Gnss applications  

### Working language Português - Suitable for English-speaking students ### Goals Understand the operating principles of GNSS systems (Global Navigation Satellite Systems). ### Learning outcomes and skills A. Know the characteristics of the current GNSS (Global Navigation Satellite Systems), identify their limitations, and acquire the necessary knowledge to determine positions and speeds. B. Identify and understand issues that may affect GNSS observations and how to overcome them. C. Knowing the advantages, and necessity, of integrating GNSS with other sensors and identifying the most appropriate solutions depending on the type of application and the desired positional accuracy. D. Realize that in science what, for some, is noise, for others, can be a valuable source of data, which allows the acquisition of relevant information for various areas of Earth and Space sciences. ### Working mode In person ### Prerequisites (prior knowledge) and co-requisites (concurrent knowledge) \- Elementary knowledge of Reference Systems \- Orbits ### Program 1\. Introduction to global positioning techniques: evolution and basic concepts, operating principles, types of observables, error sources. two\. Methodologies to eliminate and model errors in the determination of positions and velocities. 3\. GNSS integration with other sensors. Practical examples of application in remote sensing. 4\. Methods for advanced analysis of long series of temporal data. Applications in Geosciences. 5\. Ionosphere: introduction and basic concepts. Influence on the accuracy of GNSS measurements. Use of GNSS data to characterize the state of the ionosphere and identify disturbances. 6\. Reflected signals: applications of GNSS reflectometry. ### Mandatory Bibliography Sanz Subirana Jaume; [GNSS data processing](http://catalogo.up.pt/F/-?func=find-b&local_base=FCUP&find_code=SYS&request=000296749 "GNSS data processing (Opens in a new window)"). ISBN: 978-92-9221-886-7 ### Complementary Bibliography Groves Paul D.; [Principles of GNSS, inertial, and multisensor integrated navigation systems](http://catalogo.up.pt/F/-?func=find-b&local_base=FCUP&find_code=SYS&request=000291643 "Principles of GNSS, inertial, and multisensor integrated navigation systems (Opens in a new window)"). ISBN: 978-1-58053-244-6 ### Teaching methods and learning activities Classes include theoretical exposition but also oral presentations by students. Students must write and deliver a report corresponding to the work they have presented. ### Type of evaluation Distributed evaluation with final exam ### Assessment Components Presentation/discussion of a scientific work: 20.00% Exam: 80.00% **Total:**: 100.00% ### Occupation Components Frequency of classes: 21.00 Hours Self-study: 40.00 hours Laboratory work: 20.00 hours **Total:**: 81.00 ### Get Frequency Students cannot exceed the maximum number of absences from theoretical-practical classes, in accordance with the legislation in force at FCUP: ### Final classification calculation formula The final classification (EF) results from the performance in the Theoretical Exam (ET) and Presentations and Reports (AR) The final classification will be: CF= ET \*0.8 + AR\*0.2 Minimum: 50% in the written exam and 50% in the Presentations and Report NOTE: Classification superior to 15 points in the theoretical exam will only be attributed after carrying out a complementary oral test. More information at: https://sigarra.up.pt/fcup/pt/ucurr_geral.ficha_uc_view?pv_ocorrencia_id=479386
Presential
English
Gnss applications
English

Funded by the European Union. Views and opinions expressed are however those of the author(s) only and do not necessarily reflect those of the European Union or HaDEA. Neither the European Union nor the granting authority can be held responsible for them. The statements made herein do not necessarily have the consent or agreement of the ASTRAIOS Consortium. These represent the opinion and findings of the author(s).