Abstract: The invention provides a method for automatic encrypted marking of liquids and for identifying liquids marked by using this method. For marking certain number of markers is selected and for every marker a random number is generated, which define the amount of a marker used. Based on the number of markers, their measured concentrations and the relation of markers concentrations in the marked liquid, a specific marking code is compiled, characteristic only for this liquid. The marking code is encrypted and delivered to an authorized user. The encrypted marking code is decrypted and for identifying the liquid the original parameters contained in the marking code are compared with parameters actually measured on-site. This identification is carried out automatically in real time without any need for laboratory analyses, thus practically excluding human factor in both the marking and identification processes.

Abstract: The present invention discloses a portable, reliable, automated and simple device using Spectral Fluorescence Signature technology (SFS) for fast and accurate drug detection, quantification and data storage. The present also discloses a method for using Spectral Fluorescence Signature technology (SFS) for fast and accurate drug detection, quantification and data storage. Such device and method needing not highly skilled personnel or specific background to run the tests.

Abstract: A device for non contact detection of low concentration substances outside a laboratory environment is disclosed. A probing laser emission is split into two linear orthogonally polarized emission components and one component is delayed in time relative to the other. Both components are directed to a focal region that is proximate to a target medium thought to contain the substance to be detected. Between the arrival of the first and second emission components, an excitation light pulse at a wavelength corresponding to an absorption line in the spectrum of the substance is directed to the focal region. If vapours of the substance are present, they will be heated by the excitation pulse and will change the index of refraction of the focal region before the second emission component passes through it, thus altering the phase of the back-scattered emission returns. The device delays the first returned component by an equal delay and coherently couples the returned emission components.