Pulse Shaping Based on Integrated Waveguide Gratings

Kultavewuti, Pisek

25 July 2012

Temporal pulse shaping based on integrated Bragg gratings is investigated in this work to achieve arbitrary output waveforms. The grating structure is simulated based on the sidewall-etching geometry in an AlGaAs platform. The inverse scattering employin the Gel'fan-Levithan-Marchenko theorem and the layer peeling method provides a tool to determine grating structures from a desired spectral reflection response. Simulations of pulse shaping considered flat-top and triangular pulses as well as one-to-one and one-to-many pulse shaping. The suggested grating profiles revealed a compromise between performance and grating length. The integrated grating, a few hundred microns in length, could generate flat-top pulses with pulse durations as short as 500 fs with rise/fall times of 200 fs; the results are comparable to previous work in free-space optics and fiber optics. The theories and the devised algorithms could serve as a design station for advanced grating devices for, but not restricted to, optical pulse shaping.

Pulse shaping

Integrated optics

Gratings

Ultrafast optics

Picosecond pulses

AlGaAs waveguide

AlGaAs gratings

Flat-top pulse shaping

Rectangular pulse shaping

Coupled-mode theory

Inverse scattering

0544

Pulse Shaping Based on Integrated Waveguide Gratings

Kultavewuti, Pisek

25 July 2012

Temporal pulse shaping based on integrated Bragg gratings is investigated in this work to achieve arbitrary output waveforms. The grating structure is simulated based on the sidewall-etching geometry in an AlGaAs platform. The inverse scattering employin the Gel'fan-Levithan-Marchenko theorem and the layer peeling method provides a tool to determine grating structures from a desired spectral reflection response. Simulations of pulse shaping considered flat-top and triangular pulses as well as one-to-one and one-to-many pulse shaping. The suggested grating profiles revealed a compromise between performance and grating length. The integrated grating, a few hundred microns in length, could generate flat-top pulses with pulse durations as short as 500 fs with rise/fall times of 200 fs; the results are comparable to previous work in free-space optics and fiber optics. The theories and the devised algorithms could serve as a design station for advanced grating devices for, but not restricted to, optical pulse shaping.

Pulse shaping

Integrated optics

Gratings

Ultrafast optics

Picosecond pulses

AlGaAs waveguide

AlGaAs gratings

Flat-top pulse shaping

Rectangular pulse shaping

Coupled-mode theory

Inverse scattering

0544