SE521562C2 - Device for controlling a siren - Google Patents

Abstract

A device for activating a siren 10 having a control unit 14 containing a microcontroller 16 which communicates with siren 10 via a data circuit 12. The siren 10 generates an alarm when communication via the data circuit 12 is interrupted. Monitoring means 18 is provided to monitor the microcontroller 16 and in the event of a fault in the microcontroller 16 ensure that communication with the siren 10 continues.

Description

425 30 = | vw 521 ssz 2 In one embodiment, it is arranged that the second microprocessor sends to the Siren within the framework of a second protocol. The second protocol sent incorrectly is easily structured compared to the first protocol. The second protocol prevents activation of the siren, unless alarm orders are transmitted. Due to the simplified second protocol, the second microprocessor can be designed as a relatively simple electronic building element. The second simplified protocol does not include, for example, error information regarding the siren.

Further embodiments appear from the dependent claims and from the description.

An embodiment is shown in the drawing and will be described in more detail below. Fig. 1 shows a wiring diagram and Fig. 2 a fl fate diagram of the embodiment.

A siren 10 communicates via a serial bus 12 with a controller 14. The controller 14 includes a first microprocessor 16 and a second microprocessor 18. The second microprocessor 18 monitors the first microprocessor 16 for proper operation. The first and second microprocessors 16, 18 can output signals on the serial bus via a transmitter / receiver 20 to communicate with the siren 10. The control device 14 is for example connected via a data bus 22 to a burglar sensor 24.

In normal operation, the controller 14 transmits data via the first microprocessor 16, the transmitter / receiver 20 and via the serial bus 12 with a first protocol P1 to the siren 10. The siren 10 monitors the cyclic transmission process according to protocol P1. When in this protocol P1 an alarm order reaches the siren 10, an acoustic warning signal is generated for a predetermined time. The control device 14 generates e.g. an alarm order when the burglar sensor 24 reports a burglary attempt to the control device 14. This, characteristic of a burglar, the signal change of the burglar sensor 24 10 15 20 '25 30. . | . . s 521 562 3 is evaluated by the first microprocessor 16 and immediately sends an alarm signal to the siren 10 to activate it.

If, in an attempted burglary, for example, it is achieved that the serial bus line 12 is cut by force, then the siren 10 no longer receives the first protocol P1 cyclically. However, this faulty cyclically transmitted data is perceived by the siren 10 as a malfunction if, within a predetermined period of time, no more data arrives via the serial bus 12. Also in this case, the acoustic alarm sensor is activated. To ensure the constant operational readiness of the siren 10, it comprises, for example, a vehicle-independent auxiliary battery, which supplies power to the control electronics of the siren 10.

According to the invention, the second microprocessor 18 monitors the first microprocessor 16 with respect to the occurrence of an error. This can be achieved, for example, by a two-way communication between the two microprocessors 16,18. If the first microprocessor 16 does not respond as expected to a call signal from the second microprocessor 18, then the second microprocessor assumes that there is an error in the first microprocessor 16. This monitoring takes place acyclically at short time intervals. If the second microprocessor 18 detects a fault of the first microprocessor 16, the second microprocessor 18 takes over the communication with the siren 10. The second microprocessor 18 acts on the transmitter / receiver 20 so that it does not pass any signal from the first microprocessor 16 on the serial bus. 12. The second microprocessor 18 generates a second protocol P2 which is now instead of the protocol P1 transmitted over the serial bus 12 to the siren 10. The second protocol P2 may be less complex than the first protocol P 1. For example, the exchange of such information is disregarded if it is a malfunction of the siren or the auxiliary battery integrated there. The second microprocessor 18 now evaluates, instead of the microprocessor 16, the signal from the burglar sensor 24, which reaches the control device 14 via the data bus 22. In an intrusion attempt, which the burglar sensor 24 detects, the second microprocessor 18 generates an alarm order, which via the second protocol P2 is transmitted to the siren 10. If such an alarm order is present, the acoustic signal tone sensor is activated. In the normal case, ie. when no 10 15 - | . . , 521 562 4 alarm command is transmitted, the siren 10 is not activated with a regular data communication carried out via the second protocol P2. Again, if the serial bus is cut and the siren 10 senses the absence of the data communication also on the basis of the second protocol P2, an activation takes place again.

The second microprocessor 18 is in the rest position of the control device 14 in operation to lower the rest current. During the rest position of the control device 14, the second microprocessor 18 takes over the communication with the siren 10 and / or with the data bus 22.

I F ig. 2 shows in simplified form the monitoring procedure of the second microprocessor 18. After starting the controller 14, step 101, the second microprocessor 18 constantly monitors the first microprocessor for errors, step 103. If an error is present, the second microprocessor 18 sends a simplified second protocol P2, step 105. Thus also the monitoring procedure completed, step 107. However, it is repeated cyclically.

Claims (9)

0102585-7 1 5_ i:: i I i20gå_02_2g Patent claim An anti-theft device with a device (14) for controlling a siren, which device comprises a microprocessor (16) which communicates via at least one data line (12) with a siren (10), the siren (10) generating an alarm, if the regular communication via the data line (12) is interrupted, characterized in that monitoring means (18) are provided, which monitor the microprocessor (16) and which, in the event of a fault in the microprocessor (16), take care of the communication via the data line (12) to the siren (10). Device according to Claim 1, characterized in that a further microprocessor (18) is arranged as a monitoring means (18). Device according to one of the preceding claims, characterized in that the further microprocessor (18) takes over the communication via the data line (12) with the siren (10) in the event of a fault in the first microprocessor (16). Device according to one of the preceding claims, characterized in that a serial bus is used as the data line (12). Device according to one of the preceding claims, characterized in that the first microprocessor (16) transmits according to a first protocol (P1) and that the further microprocessor (18) transmits according to a second protocol (P2). Device according to one of the preceding claims, characterized in that the second protocol (P2) is simpler in structure than the first protocol (P1). Device according to one of the preceding claims, characterized in that the siren (10) does not generate an alarm when using the second protocol (P2) unless an alarm command is transmitted in the second protocol (P2). 0102585-7 521 562 i U I i i ' Device according to one of the preceding claims, characterized in that the additional microprocessor (18) takes over the communication with the siren (10) and / or with a data bus (14) connected to the control device (14) during the idle operation of the control device (14). . Device according to one of the preceding claims, characterized in that the second microprocessor (18) is arranged in the control device (14).