V. S. Shumigai scite author profile

Ghost imaging can be used to detect objects in a nonstationary environment or in the presence of variable ambient light, making it attractive when conventional imaging methods are ineffective. However, the conventional ghost imaging algorithm is susceptible to temporal fluctuations in the detected signal. In this work, we propose a polarization-multiplexed auxiliary laser channel propagating along the same optical path with the main one. The signal in the auxiliary channel is used as a reference and allows the elimination of signal disturbance. A quantitative analysis and comparison of the proposed method’s performance to the high-pass filtering method are demonstrated. For an illumination pattern refresh rate of 10 Hz, effective suppression of bucket signal fluctuations has been experimentally demonstrated. For a disturbance frequency from 1 Hz to 10 Hz, the auxiliary channel method demonstrated a ghost image Pearson correlation coefficient (PCC) of not less than 0.70, while the high-pass filtering method showed a PCC sharp drop from 0.65 to 0.02.

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Dynamics and radiation effects for charges propagating in ultraintense laser fields

Zalipaev

Shumigai

Zalialiutdinov

et al. 2022

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An Increase in the Signal-To-Noise Ratio of the Detected Terahertz Field in the CdTe Crystal With a Change in the Relative Angle between THz and IR Pulse Polarizations

Shumigai

Oparin²,

Tsypkin³

2022

Bull. Lebedev Phys. Inst.

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Investigation of dispersion properties of congruent lithium niobate crystal in the terahertz frequency range

Shumigai¹,

Oparin²,

Nabilkova³

et al. 2022

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The dependences of the refractive index of a congruent LiNbO3 crystal cut perpendicular to the x and z axes on the radiation frequency in the range of 0.25–1.25 THz are presented. These dependences are presented for different values of the crystal thickness - 0.52 mm, 1 mm and 2.21 mm. A comparative analysis of the obtained dispersion curves with the results from other works is presented. The comparison was carried out by estimating the dispersion broadening of a THz pulse with time in the process of simulating its propagation in a medium with a given dispersion. It is shown that a 1.5-cycle THz pulse is broadened in media with dispersions found in other works, which does not correspond to experimental data. In accordance with this, it was concluded that the dispersion curves for congruent LiNbO3 from the considered works do not agree with the real values of the refractive index in the THz frequency range.

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V. S. Shumigai

Formation of spatio-frequency modulation in a terahertz pulse generated in an indium arsenide crystal

Elimination of signal amplitude disturbance in ghost imaging using an auxiliary laser channel

Dynamics and radiation effects for charges propagating in ultraintense laser fields

An Increase in the Signal-To-Noise Ratio of the Detected Terahertz Field in the CdTe Crystal With a Change in the Relative Angle between THz and IR Pulse Polarizations

Investigation of dispersion properties of congruent lithium niobate crystal in the terahertz frequency range

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