Methods and systems for coherence imaging in obtaining ultrasound images

The invention claimed is: 1. An apparatus, comprising: a handheld ultrasound probe wirelessly operatively couplable to a smartphone or tablet, the handheld ultrasound probe containing: an ultrasonic transducer array configured to selectively transmit ultrasound signals at any frequency from 1 MHz-12 MHz associated with a plurality of transducer elements and receive ultrasound signals reflected through a target tissue; one or more processing devices configured to, for a point in the target tissue: process a plurality of portions of received signals the point in the target tissue, wherein each of the plurality of portions is associated with grouped into a respective one of a plurality of sub-apertures of the transducer array, wherein the processing comprises: determining a respective coherent sum over each of the plurality of portions of the received signals for each sub-aperture; performing a processing operation over the respective coherent sum to obtain respective resulting data for each sub-aperture; normalizing the respective resulting data for a sub-aperture of the plurality of sub-apertures by an incoherent sum of the received ultrasound signals associated with the sub-aperture; and summing the normalized resulting data for the plurality of sub-apertures for imaging the target tissue. 2. The apparatus of claim 1 , wherein the received ultrasound signals associated with the plurality of transducer elements are each delayed by a respective delay time. 3. The apparatus of claim 1 , wherein the processing operation comprises at least in part a square operation or a magnitude square operation. 4. The apparatus of claim 1 , wherein at least a first sub-aperture of the plurality of sub-apertures is overlapped with a second sub-aperture of the plurality of sub-apertures. 5. The apparatus of claim 4 , wherein the plurality of sub-apertures form a full aperture and a size of each of the first sub-aperture and the second sub-aperture is in a range of 50%-80% of a size of the full aperture. 6. The apparatus of claim 1 , wherein the one or more processing devices are formed in an FPGA or an ASIC. 7. The apparatus of claim 1 , wherein the one or more processing devices are configured to determine output data for imaging the target tissue at an additional point by: processing a plurality of portions of additional ultrasound signals associated with the additional point in the target tissue, wherein each of the plurality of portions of additional ultrasound signals is associated with a respective one of the plurality of sub-apertures of the transducer array, and wherein the processing comprises: determining a respective coherent sum over each of the plurality of portions of the additional signals associated with the additional point in the target tissue; and performing the processing operation over the respective coherent sum to obtain respective resulting data for each of the plurality of portions of the additional ultrasound signals; and determining output data for imaging the target tissue at the additional point by summing the resulting data for the plurality of portions of the additional signals. 8. The apparatus of claim 1 , wherein the handheld ultrasound probe is configured to perform cardiac ultrasound imaging and wherein the ultrasonic transducer array is configured to selectively transmit ultrasound signals at frequencies between 1 MHz and 5 MHz. 9. A method of processing ultrasound signals received by an ultrasonic transducer array for imaging a target tissue, the method comprising, for a point in the target tissue: processing a plurality of portions of ultrasound signals associated with the point in the target tissue, wherein each of the plurality of portions is grouped into to a respective one of a plurality of sub-apertures of the transducer array, wherein the received ultrasound signals are each delayed by a respective delay time, and wherein the processing comprises: determining a respective coherent sum over each of the plurality of portions of the ultrasound signals for each sub-aperture; performing a processing operation over the respective coherent sum to obtain respective resulting data for each sub-aperture; and normalizing the respective resulting data for a sub-aperture of the plurality of sub-apertures by an incoherent sum of the received ultrasound signals associated with the sub-aperture; and determining output data for imaging the target tissue at the point by summing the normalized resulting data for the plurality of sub-apertures. 10. The method of claim 9 , wherein the processing operation comprises at least in part a square operation or a magnitude square operation. 11. The method of claim 9 , wherein at least a first sub-aperture of the plurality of sub-apertures is overlapped with a second sub-aperture of the plurality of sub-apertures. 12. The method of claim 11 , wherein the plurality of sub-apertures form a full aperture and a size of each of the first sub-aperture and the second sub-aperture is in a range of 50%-80% of a size of the full aperture. 13. The method of claim 9 , further comprising, for an additional point in the target tissue: processing a plurality of portions of additional ultrasound signals associated with the additional point in the target tissue, wherein each of the plurality of portions corresponds to a respective one of the plurality of sub-apertures of the transducer array, wherein the additional ultrasound signals are each delayed by a respective delay time, and wherein the processing comprises: determining a respective coherent sum over each of the plurality of portions of the additional ultrasound signals; and performing a processing operation over the respective coherent sum to obtain respective resulting data for each sub-aperture; and determining output data for imaging the target tissue at the additional point by summing the resulting data for the plurality of sub-apertures.