DE2953259A1 - Alarm system for protected area - has fibre=optic transmission link between sensors and central alarm control system - Google Patents

Abstract

A secured room, such as a bank vault, has a range of alarm sensor modules coupled to a remote alarm control system within a protected area. The link between the sensors and the control unit is provided by two fibre optic bundles, that have the fibres freely mixed. When an alarm sensor is activated an oscillator circuit outputs a specific frequency and amplitude signal that is transmitted via an LED and one fibre optic link to a photo diode. A pair of comparators checks to determine the level relative to threshold values. If it is outside these values an alarm is triggered. Any disturbing light effect is felt by both fibre optic links and a second photo transistor is used to provide identification. A number of sensors may be coupled to the central facility.

Description

Security alarm system

The invention relates to a security alarm system in which a Sensor unit for detecting an alarm condition at a first location by a Signal path is connected to an alarm control at a second location, the Alarm control is activated depending on signal changes occurring in the signal path as a result of the detection of the signal condition by the sensor or an interference in the signal path.

A sensor unit, which in an alarm system of the aforementioned type may be one or more electrical switches or other devices for making or breaking an electrical circuit in dependence the penetration into an area to be protected or the like. Include. The sensor unit can also be a device which, for example, ultrasonic or microwave interference sensed to generate or interrupt an electrical signal in dependence of the alarm condition. No matter what type of sensor unit is used, the presence of the alarm state is conventionally signaled to the alarm control, which are in the vicinity of the sensor unit or at a substantial distance from it can be arranged by transmitting or interrupting an electrical Signal in one or more electrical signal lines coming from the sensor unit go off. However, such lines are resistant to attack or other interference vulnerable, thereby compromising the security of the system. Particularly the lines can be interrupted or tapped.

Although it is relatively easy to arrange the arrangement so that changes the impedance in the signal path as a result of an interruption or a tap to a Lead signal change, which is suitable to activate the alarm control, so such manipulation can remain undetected if an interference technique to trick the occurrence of such changes is used. At a System in which the alarm status is signaled by interrupting a Signals, the correct way of working can be tricked by getting into the signal path a reproduction of the normal signal is fed to the alarm controller for reception will. Although coded signals here to improve security, for example pseudorandom digital sequences can be used, so this route is usually expensive and uneconomical when transmitting signals over short distances.

The task is to train the security alarm system in such a way that that the security with regard to the signal path can be improved comparably cheaply can.

Accordingly, the invention relates to a security alarm system in which a sensor unit for detecting an alarm condition at a first location by a Signal path is connected to an alarm control at a second location, the Alarm control is activated depending on signal changes occurring in the signal path as a result of the sensing of the signal condition by the sensor or interference in the signal path, which is characterized in that the signal path is an optical Fiber optic line is and that a light signal from the sensor unit for alarm control is transmitted in the light pipe.

The use of an optical fiber line as a signal path is advantageous in that it is difficult to interfere with such a path without that thereby influencing the light signal transmitted by the sensor unit. in the In particular, it is very difficult to interrupt optical fibers in order to tap or to create a signal injection point without significantly reducing the transmitted light to attenuate, even if the fiber section to be interrupted is bridged first. Such interference can accordingly be easily detected in the alarm control by sensing the light intensity of the signal received from the light path.

The difficulty of determining the type of normal signal and of feeding a reproduction into the signal path is increased if that of the Sensor unit transmitted light signal is modulated and from the alarm control one or more modulation parameters are detected. A complicated modulation is generally not required and the modulated light signal can be generated are using an electrical pulse oscillation circuit, their output signal is used to energize a light-emitting diode or another device, until the alarm condition is detected. The necessary acquisition of the modulated signal through the alarm control can continue to be carried out by simply timed Integrating a signal derived in accordance with the light output the light guide.

A single fiber optic line can be used, however improves safety if a fiber bundle is used, especially if when different fibers transmit different signals. In the latter case, can a special light signal is transmitted in just one or more optical fibers and the alarm control can be activated depending on the reception this light signal or any light from the other or the other optical Fibers. The light guide can comprise two sub-bundles of optical fibers, which are mixed with each other between the sensor unit and the alarm control, so that it is more difficult for the sake of interference between to distinguish the fibers of the different sub-bundles.

A security alarm system in accordance with the present invention is as follows using an exemplary embodiment with reference to the accompanying drawing explains, which shows the system in schematic form.

An enclosed room 1, which is a safe, vault, The room to be protected is connected to an alarm control unit 2 within a room 3 by a flexible optical fiber line 4 and through a positive and negative electrical feed line 5 and 6. The line 4 consists from a bundle of individual optical fibers, which is divided into two multi-fiber ones Sub-bundles 7 and 8. The fibers of the two sub-bundles 7 and 8 are mixed with one another arranged at least over the part of the line 4, which is between the containers 1 and 3 extends.

The optical fiber line 4 is inside the container 1 with a Sensor unit 9 coupled, which responds to a state in which a penetration or an attempted intrusion into the room 1 or an influence on the unit 9 itself takes place. For this purpose, the unit 9 has one or more sensors which devices can be active or passive and which ones record the alarm condition. In the present case, only one sensor is shown in Form of a normally open switch 10, which depending on the alarm status closes. This switch 10 is connected in series with a diode 11 in parallel to a capacitor 12 of a relaxation oscillator 13. If the switch 10 is open, then the capacitor 12 in the oscillator circuit is charged and discharged. Of the Capacitor 12 charges through resistor 14 during each oscillation cycle and then discharges into a resistor 15 via a transistor 16 when the Capacitor voltage has reached a predetermined value. The predetermined value depends on the value of the Resistor 15, which with a base of transistor 16 is connected and is further dependent on the value of a resistor 17, which is connected to the other base. The one through resistor 15 of the oscillator 13 developing pulse train is via a resistor 18 of the base electrode a transistor 19, the emitter of which is connected to ground. At the collector of the Connected to transistor 19 is a light emitting diode (LED) 20, which in Is connected in series with a current-limiting resistor 21 and which light pulses emitted in accordance with the output pulses of the oscillator 13.

The diode 20 is optically coupled to the end of the fiber bundle 7 within the unit 9, while the end of the other partial bundle 8 is covered (or otherwise arranged) so that no light comes from the diode 20 or from a another source can penetrate into the fibers of the partial bundle 8. The one from the diode 20 emitted light pulses are along the line 4 from the sensor unit 9 to Alarm control unit 2 within room 3 via the individual fibers of the sub-bundle 7 transmitted. In contrast, no light is from the fibers of the partial bundle 8 Unit 9 transmitted.

The two sub-bundles 7 and 8 are within the unit 2 with each a phototransistor 22 and 23 coupled. The transistors 22 and 23 are inside of the unit 2 connected to individual conduction paths of a capacitor 24, which is charged via an adjustable resistor 25 and a resistor 26, which are connected in series. The voltage of the capacitor 24 is compared by two comparators 27 and 28 with respect to the upper and lower voltage limit, which is supplied by a voltage divider chain in the form of three resistors 29, 30 and 31. The outputs of the comparators 27 and 28 are each via a diode 32 and 33 are connected to a common line 34. Both diodes 32 and 33 are non-conductive when the voltage of capacitor 24 is within the narrow range remains, which is formed by the upper and lower limit of the comparison. However, if the voltage of the capacitor 24 rises above the upper comparison limit, then speaks the comparator 27 on, whereby the diode 32 conductive will. If the voltage falls below the lower comparison limit, then he speaks Comparator 28 on, whereby the diode 33 becomes conductive. In both cases the corresponding diode 32 or 33 current through a resistor 35, reducing the potential the common line 34 is reduced. This potential reduction becomes one Signaling device 36 signals so that as a function of a potential reduction a corresponding alarm is generated.

While in the normal state light pulses regularly from the partial bundle 7 to the phototransistor 22 and no light is received by the phototransistor 23 of the partial bundle 8, finds an alternating partial discharge and charge of the capacitor 24 via the resistor 26 instead. During each pulse of light from Sub-bundle 7, the transistor 22 becomes conductive, whereby the capacitor 24 discharges, while during the intervals between successive light pulses the transistor 22 is not conductive, whereby the capacitor 24 charges again. In normal condition, where transistor 22 is alternately conductive and non-conductive, synchronous with the pulses, which are generated in the oscillator 13, the transistor 23 remains non-conductive. the The voltage of the capacitor 24 in this case moves within or outside of that caused by the comparators 27 and 28 defined area. Both diodes 32 and 33 therefore remain in the non-conductive State, whereby the potential on the common line 24 is high, so that the Device 36 gives no alarm.

Changes in the duration or in the frequency of the sub-bundle 7 received pulses cause the voltage of the capacitor 24 to exceed the threshold value range leaves, so that one or the other of the diodes 32 and 33 is conductive, whereby the potential on the line 34 is reduced, whereupon the alarm device is consequently activated 36 is actuated. The same result is obtained with any noticeable Change in the intensity of the received light pulses, as this causes the flow of current is influenced by the transistor 22 and thus the extent of the discharge of the capacitor 24.

The device 36 is correspondingly actuated in the event that that the light pulses are interrupted. In this case, the charging of the capacitor 24 is not interrupted, so that the upper comparison value is exceeded. Will receive any light from transistor 23, which then becomes conductive, then the capacitor 24 is short-circuited so that the comparator 28 responds with the result that the diode 33 becomes conductive, whereby the alarm device 36 is actuated will. The alarm device 36 is operated in this case even if it is periodic Light pulses from transistor 22 are received.

The train of light pulses received by transistor 22 is interrupted and the unit 2 activated for actuating the device 36, as soon as an alarm condition is triggered by closing the switch 10 in the sensor unit 9 is detected. When the switch 10 is closed, the capacitor 12 is short-circuited, so that the Schwingungeñ of the oscillator 13 are interrupted and no more Light pulses are emitted in the partial bundle 7 of the line 4. However, it is Switch 10 is opened and light pulses are emitted into the partial bundle 7, then the unit 2 is also activated by an interference of the line 4. at an interference of the fibers of the sub-bundle 7 of the line 4 is at least one or influences several parameters of the light pulse train, namely pulse intensity, Pulse duration and pulse frequency.

A cutting, tapping, or bridging, and possibly a Pulling the fibers affects at least the light intensity. Should the pulse signal are replaced by a signal to be fed in, then it is necessary that all these parameters are accurately reproduced in order to outsmart the alarm control unit 2 to be able to.

However, there is a problem with the fibers of the sub-bundle 7 to be distinguished from those of the sub-bundle 8. Are the fibers of this sub-bundle arranged mixed with one another between rooms 1 and 3 and has a feed of the replacement signal or any light in any of the fibers of the sub-bundle 8 instead, then unit 2 is activated as a result. That way is a A high level of security in the signal path is achieved in a simple and comparative manner cheap way.

Various modifications can be made to the system described will. If a lower degree of security is tolerated, this can be done by the sensor unit transmitted light signal instead of a pulse-modulated signal a continuous one Be signal. In such a case, the alarm control unit only responds in dependence from an interruption or other change in intensity. For the same Reason, the partial fiber bundles 7 and 8 can be reduced to a fiber bundle, the fiber bundle 8 can then be omitted. Apart from the question of simplification other forms of modulation can be provided. Additional sensor units can be used and other alarm control units built into the system. For the latter are diodes 37 and 38 of a further control unit corresponding to the control unit 2 connected to the common line 34 corresponding to the diodes 32 and 33.

The use of an oscillator such as oscillator 13 in the sensor unit can be avoided by modulating a generated in the alarm control unit Light signal transmitted via another sub-bundle of fibers to the sensor unit wherein the fibers can be mixed with those of the partial bundle 7.

These signals transmitted by the alarm control unit are via the sub-bundle 7 is transmitted back if there is no alarm condition.

The reversal of the signals received by the control unit can be effected are converted into an electrical signal within the sensor as long as there is no alarm condition, this electrical signal is used to activate the light output a light emitting diode corresponding to the diode 20 in the unit 9 to modulate.

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Claims (10)

Claims Safety alarm system in which a sensor unit connected by a signal path for detecting an alarm condition at a first location is with an alarm control at a second location, with the alarm control activated is dependent on signal changes occurring in the signal path as a result of the Detection of the alarm condition by the sensor or an interference in the signal path, as a result, that the signal travels an optical fiber optic cable (4) and that the light signal from the sensor unit (9) of the alarm control unit (2) is transmitted in the light pipe (4). 2. Security alarm system according to claim 1, characterized in that g e k e n n -z e i c h n e t that the sensor unit (9) is a light-emitting device (20) comprises, which for emitting a light signal in one end of the light pipe (4) for transmission of this signal in the direction of the alarm control unit (2) can be controlled electrically is an electrical circuit (13) for generating an electrical signal for controlling the light-emitting device (20) and one or more alarm state sensors (10) are provided with the circuit (13) for interrupting the control signal provided for the light emitting device (20) upon detection of the alarm condition are, the alarm control unit (2) is activated depending on the interruption the reception of the light signal at the other end of the light line (4). 3. Security alarm system according to claim 1 or 2, characterized g e -k e n n z e i c h ne t that the alarm control unit (2) the light intensity of the from you detected by the light pipe (4) received light. 4. Safety alarm system according to one of claims 1 to 3, characterized it is noted that the light signal transmitted by the sensor unit (9) is a modulated light signal and that the alarm control unit (2) at least one the modulation parameter of the signal received by it from the light line (4) recorded. 5. Security alarm system according to one of the preceding claims, in that the alarm control unit (2) is a device (24) for the time integration of a signal which is derived in Correspondence of the light received from the light line (4) and the switching means (27, 28) are provided, which respond when the integrated signal is a predetermined Leaves border area. 6. Security alarm system according to one of the preceding claims, in that the light guide (4) has a large number of optical Includes fibers. 7. Security alarm system according to claim 6, characterized in that g e k e n n -z e i c h ne t that the sensor unit (9) the light signal in only one or some optical fibers of the light line (4) and that the alarm control unit (2) is activated depending on the reception of the light signal from another or other optical fibers (8). 8. The security alarm system according to claim 7, characterized in that it is e k e n nz e i c h n e t that the light guide (4) has two sub-bundles (7, 8) made of optical fibers comprises, which between the sensor unit (9) and the alarm control unit (2) with each other run mixed and that the light signal only in the first of the two partial bundles (7,8) is transmitted and the alarm control unit (2) the light output of both sub-bundles (7,8) recorded. 9. Security alarm system according to claim 8, characterized in that g e k e n n -z e i c h n e t that the light entrance into the second partial bundle (8) is blocked at the sensor unit (9) and the alarm control unit (2) is activated depending on the reception of light from the second partial bundle (8). 10. Security alarm system according to claim 9, characterized in that g e k e n n -z E i c h n e t that the alarm control unit (2) has a first and a second light-sensitive Device (22,23), which electrically on the light output of the first and respond to the second sub-bundle (7,8), the first photosensitive device (22) is connected to an electrical circuit (24 to 26) for generation an electrical signal with an amplitude which is dependent on an or several parameters of the received by this device (22) from the first sub-bundle (7) Light, an electrical measuring circuit (27 to 33) is provided for measuring the Amplitude of the generated signal for actuating an alarm device (36) as a function that the signal amplitude leaves a predetermined range and the second light-sensitive device (23) with the signal-generating circuit (24 to 26), which causes light to be received from the second partial bundle (8), that the signal amplitude leaves the predetermined range.