FR2698971A1 - Surveillance security device - has light source passing digitally coded light through fibre optic cable to detector - Google Patents

Abstract

The device has a light source (S) for passing light to a fibre optic cable (F) and then to a photodetector (D). The light source is coded with digital information, allowing logic information to be determined by the photodetector. A number of units may be provided to control a zone, or the unit may be used to control the opening and closing of secure doors. ADVANTAGE - Device can be used where there is a high magnetic field. Provides better security.

Description

 Security recognition device.

 The invention relates more particularly to opening and closing systems.

 Many mechanical devices are known for the development of closure systems suitable for any type of opening. Such devices are satisfactory as regards their operating principle, but are quite vulnerable.

 Access systems using magnetic cards and speech recognition methods have also been proposed. If such systems reduce the risk of break-ins, their use is not always possible. This is particularly the case with magnetic cards, with the presence of areas contaminated by the presence of intense magnetic fields.

 The object of the invention is to remedy these drawbacks in a simple, safe and effective manner.

 The problem which the invention proposes to solve is to produce a device which applies to any field where it is possible to use safety closings.

 To solve such a problem, an optical coded closure device has been designed and developed, using light conductors, in particular fibers.

 The principle underlying the invention is to create a device for spatial, frequency and / or time decoding, allowing, by means of a member containing optical fibers capable of receiving luminescent elements, the recognition and the opening of 'an electrical circuit.

To solve such a problem, the device comprises in combination, the following elements:
- at least one light source
- at least one light conductor
- at least one photo detector
said elements being suitably arranged to allow the transport of light information, with a view to creating a digitizable analog signal to provide logical information.

 From this design, the device can have different embodiments. Either the elements are subject to an excitation and continuous analysis circuit, or the elements are subject to an excitation circuit resolved over time.

 In another embodiment, the device implements photo-physical information corresponding to changes in frequency and intensity of light emitted and transmitted by the conductor (s).

 Always aiming to improve the quality and reliability of the recognition system; the latter uses emissive substances dissolved in the light conductor (s), the lifetime of the emission of which allows time discrimination to be introduced.

The invention is set out below in more detail using the appended drawings, in which:
Figure 1 is a view showing the principle behind the device according to the invention.

 Figure 2 is a view showing the recognition device, using a large number of elements: light sources, light conductors, photodetectors.

 Figure 3 is a view showing the principle of operation of the device according to the invention.

 Figure 4 is a view showing the device using time resolution.

 FIG. 5 is a view showing the principle of the device, using a temporal excitation of the sources.

 Figure 6 is a view showing the principle of light absorption.

 Figure 7 is a view showing the principle of fluorescence emission.

 Figure 8 is a view showing the fluorescence absorption and emission spectrum of fluorescein at pH = 11.

 FIG. 9 is a view showing the operating principle of the device implementing a detector comprising optical filters selecting either excitation wavelengths or wavelengths for fluorescence analysis.

 FIG. 10 is a view showing an optical fiber placed in a medium containing monomers.

As shown diagrammatically in FIG. 1, the device on which the invention is based implements the combination of the following three elements:
- at least one light source (S)
- at least one light conductor (F)
- at least one photodetector (D)
Advantageously, the light conductor is an optical fiber.

 This device works without changing frequencies and only the spatial coincidence allowing the transport of light information, leads to a digitizable analog signal, providing logical information.

 In the example of FIG. 2, the recognition device implements a high number of elements (S) (F) (D). When the user uses the member corresponding to the closure system, the different light sources (S) are placed in correspondence with the different photodetectors (D). The state of the fiber placed between the source and the corresponding photodetector, corresponding to a logic level 1 or 0, allows recognition of the organ and its user. The digitizable analog information obtained allows the recording of the passage and the authorization of the passage.

 Figure 3 shows the operating principle of the system according to the embodiment of Figure 2. The introduction of the recognition device excites the device, in particular the different light source (S) and photodetector (D) elements, thus giving , after appropriate electronic processing, digital information. In this figure, the system for reading and processing logic signals is represented by (L). The various light sources (S) are of any known and appropriate type such as white or non-white light sources, light-emitting diodes ... Similarly, as regards optical fibers, the latter are of any known and appropriate type for a person skilled in the art and commonly used in trade.

 This is particularly the case for photodetectors which advantageously can be constituted by photodiodes. The logic circuits for processing information are also of any known and appropriate type.

 According to the invention and in order to obtain a more precise recognition, the device can implement a temporal resolution.

FIG. 4 shows, by way of example, this implementation of the device. By means of optical fibers (F1) (F2) (F3) ... (Fn), it is possible to match different sources (S1) (S2) (S3) ... (Sn) and different photodetectors (D1) (D2) (D3) ... (Dn). Under these conditions, a temporal excitation of one of the light sources is followed by logical information from the photodetectors classified for example (mil) and (m2). Under these conditions, the logical information is recovered as shown in FIG. 5, corresponding for sources 1, 2 and n. At source 2, the excitation is shifted in time. It follows from these provisions, that the temporal use of light sources, or a measurement resolved over time, of photodetectors, makes it possible to have much more precise information. With the means for implementing the device, illustrated in FIG. 2, if there are n fibers, the information will be defined by a column matrix 1 X n. In the embodiment illustrated in FIGS. 4 and 5, the information is defined by a square matrix n X n, which represents a very significant increase in the degree of security.

 Still having the objective of increasing the sensitivity and the precision of the device, it is possible to use light sources which are substantially monochromatic or made substantially monochromatic by using colored filters or by using luminescent probes dissolved in the fibers.

 For a better understanding of the rest of the description, we briefly recall what is meant by luminescence.

 When a substance absorbs visible light or ultraviolet rays, an electron from a binding orbital of said substance is promoted into an anti-binding orbital thereof, with energy greater than the ground state. An electronically excited state is therefore formed.

 However, given the speed of the absorption process, the resulting molecule can be considered fixed when promoting the electron. As a result, an excited molecule is created having the same geometry as the molecule in its ground state. This geometry is not the most stable in the excited state, a first relaxation occurs, allowing to obtain a molecule excited electronically, but in thermal equilibrium with the medium.

 The excitation remains carried by the molecule for a variable time, which depends, on the one hand, on the molecule itself and, on the other hand, on its environment, The disappearance of electronic energy can be done with time of relaxation determined in different ways, namely, non-radiative relaxation, chemical process, emissive process.

This emission is defined by a fluorescence or phosphorescence spectrum and by a quantum yield defined by the number of photons, reemitted in fluorescence, relative to the number of photons absorbed. The emission results in a conservation of the geometry of the molecule (Figures 6 and 7), so that the excitation or absorption spectra and fluorescence or phosphorescence practically do not overlap (Figure 8). Under these conditions, the device according to the invention uses optical fibers which comprise:
- or at least one luminescent substance which emits in another wavelength domain than excitation,
- or an absorbent non-luminescent substance.

 In this embodiment, the photodetectors include optical filters selecting either the excitation wavelengths or the fluorescence wavelengths.

 As shown in FIG. 9, the excitation, whether temporally resolved or not, leads to the fiber output, to logical information which depends on the dissolved substance and its concentration in the fiber.

 Luminescent substances with a long or short lifespan can also be used. One can for example use optical fibers doped by two substances with short and long life, absorbing and emitting radiation around a certain wavelength. It follows that if the excitation is short or long compared to the lifetimes, there is temporal information if the measurement of the emission is shifted in time. This second temporal information is difficult to perceive from a potential fraudster.

 Obviously, the different techniques described above can be combined with one another.

 In an alternative embodiment, it is possible to use a more limited number of light sources and photodetectors, using an optical fiber of the type shown in FIG. 10. This optical fiber is placed in a medium containing, for example, monomers that we will polymerize. After stiffening, the material is cut (dashed lines in Figure 10).

 Advantageously, the device can be produced with a number of optical fibers not connected to the source and to the detector, thus making a copy particularly difficult. Luminescent relays can be used.

 The advantages are apparent from the description.

Claims (9)

-1- Safety recognition device, characterized in that it comprises in combination, the following elements - at least one light source - at least one light conductor - at least one photo detector, said elements being suitably arranged to allow transport luminous information, in order to create a digitizable analog signal to provide logical information. -2- Device according to claim 1, characterized in that the elements are subject to a circuit of excitation and continuous analysis. -3- Device according to claim 1, characterized in that the elements are subject to an excitation circuit resolved over time. -4- Device according to claim 1, characterized in that it implements photo-physical information corresponding to changes in frequency and intensity of light emitted and transmitted by the conductor (s). -5- Device according to claim 1, characterized in that it uses emissive substances dissolved in the light conductor (s), whose lifetime of the emission allows to introduce time discrimination. -6- Device according to claim 1, characterized in that the light conductors are constituted by optical fibers. -7- Device according to claim 1, characterized in that the optical fibers comprise at least one luminescent substance emitting in another range of wavelengths than excitation. -8- Device according to claim 1, characterized in that the optical fibers comprise a non-luminescent absorbent substance. -9- Device according to claim 1, characterized in that the light sources are substantially monochromatic, luminescent probes being dissolved in fibers.