Augmented reality-based test mechanism

Abstract

The present invention is a test mechanism for structural defect detection of a test object (400). Accordingly, said test mechanism is characterized in that a light source (200) is provided which accommodates pluralities of light elements (210) which can emit light in at least two different colors and which changes the light emitting condition of said light elements (210) in accordance with the signal received from a processor unit (310), an image capturing device (100) is provided which captures the image of the test object (400) positioned on a test surface (220) defined on the light elements (210) and connected to the processor unit (310) in a manner transmitting the captured image to the processor unit (310) as input; the processor unit (310) is configured in a manner providing changing of the light emitting condition of light elements (210) in a manner mentioning approval/defect for the light source (200) in accordance with the difference of the captured image from an object model (329) of the memory unit (320).

Claims

1. A test mechanism for structural defect detection of a test object which is planar, comprising: a light source which accommodates pluralities of light elements which can emit light in at least two different colors and which changes the light emitting condition of said light elements in accordance with the signal received from a processor unit; a test surface defined by the light elements arranged side by; an image capturing device which captures the image of the test object positioned on a said test surface, defined on the light elements and connected to the processor unit in a manner transmitting the captured image to the processor unit as input; a computer readable memory unit, coupled to the processor unit and storing computer executable instructions thereon, which when computer executable instructions are executed by the processor unit, cause the processor unit to carry out following actions: from the captured image determining the coordinates where the object is positioned on the test surface, detecting the coordinates on the test surface corresponding to at least one defecty section, where the test object is different from an object model stored in the memory unit, determining the coordinates on the test surface corresponding to the vicinity of the defecty sections where the test object is different from the object model, controlling light source in a manner providing the light elements which are in the vicinity of determined coordinates corresponding to the vicinity of the defecty sections emitting light in different colors from the other light elements for indicating defect, wherein said object comprises at least one transparent pattern which at least partially transmits light, the processor unit is embodied in a manner providing changing of the light emitting conditions in a manner providing emitting light in different colors for at least one of the light elements of the light source, which corresponds to the transparent pattern comprising the defecty section, from the other light elements.

2. A test mechanism according to claim 1, wherein the test object is white good front panel, it is particularly a washing machine, dishwasher, drier or oven front panel.

3. A test mechanism according to claim 1, wherein said light source is an electronic display.

4. A test method for structural defect detection of a test object comprising the following steps carried out by a processor unit, which is connected to a computer readable memory unit storing computer executable instructions thereon, which when computer executable instructions is executed by the processor unit, cause the processor unit to carry out said steps: a) controlling an image capturing device to capture image of a test object which is positioned between said image capturing device facing a light source and said light source which accommodates pluralities of light elements which emit light in at least two different colors, which changes the light emitting condition of said light elements in accordance with the signal received from the processor unit, b) receiving said image, c) comparing received image, to an object model in the memory unit, d) controlling the light source in a manner changing the light emitting condition of the light elements in a manner indicating approval/defect by the light source according to the object model of the taken image by the processor unit, e) detecting the coordinates, where the test object is positioned on the test surface, from the image taken by the processor unit, f) detecting the coordinates on the test surface corresponding to the defecty sections, where the test object is different from the object model, by the processor unit, g) controlling the light source in a manner providing emitting light in different color of the light elements from the other light elements in said coordinates or in the vicinity of said coordinates of the light source.

5. A test method according to claim 4, wherein step g) comprises the sub-steps of: h) providing changing of the light emitting conditions of the light elements in a manner defining a warning item, which marks the coordinates or the vicinity of said coordinates where defect is existing, to the light source in case there is defect.

Description

BRIEF DESCRIPTION OF THE FIGURES

(1) In FIG. 1, a representative view of the test mechanism is given.

(2) In FIG. 2, a representative view of the light source is given.

(3) In FIG. 3, a more detailed representative view of the memory unit is given.

(4) In FIG. 4, a representative view of the test mechanism is given where defect has been detected.

(5) In FIG. 5, a representative view of an alternative embodiment of the test mechanism is given.

(6) In FIG. 6, a representative view of the test object in an alternative embodiment is given.

DETAILED DESCRIPTION OF THE INVENTION

(7) In this detailed description, the subject matter test mechanism is explained with references to examples without forming any restrictive effect only in order to make the subject more understandable.

(8) With reference to FIG. 1, said mechanism comprises a light source (200) whereon the test object (400) is positioned, an image capturing device (100) which captures the image of the test object (400), a control unit (300) which takes the image from the image device and which changes the light emitting condition of said light source (200) and which provides feedback related to the defect in the test object (400).

(9) The change of the light emitting condition can be providing light emitting at different wavelengths of light sources, for example, bringing of the light source from the open condition to the closed condition and bringing of the light source from the closed condition to the open condition.

(10) Said control unit (300) comprises a processor unit (310). The processor unit (310) is connected to a memory unit (320) in a manner providing data transfer. The processor unit (310) can be a microprocessor, a general-purpose or special-purpose processor (CPU, GPU) or it can be the suitable combinations of them. The memory unit (320) can be a memory which can store data in a temporary or permanent manner (RAM, ROM) or the combinations thereof connected in a suitable manner. The memory unit (320) moreover comprises at least one object model (329). Said object model (329) can be the 2-dimensional model of a defectless test object (400) formed in computer medium. The memory unit (320) can comprise different models for different test objects. The object model (329) can be in the form as viewed by the image capturing device (100) when placed on the light source (200) of a defectless test object (400). In this exemplary embodiment, the control unit (300) is a computer.

(11) In this exemplary embodiment, said image capturing device (100) is a camera. The camera inputs the captured images to the control unit (300). The camera is directed to the light source (200) and it captures the image of the test object (400) positioned above the light source (200).

(12) Said light source (200) comprises pluralities of light elements (210) where each one of the light elements (210) can emit light in at least two different colors in an alternating manner. A surface defined by the light elements (210) arranged side by side is defined as the test surface (220). The test object (400) is positioned on this test surface (220). In this exemplary embodiment, the light source (200) is a monitor. The light elements (210) are items which provide light emitting by each pixel and the test surface (220) is the display surface. The light source (200) can be a mechanism obtained by bringing pluralities of LEDs together and by driving thereof in a suitable manner.

(13) The test object (400) preferably has a flat structure. With reference to FIG. 6, the test object (400) comprises a transparent pattern (410) in an alternative embodiment. The transparent pattern (410) has a structure which at least partially transmits light. In this alternative embodiment, the test object (400) is preferably a white good front panel produced by means of serigraphy.

(14) With reference to FIG. 3, the memory unit (320) moreover comprises functional modules which accommodate command lines executed for realizing the processes required for operation of the mechanism by the processor unit (310). A data receiving module (321) provides receiving of the instantaneous images from the image capturing device (100). A position determination module (322) determines the position of the test object (400) on the test surface (220). Said position determination module (322) uses the image processing methods known in the art and it can determine the position of the test object (400). The position determination module (322) for example may comprise algorithms which realize edge search or circle search on the test surface (220) whose size and orientation are known. A defect determination module (323) compares the object model (329) and the captured image and it determines the defects and the position of these defects on the test surface (220).

(15) A defect visualization module (324) provides the light elements (210), which correspond to the test surface (220) in the vicinity of the region where the defects exist in the test object (400), to emit light which is different from the other light elements (210). For instance, if there is a deficient region in the vicinity of the walls of the object, the light elements (210) provided in the vicinity of the deficient region walls provide emitting light in a different manner in a manner visible by the user. Additionally, these light elements (210) can emit light in a manner defining a warning item (500) in a sign form like a writing or tick, arrow in relation to the defect. In case the test object (400) is defectless within the mentioned limits, the light emitting conditions can be changed by the processor unit (310) in a manner defining a warning item (500) which mentions approval of the light elements (210).

(16) The operation of the mechanism, whose details are given above, is as follows:

(17) The test object (400) is placed onto the test surface (220) of the light source (200). The image capturing device (100) captures the image of the test object (400) and transfers said image to the processor unit (310) as input. The images received by means of the data receiving module (321) are processed, and the position of the test object (400) on the test surface (220) is determined by the position determination module (322). The test object (400) is compared with the object model (329) by the defect determination module (323), and by taking into consideration the differences between the test object (400) and the object model (329), the defects in the test object (400) are found and the coordinates of these defects on the test surface (220) are determined. The defect visualization module (324) provides the light elements (210), existing in the vicinity of said coordinates, to emit light in different color when compared with the other light elements (210). Thus, the user can view the defect in the object, placed on the test surface (220), in the vicinity of the object and there is no need for the user to turn his/her head to another direction. Thus, the defect or approval statements are presented to the user by means of augmented reality.

(18) This method and mechanism can be used in the detection of millimetrical defects on panels comprising transparent regions and produced by means of serigraphy like the white good front panel. In case there is a defect on the transparent pattern (410) wall, this transparent region is illuminated in a different color and the defect can be presented to the user in an apparent manner. This method can be used for any broad and shallow test object (400) or for any test object (400) which shall be placed in front of the light source (200) in order to view the defect.

(19) The protection scope of the present invention is set forth in the annexed Claims and cannot be restricted to the illustrative disclosures given above, under the detailed description. It is because a person skilled in the relevant art can obviously produce similar embodiments under the light of the foregoing disclosures, without departing from the main principles of the present invention.

REFERENCE NUMBERS

(20) 100 Image capturing device 200 Light source 210 Light element 220 Test surface 300 Control unit 310 Processor unit 320 Memory unit 321 Data receiving module 322 Position determination module 323 Defect determination module 324 Defect visualization module 329 Object model 400 Test object 410 Transparent pattern 500 Warning item