Publications of Anna Wawrzynczak

A list of publications authored or co-authored by Anna Wawrzynczak, derived from the SAO/NASA Astrophysics Data System (ADS). The number in brackets after each title indicates the number of citations that the paper has received.

Orcid ID: 0000-0001-8292-6875

List of publications ordered by citations
Number of papers: 35 (refereed: 18)
No. of citations: 316
First author papers: 14 (refereed: 5)

2025

  1. Sensor-Driven Localization of Airborne Contaminant Sources via the Sandpile─Advection Model and (1 + 1)-Evolution Strategy [0]
    Szaban, Miroslaw & Wawrzynczak, Anna, Sensors, 25, 6215

2022

  1. Feedforward neural networks in forecasting the spatial distribution of the time-dependent multidimensional functions [0]
    Wawrzynczak, A. & Berendt-Marchel, M., 2022 International Joint Conference on Neural Networks (IJCNN), p. 670

2021

  1. Evaluating the relationship between strong geomagnetic storms and electric grid failures in Poland using the geoelectric field as a GIC proxy [16]
    Gil, Agnieszka, Berendt-Marchel, Monika, Modzelewska, Renata, Moskwa, Szczepan, Siluszyk, Agnieszka, Siluszyk, Marek, Tomasik, Lukasz, Wawrzaszek, Anna & Wawrzynczak, Anna, Journal of Space Weather and Space Climate, 11, 30

2020

  1. The Solar Event of 14 - 15 July 2012 and Its Geoeffectiveness [9]
    Gil, Agnieszka, Modzelewska, Renata, Moskwa, Szczepan, Siluszyk, Agnieszka, Siluszyk, Marek, Wawrzynczak, Anna, Pozoga, Mariusz & Tomasik, Lukasz, Solar Physics, 295, 135

2019

  1. In search of an effective Monte Carlo method for identification of atmospheric contamination source [0]
    Kopka, Piotr & Wawrzynczak, Anna, Journal of Physics Conference Series, Journal of Physics Conference Series, 1391, p. 012106
  2. Neural net clustering in the study of electrical grids failures in relation to geomagnetic storms [0]
    Siluszyk, A., Gil, A., Modzelewska, R., Moskwa, Sz, Siluszyk, M. & Wawrzynczak, A., Journal of Physics Conference Series, Journal of Physics Conference Series, 1391, p. 012107
  3. Application of the artificial neural network in the forecasting of the airborne contaminant [1]
    Wawrzynczak, A. & Berendt-Marchel, M., Journal of Physics Conference Series, Journal of Physics Conference Series, 1391, p. 012092

2018

  1. Framework for stochastic identification of atmospheric contamination source in an urban area [14]
    Kopka, Piotr & Wawrzynczak, Anna, Atmospheric Environment, 195, 63
  2. The Algorithm of Area Optimization by Layers and Binary Classification with use of Three State 2D Cellular Automata [0]
    Szaban, Miroslaw & Wawrzynczak, Anna, 2018 International Conference on Control, Artificial Intelligence, Robotics & Optimization (ICCAIRO), p. 54
  3. Approximate Bayesian Computation for Estimating Parameters of Data-Consistent Forbush Decrease Model [5]
    Wawrzynczak, Anna & Kopka, Piotr, Entropy, 20, 622

2017

  1. Approximate Bayesian Computation in the estimation of the parameters of the Forbush decrease model [0]
    Wawrzynczak, A. & Kopka, P., Journal of Physics Conference Series, Journal of Physics Conference Series, 936, p. 012088

2016

  1. Application of the Approximate Bayesian Computation methods in the stochastic estimation of atmospheric contamination parameters for mobile sources [14]
    Kopka, Piotr, Wawrzynczak, Anna & Borysiewicz, Mieczyslaw, Atmospheric Environment, 145, 201
  2. The stochastic modeling of the short-time variations of the galactic cosmic rays [0]
    Wawrzynczak, A. & Modzelewska, R., Journal of Physics Conference Series, Journal of Physics Conference Series, 738, p. 012001

2015

  1. 27-day variation of the GCR intensity based on corrected and uncorrected for geomagnetic disturbances data of neutron monitors [0]
    Alania, M. V., Modzelewska, R., Wawrzynczak, A., Sdobnov, V. E. & Kravtsova, M. V., Journal of Physics Conference Series, Journal of Physics Conference Series, 632, p. 012085
  2. The Approximate Bayesian Computation methods in the localization of the atmospheric contamination source [1]
    Kopka, P., Wawrzynczak, A. & Borysiewicz, M., Journal of Physics Conference Series, Journal of Physics Conference Series, 633, p. 012118
  3. Numerical methods for solution of the stochastic differential equations equivalent to the non-stationary Parkers transport equation [4]
    Wawrzynczak, A., Modzelewska, R. & Kluczek, M., Journal of Physics Conference Series, Journal of Physics Conference Series, 633, p. 012058
  4. A stochastic method of solution of the Parker transport equation [1]
    Wawrzynczak, A., Modzelewska, R. & Gil, A., Journal of Physics Conference Series, Journal of Physics Conference Series, 632, p. 012084
  5. The connection of the interplanetary magnetic field turbulence and rigidity spectrum of Forbush decrease of the galactic cosmic ray intensity [1]
    Wawrzynczak, A. & Alania, M. V., Journal of Physics Conference Series, Journal of Physics Conference Series, 632, p. 012083
  6. Stochastic approach to the numerical solution of the non-stationary Parker's transport equation [5]
    Wawrzynczak, A., Modzelewska, R. & Gil, A., Journal of Physics Conference Series, Journal of Physics Conference Series, 574, p. 012078

2014

  1. May 2005 Halo CMEs and Galactic Cosmic Ray Flux Changes at Earth's Orbit [10]
    Ahluwalia, H. S., Alania, M. V., Wawrzynczak, A., Ygbuhay, R. C. & Fikani, M. M., Solar Physics, 289, 1763
  2. Peculiarities of cosmic ray modulation in the solar minimum 23/24 [14]
    Alania, M. V., Modzelewska, R. & Wawrzynczak, A., Journal of Geophysical Research (Space Physics), 119, 4164
  3. Data-driven Genetic algorithm in Bayesian estimation of the abrupt atmospheric contamination source [1]
    Wawrzynczak, A., Jaroszynski, M. & Borysiewicz, M., 2014 Federated Conference on Computer Science and Information Systems, p. 77

2013

  1. Temporal Changes in the Rigidity Spectrum of Forbush Decreases Based on Neutron Monitor Data [16]
    Alania, M. V., Wawrzynczak, A., Sdobnov, V. E. & Kravtsova, M. V., Solar Physics, 286, 561
  2. Rigidity spectrum of Forbush decrease calculated by neutron monitors data corrected and uncorrected for geomagnetic disturbances [1]
    Alania, M. V., Wawrzynczak, A., Sdobnov, V. E. & Kravtsova, M. V., Journal of Physics Conference Series, Journal of Physics Conference Series, 409, p. 012184

2012

  1. Energy dependence of the rigidity spectrum of Forbush decrease of galactic cosmic ray intensity [25]
    Alania, Michael V. & Wawrzynczak, Anna, Advances in Space Research, 50, 725

2011

  1. On the Relationship of the 27-day Variations of the Solar Wind Velocity and Galactic Cosmic Ray Intensity in Minimum Epoch of Solar Activity [31]
    Alania, M. V., Modzelewska, R. & Wawrzynczak, A., Solar Physics, 270, 629
  2. A model of the long period Galactic Cosmic Ray variations [11]
    Siluszyk, M., Wawrzynczak, A. & Alania, M. V., Journal of Atmospheric and Solar-Terrestrial Physics, 73, 1923
  3. Three dimensional model of the interplanetary magnetic field and 27-day variation of the galactic cosmic ray intensity [1]
    Wawrzynczak, A., Modzelewska, R. & Alania, M. V., Astrophysics and Space Sciences Transactions, 7, 351
  4. 3-d anisotropy during the Forbush decrease of the galactic cosmic ray [0]
    Wawrzynczak-Szaban, Anna, International Cosmic Ray Conference, International Cosmic Ray Conference, 10, p. 294
  5. Energy dependence of the rigidity spectrum of Forbush decrease of galactic cosmic ray intensity [1]
    Wawrzynczak-Szaban, Anna, International Cosmic Ray Conference, International Cosmic Ray Conference, 10, p. 290

2010

  1. Modeling and experimental study of the 27-day variation of galactic cosmic-ray intensity for a solar wind velocity depending on heliolongitude [16]
    Alania, M. V., Modzelewska, R. & Wawrzynczak, A., Advances in Space Research, 45, 421
  2. Modeling and data analysis of a Forbush decrease [53]
    Wawrzynczak, Anna & Alania, Michael V., Advances in Space Research, 45, 622

2008

  1. Forbush decrease of the galactic cosmic ray intensity: experimental study and theoretical modeling [27]
    Alania, M. V. & Wawrzynczak, A., Astrophysics and Space Sciences Transactions, 4, 59
  2. Modeling of the recurrent Forbush effect of the galactic cosmic ray intensity and comparison with the experimental data [23]
    Wawrzynczak, A. & Alania, M. V., Advances in Space Research, 41, 325

2005

  1. Peculiarities of galactic cosmic ray Forbush effects during October November 2003 [15]
    Wawrzynczak, A. & Alania, M. V., Advances in Space Research, 35, 682

Created on Mon Jun 8 04:40:25 2026.