Пенчо Генов Маринов
Цитирания
x.1, x.2, .... цитират моята работа x.0 в библиографичните си секции.
Цитиранията [c.X] не са в библиографиите на тези работи, а директно в текста и/или уводните им части.
Общ брой цитирания - 237, през последните 5 години - 139 (2011-19, 2012-33, 2013-22, 2014-26, 2015-39).
1.0. Kutiev I.S., Stankov S.M., Marinov P. Analytical expression of O+-H+ transition surface
for use in IRI (1994) Adv.Space Res.,14(12),pp.135-138.
1.1. Triskova L., Truhlic V., Smilauer J., Shultchishin Yu.A., Comparison of O+/H+ and O+/(H+ + He+)
transition levels.(1998) Advances in Space Research, 22(6), pp.895-898.
1.2. Bilitza D., International Reference Ionosphere 2000. (2001) Radio Science 36(2), pp.261-275.
1.3. Truhlic V., Trishkova L., Smilauer J. New advances in empirical modelling of ion comparison
in the outer of ionosphere. (2004) Advances in Space Res 33(6), pp.844-849.
1.4. Gulyaeva T., Stanislawska I. Night-day imprints of ionospheric slab tichness during geomagnetic
storm. (2005) Journal of Atmospheric and Solar-Terrestrial Physics 67(14), pp.1307-1314.
1.5. Bilitza, D; Reinisch, BW, International Reference Ionosphere 2007: Improvements and new parameters
Adv. Space Res, 42 (4): 599-609 AUG 18 2008
1.6. Meza, A., Brunini, C., Gularte Scarone, A.E., Mosert, M. Analysis of a topside ionospheric model
using GPS and ionosonde observables Advances in Space Research 42 (4), pp. 712-719 (2008)
1.7. Heelis, R.A., Coley, W.R., Burrell, A.G., Hairston, M.R., Earle, G.D., Perdue, M.D., Power, R.A.,
Lippincott, C.R.; Behavior of the O+/H+ transition height during the extreme solar minimum of 2008.
Geophysical Research Letters 36 (18), art. no. L00C03 (2009)
2.0. Kutiev I., Oyama K.-I., Abe T., Marinov P. Plasmasphere electron temperature model based on Akebono
data (2004) Advances in Space Research, 33 (6), pp. 975-979.
2.1. Gulyaeva T.L., Titheridge J.E. Advanced specification of electron density and temperature in the
IRI ionosphere-plasmasphere model. (2006) Advances in Space Research, 38 (11), pp.2587-2595.
2.2. Bezrukikh, VV; Kotova, GA; Verigin, MI; et al. Thermal structure of dayside plasmasphere according
to the data of Tail and Auroral Probes, and Magion-5 satellite, Cosmic Res., 44 (5): 409-418 SEP-OCT 2006
3.0. Kutiev I., Marinov P., Serafimov K.B., An approximation of the height of the O+-H+ transition level
for use in IRI (1984) Adv. Space Res., 4(1), p.119-123.
3.1. Truhlik V., Smilauer J., Trishkova L., Shultchishin Yu.A., Smirnova N.F. Manifestation of ionospheric
storms in the upper transition height. (1997) Adv.Space Research, 20(9), pp.1709-1712.
3.2. S. M. Stankov, The oxygen-helium ion transition level during low solar activity:
I. Somparison of AE-C satellite data with IRI model calculations.
Bulgarian Geophysical Journal, 25(1-4), 1999, p.95-120.
3.3. Zamlutti C.J. On the basic trends of the upper atmosphere modeling -- A Review. (1998)
Revista Brasiliera de Geofisica 16(2-3), pp.158-179.
3.4. Trishkova L., Truhlik V., Smilauer J. Empirical modeling of the upper transition height
for low and middle latitudes. (2001) Advances in Space Research 27(1), pp.111-114.
3.5. Bilitza, D; Reinisch, BW. International Reference Ionosphere 2007: Improvements and new parameters,
Adv. Space Res., 42 (4), 2008, 559-609.
4.0. Marinov P., Kutiev I., Watanabe S., Empirical model of O-H transition height based on topside sounder data.
(2004) Advances in Space Research, 34(9), pp. 2021-2025.
4.1. Stankov S.M., Jakowski N., Heise S., Reconstruction of ion and electron density profiles from space-based
measurements of the upper electron content. (2005) Planetary and Space Science,53(9),pp.945-957.
4.2. Webb P.A., Benson R.F. Grebowsky J.M., Technique for determining midlatitude O+/H+ transition heights
from topside iongrams. (2006) Radio Science 41(6), art.no.RS6S34, Oct.4, doi:10.1029/2005RS003391.
4.3. Reinisch B.W., Nsumei P., Huang X., Bilitza D.K., Modeling the F2 topside and plasmasphere for IRI
using IMAGE/RPI and ISIS data. (2007) Advances in Space Research 39(5), pp.731-738.
4.4. Bilitza, D; Reinisch, BW International Reference Ionosphere 2007: Improvements and new parameters,
Adv. Space Res, 42 (4): 599-609 AUG 18 (2008).
4.5. Bilitza, D The importance of bottomside and topside sounding measurements for the development of IRI,
Radio Sound. Plasma Phys., 974: 9-19 2008
4.6. Bilitza, D; Reinisch, BW; Radicella, SM; et al. , Improvements of the International Reference Ionosphere model
for the topside electron density profile Radio Sci., 41 (5): ART. no. rs5s15 apr 18 2006
4.7. Luan, XL; Liu, LB; Wan, WX; et al., A study of the shape of topside electron density profile derived from
incoherent scatter radar measurements over Arecibo and Millstone Hill, Radio Sci., 41 (4): art. no. rs4006 Jul 19 2006
4.8. Liu, L; Wan, W; Ning, B , A study of the ionogram derived effective scale height around the ionospheric hmF2,
Ann. Geophys., 24 (3): 851-860 2006
4.9. Strangeways, H.J., Kutiev, I., Cander, L.R., Kouris, S., Gherm, V., Marin, D., De La Morena, B., Zolesi, B.
Near-Earth space plasma modelling and forecasting
Annals of Geophysics 52 (3-4), pp. 255-271 (2009)
4.10. Kakinami, Y., Chen, C.H., Liu, J.Y., Oyama, K.-I., Yang, W.H., Abe, S.
Empirical models of Total Electron Content based on functional fitting
over Taiwan during geomagnetic quiet condition.
Annales Geophysicae 27 (8), pp. 3321-3333 (2009)
4.11. Belehaki, A., Stanislawska, I., Lilensten, J.
An overview of ionosphere-thermosphere models available for space weather purposes.
Space Science Reviews 147 (3-4), pp. 271-313 (2009)
4.12. Sibanda, P., McKinnell, L.A.
Evaluating the IRI topside model for the South African region: An overview of the modelling techniques.
Advances in Space Research 44 (6), pp. 707-714 (2009)
5.0. Tsekova K.V., Marinov P.G., Tzekova A.N., Copper accumulation by Aspergilus awamory (2000) Folia Microbiologica,
45(3),pp. 217-220.
5.1. Shimonochova A., Ahevc J., Iro S. Trichoderma viride Pers. ex Gray as biosorbent of heavy metals (Pb, Hg and Cd).
(2002) Ekologia Bratislava 21(3),pp.298-306.
5.2. Shakoori A.R., Muneer B., Copper-resistant bacteria from industrial effluents and their role in remediation
of hheavy metals in wastewater. (2002) Folia Microbiologica 47(1), pp. 43-50.
5.3. Kujan P., Prell A., Shafar H., Sobotka M., Rezanka T., Holler P. Removal of copper ions from dilute solutions by
Streptomyces noursei mycelium. Comparison with yast biomass. (2005) Folia Microbiologica, 50(4), pp. 309-313.
5.4. Wang. J., Chen C.
Biosorbents for heavy metals removal and their future.
Biotechnology Advances 27 (2), pp. 195-226 (2009)
6.0. Oyama K.-I., Marinov P., Kutiev I., Watanabe S. Low latitude model of Te at 600 km based on Hinotori satellite data.
(2004) Advances in Space Research, 34 (9), pp. 2004-2009.
6.1.. Liu, L., He, M., Wan, W., Zhang, M.-L., Topside ionospheric scale heights retrieved from Constellation Observing
System for Meteorology, Ionosphere, and Climate radio occultation measurements (2008) Journal of Geophysical Research
A: Space Physics 113 (10), art. no. A10304.
6.2. Bilitza, D., Reinisch, B.W. International Reference Ionosphere 2007: Improvements and new parameters
Advances in Space Research 42 (4), pp. 599-609 (2008).
6.3. Kakinami, Y., Watanabe, S., Oyama, K.-I An empirical model of electron density in low latitude at 600 km
obtained by Hinotori satellite Advances in Space Research, 41 (9), pp. 1494-1498 (2008)
6.4. Chamua, M., Bhuyan, P.K., Subrahmanyam, P., Garg, S.C. Diurnal, seasonal, latitudinal and solar cycle variation
of electron temperature in the topside F-region of the Indian zone ionosphere
Annales Geophysicae 25 (9), pp. 1995-2006 (2007)
6.5. Cin-Min Liu. Master's Thesis: Variations of Ionospheric electron temperature during erthquake period.
Department: Space Science, Year 2007, Semester 2, Degree Master. Date of submission 2008-07-22.
Date of Defense: 2008-06-05. (73 pages, Language: zh-TW.Big5-Chinese).
7.0. Kutiev, I., P. Marinov, S. Watanabe , Model of topside ionosphere scale height based on topside sounder data,
Adv. Space Res., 37, 5, 943-950, 2006.
7.1. Liu, L; Wan, W; Yue, X; Zhao, B; Ning, B; Zhang, ML, The Dependence Of Plasma Density In The Topside Ionosphere
On The Solar Activity Level, Annales Geophysicae, 25 (6): 1337-1343 (2007)
7.2. Liu, LB; Le, HJ; Wan, WX; Sulzer, MP; Lei, JH; Zhang, ML An Analysis Of The Scale Heights In The Lower Topside
Ionosphere Based On The Arecibo Incoherent Scatter Radar Measurements, J. Geophys. Res, 112 (6) 2007.Art.No: A06307
7.3. Liu, L., Wan, W., Zhang, M.-L., Ning, B., Zhang, S.-R., Holt, J.M.Variations of topside ionospheric scale heights
over Millstone Hill during the 30-day incoherent scatter radar experiment (2007) Annales Geophysicae 25 (9), pp. 2019-2027
7.4. Park, S.M., H. Kim, S. Min, J. Park, J.H. Lee, H. Kil, L.J. Paxton, S-Y. Su, J. Lee, and K.W. Min, Effects of solar
activity variations on the low latitude topside nighttime ionosphere,
Adv. Space Res., 42, (4), 626-633, 2008. doi: 10.1016/j.asr.2007.11.031.
7.5. Liu, L., He, M., Wan, W., Zhang, M.-L.Topside ionospheric scale heights retrieved from Constellation
Observing System for Meteorology, Ionosphere, and Climate radio occultation measurements (2008)
Journal of Geophysical Research A: Space Physics 113 (10), art. no. A10304
7.6. Tulasi Ram, S., Su, S.-Y., Liu, C.H., Reinisch, B.W., McKinnell, L.-A.
Topside ionospheric effective scale heights (HT) derived with ROCSAT-1
and ground-based ionosonde observations at equatorial and midlatitude stations.
Tulasi Ram, S., Su, S.-Y., Liu, C.H., Reinisch, B.W., McKinnell, L.-A.
Journal of Geophysical Research A: Space Physics 114 (10), art. no. A10309 (2009)
7.7. Chen, Y., Liu, L., Wan, W., Yue, X., Su, S.-Y.
Solar activity dependence of the topside ionosphere at low latitudes.
Journal of Geophysical Research A: Space Physics 114 (8), art. no. A08306 (2009)
7.8. Liu, L., Chen, Y.
Statistical analysis of solar activity variations of total electron
content derived at Jet Propulsion Laboratory from GPS observations.
Journal of Geophysical Research A: Space Physics 114 (10), art. no. A10311 (2009)
7.9. Belehaki, A., Stanislawska, I., Lilensten, J.
An overview of ionosphere-thermosphere models available for space weather purposes.
Space Science Reviews 147 (3-4), pp. 271-313 (2009)
7.10. Sibanda, P., McKinnell, L.A.
Evaluating the IRI topside model for the South African region: An overview of the modelling techniques,
Advances in Space Research 44 (6), pp. 707-714 (2009)
7.11. Strangeways, H.J., Kutiev, I., Cander, L.R., Kouris, S., Gherm, V., Marin, D., De La Morena, B., (...), Zolesi, B.
Near-Earth space plasma modelling and forecasting
Annals of Geophysics 52 (3-4), pp. 255-271 (2009)
8.0. Belehaki, A., P. Marinov, I. Kutiev, N. Jakowski, S. Stankov,Comparison of the topside ionosphere scale height
determined by topside sounders model and bottomside digisonde profiles, Adv. Space Res., 2006, 37, 5, 963-966.
8.1. Liu, LB; He, MS; Wan, WX; Zhang, ML , Topside ionospheric scale heights retrieved from Constellation Observing System
for Meteorology, Ionosphere, and Climate radio occultation measurements, J. Geophys. Res, 113 (A10): Art. No. A10304 OCT 11 2008
8.2. Nambala, FJ; McKinnell, LA; Oyeyemi, E Variations in the ionospheric scale height parameter at the F2 peak over
Grahamstown, South Africa, Adv. Space Res, 42 (4): 707-711 AUG 18 2008
8.3. Bilitza, D The importance of bottomside and topside sounding measurements for the development of IRI Radio Sound.
Plasma Phys., Vol.974, pp. 9-19 (2008)
8.4. Lee, CC; Reinisch, BW , Quiet-condition variations in the scale height at F2-layer peak at Jicamarca during solar
minimum and maximum, Ann. Geophys., 25 (12): 2541-2550 (2007)
8.5. Liu, L.; Wan, W; Zhang, ML; Ning, B; Zhang, SR; Holt, JM, Variations of topside ionospheric scale heights over
Millstone Hill during the 30-day incoherent scatter radar experiment, Ann. Geophys, 25 (9): 2019-2027 (2007)
8.6. L. Liu, W. Wan, B. Ning. A study of the ionogram derived effective scale height around the ionospheric hmF2.
Ann. Geophys., 24 (3), 851-860, 2006.
8.7. Liu, LB; Le, HJ; Wan, WX; Sulzer, MP; Lei, JH; Zhang, ML. An Analysis Of The Scale Heights In The Lower Topside
Ionosphere Based On The Arecibo Incoherent Scatter Radar Measurements, J. Geophys. Res, 112 (6) 2007.Art.No: A06307
8.8. Tulasi Ram, S., Su, S.-Y., Liu, C.H., Reinisch, B.W., McKinnell, L.-A.
Topside ionospheric effective scale heights (HT) derived with ROCSAT-1
and ground-based ionosonde observations at equatorial and midlatitude stations.
Journal of Geophysical Research A: Space Physics 114 (10), art. no. A10309 (2009)
9.0. Warnant, R., I. Kutiev, P. Marinov, M. Bavier, and S. Lejeune, Ionospheric and geomagnetic conditions during periods
of degraded GPS position accuracy: 2. RTK events during disturbed and quiet geomagnetic conditions,
Adv. Space Res., 39, 881-888, 2007. doi:10.1016/j.asr.2006.06.018
9.1. Stankov, SM; Jakowski, N, Ionospheric effects on GNSS reference network integrity, J. Atm. Solar-Terr.
Phys, 69 (4-5): 485-499 2007
9.2. Stankov, SM; Jakowski, N; Tsybulya, K; et al. Monitoring the generation and propagation of ionospheric
disturbances and effects on Global Navigation Satellite System positioningRadio Sci., 41 (6):
ART. NO. RS6S09 AUG 12 2006
9.3. Juan Manuel Cordoba, Diego Marin, Jose Manuel Angujar. Inigo Blanko, Benito A. de la Morena.
Metodo de prediccion a corto-plazo de foF2 basado en modelado neuroborroso para su aplication
en sistemas de comunicacion por satelite de alta precision.
(Recibido 12 Feb. 2008; recibido en forma revisada 6 Mar. 2008; acceptado 20 Mar 2008)
Fisica de la Tierra, 2008 (20), 167-182.
9.4. Ya'Acob, N., Abdullah, M., Mahamod, I., Zaharim, A.
Model validation for GPS total electron content (TEC) using 10th
polynomial function technique at an equatorial region.
WSEAS Transactions on Computers 8 (9), pp. 1533-1542 (2009)
10.0.. Kutiev, I., and P. Marinov, Topside sounder model of scale height and transition height characteristics
of the ionosphere, to be published in Adv. Space Res., 39(5), 759-766, 2007. doi:10.1016/j.asr.2006.06.013.
10.1. Bilitza, D, The importance of bottomside and topside sounding measurements for the development of IRI,
Radio Sound. Plasma Phys., [AIP Conf. Proc. Feb.4] Volume 974, issue 1,: (2008), pp. 9-19. (DOI: 10.1063/1.2885039
10.2. Liu, L.; Wan, W; Zhang, ML; Ning, B; Zhang, SR; Holt, JM, Variations of topside ionospheric scale heights over
Millstone Hill during the 30-day incoherent scatter radar experiment, Ann. Geophys., 25 (9): 2019-2027 (2007)
10.3. Liu, L; Wan, W; Yue, X; Zhao, B; Ning, B; Zhang, ML, The Dependence Of Plasma Density In The Topside Ionosphere
On The Solar Activity Level, Ann. Geophys, 25 (6): 1337-1343 (2007)
10.4. Liu, LB; Le, HJ; Wan, WX; Sulzer, MP; Lei, JH; Zhang, ML, An Analysis Of The Scale Heights In The Lower Topside
Ionosphere Based On The Arecibo Incoherent Scatter Radar Measurements, J. Geophys. Res, 112 (A6) 2007
10.5. P. Coisson, B. Nava, S.M. Radicella. On the use of NeQuick topside option in IRI-2007.
Advances in Space Research, 43(11), 2009, 1688-1693.
10.6. Heelis, R.A., Coley, W.R., Burrell, A.G., Hairston, M.R., Earle, G.D., Perdue, M.D., Power, R.A., (...), Lippincott, C.R.
Behavior of the O+/H+ transition height during the extreme solar minimum of 2008.
Geophysical Research Letters 36 (18), art. no. L00C03 (2009)
10.7. Kakinami, Y., Chen, C.H., Liu, J.Y., Oyama, K.-I., Yang, W.H., Abe, S.
Empirical models of Total Electron Content based on functional fitting over Taiwan during geomagnetic quiet condition.
Annales Geophysicae 27 (8), pp. 3321-3333 (2009)
10.8. Belehaki, A., Stanislawska, I., Lilensten, J.
An overview of ionosphere-thermosphere models available for space weather purposes.
Space Science Reviews 147 (3-4), pp. 271-313 (2009)
10.9. Strangeways, H.J., Kutiev, I., Cander, L.R., Kouris, S., Gherm, V., Marin, D., De La Morena, B., (...), Zolesi, B.
Near-Earth space plasma modelling and forecasting.
Annals of Geophysics 52 (3-4), pp. 255-271 (2009)
11.0. . Stankov, S.M., P. Marinov , and I. Kutiev, Comparison of NeQuick, PIM, and TSM model results for the plasma scale
and transition heights, Adv. Space Res., 39, 767-773, 2007. doi:10.1016/j.asr.2006.10.023.
11.1. Zulkifli, SSN; Abdullah, M; Ismail, M Application of 3-D ray-tracing for accurate GPS range finding.
2007 5TH Student Conference On Research And Development, SCORED, :pp. 396-400 (2007), art. no. 4451413
2008-02-15, ISBN: 978-1-4244-1469-7.
11.2. Strangeways, H.J., Kutiev, I., Cander, L.R., Kouris, S., Gherm, V., Marin, D., De La Morena, B., (...), Zolesi, B.
Near-Earth space plasma modelling and forecasting.
Annals of Geophysics 52 (3-4), pp. 255-271 (2009)
11.3. Zulkifli, S.S., Abdullah, M., Zaharim, A., Ismail, M.
Ionospheric effects on GPS range finding using 3D ray-tracing and Nelder-Mead optimisation algorithm.
WSEAS Transactions on Mathematics 8 (1), pp. 1-10 (2009)
11.4. Belehaki, A., Stanislawska, I., Lilensten, J.
An overview of ionosphere-thermosphere models available for space weather purposes.
Space Science Reviews 147 (3-4), pp. 271-313 (2009)
12.0. Bl. Sendov, P. Marinov, On the Mean Value Conjectures of Smale and Tischler, East Journal on
Approximations, 12, 3 (2006), 353-366
12.1. Dimitrov, D. K. Smale's Conjecture on Mean Values of Polynomials and Electrostatics.
Serdica Mathematical Journal, Volume 33, Number 4, 2007, (pp. 399-410)
13.0. A. Andreev and P. Marinov, "Numerical determination of the element of best Hausdorff approximation",
Numerical determination of the element of best Hausdorff approximation, Ed. B. Bojanov, ed., (DABRA, Sofia), 2002, 1-12.
13.1. Б. Х. Сендов Хаусдорфово расстояние и обработка изображений Успехи математических наук, 2004, 59:2(356), 127Ц136
13.2. B Sendov, "Hausdorff distance and image processing", RUSS MATH SURV, 2004, 59 (2), 319-328
14.0. V. Bochev, P. Marinov, P. Nus, and T. Cecchin, "An FPGA/PLSI Hausdorff distance processor design for pattern recognition
applications", International Conference on Signal Processing, Applications and Technology (Boston), 1995;
International Conference on Signal Processing, Applications and Technology (ICSPAT, Boston), 1995, 1015-1018.
14.1. Б. Х. Сендов Хаусдорфово расстояние и обработка изображений Успехи математических наук,
2004, 59:2(356), 127-136.
14.2. B Sendov, "Hausdorff distance and image processing", RUSS MATH SURV, 2004, 59 (2), 319-328
15.0. P. G. Marinov, Approximate Determination of the Generalized Polynomial of the Best One-sided Hausdorff
Approximation. Matematica Balkanika, New series, Vol.3, 1989, Fasc 1, pp. 97-105.
15.1. K SUAREZ, J SILVA, M NAJIM -A Genetic Algorithm Approach For Pattern Recognition In Biomedical Signals. 2001
-- documents.irevues.inist.fr (Technical Report INIST-CNRS, Cote INIST : Y 34085 (1), 35400010842848.1700), GRETSI,
Groupe d'Etudes du Traitement du Signal et des Images,
16.0. Пенчо Г. Маринов,
Алгоритми за приближение с рационални функции
относно Хаусдорфово разстояние. Дисертационен труд
за получаване на научната степен
'кандидат на математическите науки'- София, 1991 год.;
(сега - 'образователна и научна степен Доктор')
публична защита на 29.06.1993 г.; ( Автореферат).
16.1. Dodov, B., Foufoula-Georgiou, E.. Incorporating the spatio-temporal distribution of rainfall and basin
geomorphology into nonlinear analyses of streamflow dynamics (2005) Advances in Water Resources 28 (7), pp. 711-728
16.2. Петър Апостолов, Математически приближения с компресирани косинуси и техните приложения.
Академично издателство „Проф. Марин Дринов“, 2012, ISBN 978-954-322-542-2.
17.0. Rene Warnant, Ivan Kutiev, Pencho Marinov, Michael Bavier, Sandrine Lejeune.
Ionospheric and geomagnetic conditions during periods of degraded GPS position accuracy:
1. Monitoring variability in TEC wich degrades the accuracy of Real-Time Kinematics GPS applications.
Advances in Space Research. Volume 39, Issue 5, (2007), 875-880.
(doi: 10.1016/j.asr. 2006.03.044)
17.1. Amato Bonavita (*), Lorenzo Pini (*), Paolo Pellegrini (*)
Attendibilita del posizionamento planimetrico
satellitare GNSS in ambito forestale con
strumentazione GPS semplificata.
L'Italia Forecaste e Montana, in corso di stampa (2008).
(*) Dipartimento di Ingegneria Agraria e Forestale, Sez. Costruzioni e Territorio, UniversitГа degli Studi di
Firenze, Via S. Bonaventura, 13 - 50145 Firenze, e-mail: amato.bonavita@unifi.it.
17.2. Juan Manuel Cordoba, Diego Marin, Jose Manuel Angujar. Inigo Blanko, Benito A. de la Morena.
Metodo de prediccion a corto-plazo de foF2 basado en modelado neuroborroso para su aplication
en sistemas de comunicacion por satelite de alta precision.
(Recibido 12 Feb. 2008; recibido en forma revisada 6 Mar. 2008; acceptado 20 Mar 2008)
Fisica de la Tierra, 2008 (20), 167-182.
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