• 专利附录
  • 专利说明
  • 权利要求
  • 类似技术
  • 同族专利
  • 引用文献
  • 法律状态
  • 优先权
    • 专利摘要:
    A sensor (10) for controlling an automatic door, the sensor (10) comprising a laser scanner (12) for detecting the presence of an object with at least one laser curtain (22, 32, 34) in a predefined detection region of the scanning field, the sensor (10) comprising a distance data acquisition unit (13) which is implemented to acquire the distances of the reflection points of the signal reflected by a flight time evaluation , a presence detection unit (15), the result of the distance data acquisition unit (13) being fed to the presence detection unit (15), the data acquisition unit of distance (13) transferring the distance data information to the presence detecting unit (15), the presence detecting unit (15) evaluating whether an object is detected within the predefined detection region by data analysis said presence detection information being created and injected into at least one sensor output port (18, 18b). The invention is characterized in that the sensor further comprises an object information unit (11) comprising a human body identification unit (16), the object information unit (11) receiving the distance data, and the human body identification unit (16) using the distance data to determine whether the detected object is a human body, the object information unit (11) creating object information that is injected into the at least one output port (18, 18a).
    公开号:BE1025335B1
    申请号:E2018/5229
    申请日:2018-04-05
    公开日:2019-01-29
    发明作者:Gautier Radermecker
    申请人:Bea S.A.;
    IPC主号:
    专利说明:

    Sensor for controlling an automatic door
    The invention relates to a sensor for controlling automatic doors according to the preamble of claim 1.
    A sensor for controlling an automatic door, the sensor comprising a laser scanner for detecting the presence of an object inside a predefined detection region of its laser curtain, the sensor comprising a presence detection output port at which a presence detection signal is injected. This allows safe operation of the door. The laser scanner deduces reflection points by a distance measurement using a "Time of Flight" technology.
    The objective of the invention is to improve the control possibilities of a sensor to allow more specific behavior.
    The problem is solved by the features of claim 1.
    In a known manner, a door sensor for detecting the presence of an object inside a predefined detection region of the scanning field comprises a laser scanner with at least one laser curtain, the sensor comprising a unit for distance data acquisition which is implemented to acquire the distances from the reflection points of a laser beam reflected from the laser scanner from an object by evaluation of time of flight.
    The sensor further comprises a presence detection unit which receives the distance data information as a result of the distance data acquisition unit, the distance data acquisition unit transferring the data information away from the presence detection unit. The presence detection unit assesses whether an object is detected within a predefined detection region by analyzing distance data. The presence detection unit is implemented to create presence detection information which is injected into at least one sensor output port. Usually this signal is used by door control units for security purposes.
    2018/5229
    BE2018 / 5229
    According to the invention, the sensor further comprises an object information unit comprising a human body identification unit, the object information unit receiving the distance data and the object identification unit. human body using the distance data to determine whether the detected object is a human body, the object information unit creating object information which is injected at the at least one output port.
    Preferably, the signal from the presence detection unit is processed in real time, the result of the human body identification unit being based on an accumulation of distance data. For example, the presence detection signal can have a response time of less than 90 ms. The sensor is able to detect objects that are smaller than 10 cm.
    According to the additional information gathered, a door control unit may act differently by detecting the presence of a human body and the presence of a non-human body.
    According to another aspect of the invention, the object information unit may include a counting unit for counting the number of human bodies detected by the sensor, so that the counting information can be provided on a port Release.
    In addition to basic information which is essential for controlling and / or protecting an automatic door, other additional information such as counting information can be used to control a door, for example keeping it closed after a certain number of human bodies have entered. Additional information can be derived for statistical purposes
    In addition, the laser scanner can generate multiple laser curtains and the object information unit includes a motion detection unit for detecting motion and in particular identifying the direction of movement of an object.
    This object information can be used to control the automatic door, such as triggering the door to open once an approaching object is detected. Therefore, object information can provide some form of approach signal to at least one output port, regardless of the type of object.
    2018/5229
    BE2018 / 5229
    In addition to this, by deducing information about whether an object is a body and information about its direction, more precise counting can take place. Under this option, a net account can be set in a certain direction.
    According to an embodiment of the invention, the sensor comprises an output port, the presence detection information and the object information being injected into the same at least one output port. A CAN bus or LON bus can be suitable output ports to support both types of information.
    In another aspect of the invention, the sensor includes at least two separate output ports, a first output port being dedicated to presence information and a second output port being dedicated to object information. A first output port includes a relay output, while the second output port could, for example, be based on an Ethernet protocol.
    The human body identification unit can be implemented as a computer implemented method, on a processing unit, for example a microprocessor, which performs a computer implemented procedure and can contain other parts of programs that are other units.
    The method for determining a human body on the basis of the distance of the measured reflection points is described in detail below.
    The human body identification unit includes an evaluation unit which combines distance information from the reflection points with the direction of the pulse to retrieve a position within a monitored region, the unit d evaluation combining the reflection points belonging to an object detected in an evaluation plane having a Z axis which is associated with the height and an axis perpendicular to the Z axis which is associated with the width in the direction of the extension side of the laser curtain.
    According to the invention, the evaluation plan is evaluated on the basis of a density distribution on the axis
    Z and the evaluation result is compared to anthropometric parameters by the evaluation unit.
    2018/5229
    BE2018 / 5229
    The monitored region is defined by the laser curtain and has a vertical height direction and two lateral directions, a depth and a width, which are all perpendicular to each other. In the case of a single vertical laser curtain, the depth of the monitored region is equal to the depth of the laser curtain.
    The evaluation plane can have a Z axis which corresponds to the vertical axis of the vertical plane and / or an evaluation width extension which corresponds to the width of the monitored region. However, the Z axis, for example, can be defined along a laser curtain inclined to the vertical direction, but the width can still correspond to the width of the laser curtain.
    Anthropometric parameters according to the invention are measurements of the human body and / or proportions of the human body.
    In particular, anthropometric parameters are parameters that relate in particular to the height, width, shoulder width, shoulder height, head width, total height of a human body.
    Based on the density distribution in the evaluation plan, the evaluation unit decides whether or not the density distribution corresponds to that of a human body.
    To determine if a detected object is a human body, the density distribution along the Z axis is evaluated, the Z axis representing the height of a detected object. The density distribution corresponding to a human body includes two peaks, one peak being approximately at the top of the head and the second peak being approximately at the top of the shoulder.
    The determination is preferably made to determine the ratio of the height of the head to the height of the shoulder. Since the ratio head height to shoulder height is an anthropometric parameter which is essentially equal for all human beings and above all it is not dependent on absolute height, a reliable distinction of human beings is possible according to the density distribution assessment.
    2018/5229
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    In addition to the density distribution, the evaluation unit can evaluate the width of an object in an additional step. Therefore, it analyzes the reflection points in the evaluation plan belonging to an object at the position of the density distribution peaks and determines the effective head and shoulder width of the human body.
    Due to the integration of this information, the assessment can be obtained more precisely. A valid head width and shoulder width ratio can be predefined to check if it corresponds to the result deduced from the evaluation density distribution evaluation. The result can be compared to the result of the density evaluation. If both assessments are positive, it is most likely that the object detected is a human body.
    In addition, the evaluation unit can count the number of reflection points within the peak areas of the density distribution evaluation. If the number is below a predefined number, the measurement will be ignored.
    The movement of the human body takes place in a direction of movement, the direction of movement being essentially a vector of width and depth. In particular, in door applications, the direction of movement is perpendicular to the direction of width and, therefore, the orientation of the shoulders of a human body is usually aligned with the direction of width.
    According to the invention, individual evaluation objects can be identified among all the reflection points of the evaluation plan and a subset of reflection points is created for each evaluation object, which is then subjected to an analysis. density distribution.
    Depending on this, there may be a decision on each evaluation object present as to whether or not it corresponds to a human body. As a result, detection sensors can base their decision to control doors or lights on whether a detected object is a human body or not.
    The determination of individual evaluation objects is carried out by the evaluation unit, the evaluation plan, containing all the reflection points, being analyzed by a neighboring zone, from the top to the bottom of the plan. Once a reflection point or reflection points are
    2018/5229
    BE2018 / 5229 newly present in the neighboring area, all the reflection points inside the neighboring area are taken into account and the newly present reflection point is assigned to an evaluation object. It is assigned to a new evaluation object if there is not another point on the newly present point inside the neighboring area, or to an existing evaluation object if the reflection point has the smallest distance to the mathematical center of gravity of an existing evaluation object.
    According to this procedure, all the reflection points are grouped in a subset of reflection points belonging to an evaluation object.
    According to this assessment, even two or more people walking parallel through the laser curtain can be distinguished.
    According to another improvement of the invention, the reflection points can be integrated in time on the evaluation plan. This leads to a higher density of reflection points and, therefore, evaluation objects can be better distinguished and detected objects can be classified more reliably.
    The time integration can be carried out on the basis of a fixed time interval after a first detection of a detected object has taken place.
    According to another improvement of the invention, integration over time is carried out in such a way that the subset of reflection points is assigned to a temporal object by projection of the reflection points in a width-time plane, the height of the reflection point being ignored. The width axis is extended as a function of a predefined accumulation / integration time.
    The reflection points projected in the time-width plane are grouped into subsets assigned to temporal objects. Each time object is the main set of reflection points to generate the evaluation plan, the time component of the reflection point being neglected but the height being taken into account.
    2018/5229
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    According to this procedure, a more precise decision on the delimitation of temporal objects is possible. Therefore, the information acquired is more precise as to the number of humans passing by.
    The grouping of temporal objects is preferably carried out using a spatial grouping algorithm by density of applications in the presence of noise (DBSCAN).
    Preferably, the scanner generates multiple laser curtains which are inclined with respect to each other. Due to the different laser curtains, a more precise image can be taken and the direction of movement of the object can be taken into account.
    The scanner, preferably, evaluates and / or generates multiple laser curtains in succession.
    By taking into account at least two curtains, which are inclined with respect to each other, two positions of depth perpendicular to the width of the scanning plane can be evaluated. As the two planes are scanned in succession, the direction of movement of a human being can be detected since the center of gravity during a scanning time changes in the time-width diagram in the direction of movement of the detected object.
    When using multiple laser curtains, a predefined accumulation time for time integration is longer or equal to the time it takes to scan the laser curtains present from the sensor.
    The evaluation unit may not accept reflection points which clearly refer to background effects. Therefore, background noise can be reduced at this point.
    The invention further relates to a human recognition sensor for analyzing an object in a monitored region and deciding whether or not the object is a human body, comprising a laser scanner and an evaluation unit which is capable to execute a process as described above.
    2018/5229
    BE2018 / 5229
    Another aspect relates to a sensor which generates at least one laser curtain which is inclined less than 45 ° relative to the vertical axis. This allows aerial scanning so that human bodies can be recognized as they pass under the sensor.
    The human recognition sensor can comprise a computer unit, preferably a microprocessor, a microcontroller or a programmable pre-distributed network (FPGA), on which the evaluation unit is implemented in the form of a software program, executing the method described above.
    Other characteristics, advantages and potential applications of the present invention can be gathered from the description which follows, together with the embodiments illustrated in the drawings.
    Throughout the description, the claims and the drawings, the associated terms and reference numbers will be used as noted in the attached list of reference numbers. In the drawings are represented
    Fig. 1a a schematic view of a door sensor according to the invention;
    Fig. 1 b a schematic view of another embodiment of a door sensor according to the invention;
    Fig. 2
    Fig. 3
    Fig. 4
    Fig. 5a a first embodiment of a sensor according to the invention, having a scanning curtain;
    a principle of operation of the evaluation unit of a human recognition sensor of FIG. 1;
    a second embodiment of a sensor according to the invention, having two scanning curtains;
    an operating principle of the evaluation unit describing a first step by generation of temporal objects;
    2018/5229
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    Fig. 5b an enlarged view of a created temporal object;
    Fig. 6 has a view of the temporal object of FIG. 4b in the evaluation plan;
    Fig. 6b a view of the temporal object after separation of human objects;
    Fig. 7 has a separate human object from FIG. 5b;
    Fig. 7b a density distribution of the human object of FIG. 6a;
    Fig. 8 has a time-width view on the time object of FIG. 4b for the first sweep curtain, and
    Fig. 8b a time-width view for the time object of FIG. 4b for the second curtain.
    Fig. 1a shows a first embodiment of a door sensor 10 according to the invention. The door sensor 10 comprises a laser scanner 12, a processing unit 14, the processing unit 14 comprising an evaluation unit 16 determining whether an object is a human body. The processing unit 14 is connected to the laser scanner 12 as well as to output ports 18a, 18b in such a way that the result of the object information unit 11 is injected into a dedicated output port 18a to provide object information, to which information can be transferred, which contains information relating to results of human recognition, and that information relating to the result of one presence detection unit 15 is injected into another output port 18b dedicated to presence detection. In addition, the processing unit 14 includes a distance determining unit 13 using the flight time to determine the distance from a reflection point. This distance information is injected into the presence detection unit 15 which determines whether the reflection point is due to an object in a critical region. In addition, the processing unit 14 includes a direction determining unit 17 which is capable of deducing the direction of movement of a human body or an object. Preferably, the evaluation unit 16 and the direction determination unit 17 are
    2018/5229
    BE2018 / 5229 grouped in the object information unit 11 so that the two information can be combined and communicated to the output port 18a.
    The laser scanner of the embodiment according to FIG. 1 uses at least two laser curtains which are evaluated by taking into account the point of the reflections which are deduced by pulses of light (where the time of flight (TOF) is determined. According to this determination of time of flight and the direction of the pulse, a position of the reflection point with respect to the laser scanner can be deduced This evaluation can be carried out by the processing unit 14, relevant reflection points being determined and their position being injected into the unit d 16.
    According to this configuration, the evaluation unit 16 receives the data from the reflection point with regard to the laser scanner.
    The evaluation unit 16 then analyzes the point of the reflections according to the invention as will be described in more detail in the following figures and, consequently, it will output a signal containing information as to whether or not an object detected is a human body.
    Figure 1b shows a schematic view of another embodiment of a sensor according to the invention.
    Unlike the example in Figure 1a, the other embodiment includes a common output port 18 for presence detection information as well as object information. For example, a common CAN signal is produced inside the processing unit 14, which is transferred to the output port. When creating the signal, it is essential that the presence detection signal has higher priority than object information to meet security standards.
    Another difference, which is shown in Figure 1b, is that the distance information is first injected into the presence detection unit 15 and then transferred to the object information unit, while Figure 1a shows an example of a principle of operation in parallel.
    2018/5229
    BE2018 / 5229
    The method by which distance data is transferred is independent of the solution of using a common output port or separate output ports. Consequently, these aspects can be combined as required.
    Fig. 2 shows an example of an application where the human recognition sensor 20 is mounted in a high position, there are objects passing beneath it. The human recognition sensor 20 projects in a vertical direction a laser curtain which extends in a direction of width W. It is shown then that a person P moves through the laser curtain 22 in a direction of movement M The passing person P reflects light pulses, the laser scanner of the human recognition sensor 20 evaluating the point of reflection inside the laser curtain.
    The evaluation unit of the sensor 20 is adjusted in such a way that it evaluates an evaluation plane EP which corresponds to the laser curtain 22. Consequently, the evaluation plane EP has a Z axis in a vertical direction and the same axis of width W as the laser curtain 22.
    Fig. 3 shows the process for recognizing the human body by evaluating the EP evaluation plan, in this case the points of reflection not having to be projected into the EP evaluation plan since the EP evaluation plan corresponds to the laser curtain 22. The reflection points are applied to the EP evaluation plan according to their position. The evaluation plan EP has an axis Z and an axis of width W.
    According to the invention, the evaluation unit 16 now calculates a density distribution along the Z axis of the evaluation plane EP, in this density distribution two peaks being assumed to be deducible.
    If there is, for example, only one peak, the measurement is discarded and the object of assessment is not identified as a human body.
    If there are two peaks 24, 26, as would be the case when detecting a human body, the position H1, H2 of the position of the peaks on the Z axis is taken. The first peak 24 is assumed to provide the total height H1 of the object, which is the head when looking at the human body, and the second peak is assumed to be the shoulder height H2 of a person. The ratio of the total height H1 and
    2018/5229
    BE2018 / 5229 of shoulder height H2 is compared to a range of predefined human body proportions. In addition, head height (the distance between shoulder height and total height; H1-H2) can also be taken into account, since the proportions of the human body change with the age of human beings.
    According to this, it is not necessary to limit the measurement to a minimum height which could possibly exclude children from detection, since they can be defined according to the evaluation described above.
    Within the evaluation plan EP, the width W2 of the shoulders and the position H2 of the second density peak 26 can be determined. In the region of the first peak 24, the width of the head W1 can be determined. Due to these additional parameters, a more precise evaluation of the object with regard to recognition of the human body can be obtained.
    Fig. 4 shows a configuration with a human recognition sensor 30 which generates multiple laser curtains 32, 34. The human recognition sensor 30 in this case is mounted above the door frame and monitors the region in front of the door . The laser curtains 32, 34 are inclined with respect to the vertical axis and one with respect to the other and extend parallel to the door in a direction of width W. The evaluation plane EP is defined parallel to the door plan.
    The laser scanner of the human recognition sensor 30 deduces the position of the reflection points of the detected object relative to the laser scanner, the evaluation unit projecting them into the evaluation plan EP as objects of 'Evaluation.
    People P, as they move through the laser curtains 32, 34, produce reflection points during an acquisition period.
    As depicted in FIG. 5a, the acquisition period is approximately 15 seconds. In the case described, four detected objects pass in succession through the laser curtains, two detected objects passing through the laser curtains at the same time. The evaluation unit is implemented to project the points of reflection acquired in a time-width plane.
    2018/5229
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    In this time-width plane, the reflection points present are grouped into time objects TO_1, TO_2, TO_3. This is done using the noise clustering algorithm for application density in the presence of noise (DBSCAN).
    The four objects detected passing through the laser curtain during the acquisition period in this case lead to the definition of three time objects TO_1, TO_2, TO_3.
    As shown in an enlarged view of the time object TO_2, there may be more objects detected in the time object TO_2.
    The evaluation unit is furthermore arranged to take the reflection points of each time object and project them into the evaluation plan EP, as shown in FIG. 6a. The evaluation plan has a vertical axis Z and an axis of width W.
    In a following separation step, the evaluation unit assigns the reflection points of each time object TO_1, TO_2, TO_3 to objects.
    This is done by analyzing the EP evaluation plan from the top to the bottom and by assigning each point to an evaluation object.
    The determination of individual evaluation objects 01 is carried out by the evaluation unit, the evaluation plan EP containing all the reflection points of the time object T0_2. The EP evaluation plan is analyzed by a neighboring zone 40 from the top to the bottom of the EP evaluation plan. Once a reflection point or reflection points are newly present in the neighboring area 40, all the reflection points inside the neighboring area 40 are taken into account and the newly present reflection point is assigned to an evaluation object; for example see in Fig. 6b an object 02 (cross) and an object 01 (circles). It is assigned to a new evaluation object, if there is not another point on the newly present point inside the neighboring area, or to an existing evaluation object when the reflection point has the smallest distance to the mathematical center of gravity of an existing object, 01 or 02. According to this procedure, all the reflection points are grouped in a subset of reflection points belonging to an evaluation object 01.02.
    2018/5229
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    Consequently, FIG. 6b shows that the time object T0_2 in FIG. 5b has been separated into two evaluation objects 01, 02.
    Each object in this evaluation plan, as shown in Fig. 7a, is then subjected to the density distribution analysis along the Z axis, as shown in Fig. 7b. In Figs. 7a, 7b, object 01 is analyzed. The additional assessment to determine whether or not an object is a human body is performed as described in Fig. 3, by comparison of the measurements applied to anthropometric data.
    According to another improvement of the invention, the evaluation unit may be able to analyze the direction of movement of objects. This allows the human recognition sensor to provide direction information with the object information. For example, this allows a count of how many people enter or leave a building or totals itself and simply provides the net count at the port of exit.
    The direction of movement is analyzed by comparison of the reflection points accumulated from the two curtains 32, 34 over a short period of time, for example 500 ms. The reflection points are projected into a time-width plane, in which the mathematical center of gravity of the reflection points present is determined for each curtain.
    According to the displacement of the center of gravity, indicated by the cross in Fig. 8a and in FIG. 8b, the center of gravity passes first through the first curtain 32, then through the second curtain 34, which is then the direction of movement of the object.
    2018/5229
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    List of reference digits human recognition sensor object information unit laser scanner distance determination unit processing unit presence detection unit evaluation unit direction determination unit
    18a output port
    18b output port human recognition sensor laser curtain peak pic human recognition sensor first laser curtain second laser curtain center of gravity center of gravity
    TO_1 time object
    TO_2 time object
    TO_3 time object object object
    EP evaluation plan
    P person
    M direction of travel
    Z axis Z
    W width axis
    2018/5229
    BE2018 / 5229
    Fig. 1a
    Object information
    Distance by TOF
    Presence
    Human body
    Direction
    18a, 18b Exit
    Fig. 1b
    Object information
    Distance by TOF
    Presence
    Human body
    Direction
    Exit
    Fig. 3
    Z axis
    Width (m)
    Density (% of number of points)
    Fig. 5a
    Time (s)
    Width (m)
    Figs. 6a, 6b, 7a
    Height (m)
    Width (m)
    Fig. 7b
    Height (m)
    Density (% of number of points)
    2018/5229
    BE2018 / 5229
    Fig. 8a
    Curtain 1
    Time (s)
    Width (m)
    Fig. 8b
    Curtain 2
    Time (s)
    Width (m)
    权利要求:
    Claims (15)
    [1]
    1. Sensor (10) for controlling an automatic door, the sensor (10) comprising a laser scanner (12) for detecting the presence of an object with at least one laser curtain (22, 32, 34) in a detection region predefined scanning field, the sensor (10) comprising a distance data acquisition unit (13) which is implemented to acquire the distances from the reflection points of the reflected signal by a time of flight evaluation, a unit presence detection unit (15), the result of the distance data acquisition unit (13) being injected into the presence detection unit (15), the distance data acquisition unit (13 ) transferring the distance data information to the presence detection unit (15), the presence detection unit (15) evaluating whether an object is detected within the predefined detection region by analyzing the data distance, information of presence detection being created and injected into at least one sensor output port (18,18b), characterized in that the sensor further comprises an object information unit (11) comprising an identification unit body (16), the object information unit (11) receiving the distance data, and the human body identification unit (16) using the distance data to determine whether the object detected is a human body, the object information unit (11) creating object information which is injected into the at least one output port (18, 18a).
    [2]
    2. Sensor according to claim 1, characterized in that the object information unit (11) comprises a counting unit for counting the number of human bodies detected by the human body detection unit (16) , so that counting information is injected at at least one output port (18,18a).
    [3]
    3. Sensor according to claim 1 or 2, characterized in that the laser scanner (12) generates multiple laser curtains (32, 33) and the object information unit comprises a movement detection unit for recognizing the movement of an object, preferably the direction of movement of an object.
    [4]
    4. Sensor according to any one of these preceding claims, characterized in that the output port (18,18a, 18b) is a physical or wireless port.
    2018/5229
    BE2018 / 5229
    [5]
    5. Sensor according to any one of the preceding claims, characterized in that the presence information and the object information are injected at the same output port (18).
    [6]
    6. Sensor according to any one of the preceding claims, characterized in that the sensor comprises at least two output ports, a first output port (18b) being dedicated to presence information and a second output port (18a) being dedicated to object information.
    [7]
    7. Sensor according to claim 5, characterized in that the presence information has a higher priority than that of the object information.
    [8]
    8. Sensor according to one of the preceding claims, characterized in that it comprises a computer unit (14) which is capable of carrying out a process for recognizing a human body.
    [9]
    9. A human body recognition method according to claim 8, characterized by the analysis of a detected object (P) in a monitored region and by decision as to whether or not the detected object is a human being with a laser curtain (12), comprising:
    the laser scanner (12) generates at least one laser curtain (22, 32, 34), each laser curtain (22, 32, 34) being generated by multiple pulses evaluated by measurement of time of flight (TOF) of individual pulses to generate the distance of the reflection points from the position of the laser scanner;
    a combination of distances from the reflection points with the direction of the pulse to recover a position in a predefined detection area within a monitored region; project the reflection points belonging to an object detected in an evaluation plan (EP) as evaluation objects (01.02), the evaluation plan (EP) having a Z axis which is associated with the height and an axis perpendicular to the Z axis which is associated with the width in the direction of the lateral extension of the laser curtain (22, 32, 34), the evaluation plane (EP) being evaluated on the basis of the density distribution of the reflection points along the Z axis and the evaluation result being compared to anthropometric parameters.
    2018/5229
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    [10]
    10. Method according to claim 9, characterized in that the anthropometric parameters are measurements of the human body and / or proportions of the human body.
    [11]
    11. Method according to claim 10, characterized in that the reflection points belonging to an evaluation object (01, 02) are evaluated on the basis of a density distribution over the height, from which are deducted accordingly a head height (H1) and a shoulder height (H2), and the anthropometric parameter is the ratio head height (H1) to shoulder height (H2), which is compared to a predefined range for a human body .
    [12]
    12. Method according to any one of claims 9 to 11, characterized in that the head height (H1) and the shoulder height (H2) are deduced by evaluation of the peaks (24, 26) of the distribution of density.
    [13]
    13. Method according to any one of claims 9 to 11, characterized in that the evaluation plane (EP) is evaluated due to the density distribution over the height, a head width (W1) and a width shoulder (W2) being deducted by taking the width (W1, W2) at the peaks of the corresponding density distribution.
    [14]
    14. The method of claim 13, characterized in that the anthropometric parameter is the ratio head width (W1) to shoulder width (W2), which is compared to a predefined range for a proportion of human body.
    [15]
    15. Method according to any one of claims 10 to 13, characterized in that the reflection points are integrated in time over an acquisition period.
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    同族专利:
    公开号 | 公开日
    CN110720051A|2020-01-21|
    WO2018189192A1|2018-10-18|
    BR112019021181A2|2020-04-28|
    US20210011160A1|2021-01-14|
    BE1025335A1|2019-01-24|
    JP2020516911A|2020-06-11|
    EP3388863A1|2018-10-17|
    AU2018253351A1|2019-11-21|
    CA3059268A1|2018-10-18|
    EP3610292A1|2020-02-19|
    KR20190133769A|2019-12-03|
    SG11201909262SA|2019-11-28|
    引用文献:
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    法律状态:
    2019-02-25| FG| Patent granted|Effective date: 20190129 |
    优先权:
    申请号 | 申请日 | 专利标题
    EP17165848.7A|EP3388863A1|2017-04-10|2017-04-10|Sensor for controlling an automatic door|
    EP17165848.7|2017-04-10|
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