Development of the IANS Chain Using a Satellite System

• Autorzy: Czaplewski K.

Identyfikatory

DOI

10.12716/1001.08.04.02

• Języki publikacji: EN

Abstrakty

EN

This paper presents ideas for creating and developing Interactive Navigational Structures (IANS) by using satellite systems. The author of the present paper introduced the concept of IANS into the literature in 2004 (Czaplewski, 2004). The paper presents the possibility of adapting the contemporary methods of robust estimation that are used in geodesy for the purpose of performing selected marine navigation tasks. IANS utilise modern M-estimation methods. Interactive structures can assist human beings in carrying out special tasks at sea, for example, in identifying objects at sea and on land without the need to approach them. Moreover, these structures can also be used in the process of navigation carried out by underwater vehicles or unmanned watercraft. This paper presents the mathematical methods that are essential for creating IANS. The theoretical assumptions are illustrated with an example of how IANS can be used while performing a typical navigation task. The paper closes with information about research studies which deal with the practical aspects of using this set of mathematical methods.

Słowa kluczowe

EN

Interactive Navigational Structures (IANS); navigational methods; navigation techniques; terrestrial navigation; vessel traffic service (VTS); satellite system; satellite positioning system; differential GPS (DGPS)

• Wydawca: Faculty of Navigation, Gdynia Maritime University
• Czasopismo: TransNav : International Journal on Marine Navigation and Safety of Sea Transportation
• Rocznik: 2014
• Tom: Vol. 8 no. 4
• Strony: 485--493
• Opis fizyczny: Bibliogr. 11 poz., rys., tab.

Twórcy

autor

Czaplewski K.

• Gdynia Maritime University, Gdynia, Poland

Bibliografia

• 1 Baran, W. L. (1999). Teoretyczne podstawy opracowania wyników pomiarów geodezyjnych. PWN, Warsaw, Poland.
• 2 Czaplewski, K. (2004). Pozycjonowanie z wykorzystaniem Interaktywnych Struktur Nawigacyjnych. Wydawnictwo AMW, Gdynia, Poland.
• 3 Czaplewski K. Morgaś W. and Kopacz Z. (2010). National Systems of Safety and Protection of Navigation. Scientific Journal of Maritime University of Szczecin, Szczecin, Poland.
• 4 Czaplewski K. and Wąż M. (2004). The Using of the Neutral Networks and Robust Estimation Methods In Radar Navigation. The Proceedings of 5th Russian Scientific‐ Technical Conference “The Present‐Day State and Problems of Navigation and Oceanography”, pp. 105‐ 115, St. Petersburg, Russia.
• 5 Hampel F. R., Ronchetti E. M., Rousseeuw P.J and Stahel W.A. (1986). Robust Statistics. The Approach Based on Influence Functions. John Wiley & Sons, New York, USA.
• 6 Kopacz Z. and Urbański J. (1998). The Navigation of the Beginning of the 21st Century. Geodezja i Kartografia, no. XLVII, issues 1‐2, pp. 59‐68, Warsaw, Poland.
• 7 Wiśniewski Z. (2002). Koncepcja opracowania wyników pomiarów nawigacyjnych. Wydawnictwo AMW, Gdynia, Poland.
• 8 Wiśniewski Z. (2009). Rachunek Wyrównawczy w Geodezji (z przykładami). Wydawnictwo UWM, Olsztyn, Poland.
• 9 Yang Y. (1994). Robust Estimation for Dependent Observations. Manuscripta Geodaetica, no. 19, Germany.
• 10 YANG Y. (1997). Estimators of Covariance Matrix AT Robust Estimation Based on Influence Functions. ZfV, Helf 4, Germany
• 11 Yang Y., Song L. and Xu T. (2002). Robust Estimator for Correlated Observations Based on Bifactor Equivalent Weights. Journal of Geodesy nr 76, pp 353 – 358, Heidelberg, Germany