Frequency-resolved optical gating with the use of second-harmonic generation

DeLong, Kenneth W.; Trebino, Rick; Hunter, James R.; White, William E.

doi:10.1364/josab.11.002206

Cited by 373 publications

(232 citation statements)

References 18 publications

(26 reference statements)

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“…Experimental data was taken by spectrally resolving the autocorrelation of the pulse (SHG FROG [121]). Figure 17 shows an experimental SHG FROG trace of a 72-fs fundamental pulse (compressed with a 150 lines/mm grating pair) along with the best calculated fit, obtained with the generalized projections algorithm [122].…”

Section: Frequency-resolved Optical Gating Measurementsmentioning

confidence: 99%

Ultrashort-pulse fiber ring lasers

Nelson¹,

Jones²,

Tamura³

et al. 1997

Applied Physics B: Lasers and Optics

730

385

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Abstract. This paper reviews recent progress on ultrashort pulse generation with erbium-doped fiber ring lasers. The passive mode-locking technique of polarization additive pulse mode-locking (P-APM) is used to generate stable, selfstarting, sub-500 fs pulses at the fundamental repetition rate from a unidirectional fiber ring laser operating in the soliton regime. Saturation of the APM, spectral sideband generation, and intracavity filtering are discussed. Harmonic modelocking of fiber ring lasers with soliton pulse compression is addressed, and stability regions for the solitons are mapped and compared with theoretical predictions. The stretchedpulse laser, which incorporates segments of positive-and negative-dispersion fiber into the P-APM fiber ring, generates shorter (sub-100 fs) pulses with broader bandwidths (> 65 nm) and higher pulse energies (up to 2.7 nJ). We discuss optimization of the net dispersion of the stretched-pulse laser, use of the APM rejection port as the laser output port, and frequency doubling for amplifier seed applications. We also review the analytical theory of the stretched-pulse laser as well as discuss the excellent noise characteristics of both the soliton and stretched-pulse lasers. 42.60F; 42.65; 42.80 Fiber lasers were made possible in the 1960s by the incorporation of trivalent rare-earth ions such as neodymium, erbium, and thulium into glass hosts [1]. Soon thereafter neodymium was incorporated into the cores of fiber waveguides [2,3]. Due to the high efficiency of the Nd +3 ion as a laser, early work focused on Nd +3 -doped silica fiber lasers operating at 1.06 µm [4]. Doping of silica fibers with Er +3 ions was not achieved until the 1980s [5,6]. Since that time Er +3 -doped fiber lasers have received much attention, because the lasing wavelength at 1.55 µm falls within the low-loss window of optical fibers and thus is suitable for optical fiber communications. Rare-earth ions such as Ho +3 [7,8], Tm +3 [9-11], and * Current address: Lucent Technologies/Bell Labs, 791 Holmdel-Keyport Road, Holmdel, NJ, USA * * Current address: NTT Access Network Systems Laboratory, Tokai-mura, Naka-gun, Ibaraki-ken 319-11, Japan Yb +3 [12,13] have also been used as dopants or co-dopants in silica or fluoride fibers, allowing new lasing or pumping wavelengths, and Pr +3 has been incorporated into fluoride fiber, providing emission at 1.3 µm [14,15]. PACS:Among the numerous advantages of fiber lasers are simple doping procedures, low loss, and the possibility of pumping with compact, efficient diodes. The fiber itself provides the waveguide, and the availability of various fiber components minimizes the need for bulk optics and mechanical alignment. Many different cavity configurations can be easily built with fibers and fused-fiber couplers, including linear FabryPerot, ring, and combinations of the two. Enhancement of the fiber nonlinearity due to large signal intensities and long interaction lengths is an additional advantage of fiber lasers that is particularly important for mode-locki...

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Section: Frequency-resolved Optical Gating Measurementsmentioning

confidence: 99%

Ultrashort-pulse fiber ring lasers

Nelson¹,

Jones²,

Tamura³

et al. 1997

Applied Physics B: Lasers and Optics

730

385

View full text Add to dashboard Cite

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“…The laser was biased below threshold at 5 mA, and gain-switched at a repetition rate of 500 MHz using electrical pulses from a step recovery diode. The electrical pulses had a duration of 80 ps and an amplitude of 13 V. The DFB laser pulses were characterised using spectral and autocorrelation measurements, as well as a second-harmonic generation FROG set-up to determine the pulse intensity and chirp [6].…”

Section: Experimental Set-upmentioning

confidence: 99%

“…In this paper we report a systematic approach to fibre compressor design based on the complete intensity and chirp characterisation of the initial gainswitched laser pulses using the technique of frequency-resolved optical gating (FROG) [6]. The complete characterisation of the electric field of the laser pulses allows the design of the fibre-pulse compressor to be optimised by examining the propagation of the pulses in different types of optical fibre using numerical 3 simulations based on the nonlinear Schrödinger equation (NLSE).…”

Section: Introductionmentioning

confidence: 99%

Optimised design of fibre-based pulse compressor for gain-switched DFB laser pulses at 1.5 [micro sign]m

et al. 1999

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An optical-fibre based pulse compressor for gain-switched DFB laser pulses has been optimised using a systematic procedure based on the initial complete characterisation of the laser pulses, followed by numerical simulations of the pulse propagation in different types of fibre to determine the required lengths for optimum compression.Using both linear and nonlinear compression techniques, an optimum compression factor of 12 is achieved.2

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“…In this letter, we apply the measurement technique of frequency-resolved optical gating (FROG) [5] to determine the switching characteristics of a NALM during the steady-state operation of a modelocked F8L. We use FROG measurements to determine the intensity and phase of pulses coupled out from the NALM in both the clockwise and anticlockwise directions, and using the nonlinear Schrödinger equation, we numerically propagate these pulses back into the NALM to determine the intracavity propagating fields.…”

Section: Introductionmentioning

confidence: 99%

“…The F8L output pulses were characterized using an experimental FROG technique based on the spectral resolution of a second harmonic generation autocorrelation signal in a BBO crystal, and our experimental setup was similar to that in [5]. The pulse intensity and phase characteristics were retrieved from the measured FROG signal using standard phase-retrieval techniques [5]. Fig.…”

Section: Introductionmentioning

confidence: 99%

Characterization of nonlinear switching in a figure-of-eight fiber laser using frequency-resolved optical gating

Bollond

Barry

Dudley

et al. 1998

IEEE Photon. Technol. Lett.

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Abstract-The measurement technique of frequency-resolved optical gating is applied to determine the nonlinear switching characteristics of a passively modelocked figure-of-eight erbiumdoped fiber laser. By completely characterizing the intensity and phase of the laser output pulses, the intracavity fields in the nonlinear amplifying loop mirror of the laser cavity are determined by numerical propagation using the nonlinear Schrödinger equation. Excellent switching of 95% can be achieved as a result of uniform phase characteristics developed by pulses propagating in the nonlinear amplifying loop mirror.

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Frequency-resolved optical gating with the use of second-harmonic generation

Cited by 373 publications

References 18 publications

Ultrashort-pulse fiber ring lasers

Ultrashort-pulse fiber ring lasers

Optimised design of fibre-based pulse compressor for gain-switched DFB laser pulses at 1.5 [micro sign]m

Characterization of nonlinear switching in a figure-of-eight fiber laser using frequency-resolved optical gating

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