Aberration diverse Optical Coherent Tomography (OCT) imaging to suppress optical scattering noise

What is claimed is: 1. A method for optically measuring a target sample based on Optical Coherence Tomography (OCT) imaging, comprising: operating a light source to direct probe light to a location of the target sample to collect returned probe light from the location of the target sample to perform OCT imaging; sequentially superimposing different optical aberration patterns on the wavefront of the probe light directed to the location of the target sample to obtain different OCT imaging outputs of the location of the target sample, respectively, that respectively correspond to the different optical aberration patterns; processing the different OCT imaging outputs that respectively correspond to the different optical aberration patterns to reconstruct different OCT images of the location of the target sample, respectively, where each reconstructed OCT image corresponds to one of the different OCT imaging outputs and includes (1) first OCT image components that are caused by ballistic photons of the probe light with a single-scattering contribution and are in phase and (2) second OCT image components that are caused by multiply scattered photons of the probe light due to multiple scattering in the target sample and exhibit random phase values; and subsequently adding the reconstructed OCT images together to obtain a final reconstructed OCT image based on a first sum of the first OCT image components of the different reconstructed OCT images that are in phase and a second sum of the second OCT image components of the different reconstructed OCT images exhibiting random phase values, thus suppressing a contribution of the second sum caused by multiply scattered photons of the probe light due to multiple scattering in the target sample, wherein the first and second OCT image components include complex valued OCT signals. 2. The method as in claim 1 , wherein: the step of sequentially superimposing different optical aberration patterns on the wavefront of the probe light directed to the target sample is performed by using a rotating lens to produce a varying optical lens astigmatism. 3. The method as in claim 1 , wherein: the step of sequentially superimposing different optical aberration patterns on the wavefront of the probe light directed to the target sample is performed by using an adaptive optical device. 4. The method as in claim 1 , wherein: the step of sequentially superimposing different optical aberration patterns on the wavefront of the probe light directed to the target sample is performed by using a deformable mirror. 5. The method as in claim 1 , wherein: the step of sequentially superimposing different optical aberration patterns on the wavefront of the probe light directed to the target sample is performed by using an adaptive metalens structured to provide electrical control of a focal length, lens astigmatism, and beam scanning. 6. The method as in claim 1 , wherein: the step of sequentially superimposing different optical aberration patterns on the wavefront of the probe light directed to the target sample is performed by using an acoustic deflector. 7. The method as in claim 1 , wherein: the step of sequentially superimposing different optical aberration patterns on the wavefront of the probe light directed to the target sample is performed by using a deformable digital mirror array. 8. The method as in claim 1 , wherein: the OCT imaging is based on spectral or frequency domain OCT. 9. The method as in claim 1 , wherein sequentially superimposing different optical aberration patterns includes rotating lens to produce the different optical aberration patterns. 10. The method as in claim 1 , wherein the step of sequentially superimposing different optical aberration patterns on the wavefront of the probe light directed to the target sample is performed by a multi-stage process, in which large lower order aberration and small higher order aberration can be applied separately. 11. The method as in claim 10 , wherein the multi-stage process is performed by using a combination of a cylindrical lens and a wavefront shaping device including at least one of an adaptive optical device, a deformable mirror, an adaptive metalens, an acoustic deflector, and a deformable digital mirror array. 12. An optical coherent tomography (OCT) device for optically measuring a target sample, comprising: a light source to direct probe light to a location of the target sample to collect returned probe light from the location of the target sample to perform OCT imaging; an optical aberration device placed in an optical path of the returned probe light from the target sample and structured to sequentially superimpose different optical aberration patterns on the wavefront of the probe light directed to the location of the target sample to obtain different OCT imaging outputs of the location of the target sample, respectively, that respectively correspond to the different optical aberration patterns; an OCT processor coupled to the optical aberration device to receive the different OCT imaging outputs that respectively correspond to the different optical aberration patterns and to process the received different OCT imaging outputs to reconstruct different OCT images of the location of the target sample, respectively, where each reconstructed OCT image corresponds to one of the different OCT imaging outputs and includes (1) first OCT image components that are caused by ballistic photons of the probe light with a single-scattering contribution and are in phase and (2) second OCT image components that are caused by scattered photons of the probe light due to scattering in the target sample and exhibit random phase values, wherein the OCT processor is further configured to add the reconstructed OCT images together to obtain a final reconstructed OCT image based on a first sum of the first OCT image components of the different reconstructed OCT images that are in phase and a second sum of the second OCT image components of the different reconstructed OCT images exhibiting random phase values, thus suppressing a contribution of the second sum caused by scattered photons of the probe light due to scattering in the target sample, wherein the first and second OCT image components include complex valued OCT signals. 13. The OCT device as in claim 12 , wherein: the optical aberration device includes a rotating lens to produce a varying optical lens astigmatism that in turn produces the different optical aberration patterns. 14. The OCT device as in claim 12 , wherein: the optical aberration device includes an adaptive optical device. 15. The OCT device as in claim 12 , wherein: the optical aberration device includes a deformable mirror. 16. The OCT device as in claim 12 , wherein: the optical aberration device includes an adaptive metalens structured to provide electrical control of a focal length, lens astigmatism, and beam scanning. 17. The OCT device as in claim 12 , wherein: the optical aberration device includes an acoustic deflector. 18. The OCT device as in claim 12 , wherein: the optical aberration device includes a deformable digital mirror array. 19. The OCT device as in claim 12 , wherein: the OCT device is structured based on spectral or frequency domain OCT. 20. The OCT device as in claim 12 , wherein: the optical aberration device includes multiple stages of aberration control including one stage to control and induce aberrations of large magnitude and another stage to separately control and i