Band W., Madders M., Whitfield D.P. 2007. Developing field and analytical methods to assess avian collision risk at wind farms. In: Birds and wind farms. Risk assessment and mitigation . Edit Quercus, Madrid.
Busse P. 2013. Methodological procedure for pre-investment wind farm ornithological monitoring based on collision risk estimation . Ring 35: 3-10.
Eichhorn M., Johst K., Seppelt R., Drechsler M. 2012. Model-Based Estimation of Collision Risks of Predatory Birds with WindTurbines . Ecology and Society 17 (2): 1. http
Bohumil Frantál, Tadej Bevk, Bregje Van Veelen, Mihaela Hărmănescu and Karl Benediktsson
APPLEYARD, D. (1970): Styles and methods of structuring a city. Environment and Behaviour, 2: 100–117.
BAXTER, J., MORZARIA, R., HIRSCH, R. (2013): A case-control study of support/opposition to windturbines: Perceptions of health risk, economic benefits, and community conflict. Energy Policy, 61: 931–943.
BELL, S. (2012). Landscape: pattern, perception and process. New York, Routledge.
BELL, D., GRAY, T., HAGGETT, C. (2005): The ‘social gap’ in wind farm siting decisions: explanations and policy responses. Environmental
Museok Song, Moon-Chan Kim, In-Rok Do, Shin Hyung Rhee, Ju Hyun Lee and Beom-Soo Hyun
Bahaj, A.S., Molland, A.F., Chaplin, J.R. and Batten, W.M.J., 2007. Power and thrust measurements of marine current turbines under various hydrodynamic flow condition in a cavitation tunnel and a towing tank. Renewable Energy, 32(3), pp.407-426.
Baltazar, J. and Falcao de Campos, J.A.C., 2009. Unsteady analysis of a horizontal axis marine current turbine in yawed inflow conditions with a panel method. 1st International symposium on marine propulsors. Trondheim, Norway.
Burton, T., Share, D., Jenkins
Geography, 4(2): 169–184.
BROEKEL, T., ALFKEN, C. (2015): Gone with the wind? The impact of windturbines on tourism demand. Energy Policy, 86: 506–519.
CLARKE, S. (2009): Balancing environmental and cultural impact against the strategic need for wind power. International Journal of Heritage Studies, 15(2–3): 175–191.
COWELL, R. (2010): Wind power, landscape and strategic, spatial planning – The construction of ‘acceptable locations’ in Wales. Land Use Policy, 27(2): 222–232.
DAUGSTAD, K. (2008): Negotiating landscape in rural tourism. Annals of
Czesław Dymarski, Paweł Dymarski and Jędrzej Żywicki
// ARCHIVES OF MECHANICS. -Vol. 64, nr. 2 (2012), s.153-175.
4. Barthelmie R., Pryor S., Frandsen S., Hansen K., Schepers J., K. Rados K., Schlez W., Neubert A., Jensen L. and Neckelmann S.: Quantifying the Impact of WindTurbine Wakes on Power Output at Offshore Wind Farms. Journal of Atmospheric and Oceanic Technology Vol. 27, 2010,
5. Ackermann T., Söder L.: Wind energy technology and current status: a review, Renewable and Sustainable Energy Reviews, 4 (2000), pp. 315-374
6. Markard J., Petersen R.: The offshore trend
5. Dymarski P., Ciba E., Marcinkowski T.: Effective method for determining environmental loads on supporting structures for offshore windturbines, 20th International Conference on Hydrodynamics in Ship Design and Operation HYDRONAV 2014, Wroclaw, Poland, June 2014
6. Turbine graphics, source: Repower (in Polish)
7. PN-80/B-03040 „Foundations and supporting structures for machines” (in Polish)
8. DNV-OS-J101 Design of Offshore WindTurbine Structures
Vehicle Applications," IEEE Transactions on Power Electronics, vol. 28, no. 12, pp. 5477-5488, Dec. 2013.
 D. Vinnikov, I. Roasto, "Quasi-Z-Source-Based Isolated DC/DC Converters for Distributed Power Generation," IEEE Transactions on Industrial Electronics, vol. 58, no. 1, pp. 192-201, Jan. 2011.
 D. Vinnikov, L. Bisenieks, I. Galkin, "New Isolated Interface Converter for PMSG based Variable Speed WindTurbines," Przeglad Elektrotechniczny, vol. 88, no 1a, pp. 75-80, 2012.
 D. Vinnikov, I. Roasto, R. Strzelecki
Elvisa Bećirović, Jakub Osmić, Mirza Kušljugić and Nedjeljko Perić
 HUGHES, F. M.—ANAYA-LARA, O.—JENKINS, N.—STRBAC, G.: Control of DFIG-Based Wind Generation for Power Network Support, IEEE Trans. Power Systems 20 No. 4 (Nov 2005), 1958–1966.
 MORREN, J.—de HAAN, S. W. H.—KLING, W. L.—FERREIRA, J. A.: WindTurbines Emulating Inertia and Supporting Primary Frequency Control, IEEE Trans. Power Systems 21 No. 1 (Feb 2006), 433–434.
 MULJADI, E.—GEVORGIAN, V.—SINGH, M.—SANTOSO, S.: Understanding Inertial and Frequency Response of Wind Power Plants, Preprint, IEEE Symposium on Power Electronics and Machines in Wind
Habib Benbouhenni, Zinelaabidine Boudjema and Abdelkader Belaidi
 A. Medjber, A. Moualdia, A. Mellit, M. A. Guessoum, “ Comparative study between direct and indirect vector control applied to a windturbine equipped with a double-fed asynchronous machine article,” International Journal of Renewable Energy Research, Vol. 3, No. 1, pp. 88-93, 2013.
 K. Kerrouche, A. Mezouar, Kh. Belkacem, “Decoupled control of doubly fed induction generator by vector control for wind energy conversion system,” Energy Procedia, Vol. 42, pp. 239-248, 2013.
 F. Amrane, A. Chaiba, B. Babas, S. Mekhilef, “ Design
Naziha Harrabi, Maher Kharrat, Abdel Aitouche and Mansour Souissi
Babu, N.R. and Arulmozhivarman, P. (2013). Wind energy conversion systems-a technical review, Journal of Engineering Science and Technology 8(4): 493-507.
Blaabjerg, F., Liserre, M. and Ma, K. (2012). Power electronics converters for windturbine systems, IEEE Transactions on Industry Applications 48(2): 708-719.
Boyd, S., El Ghaoui, L., Feron, E. and Balakrishnan, V. (1994). Linear Matrix Inequalities in System and Control Theory, SIAM, Philadelphia, PA.
Camacho, E.F., Samad, T