Imaging systems and methods of using the same

The invention claimed is: 1. A shadow optical imaging method comprising: receiving, at a single detector of a lensless optical imaging system, an optical shadow cast thereon by an object that is disposed in immediate proximity to said single detector and that is irradiated with a single diverging monochromatic wavefront of light; acquiring multiple sets of optical data with said single detector over a period of time, each set of optical data representing a respectively-corresponding first image of said optical shadow formed with said wavefront at a respectively-corresponding point in time within said period, wherein spatial positions and orientations of said detector, said object, and said light source remain unchanged during said acquiring; wherein said wavefront has a rate of spatial divergence that remains unchanged in time and an optical axis the spatial orientation of which remains unchanged during said period of time, wherein said first image is characterized by a first spatial resolution; from said multiple sets of optical data, forming a second image of said object with a computer processor, said forming including anisotropic filtering of a set of optical data from said multiple sets to correct geometrical information of each first image, wherein said second image is characterized by second spatial resolution, the second spatial resolution being higher than the first spatial resolution. 2. A method according to claim 1 , wherein said receiving the optical shadow includes receiving said optical shadow cast onto said detector without cessation and interruption in time during said period. 3. A method according to claim 1 , further comprising forming said diverging wavefront of light by spatially-filtering light that has been emitted by an only light source of said system at a pinhole. 4. A method according to claim 1 , wherein each of first images respectively corresponding to said multiple sets of optical data subtends a first field-of-view from an overall field-of-view of the optical shadow cast, and wherein said acquiring includes at least one of (i) increasing a frame-rate of video acquisition of said first images while reducing said first field-of-view and (ii) decreasing said frame-rate while increasing said first field-of-view. 5. A method according to claim 1 , devoid of any spatial repositioning of any element of the lensless optical imaging system. 6. A method according to claim 5 , wherein the acquiring multiple sets of optical data includes acquiring said multiple sets representing, respectively, multiple first images of the stationary optical shadow. 7. A method according to claim 1 , wherein the first image is characterized by the first signal to noise ratio (SNR), the second image is characterized by the second SNR, and the second SNR is higher than the first SNR. 8. A shadow optical imaging system comprising a point light source configured to produce a wavefront of partially coherent light; a sample holder in direct optical communication with said point light source without any optical component in between; and an optical detection system having an optical detector that is disposed immediately adjacently to the sample holder, said optical detection system configured to acquire multiple sets of optical data with said optical detector over a period of time, each set of optical data representing a respectively-corresponding first image of said optical shadow formed with said wavefront at a respectively-corresponding point in time within said period, wherein each of first images represented by said multiple sets of optical data is characterized by a first spatial resolution, and to form, with electronic circuitry of said optical detection system, a second image of said object at least in part by anisotropically filtering of a set of optical data from said multiple sets to correct geometrical information of each first image, wherein said second image is characterized by a second spatial resolution, the second spatial resolution being higher than the first spatial resolution; wherein each and every component of the optical imaging system is spatially fixed and configured to be non-repositionable with respect to any other component of the optical imaging system. 9. A shadow optical imaging system according to claim 8 , wherein said wavefront has (i) a rate of spatial divergence that remains unchanged during said period and (ii) an optical axis a spatial orientation of which remains unchanged during said period. 10. A shadow optical imaging system according to claim 8 , wherein said optical detection system is configured to acquire said multiple sets of optical data by at least one of (i) increasing a frame-rate of video acquisition of said first images while reducing a first field-of-view that each of said first images subtends from an overall optical shadow cast, and (ii) decreasing said frame-rate while increasing said first field-of-view.