There is provided a paint including a pigment, a carrier liquid, a binder, one or more additives, and a taggant corresponding to the one or more additives. The taggant is provided in an amount up to substantially 0.1% by weight of the paint. The taggant is excitable by infra-red or UV light at one wavelength to emit light at one or more other wavelengths, the emission wavelength or spectrum of the taggant being indicative of the additive(s) in the paint. A method of authenticating the paint on a substrate is also provided.

Described herein is a sensor for a virtually simultaneous measurement of transmission and/or forward scattering and/or remission and for a simultaneous measurement of the transmission and forward scattering or the transmission and remission of a liquid sample. Further described herein is a method for a virtually simultaneous measurement of transmission and/or forward scattering and/or remission and for a simultaneous measurement of the transmission and forward scattering or the transmission and remission of a liquid sample using a sensor according to the invention. Further described herein is a method for using the sensor according to the invention in order to determine the color properties of painting agents such as lacquers, dyes, pastes, and pigments or dilutions thereof.

Described herein is a sensor for a virtually simultaneous measurement of transmission and/or forward scattering and/or remission and for a simultaneous measurement of the transmission and forward scattering or the transmission and remission of a liquid sample. Further described herein is a method for a virtually simultaneous measurement of transmission and/or forward scattering and/or remission and for a simultaneous measurement of the transmission and forward scattering or the transmission and remission of a liquid sample using a sensor according to the invention. Further described herein is a method for using the sensor according to the invention in order to determine the color properties of painting agents such as lacquers, dyes, pastes, and pigments or dilutions thereof.

Disclosed herein are a method of screening coating material compositions for development of new coating formulations in the automotive field, the method making use of measuring, selecting and improving at least one property of a coating material composition or of a wet coating film obtained therefrom, and a method for investigating the influence of certain constituents of coating material compositions on their properties or on the properties of resulting wet coating films obtained therefrom.

Disclosed herein are a method of screening coating material compositions for development of new coating formulations in the automotive field, the method making use of measuring, selecting and improving at least one property of a coating material composition or of a wet coating film obtained therefrom, and a method for investigating the influence of certain constituents of coating material compositions on their properties or on the properties of resulting wet coating films obtained therefrom.

Disclosed herein is a computer-implemented method for a color matching process where an offset is determined that is relieved of an application process bias. Further disclosed herein is a respective system.

Disclosed herein is a computer-implemented method for a color matching process where an offset is determined that is relieved of an application process bias. Further disclosed herein is a respective system.

A method and apparatus for detecting a pulsed THz beam includes emitting, by THz emitter, pulsed THz radiation of outgoing pulse shape for interacting with target body; detecting, by THz detector, incoming THz radiation comprising THz pulses, and outputting, by THz detector, a raw detector data of pulse shapes of incoming THz pulses; and determining, by pulse shape reconstruction module, a reconstructed incoming pulse shape based on the raw detector data, measuring, by sensor, a time-of-flight quantity (d) affecting the time of flight of the THz radiation; and adjusting operation of at least one of THz emitter, THz detector and pulse shape reconstruction module using the time-of-flight quantity (d), for correcting for variations in time of flight of the THz radiation.

A method and apparatus for detecting a pulsed THz beam includes emitting, by THz emitter, pulsed THz radiation of outgoing pulse shape for interacting with target body; detecting, by THz detector, incoming THz radiation comprising THz pulses, and outputting, by THz detector, a raw detector data of pulse shapes of incoming THz pulses; and determining, by pulse shape reconstruction module, a reconstructed incoming pulse shape based on the raw detector data, measuring, by sensor, a time-of-flight quantity (d) affecting the time of flight of the THz radiation; and adjusting operation of at least one of THz emitter, THz detector and pulse shape reconstruction module using the time-of-flight quantity (d), for correcting for variations in time of flight of the THz radiation.

A method includes obtaining a first set of analysis values using a first analysis method, obtaining a second set of analysis values using the first analysis method, a first set of arc-tangents calculation step of obtaining a set of arc-tangents .sub.1n, performing a principal component analysis of the set of arc-tangents .sub.1n to obtain a principal component score comp.1, obtaining a third set of analysis values using a second analysis method, obtaining a fourth set of analysis values using the second analysis method, a second set of arc-tangents calculation step of obtaining a set of arc-tangents .sub.2n, performing principal component analysis on the set of arc-tangents .sub.2n to obtain a principal component score comp.2, and a classification step of classifying the sample of material based on the principal component score comp.1 and the principal component score comp.2.