System and method for the volumetric and isotopic identification of radiation distribution in radioactive surroundings

The invention claimed is: 1. A system for the volumetric and isotopic identification of the spatial distribution of ionizing radiation from at least one point or extensive radioactive source in radioactive surroundings wherein the system comprises: a gamma radiation detector, for generating an electrical signal proportional to the energy of the ionizing radiation, and which comprises collimation mechanisms intended to obtain directional information from the radioactive surroundings, and an optical transducer linked to the gamma radiation detector for capturing images of the radioactive surroundings, wherein the gamma radiation detector is joined to the optical transducer, the optical transducer is a depth or contour camera, which provides projected distances, and the system comprises a control unit which in turn comprises: a microprocessor, and a memory linked to the microprocessor, and which comprises: positioning instructions for: defining an initial image of the radioactive surroundings captured by the optical transducer, detecting at least one visual reference in the initial image, wherein the visual reference is an object placed within the radioactive surroundings and within the field of the depth or contour camera in the initial position thereof; determining the initial orientation of the gamma radiation detector with respect to said visual reference, detecting the absolute position of the system with respect to the visual reference of the initial image in a series of locations, starting from subsequent images after the initial image, and for determining the orientation of the gamma radiation detector for each location within the radioactive surroundings, and measurement instructions for: performing measurements of the ionizing radiation, by means of the gamma radiation detector, in each location of the system within the radioactive surroundings, relating these measurements to the absolute position obtained by means of the positioning instructions, establishing the spatial distribution thereof in the radioactive surroundings forming a three-dimensional matrix with the shape of sub-volumes wherein each sub-volume region comprises a value proportional to the intensity of the radiation thereof, and characterizing the ionizing radiation according to the value of the electrical signal produced by the transducer according to the photopeaks in order to determine the isotope composition thereof. 2. The system of claim 1 , wherein the collimation mechanisms comprise a structure with segmenters for detecting the direction of the ionizing radiation from the radioactive source in each location of the system. 3. The system of claim 1 , wherein the control unit comprises detection instructions in the memory comprising collimation techniques such as Compton techniques for detecting the direction of the ionizing radiation from the radioactive source in each location of the system. 4. The system of claim 1 , wherein the control unit memory comprises first sub-instructions which determine the sub-volumes: X,Y,Z=Dx·i+Xo,Dy·j+Yo,Dz·k+Zo Wherein: X, Y, Z: are the spatial coordinates of each sub-volume (cm), called LOC_X. i, j, k: are integers which identify the position of the voxel Dx, Dy, Dz: are integer values which represent the distance between the spatial coordinates between one voxel and the next. Xo, Yo, Zo: are spatial coordinates, the initial ones of the voxel (cm). 5. The system of claim 4 , wherein the control unit memory comprises second sub-instructions in the measurement instructions which measure the radiation for each sub-volume according to: E=I ·CAL_ E+Eo Wherein: E is the energy factor (Ke), I is the value of the signal measured in the detector (V), CAL_E is the scale factor which relates the signal from the detector to the energy (Ke/V), Eo is the value of the energy when the signal from the detector is 0 (Ke). 6. The system of claim 5 , wherein the control unit memory comprises third sub-instructions in the measurement instructions which relate the sub-volumes to the energy factor in order to obtain the radioactive intensity factor (FI) of each sub-volume, by means of the following equation: FI=E (LOC_ X ,POSE_ D ( t ))· E ((POSE_ D ( t )−LOC_ X ) 2 )·EFF_ C ( E )· FC Wherein: E(LOC_X, POSE_D(t)) is the known efficiency factor of the gamma detector and which, in this case, depends on the orientation of the gamma radiation detector, and on the construction thereof, E((POSE_D(t)−LOC_X) 2 ) is the efficiency factor relative to the distance which relates the relative distance between the position of the radioactive source to each sub-volume of the measurement, EFF_C(E) is the factor which determines the efficiency of the gamma radiation detector in obtaining a signal for each photopeak energy, and FC are additional factors referring to the gamma detector obtained by means of calibration. 7. A method for the isotopic identification and characterization of the spatial distribution of ionizing radiation from a radioactive point, or extensive, source or sources in radioactive surroundings, which uses the system of claim 1 , wherein it comprises the following steps: a) determining an initial location of the system in the radioactive surroundings, b) establishing a measurement region within the field of vision of the depth or contour camera in the radioactive surroundings identifying at least one visual reference, which is an object placed within the radioactive surroundings and within the field of the depth or contour camera in the initial position thereof; c) obtaining, by means of the positioning instructions, an initial image of the measurement region of the radioactive surroundings, by means of the depth or contour camera and obtaining the initial orientation of the gamma radiation detector, d) determining, by means of the positioning instructions, the initial absolute position of the system with respect to the visual reference, e) modifying, at least once, the position of the system and performing the following steps for each series of positions after the initial position: i. taking, by means of the depth or contour camera and the positioning instructions, a series of images succeeding the initial image, ii. performing, by means of the measurement instructions and the gamma radiation detector, radiation measurements in the radioactive surroundings, iii. generating, by means of the control unit, a measurement volume in the image for projecting the radiation measurements by generating sub-volumes, iv. determining the three-dimensional coordinates which determine the sub-volumes and relating them to the measurements of the radioactive surroundings by means of the control unit, v. establishing, by means of the measurement instructions, a value greater than zero for each sub-volume and which in each succession of positions will be increased in each sub-volume wherein radioactive intensity is detected and will be decreased in each sub-volume wherein radioactive intensity is not detected, and vi. characterizing the ionizing radiation according to the value of the electrical signal produced by the transducer according to the photopeaks in order to determine the isotope composition thereof. 8. The method of claim 7 , wherein the control unit memory comprises first sub-instructions which determine the sub-volumes: X,Y,Z=Dx·i+Xo,Dy·j+Yo,Dz·k+Zo Wherein: X, Y, Z: are the spatial coordinates of each sub-volume (cm), called LOC_X. i, j, k: are integers which identify the position of the voxel Dx, Dy, Dz: are integer values which represent the distance between the spatial coordinates between one voxel and the next. Xo, Yo, Zo: are spatial coordinates, the initial one