System, computing device, and method for extraction of optical properties of turbid medium by using diffuse reflectometry

The invention claimed is: 1. A system for extraction of optical properties of a turbid medium by using diffuse reflectometry, the system comprising: at least one light source configured to provide radiation to the turbid medium in a radiation input area of the at least one light source; an optical receiver configured to receive radiation, passed through the turbid medium, in a radiation receiving area of the optical receiver, and obtain a distribution of radiation intensity, wherein the optical receiver comprises an array of liquid crystal (LC) cells, an array of microlenses, and an array of photodetectors which are aligned so that each LC cell from the array of LC cells corresponds to a corresponding microlens from the array of microlenses and to a corresponding photodetector from the array of photodetectors; at least one separator configured to separate the radiation input area of the at least one light source from the radiation receiving area of the optical receiver, and prevent radiation, partially reflected from a surface of the turbid medium in the radiation input area of the at least one light source, from entering the radiation receiving area of the optical receiver; and at least one processor configured to: control the optical receiver, while the radiation is provided to the turbid medium in the radiation input area of the at least one light source, to sequentially open each LC cell from the array of LC cells, and simultaneously receive radiation, passed through the sequentially opened LC cells and corresponding microlenses, by corresponding photodetectors from the array of photodetectors to obtain the distribution of radiation intensity; and extract the optical properties of the turbid medium based on the distribution of radiation intensity. 2. The system of claim 1 , wherein the array of LC cells, the array of microlenses, and the array of photodetectors are aligned with each other in an order corresponding to respective positions of the array of LC cells, the array of microlenses, and the array of photodetectors with respect to the turbid medium. 3. The system of claim 1 , wherein the array of LC cells comprises two or more LC cells arranged in at least one row, wherein the array of microlenses comprises two or more microlens arranged in at least one row, and wherein the array of photodetectors comprises two or more photodetectors arranged in at least one row. 4. The system of claim 3 , wherein the optical receiver is positioned relative to the at least one light source and the at least one separator so that a source-detector separation (SDS) distance is increased between the at least one light source and each subsequent photodetector in the at least one row of photodetectors, and wherein the at least one processor is configured to control the optical receiver to sequentially open each LC cell from the array of LC cells starting from an LC cell corresponding to a photodetector having the smallest SDS distance, and continue until an LC cell corresponding to a photodetector having the largest SDS distance is opened. 5. The system of claim 1 , wherein to extract the optical properties of the turbid medium, the at least one processor is configured to compare measured radiation intensity values, from the radiation intensity distribution obtained for the turbid medium, with a corresponding set of possible radiation intensity values fora given type of turbid medium from a plurality of sets of possible values of radiation intensity, previously simulated by the Monte Carlo method for various optical properties of turbid media of various types, and find a subset of radiation intensity values that minimizes an error E: E = 1 S ⁢ ∑ i ⁢ [ R i , meas - R i , model R i , meas ] 2 wherein S is a number of photodetectors, wherein i is a photodetector number, wherein R i,meas is a measured value of a radiation intensity for a photodetector i, wherein R i,model is a simulated value of the radiation intensity for the photodetector i, wherein the subset of values that minimizes the error E indicates specific optical properties of the turbid medium, and wherein the specific optical properties are an absorption coefficient and a scattering coefficient of the turbid medium. 6. The system of claim 1 , wherein the array of microlenses is an array of LC microlenses configured to change a focal length based on an applied control voltage of the at least one processor. 7. The system of claim 1 , further comprising: a mirror-lens system provided on a side of the at least one separator corresponding to the at least one light source, and configured to form a parallel or converging light beam incident on the turbid medium surface in a normal or oblique direction, using one or more lenses and one or more mirrors or using one or more lenses or one or more mirrors. 8. The system of claim 1 , wherein the optical receiver is mounted in a frame configured to move along the surface of the turbid medium to allow radiation to be received by the optical receiver with different SDS distances. 9. The system of claim 1 , wherein the optical receiver further comprises an additional array of microlenses aligned with the array of LC cells, the array of microlenses, and the array of photodetectors, and wherein one of the additional array of microlenses and the array of microlenses mounted in the frame is configured to substantially perpendicular to the surface of the turbid medium relative to a stationary other one of the additional array of microlenses and the array of microlenses to vary a resolution provided by the optical receiver. 10. The system of claim 1 , further comprising: optical fiber coupled to the at least one light source, and configured to transmit radiation from the at least one light source to the turbid medium in the radiation input area of the at least one light source. 11. The system of claim 10 , further comprising: a reference channel configured to divert a part of the radiation emitted by the at least one light source to a reference receiver configured to measure a change in power of the at least one light source based on an intensity of the diverted part of the radiation, and report the measured change in power to the at least one processor to account for a change in extraction of the optical proper