EP1372124A1 - Alarm detector with commnication interface and alarm system - Google Patents

Abstract

The communications interface (K) is constructed for wireless communication and has corresponding transmission and reception equipment.

Description

The present invention relates to a hazard detector with a sensor for a hazard parameter, evaluation electronics for evaluating the sensor signals, a memory for storing alarm data and a communication interface for communication of the hazard detector with an operating module remote from it.

Modern high-end hazard detectors, such as motion detectors, can be parameterized in many ways and can save data and status information recorded during operation, which is then available for reading from the detector by an authorized person stand. Such data can include, for example, operational information, alarm data of all types, such as for example, the type and time of an alarm, near-alarms, and so on, and for motion detectors with camera, crime scene pictures. Because motion detectors are usually on one Mounted at a height at which they cannot be reached without aids (ladder) would be one Wireless data transmission is a great advantage.

EP-A-0 872 817 describes a hazard detector which is a communication interface for the transmission of data recorded by the detector, which preferably by the light source for alarm display, the so-called alarm indicator, or an additional one Infrared source is formed. The communication interface can also be a receiver for from data sent from an external source, which is preferably through an infrared receiver is formed. This infrared receiver is located inside the detector housing and inaccessible from the outside when the housing cover is closed. For the purpose of data transfer the housing cover must be removed between the detector and an external module and be replaced by a special data transfer cover.

With this hazard detector there is communication between the detector and the external one Module not easy to use. In particular the transfer of data from the module to Detector is very complicated and requires manipulation directly on the detector, so that parameterization the detector or a software update in practice is out of the question. moreover the data transmission distance is severely limited.

The invention is now intended to specify a hazard detector, its communication interface is designed so that data transmission between the detector and external Module in both directions is easily possible. Data communication should be as possible easy to use, and it should in particular be possible with a ceiling height mounted detectors to exchange data.

According to the invention, this object is achieved in that the communication interface is designed for wireless communication and corresponding transmission and reception means having.

This is a first preferred embodiment of the hazard detector according to the invention characterized that the communication interface for communication in the high frequency range, preferably according to the Bluetooth standard, or in the infrared range, preferably according to the IrDA standard, trained and by a transceiver or a separate transmitter and Receiver is formed.

The "Bluetooth" standard is a short-range radio standard that uses carrier frequencies from the "Industrial-", "Scientific-", "Medical-" 2.4 GHz band (ISM band) works and for a wireless Connection of end devices in a radio cell with a radius of up to 10 meters, in particular Allows falls up to 100 meters. "Bluetooth" is a trademark of Bluetooth SIG, Inc.

IrDA is short for "Infrared Data Association", which is an organization that supports the Has defined the industry standard "IrDA DATA" for wireless data transmission using infrared today in many PDAs, cell phones, laptops, watches, printers, digital cameras and so on Data exchange is used.

This is a second preferred embodiment of the hazard detector according to the invention characterized in that the sensor is designed to detect thermal radiation and is exposed to infrared radiation through a window in the housing of the detector, and that the the transceiver or transmitter and receiver forming the communication interface is arranged behind the window.

This is a third preferred embodiment of the hazard detector according to the invention characterized in that the detector has a device for detecting sabotage, which comprises an infrared transmitter and an infrared receiver, and that the infrared transmitter or the infrared receiver through the IrDA transceiver forming the communication interface or IrDA transmitter and IrDA receiver is formed.

The invention further relates to a hazard detection system with at least one sensor for a hazard parameter, evaluation electronics for evaluating the sensor signals, a memory for storing alarm data and a communication interface having hazard detectors and with a portable control module for wireless communication with the at least one hazard detector.

The hazard warning system according to the invention is characterized in that the operating module by a remote control or a computer like a PC, laptop or Handheld is formed and an analog communication interface like the hazard detector and that the two communication interfaces for communication in radio frequency or infrared range are formed.

A first preferred embodiment of the hazard detection system according to the invention is characterized in that the communication interfaces each by a transceiver or a transmitter and receiver are formed, and that communication between Hazard detector and control module according to the IrDA or the Bluetooth standard.

A second preferred embodiment of the hazard detection system according to the invention is characterized in that the hazard detector by the operating module in a data transmission mode is settable.

A third preferred embodiment of the hazard detection system according to the invention is characterized in that the hazard detector automatically switches to data transmission mode sets if the operating module authenticates itself as an allowed partner.

A fourth preferred embodiment of the hazard detection system according to the invention is characterized in that the authentication using a code or a cryptological Procedure takes place.

A fifth preferred embodiment of the hazard detection system according to the invention is characterized in that in data transmission mode a transmission from in the hazard detector stored data, in particular alarm-relevant data and / or crime scene images, to the control module.

A sixth preferred embodiment of the hazard detection system according to the invention is characterized in that a parameterization and / or a in the data transmission mode Software update of the hazard detector is carried out.

Another preferred embodiment is characterized in that the hazard detector A sabotage message when exchanging security-relevant data in transmission mode settles.

Fig. 1

eine schematische Darstellung eines erfindungsgemässen Gefahrenmelders und eines von diesem abgesetzten Bedienungsmoduls in der Art einer Fernbedienung,

Fig. 2

einen Längsschnitt durch einen bekannten Passiv-Infrarotmelder; und

Fig. 3

eine Ansicht in Richtung des Pfeiles III von Fig. 2.

The invention is explained in more detail below on the basis of an exemplary embodiment and the drawings; it shows:

Fig. 1

1 shows a schematic illustration of a hazard detector according to the invention and of an operating module set off from it in the manner of a remote control,

Fig. 2

a longitudinal section through a known passive infrared detector; and

Fig. 3

a view in the direction of arrow III of Fig. 2nd

1 shows a detail of a hazard detection system according to the invention M, for example a passive infrared detector, and a portable one assigned to it Operating module H. The operating module H is used to exchange data with the Detector M; it can be, for example, by a remote control, a PC, a laptop or a Be handheld. In the case of the data exchange mentioned, data is transmitted on the one hand from detector M to control module H (alarm-relevant data; crime scene images, if the detector M is equipped with a camera; Operating data) and on the other hand from the control module H to detector M (parameterization, software update of detector M). To make it possible Both the detector M and the operating module H have this data exchange a communication interface K or K '. The communication interface K, K 'is for trained the IrDA or the Bluetooth standard and has a suitable transceiver or a separate transmitter and receiver.

If the term transceiver is used in the following, this means both a combined transmitter / receiver and separate transmitters and receivers. IrDA refers to the "IrDA DATA" industry standard developed by the Infrared Data Association for wireless data transmission using infrared; For more information, see for example at www.irda.org/standards. The "Bluetooth" standard is a short-range radio standard in the ISM band for the wireless connection of end devices in a radio cell with a radius of up to 10 meters, in special cases up to 100 meters. For more information on Bluetooth, see, for example, at www.bluetooth.com.

If in the following only communication interfaces K, trained for the IrDA standard K 'are called, then this should not be understood restrictively, but always also include the Bluetooth standard.

There are commercially available IrDA transceivers (transmitters / receivers) that meet the IrDA standard. and IrDA transmitter (transmitter) and IrDA receiver (receiver) for data exchange for PDAs, cell phones, laptops, watches, printers, digital cameras, toys and the like. The Communication interfaces K, K 'are each through such a commercially available IrDA transceiver educated. The transmission distance is at least one meter, so even with a hazard detector installed at a height of over three meters is no problem Data communication is possible.

If an operating module H authenticates itself as authorized to communicate with the detector M, the detector sets itself in data transmission mode. This authentication can be done using special codes or a cryptological procedure (e.g. challenge-response sequence) respectively. This prevents an unauthorized control module H accidentally or deliberately puts the detector M into data transmission mode. In In this data transmission mode, software updates are also possible the software block to be replaced is signed by suitable cryptological methods and the Signature in the detector can be checked. When exchanging security-relevant data the detector M issues a sabotage message.

The detector M described in detail with reference to FIGS. 2 and 3 is preferably a passive infrared detector with a housing cover 2 and a detector window 3 provided therein for the passage of infrared radiation falling on the detector from the room to be monitored inside the detector. The detector M is equipped with a so-called anti-mask device provide at least one infrared transmitter and one infrared receiver (see FIGS. 2 and 3), and the IrDa transceiver (communication interface) K forms one of these infrared transmitters or receiver. The operating module H contains, in addition to the communication interface K 'a display D and a keypad T, which for example navigation keys, a Send button and an on / off button.

Fig. 2 shows a longitudinal section through a known passive infrared detector in the direction perpendicular to the rear wall or floor and Fig. 3 shows a view from behind, the Detector rear wall removed and the one focusing the incident infrared radiation Mirror is removed from the detector. According to the illustration, the passive infrared detector is in the essentially of a two-part housing with a bottom 1 and the cover 2, from which Detector window 3 provided in the cover 2 for the area to be monitored from the Infrared radiation falling on the detector from a circuit board 4 arranged inside the detector which, inter alia, an infrared sensor 5 and an evaluation circuit 6 are arranged, and from a mirror 7 also arranged in the interior of the detector for focusing the through the Detector window 3 incident infrared radiation on the infrared sensor 5. The evaluation circuit contains a memory (not shown) for storing operating and alarm data.

The detector window 3, which consists for example of polyethylene or polypropylene, is in inserted a beveled or concave part of the lid 2 and laterally of projections F of the lid 2 limited. The mirror 7 is designed so that it radiation in the near Infrared absorbed and body radiation reflected. Regarding the shape of the mirror, the EP-A-0 303 913 and with regard to the mirror material to EP-A-0 707 294. Das Detector window 3, the mirror 7, the infrared sensor 5 and the evaluation circuit 6 are used for Detection of a person's intrusion into the monitored room. The detector window 3 can be designed as a Fresnel lens and instead of the mirror 7, the infrared radiation on the Focus infrared sensor 5.

The passive infrared detector shown is with a so-called anti-mask device for detection of processes or visual changes immediately before the detector and of changes the optical properties of the detector window 3, in particular sabotage of the Detector, equipped. Such sabotage is used to manipulate the detector in such a way that No infrared radiation can reach the infrared sensor, so that unauthorized persons can no longer be detected and can move freely in the monitored room. sabotage is usually perpetrated during the disarming of the detector when it is in a standby mode is switched on and there are no alarms in the monitored room trigger.

The anti-mask device is designed as follows: On the front of the detector, just above of the detector window 3 are an optical transmitter 8, for example an infrared LED with 950 nm Wavelength, and an optical receiver 9, for example an infrared photodiode, arranged, the transmitter 8 on the outside and the receiver 9 on the inside of the housing cover 2 is located. The transmitter 8 continuously emits infrared radiation from the detector, which is abnormal Operating state in the monitoring room before the detector is emitted. However, as soon as an object is brought close to the detector or is located there, becomes a large part of the Radiation emitted by the transmitter 8 is reflected and passes through the detector window 3 the receiver 9. The resulting increase in received radiation is called a masking attempt interpreted.

In the interior of the detector there is an additional optical one in the area of one of the two wings F Transmitter 10, for example an infrared LED, arranged in a light shaft 11 infrared radiation sends. The light shaft 11 is angled and opens into an infrared transparent Window 12, which in the detector window 3 facing side wall of the relevant projection F is provided. As shown, this projection F is that Transmitter 8 adjacent and opposite the receiver 9 projection. The additional Transmitter 10 emitted infrared radiation passes through the light shaft 11 via a Mirror 11a and the window 12 at a flat angle of incidence on the detector window 3 and passes through it under normal conditions. Through the window 12 is the additional transmitter 10 emitted radiation focused on the center of the detector window 3 and passes through it to the receiver 9.

However, if the detector window 3 has been masked, i.e. made infrared-opaque, then less radiation reaches detector window 3 or that falling on the entrance window Radiation from the additional transmitter 10 is reflected by the detector window 3 and arrives less radiation onto the receiver 9, which is interpreted as a masking attempt. To avoid reflections of the radiation emerging from the window 12 from the additional light source 10 or the radiation emitted by the transmitter 8 on the side walls of the wing F they are provided with an infrared absorbing coating.

One of the infrared transmitters / receivers 8, 10 and 9 of the anti-mask device is through one IrDA transceiver formed and takes over the function of the communication interface K (Fig. 1). This is preferably the receiver 9 located behind the detector window 3. The transmitter 10 is not an option for this task because it is covered by the housing cover 2 Transmitter 8 could of course form the communication interface K.

A differently designed anti-mask device is described in EP-A-1 061 489. At the in This application described detectors are behind the detector window two on the middle of the Detector-aligned infrared transmitter and an infrared receiver arranged between them intended. This is arranged so that the one emitted by the infrared transmitters Radiation to a part dependent on the optical properties of the detector window is reflected on the infrared receiver. This detector therefore has the entire anti-mask device arranged inside the detector. Here is preferably the infrared receiver as a communication interface educated.

Of course, an additional one acting as a communication interface K could also be used Transmitting and / or receiving diode provided and preferably behind the detector window be arranged.

Claims (12)

Hazard detector with a sensor (5) for a hazard parameter, evaluation electronics (6) for evaluating the sensor signals, a memory for storing alarm data and a communication interface (K) for the communication of the hazard detector (M) with an operating module remote from it H), characterized in that the communication interface (K) is designed for wireless communication and has corresponding transmitting and receiving means. Hazard detector according to claim 1, characterized in that the communication interface (K) is designed for communication in the high-frequency range, preferably according to the Bluetooth standard or in the infrared range, preferably according to the IrDA standard, and is formed by a transceiver or a separate transmitter and receiver. Hazard detector according to claim 2, characterized in that the sensor (5) is designed to detect thermal radiation and is exposed to infrared radiation through a window (3) in the housing (2) of the detector (M), and that the communication interface (K ) forming transceivers or transmitters and receivers are arranged behind said window (3). Danger detector according to claim 3, characterized in that the detector (M) has a device (8, 9, 10) for detecting sabotage, which comprises an infrared transmitter (8) and an infrared receiver (9), and that Infrared transmitter (8) or the infrared receiver (9) are formed by the IrDA transceiver or IrDA transmitter and IrDA receiver forming the communication interface (K). Hazard detection system with at least one sensor (5) for a hazard parameter, evaluation electronics (6) for evaluating the sensor signals, a memory for storing alarm data and a communication interface (K) with hazard detectors (M) and with a portable control module (H) for wireless communication with the at least one hazard detector (M), characterized in that the operating module (H) is formed by a remote control or a computer in the manner of a PC, laptop or handheld and an analog communication point (K ') as the hazard detector ( M), and that the two communication interfaces (K, K ') are designed for communication in the high-frequency or infrared range. Hazard detection system according to claim 5, characterized in that the communication interfaces (K, K ') are each formed by a transceiver or a transmitter and receiver, and that the communication between the hazard detector (M) and the operating module (H) according to the IrDA or Bluetooth -Standard is done. Hazard detection system according to claim 5 or 6, characterized in that the hazard detector (M) can be set into a data transmission mode via the operating module (H). Hazard detection system according to claim 7, characterized in that the hazard detector (M) automatically sets itself in the data transmission mode when the operating module (H) authenticates itself as a permitted partner. Hazard detection system according to claim 8, characterized in that the authentication is carried out using a code or a cryptological method. Hazard detection system according to one of Claims 7 to 9, characterized in that, in the data transmission mode, data stored in the danger detector (M), in particular alarm-relevant data and / or crime scene images, is transmitted to the operating module (H). Hazard detection system according to one of claims 7 to 9, characterized in that the data transmission mode is used for parameterization and / or a software update of the hazard detector (M). Hazard detector according to one of claims 7 to 11, characterized in that the hazard detector (M) issues a sabotage message when security-related data is exchanged in data transmission mode.

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