DE10044689A1 - Device for monitoring an area of a room - Google Patents

Abstract

The invention relates to a device for surveilling an area. Said device comprises an image-recording means, especially a sensor array in the form of a two-dimensional image-producing sensor, and an emitting means emitting electromagnetic waves for illuminating a room to be covered by said image-recording means. The emitting means emits electromagnetic waves in a pulsed manner, and the image-recording means records an image within a defined time frame after the electromagnetic waves have been emitted by the emitting means. The beginning and the duration of the emitted electromagnetic pulses, and the temporal distance between the emitted pulse and the beginning and/or end of the image-recording is pre-determined, thus enabling the distance to be pre-determined between the image-recording means and the intersecting plane (E) to be recorded of the room to be surveilled, and/or the spatial depth (h) of the intersecting plane (serial gating method).

Description

The present invention relates to a device for Surveillance of an area, an imaging device having, in particular a sensor array in the form of a flat imaging sensor, and an electromagnetic transmitting waves for lighting nes to be detected by means of the image-receiving means Having space, the transmission means electromagnetic emits waves and the image-taking Average within a certain time window after sending out the electromagnetic waves through the transmission means an image receives.

In the industrial world and other areas there is always the problem that a large area to be monitored against access. This Task cannot always be done with simple sensors like z. B. solve light barriers and motion detectors. Schwiering Problems arise especially when a dyna mixer area monitored and / or a three-dimensional  Area monitoring to be implemented.

The object of the present invention is a Vorrich device for recording and / or monitoring a particular to provide three-dimensional space.

This object is achieved by means of a Vorrich tion according to the features of claim 1 or a Vor direction solved according to the features of claim 11. Further advantageous designs of the devices according to of claims 1 or 11 result from the dependent claims Chen 2 to 10 and 12 to 23.

By means of the device according to claim 1, it is advantageous it is possible to open individual sectional planes of a room to take. This is achieved in that a light pulse of a certain duration to illuminate a Room is sent out. According to the necessary Run time from the illuminant to expose the cutting plane is used after a certain time an image is taken by an image-receiving means. with By means of this method it is possible to create a height profile of the three-dimensional space. This principle can also be called serial gating. benefit A fast CMOS array is used as an imaging sensor sor used. Distortions due to the wide-angle optics can be advantageously compensated for by image processing become. For example, a Sensor array, especially a CCD sensor use fin the. Depending on when the light pulse is emitted imaging points of the sensor array are read out, can thus be targeted individual sectional planes in the room to be sought. The integration time determines the vertical extent, that is the thickness of each cut  tebene. The device can be used advantageously successively different sectional planes of real space take up. However, it is also possible to start from time would take pictures of the same section plane to by comparing these sequentially taken pictures detect a change within the cutting plane len. The comparison of two pictures taken one after the other for example, by means of image processing be carried out by so-called difference image analysis. In particular, there are differences in the gray values of the pictures examined. Results between two pictures a significant or not permitted gray value difference, for example, an alarm signal can be triggered. to However, the image information obtained can be evaluated other image processing methods can also be used. It is also conceivable that by taking pictures of several cutting planes within a period and through Comparison of images, especially three-dimensional objects are recognizable. The device can e.g. B. on detection certain objects that are not in the surveillance An alarm or another may stop the area Trigger event. It is also conceivable that the pre direction monitors the status of a system and when it is switched off occurs from liquids and gases and recognizes them if suitable measures for alarming and / or for Initiates troubleshooting. It is also conceivable that the device after entering an object in the monitoring area a certain process automa table starts. So z. B. air conditioning, music system ge, etc. are turned on when a person has the Be enters richly. The device can also, for example advantageous for monitoring ATMs or rooms Find use. Fixed objects are replaced by the  constant comparison of images automatically recognized that means the system learns the space through constant ver know immediately and can therefore decide whether new objects have come to the room. Depending on the locomotion speed of those in the room to be monitored Objects or people can also do this, for example based on their outlines or other identifying features recognized and possibly classified.

Markings can advantageously be used to limit the area Find use either in one level or in different room levels or sectional planes are, making either a two-dimensional or three-dimensional dimensional range can be determined. The marks who those due to their reflection characteristics and / or contours automatically recognized by the system. As soon as an object Moved over the area limit, the system will knows and it will be a corresponding event, such as An alarm, for example, triggered automatically by the system. It it is possible, for example, that people or objects, wel be in the area with a tag are provided. The system is thus able to these objects or people from others, these oriels characteristics or objects that do not have to distinguish. Once an object or person is in the area to be monitored enters, which ches or which the corresponding marking does not indicates a corresponding event such as an alarm is triggered.

In an advantageous embodiment of the device the room is illuminated by a radiation source, wel electromagnetic waves in the invisible range emits, so that on the one hand interference from daylight  fluctuations are reduced and on the other hand the over area is not visible to the naked eye.

The device according to the invention is described below Drawings explained in more detail.

Show it:

Fig. 1 shows the principle of the Serial-gating process;

FIG. 2 shows the principle of differential image analysis;

Fig. 3 is an area to be monitored for a limiting sponding space by means of corner marks;

Fig. 4 shows a division of the area to be monitored by rectangular markings.

Fig. 1 shows the basic operation of the on device according to claim 1, in which the environment or the area to be monitored is illuminated with a light pulse of short duration. Depending on when the imaging points of the sensor array are read out after the light pulse, sectional planes E ₁ , E ₂ , E ₃ and E ₄ can be viewed in a targeted manner. The integration time, that is to say the time in which the imaging points of the sensor array are charged by the incidence of light, thus determines the vertical extent, that is to say the height h of the planes E ₁ to E ₄ .

At time T ₁ , the illuminant emits a short light pulse of a certain duration. At time T ₂ , the illuminated cutting plane is recorded for a short period of time (integration time) by means of sensor 5 . The duration of the integration time starting with the time T ₂ determines the thickness h _{1 of} the cut plane E ₁ .

Subsequently, the sectional plane E _{2 is} monitored by the illuminant L emitting a short pulse of light at time T ₃ and the sensor S being exposed for a short time starting at time T ₄ , for example by opening the diaphragm or controlling the sensor accordingly. The levels E ₃ and E _{4 can be} recorded accordingly.

Depending on the integration time and the exposure time and the time interval between transmissions the light pulse and taking an image using the Sensor, the cutting plane and its thickness is fixed sets. So it is possible that the cutting planes part overlap or border exactly on each other or but certain sectional planes of the room were not included become.

Fig. 2 shows the comparison of two recorded Bil the B ₁ and B _{2 of} a sectional plane. The area to be monitored 1 is marked by markings 2 . Fixed objects are eliminated by the difference value formation (gray value difference). In contrast, the person P who was not in the area 1 to be monitored in the image B _{1 is} recognized when the difference value is formed. This is shown with the difference value image G and the person P 'shown in dashed lines. Due to the difference, objects O in Figure 6 are no longer available. The area 1 to be monitored is delimited by the markings 2 . Due to the superimposition of the images, the device knows, starting from the image B ₁ or B ₂ , where the limits of the area 1 to be monitored are located. Area marking 2 is shown in Figure 6 only for clarity. When calculating the difference, however, it is deducted, so that it would actually no longer exist in Figure 6.

FIG. 3 shows a further possibility, an area 1 by means markers 3 to be marked. In this case, punctiform markings 3 are arranged only in the corners of the area to be monitored (polygon). From this, the data processing system of the device calculates the area 1 to be monitored.

As an alternative to the above-described markings, it is possible to divide the area to be monitored by means of line-shaped markings 4 into sub-areas a to f, it thereby being possible to determine whether objects or people are either in the area to be monitored or from part of the area to be monitored move to another area or out of the area to be monitored.

It goes without saying that the area markings shown in FIGS. 2 to 4 can also be used for the individual cutting planes E ₁ to E ₄ , that is, that several markings in the room can be arranged one above the other in the room, thereby a arbitrarily shaped area can be defined and monitored. By means of differently marked or shaped markings for different cutting planes, it can be ensured that markings lying one above the other are reliably known. For example, it is also possible to provide markings which are arranged on the floor of the area to be monitored and which, because of their peculiarity, serve as area markings for several cutting planes.

Claims (23)

1. Device for monitoring an area, having an image-receiving means, in particular a sensor array in the form of a flat imaging sensor, and an electromagnetic wave emitting the transmitting means for illuminating a space to be detected by means of the image-receiving means, the transmitting means being electromagnetic Emits waves in a pulsed manner and the image-taking means takes a picture in a certain time window after the electromagnetic waves have been emitted by the transmitting means, characterized in that the start and duration of the emitted electromagnetic pulse, as well as the time interval between the emitted pulse and the start and / or the end of the image recording can be specified, and in this way the distance between the image recording medium and the cutting plane (E) of the space to be monitored and / or the spatial depth (h) of the cutting plane can be specified (serial gating method). 2. Device according to claim 1, characterized ge indicates that the device has several Images of sectional planes (E) of the real room takes up each other. 3. Device according to claim 2, characterized ge indicates that the device is the time pictures of the cut taken one after the other  levels to determine differences with each other compares. 4. Device according to one of claims 1-3, there characterized by that by the Recording of different cutting planes of the real one A three-dimensional image of the room is indirect. 5. Device according to one of claims 1 to 4, there characterized by that the pre direction at intervals, in particular periodically egg ne section plane of the real space and at least least the last two pictures taken Cutting plane compared to each other. 6. The device according to claim 5, characterized ge indicates that in a period after other images of all sectional planes of the real rough mes be recorded and at least the pictures of the the last two recorded periods in one speech cached and compared become. 7. Device according to one of the preceding claims, characterized in that the Device using the determined cutting plane which monitors a 3-dimensional area, whereby especially the cutting planes below each other can have different range limits, which can be assigned or ascertained. 8. Device according to one of the preceding claims, characterized in that the Depth resolution of a section plane image over the  Duty cycle of the lighting source is controlled, in particular the duty cycle equals 6.6 nsec for a depth resolution of 1 m. 9. Device according to one of the preceding claims, characterized in that the Time interval between sending and sensitive switch the at least one image-taking Mit specifies the spatial position of the vertical section. 10. Device according to one of claims 1 to 9, there characterized in that at least a certain image area of a section plane image represents at least one area to be monitored and only differences that in the respective image be richly determined for area monitoring are considered relevant by the device. 11. Device for monitoring an area, an image having a receiving agent, in particular a having electronic camera, wherein a Datenver work system recorded one after the other Images to determine differences in the images compared with each other, thereby known records that at least one particular picture area each represents an area to be monitored represents and only differences in each image area be determined for area monitoring by the Device can be considered relevant. 12. The apparatus of claim 10 or 11, characterized characterized that area marks are arranged in the area to be monitored, wel areas can be detected by means of image processing, and the at least one image area to be evaluated  determine. 13. The apparatus according to claim 12, characterized ge indicates that the area mark rations in particular high contrast or by a be color matched at least in sections from the back take off due to the area to be monitored. 14. The apparatus of claim 12 or 13, characterized characterized that the area mark requirements along the limits of the monitored area rich are arranged. 15. Device according to one of the preceding claims, characterized in that the Device identification and / or classification adornment of itself in the area to be monitored carries out richly moving objects and / or the Be direction of movement of objects determined. 16. The apparatus according to claim 15, characterized ge indicates that object classes exist, those for the surveillance area and not for the include objects belonging to the monitoring area. 17. The apparatus of claim 15 or 16, characterized characterized in that depending on the determined object type and / or the position and / or the direction of movement and / or the course of movement different alarm signals can be generated for an object are. 18. Device according to one of claims 15 to 17, characterized in that the Device in particular different from each other Alarm signals are generated, provided there is at least one  specific object in the direction of the object to be monitored Range moves, and / or at least one be right object in the immediate vicinity and / or inside half of the area to be monitored. 19. Device according to one of claims 15 to 18, characterized in that the Device generates an alarm signal if there is at least one particular object atypical for the monitoring area behaves. 20. Device according to one of the preceding claims, characterized in that the The area is monitored in that the Da processing system the gray values or reflect dance values of the recorded sectional plane images, wel che in particular by means of the "serial gating Procedures "have been added, ver like. 21. Device according to one of the preceding claims, characterized in that the Data processing system for determining sub Eliminate two pictures taken one after the other their gray values or reflectance values a reflect dance picture calculated, the first picture (GWB1) without active lighting of the image area and the second Image (GWB2) with active illumination of the image area is recorded, and the reflectance image is equal to that is the difference GWB2-GWB1 of the two pictures. 22. The apparatus according to claim 21, characterized ge indicates that the images are in time intervals that of 1-10000 msec (milliseconds) in succession, especially in intervals of 10-2000 msec  be taken. 23. Device according to one of the preceding claims, characterized in that the Device has a database, in particular their trained image information to be monitored appropriate two-dimensional and / or three-dimensional Areas for different states are stored, this image information for the detection of Ab switches or to monitor the areas with the currently recorded images or sectional images of the Cutting planes are compared.