fairly
long delay. It can serve as a basis for production in the form of integrated circuits of extremely reduced volume.

 Thus, the consumption of the three circuits of Figures 2, 3 and 4 is limited to the conduction of the light sensor in series with the resistor R1, and to the leakage currents of the transistors. With a good cadmium sulfide cell whose resistance in the dark is 10 megohms, the flow rate is limited to l) uA with a 9 V battery. The leakage current of the transistors does not exceed 50 nA per element. Thus consumption is almost zero in standby state.

 In the diagrams of FIGS. 2 to 4, the same elements are designated by the same references.

As a practical example, it is possible to produce devices according to the invention of good quality using a cadmium sulfide cell and the following values for the various elements R1 470 kohms
R2 1 megohm
R3 5.6 kilo ohms can be up to 470 Kohms in
circuit nO 3 C1 0.5 uF D1 silicon diode type 1N4148 T1 weak silicon transistor Icbo type 2N2484 Tlltransistor low silicon Icbo type BC237
T31 weak silicon transistor Icbo type 2N2484
T21 - T32 weak Icbo transistor type 2N2907
D2 - Dll - D21 - D22 - D31 silicon diode type 1N4148
D3 LED diode 20 mA Rîl 100 Kohms
R21 100 Kohms
R22 68 Kohms
R23 10 Kohms
R31 10 Kohms
R32 1 megohm
R33 470 Kohms Cîl 50 uF
C21 22 uF
C31 3.3 uF
C22 100 uF
Relay 10 8V 20 mA
As a radio transmitter, any suitable commercial transmitter can be used, such as those used for garage door openers and the associated signaling devices.

 For example, with the circuit of FIG. 4 and the values indicated, it is possible to use the transmitter-receiver units sold by the company called Linear Corporation under the trade names of "E1ectronic Key II Radio Controls" and "Delta-3 Digital Receiver".

 Of course, the invention is in no way limited to the embodiments described and shown, it is capable of numerous variants accessible to those skilled in the art, depending on the applications envisaged and without departing from the scope of the invention. 'invention.

Claims (10)

 1. A method for detecting and signaling an intrusion into a protected place, characterized in that the lighting of said place is permanently controlled, only sudden increases in said lighting are detected, excluding any slow variation in increasing or decreasing said lighting, each of said sudden increases exceeding a predetermined minimum is materialized in the form of an electrical signal, and said signal is applied to the triggering of a signaling device.  2. Method according to claim 1, characterized in that the lighting is controlled remotely from the signaling device and the signal of sudden increase in lighting is transmitted by air to said signaling device.  3. Intrusion detector-signaling device in a protected place according to the method of claim 1 or 2 characterized in that it comprises a light sensor (1) disposed in said place, an electrical circuit controlled by said sensor and comprising an electric current supply, means for ensuring a predetermined permanent leakage of the current countered by said sensor, abrupt triggering means which emit a signal (4) in response to a predetermined minimum value of said current against and at least one device for signaling (5) actuated by said signal.  4. Device according to claim 3, characterized in that the light sensor is an electronic component, the conductivity of which varies as a function of the illumination, of the group comprising in particular cells with cadmium sulfide or selenide, photodiodes, phototransistors.  5. Device according to one of claims 3 or 4, characterized in that it comprises a transmitter transmitting by air the signal to at least one receiver actuating a signaling device.  6. Device according to claim 5, characterized in that the transmitter transmits the signal to the signaling device in the form of radio waves, infrared radiation or ultrasound.  7. Device according to one of claims 3 to 6, characterized in that it comprises at least one signaling device emitting a sound signal or light signal, or establishing a telephone call, or releasing a chemical substance.  8. Device according to one of claims 3 to 7, characterized in that its supply of electric current is autonomous.  9. Device according to one of claims 3 to 8, characterized in that it comprises a timer member which extends a fleeting signal for a predetermined period of time born.  10. Device according to one of claims 3 to 9, characterized in that the electrical circuit is of the monostable type with practically zero consumption in the standby state.