NL1015029C1 - Bar-code with reflective and non-reflective stripes to increase contrast and hence range at which laser scanner may be used - Google Patents

Abstract

The base (11) is of retro-reflective material and serves as the first stripe (14). The second stripe (15) of light-absorbent material is applied by conventional printing methods. An inverse construction could be used, together with mirror-reflective stripes.

Description

Title: Code body.

The present invention relates to a code member, comprising a carrier with a barcode in the form of mutually parallel strips applied to it, comprising first strips with a first reflection coefficient and second strips with a second reflection coefficient lower than the first reflection coefficient. Such code bodies are known in practice. The stripe pattern that represents information in coded form is also referred to as barcode.

10 Barcodes apply, among other things, to consumer items, where the barcode contains information about the item. Basically, barcodes consist of an area applied to a surface, which is divided into several successive strips with mutually different reflection coefficients, the reflection coefficient being defined as the ratio between the incident and reflected amount of light.

In practice, a stripe or line pattern is usually applied to a light background, the stripe or line pattern contrasting darkly against the light background. To read the information stored in the barcode, the barcode can be scanned by means of a scanner. It comprises a light source, usually a low power laser, which emits a narrow beam of light, varying the direction of the beam. Part of the emitted light is, while retaining the barcode pattern, reflected by the code member and received by the scanner.

In the scanner, a received light signal is converted into an electrical signal, the strength of which corresponds to the amount of light received. Thus, an electric signal of varying strength is produced, in accordance with the 1015029 2 pattern of the barcode. It is important here that there is sufficient contrast between the light and dark parts of the code element to guarantee a correct 'scanning' of the barcode.

It has been found in practice that the degree of reflection of conventional code members with barcodes is very low. The contrast between, for example, black stripes and a white background is optically quite great, but the strength of the light received back by the scanner is very weak, and moreover decreases exponentially with increasing distance between the scanner and the code element. One reason for this lies in the fact that the materials used for the carrier of the barcode, usually printed paper, have a reflection characteristic which is partly specular and partly diffuse. The amount of light reflected towards the scanner is only a very small fraction (<10 ”6) of the light emitted by the scanner. All this results in a reading distance of about thirty centimeters. Beyond this distance, the amount of reflected light reaching the scanner will be so small that it becomes difficult or impossible to read the barcode with certainty. These barcodes will be poorly suited especially when barcodes are used in an industrial and / or electrically polluted environment, where distances often have to be bridged that exceed the reading distance of the conventional barcodes.

An increase in the maximum reading distance is possible by using more powerful lasers. However, this makes the scanners considerably more expensive, and in addition, the use of powerful lasers is undesirable for safety reasons. In addition, the effect to be achieved is limited.

It is therefore an object of the present invention to provide an improved code element, in particular with a barcode, which can be recognized with certainty from already longer distance by pre-existing laser scanners.

The present invention is based on the insight that a better contrast and thus a better detectability of the barcode can be achieved if the efficiency of the reflection characteristic in the direction of the scanner is improved. The present invention is further based on the recognition that such an improvement can be achieved by using retro-reflective material, ie material where the peak of the reflection characteristic is measured at 180 °. Commercially available retro-reflective materials can achieve a reflection coefficient of the order of 10 "2 at an angle of 10 180 °.

To achieve the above-mentioned purpose, a code member according to the invention is therefore characterized in that the first strips are made of a substantially retro-reflective material. Hereby, a code member will be obtained with a high contrast between the first strips and the second strips of the code member.

In a preferred embodiment, the second strips are made of a substantially diffuse-reflective material. Hereby an even higher contrast is obtained between the first strips and the second strips of the coder, which results in an improved detectability of the coder.

In an alternative embodiment, the second strips are made of mirror-reflective material. This also results in a code member with a further improved detectability.

In a further alternative embodiment, the second strips are made of material with a greater light absorption than the retro-reflective material of the first strips.

The carrier is advantageously made of retro-reflective material, on which the second strips are arranged with mutual spaces, the mutual spaces acting as the first strips, which results in an easily manufactured code member.

1015029 4

In a possible embodiment according to the present invention, the carrier is made of non-retro-reflective material, on which the first strips are mutually spaced, the spacings acting as the second strips.

In a further preferred embodiment, the carrier is a sticker on which the barcode can be applied. A code element is thus provided which is very user-friendly and, moreover, is very versatile. The barcode can be applied to the carrier by means of a printing technique known per se, such as screen printing, offset, stamping, inkjet or the like.

These and other aspects, features and advantages of the present invention will be further elucidated with reference to the following description of a preferred embodiment of a code member according to the invention with reference to the drawing, and in which: figure 1a schematically shows a substantially mirror-20 shows reflective surface with incident light beam; Figure 1b schematically shows a substantially retro-reflecting surface with an incident light beam; Figure 1c shows a reflection characteristic; figure 2 schematically shows a top view of a code member according to the invention with a carrier and a barcode arranged thereon; figure 3 shows schematically in cross section an embodiment of the code member of figure 2; figure 4 schematically shows in perspective a code member according to the invention in a first alternative embodiment, and figure 5 shows schematically in perspective a code member according to the invention in a second alternative embodiment.

1015029 5

In general, the reflection properties of a light-reflecting surface will now first be discussed with reference to Figures 1a to 1c.

Figures 1a and 1b show a light-reflecting surface 1 5 and an incident light beam 2. The incident light beam 2 makes an angle φ with the normal AA 'of the surface 1. The light-reflecting surface 1 will reflect the incident light beam 2 at a manner depending on the light-reflecting properties of the surface 1. Figure 1a illustrates the reflection of the incident light beam 2 in case the surface 1 has mainly mirror-reflecting properties. In the theoretical case that the surface 1 is an ideal specular surface, the incident light beam 2 will be reflected by the surface 1 as a single light beam with a beam axis 4, in a direction relative to the normal for which angle of incidence applies. = angle of reflection. The beam axis 4 therefore makes an angle Θ with the incident light beam 2 which is equal to 180 ° -2φ. In practice, materials generally have non-ideal properties and thus the surface 1 will be non-ideal reflective. As a result, the incident light beam 2 will be reflected by the surface 1 as a divergent light beam 3 with a main direction coinciding with the beam axis 4. This is shown in the figure in broken lines, which serve only as an illustration and no physical boundary of the divergent represent beam 3.

In the case that the surface 1 is ideally diffuse-reflective, the incident light beam 2 will be completely scattered and reflected equally in all directions.

Similar to the aforementioned case of an ideal specular surface, in the theoretical case that the surface 1 is ideal retro-reflective, the incident light beam 2 will be reflected by the surface 1 as a single light beam with a beam axis 6. The incident 1015029 6 light beam 2, because of the retro-reflective properties of the surface 1, is reflected in a direction opposite to the direction from which it was emitted, so that the beam axis 6 makes an angle γ with the 5 normally AA 'which is equal is at the angle φ. The angle between the beam axis 6 and the light beam 2 is therefore 180 °.

In practice, however, because of the non-ideal properties of the surface 1, the incident light beam 2 will be reflected as a divergent light beam 5 with a main direction coinciding with the beam axis 6. This is shown in the figure in broken lines, which again are for illustrative purposes only and do not represent a physical boundary of the divergent beam 5.

The intensity I of the reflected light is dependent on the location in the light beam 3, 5, ie dependent on an angle β with respect to the beam axis 4, 6. This is indicated by I (β) and is discussed in more detail on the hand of figure 1c.

Figure 1c shows a reflection characteristic 7 of a reflecting surface, ie an intensity profile of a reflected light beam 3, 5, the intensity I (β) being shown along the vertical axis and the angle β along the horizontal axis. The angle β = 0 ° corresponds to the beam axis 4, 6 of the reflected light beam 3, 5. The intensity I (β) of the reflected light shows a maximum value or peak reflection for β = 0 °.

Generally, the intensity profile of the reflected beam 3, 5 will have a bell-shaped contour, as shown by a solid line 8.

If the surface 1 is an ideal-diffuse-reflecting surface, the incident light beam 2 is reflected equally in all directions and the intensity I of the reflected light is therefore constant in each direction.

This is indicated in the figure by a dashed line 9, 35 where the angle β = 0 ° in this case is an arbitrary direction, 1015029 7 and can for example correspond to the normal of the surface 1.

In the context of the present invention the following concepts will be used: - mainly retro-reflective: the reflection characteristic has a local maximum at a reflection angle of 180 °, that is, an incident light beam is reflected in a direction which is opposite to the direction from which it was broadcast; - mainly mirror-reflective: the reflection characteristic has a local maximum at a reflection angle equal to the angle of incidence, that is, an incident light beam is reflected in a direction with respect to 15 of the normal for which: angle of incidence = angle of reflection; - diffuse: an incident light beam is completely scattered and equally reflected in all directions.

Figure 2 shows a code member 10 with a flat support 11, very schematically shown from the viewpoint of illustrative simplicity, with a barcode 12 applied thereon. Figure 3 shows a part of the code member 10 schematically in cross section. The barcode 12 is provided on the carrier 11 in the form of mutually parallel strips 13. The strips 13 alternately comprise first strips 14 and second strips 15, with a first and a second reflection coefficient, respectively, the second reflection coefficient being less than the first reflection coefficient. In the context of the present invention, the term "reflection coefficient" means the reflection coefficient measured at an angle of 180 ° with respect to incident light.

The first strips 14 consist of retro-reflective material and the second strips 15 may consist of non-retro-reflective material. Since retro-reflective materials suitable for use in a coder of the present invention are known per se 1015029, such material will not be explained in more detail here. Suffice it to mention, for example, the commercially available Fascal Retro-reflective Class II (XR-1000) from Avery Dennison.

Figure 3 illustrates the operation of the invention. A beam of light 16, for example emitted by a laser scanner, falls on the code member 10, with a first beam part 19 and a second beam part 20, each beam part 19, 20 making an angle φ with the normal AA 'of the carrier 11. The first bundle part 19 strikes a first strip 14 and second bundle part 20 strikes a second strip 15.

Because of the retro-reflective properties of the first strips 14, the first beam part 19 is reflected substantially at an angle of 180 ° with the direction of the beam 16, as explained with reference to Figure 1b.

This is represented in figure 3 by arrow 18. The second beam part 20 is reflected essentially in a direction indicated by arrow 17 and with the second beam part 20 makes an angle Θ which is equal to 180 ° -2φ.

A detector arranged at 180 ° will observe a large contrast between reflected light from the first strips 14 on the one hand and reflected light from the second strips 15 on the other. The light intensity of the reflection light from the first strips 14 is relatively large. This results in good detectability. In order to improve the detectability of the code member, it is preferable that the second strips 15 are made of a mirror-reflective or a diffuse-reflective material and that the absorption coefficient of the material of the second strips 15 is greater. than the absorption coefficient of the material of the first strips 14. In the case where the second strips 15 are made of a material having mainly mirror-reflective properties, it is preferable to use a detector at an angle deviating from 180 ° relative to draw up code body 1.

1015029 9

In the embodiment of the code member 10 shown in figure 3, the first strips 14 and the second strips 15 are arranged side by side on the common carrier 11. However, it is also possible to use the carrier 11 of the code member 105 alone. provided with strips with a different reflection coefficient than that of the carrier 11. This is shown in figures 4 and 5.

The carrier 11 can for instance be made of retro-reflective material, on which second strips 15 are arranged of non-retro-reflective material, as illustrated in figure 4. The surface of the carrier 11 hereby functions as the first strips 14. The strips 15 of non-retro-reflective material can be applied to the carrier 11 by means of a printing technique known per se, such as screen printing, offset, stamping, inkjet or the like.

Conversely, it is also possible to manufacture the carrier 11 from non-retro-reflective material, such as paper, cardboard, plastic and the like, on which first strips 14 of retro-reflective material are arranged.

It is also possible to apply a so-called inverse imprint 21 on the carrier 11. This is shown in figure 5.

In the imprint 21, strip-shaped openings are provided which function as the first strips 14 in the case that the support 25 11 is made of retro-reflective material and the imprint 21 is made of non-retro-reflective material. If the carrier 11 is made of non-retro-reflective material and the imprint is made of retro-reflective material, the strip-shaped openings 30 in the inverse imprint 21 can function as the second strips 15.

In a particularly preferred embodiment of the code member according to the invention, the carrier 11 is a sticker of retro-reflective material, on which a barcode can easily be applied by, for example, screen printing, printing or a similar method. This provides a very user-friendly and easy-to-manufacture code member with a high degree of detectability.

1015029 10

Any product on which a barcode must be applied can also function as a carrier. This could include, for example, packaging of consumer goods, industrial packaging, semi-finished and whole products, etcetera. Another application may be the provision of a platform of a (metro) station with a code device according to the invention for identifying the relevant station by an incoming (metro) train for passenger information in the (metro) train.

The code element according to the invention is not limited to the embodiments shown in the figures, but can have any arbitrary shape, for instance 3-dimensional, in which the barcode is applied as raised strips of material to a surface, whereby either the surface or the strips 15 are made of retro-reflective material. The dimensions of the code organ are also not important; this can be any size.

Although it is preferred that the second strips are made of non-retro-reflective material, it is also possible that the second strips, like the first strips, are made of retro-reflective material, but with a lower peak reflection than the first strips.

1015029

Claims (8)

A code member, comprising a carrier having a barcode in the form of mutually parallel strips thereon, comprising first strips with a first reflection coefficient and second strips with a second reflection coefficient lower than the first reflection coefficient, characterized in that the first strips (14) are made of a substantially retro-reflective material. Code member according to claim 1, characterized in that the second strips (15) are made of a substantially diffuse-reflecting material. Code member according to claim 1, characterized in that the second strips (15) are made of mirror-reflecting material. Code member according to any one of claims 1 to 3, characterized in that the second strips (15) are made of material with a greater light absorption than the retro-reflective material of the first strips (14). Code member according to any one of claims 1 to 4, characterized in that the carrier (11) is made of retro-reflective material, on which the second strips (15) are arranged at mutual intervals, the mutual gaps act as the first strips (14). Code member according to any one of claims 1 to 4, characterized in that the carrier (11) is made of non-retro-reflective material, on which the first strips (14) are arranged at mutual intervals, wherein the interstices act as the second strips (15). 1015029 Code member according to any one of claims 1 to 4, characterized in that the carrier (11) is made of any material on which mutually parallel strips (13) are arranged, which alternately form the first strips (14) 5 and the second strips (15). Code member according to any of the preceding claims, characterized in that the carrier (11) is a sticker. 10 1015029