Method and system for measuring transient time width of ultrashort pulse

What is claimed is: 1. A method for measuring a transient time width of an ultrashort pulse in real time, comprising: performing an interaction of a laser pulse to be measured with a linear chirped pulse in a second-order non-linear medium, to generate a sum-frequency beam, wherein an intensity sag occurs in the chirped pulse after the interaction; performing a time spreading by a time stretching system on the chirped pulse with the intensity sag; detecting the spread chirped pulse with the spread intensity sag by a photoelectric detector, and measuring and recording a time width τ′ of the spread intensity sag by an oscilloscope; and obtaining the transient time width τ of the laser pulse to be measured according to a formula of τ=τ′/M, where M is an amplification coefficient of the time stretching system. 2. The method of claim 1 , wherein performing the time spreading comprises: stretching a pulse width t of the chirped pulse to a large time dimension T with a section of dispersive medium having a group-velocity dispersion of D: T = t ⁢ 1 + ( 4 ⁢ ⁢ ln ⁢ ⁢ 2 ⁢ D t 2 ) 2 , where, M=T/t. 3. The method of claim 1 , wherein the intensity sag is generated due to a part of energy of the chirped pulse transferring to the sum-frequency beam after the interaction, and a time width of the intensity sag has a one-to-one relationship with the laser pulse to be measured. 4. The method of claim 3 , wherein a carrier frequency in an envelope of the linear chirped pulse has a linear distribution under the group-velocity dispersion. 5. The method of claim 3 , wherein the pulse to be measured is generated by a pulse laser having a repetition frequency greater than 10 6 Hz. 6. A system for measuring a transient time width of an ultrashort pulse in real time, comprising a laser, a beam splitter, a time delayer, a first reflecting mirror, a half-wave plate, a second reflecting mirror, a third reflecting mirror, a first coupler, a fiber, a second coupler, a beam combiner, a lens, a sum-frequency crystal, a time stretching system, an photoelectric detector, and an oscilloscope, wherein the laser is configured to generate an ultrashort pulse to be measured; the beam splitter is configured to split the ultrashort pulse into two beams, wherein one beam is configured to pass through the third reflecting mirror, the first coupler, the fiber, and the second coupler in sequence to generate the chirped pulse, and the other beam is configured to pass through the first reflecting mirror, the time delayer, the half-wave plate and the second reflecting mirror in sequence, for enabling the two beams to have consistent polarization and time coincidence, and after passing through the beam combiner, the ultrashort pulse to be measured and the chirped pulse are focused by the lens to the sum-frequency crystal; the sum-frequency crystal is configured to perform an interaction of the ultrashort pulse to be measured with the chirped pulse, to generate a sum-frequency beam, in which an intensity tag occurs in the chirped pulse after the interaction; the time stretching system is configured to perform time spreading on the chirped pulse with the intensity sag; the photoelectric detector is configured to detect the spread chirped pulse with the spread intensity sag; the oscilloscope is configured to measure a time width τ′ of the spread intensity sag, for calculating the transient time width τ of the ultrashort pulse to be measured according to a formula of τ=τ′/M, where M is an amplification coefficient of the time stretching system. 7. The system of claim 6 , wherein the time stretching system is formed by a section of fiber, in which the fiber is configured to provide sufficient dispersion such that a pulse width is spread from femtosecond order to nanosecond order. 8. The system of claim 7 , wherein the dispersion of the fiber is D, the pulse width of the chirped pulse is t, and the pulse width of the spread chirped pulse is T, T = t ⁢ 1 + ( 4 ⁢ ⁢ ln ⁢ ⁢ 2 ⁢ D t 2 ) 2 , where, M=T/t. 9. The system of claim 6 , wherein the intensity sag is generated due to a part of energy of the chirped pulse transferring to the sum-frequency beam after the interaction, and a time width of the intensity sag has a one-to-one relationship with the laser pulse to be measured.