Method for estimating a dose rate on the basis of a spectral image

The invention claimed is: 1. A method for estimating a first dose rate generated at a gamma camera, based on measurements taken by the gamma camera, wherein the estimated first dose rate originates from irradiating sources located in an observation field, the irradiating sources emitting ionizing electromagnetic radiation, the observation field is discretized into a mesh, the gamma camera comprises a plurality of pixels, each pixel being configured to detect the ionizing electromagnetic radiation, during an acquisition time, and to form a pixel corresponding energy spectrum therefrom such that the pixels allow a position of the irradiating sources in the observation field to be obtained, the method comprising: with the gamma camera at a predetermined position, acquiring the pixel corresponding energy spectrum at each pixel of the plurality of pixels of the gamma camera; selecting an emission spectrum, the emission spectrum having one or more energy bands; selecting points of the mesh of the observation field; based on the pixel corresponding energy spectrum acquired by each pixel of the plurality of pixels of the gamma camera, estimating a spatial distribution of an activity, corresponding to the selected emission spectrum for the selected points of the mesh; for each energy band of the emission spectrum, determining a corresponding conversion function relating a photon flux value to a dose rate value for the energy band; and based on the determined corresponding conversion function for each energy band of the emission spectrum and the estimated spatial distribution of the activity, estimating the first dose rate generated, at the gamma camera, by the selected points of the mesh, wherein the estimating the spatial distribution comprises, in each energy band of the emission spectrum, and for each pixel of the plurality of pixels: determining an estimated photon flux estimated to be detected by the pixel in the energy band, depending on the spatial distribution of the activity of the selected points of the mesh; based on the pixel corresponding energy spectrum acquired at the pixel, determining, in the energy band, a measured photon flux detected by the detector element; and minimizing a discrepancy between the estimated photon flux and the measured photon flux. 2. The method as claimed in claim 1 , wherein: the selecting the emission spectrum comprises selecting an isotope, or a set of isotopes, potentially present in the observation field, the selected emission spectrum corresponding to a first emission spectrum of the isotope or to a second emission spectrum of the set of isotopes; and the estimating the spatial distribution of the activity comprises estimating a first spatial distribution of a first activity corresponding to the isotope or estimating a second spatial distribution of a second activity corresponding to the set of isotopes. 3. The method as claimed in claim 1 , wherein the selected emission spectrum comprises a single energy band. 4. The method as claimed in claim 1 , wherein the determining the spatial distribution comprises determining the spatial distribution using a spatial model associated with each pixel of the plurality of pixels, the spatial model defining a probability that a photon emitted by each point of the mesh is detected by the pixel with which the spatial model is associated. 5. The method as claimed in claim 1 , wherein the spatial distribution of the activity corresponds to a distribution of the activity over an object surface. 6. The method as claimed in claim 1 , wherein the determining the corresponding conversion function comprises estimating the corresponding conversion function by simulation. 7. The method as claimed in claim 1 , wherein the determining the corresponding conversion function comprises estimating the corresponding conversion function by exposing at least one pixel of the plurality of pixels of the gamma camera to a calibration irradiating source, such that a calibration dose rate to which the pixel is exposed is known. 8. The method as claimed in claim 1 , wherein the gamma camera is associated with a rangefinder, and wherein the method further comprises: measuring, with the rangefinder, a distance between the gamma camera and at least one point of the observation field; and using the measured distance and the estimated spatial distribution of the activity, estimating a second dose rate generated, by the estimated spatial distribution of the activity, in a second position different from the predetermined position of the gamma camera. 9. The method as claimed in claim 8 , wherein the estimating the second dose rate in the second position different from the predetermined position of the gamma camera is based on the estimated first dose rate at the gamma camera. 10. The method as claimed in claim 1 , wherein the estimated first dose rate is an equivalent dose rate. 11. The method as claimed in claim 1 , wherein the selecting the points of the mesh comprises selecting all of the points of the mesh of the observation field. 12. A measuring device, comprising: a gamma camera comprising a plurality of pixels, each pixel being configured to detect ionizing electromagnetic radiation, emitted by at least one irradiating source located in an observation field discretized into a mesh, during an acquisition time, and to form a pixel corresponding energy spectrum therefrom such that together the plurality of pixels allow a spatial distribution of each irradiating source in the observation field to be obtained in one energy band or in a plurality of energy bands; and processing circuitry configured to: with the gamma camera at a predetermined position, acquire the pixel corresponding energy spectrum at each pixel of the plurality of pixels of the gamma camera; select an emission spectrum, the emission spectrum having one or more energy bands; select points of the mesh of the observation field; based on the pixel corresponding energy spectrum acquired by each pixel of the plurality of pixels of the gamma camera, estimate a spatial distribution of an activity, corresponding to the selected emission spectrum for the selected points of the mesh; for each energy band of the emission spectrum, determine a corresponding conversion function relating a photon flux value to a dose rate value for the energy band; and based on the determined corresponding conversion function for each energy band of the emission spectrum and the estimated spatial distribution of the activity, estimate a dose rate generated, at the gamma camera, by the selected points.