Device for optically measuring doses of radiation absorbed by a gel dosimeter by means of polarized light

The invention claimed is: 1. A device ( 2 ) for measuring at least one dose of radiation absorbed by a gel dosimeter ( 4 ), comprising: a light source ( 6 ) emitting a light beam ( 8 ) whose wavelength is modifiable over time; a support ( 10 ) for positioning a gel dosimeter ( 4 ) in the light beam ( 8 ) emitted by the light source ( 6 ); an optical detector ( 14 ) of the light beam ( 8 ), positioned so that its detection axis ( 18 ) forms a scattering angle (α) with the axis of the light beam ( 8 ) at the support ( 10 ); wherein the measurement device ( 2 ) comprises: a means ( 22 ) for polarizing the light beam ( 8 ) according to at least two distinct polarization angles, the polarization means ( 22 ) being positioned between the light source ( 6 ) and the optical detector ( 14 ); and a unit ( 28 ) for measuring the value of the light beam ( 8 ) intensity measured by the optical detector ( 14 ); and a unit ( 30 ) for calculating the value of a ratio of intensities of the light beam ( 8 ), measured by the optical detector ( 14 ), for two distinct and successive polarization angles of the light beam ( 8 ) selected by the polarization means ( 22 ) and/or for two distinct and successive wavelengths of the light beam ( 8 ), the calculation unit ( 30 ) being configured to associate, with at least one value of the intensity ratio calculated by the calculation unit ( 30 ), a value of dose of radiation absorbed by a gel dosimeter ( 4 ). 2. The measurement device ( 2 ) according to claim 1 , wherein the scattering angle value (α) is comprised between 10° and 350°. 3. The measurement device ( 2 ) according to claim 2 , wherein the calculation unit ( 30 ) comprises a memory unit ( 32 ) in which is memorized a look-up table between at least one value of an intensity ratio calculated by the measurement unit ( 28 ) and one value of dose of radiation absorbed by a gel dosimeter ( 4 ). 4. The measurement device ( 2 ) according to claim 1 , wherein the calculation unit ( 30 ) comprises a memory unit ( 32 ) in which is memorized a look-up table between at least one value of an intensity ratio calculated by the measurement unit ( 28 ) and one value of dose of radiation absorbed by a gel dosimeter ( 4 ). 5. The measurement device ( 2 ) according to claim 1 , wherein the light source ( 6 ) comprises a means ( 7 ) for selecting at least two distinct wavelength ranges observable by the optical detector ( 14 ). 6. The measurement device ( 2 ) according to claim 1 , wherein the polarization means ( 22 ) comprises a first polarizer ( 24 ) positioned between the light source ( 6 ) and the support ( 10 ), and a second polarizer ( 26 ) positioned between the support ( 10 ) and the optical detector ( 14 ). 7. The measurement device ( 2 ) according to claim 1 , wherein the polarization means ( 22 ) comprises a first polarizer ( 24 ) and a second polarizer ( 26 ), both positioned between the light source ( 6 ) and the support ( 10 ), or between the support ( 10 ) and the optical detector ( 14 ). 8. The measurement device ( 2 ) according to claim 1 , wherein it comprises a scattering means positioned between the light source ( 6 ) and the support ( 10 ), for uniformizing the polarization of the light beam ( 8 ) emitted by the light source ( 6 ). 9. The measurement device ( 2 ) according to claim 1 , wherein it comprises means for moving the support ( 10 ) with respect to the detection axis ( 18 ) of the detector. 10. The measurement device ( 2 ) according to claim 1 , wherein it comprises means for pivoting the optical detector ( 14 ) with respect to the support ( 10 ), so as to modify the scattering angle value (α). 11. The measurement device ( 2 ) according to claim 1 , wherein it comprises two oscillating mirrors, linearly or angularly oscillating at frequencies higher than the inverse of the measurement time of the measurement unit ( 28 ), positioned on the light beam path between the light source ( 6 ) and the optical detector ( 14 ). 12. A method for measuring at least one dose of radiation absorbed by a gel dosimeter ( 4 ) using a measurement device ( 2 ) according to claim 1 , implementing the following steps: positioning a gel dosimeter ( 4 ) on the support ( 10 ) so that the light beam ( 8 ) emitted by the light source ( 6 ) illuminates the gel dosimeter ( 4 ) at a first wavelength; directing the optical detector ( 14 ) so that its detection axis ( 18 ) passes through the gel dosimeter ( 4 ) and forms a scattering angle (α) with the light beam ( 8 ); determining, by the measurement unit ( 28 ), the light intensity observed by the optical detector ( 14 ); modifying the angle of polarization of the light beam ( 8 ) using the polarizing means ( 22 ) and/or modifying the wavelength of the light beam ( 8 ); determining again, by the measurement unit ( 28 ), the light intensity observed by the optical detector ( 14 ); estimating, by the calculation unit ( 30 ), the value of a ratio between the two intensities measured; identifying in a look-up table, by the calculation unit ( 30 ), a dose of radiation absorbed by a gel dosimeter ( 4 ) from the value of the intensity ratio estimated by the calculation unit ( 30 ). 13. The measurement method according to claim 12 , wherein the preceding steps are reiterated for a gel dosimeter ( 4 ) irradiated at different known doses, in order to establish a look-up table. 14. The measurement method according to claim 12 using a measurement device ( 2 ) according to one of claims 4 to 10 , wherein the scattering angle (α) of the detector is modified as a function of the light beam ( 8 ) wavelength range selected by a selection means ( 7 ). 15. The measurement method according to claim 12 , wherein the support ( 10 ) is moved between each series of measurements in order to obtain the doses of radiation absorbed by the gel dosimeter ( 4 ) in a two-dimensional plane. 16. The measurement method according to claim 12 , wherein the support ( 10 ) is moved between each series of measurements in order to obtain the doses of radiation absorbed by the gel dosimeter ( 4 ) in a three-dimensional space. 17. The method for measuring at least one dose of radiation absorbed by a gel dosimeter ( 4 ) using a measurement device ( 2 ) according to claim 1 , implementing the following steps: a) positioning a gel dosimeter ( 4 ) on the support ( 10 ) so that the light beam ( 8 ) emitted by the light source ( 6 ) illuminates the gel dosimeter ( 4 ) at a first wavelength; b) directing the optical detector ( 4 ) so that its detection axis ( 18 ) passes through the gel dosimeter ( 4 ) and forms a scattering angle (a) with the light beam ( 8 ); c) determining, by the measurement unit ( 28 ), the light intensity observed by the optical detector ( 14 ); d) modifying the angle of polarization of the light beam ( 8 ) using the polarization means ( 22 ); e) determining again, by the measurement unit ( 28 ), the light intensity observed by the optical detector ( 14 ); f) estimating, by the calculation unit ( 30 ), the value of a ratio between the two measured intensities, called polarization rate; g) modifying the value of the wavelength of the light beam ( 8 ) emitted by the light source and/or modifying the scattering angle (a); h) reproducing steps c) to g) several times in a row in order to obtain polarization rates for different couples of wavelength and scattering angle values; i) modelling, by the calculation unit ( 30 ), a theoretical polarization rate as a function of the size of the scattering structures present in the gel dosimeter; j) identifying, by the calcula