Sensor and method for checking authenticity of valuable documents with a luminscent security feature

The invention claimed is: 1. A method for checking the authenticity of value documents which for checking their authenticity are transported past a sensor and which have a security feature which in response to a luminescence excitation by an excitation source emits a first luminescence at a first wavelength, which has as a function of time t a first intensity pattern y 1 ( t ) with a first characteristic time constant τ 1 , as well as a second luminescence at a second wavelength different from the first wavelength, which has as a function of time t a second intensity pattern y 2 ( t ) with a second characteristic time constant τ 2 , with the following steps: detecting the first intensity pattern y 1 ( t ) and the second intensity pattern y 2 ( t ) as a function of time t at the same location of detection of the security feature with the help of the sensor; calculating a first index S 1 =S(y 1 ( t i )), with i=1, 2, . . . , n, with the help of a scaling-invariant function S:R n →R from several first intensity values y 1 ( t i ) of the first luminescence, which are detected at different points in time t i during a building up and/or during a decaying of the first identity pattern y 1 ( t ); calculating a second index S 2 =S(y 2 ( t i )), with i=1, 2 . . . , n, with the help of a scaling-invariant function S:R n →R from several second intensity values y 2 ( t i ) of the second luminescence, which are detected at the different points in time t i during a building up and/or during a decaying of the second intensity pattern y 2 ( t i ); determining a ratio V between the first index S 1 and the second index S 2 ; and checking the authenticity of the value document on the basis of the ratio V or on the basis of a value W derived from the ratio V, wherein the scaling-invariant function S has the property that the first index S 1 is scaling-invariant with respect to the first intensity values y 1 ( t i ) and the second index S 2 is scaling-invariant with respect to the second intensity values y 2 ( t i ). 2. The method according to claim 1 , wherein for the calculation of the first index S 1 and of the second index S 2 the same scaling-invariant function S is used. 3. The method according to claim 1 , wherein at least some of the points in time t i lie during the building up of the first and second intensity patterns and the ratio V is a measure for the ratio between the build-up time of the first intensity pattern y 1 ( t ) and the build-up time of the second intensity pattern y 2 ( t ). 4. The method according to claim 1 , wherein at least some of the points in time t i lie during the decaying of the first and second intensity patterns and the ratio V is a measure for the ratio between the decay time of the first intensity pattern y 1 ( t ) and the decay time of the second intensity pattern y 2 ( t ). 5. The method according to claim 1 , wherein the second intensity values y 2 ( t i ), from which the second index S 2 is calculated, for i=1, 2 . . . , n, are detected at the same points in time t i as the first intensity values y 1 ( t i ), from which the first index S 1 is calculated. 6. The method according to claim 1 , wherein within the framework of the scaling-invariant function S there is formed the quotient P J /P K of two different linear functionals P J and P K , which respectively map the first intensity values y 1 ( t i ) or second intensity values y 2 ( t i ) detected at the different points in time t i into the space of real numbers. 7. The method according to claim 1 , wherein for the calculation of the first index S 1 , the quotient P J (y 1 ( t i ))/P K (y 1 ( t i )) of two different linear functionals P J (y 1 ( t i )) and P K (y 1 ( t i )) is used, which respectively map several first y 1 ( t i ) intensity values detected at the different points in time t i into the space of real numbers, and that for the calculation of the second index S 2 , the quotient P J (y 2 ( t i ))/P K (y 2 ( t i )) of two different linear functionals P J (y 2 ( t i )) and P K (y 2 ( t i )) is used, which respectively map several second intensity values y 2 ( t i ) detected at the different points in time t i into the space of real numbers. 8. The method according to claim 1 , wherein for the calculation of the first index S 1 there is used the same linear functional P J and the same linear functional P K as for the calculation of the second index S 2 , wherein for the first index S 1 the linear functionals P J and P K are calculated on the basis of the first intensity values y 1 ( t i ) and wherein for the second index S 2 the linear functionals P J and P K are calculated on the basis of the second intensity values y 2 ( t i ). 9. The method according to claim 1 , wherein the linear functional P J (y 1 ( t i )) maps the first intensity values y 1 ( t j ) detected at several points in time t j into the space of real numbers and that the linear functional P K (y 1 ( t i )) maps the first intensity values y 1 ( t k ) detected at several points in time t k into the space of real numbers and that the linear functional P J (y 2 ( t i )) maps the second intensity values y 2 ( t j ) detected at several points in time t j into the space of real numbers and that the linear functional P K (y 2 ( t i )) maps the second intensity values y 2 ( t k ) detected at several points in time t k into the space of real numbers, wherein the points in time t k are different from the points in time t j . 10. The method according claim 1 , wherein by the linear functional P J , applied to the first intensity values y 1 ( t j ), there is calculated an integral or a sum of the first intensity values y 1 ( t j ), and that by the linear functional P J , applied to the second intensity values y 2 ( t j ), there is calculated an integral or a sum of the second intensity values y 2 ( t j ), and that by the linear functional P K , applied to the first intensity values y 1 ( t k ), there is calculated an integral or a sum of the first intensity values y 1 ( t k ), and that by the linear functional P K , applied to the second intensity values y 2 ( t k ), there is calculated an integral or a sum of the second intensity values y 2 ( t k ), wherein the points in time t k are different from the points in time t j . 11. A sensor for checking value documents which for their check are transported along a transport direction (x) past the sensor, the value documents having a security feature which in response to a luminescence excitation by an excitation source emits a first luminescence at a first wavelength, which has as a function of time t a first intensity pattern y 1 ( t ) with a first characteristic time constant τ 1 , as well as a second luminescence at a second wavelength different from the first wavelength, which has as a function of time t a second intensity pattern y 2 ( t ) with a second characteristic time constant τ 2 , the sensor comprising: an excitation source for exciting a first luminescence and a second luminescence of the value document; at least two photodetectors for detecting the first and second luminescence which the value document excited by the excitation source emits in a detection region, wherein the luminescence of the value document is detectable by the photodetectors in at least two different spectral regions and wherein the sensor is configured such that the photodetectors respectively detect the luminescence of the same detection region of the value document at the same points in time; and an evaluation device which is configured to carry out an authenticity check of the value documents by detecting the first intensity pat