Search results for "Optical pulse train"

showing 2 items of 2 documents

High-repetition-rate source delivering optical pulse trains with a controllable level of amplitude and temporal jitters

2020

International audience; We theoretically propose and numerically validate an all-optical scheme to generate optical pulse trains with varying peak-powers and durations. A shaping of the spectral phase thanks to discrete /2 phase shifts enables an efficient phase-to-intensity conversion of a temporal phase modulation based on a two-tone sinusoidal beating. Experiments carried out at telecommunication wavelengths and at a repetition rate of 10 GHz confirm the ability of our approach to efficiently generate a train made of pulses with properties that vary from pulse-to-pulse. The levels of jitters can be accurately controlled.

Phase (waves)FOS: Physical sciences02 engineering and technologyoptical telecommunications01 natural scienceslcsh:QA75.5-76.95010309 optics020210 optoelectronics & photonicsOptics0103 physical sciences0202 electrical engineering electronic engineering information engineeringhigh-repetition rate optical pulse trainsPhysics[PHYS.PHYS.PHYS-OPTICS]Physics [physics]/Physics [physics]/Optics [physics.optics]optical component testingRepetition (rhetorical device)business.industryhigh‐repetition rate optical pulse trainsPulse (physics)WavelengthAmplitudelcsh:TA1-2040Trainlcsh:Electronic computers. Computer sciencebusinesslcsh:Engineering (General). Civil engineering (General)Phase modulationOptics (physics.optics)Physics - Optics
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Periodic time-domain modulation for the electrically tunable control of optical pulse train envelope and repetition rate multiplication

2012

An electrically tunable system for the control of optical pulse sequences is proposed and demonstrated. It is based on the use of an electrooptic modulator for periodic phase modulation followed by a dispersive device to obtain the temporal Talbot effect. The proposed configuration allows for repetition rate multiplication with different multiplication factors and with the simultaneous control of the pulse train envelope by simply changing the electrical signal driving the modulator. Simulated and experimental results for an input optical pulse train of 10 GHz are shown for different multiplication factors and envelope shapes. © 2006 IEEE.

Signal processingElectrically tunableMultiplication factorElectrical signalPhysics::Optics02 engineering and technologyOptical signal processingSimultaneous control01 natural sciencesOptical pulse train010309 opticsQ switched lasers020210 optoelectronics & photonicsOptics0103 physical sciencesTEORIA DE LA SEÑAL Y COMUNICACIONES0202 electrical engineering electronic engineering information engineeringTalbot effectPulse waveOptical fibersTime domainOptical fiber dispersionElectrical and Electronic EngineeringTemporal Talbot effectsEnvelope (waves)PhysicsTelecomunicacionesDispersive devicesRepetition rate multiplicationbusiness.industryOptical pulse shapingAtomic and Molecular Physics and OpticsPulse (physics)Optical signalsPhase modulationModulationTemporal Talbot effectElectro-optic modulatorsPulse trainOptical pulse sequencesDiffraction gratingsMultiplicationElectrónicaTime domainbusinessPhase modulation
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