Simon Ek scite author profile

Simon Ek

5Publications

15Citation Statements Received

106Citation Statements Given

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Lund University

Publications

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Long sequence single-exposure videography using spatially modulated illumination

Kornienko

Kristensson

2020

Sci Rep

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Frequency recognition algorithm for multiple exposures (FRAME) is a single-exposure imaging technique that can be used for ultrafast videography, achieved through rapid illumination with spatially modulated laser pulses. To date, both the limit in sequence length as well as the relation between sequence length and image quality are unknown for FRAME imaging. Investigating these questions requires a flexible optical arrangement that has the capability of reaching significantly longer image sequences than currently available solutions. In this paper we present a new type of FRAME setup that fulfills this criteria. The setup relies only on (i) a diffractive optical element, (ii) an imaging lens and (iii) a digital micromirror device to generate a modulated pulse train with sequence lengths ranging from 2 to 1024 image frames. To the best of the authors’ knowledge, this is the highest number of temporally resolved frames imaged in a single-exposure.

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High-speed videography of transparent media using illumination-based multiplexed schlieren

Kornienko

Roth

et al. 2022

Sci Rep

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Schlieren photography is widely used for visualizing phenomena within transparent media. The technique, which comes in a variety of configurations, is based on detecting or extracting the degree to which light is deflected whilst propagating through a sample. To date, high-speed schlieren videography can only be achieved using high-speed cameras, thus limiting the frame rate of such configurations to the capabilities of the camera. Here we demonstrate, for the first time, optically multiplexed schlieren videography, a concept that allows such hardware limitations to be bypassed, opening up for, in principle, an unlimited frame rate. By illuminating the sample with a rapid burst of uniquely spatially modulated light pulses, a temporally resolved sequence can be captured in a single photograph. The refractive index variations are thereafter measured by quantifying the local phase shift of the superimposed intensity modulations. The presented results demonstrate the ability to acquire a series of images of flame structures at frame rates up to 1 Mfps using a standard 50 fps sCMOS camera.

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Simultaneous multiple time scale imaging for kHz–MHz high-speed accelerometry

et al. 2022

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Fast transient events, such as the disintegration of liquid bodies or chemical reactions between radical species, involve various processes that may occur at different time scales. Currently, there are two alternatives for monitoring such events: burst- or high-speed imaging. Burst imaging at ultrahigh speeds ( ∼ 100 MHz to THz ) allows for the capture of nature’s fastest processes but only for a narrowly confined period of time and at a repetition rate of ∼ 10 Hz . Monitoring long lasting, rapidly evolving transient events requires a significantly higher repetition rate, which is met by existing ∼ kHz to 1 MHz high-speed imaging technology. However, the use of such systems eliminates the possibility to observe dynamics occurring on the sub-microsecond time scale. In this paper, we present a solution to this technological gap by combining multiplexed imaging with high-speed sensor technology, resulting in temporally resolved, high-spatial-resolution image series at two simultaneous time scales. We further demonstrate how the collection of such data opens up the tracking of rapidly evolving structures up to MHz burst rates over long durations, allowing, for the first time, to our knowledge, the extraction of acceleration fields acting upon the liquid bodies of an atomizing spray in two dimensions at kHz frame rates.

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Transitioning from conventional photon therapy to proton therapy for primary brain tumors

Kristensen

Stenberg

et al. 2023

Acta Oncologica

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Phase reconstruction of high-order harmonics by quantum path interference

Olofsson

Ibrakovic

et al. 2020

J. Phys.: Conf. Ser.

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Synopsis We present a method to retrieve the phase of XUV light generated through high-order harmonic generation, by observing the intensity dependence of the interference pattern in the far-field. This interference pattern arises from electron trajectories in the generation process. These trajectories spend different time in the continuum and the phase of the generated light will therefore depend differently on the instantaneous intensity of the driving field. By changing the intensity of the driving field the phase of the contributing trajectories can be extracted.

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Simon Ek

Long sequence single-exposure videography using spatially modulated illumination

High-speed videography of transparent media using illumination-based multiplexed schlieren

Simultaneous multiple time scale imaging for kHz–MHz high-speed accelerometry

Transitioning from conventional photon therapy to proton therapy for primary brain tumors

Phase reconstruction of high-order harmonics by quantum path interference

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