Chirped pulse amplification laser system

The invention claimed is: 1. A method of generating transform limited sub-nanosecond (sub-ns) pulses at the output of a chirped pulse amplification (CPA) laser system which is configured with a laser source emitting nearly transform limited (TL) sub-nanosecond (sub-ns) pulses along a path, a first Bragg grating ( 13 G) stretching TL pulses, and a second BG recompressing the chirped pulses, the method comprising: calibrating at least one of the first or second BGs, the calibrated BG having a plurality of spaced segments, wherein the calibration includes: determining segment to frequency correspondence across the one BG, and determining temperature to spectral phase dependence or voltage to spectra phase dependence across the one BG; calculating a phase correction for each segment across a spectrum of each compressed pulse, thereby obtaining a desired voltage or temperature profile; and applying the desired temperature or voltage profile to the one BG, thereby selectively actuating the segments to tune the one BG so as to output the near transform limited compressed sub-ns pulses. 2. The method of claim 1 , wherein the calibration of the tunable one BG is performed using a modulation phase-shift method to determine both the segment to frequency and temperature to spectral phase or voltage to spectral phase dependencies. 3. The method of claim 2 , wherein the temperature or voltage to spectral phase dependence varies from segment to segment or is uniform for all segments. 4. The method of one of claim 1 , wherein the phase correction calculation utilizes multiphoton intrapulse interference phase scan (MIIPS), Chirp Reversal Technique (CRT) or d-scan. 5. A chirped pulse amplification (CPA) pulse laser system comprising: a mode-locked laser operative to output near transform limited (TL) sub-nanosecond (sub-ns) pukes having a spectral bandwidth and propagating along a path; a first Bragg gratings (BG) spaced downstream from the mode-locked laser and operative to stretch the TL sub-ns pulses coupled into the first BG; a second BG spaced downstream from the first BG and operative to recompress the stretched pulses, wherein one of the first or second BGs is configured with a plurality of tunable segments corresponding to respective wavelengths of the bandwidth; an array of actuators coupled to respective segments; and a pulse shaping unit operative to determine a deviation of the spectral phase for each wavelength of the bandwidth of the compressed pulse from that of the IL sub-ns pulse, and to output corrective signals coupled into the array of actuators which selectively and controllably induce spectral phase changes on respective segments of the one BG so as to adjust the spectral phase to that of the TL sub-ns pulse. 6. The CPA laser system of claim 5 , wherein the first and second BGs each are a chirped fiber Bragg grating (CFBG) or volume Bragg grating (VBG). 7. The CPA laser system of claim 5 , wherein the one BG is calibrated to have a predetermined frequency to segment dependence across the compressed pulse and spectral phase to temperature or spectral phase to voltage dependence. 8. The CPA laser system of one of claim 5 , wherein the pulse shaping unit includes a measurement unit based on a CRT scheme, or MIIPS scheme or d-scan scheme. 9. The CPA laser system of claim 5 , wherein the actuators each include a heating element or piezoelectric element. 10. The CPA laser system of claim 5 , wherein the one BG is configured with a base supporting the array of actuators, and plurality of spaced segments each of which is coupled to the actuator. 11. The CPA laser system of claim 5 further comprising a housing encasing the mode locked laser, the first and second BG and the pulse shaping unit. 12. The CPA laser system of claim 5 , wherein the mode-locked laser has a master oscillator power amplifier architecture with one or more amplifying stages flanked by the first and second BGs, the power amplifier being selected from the group consisting of fiber amplifiers, and crystal-host rare earth ion-doped amplifiers. 13. The CPA laser system of claim 5 , wherein the one BG further includes a plurality of resistors coupled to respective segments. 14. The CPA laser of claim 5 , wherein the one BG is configured with a single central column mounted on the base, a plurality of side segments flanking the base and coupled to the central segment, and a plurality of resilient components extending between adjacent segments. 15. The CPA laser of claim 5 , wherein the one BG further comprising a continuous plate supporting the CFBG or VBG and coupled to respective actuators.