Optical phase measurement method and system

What is claimed is: 1. A measurement system for use in measuring parameters of a patterned sample, the system comprising: a broadband light source; an optical system including an objective lens and configured as an interferometric system; a detection unit; a control unit; and a beam-splitter-and-combiner positioned along an optical path between the objective lens and the patterned sample, wherein the interferometric system defines an illumination channel, and detection channels having a sample arm and a reference arm comprising a reference reflector, wherein the sample arm is not parallel with the reference arm, the detection channels comprise a first detection channel and a second detection channel that share at least the objective lens; and is configured and operable to induce an optical path difference between the sample arm and reference arm, and to combine output of the sample arm and reference arm into the detection channels for propagation of a combined light beam formed by a light beam reflected from said reference reflector and a light beam propagating from the patterned sample, the light beams derived from light originating from the broadband light source, wherein the detection unit comprises an imaging sensor and a spectral sensor, the spectral sensor is configured and operable to detect a first portion of the combined light beam from the first detection channel and generate measurement data indicative of each wavelength of the first portion of the combined light separately, the imaging sensor is configured to detect a second portion of the combined light beam; wherein said control unit is configured and operable to receive the measurement data for determining one or more parameters of a pattern in the patterned sample, and wherein the beam-splitter-and-combiner is configured to: split the light originating from the broadband light source into a probe light beam and a reference light beam, direct the probe light beam along the sample arm towards the patterned sample, and direct the reference light beam along the reference arm towards the reference reflector. 2. The measurement system of claim 1 , wherein said interferometric system comprises polarizers, wherein the polarizers consist of a first polarizer in the illumination channel and outside the collection channels a second polarizer in the detection channels and outside the illumination channel. 3. The measurement system of claim 2 , wherein said interferometric system comprises a driving mechanism, associated with either one or both of said reference reflector and a sample support supporting the patterned sample, and configured and operable to controllably move at least one of said reference reflector and the sample support along an optical axis of the interferometric system, to induce the optical path difference between the sample arm and the reference arm. 4. The measurement system of claim 1 , wherein at least one of said reference reflector and a sample support supporting the patterned sample is oriented with a fixed tilted position with respect to an optical axis of the interferometric system, providing the optical path difference between the sample arm and the reference arm. 5. The measurement system of claim 4 , wherein said reflector is located in a plane parallel to and spaced-apart from a focal plane of an objective lens unit of said interferometric system. 6. The measurement system of claim 4 , wherein said reflector is configured as a retro-reflector assembly. 7. The measurement system of claim 1 , wherein said interferometric system is configured and operable to induce defocusing effect on an illuminating light beam propagating along the reference arm towards said reference reflector, providing the optical path difference between the sample arm and the reference arm. 8. The measurement system of claim 1 , wherein the broadband light source is configured and operable to produce illumination in the form of ultra-short pulses. 9. The measurement system of claim 1 , comprising an additional beam-splitter-and-combiner that is configured to split the combined light beam to the first portion of the combined light beam and to the second portion of the combined light beam. 10. The measurement system of claim 9 , wherein the imaging sensor is a CCD. 11. The measurement system of claim 1 , wherein the reference reflector is a MEMS reference mirror that is movable for controlling at least one of tilt and the optical path difference. 12. The measurement system of claim 11 , wherein the imaging sensor is in communication with the control unit. 13. A method for use in measuring parameters of a patterned sample, the method comprising: directing broadband light through an interferometric optical system, the interferometric optical system including an objective lens and defining an illumination channel and detection channels having a sample arm not parallel to a reference arm comprising a reference reflector; the detection channels comprise a first detection channel and a second detection channel that share at least the objective lens; splitting the broadband light into a probe light beam and a reference light beam, wherein the splitting is performed along an optical path between the objective lens and the patterned sample; directing the probe light beam along the sample arm towards the patterned sample; directing the reference light beam along the reference arm towards the reference reflector; inducing an optical path difference between the sample arm and the reference arm; combining output of the sample arm and reference arm into the detection channel for propagation of a combined light beam formed by a light beam reflected from said reference reflector and a light beam propagating from a patterned sample, the light beams derived from the broadband light; detecting an intensity of every wavelength separately of a first portion of the combined light beam using a spectral sensor and generating measurement data, detecting, by an imaging sensor that differs from the spectral sensor, a second portion of the combined light sensor; and determining from the measurement data one or more parameters of a pattern in the patterned sample. 14. The method of claim 13 , wherein the reference reflector is a MEMS reference mirror, the method further comprising moving the MEMS reference mirror. 15. The method of claim 13 , and further comprising controllably moving, along an optical axis of the interferometric system, at least one of said reference reflector and a sample support supporting the patterned sample, thereby inducing the optical path difference between the sample arm and the reference arm. 16. The method of claim 13 , and further comprising orienting, with a fixed tilted position with respect to an optical axis of the interferometric system, at least one of said reference reflector and a sample support supporting the patterned sample, thereby providing the optical path difference between the sample arm and the reference arm. 17. The method of claim 16 , and further comprising positioning said reflector in a plane parallel to and spaced-apart from a focal plane of an objective lens unit of said interferometric system. 18. The method of claim 16 , and further comprising configuring said reflector as a retro-reflector assembly. 19. The method of claim 13 , and further comprising inducing a defocusing effect on an illuminating light beam propagating along the reference arm towards said reference reflector, thereby providing the optical path difference between the