JP2021147223A - Elevator user detection system - Google Patents

Abstract

To correctly detect elevator users by suppressing erroneous detection attributed to the brightness of a floor face, and reflect a detection result on door opening/closing control.SOLUTION: An elevator user detection system includes brightness measuring means, camera setting adjusting means, detection means, and door opening/closing control means. The brightness measuring means measures the brightness of a floor face of at least one of a car stop and a car by using an image obtained from a camera. The camera setting adjusting means adjusts setting information including at least one of an exposure time and a gain of the camera according to the brightness of the floor face measured by the brightness measuring means. The detection means detects a user present on the floor face from the image of the camera adjusted by the camera setting adjusting means. The door opening/closing control means controls a door opening/closing operation of a door of the car on the basis of a result of the detection by the detection means.SELECTED DRAWING: Figure 1

Description

An embodiment of the present invention relates to an elevator user detection system.

Normally, when the elevator car arrives at the landing and opens the door, the door closes and departs after a predetermined time has passed. At that time, since the elevator user does not know when the car will close, he / she may hit the door in the middle of closing when he / she gets on the car from the landing. In order to avoid such a collision of the door at the time of boarding, there is a system that detects a user who gets in the car by using an image taken by a camera and reflects the detection result in the door opening / closing control.

Japanese Patent No. 6092433

In the system described above, the presence or absence of a user is determined by utilizing the fact that the brightness of the image changes due to the movement of the user. However, if the shadow of the user is reflected in the image, the movement of the shadow may be erroneously detected as the user. Especially when the floor surface is bright, shadows appear clearly, so that the frequency of false positives increases.

The problem to be solved by the present invention is to provide an elevator user detection system capable of suppressing false detection due to the brightness of the floor surface, correctly detecting the user, and reflecting it in the door opening / closing control. That is.

The elevator user detection system according to the embodiment is installed in the car and detects the user from the image of the camera that captures the vicinity of the door of the car and the landing. The elevator user detection system includes a brightness measuring means, a camera setting adjusting means, a detecting means, and a door opening / closing control means.

The brightness measuring means measures the brightness of at least one floor surface of the landing and the car using the image obtained from the camera. The camera setting adjusting means adjusts setting information including at least one of the exposure time and the gain of the camera according to the brightness of the floor surface measured by the brightness measuring means. The detection means detects a user existing on the floor surface from the image of the camera adjusted by the camera setting adjustment means. The door opening / closing control means controls the door opening / closing operation of the car door based on the detection result of the detection means.

FIG. 1 is a diagram showing a configuration of an elevator user detection system according to the first embodiment. FIG. 2 is a diagram showing a configuration of a portion around an entrance / exit in the car according to the same embodiment. FIG. 3 is a diagram showing an example of a photographed image of the camera in the same embodiment. FIG. 4 is a flowchart showing a user detection process when the door of the user detection system according to the same embodiment is opened. FIG. 5 is a diagram for explaining a coordinate system in real space in the same embodiment. FIG. 6 is a diagram showing a state in which the captured images in the same embodiment are divided into blocks. FIG. 7 is a diagram showing an example of a photographed image when the floor surface of the landing in the same embodiment is bright. FIG. 8 is a diagram showing an example of a photographed image when the floor surface of the landing of FIG. 7 is photographed brightly. FIG. 9 is a diagram showing an example of a photographed image when the floor surface of the landing in the same embodiment has an intermediate brightness. FIG. 10 is a diagram showing an example of a photographed image when the floor surface of the landing of FIG. 9 is photographed darkly. FIG. 11 is a diagram showing an example of a photographed image when the floor surface of the landing in the same embodiment is dark. FIG. 12 is a diagram showing an example of a photographed image when the floor surface of the landing is photographed brightly. FIG. 13 is a flowchart showing a camera setting adjustment process of the user detection system in the same embodiment. FIG. 14 is a diagram for explaining a method of setting a measurement area in the same embodiment. FIG. 15 is a diagram for explaining the brightness level of the floor surface in the same embodiment. FIG. 16 is a diagram showing the relationship between the detection area set in the car and the measurement area in the second embodiment.

Hereinafter, embodiments will be described with reference to the drawings.
The disclosure is merely an example, and the invention is not limited by the contents described in the following embodiments. Modifications that can be easily conceived by those skilled in the art are naturally included in the scope of disclosure. In order to clarify the explanation, in the drawings, the size, shape, etc. of each part may be changed with respect to the actual embodiment and represented schematically. In a plurality of drawings, the corresponding elements may be given the same reference numbers and detailed description may be omitted.

(First Embodiment)
FIG. 1 is a diagram showing a configuration of an elevator user detection system according to the first embodiment. Although the description will be given here by taking one car as an example, the same configuration is used for a plurality of cars.

A camera 12 is installed above the doorway of the car 11. Specifically, the camera 12 is installed in the curtain plate 11a covering the upper part of the entrance / exit of the car 11 with the lens portion tilted directly downward, or on the landing 15 side or the inside of the car 11 by a predetermined angle. ..

The camera 12 is a small surveillance camera such as an in-vehicle camera, has a wide-angle lens or a fisheye lens, and can continuously capture images of several frames (for example, 30 frames / second) per second. For example, the camera 12 is activated when the car 11 arrives at the landing 15 on each floor, and takes a picture including the vicinity of the car door 13 and the landing 15. The camera 12 may be in constant operation when the car 11 is in operation.

The shooting range at this time is adjusted to L1 + L2 (L1 >> L2). L1 is a shooting range on the landing side, and has a predetermined distance from the car door 13 toward the landing 15. L2 is a shooting range on the car side, and has a predetermined distance from the car door 13 toward the back of the car. Note that L1 and L2 are ranges in the depth direction, and the range in the width direction (direction orthogonal to the depth direction) is at least larger than the width of the car 11.

At the landing 15 on each floor, a landing door 14 is installed at the arrival port of the car 11 so as to be openable and closable. The landing door 14 engages with the car door 13 when the car 11 arrives to open and close. The power source (door motor) is on the car 11 side, and the landing door 14 only opens and closes following the car door 13. In the following description, it is assumed that the landing door 14 is also open when the car door 13 is open, and the landing door 14 is also closed when the car door 13 is closed.

Each image (video) continuously captured by the camera 12 is analyzed and processed in real time by the image processing device 20. Although the image processing device 20 is taken out from the car 11 for convenience in FIG. 1, the image processing device 20 is actually housed in the curtain plate 11a together with the camera 12.

The image processing device 20 includes a storage unit 21 and a detection unit 22. The storage unit 21 is composed of a memory device such as a RAM. The storage unit 21 has a buffer area for sequentially storing images taken by the camera 12 and temporarily storing data necessary for processing of the detection unit 22. The storage unit 21 may store an image that has undergone processing such as distortion correction, enlargement / reduction, and partial cropping as preprocessing for the captured image.

The detection unit 22 is composed of, for example, a microprocessor, and detects a user near the car door 13 by using an image captured by the camera 12. When the detection unit 22 is functionally divided, it is composed of a detection area setting unit 22a, a detection processing unit 22b, a brightness measurement unit 22c, and a camera setting adjustment unit 22d. These may be realized by software, may be realized by hardware such as an IC (Integrated Circuit), or may be realized by using software and hardware in combination.

The detection area setting unit 22a sets at least one detection area for detecting the user on the captured image obtained from the camera 12. In the present embodiment, the detection area E1 for detecting the user at the landing 15 is set. Specifically, the detection area setting unit 22a sets the detection area E1 including the sills 18 and 47 from the entrance / exit of the car 11 and having a predetermined distance L3 toward the landing 15 (see FIG. 3).

The detection processing unit 22b detects a user or an object existing in the landing 15 by using the image in the detection area E1 set by the detection area setting unit 22a. The "thing" includes, for example, a user's clothes and luggage, and a moving body such as a wheelchair. In the following explanation, when "user is detected", it is assumed that "thing" is included.

The brightness measuring unit 22c measures the brightness of at least one floor surface of the landing 15 and the car 11 using the image obtained from the camera 12. In the present embodiment, the brightness measuring unit 22c measures the floor surface 16 of the landing 15, and measures the brightness of the floor 16 of the landing 15 using, for example, the brightness value of the image.

The camera setting adjustment unit 22d adjusts the setting information including at least one of the exposure time and the gain of the camera 12 according to the brightness of the floor surface 16 measured by the brightness measurement unit 22c. The "exposure time" is the time during which the image pickup element provided in the camera 12 is exposed through the lens, and corresponds to the shutter opening time at the time of shooting. The longer the exposure time, the brighter the image can be obtained. The "gain" is a coefficient for increasing or decreasing the output value of the camera 12. If the value of the gain is increased, the output value of the camera 12 is also increased, so that a bright image can be obtained.

Both the exposure time and the gain may be adjusted according to the brightness of the floor surface 16, or either one may be adjusted. However, increasing the gain also amplifies the noise contained in the image, so it is preferable to adjust the exposure time in consideration of image quality. Further, if the exposure time is too long, a moving subject will be blurred, so it is preferable to limit the exposure time so that it does not exceed a predetermined value. The elevator control device 30 may have some or all of the functions of the image processing device 20.

The elevator control device 30 includes a computer equipped with a CPU, ROM, RAM, and the like. The elevator control device 30 controls the operation of the car 11. Further, the elevator control device 30 includes a door opening / closing control unit 31.

The door opening / closing control unit 31 controls the opening / closing of the car door 13 when the car 11 arrives at the landing 15. Specifically, the door opening / closing control unit 31 opens the car door 13 when the car 11 arrives at the landing 15, and closes the door after a predetermined time has elapsed. However, if the user is detected by the detection processing unit 22b while the door closing operation of the car door 13 is in progress, the door opening / closing control unit 31 prohibits the door closing operation of the car door 13 to prohibit the door closing operation of the car door 13. 13 is reopened in the fully open direction to maintain the door open state.

FIG. 2 is a diagram showing a configuration of a portion around the entrance / exit in the car 11.
A car door 13 is provided at the entrance and exit of the car 11 so as to be openable and closable. In the example of FIG. 2, a double door double door type car door 13 is shown, and the two door panels 13a and 13b constituting the car door 13 open and close in opposite directions along the frontage direction (horizontal direction). .. The "frontage" is the same as the entrance / exit of the car 11.

Front pillars 41a and 41b are provided on both sides of the doorway of the car 11, and surround the doorway of the car 11 together with the curtain plate 11a. The "front pillar" is also referred to as an entrance / exit pillar or an entrance / exit frame, and a door pocket for storing the car door 13 is generally provided on the back side. In the example of FIG. 2, when the car door 13 is opened, one door panel 13a is housed in a door bag 42a provided on the back side of the front pillar 41a, and the other door panel 13b is provided on the back side of the front pillar 41b. It is stored in the door bag 42b.

A display 43, an operation panel 45 on which a destination floor button 44 and the like are arranged, and a speaker 46 are installed on one or both of the front pillars 41a and 41b. In the example of FIG. 2, the speaker 46 is installed on the front pillar 41a, the display 43 and the operation panel 45 are installed on the front pillar 41b. Here, a camera 12 having a wide-angle lens is installed in the central portion of the curtain plate 11a above the entrance / exit of the car 11.

FIG. 3 is a diagram showing an example of a captured image of the camera 12. The upper side is the landing 15 and the lower side is the inside of the car 11. In the figure, 16 indicates the floor surface of the landing 15, and 19 indicates the floor surface of the car 11. E1 represents a detection area.

The car door 13 has two door panels 13a and 13b that move on the car sill 47 in opposite directions. The same applies to the landing door 14, which has two door panels 14a and 14b that move in opposite directions on the landing sill 18. The door panels 14a and 14b of the landing door 14 move in the door opening / closing direction together with the door panels 13a and 13b of the car door 13.

The camera 12 is installed above the doorway of the car 11. Therefore, when the car 11 opens at the landing 15, as shown in FIG. 1, a predetermined range (L1) on the landing side and a predetermined range (L2) in the car are photographed. Of these, a detection area E1 for detecting a user riding in the car 11 is set in a predetermined range (L1) on the landing side.

In the real space, the detection area E1 has a distance of L3 from the center of the entrance / exit (frontage) toward the landing direction (L3 ≦ the shooting range L1 on the landing side). The width W1 of the detection area E1 when fully opened is set to a distance equal to or greater than the width W0 of the entrance / exit (frontage). The detection area E1 is set including the sills 18 and 47 and excluding the blind spots of the three-sided frames 17a and 17b, as shown by diagonal lines in FIG. The size of the detection area E1 in the lateral direction (X-axis direction) may be changed according to the opening / closing operation of the car door 13. Further, the size of the detection area E1 in the vertical direction (Y-axis direction) may be changed according to the opening / closing operation of the car door 13.

The operation of this system will be described below by dividing it into (a) user detection processing and (b) camera setting adjustment processing.

(A) User detection processing
FIG. 4 is a flowchart showing a user detection process when the door is opened in this system.

First, as an initial setting, the detection area setting process is executed by the detection area setting unit 22a of the detection unit 22 provided in the image processing device 20 (step S10). This detection area setting process is executed as follows, for example, when the camera 12 is installed or when the installation position of the camera 12 is adjusted.

That is, the detection area setting unit 22a sets the detection area E1 having a distance L3 from the doorway to the landing 15 in a state where the car 11 is fully opened. As shown in FIG. 3, the detection area E1 includes the sills 18 and 47 and is set excluding the blind spots of the three-sided frames 17a and 17b. Here, when the car 11 is fully opened, the size of the detection area E1 in the lateral direction (X-axis direction) is W1, and the width of the entrance / exit (frontage) is W0 or more.

Here, when the car 11 arrives at the landing 15 on an arbitrary floor (Yes in step S11), the elevator control device 30 opens the car door 13 and waits for a user to board the car 11 (step S12). ).

At this time, the camera 12 installed at the upper part of the doorway of the car 11 captures a predetermined range (L1) on the landing side and a predetermined range (L2) in the car at a predetermined frame rate (for example, 30 frames / second). The image processing device 20 acquires images taken by the camera 12 in chronological order, and while sequentially storing these images in the storage unit 21 (step S13), executes the following user detection processing in real time. (Step S14). As preprocessing for the captured image, distortion correction, enlargement / reduction, and partial cropping of the image may be performed.

The user detection process is executed by the detection processing unit 22b of the detection unit 22 provided in the image processing device 20. The detection processing unit 22b extracts images in the detection area E1 from a plurality of captured images obtained by the camera 12 in time series, and detects the presence or absence of a user or an object based on these images.

Specifically, as shown in FIG. 5, the camera 12 has an X-axis in a direction horizontal to the car door 13 provided at the entrance / exit of the car 11, and a direction from the center of the car door 13 to the landing 15 (car door 13). An image is taken with the Y-axis in the direction perpendicular to the vehicle 11 and the Z-axis in the height direction of the car 11. By comparing the part of the detection area E1 in block units in each image taken by the camera 12, the foot position of the user moving in the direction of the landing 15 from the center of the car door 13, that is, in the Y-axis direction. Detect movement.

FIG. 6 shows an example in which the captured image is divided into a matrix in predetermined block units. A grid of Wblocks on each side of the original image is called a "block". In the example of FIG. 6, the vertical and horizontal lengths of the blocks are the same, but the vertical and horizontal lengths may be different. Further, the block may have a uniform size over the entire image, or may have a non-uniform size such that the vertical (Y-axis direction) length is shortened toward the upper part of the image.

The detection processing unit 22b reads out each image held in the storage unit 21 one by one in chronological order, and calculates the average luminance value of these images for each block. At that time, it is assumed that the average luminance value for each block calculated when the first image is input as the initial value is held in the first buffer area (not shown) in the storage unit 21.

When the second and subsequent images are obtained, the detection processing unit 22b detects the average luminance value for each block of the current image and the average luminance value for each block of the previous image held in the first buffer area. Compare with. As a result, when there is a block having a brightness difference equal to or larger than a preset threshold value in the current image, the detection processing unit 22b determines the block as a moving block. When determining the presence or absence of motion with respect to the current image, the detection processing unit 22b holds the average luminance value for each block of the image in the first buffer area for comparison with the next image. After that, in the same manner, the detection processing unit 22b repeats determining the presence or absence of movement while comparing the brightness values of each image in block units in chronological order.

The detection processing unit 22b checks whether or not there is a moving block in the image in the detection area E1. As a result, if there is a moving block in the image in the detection area E1, the detection processing unit 22b determines that a user or an object exists in the detection area E1.

When the presence of a user or an object is detected in the detection area E1 when the car door 13 is opened by such a method (Yes in step S15), the user from the image processing device 20 to the elevator control device 30. A detection signal is output. By receiving this user detection signal, the door open / close control unit 31 of the elevator control device 30 prohibits the door closing operation of the car door 13 and maintains the door open state (step S16).

Specifically, when the car door 13 is fully opened, the door opening / closing control unit 31 starts a door opening time counting operation, and closes the door when a predetermined time T (for example, 1 minute) is counted. When the user is detected during this period and the user detection signal is sent, the door opening / closing control unit 31 stops the counting operation and clears the counting value. As a result, the open state of the car door 13 is maintained during the time T.

If a new user is detected during this period, the count value is cleared again, and the car door 13 is maintained in the open state during the time T. However, if the user comes many times during the above time T, the car door 13 cannot be closed indefinitely. Therefore, an allowable time Tx (for example, 3 minutes) is provided and this allowable time is set. It is preferable to forcibly close the car door 13 when Tx has passed.

When the counting operation for the time T is completed, the door opening / closing control unit 31 closes the car door 13 and departs the car 11 toward the destination floor (step S17).

In the flowchart of FIG. 4, the explanation is made assuming that the car door is opened, but the same applies when the door is closed, and it is detected during the period from the start of the door closing to the full closing (during the door closing operation). When a user or an object is detected in the area E1, the door closing operation is temporarily suspended.

(B) Camera setting adjustment process As described above, the user detection process detects the movement of the user from the change in the brightness of the image in the detection area E1. However, for example, due to the light of lighting equipment or the light of sunlight, shadows of users and doors are reflected in the captured image, and the movement of the shadows appears as a change in brightness on the image, resulting in false detection as a user. There are times. In particular, when the color of the floor surface 16 of the landing 15 is bright, shadows are strongly reflected in the captured image, so that the possibility of erroneous detection increases.

Therefore, in the present embodiment, when the floor surface 16 of the landing 15 has a brightness at which shadows are likely to appear, the influence of shadows on the captured image is reduced by adjusting the setting information (exposure time, gain) of the camera 12. This is intended to prevent false positives. As will be described later, the “brightness in which shadows are likely to appear” includes, for example, a case where the floor surface 16 has a brightness close to white and a case where the floor surface 16 has an intermediate brightness between white and black.

Specific examples are shown in FIGS. 7 to 12.
-When the floor surface 16 of the landing 15 is bright As shown in FIG. 7, when the floor surface 16 of the landing 15 is a bright color (for example, white), the camera 12 is used regardless of the color of the clothes of the user P1. The shadow S1 of the user P1 appears strongly in the captured image. In such a case, the setting information of the camera 12 is raised to brightly photograph the floor surface 16 of the landing 15. That is, the exposure time and gain values set in the camera 12 are increased so as to shoot brightly. The specific adjustment method of the exposure time and the gain will be described later.

When the floor surface 16 is bright, by shooting brighter, as shown in FIG. 8, the shadow S1 is blown out and disappears, or remains thin, so that only the user P1 can be detected. Become. For example, if a thin shadow S1 is formed on the white floor surface 16 (luminance value “255”), the brightness value of the shadow S1 becomes about “233”. By shooting brightly, the brightness value of the shadow S1 becomes “255”, which is the same as that of the floor surface 16, and the shadow S1 becomes invisible, so that false detection of the shadow S1 can be prevented. At this time, the user P1 is also photographed brightly, but since the contrast with the floor surface 16 is maintained by the clothes and shoes of the user P1, the user P1 can be detected.

-When the floor surface 16 of the landing 15 has an intermediate brightness As shown in FIG. 9, it is assumed that the floor surface 16 of the landing 15 has an intermediate brightness color (for example, gray). In this case, if the photograph is taken brightly, the shadow S1 of the user P1 may be emphasized. Therefore, it is preferable to lower the setting information of the camera 12 to darken the floor surface 16 of the landing 15. That is, the exposure time and gain values set in the camera 12 are lowered to take a dark image. As a result, as shown in FIG. 10, the contrast between the shadow S1 reflected in the captured image and the floor surface 16 is lowered, and erroneous detection of the shadow S1 can be prevented.

-When the floor surface 16 of the landing 15 is dark As shown in FIG. 11, when the floor surface 16 of the landing 15 is a dark color (for example, black), the shadow S1 of the user P1 becomes the color of the floor surface 16. Since it does not appear confusingly, the possibility of false detection is low. Therefore, it is not always necessary to adjust the setting information of the camera 12 for the purpose of preventing false detection of the shadow S1.

However, if the floor surface 16 is dark, it may not be possible to distinguish between the user P1 and the floor surface 16, so it is preferable to raise the setting information of the camera 12 and shoot brightly. By shooting brightly, as shown in FIG. 12, the contrast between the user P1 and the floor surface 16 increases on the captured image, so that the user P1 can be detected correctly.

Adjusting the setting information of the camera 12 according to the brightness of the floor surface 16 of the landing 15 in this way is called a camera setting adjustment process. This camera setting adjustment process is executed at the following timing.

(1) Before normal operation Normal operation is an operation in which a user is placed in a car 11 and moves on each floor. Before this normal operation, the camera setting adjustment process is executed, the car 11 is stopped unattended on each floor, and the setting information of the camera 12 is adjusted according to the brightness of the floor surface 16 of the landing 15. The adjusted setting information is registered, for example, in the table TB of the storage unit 21 shown in FIG. 1 in association with the floor information. When the car 11 stops at an arbitrary floor in response to a car call or a landing call when shifting to normal operation, the setting information corresponding to the stopped floor is read from the table TB and based on the setting information. Controls the shooting operation of the camera 12.

(2) During normal operation During normal operation, when the car 11 stops at an arbitrary floor and the door is opened, the camera setting adjustment process is executed, and the camera 12 is subjected to the brightness of the floor surface 16 of the landing 15. Adjust the setting information. However, if the car 11 stops at the registration floor of the car call, the user who got off the car 11 to the landing 15 may get in the way. Therefore, it is preferable to perform the camera setting adjustment process when the car call is not registered.

Before the normal operation of (1) above, since there are no users at the landing 15 on each floor, the brightness of the floor surface 16 of the landing 15 can be accurately measured and the setting information of the camera 12 can be adjusted on each floor. There are merits such as. However, the brightness of the floor surface 16 may change, for example, when a carpet is laid on the floor surface 16 of the landing 15 on an arbitrary floor. In addition, the brightness of the floor surface 16 may change significantly depending on the failure of the lighting equipment at the landing 15 or the way the sunlight enters. When the brightness of the floor surface 16 changes, it does not match the setting information of the camera 12 registered in advance in the table TB.

Therefore, as described in (2) above, the brightness of the floor surface 16 is measured in real time each time the car 11 stops on each floor during normal operation, and the setting information of the camera 12 is adjusted according to the brightness. Is preferable. Specifically, in step S13 of FIG. 4, the brightness of the floor surface 16 of the landing 15 is measured using the image taken by the camera 12 on the stop floor of the car 11, and the camera 12 is measured according to the brightness. Adjust the setting information of.

FIG. 13 is a flowchart showing a camera setting adjustment process in this system.
The camera setting adjustment process is executed in the following procedure through the brightness measurement unit 22c and the camera setting adjustment unit 22d of the detection unit 22 provided in the image processing device 20.

First, the brightness measuring unit 22c measures the brightness of the floor surface 16 of the landing 15 using the image taken by the camera 12 on the stop floor of the car 11 (step S21). Specifically, the brightness measurement unit 22c sets the measurement area E11 on the captured image by any of the following methods, and sets the average value of the brightness values of each pixel in the measurement area E11 as the brightness of the floor surface 16. calculate.

[How to set the measurement area E11]
-Whole or part of the floor surface 16 of the landing 15 As shown in FIG. 14, the whole floor surface 16 of the landing 15 is set as the measurement area E11, or a part of the floor surface 16 is set as the measurement area E11. do. When a part of the floor surface 16 is set as the measurement area E11, it is preferable that the floor surface 16 of the landing 15 is not hidden by the user at the landing 15, for example, near the three-sided frames 17a and 17b. The area where the floor surface 16 of the landing 15 is reflected and the area where the elevator structures such as the three-sided frames 17a and 17b are reflected on the photographed image are the design values (width of frontage, height of the door, etc.) of each component of the car 11. ) And the installation information (position, angle of view, etc.) of the camera 12. The measurement area E11 is set based on the coordinate information of these areas.

・ E1 = E11
The detection area E1 may be used as the measurement area E11. Using the detection area E1 as the measurement area E11 has the advantages that it is possible to save the trouble of separately setting the measurement area E11 and to measure the brightness of the floor surface portion directly related to the user detection process.

The camera setting adjustment unit 22d adjusts the setting information of the camera 12 according to the brightness of the floor surface 16 in the measurement area E11. Specifically, as shown in FIG. 15, when the brightness value is represented by 256 gradations, the camera setting adjustment unit 22d determines the brightness of the floor surface 16 by dividing it into the following three levels.

First level: The brightness is close to white, and has, for example, a brightness value in the range of "200 to 255".
-Second level: The brightness is close to black, and has a brightness value in the range of "0 to 49", for example.
Third level: Brightness close to a neutral color (gray) between white and black, for example, having a brightness value in the range of "50 to 199".

The range of each level can be changed arbitrarily. For example, when the brightness value "200" is the threshold value TH1 and the brightness value "50" is the threshold value TH2, if the average value of the brightness values of each pixel in the measurement area E11 is the threshold value TH1 or more, the first level It is determined to be brightness, and if it is less than the threshold value TH2, it is determined to be the brightness of the second level. Further, if the average value of the brightness values of each pixel in the measurement area E11 is equal to or more than the threshold value TH2 and less than the threshold value TH1, it is determined that the brightness is the third level.

[Method of judging brightness other than threshold processing]
Brightness may be determined by using, for example, a processing table or a processing function without using the threshold value as described above.

-Method of using the processing table For example, the processing table 23 is stored in the storage unit 21. In the processing table 23, the brightness level with respect to the brightness value of the image is preset. Specifically, the brightness value "200 to 255": the first level, the brightness value "50 to 199": the third level, the brightness value "0 to 49": the second level, and so on. It is associated with the brightness level. Therefore, if the processing table 23 is searched using the average value of the brightness values of each pixel in the measurement area E11 as the input value, the brightness level corresponding to the input value can be obtained as the output value.

-Method of using a processing function The processing function is a function formula 24 for calculating the brightness level from the brightness value of each pixel in the measurement area E11, and is stored in, for example, the storage unit 21. In this function formula 24, the brightness value In (In: in the measurement area) of each pixel is input, and the brightness of the image in the measurement area E11 is "close to white", "close to black", and "close to neutral color (gray)". Is classified into three levels and output. Machine learning may be used as the classification process. As the classification process by machine learning, for example, general processes such as k-nearest neighbor method, decision tree method, support vector machine (SVM), and deep learning may be used.

[How to read the brightness value]
When measuring the brightness of the floor surface 16 of the landing 15 using the brightness value of the captured image, the brightness value of the captured image should be read not only once at the time of opening the door but also continuously or periodically (at intervals of several seconds). Is preferable. This is because even if the measurement area E11 is set while avoiding the user, the user may get on and off when the car door 13 is opened, so that reading only once lacks accuracy. If the brightness value is read continuously or periodically (at intervals of several seconds), the brightness value becomes stable when the user leaves the landing 15, so if the stable brightness value is used, the brightness of the floor surface 16 is bright. Can be measured accurately.

[Brightness measurement method]
-Measured brightness value = brightness value As described above, the actual brightness of the floor surface 16 is measured using the brightness value of the captured image.

・ Brightness measurement value = brightness value / (exposure time x gain)
Alternatively, the actual brightness of the floor surface 16 may be measured using at least one of the exposure time and the gain included in the setting information of the camera 12 in addition to the brightness value of the captured image. That is, since both the exposure time and the gain are values proportional to the brightness value, the measured value of the brightness can be calculated by adding the values of the exposure time and the gain by the above formula. For example, when the color of the floor surface 16 is white, the exposure time and the gain value are low, and the brightness value may appear dark (such as the brightness value “100”). Even in such a case, the correct brightness measurement value can be calculated by adding at least one of the exposure time and the gain.

Returning to FIG. 13, when the brightness of the floor surface 16 is included in the range of the first level (Yes in step S22), the camera setting adjustment unit 22d raises the setting information of the camera 12 with respect to the landing 15 on the current floor. (Step S23). That is, if the floor surface 16 of the landing 15 is bright and the shadow S1 is likely to appear, the shadow S1 is overexposed by shooting even brighter to prevent erroneous detection (see FIGS. 7 and 8).

Further, when the brightness of the floor surface 16 is included in the range of the third level (No in step S24), the camera setting adjustment unit 22d lowers the setting information of the camera 12 with respect to the landing 15 on the current floor (step S26). .. That is, if the floor surface 16 of the landing 15 is bright in the middle and the shadow S1 appears strongly, the contrast between the shadow S1 and the floor surface 16 is lowered by shooting darkly to prevent erroneous detection of the shadow S1. (See FIGS. 9 and 10).

On the other hand, when the brightness of the floor surface 16 is included in the range of the second level (Yes in step S24), the camera setting adjustment unit 22d raises the setting information of the camera 12 for the landing 15 on the current floor (step S25). .. That is, if the floor surface 16 of the landing 15 is dark, the shadow S1 does not appear strongly. In such a case, by shooting brightly, the contrast between the user P1 and the floor surface 16 is increased to facilitate the detection of the user P1 (see FIGS. 11 and 12).

Here, "increasing the setting information of the camera 12" means adjusting the values of the exposure time and the gain included in the setting information of the camera 12 so as to be higher than the standard values, and adjusting the subject (here, the landing 15). Shoot brightly.

The "standard value" is a standard value preset in the camera 12 by default. For example, assuming that the standard values of the exposure time and gain of the camera 12 are T1 and G1, in step S23, the exposure time and gain are adjusted to be higher than the standard values T1 and G1. That is, in order to shoot the subject brightly, the exposure time and the gain are adjusted to the target values Ta and Ga set higher than the standard values T1 and G1 (T1 <Ta, G1 <Ga).

The target value Ta is the exposure time for shooting brightly, and the target value Ga is the value of the gain for shooting brightly, and each is set to the optimum value in consideration of the environment of the subject (here, the landing 15). .. Either one of the exposure time and the gain may be adjusted, or both the exposure time and the gain may be adjusted.

“Reducing the setting information of the camera 12” means adjusting the values of the exposure time and the gain included in the setting information of the camera 12 so as to be lower than the standard values, and shooting the subject darkly.

As described above, the "standard value" is a standard value preset in the camera 12 by default. For example, assuming that the standard values of the exposure time and the gain are T1 and G1, in step S26, the exposure time and the gain are adjusted to be lower than the standard values T1 and G1. That is, in order to shoot the subject darkly, the exposure time and the gain are adjusted to the target values Tb and Gb set lower than the standard values T1 and G1 (T1> Tb, G1> Gb).

The target value Tb is the exposure time for shooting in the dark, and the target value Gb is the gain value for shooting in the dark, and each is set to the optimum value in consideration of the environment of the subject (here, the landing 15). .. Either one of the exposure time and the gain may be adjusted, or both the exposure time and the gain may be adjusted.

[Adjustment method]
-Preset method The method described above is a method of adjusting the exposure time and the gain to the preset target values according to the brightness of the floor surface 16. Only one of the exposure time and the gain may be adjusted to the target value. That is, the exposure time is fixed to the standard value and the gain is adjusted to the target value. By fixing the exposure time to a standard value, blurring of the subject can be suppressed. Alternatively, the gain may be fixed to a standard value and the exposure time may be adjusted to a target value. By fixing the gain to the standard value, the noise can be kept at a constant amount.

-Adjustment method using the processing table When adjusting the exposure time and the gain to the target values according to the brightness of the floor surface 16, the processing table 23 described above may be used. In the processing table 23, a target value for the brightness of the floor surface 16 is set with respect to at least one of the exposure time and the gain of the camera 12. The “brightness of the floor surface 16” is represented by a brightness value of the image, a value considering the exposure time / gain (brightness value / (exposure time × gain)), or the like.

Specifically, for example, when the brightness of the floor surface 16 is measured from the brightness value of the image, the standard value of the camera 12 is set with respect to the brightness value "200 to 255" included in the first level range. For the higher target values Ta, Ga and the brightness values "50 to 199" included in the third level range, the darker target values Tb, Gb set lower than the standard value of the camera 12 For the brightness values "0 to 49" included in the second level range, target values Ta and Ga set higher than the standard value of the camera 12 are set.

Further, as the configuration of the processing table 23, for example, the brightness value “255”: the target value Ta ₁ , Ga ₁ , the brightness value “254”: the target value Ta ₂ , Ga ₂ , the brightness value “253”: the target value Ta ₃ , Ga. _{As in the case of 3} ... (Ta ₁ , Ga ₁ > Ta ₂ , Ga ₂ > Ta ₃ , Ga ₃ ), the target value may be set in detail for each of the brightness values.

In any configuration, if the processing table 23 is searched using the brightness value indicating the brightness of the floor surface 16 as the input value, the target value of the exposure time and the target value of the gain corresponding to the brightness value are used as the output values. It can be obtained uniquely. The camera setting adjustment unit 22d adjusts the setting information of the camera 12 to the target value obtained from the processing table 23. It is also possible to adjust only one of the exposure time and the gain included in the setting information.

-Adjustment method using a function formula When adjusting the exposure time and the gain to the target values according to the brightness of the floor surface 16, the above-mentioned function formula 24 may be used. The function formula 24 includes a calculation formula for calculating a target value for the brightness of the floor surface 16 with respect to at least one of the exposure time and the gain of the camera 12. As described above, the "brightness of the floor surface 16" is represented by a brightness value of the image or a value (brightness value / (exposure time x gain)) in consideration of the exposure time and gain.

Specifically, for example, when the brightness of the floor surface 16 is measured from the brightness value of the image, the standard value of the camera 12 is set with respect to the brightness value "200 to 255" included in the first level range. For the higher target values Ta, Ga and the brightness values "50 to 199" included in the third level range, the darker target values Tb, Gb set lower than the standard value of the camera 12 For the brightness values "0 to 49" included in the second level range, the function formula 24 is used to output the target values Ta and Ga set higher than the standard value of the camera 12.

Further, as the configuration of the function formula 24, for example, the brightness value “255”: the target value Ta ₁ , Ga ₁ , the brightness value “254”: the target value Ta ₂ , Ga ₂ , the brightness value “253”: the target value Ta ₃ , Ga. _{As in the case of 3} ... (Ta ₁ , Ga ₁ > Ta ₂ , Ga ₂ > Ta ₃ , Ga ₃ ), the target value may be output in detail for each luminance value.

In any configuration, if the brightness value indicating the brightness of the floor surface 16 is substituted into the function formula 24 as the input value, the target value of the exposure time and the target value of the gain corresponding to the brightness value are used as the output values. It can be obtained uniquely. The camera setting adjustment unit 22d adjusts the setting information of the camera 12 to the target value obtained from the function formula 24. It is also possible to adjust only one of the exposure time and the gain included in the setting information.

As described above, according to the first embodiment, the setting information of the camera 12 is adjusted according to the brightness of the floor surface 16 of the landing 15, and the user detection process is performed using the photographed image after the adjustment. , It is possible to accurately detect only the user and reflect it in the door opening / closing control without erroneously detecting the shadow.

In the first embodiment, the setting information of the camera 12 is adjusted including the case where the floor surface 16 of the landing 15 is dark (second level in FIG. 15), but the brightness is such that shadows are likely to appear. Only at that time (first level and third level in FIG. 15), the setting information of the camera 12 may be adjusted according to the brightness at that time.

(Second Embodiment)
Next, the second embodiment will be described.
In the first embodiment, the case where the user in the landing 15 is detected is assumed, but in the second embodiment, the case where the user in the car 11 is detected is assumed.

The process for detecting the user in the car 11 will be described below.
FIG. 16 is a diagram showing the relationship between the detection area E2 set in the car 11 and the measurement area E21 in the second embodiment.

The detection area E2 is set in the car 11 by the detection area setting unit 22a provided in the detection unit 22. The detection area E2 is adjacent to the car sill 47 provided on the floor surface 19 of the car 11. The detection area E2 is an area for detecting a user on a captured image, and is used to prevent an accident in which a user's hand or the like near the car door 13 is drawn into the door pockets 42a and 42b when the door is opened. Be done.

The detection area E2 has a predetermined width in a direction orthogonal to the entrance / exit (Y-axis direction), and is set in a strip shape along the longitudinal direction (X-axis direction) of the car sill 47. Since the car doors 13 (door panels 13a and 13b) move on the car sill 47, the area is not set. That is, the detection area E2 is set so as to be adjacent to one side side in the longitudinal direction of the car sill 47 except on the car sill 47. As a result, the detection area E2 that is not affected by the opening / closing operation of the car door 13 can be set.

In the example of FIG. 16, the car 11 is shown in the door open state, but the detection area E2 is preferably set on the image taken in the door closed state. This is because the background on the landing 15 side is not reflected in the captured image, so that the detection area E2 can be set based only on the structure in the car 11.

The camera setting adjustment process is executed before or during normal operation. Before or during normal operation, when the car 11 stops on each floor, the brightness of the floor surface 19 may be measured and the setting information of the camera 12 may be adjusted, or on any floor. The setting information of the camera 12 may be adjusted only once. However, the brightness of the floor surface 19 may change due to a failure of the lighting equipment in the car 11 or the like. Therefore, each time the car 11 stops on each floor during normal operation, the brightness of the floor surface 19 is bright. It is preferable to measure the brightness and adjust the setting information of the camera 12.

The brightness measuring unit 22c measures the brightness of the floor surface 19 of the car 11 using the captured image of the camera 12. Specifically, the brightness measurement unit 22c sets the measurement area E21 on the captured image by any of the following methods, and sets the average value of the brightness values of each pixel in the measurement area E21 as the brightness of the floor surface 19. calculate.

[How to set the measurement area E21]
-Whole or part of the floor surface 19 of the car 11 As shown in FIG. 16, the whole floor surface 19 of the car 11 is set as the measurement area E21, or a part of the floor surface 19 is set as the measurement area E21. Set as. When a part of the floor surface 19 is set as the measurement area E21, for example, it is preferably near the car sill 47 (that is, near the doorway). This is because it is rare for a user to get in the vicinity of the doorway in the car 11, so that the brightness of the floor surface 19 can be measured without being disturbed by the user before the door is opened. The area where the floor surface 19 of the car 11 is reflected and the area where the elevator structures such as the front pillars 41a and 41b and the car sill 47 are reflected on the photographed image are the design values of each component of the car 11 (width of frontage, frontage width, It is obtained based on the height of the door, etc.) and the installation information (position, angle of view, etc.) of the camera 12. The measurement area E21 is set based on the coordinate information of these areas.

・ E2 = E21
The detection area E2 may be used as the measurement area E21. Using the detection area E2 as the measurement area E21 has the advantages of saving the trouble of setting the measurement area E21 and measuring the brightness of the floor surface 19 in the detection area E2 directly related to the user detection process. ..

The camera setting adjustment unit 22d adjusts the setting information (exposure time, gain) of the camera 12 according to the brightness of the floor surface 19 of the car 11. Specifically, as described with reference to FIGS. 13 and 15, for example, the brightness of the floor surface 19 is divided into three stages, and the setting information of the camera 12 is in the range of the first level, which is the brightest level among them. Is raised, and the setting information of the camera 12 is lowered in the range of the third level, which is an intermediate brightness. Further, in the range of the second level, which is the darkest level, the setting information of the camera 12 is increased. The setting information (exposure time, gain) of the camera 12 may be continuously adjusted according to the brightness of the floor surface 19 of the car 11.

By such adjustment, even if a shadow of the user is generated near the car door 13, for example, an image in which the shadow is reduced can be obtained. Therefore, the detection processing unit 22b can correctly detect the user near the car door 13 by using this image. When a user near the car door 13 is detected when the door is opened, the door opening / closing control unit 31 interrupts the door opening operation, and the car door 13 is reclosed in the fully closed direction. As a result, it is possible to prevent the user's hand or the like from being drawn into the door pockets 42a and 42b.

As described above, according to the second embodiment, the brightness of the floor surface 19 of the car 11 is measured, and the setting information of the camera 12 is adjusted according to the brightness so as not to be affected by the shadow. Only the user can be detected correctly, and the detection result can be reflected in the door opening / closing control.

In the second embodiment, the setting information of the camera 12 is adjusted including the case where the floor surface 19 of the car 11 is dark (second level in FIG. 15), but shadows are likely to appear. The setting information of the camera 12 may be adjusted according to the brightness at that time only when it is bright (first level and third level in FIG. 15).

It is also possible to configure the first embodiment in combination with the second embodiment. In this case, the measurement target is switched between when the door is open and when the door is closed, the brightness of the floor surface 16 of the landing 15 is measured when the door is open, and the brightness of the floor surface 19 of the car 11 is measured when the door is closed. Therefore, the setting information of the camera 12 is adjusted for each.

According to at least one embodiment described above, an elevator user detection system capable of suppressing false detection due to the brightness of the floor surface, correctly detecting the user, and reflecting it in the door opening / closing control is provided. Can be provided.

Although some embodiments of the present invention have been described, these embodiments are presented as examples and are not intended to limit the scope of the invention. These novel embodiments can be implemented in various other embodiments, and various omissions, replacements, and changes can be made without departing from the gist of the invention. These embodiments and modifications thereof are included in the scope and gist of the invention, and are also included in the scope of the invention described in the claims and the equivalent scope thereof.

11 ... Car, 11a ... Curtain board, 12 ... Camera, 13 ... Car door, 13a, 13b ... Door panel, 14 ... Landing door, 14a, 14b ... Door panel, 15 ... Landing, 17a, 17b ... Three-sided frame, 18 ... Landing Sill, 47 ... Basket sill, 20 ... Image processing device, 21 ... Storage unit, 22 ... Detection unit, 22a ... Detection area setting unit, 22b ... Detection processing unit, 22c ... Brightness measurement unit, 22d ... Camera setting adjustment unit, 30 ... Elevator control device, 31 ... Door open / close control unit, E1, E2 ... Detection area, E11, E21 ... Measurement area.

The brightness measuring means measures the brightness of at least one floor surface of the landing and the car using the image obtained from the camera. The camera setting adjusting means adjusts setting information including at least one of the exposure time and the gain of the camera according to the brightness of the floor surface measured by the brightness measuring means. The detection means detects a user existing on the floor surface from the image of the camera adjusted by the camera setting adjustment means. The door opening / closing control means controls the door opening / closing operation of the car door based on the detection result of the detection means.
In the user detection system of the elevator having the above configuration, the camera setting adjusting means determines the brightness of the floor surface by dividing it into a first level and a second level, and the first level is the second level. When the brightness of the floor surface is included in the range of the first level when it is brighter than the level, at least one of the exposure time and the gain of the camera included in the setting information is set as a standard value. It is characterized in that the floor surface is photographed brightly by adjusting it so that it is higher.

Claims (17)

In the elevator user detection system that is installed in the car and detects the user from the image of the camera that captures the vicinity of the car door and the landing.
A brightness measuring means for measuring the brightness of at least one of the floor surface of the landing and the car using the image obtained from the camera, and
It is adjusted by the camera setting adjusting means and the camera setting adjusting means for adjusting the setting information including at least one of the exposure time and the gain of the camera according to the brightness of the floor surface measured by the brightness measuring means. A detection means for detecting a user existing on the floor surface from the image of the camera, and
An elevator user detection system including a door opening / closing control means for controlling the door opening / closing operation of the car door based on the detection result of the detection means. The above camera setting adjustment means
The elevator user detection system according to claim 1, wherein the setting information is adjusted stepwise or continuously according to the brightness of the floor surface. The above camera setting adjustment means
The elevator user detection system according to claim 1, wherein the setting information is adjusted when the brightness is such that shadows are likely to appear on the floor surface. The above camera setting adjustment means
Depending on the brightness of the floor surface, at least one of the exposure time and gain of the camera included in the setting information is adjusted to be higher than the standard value, or adjusted to be lower than the standard value. The elevator user detection system according to claim 1. The above camera setting adjustment means
When the brightness of the floor surface is determined by dividing it into a first level and a second level, and the first level is brighter than the second level,
When the brightness of the floor surface is included in the range of the first level, at least one of the exposure time and the gain of the camera included in the setting information is adjusted to be higher than the standard value. The elevator user detection system according to claim 4, wherein the floor surface is photographed brightly. The above camera setting adjustment means
The brightness of the floor surface is determined including the third level, which is intermediate between the first level and the second level.
When the brightness of the floor surface is included in the third level range, at least one of the exposure time and gain of the camera included in the setting information is adjusted to be lower than the standard value. The elevator user detection system according to claim 5, wherein the floor surface is photographed darkly. The above camera setting adjustment means
When the brightness of the floor surface is included in the range of the second level, at least one of the exposure time and the gain of the camera included in the setting information is adjusted to be higher than the standard value. The elevator user detection system according to claim 5, wherein the floor surface is photographed brightly. The above camera setting adjustment means
Having a table in which target values for the brightness of the floor surface are set for at least one of the exposure time and gain of the camera.
By searching the table using the brightness of the floor surface obtained as the measurement result of the brightness measuring means as an input value, the target value corresponding to the brightness of the floor surface is acquired, and the exposure of the camera is obtained. The user detection system for an elevator according to claim 1, wherein at least one of the time and the gain is adjusted to the above target value. The above camera setting adjustment means
It has a functional expression for calculating a target value for the brightness of the floor surface with respect to at least one of the exposure time and the gain of the camera.
By substituting the brightness of the floor surface obtained as the measurement result of the brightness measuring means into the function formula as an input value, the target value corresponding to the brightness of the floor surface can be obtained, and the camera can obtain the target value. The user detection system for an elevator according to claim 1, wherein at least one of the exposure time and the gain is adjusted to the above target value. The above brightness measuring means
The user detection system for an elevator according to claim 1, wherein the brightness of the floor surface is measured based on the brightness value of the image in the measurement area set on the floor surface. The above brightness measuring means
The user detection system for an elevator according to claim 10, wherein the brightness of the floor surface is measured in consideration of at least one of the exposure time and the gain included in the setting information. The above measurement area is
The user detection system for an elevator according to claim 10, wherein the elevator user detection system is set in an area where the floor surface of the image is reflected based on the design value of each component of the car and the installation information of the camera. .. The above measurement area is
The elevator user detection system according to claim 10, wherein the elevator user detection system is set on the whole or a part of the floor surface. The above measurement area is
The user detection system for an elevator according to claim 10, wherein the elevator is set near the three-sided frame of the landing. The above measurement area is
The user detection system for an elevator according to claim 10, wherein the elevator user detection system is set in a portion close to a sill provided at the entrance / exit of the car. The above detection means
The movement of the user is detected from the change in the brightness of the image in the detection area set on the floor surface.
The elevator user detection system according to claim 10, wherein the detection area is used as the measurement area. The above brightness measuring means
The feature is that the brightness of the floor of the landing is measured when the door of the car is opened, and the brightness of the floor of the car is measured when the door of the car is closed. The user detection system for the elevator according to claim 1.

Images