EP0233576A1 - Alarm-system - Google Patents

Abstract

The alarm system with autonomous alarm sensors (1-4) and alarm transmitters excited by the alarm sensors manages without central equipment. The alarm sensors, which cannot be switched off, can be set up arbitrarily in a new arrangement at any time. Every alarm sensor (1-4) contains a sensor, an alarm triggering circuit to which an exciter signal circuit transmitting an exciter signal and an alarm transmitter are connected, and a receiving circuit which responds to the exciter signal of another alarm sensor and which is also connected to the alarm triggering circuit. Alarm sensors (1-4) act on one another in direct mutual interaction in any number independently of any central equipment. <IMAGE>

Description

The invention relates to an alarm system with autonomous alarm sensors and alarm generators excited by the alarm sensors.

Known alarm systems require a scheduled installation of the alarm sensors in connection with a central device. The alarm system is designed according to an installation plan. This plan can be determined by unauthorized persons with more or less effort, so that the alarm system can be deactivated. In addition, a conventional alarm system contains a switch-off stage that can be triggered by a code. As a result, a conventional alarm system is very sensitive and is relatively easy to turn off and ineffective.

The object of the invention is to provide an alarm system which does not require a central device and whose alarm sensors which cannot be switched off can be set up at any time and in new distribution.

This object is achieved according to the invention in that each alarm sensor contains a sensor, an alarm trigger circuit, to which an exciter signal circuit emitting an excitation signal and an alarm transmitter are connected, and a receiving circuit responsive to the excitation signal of another alarm sensor, which is also connected to the alarm trigger circuit , and that alarm sensors interact in any number, regardless of a central device, in direct mutual influence.

The alarm system according to the invention differs from the prior art in that all alarm sensors have equal rights. Each alarm sensor responds with its sensor to a change in the environment to be monitored and gives when a change is detected an alarm signal. In addition, an excitation signal is emitted to excite further alarm sensors. When a single alarm sensor is excited, all of the system's alarm sensors are excited and emit alarm signals. The effect of an alarm sensor can thereby be multiplied. The alarm sensors can be installed in any distribution without a fixed installation plan. This distribution can be changed at any time. It is therefore not possible for unauthorized persons to deactivate the alarm system. Once an alarm sensor is energized, it can no longer be switched off, possibly until the energy source is exhausted. Even if an unauthorized person were able to remove or destroy a single alarm sensor, this would not significantly impair the effectiveness of the overall system, since all alarm sensors are equivalent, equal and equally sensitive. The individual autonomous alarm sensors are comparatively inexpensive, so that the entire alarm system can be adapted to the respective need for protection. The protective effect of the alarm system is already given by a small number of alarm sensors. The greater the number of alarm sensors, the more the protective effect is multiplied.

The individual sensors respond to changes in the environment in a manner known per se. The sensors can respond to changes in position, changes in force, changes in lighting, shocks, influences of sound, accelerations. You can provide sensors of any kind in the individual alarm sensors.

A complete autonomous energy supply for each alarm sensor is achieved in that a battery is used as the energy source for each alarm sensor.

Mutual influence of the individual alarm sensors is ensured in that the excitation signal circuit generates a high-frequency transmission signal and that the receiving circuit responds to this high-frequency transmission signal. A high-frequency signal can be easily extracted from the basic signal level of the environment. Other telecontrol signals such as ultrasound signals, light signals and the like can also be used.

A particularly effective alarm is ensured in that the alarm transmitter emits an acoustic alarm signal itself.

• Fig. 1 eine schematische Gesamtdarstellung eines Alarmsystems nach der Erfindung und
• Fig. 2 ein Blockschaltbild eines Alarmsensors.

An embodiment of the invention is explained below with reference to the accompanying drawing, in which:

• Fig. 1 is a schematic overall representation of an alarm system according to the invention and
• Fig. 2 is a block diagram of an alarm sensor.

An alarm system according to the invention can comprise any number of alarm sensors. 1 shows a system with four alarm sensors 1, 2, 3, 4, each of which is autonomous, that is to say independent of an external energy supply, and has equal rights with one another.

The structure of an alarm sensor is explained with reference to FIG. 2. The alarm sensor contains a sensor 7, which responds to a state of the environment to be monitored, and a receiving circuit 8, which responds to an excitation signal from another alarm sensor. An alarm trigger circuit 9 is present within the alarm sensor and responds to output signals from the sensor 7 and the receiving circuit 8. The alarm trigger circuit transmits a signal to an excitation signal circuit 10 on the one hand and to an alarm transmitter 11 on the other hand. Finally, an energy source 12, e.g. a battery is provided. The energy source 12 is connected to all switching stages and supplies them with energy. Individual connections are shown in Fig. 2.

The sensor 7 responds to an environmental condition. The sensor 7 can be position-dependent, force-dependent, acceleration-dependent. It can also respond to light signals, acoustic signals, impact sound and any other environmental signals caused by unauthorized intruders. As soon as the sensor 7 responds and emits a signal, the alarm trigger circuit 9 is excited. This cannot be switched off after a single excitation. The alarm trigger circuit turns on the excitation signal circuit 10, which outputs an excitation signal. It can be a high-frequency signal that is emitted via an antenna 13. The signal can be encoded to prevent interference with other signal sources. The antenna 13 is simultaneously the transmitting antenna and the receiving antenna. The receiving part of the antenna 13 is connected to the receiving circuit. The receiving circuit 8 responds to excitation signals from any other alarm sensor of the alarm system and also acts on the alarm trigger circuit 9. This ensures that all alarm sensors of the system are energized as soon as any alarm sensor is excited by an unauthorized influence.

Furthermore, the alarm trigger circuit 9 acts on an alarm transmitter 11, which generates an acoustic alarm signal, for example. Each alarm sensor contains such an alarm device and can generate an acoustic alarm signal send out. Of course, other alarm signals can also be provided. The alarm signal from the alarm transmitter can also be transmitted to a stationary facility. In any case, it is important that each individual alarm sensor emits such an alarm signal. As a result, a large number of alarm signals are generated in accordance with the large number of alarm sensors, which lead to enormous confusion of the unauthorized intruder.

1 shows how when any alarm sensor 1, 2, 3 or 4 is excited, all other alarm sensors are excited. The excitation can reach all other alarm sensors directly from one alarm sensor, or the excitation can propagate from one alarm sensor to neighboring alarm sensors.

The whole system is triggered when any alarm sensor is excited. This excitation state remains after a single excitation, since the receiving circuits are designed as latching circuits. So the excitement cannot be recalled. The excitation can be ended after a predetermined time. In the simplest case, the excitation stops after the battery is exhausted.

Claims (4)

1. Alarm system with autonomous alarm sensors and alarm sensors excited by the alarm sensors, characterized in that each alarm sensor (1 ... 6) has a sensor (7), an alarm trigger circuit (9) to which an exciter signal circuit (10) emitting an exciter signal and a Alarm transmitters (11) are connected, and contains a receiving circuit (8) which responds to the excitation signal of another alarm sensor and which is also connected to the alarm trigger circuit (9), and that alarm sensors (1 ... 6) in any number regardless of a central device interact with each other in direct mutual influence. 2. Alarm system according to claim 1, characterized in that a battery is used as the energy source (12) of each alarm sensor. 3. Alarm system according to claim 1 or 2, characterized in that the excitation signal circuit (10) generates a radio frequency transmission signal and that the receiving circuit (8) responds to this radio frequency transmission signal. 4. Alarm system according to one of claims 1 to 3, characterized in that the alarm transmitter (11) emits an acoustic alarm signal itself.

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