Detection apparatus and method
First Claim
1. Detection apparatus for determining the presence, absence or characteristic of a security ink on a sample, the apparatus comprising:
- (a) a radiation source for providing excitation radiation of a first measurable frequency spectrum to the sample;
(b) a detector for detecting radiation of a second measurable frequency spectrum emitted from the sample subsequently and as a result of providing said excitation radiation to said sample; and
(c) a processor arranged in use to determine the presence, absence or characteristic of said ink on the sample according to analysis of the detected spectrum of radiation subsequently emitted from the sample in response to providing said excitation spectrum to said sample by measuring the frequency of radiation emitted from the sample in the same part of the spectrum as the frequency of excitation subsequently following said excitation; and
by subsequently automatically adjusting the intensity of a subsequent excitation radiation of said first frequency spectrum from said radiation source thereafter depending on the detected strength of detected radiation frequency spectrum emitted from the sample.
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Accused Products
Abstract
A technique and apparatus for detection of infrared radiation emitted from a taggant material sample following the excitation of the sample are described. The decay time of the radiation is a function of the particular taggant being used and so, if the decay characteristic or signature is accurately measured, the particular taggant can be accurately identified. The apparatus comprises an electronic controller (10), a pair (12) of illuminating light-emitting diodes, a photo-detector (14), a first amplifier (16), a three-way sampling switch (18), filter/stores (20)(a-c), second amplifiers (22)(a-c) and an output display (26). The infrared emission is excited by repeatedly illuminating the material for a period of microseconds every few milliseconds using a very intense source of infrared light. This light is supplied by the pair of 940 nm, light-emitting diodes (12). Once this light source has been turned off, the sample continues radiating infrared light for a few milliseconds. The emission is detected by photo-detector (14) that is only sensitive to infrared light in the 800 to 1000 nm waveband. This helps to reject interference from visible light sources.
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Citations
13 Claims
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1. Detection apparatus for determining the presence, absence or characteristic of a security ink on a sample, the apparatus comprising:
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(a) a radiation source for providing excitation radiation of a first measurable frequency spectrum to the sample; (b) a detector for detecting radiation of a second measurable frequency spectrum emitted from the sample subsequently and as a result of providing said excitation radiation to said sample; and (c) a processor arranged in use to determine the presence, absence or characteristic of said ink on the sample according to analysis of the detected spectrum of radiation subsequently emitted from the sample in response to providing said excitation spectrum to said sample by measuring the frequency of radiation emitted from the sample in the same part of the spectrum as the frequency of excitation subsequently following said excitation; and
by subsequently automatically adjusting the intensity of a subsequent excitation radiation of said first frequency spectrum from said radiation source thereafter depending on the detected strength of detected radiation frequency spectrum emitted from the sample. - View Dependent Claims (2, 3, 4, 5, 6, 7)
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8. A method of determining the presence, absence or characteristic of security ink on a sample, the method comprising:
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irradiating the sample with excitation radiation of a first frequency spectrum; subsequently detecting a second frequency spectrum of excitation radiation emitted from the sample; and processing an electronic signal derived from the subsequently detected frequency spectrum of radiation including; measuring the frequency of radiation emitted from the sample, in the same part of the spectrum as the frequency spectrum of excitation radiation following irradiating said sample with said excitation radiation; and subsequently automatically adjusting the intensity of a subsequent the irradiating excitation radiation of said first frequency spectrum thereafter depending on the detected strength of the detected radiation frequency spectrum emitted from the sample. - View Dependent Claims (9, 10, 11)
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12. Detection apparatus for determining the presence, absence or characteristic of a security ink on a sample, said ink characterized by a emission frequency spectrum of radiation in response to a frequency spectrum of excitation radiation illuminated upon said security ink, said apparatus comprising:
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a) a radiation source for providing a first excitation radiation of a predetermined frequency spectrum and time to the sample by illuminating the sample for a fixed time and intensity with said excitation radiation; b) a detector for detecting the intensity of emitted radiation of a frequency spectrum from the sample at a measured time subsequent to said fixed time and as a result of the first excitation radiation illumination of the sample; c) a processor arranged to control the time period of the first excitation radiation to record the said measured intensity of the emitted radiation, and to automatically adjust the intensity of a subsequent illumination of the sample by excitation radiation based on the intensity of the emitted radiation; and d) display apparatus arranged to indicate the presence, absence or characteristic of the sample.
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13. A method of identifying a taggant comprising the steps of:
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(a) irradiating the taggant with a pulse of excitation radiation so as to cause the taggant to emit luminescent radiation that decays with time; (b) measuring and storing a reference reading, and a decay reading of the luminescent radiation emitted from the taggant; (c) ratioing the reference reading and the decay reading to generate decay ratio data; (d) repeating steps (a)-(c) and in step (a) to thereby adjust the intensity of the excitation radiation depending previously measured ratio data readings; and (e) identifying the taggant by referencing the ratio data generated in step (c).
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Specification