DE102011053179A1 - Device for taking back empties and method for classifying empties by means of light fields - Google Patents

Abstract

The invention relates to a device (10, 12, 14) for returning empties (16), which comprises an input compartment (20) for inputting the empties (16) into a detection area and an image detection unit (18) for receiving at least one light field of the detection area , A control unit (40) classifies the empties (16) with the aid of the light field. Furthermore, the invention relates to a method for classifying empties (16), in which the empties in accordance with a recorded light field of the empties (16) is classified.

Description

The invention relates to a device for the return of empties, in which the empties is entered into a detection area of an input tray. The entered empties are classified using optical methods. Furthermore, the invention relates to a method for classifying empties, in which the empties input in the input tray is classified by means of optical methods.

The device is in particular a reverse vending machine which is used in retail outlets so that the customers can return their empties and receive the deposit raised on the empties. The empties are in particular containers that consist of a crate with several compartments and possibly recorded in the compartments bottles. The bottles accommodated in the compartments are in particular glass faults, ie returnable bottles.

In known reverse vending machines, a stereo camera is provided which comprises two cameras, with each of which an image is captured with a picture of the entered empties. With the aid of a control unit, a three-dimensional measurement of the empties, in particular the height, width and length of the crate, the position and / or size of the compartments of the crate and the dimensions of the arranged in the compartments bottles are determined. Depending on the determined dimensions, the empties are classified. In particular, it is determined here whether the empties are empties subject to a deposit and how high the deposit for the corresponding empties is. Accordingly, this pledge is credited to the customer and issued after completion of the input all empties via a receipt with the value of the credit to him.

A problem with the use of stereo cameras to determine the dimension and thus to classify the empties is that with the help of the stereo camera often only a very inaccurate determination of the dimensions of the boxes and bottles is possible. In particular, edges that lie outside the focus plane of the stereo camera can only be imaged relatively blurred in the images captured by the stereo camera, so that it is difficult to determine the dimensions of these blurred body edges. In addition, it is problematic that only two images of the empties are determined, so that the measurement of edges that are parallel to the epipolar lines, is problematic. To recognize the bottles and to determine their dimensions, it is particularly important to detect the bottle mouth. This is done in particular via the reflection of light at this mouth of the bottle, which is very difficult to detect with glass bottles, since there is no lambert reflection. Furthermore, it is disadvantageous that such a stereo camera must be calibrated consuming.

Furthermore, it is known to use instead of the stereoscopic method for 3D measurement of the empties light section method, in which case the recording of images via a stereo camera or a monocamera and essentially the same problems as described above occur.

It is an object of the invention to provide a device for taking back empties and a method for classifying empties, with the help of which empties entered can be reliably classified in a simple manner.

This object is achieved by a device having the features of claim 1 and by a method having the features of the independent method claim. Advantageous developments of the invention are specified in the dependent claims.

According to the invention, the device comprises an image acquisition unit, with the aid of which at least one light field of the coverage area, and thus of any empties entered, is recorded. The control unit classifies the empties with the help of this light field.

In particular, a light field is understood to mean a function which describes the amount of light that falls in every direction at each point of the three-dimensional space. Thus, not only the light intensity but also the direction in which the light is incident on the corresponding point of the image acquisition unit is preferably detected in the light field in each individual pixel.

The use of a light field for classifying the empties has the advantage that the three-dimensional measurement of empties containers with the help of only one detection unit and only one light field is possible because this contains a light field more for the classification of boxes and bottles relevant information than the images of a stereo camera. The light field is in particular seven-dimensional, d. H. The light field includes the three-dimensional geometry, the two-dimensional reflections, the wavelength and the time, so that also for the classification of the empties more information is available.

In a light field, it is basically possible to perform a so-called re-focusing, ie that the focus on different image planes of the light field can be subsequently changed without further images of the empties must be recorded. Thus, all necessary for the measurement of the empties edges can be focused, so that an accurate measurement of these edges is possible. In addition, the light field allows a large number of different viewing angles to be detected within the emptying area given by the recording of the light field, so that the problem of detection and measurement of edge parallel to epipolar lines is bypassed or does not occur.

The device has in particular a lighting unit for illuminating the detection area, wherein the lighting unit and the image detection unit are preferably arranged such that a dark field illumination of the empties takes place. With such a dark field illumination, the empties are illuminated in such a way that only indirect light reflected by empties enters the objective of the image acquisition unit. This dark field illumination ensures that the mouth of bottles of empties is illuminated at a shallow angle, and thus the reflection of the mouth in the light field can be classified in a simple manner.

In particular, the image acquisition unit comprises a plenoptic camera, so that only one camera is necessary for the acquisition of the light field. Thus, it is not necessary, as with a stereo camera to calibrate the individual cameras consuming. Furthermore, the plenoptic camera makes it possible to easily and inexpensively record the light field of the detection area in a short time.

A plenoptic camera is understood in particular to mean a camera which detects a 4D light field. In contrast, a stereo camera captures only a 2D image. In a 4D light field not only the position and intensity of a light beam on the image sensor is known, but also the direction from which the light beam has fallen. The light field measurement is made possible by a grid of several microlenses in front of the image sensor. The special ability of a plenoptic camera is that the maximum depth of field is very high, no focussing process has to be awaited and the focal plane of a recorded image can be subsequently adjusted. From the image data, the depth information can be determined, so that a plenoptic camera is also suitable as a 3D camera.

In particular, the plenoptic camera comprises a lens grid comprising a large number of lenses, which is arranged in front of the image sensor. Through this lens grid, each pixel is refracted again and expanded into a cone, which hits the sensor surface in a circle. The point at which the light beam strikes the sensor surface reveals which direction the light beam originally came from. A vertically incident light beam ends up, for example, in the center of the circle, an obliquely arriving further on the edge. Thus, with the aid of a control unit and / or software, the sharpness can be subsequently re-determined, in particular calculated, and, as in the case of a "correct" lens, the focus can be changed.

In particular, a database is stored in the control unit in which different empties classes are assigned characteristic features, wherein the control unit determines at least one characteristic feature in the light field and classifies the empties as a function of this determined characteristic feature. The features are, in particular, dimensions of the empties, wherein at least one image processing algorithm is stored in the control unit, which the control unit processes to determine at least one dimension of the empties from the light field.

The empties are in particular and empties containers, which consist of a crate and possibly recorded therein surfaces. In particular, the dimensions of the crate, the number and / or position of the compartments of the box, the height of the bottles and / or at least the radius of the bottles are determined as characteristic features. For this purpose, the control unit carries out in particular a three-dimensional measurement of the empties with the aid of the light field. This ensures that an accurate, reliable classification of the empties is possible and thus a false classification and thus the payment of a false deposit amount are avoided.

In particular, the image capture unit only picks up one light field from each empties entered, so that it is possible to classify the empties with little effort. Due to the large number of information contained in the only one light field, it is not necessary to detect multiple light fields.

The control unit classifies the empties in particular as a function of the information contained in the light field on the three-dimensional geometry of the empties, the information contained in the light field about the occurring two-dimensional reflections, the information contained in the light field about the wavelengths, ie the spectral composition of the light, and / or the information contained in the light field over time, ie over the temporal change of incident light. As a result, a particularly accurate classification of empties is possible.

The classification is understood in particular to mean that the entered empties are divided into the different empties classes via the control unit. Here, the empties classes can be designed such that each empties class corresponds to a preset deposit amount. Alternatively, the empties classes can be preset in such a way, since a separate empties class is preset for each type of crate used and / or for each type of bottle used. In addition, the empties entered are classified insofar as they are a returnable or non-refundable empties or foreign bodies. The empties subject to a deposit are in particular drawn by the device, whereas the empties and / or the foreign bodies which are not subject to a deposit are returned to the operator of the device.

The device comprises, in particular, a receipt printer, by means of which, after the empties have been entered and their classification assigned to the operator, a receipt can be issued with the deposit amount due to him.

Another aspect of the invention relates to a method for classifying empties, in which the empties are entered into an input tray and at least one light field of the empties is determined. The empties are classified depending on the light field. The light field is also recorded in this case, preferably via a plenoptic camera.

By classifying the empties on the information contained in the light field, an accurate classification of the empties is possible with little effort. In particular, edges that run parallel to epipolar lines and edges of different focal planes can be measured accurately.

In the classification of the object, in particular at least two different focal planes are determined by the control unit in the light field and in each case at least one dimension of at least one edge of the empties is determined in these two focal planes.

The classified empties is illuminated in particular with the aid of a dark field illumination, so that the edges of bottles, in particular their mouths, can be reliably detected and thus the dimension of the bottle can be easily determined.

The method specified by the independent method claim may be further developed by means of the features described in the claims dependent on the independent apparatus claim or their corresponding method features.

Further features and advantages of the invention will become apparent from the following description, which illustrates the invention with reference to embodiments in conjunction with the accompanying figures.

Show it:

1 a schematic representation of a device for taking back empties according to a first embodiment in a plan view;

2 a schematic representation of a device for taking back empties according to a second embodiment in a side view;

3 a schematic representation of a device for taking back empties according to a third embodiment in a side view;

4 a schematic representation of a plenoptic camera;

5 a schematic representation of a light field of a crate when focusing on a first plane; and

6 a schematic representation of the light field after 5 focusing on a second level.

In the 1 to 3 is a schematic representation of a device 10 . 12 . 14 for the return of empties 16 shown, where 1 a top view of a first embodiment, 2 a side view of a second embodiment and 3 a side view of a third embodiment shows. The embodiments differ only in the arrangement of a plenoptic camera 18 for receiving light fields, therefore, the general structure will be described below for all three embodiments together.

The device 10 . 12 . 14 , which is also referred to as reverse vending machine, has input tray 20 on, in which the empties 16 from an operator of the device 10 . 12 . 14 can be entered. With the empties 16 These are in particular empties containers that come from a crate 22 and several in compartments of this crate 22 recorded bottles 24 consist. In the in the 1 to 3 shown embodiment are in the crate 22 six bottles 24 arranged. Alternatively, as Empties 16 also empty crates 22 , ie beverage crates 22 in which there are no bottles 24 are entered. It is also possible that as empties 16 crates 22 with more than six bottles 24 or less than six bottles 24 can be entered. With the bottles 24 In particular, they are glass bottles, that is, reusable counterfeits. Alternatively, it can also be disposable PET bottles or plastic returnable bottles 24 act.

Furthermore, the device comprises 10 . 12 . 14 a lighting unit 26 , wherein the lighting unit 26 and the plenoptic camera 18 are arranged such that a dark field illumination of the empties 16 he follows. Under a dark field illumination is understood in particular that no direct lighting follows, but that only stray light from the empties 16 into the lens of the plenoptic camera 18 which has the advantage that reflections 28 at the mouths of the bottles 30 the bottles 24 are better detectable.

With the help of the plenoptic camera 18 becomes a light field of a detection area of the plenoptic camera 18 in which the empties 16 is arranged, and thus also the empties 16 myself recorded. The general construction of the plenoptic camera 18 is still related in the following 4 described in more detail. Alternatively, instead of a plenoptic camera 18 Any other imaging unit that is capable of capturing light fields can also be used.

Furthermore, the device has 10 . 12 . 14 a control unit 40 , which processes at least one image processing algorithm stored in it in order to extract from the recorded light field of the empties 16 Dimensions of the empties 16 to determine and depending on these determined dimensions the empties 16 to classify. In particular, the edges of the crate 22 , the number and / or position of the compartments of the crate 22 and / or the dimensions of the bottles 24 determined by means of the light field or from the light field.

About the comparison of the determined three-dimensional dimensions of the empties 16 with dimensions stored in a database determines the control unit 40 whether it is the entered object 16 actually empties 16 and whether this empties 16 is subject to a deposit. In particular, the control unit determines 40 What kind of empties 16 it is and how high for this empties 16 provided deposit amount is.

A light field is understood to mean a function that describes the amount of light that is incident at every point of the three-dimensional space in all directions. Thus, in a four-dimensional light field using the plenoptic camera 18 not only the gray value of each pixel, but also determines the direction of the incident light beam. This allows for a re-focusing, as related to the 5 and 6 is described in more detail, and on the other hand, that the empties 16 in one by the plenoptic camera 18 predetermined areas can be viewed from different angles with the help of only one recorded light field. This has the consequence that an accurate measurement of the empties 16 is possible. In particular, edges which run parallel to the epipolar lines can also be measured accurately, since corresponding viewing angles can be assumed. Furthermore, it is possible to sharply map each edge to be considered by a corresponding re-focusing so that this edge can be reliably and accurately detected and its dimension can be determined.

In addition, the plenoptic camera has 18 the advantage that only a single camera is necessary, with the help of only one light field of each empties 16 must be recorded. Thus, a simple cost-effective design is achieved and a calibration effort, as is necessary in a stereo camera is avoided. In the first and second embodiments of the 1 and 2 takes the plenoptic camera 18 the light field of the empties 16 directly on, whereas in the third embodiment according to 3 a mirror 50 is provided, the empties 16 reflects and on the plenoptic camera 18 is directed. As a result, a particularly compact construction is achieved.

In 4 is a schematic representation of a plenoptic camera 18 as well as a bottle 24 shown. The plenoptic camera 18 includes a main lens 42 , with whose help a virtual picture 44 the bottle 24 is produced. Between the image sensor 46 the plenoptic camera 18 and this virtual picture 44 is a lens array 48 arranged from microlenses, one of which by way of example by the reference numeral 50 is designated. These microlenses 50 "Consider" the virtual image 44 and make this on the image capture sensor 46 from. Through the microlenses 50 of the lens array 48 becomes every pixel of the virtual image 44 refracted again and expanded into a cone that circles the image capture sensor 46 meets. About the position in which the light beam within the corresponding cone of the respective microlens 50 on the image capture sensor 46 incident, the direction of the incident light beam can be determined.

In an alternative plenoptic camera 18 can be determined instead of a 4D light field and a 7D light field that even more information about the recorded empties 16 contains. The seven dimensions are in particular the three-dimensional geometry, the two-dimensional reflections, the wavelength and the time.

In the 5 and 6 is a light field of a beverage crate 22 shown, wherein in both figures, the same light field is shown. In 5 is the focal plane, which is also referred to as sharpness level, in the area of the front side of the beverage crate 22 , at 6 in contrast, in the area of the rear side of the crate 22 set so that in 5 the front and in 6 the rear side is sharp and the corresponding edges can be determined and measured reliably and accurately by processing the corresponding image processing algorithms. By using a light field, it is possible to focus on different focal planes without having to take several pictures. A corresponding change of the focal plane is also referred to as re-focusing. In the 5 and 6 The sharp edges are each represented by a single line, the blurred edges by double lines.

LIST OF REFERENCE NUMBERS

10, 12, 14

contraption

16

Empties

18

camera

20

input tray

22

crate

24

bottle

26

lighting unit

28

reflection

30

muzzle

40

control unit

42

main lens

44

virtual picture

46

image sensor

48

lens array

50

microlens

Claims (13)

Device for taking back empties, with an input tray ( 20 ) for entering the empties ( 16 ) into a detection area, an image acquisition unit ( 18 ) for receiving at least one light field of the detection area, and with a control unit ( 40 ), which with the help of the light field, the empties ( 16 ). Contraption ( 10 . 12 . 14 ) according to claim 1, characterized in that a lighting unit ( 26 ) is provided for illuminating the detection area. Contraption ( 10 . 12 . 14 ) according to claim 2, characterized in that the lighting unit ( 26 ) and the image capture unit ( 18 ) arranged such that a dark field illumination of the empties ( 16 ) he follows. Contraption ( 10 . 12 . 14 ) according to one of the preceding claims, characterized in that the image acquisition unit ( 18 ) comprises a plenoptic camera. Contraption ( 10 . 12 . 14 ) according to one of the preceding claims, characterized in that in the control unit ( 40 ) a database is stored, in which different empties classes characteristic features are assigned, that the control unit ( 40 ) in the light field at least one characteristic feature is determined, and that the control unit ( 40 ) the empties ( 16 ) are classified as a function of this determined characteristic feature. Contraption ( 10 . 12 . 14 ) according to one of the preceding claims, characterized in that in the control unit ( 40 ) at least one image processing algorithm is stored, that the control unit ( 40 ) this image processing algorithm for determining at least one dimension of the empties ( 16 ) works out of the light field, and that the control unit ( 40 ) the empties ( 16 ) classified as a function of this dimension. Contraption ( 10 . 12 . 14 ) according to claim 6, characterized in that the control unit ( 40 ) using the light field, a three-dimensional measurement of the empties ( 16 ). Contraption ( 10 . 12 . 14 ) according to claim 7, characterized in that the control unit ( 40 ) the height, width and / or depth of an empties ( 16 ) entered beverage crate ( 22 ), the positions and / or dimensions of the compartments of the crate ( 22 ) and / or the height and / or at least one diameter of at least one bottle accommodated in one of the compartments ( 24 ). Contraption ( 10 . 12 . 14 ) according to claim 7 or 8, characterized in that the control unit ( 40 ) for measuring empties ( 16 ) the illustration of the empties ( 16 ) is focused in the light field in a first image plane and at least one second image plane. Contraption ( 10 . 12 . 14 ) according to one of the preceding claims, characterized in that precisely one light field of the detection area is detected by means of the image acquisition unit ( 18 ) is recorded. Contraption ( 10 . 12 . 14 ) according to one of the preceding claims, characterized that the control unit ( 40 ) the empties ( 16 ) depending on the information contained in the light field about the three-dimensional geometry of the empties ( 16 ), through which the empties ( 16 ) occurring two-dimensional reflections, over the wavelength and / or over time classified. Method for classifying empties, in which the empties ( 16 ) in an input tray ( 20 ), at least one light field ( 16 ) of the empties ( 16 ) and in which the empties ( 16 ) is classified as a function of the light field. Method according to claim 12, characterized in that the empties ( 16 ) is illuminated with a dark field illumination.

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