RU2443983C1 - Method for remote object identification, fluorescent-retroreflective device and optical reader for realising said method - Google Patents

Abstract

FIELD: physics.

SUBSTANCE: disclosed is a method for remote object identification, where a fluorescent-retroreflective device is first placed on an information area, said device illuminating a narrow-directed light beam. Reflected fluorescence radiation, which is encoded via amplitude modulation, is picked up and the obtained information is decoded. Disclosed is a fluorescent-retroreflective device to realise the method, as well as an optical reader.

EFFECT: low labour input, wider operating range and noise immunity.

24 cl, 3 dwg

Description

The invention relates to optical marking and can be used in warehousing, trade, transport, agriculture and other industries where it is necessary to recognize a remote object from a large number of homogeneous ones.

A known method and device for remote identification of an object, according to which a layer with spherical optical elements and an image layer made of pigment or fluorescent paint / US 6100217, G02B 5/128, 2000 / are applied to the mirror surface. The method is implemented under ordinary natural or artificial lighting. Reliability of remote identification of an object in this case is low, since exposure due to specular reflection from flat surfaces of the device itself makes the system operation problematic and limits the range of applications.

Closest to the claimed is a method of identification and a fluorescent retroreflective device set forth in the application / US 2003/0016368, G01B 11/14, 2003 /. In accordance with the specified source of information, micro-optical bodies are applied to the reflective material, designed to transmit the visible spectrum while reflecting the energy of the invisible spectrum, such as ultraviolet or infrared. Reflectors of the invisible spectrum are located below the micro-optical bodies, the materials of which can be amplified by fluorescent components. Instrumentally, the reflected radiation of the invisible spectrum is recorded for computer monitoring systems for the movement of an object. Visually observe reflected fluorescence to improve the visibility of signs or clothing at night.

The specified method and device have the following disadvantages. Firstly, the method has increased complexity, since the application of information on an identifiable object is associated with the implementation of complex, graphic images made of microscopic reflecting elements placed on a surface of an object in a certain way. Secondly, the prototype is characterized by insufficient range and noise immunity, which is the result of insufficient focusing of retroreflective radiation, as well as self-absorption of retroreflective radiation by fluorescent material.

Optical readers are known, i.e. electron-optical reading devices that automatically recognize images of individual letters, numbers and their combinations printed or written on tangible media, for example, a portable, optical reader Ezio Optical Reader from Gemalto (France-Holland). The disadvantage of all known optical readers is the insufficient range and lack of noise immunity.

The present invention is the creation of a method and means of its hardware, devoid of these disadvantages.

The technical result of the claimed invention is to reduce the complexity, increasing the range and noise immunity.

To solve the problem, as well as to achieve the technical result, a method for remote identification of an object is proposed, in which a fluorescence-retroreflective device that is illuminated by a narrow beam of light is preliminarily placed on the information section of the object, the returned fluorescence radiation encoded by amplitude modulation is recorded, and decoded information received.

In addition, it is proposed to register fluorescent radiation focused on the light source.

To implement the method, a fluorescent retroreflective device is proposed comprising successively deposited layers: a layer of fluorescent material, a layer comprising a set of optical focusing elements and an information layer. In this case, one surface of the fluorescent material is in contact with the substrate, the other is between the focal plane of the optical focusing elements and their back surface, and the distance from the outer surface of the fluorescent layer to the focal plane of the optical focusing elements does not exceed the absorption depth of the fluorescent material constituting the fluorescent layer.

In special cases:

- the fluorescent material may be an organic dye in a polymer matrix or quantum dots made, for example, of cadmium selenide passivated by zinc sulfide, or inorganic phosphorus or anti-Stokes phosphor;

- a layer of fluorescent material can contact the rear surface of the optical focusing elements;

- the surface of the substrate in contact with the fluorescent material can be made reflective, for example, of aluminum with a thickness of from 0.9 to 1.1 μm;

- optical focusing optical elements can be placed in a matrix of transparent material, leaving the outer half of the optical elements open;

- the matrix may be made of a polymeric material;

- focusing optical elements can be made in the form of spheres of a transparent material with a diameter in the range from 20 microns to 100 microns;

- spherical recesses can be made in the substrate, in which the focusing optical elements are placed;

- the information layer can be made of a transparent film or plate on which a one-dimensional or two-dimensional code of opaque material is applied;

- the information layer can be made of an opaque film or plate enlightened in the form of a one-dimensional or two-dimensional code.

To solve this problem, an optical reader is also proposed for remote identification of an object, containing a source of narrowly directed light, an optical channel for receiving retroreflected fluorescence radiation, the output of the optical channel being connected to the input to the optoelectronic matrix recording device, the output of which is connected to the input to the decoding device.

Additionally, it is proposed that the light source be laser.

In addition, it is proposed to equip the reader with a spectral filter installed either in front of the entrance to the optical channel or between the output of the optical channel and the entrance to the optoelectronic matrix recording device.

The implementation of the claimed method in combination with the claimed devices can improve the signal-to-noise ratio by improving the directivity of the reflected luminescent glow. In this case, the directivity improvement occurs due to the phosphor being in the focal plane of the optical focusing elements and as close to the surface as possible, otherwise the luminescence photons will not be able to reach the surface and will be absorbed by the material itself. Those. the presence of a focal plane and a thin layer, as well as a certain concentration of the phosphor (so that there is no self-extinguishing effect) determine the maximum detection efficiency of luminescence photons. The presence of an information layer on the outside of the fluorescent retroreflective device makes it easy to apply encoded information, for example, in the form of a one-dimensional or two-dimensional code. Thus, a technical result is achieved.

Figure 1 shows a schematic diagram of a fluorescent retroreflective device, figure 2 shows a schematic diagram of a preferred implementation of a fluorescent retroreflective device, figure 3 shows a diagram of an optical reader, where 1 is a substrate with a reflective layer 2, 3 is a layer of fluorescent material 4 - a layer including a set of optical focusing elements 5, 6 - an information layer, 7 - a matrix of transparent material, 8 - spherical recesses, 9 - a source of narrowly directed light (laser), 10 - optical channel for receiving retroreflected fluorescent radiation, 11 — an optoelectronic matrix recording device, 12 — a decoding device, 13 — a spectral filter.

The method is carried out, and the device operates as follows. A fluorescent retroreflective device with pre-printed information about the object on information layer 5 is fixed on the identifiable object. The identifiable object may be a domestic or wild animal, a transport container, product packaging, etc. In this case, the place of fastening of the retroreflective device, for example, the ear of an animal, is known in advance. If it is necessary to identify the object, the retroreflective device is illuminated by the light (laser) beam of the source 9 of the optical reader. The beam excites the fluorescence signal along its entire path in layer 2, which is then collected and quasi-collimated by the optical focusing element 4. The efficiency of such a scheme is improved when the surface of the substrate in contact with the fluorescent material is made reflective. Then, the reflective layer of the substrate 2 reflects the exciting light back into the layer 3. Note that the presence of the reflective layer 2 is unprincipled. Examples of effective fluorophores are quantum dots (excited in a wide, preferably ultraviolet, spectral range with a controlled size-dependent emission spectral band), organic dyes embedded in a polymer, effective inorganic phosphors (preferred because of their brightness and photostability), chelated rare-earth metals, and in polymer, etc.

Thus, the incident beam is converted into fluorescence and retroreflected in the direction of the source, passing through the information layer 6, with a barcode, 2D code or PIN code applied to it, where it is partially blocked by code information elements, which in other terms is called "amplitude modulation " The wavelength of fluorescent light obviously differs from the wavelength of the exciting light. A set of optical focusing elements 5, densely covering the substrate 1, allows for retroreflection from the entire surface. The selection of key parameters of the presented retroreflective device is as follows. The thickness of the fluorescent layer t = 1 / µ _α , where µ _α = ξ _M · C _M , where µ _α is the linear absorption coefficient (cm ^-1 ); C _M is the molar concentration (M); ξ _M is the molar absorption coefficient (cm ^-1 M ^-1 ). If, as an example of a fluorescent material, Rhodamine 6Ж is chosen (ε _M = 5 × 10 ⁵ cm ^-1 M ^-1 , the maximum molar concentration is C _M = 10 ^-3 M ^-1 ), then t µ20 μm. The reflective layer is selected with a thickness sufficient to reflect light with minimal loss, for example 1 µm aluminum layer. The refractive index of the reflective elements is selected, if possible, more so that the focus points are closer to the rear surface of the ball. The ideal configuration is focusing on the metal layer.

It is expected that the collimation of a fluorescence-retroreflected beam will allow its effective registration at large distances, according to our estimates below. The efficiency of the conversion of exciting light to fluorescence depends on parameters such as the quantum efficiency of the fluorophore, layer 2 thickness, absorption and self-absorption, and can reach 20% or more under optimal conditions according to our numerical and experimental estimates. The advantage of registering a fluorescence signal is the suppression of flare from surfaces, including the surface of a retroreflective device.

The fluorescent retroreflected light beam enters the optical channel 10 of the optical reader, after which the image deposited on the information layer 6 is transmitted to the optoelectronic matrix recording device 11, which is captured, processed and decoded by the decoding device 12. The spectral filter 13 suppresses the light of the source, as well as others external flare. A decoding device may transmit information to external devices (not shown).

Claims (24)

1. A method for remote identification of an object, in which a fluorescent retroreflective device that is illuminated with a narrow beam of light is preliminarily placed on the information area of the object, the returned fluorescence radiation encoded by amplitude modulation is recorded, and the received information is decoded. 2. The method according to claim 1, characterized in that they register fluorescent radiation focused on the source of the light beam. 3. A fluorescent retroreflective device comprising layers successively deposited on a substrate: a layer of fluorescent material, a layer comprising a set of optical focusing elements, and an information layer, while one surface of the fluorescent material is in contact with the substrate, the other is between the focal plane of the optical focusing elements and their back surface, and the distance from the outer surface of the fluorescent layer to the focal plane of the optical focusing elements does not exceed the depths absorption of the fluorescent material constituting the fluorescent layer. 4. The device according to claim 3, characterized in that the fluorescent material is an organic dye in a polymer matrix. 5. The device according to claim 3, characterized in that the fluorescent material is a quantum dot. 6. The device according to claim 5, characterized in that the fluorescent material is a quantum dot made of cadmium selenide passivated by zinc sulfide. 7. The device according to claim 3, characterized in that the fluorescent material is inorganic phosphorus. 8. The device according to claim 3, characterized in that the fluorescent material is an anti-Stokes phosphor. 9. The device according to claim 3, characterized in that the layer of fluorescent material is in contact with the rear surface of the optical focusing elements. 10. The device according to claim 3, characterized in that the surface of the substrate in contact with the fluorescent material is made reflective. 11. The device according to claim 10, characterized in that the reflective surface is made of aluminum. 12. The device according to claim 11, characterized in that the reflective surface is made of aluminum with a thickness of from 0.9 to 1.1 microns. 13. The device according to claim 3, characterized in that the optical focusing optical elements are placed in a matrix of transparent material, leaving the outer half of the optical elements open. 14. The device according to item 13, wherein the matrix is made of a polymeric material. 15. The device according to claim 3, characterized in that the focusing optical elements are made in the form of spheres of transparent material. 16. The device according to clause 15, wherein the spheres are made with a diameter in the range from 20 microns to 100 microns. 17. The device according to p. 15, characterized in that the substrate has spherical recesses in which the focusing optical elements are located. 18. The device according to claim 3, characterized in that the information layer is made of a transparent film or plate on which a one-dimensional or two-dimensional code of opaque material is applied. 19. The device according to claim 3, characterized in that the information layer is made of an opaque film or plate enlightened in the form of a one-dimensional or two-dimensional code. 20. The optical reader for implementing the method according to claim 1, containing a source of narrowly directed light, an optical channel for receiving retroreflective fluorescence radiation, the output of the optical channel being connected to the input to the optoelectronic matrix recording device, the output of which is connected to the input to the decoding device. 21. The reader according to claim 20, characterized in that the light source is a laser. 22. The reader according to claim 20, characterized in that it is equipped with a spectral filter. 23. The reader according to item 22, wherein the spectral filter is installed before entering the optical channel. 24. The reader according to claim 22, characterized in that the spectral filter is installed between the output of the optical channel and the input to the optoelectronic matrix recording device.

Images