Satellite Communications Systems Engineering: Atmospheric Effects, Satellite Link Design And System VERIFIED
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Focuses on the important basic principles that are unique and timeless to satellite-based communications delivery systems The first edition of Satellite Communications Systems Engineering (Wiley, 2008) was written for those concerned with the design and performance of satellite communications systems employed in fixed point-to-point, broadcasting, mobile, radio navigation, data relay, computer communications, and related satellite-based applications. The rapid growth in satellite communications created a need for accurate information on both satellite communications systems engineering and the impact of atmospheric effects on satellite link design and system performance. It addressed that need for the first time in a single comprehensive source. This welcome second edition continues the basic premise and enhances the publication with the latest updated information and new technologies developed since the publication of the first edition. More in-depth treatments are included for the mobile satellite channel, satellite signal processing, on-board processing satellites, satellite orbits, transmission impairments, and propagation effects modeling and prediction. New chapters include interference mitigation in satellite communications, spectrum management for satellite communications, and high throughput satellites (HTS). Many of the updated tools and calculations are provided in a \\\"handbook\\\" form, with step-by-step procedures and all necessary algorithms in one place to allow direct calculations from one source. The book is based on graduate level satellite communications course material and has served as the primary text for electrical engineering Masters and Doctoral-level courses in satellite communications and related areas. Introductory to advanced level engineering students in electrical, communications and wireless network courses, and electrical engineers, communications engineers, systems engineers, and wireless network engineers looking for a refresher will find this essential text invaluable.
The first edition of Satellite Communications Systems Engineering (Wiley 2008) was written for those concerned with the design and performance of satellite communications systems employed in fixed point to point, broadcasting, mobile, radio navigation, data relay, computer communications, and related satellite based applications. This welcome Second Edition continues the basic premise and enhances the publication with the latest updated information and new technologies developed since the publication of the first edition. The book is based on graduate level satellite communications course material and has served as the primary text for electrical engineering Masters and Doctoral level courses in satellite communications and related areas. Introductory to advanced engineering level students in electrical, communications and wireless network courses, and electrical engineers, communications engineers, systems engineers, and wireless network engineers looking for a refresher will find this essential text invaluable.
This book will serve as an excellent reference to communications engineers, wireless network and system engineers, system designers and graduate students in satellite communications and related areas.
Dr. Louis Ippolito, over a brilliant career has done it all. He's carried out satellite research at NASA, designed satellite systems for the aerospace industry, and taught satellite engineering at The George Washington University. Now, in a comprehensive and highly readable book, he has encapsulated his knowledge in clear and quite intelligent form. His completely up-to-date book covers the latest innovations that range from mobile satellites to millimeter wave satellites and associated rain fade mitigation technologies. His chapters on propagation effects modeling and prediction, RF transmission impairments and link systems performance are truly outstanding. If you want to understand satellite communications and RF propagation, you need Dr. Ippolito's book.
The first edition of Satellite Communications Systems Engineering (Wiley, 2008) was written for those concerned with the design and performance of satellite communications systems employed in fixed point-to-point, broadcasting, mobile, radio navigation, data relay, computer communications, and related satellite-based applications. The rapid growth in satellite communications created a need for accurate information on both satellite communications systems engineering and the impact of atmospheric effects on satellite link design and system performance. It addressed that need for the first time in a single comprehensive source.
The book is based on graduate level satellite communications course material and has served as the primary text for electrical engineering Masters and Doctoral-level courses in satellite communications and related areas. Introductory to advanced level engineering students in electrical, communications and wireless network courses, and electrical engineers, communications engineers, systems engineers, and wireless network engineers looking for a refresher will find this essential text invaluable.
In this webinar, we introduce new standard-based functionality in MATLAB for modeling, simulation, and testing of satellite communications systems. You can visualize and model satellite orbits and perform link budget analysis and access calculations. You can generate test waveforms based on DVB-S2, DVB-S2X, CCSDS, and GPS standards. You can also design physical layer algorithms together with RF components and ground station receivers. As all this functionality is provided as open MATLAB code, you can modify and customize each function and use them as reference models for implementing satellite communications systems and devices.
KEYWORDS: atmospheric sounding; laser sounding; radar; radiometry; synthetic aperture radar; polarimetry; interferometry; radio occultation; electromagnetic propagation; limnology; seismology; environmental monitoring; remote sensing; surveillance; Russian S&T.TABLE OF CONTENTS: Summary Discussion Site Visits3.1 MOSCOW REGION3.1.1 Institute of Radio Engineering and Electronics3.1.2 Institute of Radio Engineering and Electronics - Fryazino3.1.3 Space Research Institute 3.1.4 VEGA-M Scientific and Production Corporation 3.1.5 Moscow State Technical University of Civil Aviation 3.2 ST. PETERSBURG: 3.2.1 Academy of Civil Aviation3.2.2 Electrotechnical University 3.2.3 St. Petersburg State Academy of Aerospace Instrumentation3.2.4 Acad. Prof. Dr. Sci. Valery B. Mit'ko3.3 TOMSK, SIBERIA3.3.1 Tomsk State University of Control Systems and Radioelectronics 3.3.2 Institute of Atmospheric Optics 3.4 NOVOSIBIRSK, SIBERIA3.4.1 Institute of Computational Mathematics and Mathematical Geophysics 3.5 IRKUTSK, SIBERIA3.5.1 Limnological Institute 3.5.2 Institute of Solar-Terrestrial Physics 3.6 ULAN-UDE, SIBERIA 3.6.1 Buryat Institute of Natural Sciences Overall Impression / Assessment Feedback1. SUMMARYDescription of travel by Otto Kessler, Associate Director ONR-EUR and by Dr. Wolfgang-M. Boerner, Professor at University of Illinois at Chicago and Distinguished Senior US Navy Scientist, to 14 Russian R&D institutes in 6 cities. These institutes are performing research relevant to polarimetric and interferometric surveillance and sensing theory, metrology and technology. Discussion covered broad capabilities and research specific to applications in area surveillance, target characterization, propagation, and environmental monitoring of surface and atmospheric surroundings. The perspective derived from these visits is that there is widespread capability for good research in radar and radiometry in pursuit of remote sensing. The techniques encompass combinations of moderately high resolution, synthesized apertures, polarimetry, and multispectral or multifrequency measurements. A robust research capability is also present in measurement of propagation effects employing radio occultation and direct path measurements. More general atmospheric probing to measure standard meteorological parameters as well as detection of turbulence, pollutants, and other anomalies is being pursued with diverse techniques, spanning the electromagnetic spectrum: radio occultation, radiometric, and laser techniques. Other observations regarding the general science and technology environment are also included.2. DISCUSSIONA visit to Russia was made for the purpose of exploring research opportunities and capabilities in remote sensing using interferometric and polarimetric techniques. Application to radar was of primary concern although potential use in infrared and radiometric applications was also considered. This report describes visits to institutions in six Russian cities; Moscow, Saint Petersburg, Tomsk, Novosibirsk, Irkutsk, Ulan Ude. Section 3 provides the details of discussions and findings at each location. Section 4 provides overall assessment and related impressions. Details of the travel itinerary will be provided in a separate newsletter and homepage posting. It should be observed that travel within Russia was performed with relative efficiency, only because of the intervention and support of our hosts at each location. Their concern for our well-being and their efforts on our behalf were quite essential and most appreciated. Routine tourism is not yet a fact of Russian life. Two categories of institutions were visited: Universities, with both educational and research functions; and Laboratories with research and equipment design roles under the Soviet regime. All of these institutes are part of or connected with the Russian Academy of Sciences (RAS). While that association lends a measure of credibility to the S&T capability of the organization it should not be interpreted as implying the kind of direction or coordination that might have existed in the past. The general characteristic of all these institutes is that as organizations the