The present invention describes a method and a device for simulating shadows and/or simulating noises of a person, particularly in the field of break-in protection and/or security technology or the like.
Various security devices for securing buildings or objects against illegal break-ins or illegal theft are known from the prior art. Here in particular, security devices exist, which prophylactically simulate the presence of people in a building, for example by switching on and off illumination of rooms at predetermined times or by automatic roller-shutter controls, in which roller shutters are automatically moved into an open position at daybreak and into a closed position at nightfall.
Furthermore, a device is known from U.S. Pat. No. 5,442,524 for simulating shadows of a person for improved security and for preventively deterring burglars in a private residence or a place of business. This device comprises a central light source and a cylindrical element rotating around the light source, which element generates the casting of a shadow onto a projection surface, e.g. the inner walls of the building and provokes the impression of a person moving in the building as a result.
In addition, diverse security devices are known from the prior art, which should simulate a switched-on TV set on the basis of flickering, differently coloured light sources, such as flickering LEDs for example.
A further device for simulating shadows of a person is known from the document DE 10 2011 084 325 A1 in the field of break-in protection or security technology. The device comprises a multiplicity of LED lights for imitating basic lighting, which function as a projector, and projects an image or for example the casting of a shadow onto a projection surface, particularly in a room. In this case, the image can be configured in such a manner that the presence of people or animals is simulated by the same. The projected image may in this case be provided on a screen. The device from DE 10 2011 084 325 A1 may likewise comprise a loudspeaker for simulating noises of a person.
These known security devices have the disadvantage that the simulations achieved do not imitate a person moving in a building in a particularly true manner.
One aspect of the present invention provides a method for simulating shadows of a person, particularly in the field of break-in protection and/or security technology or the like, and also a device for carrying out the method, wherein a particularly realistic simulation of a moving person should be reproduced in a simple manner.
According to an embodiment of the invention, the at least two lamps can be activated alternately in such a manner on the basis of the control and switched on or switched off in sequence, so that movements or shadows of a person are simulated. In other words, the at least two lamps connected in sequence may be understood as effect lights, which are superimposed onto a basic lighting.
In the sense of the present invention, at least one lamp, LED lamp in particular, which is switched on constantly, should simulate a switched-on lamp or create basic lighting.
Switching on or switching off in sequence is understood below to mean that the lamps are switched on alternately and in sequence, whilst an earlier lamp is switched off simultaneously or in a crossfading manner. In this case, the activated lamps to be switched on are activated in a sequence or diffusely, i.e. not sequentially.
It was advantageously found in this case that the impression of a person moving in a building can be simulated solely by means of a lamp sequence superimposed onto the basic lighting. The travelling light cones due to the lamps, which are preferably dimmed down or dimmed up in series, simulate such movements.
The at least two lamps, particularly LED lamps, which are switched in sequence, preferably allow a beam angle of 30° to 120°, more preferably 50° to 90°.
According to a preferred embodiment, in one setting of the device according to the invention, only the basic lighting may be switched on, as a result of which the device only functions as a lamp.
Further advantageous embodiments are also disclosed.
Preferably, the sequence circuit is configured in such a manner that in one setting, the at least two lamps can be switched on or switched off in sequence for creating a lamp sequence. As a result, short, i.e. not abrupt, transitions between the travelling light cones are created, and movements of a person which are as realistic as possible can advantageously be imitated.
More preferably, the control is configured in such a manner that in each case, a subsequent lamp, is dimmed up during the dimming down of the preceding lamp in the series. As a result, even softer transitions of the lamps switched in sequence can advantageously be achieved and thus imitate even more realistic movements of a person.
Preferably, the device according to the invention comprises at least one, preferably two, coloured, such as blue and/or red and/or green, LED lamps (preferably RGB LEDs) for simulating a switched-on TV set, wherein the blue LED lamps preferably allow a beam angle between 30° and 120°, more preferably between 50° and 90°. Particularly preferably, the control of the device according to the invention is configured in such a manner that in one setting, the white and blue LED lamps flicker diffusely, i.e. not in sequence, to simulate a switched-on TV set.
According to a preferred embodiment, the device according to the invention may comprise a means for creating the casting of a shadow, for example a silhouette placed between lamps and projection surface and at least partially non-light-permeable, which creates a shadow and can be attached on or integrated in the device for example. Alternatively or additionally, the device may comprise a light-shaping element which is placed between the lamps and the projection surface and is at least partially non-light-permeable. The use of such a light-shaping element has the advantage that the light cones which can theoretically be created can be delimited and, as a result, in particular the overlap of the light cones of adjacent lamps can be delimited in a targeted manner. It has advantageously been shown here that the effect of the shadow effects achieved by the lamp sequence can be influenced as desired, whilst in the case of simultaneous operation of all lamps, a uniform light image (i.e. without strong individual “hotspots”) corresponding to a lamp which is switched on constantly without a simulated movement pattern, can be achieved.
Preferably, the device comprises a transparent or translucent light-permeable cover as protection for the lamps, i.e. this cover lets the created light cones of the lamps pass. Furthermore, it is conceivable that this transparent light-permeable cover has a corrugated structure for example, functions as a diffuser plate as a result and additionally disperses the light cones created by the lamps.
Furthermore, the device according to the invention can, according to a preferred embodiment, comprise a brightness sensor for detecting lamps located outside the device, for example ambient light, for automatically adapting the light intensity of the LED lamps. Alternatively or additionally to a brightness sensor, a computer of the device according to the invention can be equipped with a corresponding software, which adapts the light intensity of the lamps on the basis of day- and night-times.
Preferably, the device comprises at least one loudspeaker connected to the computer for simulating noises of a person. Very particularly preferably, the software stored on the computer is configured in such a manner that the noise simulation is adapted to a simultaneously generated shadow simulation.
Particularly preferably, the device comprises a microphone, wherein the microphone is used for detecting noises of third parties. For example, the microphone can be used for generating an acoustic counter-reaction to the noise of third parties.
A preferred exemplary embodiment of the subject matter of the invention is described in the following in connection with the attached drawings. In the figures:
As indicated dashed, the control 2 is connected to the LED lamps 4; 4′; 5; 5′; 5″; 5′″; 5″″; 6; 6′ for the activation or actuation thereof. The control 2 is in turn connected to a computer 14 (for example Espressif or Raspberry Pi). The computer 14 contains software for actuating the control 2. On the basis of the software stored on the computer 14 and the control 2, the LED lamps 5; 5′; 5″; 5′″; 5″″ functioning as effect lights can be activated in such an alternating manner on the basis of the control 2 and switched on or switched off in sequence, so that the impression of a moving person is created.
Preferably, the device 1 according to the invention can be used in an operating setting as a pure LED lamp, i.e. without constant switching on or switching off of individual LED lamps.
Here, by way of example, the device 1 shown in
Furthermore, the device 1 shown in
A section through the light-shaping element 12, essentially centrally through or along the LED lamps 4′, 5; 5′; 5″; 5′″, which are arranged in a row here, can be seen in
A preferred light-shaping element 12, at least in the longest extent shown in
Preferably, the LED lamps 4, 5; 5′; 5″; 5′″ and the funnel-shaped depressions 13; 13′; 13″ of the light-shaping element 12 are dimensioned in such a manner that the delimited beam angle α1, measured crosswise across the LED lamps 5′; 5″ mounted in the depressions 13′, of preferably 30° to 120°, very particularly preferably approximately 70°, can be achieved, and that the delimited beam angle α2, measured crosswise across the LED lamps 5; 5′″ mounted in the depressions 13″, of preferably 30° to 120°, very particularly preferably approximately 70° can be achieved (cf.
The two white LED lamps 5′; 5″ functioning as effect lights are switched on here and create light cones L1; L2. At the same time, a white, constantly switched-on LED lamp 4′ illuminates an interior of a building with a delimited beam angle β1 of preferably 90° to 180°, very particularly preferably approximately 125°, and forms basic lighting as a result.
For example, here the LED lamp 5′ dims straight down, whilst the LED lamp 5″ dims straight up to create an LED sequence. An observer B outside the building for example sees the light cone L2 of the LED lamp 5″ and a light cone of the LED lamp 4′ on a wall W2.
On the basis of an external control device, here a smartphone 20 by way of example, it may be possible to activate and configure the device 1 for example via the internet and an internet router 22. Preferably, a suitable app is installed on the smartphone 20 for this.
Alternatively or additionally, the device 1 may comprise a Bluetooth module, as a result of which it may also be possible to activate and configure the external control device directly using the device.
Preferably, in addition, one device 1 additionally comprises a user interface, which can be operated manually, in each case.
Number | Date | Country | Kind |
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01083/17 | Aug 2017 | CH | national |
00007/18 | Jan 2018 | CH | national |
Filing Document | Filing Date | Country | Kind |
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PCT/EP2018/073026 | 8/27/2018 | WO |
Publishing Document | Publishing Date | Country | Kind |
---|---|---|---|
WO2019/042940 | 3/7/2019 | WO | A |
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Number | Date | Country |
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10 2009 015466 | Sep 2010 | DE |
10 2011 084325 | Apr 2013 | DE |
10 2014 214114 | Jan 2016 | DE |
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Entry |
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International Search Report, dated Nov. 26, 2018, for PCT/EP2018/073026, filed on Aug. 27, 2018, with English translation. |
English translation of Written Opinion for PCT/EP2018/073026, filed Aug. 27, 2018. |
International Search Report, dated Nov. 26, 2018, for PCT/EP2018/073026, filed on Aug. 27, 2018. |
Written Opinion for PCT/EP2018/073026, filed Aug. 27, 2018. |
Number | Date | Country | |
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20200394885 A1 | Dec 2020 | US |