The invention relates to a method for producing a three-dimensional image. The invention relates in particular to a method for producing a three-dimensional portrait image of a person, comprising the steps of:
It is known for a three-dimensional image to be created by producing two or more images of an object from a different angle. The images are divided into image lines in a digital processing unit and are interlaced, so that groups of image lines are formed. These groups of image lines are then applied onto an image layer of an image carrier, and a linear lens is applied above each group of image lines. The interlaced images under each lens are mapped by the linear lenses at a predefined viewing distance onto a left or a right eye, so that a stereoscopic image is obtained. One method for applying the image lines onto the image carrier is by means of a laser beam, which is focused by the linear lenses on an image layer of, for example, polycarbonate, where it causes a discolouration with an intensity depending on a greyscale value of an image element (pixel) located along the image line.
In an alternative method, the lines can be applied onto the image layer by means of a printing technique, after which the lenses are applied over the groups of printed image lines.
Three-dimensional images of the abovementioned type are used in identity documents such as identity cards, passports, driving licences or in access passes, bank passes and other secured identification means.
In order to obtain a stereoscopic effect at different viewing distances, four or more images of a person are often simultaneously created, each from a different angle. To do this, four or more digital cameras are used, which are set up at different angles and which simultaneously create an image from these different angles. A set-up of this type is relatively costly, due to the large number of cameras and the synchronous effect thereof. As a result, three-dimensional images, in particular portraits for use on identity media, can only be produced in a specialized environment.
A method according to the preamble to claim 1 is known from WO 2006/110038. This publication describes how two rotation images can be obtained from a two-dimensional basic image by means of projection in an image processing device with the aid of special software, said images being applied in an interlaced manner under linear lenses in order to form a stereoscopic portrait image for use in a security or identification document.
A disadvantage of the known method is that the similarity with the original basic image may decrease through calculation of the rotation images, and that images calculated in this way are thereby less suitable for use in security and identification documents such as passports, driving licences, access badges, etc. As a result, the authenticity of a three-dimensional image of this type is difficult to establish on visual inspection. An object of the invention is to provide a method for producing a three-dimensional image, with which a stereoscopic image can be created without special cameras, the authenticity of which can quickly be established on visual inspection. A further object is to provide a three-dimensional image of a person which reveals a close similarity with the imaged person. An object of the invention is also to provide a method with which a stereoscopic image can be produced in a relatively fast and economical manner, also without using a camera.
For this purpose, the method according to the invention is characterized in that:
and that image lines are formed for the basic image which form part of the groups of corresponding image lines and are applied with the imaging device onto the substrate. A three-dimensional primary form is calculated in an image area in the processing device from a single capture by measuring the facial points in the basic image. The three-dimensional facial form is then determined in the processing device through projection of the basic image onto the primary form. Through projection of this three-dimensional facial form onto the projection area, at least one rotated image is calculated, with which an accurate stereoscopic image can be obtained. A “projection view generation” of this type according to the invention, unlike, for example, an “intermediate view generation”, wherein the average missing images between two basic images are calculated, provides a rotation image closely resembling the person. Since the original basic image is also used in the formation of the three-dimensional, interlaced image, the visual check on the authenticity of the image can be carried out very quickly and effectively, and the risk of the unique characteristics of the image being lost through calculation is substantially reduced.
Since at least one closely similar rotated image is calculated from a single two-dimensional capture through “projection view generation” calculation in the processing device, said image being combined with the original two-dimensional capture, an accurate stereoscopic image can be obtained for use in identification documents or security documents from only one single conventional two-dimensional image, such as a scan or a photo. As a result, the stereoscopic photos associated with identity documents can be produced at various issue locations, such as photo studios, town halls, etc. Furthermore, the costs of producing the stereoscopic images are reduced through the use of a single camera or scanned-in photo.
In one embodiment, the imaged object is a human face and the distance D between the face and the camera is between 40 cm and 3.0 m, and the rotation angle of each calculated rotation image is between 3 and 10 degrees. Evidence reveals that an accurate stereoscopic image which is highly suitable for identification purposes can be obtained with these distances and angles of rotation.
In an alternative embodiment, the rotation point is located between the eyes, on or near the surface of the face. As a result, a natural representation of the human face is obtained which is highly suitable for identification purposes, wherein the eye position of the imaged person remains constant when the image is rotated in relation to the observer.
In one preferred embodiment, it is ensured during the formation of the interlaced images on the carrier under the linear lenses that the eye positions of each image are applied in an overlapping manner onto the substrate. When the three-dimensional image is viewed by a checking person, the viewed eye position of the image will thereby always remain constant and this eye position will be permanently in sharp focus. The other parts of the face will rotate as the viewing angle varies and may also vary in sharpness. By allowing the eye positions of the basic image and the rotation images to coincide on the carrier, the accuracy and effectiveness of visual inspection are increased.
In a further embodiment, a mark, which is relatively small in relation to the images, is placed in the processing device on the at least two images.
By applying a mark placed in front of the object, for example a security mark with digits and/or letters, this mark on the image appears to move backwards and forwards in front of the imaged object if the image is viewed from different viewing directions. As a result, an additional authenticity characteristic is formed in the image, which helps to establish the authenticity and/or uniqueness of the image.
The imaging device preferably comprises a laser and a carrier table with an image surface, wherein the laser is movable along image lines over the image surface, wherein the carrier table is rotatable around an axis located in the direction of the image lines, wherein a carrier layer is positioned on the carrier table with the linear lens pattern above it and the image lines are applied with the laser via the lens pattern in the carrier layer and wherein, following the application of an image, the carrier table is rotated, after which the next image is applied onto the carrier layer.
Since the tilting of the carrier table is linked to the rotation angle of the calculated rotation images, an effective and accurate production of stereoscopic images is obtained on the basis of a single image.
A number of embodiments of a method for producing a three-dimensional image according to the invention will be explained in detail by way of example with reference to the attached drawing. In the drawing:
a and 5b respectively show a top view and a side view of the primary form,
a shows a projection of the basic image onto the primary form in the image area to obtain the facial form,
b and
In an image layer 7 of the substrate 2, a group 8, 9, 10 of interlaced image lines is applied which comprise image elements (pixels) which are burned via a laser into the image layer 7. In the example shown, the groups of image lines 8-10 are formed by vertical areas of carbonized image layer material (for example polycarbonate), which are formed in places where the laser beam is focused by the lenses 3-5 on the image layer 7. Since the laser beam is focused by the lenses 3-5 during the writing of the image lines into the image layer, the groups of interlaced image lines are exactly aligned in relation to the lenses 3-5.
Each group 8, 9, 10 of image lines (111, 121 . . . 1m1), . . . , 11n, 12n, . . . ,1mm) comprises m lines, wherein m may be between 2 and 60 (for the sake of clarity, only 3 image lines per group are shown). Each image line in a group is deflected by the associated lens in a predefined direction to the observer. An observer viewing the image carrier 1 from a specific angle will ideally only see 1 image line per lens with one eye, for example image line 11v, 12v . . . 1mv in each group of image lines (111 . . . 1m1), . . . , (11n . . . 1mn). Different images can be viewed through movement of the observer in relation to the image carrier 1.
The height H of the substrate 2 is, for example, 250 μm. The thickness T of the image layer 7 is, for example, 50 μm. The width L of a linear lens is, for example, 75 μm and the height D of a lens can be 10 μm. The width of the carbonized areas 11 in the image layer is around 15 μm and the distance between these areas is around 1 μm.
As shown in
The basic image A of the person is then projected from a projection surface 59 with coordinate zp, in the image area 58 onto the primary form 57 in order to form the facial form 60 in the image area 58, as shown in
The steps which are carried out in the image processing device and which are described with reference to
The image values of the pixels 16 are converted for each group of image lines into an intensity and/or colour and are applied onto a carrier in a direction which corresponds to the arrows in the images A-C in order to obtain the three-dimensional image D, as explained in detail with reference to
The three-dimensional image D is composed by combining rotation images A, B, C, wherein the images B and C are calculated according to the invention on the basis of the original image A. When projecting the images A-C onto the carrier, it is ensured that the coordinates of eye positions (xo, yo) of these images for the original A and for the rotation images B, C are identical: (xo, yo)A=(xo, yo)B=(xo, yo)C. As a result, when the image D is viewed from different angles, the observer will retain the eye area in constant sharp focus so that visual inspection of the image and comparison of this image with the actual person are simplified. It is also possible to use different original images A in the construction of the 3-dimensional image D.
In the processing unit 30, one or more rotation images are formed (in this example, four rotation images are formed) from the pixels of the upright image 24 and are represented by the schematic positions 25, 26, 27 and 28 of the nose 24. The rotation angle γ is, for example, in each case between 2 degrees in a positive or negative direction of rotation. The four rotation images are stored in the processing unit 30 in the form of image values associated with pixels positioned along image lines. From the processing unit 30, the image information for each rotation image is supplied to a write device 31 which comprises a laser and a tiltable carrier table on which an image carrier of the type shown in
Number | Date | Country | Kind |
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2004481 | Mar 2010 | NL | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/NL2011/050210 | 3/29/2011 | WO | 00 | 9/26/2012 |