Automated cell identification using shearing interferometry

The invention claimed is: 1. A method for automated classification of a micro-object, the method comprising: obtaining digital holographic data from a sample imaged in a common path shearing digital holographic microscope, the common path shearing digital holographic microscope including a laser source, a microscopic objective lens, a glass plate and an imaging device, the digital holographic data including a video hologram of at least one micro-object in the sample recorded over a pre-determined time period; generating a plurality of 3D reconstructed height profiles of a micro-object in the video hologram, the plurality of 3D reconstructed height profiles obtained from a corresponding plurality of hologram frames spanning the pre-determined time period; generating a 2D mean map of the 3D reconstructed height profiles of the micro-object, the 2D mean map generated by determining the mean height for each pixel of the plurality of 3D reconstructed height profiles over the pre-determined time period; generating a 2D standard deviation map of the 3D reconstructed height profiles of the micro-object, the 2D standard deviation map generated by determining the standard deviation in height for each pixel of the plurality of 3D reconstructed height profiles over the pre-determined time period; determining the standard deviation of the 2D mean map to generate a value for a first feature for the micro-object in the video hologram; determining the standard deviation of the 2D standard deviation map to generate a value for a second feature for the micro-object in the video hologram; determining optical flow vectors between 3D reconstructed height profiles corresponding to successive frames for each 3D reconstructed height profile after the first 3D reconstructed height profile; determining the mean of the magnitude of the optical flow vectors over the pre-determined time period; determining the standard deviation of the mean of the magnitude of the optical flow vectors of the plurality of 3D reconstructed height profiles over the pre-determined time period to generate a value for a third feature for the micro-object in the video hologram; determining whether the micro-object belongs to a particular type of micro-object by applying a pre-trained classifier to the value of the first feature, the value of the second feature and value of the third feature; and based on the determination, saving an indication of whether the micro-object belongs to a particular type of micro-object. 2. The method of claim 1 , wherein the pre-trained classifier is a random forest classifier. 3. The method of claim 1 , wherein the particular type of micro-object is a healthy red blood cell. 4. The method of claim 1 , wherein the particular type of micro-object is a sickled red blood cell. 5. The method of claim 1 , wherein the particular type of micro-object is a biological cell or a microorganism. 6. The method of claim 1 , wherein the sample includes blood. 7. The method of claim 1 , wherein the plurality of hologram frames of the video hologram of the at least one micro-object in the sample are recorded at a rate of between 20 and 40 frames per second. 8. The method of claim 1 , wherein the plurality of hologram frames comprise between 100 and 900 frames. 9. The method of claim 8 , wherein the plurality of hologram frames comprise between 400 and 700 frames.