EP3008705A1

EP3008705A1 - Break-in sensor for monitoring an entrance to a building to be monitored, and method

Info

Publication number: EP3008705A1
Application number: EP14733542.6A
Authority: EP
Inventors: Christian Reichert; Julian Bartholomeyczik; Frank Schindler; Qiulu DAI
Original assignee: Robert Bosch GmbH
Current assignee: Robert Bosch GmbH
Priority date: 2013-06-10
Filing date: 2014-06-05
Publication date: 2016-04-20
Anticipated expiration: 2034-06-05
Also published as: US20160117918A1; CN105283909A; US9799209B2; WO2014198621A1; DE102013210747A1; EP3008705B1; CN105283909B

Abstract

The present invention relates to a break-in sensor for monitoring an entrance to a building to be monitored, wherein the break-in sensor is arranged on the inside of the building on the entrance, comprising: an acceleration sensor, which is designed to detect motions of the break-in sensor in at least one spatial axis and to output an acceleration signal in the event of a motion in the at least one axis; an environment sensor, which is designed to detect at least one value of at least one physical variable in the environment of the break-in sensor; and a plausibility-checking device, which is designed to check the plausibility of the acceleration signal by means of the detected value of the physical variable and to output a break-in signal in the event of the plausibility check being passed. The present invention further relates to a corresponding method and to an alarm system having a break-in sensor according to the invention.

Description

Description title

BURGLAR SENSOR FOR MONITORING ACCESS TO AN OUTSTANDING BUILDING AND METHOD

The present invention relates to a burglary sensor for monitoring access to a building to be monitored, wherein the burglary sensor is disposed at the access on the inside of the building. Furthermore, the present invention relates to a method for monitoring access to a building to be monitored.

PRIOR ART In many applications it is important today to detect the unauthorized opening of a door or a window. For example, building alarms may include intrusion detectors located on the individual doors and windows of a building that serve to detect the opening of the door or window. If the alarm system is turned on, it can trigger an alarm in case of unauthorized opening of a door or a window of the building and an alarm signal, e.g. to a central registration office or the police.

The detection of unauthorized opening a door or a window of a building, so a burglary through the door or the window, for example, by a sensor which is adapted to detect vibrations or vibrations caused by the burglary on the door or occur in the window.

DE60200401 1587T2 shows a conventional burglary sensor for monitoring a building.

These vibrations can be caused, for example, by the burglary tool applied to the door lock or the window, eg a lockpick or other lock picking instruments. But these shocks can also, for example, by the exercise of raw violence on the door to separate the door lock of the corresponding recording in the door frame are caused. This is the case when entering the door, for example.

The sensor is usually attached to the inside of the door or window, so on the inside of the building. In this case, the sensor usually detects accelerations in all three spatial axes at the same time and reports them to the alarm system or to a microcontroller integrated into the sensor, which transmits an intrusion signal to the alarm system. If a sensor is mounted on the inside of the door or the window, which monitors only a movement in the three spatial axes, false alarms can be triggered very easily because the sensor can not detect the actual cause of the vibration. If, for example, a child located inside the apartment on the floor encounters a door equipped with a sensor as described above, it can not be ruled out that the sensor triggers an intruder alarm, although no intrusion occurs. Since the sensor detects only the vibrations of the door, he can not differentiate whether the door was shaken by a legitimate or by an unauthorized person.

DISCLOSURE OF THE INVENTION The present invention discloses a burglary sensor having the features of claim 1 and a method having the features of claim 6.

Accordingly, there is provided: an intrusion sensor for monitoring access to a building to be monitored, the intrusion sensor being located at the access on the inside of the building, having an acceleration sensor configured to detect movements of the intrusion sensor in at least one spatial axis; in the case of a movement in the at least one axis, output a movement signal, in particular an acceleration signal, with an environment sensor which is designed to have at least one value of at least one physical variable in the surroundings of To detect burglary sensor, and with a plausibility device, which is designed to plausibilize the motion signal, in particular the acceleration signal, with the detected value of the physical quantity and output a burglary signal in a negative plausibility.

It is also provided:

A method for monitoring access to a building to be monitored, comprising the steps of detecting a movement of the access in at least one spatial axis and outputting a motion signal, in particular an acceleration signal, in the case of a movement in the at least one axis, detecting at least one value at least one physical quantity in the vicinity of the access on the inside of the building, plausibility of the movement signal, in particular the acceleration signal, with the detected value of the physical quantity, and output of a break-in signal in the event of a negative plausibility check.

Finally, it is planned:

An alarm system, with an alarm transmitter, which is designed to issue an alarm, and with at least one burglary sensor according to the invention, which is designed to transmit a burglary signal to the alarm device.

Advantages of the invention

The finding underlying the present invention is that detection of movements in three axes alone is not sufficient to avoid false triggering in a burglary sensor. The idea underlying the present invention is now to take this knowledge into account and to provide a burglar sensor which, in addition to detecting the movements of the access to a building, detects further physical quantities in order to make the output of the acceleration sensor plausible. In particular, the present invention provides physical quantities for the

Plausibility check, which allows the sensor to infer Whether a person is on the outside of the access to the building or on the inside of the entrance to the building.

If the acceleration sensor detects a movement of the access, e.g. a jolting on a door, detected and issued an acceleration signal, a value of at least one of the physical quantities is detected and used for plausibility of the acceleration signal.

If the acceleration signal is positively plausibilized, ie if a person is located on the inside of the building in the vicinity of the access, no alarm is triggered despite the acceleration signal output by the acceleration sensor.

If the acceleration signal is negatively plausibilized, ie if no person is located on the inside of the building in the vicinity of the access, an alarm is triggered on the basis of the acceleration signal output by the acceleration sensor.

Thus, the present invention makes it possible to significantly reduce the number of false alarms of a burglary sensor and thereby to increase the field of application and the acceptance of such a sensor.

Advantageous embodiments and further developments emerge from the dependent claims and from the description with reference to the figures. In one embodiment, the environmental sensor is designed as a temperature sensor, which is designed to detect the temperature in the vicinity of the burglary sensor. Since a person has a body temperature of about 37 ^< Ό, using a temperature sensor, the temperature on the inside of the building in the vicinity of the access can be detected and used to determine the presence of a person. This allows a precise plausibility of the acceleration signal.

In one embodiment, the environmental sensor is designed as a moisture sensor, which is designed to detect the humidity in the vicinity of the burglary sensor. A person changes the temperature in their environment with their presence, as already described above. At the same time, the air Moisture of air in the environment of a person. The use of a humidity sensor therefore allows a further plausibility check of the acceleration signal.

In one embodiment, the environmental sensor is designed as a sensor which is designed to detect a plurality of physical variables simultaneously in the vicinity of the intrusion sensor. By combining multiple physical quantities, the plausibility check can be further improved.

In one embodiment, the plausibility checker comprises a memory and is configured to store at predetermined intervals a detected value of the physical quantity and to calculate an average of the detected values of the physical quantity. If an average value for the acquired values of the physical variable is formed, the course of the physical variable can be used over time during the plausibility check.

In one embodiment, the plausibility check device is configured to calculate a long-term mean value for all detected values of the physical quantity. This makes it possible to obtain a very stable mean, e.g. to be calculated in air-conditioned rooms. Additionally or alternatively, the plausibility check device is configured to calculate a moving average for a predetermined number of detected values of the physical quantity. This allows the mean to be adjusted in changing environmental conditions, e.g. with temperature fluctuation during the course of a day.

In one embodiment, the intrusion sensor has a data interface configured to communicate with an air conditioner of the building and to interrogate therefrom the current building temperature. The requested building temperature can also be used for a comparison with the detected value of the physical quantity.

In one embodiment, when an acceleration signal is output by the acceleration sensor, the plausibility-checking device is configured to query a current value of the physical quantity from the environmental sensor and to compare it with the average value, and to positively check the acceleration signal if the current value of the physical quantity changes less than a given Threshold deviates from the mean, and negative plausibility of the acceleration signal, if the current value of the physical quantity deviates by more than the predetermined threshold value of the mean value. This allows the

Plausibility to adapt to different applications.

For example, the threshold can be adjusted so that not only temperature changes by adults but also by children can be made plausible. However, the threshold value may also be set such that changes in temperature or other changes in a physical quantity by animals, e.g. Cats or dogs can be used for an accurate plausibility check.

The above embodiments and developments can, if appropriate, combine with each other as desired. Further possible refinements, developments and implementations of the invention also include combinations of features of the invention which have not been explicitly mentioned above or described below with regard to the exemplary embodiments. In particular, the person skilled in the art will also add individual aspects as improvements or additions to the respective basic form of the present invention.

Brief description of the drawings

The present invention will be explained in more detail with reference to the exemplary embodiments indicated in the schematic figures of the drawings. It shows:

Fig. 1 is a block diagram of an embodiment of a burglary sensor according to the invention;

2 shows a flow chart of an embodiment of a method according to the invention;

Fig. 3 is a block diagram of another embodiment of an inventive

Intrusion sensor; 4 shows a flowchart of a further embodiment of a method according to the invention; Fig. 5 is a block diagram of a building with an embodiment of a burglary sensor according to the invention. In all figures, the same or functionally identical elements and devices - unless otherwise stated - have been given the same reference numerals.

In the context of this patent application, access to a building means any access to a building which can be closed by a movable shutter. Accesses according to the invention can be designed as doors, windows and the like.

As an acceleration sensor is considered in the context of this patent application, each sensor which is adapted to absorb acceleration, movement, vibration or the like in at least one of the three spatial axes. An acceleration sensor according to the invention can also record acceleration, movement, vibration or the like in all three spatial axes.

In the context of this patent application, a positive plausibility check means that the plausibility check indicates that a person is staying on the inside of the building near the entrance, so that the presence of the person can be ascertained by the detection of the physical quantities.

In the context of this patent application, a negative plausibility check means that the plausibility check shows that no person is on the inside of the building near the entrance.

DETAILED DESCRIPTION FIG. 1 shows a block diagram of an embodiment of a burglary sensor 1 according to the invention.

The burglary sensor 1 in FIG. 1 is arranged on a door 2 and has an acceleration sensor 4, which is coupled to a plausibility check device 9. Furthermore, the burglary sensor 1 in FIG. 1 has an environmental sensor 6, which is likewise coupled to the plausibility check device 9. The burglary sensor of Fig. 1 is used to monitor the door 2, which is an access to a monitored building. In this case, the burglary sensor 1 is arranged on the door 2 on the inside of the building.

The acceleration sensor 4 serves to detect movements of the burglary sensor 1 in at least one spatial axis. This is always the case when the door 2 is moved or is e.g. a burglar on the door 2 to create. In the case of a movement of the door 2, the acceleration sensor 4 outputs an acceleration signal 5 to the plausibility check device 9.

The environmental sensor 6 detects a value 7 of the temperature 8 in the vicinity of the burglary sensor 1. The environmental sensor 6, in one embodiment, may also be configured to additionally or alternatively include other physical quantities 8, e.g. the humidity 8, to detect. The detected value of the temperature 8 is provided by the environmental sensor 6 of the plausibility check device 9. The environment sensor 6 may be formed in other embodiments as any sensor that is capable of detecting the presence or absence of a person or other living thing. This can e.g. be an infrared sensor.

Finally, the plausibility check device 9 plausibilizes the acceleration signal 5 with the aid of the detected values 7 of the temperature 8. In the case of a negative plausibility check, the plausibility check device 9 outputs a break-in signal 10. If the environmental sensor 6 is adapted to additionally or alternatively include other physical quantities 8, e.g. the humidity 8, these recorded values can also be used in the plausibility check.

2 shows a flow chart of an embodiment of a method according to the invention.

The method according to the invention provides in a first step S1 to detect a movement of the access 2, 3 in at least one spatial axis and to output an acceleration signal 5 in the case of a movement in the at least one axis in a second step S2. In a third step S3, at least one value 7 of at least one physical variable 8 in the vicinity of the access 2, 3 on the inside of the building 14 is detected.

The method also provides for the plausibility check S4 of the acceleration signal 5 with the detected value 7 of the physical quantity 8 and the output S5 of a break-in signal 10 in the case of a negative plausibility check.

3 shows a block diagram of a further embodiment of a burglary sensor 1 according to the invention.

The intrusion sensor 1 of FIG. 3 is based on the intrusion sensor 1 of FIG. 1 and differs therefrom in that the plausibility check device 9 has a memory 11 and is designed to store a detected value 7 of the physical quantity 8 at predetermined intervals and calculate an average value 12 of the detected values 7 of the physical quantity 8.

In this case, the plausibility check device 9 forms a long-term mean value 12 for all detected values 7 of the physical quantity 8. In one embodiment, the plausibility checker 9 can also calculate a moving average value 12 for a given number of detected values 7 of the physical quantity 8.

Plausibilisierungseinrichtung 9 of FIG. 3 is further adapted to query when outputting an acceleration signal 5 by the acceleration sensor 4, a current value 7 of the physical quantity 8 of the environmental sensor 6 and to compare with the average value 12.

If the current value 7 of the physical quantity 8 deviates from the mean value 12 by more than a predetermined threshold value 13, the plausibility checker 9 plausibly checks the acceleration signal 5 and no break-in signal 10 is output.

If the current value 7 of the physical quantity 8 deviates from the mean value 12 by less than the predetermined threshold value 13, the plausibility checker 9 plausibly checks the acceleration signal 5 and an alarm is triggered or a break-in signal 10 is output. In one embodiment, the environmental sensor 6 is designed as a sensor 6, which is designed to detect a plurality of physical variables 8 simultaneously in the vicinity of the burglary sensor 1. For example, the sensor 6 can detect temperature and humidity.

In one embodiment, the burglary sensor 1 has a data interface which is designed to communicate with an air conditioning system of the building 14 and to query the current building temperature therefrom. The requested building temperature can also be used for comparison with the detected value of the physical quantity 8.

4 shows a flowchart of a further embodiment of a method according to the invention. The method of FIG. 4 is based on and differs from the method of FIG. 2 in that the plausibility check step S4 provides for storing at predetermined intervals a detected value 7 of the physical quantity 8 S6 and a mean value 12 of the detected values 7 to calculate the physical quantity 8 S7. In this case, when calculating S7 the mean value 12, a long-term mean value 12 for all detected values 7 of the physical quantity 8 can be calculated. Additionally or alternatively, in calculating S7 of the mean value 12, a moving average 12 can be calculated for a predetermined number of detected values 7 of the physical quantity 8. Furthermore, in the case of a plausibility check S4, the method provides that when an acceleration signal 5 is output by the acceleration sensor 4, a current value 7 of the physical quantity 8 is detected S8 and compared with the mean value 12 S9.

In this case, the acceleration signal 5 is positively plausibilized if the current value 7 of the physical quantity 8 deviates from the mean value 12 by more than a predetermined threshold value 13. Furthermore, the acceleration signal 5 is negatively plausibilized if the current value 7 of the physical quantity 8 deviates from the mean value 12 by less than the predetermined threshold value 13. 5 shows a block diagram of an alarm system 16 with an embodiment of a burglary sensor 1 according to the invention. The alarm system 16 is arranged in a building 14. The building 14 of FIG. 5 is shown only schematically by two wall sections 14, which have an opening in which a window 3 is arranged, on which an inventive intrusion sensor 1 is arranged.

By an arrow running in a curve, the opening direction of the window 3 is displayed in Fig. 5. The opening direction in FIG. 5 is shown merely by way of example and does not necessarily have to be limited to the vertical spatial axis shown in FIG. 5. Should the door / window be damaged with great force, e.g. also give a rotational tilting movement, which is not exclusively described by the vertical axis of space.

The alarm system 16 has an alarm transmitter 15, which is coupled to the burglary sensor 1.

The burglary sensor 1 is designed to transmit to the alarm generator 15 a burglary signal 10, which then outputs an alarm.

Although the present invention has been described above by means of preferred embodiments, it is not limited thereto, but modifiable in a variety of ways. In particular, the invention can be varied or modified in many ways without deviating from the gist of the invention.

Claims

claims

1 . Intruder sensor (1) for monitoring an access (2, 3) to a building (14) to be monitored, the intrusion sensor (1) being arranged on the access (2, 3) on the inside of the building (14) an acceleration sensor (4), which is designed to detect movements of the burglary sensor (1) in at least one spatial axis and, in the case of a movement in the at least one axis, to output a motion signal, in particular an acceleration signal (5); with an environmental sensor (6) which is designed to detect at least one value (7) of at least one physical variable (8) in the vicinity of the burglary sensor (1); and with a plausibility check device (9), which is designed to make the motion signal, in particular the acceleration signal (5), plausible with the detected value (7) of the physical variable (8) and, in the case of a negative plausibility check, a break-in signal (10). issue.

2. burglary sensor according to claim 1,

characterized in that

the environmental sensor (6) is designed as a temperature sensor, which is designed to detect the temperature in the vicinity of the burglary sensor (1), and / or a moisture sensor is designed, which is adapted to the humidity in the environment of Intrusion sensor (1) to detect.

3. Burglary sensor according to one of the preceding claims,

characterized in that

the plausibility check device (9) has a memory (11) and is designed to store at predetermined intervals a detected value (7) of the physical quantity (8) and an average value (12) of the detected values (7) of the physical quantity (7) 8).

4. burglary sensor according to claim 3, characterized,

in that the plausibility check device (9) is designed to calculate a long-term mean value (12) for all detected values (7) of the physical quantity (8); and / or that the plausibility check device (9) is designed to calculate a moving average (12) for a predetermined number of detected values (7) of the physical quantity (8).

5. burglary sensor according to claim 3,

characterized in that the plausibility check device (9) is designed to interrogate a current value (7) of the physical variable (8) from the environmental sensor (6) when the acceleration signal (5) is output by the acceleration sensor (4) and the average value (7). 12) and to plausibilize the acceleration signal (5) positively if the current value (7) of the physical quantity (8) deviates from the mean value (12) by more than a predetermined threshold value (13); and negatively plausibility checking the acceleration signal (5) if the current value (7) of the physical quantity (8) deviates from the mean value (12) by less than the predetermined threshold value (13).

6. A method for monitoring an access (2, 3) to a building to be monitored (14), comprising the steps of:

Detecting (S1) a movement of the access (2, 3) in at least one spatial axis and outputting (S2) a motion signal, in particular an acceleration signal (5), in the case of a movement in the at least one axis;

Detecting (S3) at least one value (7) of at least one physical quantity (8) in the vicinity of the access (2, 3) on the inside of the building (14);

Plausibilizing (S4) the motion signal, in particular the acceleration signal (5), with the detected value (7) of the physical quantity (8); and Outputting (S5) a break-in signal (10) in the event of a negative plausibility check.

7. The method according to claim 6,

wherein upon detection (S3) of at least one value (7) of at least one physical variable (8) the temperature and / or the humidity is detected.

8. The method according to any one of claims 6 and 7,

wherein the plausibility check (S4) provides to store at predetermined intervals a detected value (7) of the physical quantity (8) (S6) and to calculate an average value (12) of the detected values (7) of the physical quantity (8) (S7 ).

9. The method according to claim 8,

wherein in calculating (S7) the mean value (12) a long-term mean value (12) is calculated for all the detected values (7) of the physical quantity (8); and / or wherein in calculating (S7) of the mean value (12) a moving average value (12) is calculated for a predetermined number of acquired values (7) of the physical quantity (8).

10. The method according to claim 8,

wherein in the plausibility check (S4), when an acceleration signal (5) is output by the acceleration sensor (4), a current value (7) of the physical quantity (8) is detected (S8) and compared with the mean value (12) (S9), and the acceleration signal (5) is positively plausibilized if the current value (7) of the physical quantity (8) deviates from the mean value (12) by less than a predetermined threshold value (13); and the acceleration signal (5) is rendered negative plausibility if the current value (7) of the physical quantity (8) deviates from the mean value (12) by more than the predetermined threshold value (13).

1 1. Alarm system (16), with an alarm transmitter (15), which is designed to output an alarm; and with at least one burglary sensor (1) according to one of claims 1 to 6, which is designed to transmit an intrusion signal (10) to the alarm transmitter (15).