M. Jastrzębski scite author profile

M. Jastrzębski

5Publications

13Citation Statements Received

51Citation Statements Given

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Affiliations

Quantum Technologies (Sweden), Lodz University of Technology, University of Łódź

Publications

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Variable electro-optic shearing interferometry for ultrafast single-photon-level pulse characterization

Kurzyna¹,

Jastrzębski²,

Fabre

et al. 2022

Opt. Express

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Despite the multitude of available methods, the characterization of ultrafast pulses remains a challenging endeavor, especially at the single-photon level. We introduce a pulse characterization scheme that maps the magnitude of its short-time Fourier transform. Contrary to many well-known solutions it does not require nonlinear effects and is therefore suitable for single-photon-level measurements. Our method is based on introducing a series of controlled time and frequency shifts, where the latter is performed via an electro-optic modulator allowing a fully-electronic experimental control. We characterized the full spectral and temporal width of a classical and single-photon-level pulse and successfully tested the applicability of the reconstruction algorithm of the spectral phase and amplitude. The method can be extended by implementing a phase-sensitive measurement and is naturally well-suited to partially-incoherent light.

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Adaptive Position Tracking with Hard Constraints—Barrier Lyapunov Functions Approach

Kabziński

Mosiołek

Jastrzębski

2016

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Experimental implementation of the optical fractional Fourier transform in the time-frequency domain

Niewelt¹,

Jastrzębski²,

Kurzyna³

et al. 2023

Preprint

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The fractional Fourier transform (FrFT), a fundamental operation in physics that corresponds to a rotation of phase space by any angle, is also an indispensable tool employed in digital signal processing for noise reduction. Processing of optical signals in their time-frequency degree of freedom bypasses the digitization step and presents an opportunity to enhance many protocols in quantum and classical communication, sensing and computing. In this letter, we present the experimental realization of the fractional Fourier transform in the timefrequency domain using an atomic quantum-optical memory system with processing capabilities. Our scheme performs the operation by imposing programmable interleaved spectral and temporal phases. We have verified the FrFT by analyses of chroncyclic Wigner functions measured via a shot-noise limited homodyne detector. Our results hold prospects for achieving temporal-mode sorting, processing and super-resolved parameter estimation.

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Reconstructing charged particle track segments with a quantum-enhanced support vector machine

Duckett¹,

Facini²,

Jastrzębski³

et al. 2022

Preprint

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Adaptive and robust motion control in presence of LuGre-type friction

Jastrzębski

Kabziński

Mosiołek

2017

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M. Jastrzębski

Variable electro-optic shearing interferometry for ultrafast single-photon-level pulse characterization

Adaptive Position Tracking with Hard Constraints—Barrier Lyapunov Functions Approach

Experimental implementation of the optical fractional Fourier transform in the time-frequency domain

Reconstructing charged particle track segments with a quantum-enhanced support vector machine

Adaptive and robust motion control in presence of LuGre-type friction

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