Title :
Characterization of arbitrary femtosecond pulses using frequency-resolved optical gating
Author :
Kane, Daniel J. ; Trebino, Rick
Author_Institution :
Southwest Sciences Inc., Sante Fe, NM, USA
fDate :
2/1/1993 12:00:00 AM
Abstract :
The frequency-resolved optical gating (FROG) technique for characterizing and displaying arbitrary femtosecond pulses is presented. The method is simple, general, broadband, and does not require a reference pulse. Using virtually any instantaneous nonlinear-optical effect, FROG involves measuring the spectrum of the signal pulse as a function of the delay between two input pulses. The resulting trace of intensity versus frequency and delay is related to the pulse´s spectrogram a visually intuitive transform containing time and frequency information. It is proven using phase retrieval concepts that the FROG trace yields the full intensity I(t) and phase φ( t) of an arbitrary ultrashort pulse with no physically significant ambiguities. FROG appears to have temporal resolution limited only by the response of the nonlinear medium. The method is demonstrated by using self-diffraction through the electronic Kerr effect in BK-7 glass and 620-nm, linearly chirped, ~200-fs pulses of a few microjoules
Keywords :
high-speed optical techniques; light diffraction; optical Kerr effect; spectroscopy; 200 fs; 620 nm; BK-7 glass; FROG trace; arbitrary femtosecond pulses; broadband; electronic Kerr effect; frequency information; frequency-resolved optical gating; full intensity; instantaneous nonlinear-optical effect; linearly chirped; nonlinear medium; polarisation spectroscopy; pulse phase; self-diffraction; signal pulse spectrum measurement; spectral analysis; spectrogram; temporal resolution; time information; transform; ultrashort pulse; Delay effects; Frequency; Glass; Kerr effect; Nonlinear optics; Optical pulses; Pulse measurements; Spectrogram; Ultrafast electronics; Ultrafast optics;
Journal_Title :
Quantum Electronics, IEEE Journal of
