Anomaly and change detection in remote sensing

• Autores: José Antonio Padrón Hidalgo
• Directores de la Tesis: Valero Laparra Pérez-Muelas (dir. tes.), Gustavo Camps Valls (codir. tes.)
• Lectura: En la Universitat de València ( España ) en 2021
• Idioma: español
• Tribunal Calificador de la Tesis: Luca Martino (presid.), Julia Amorós López (secret.), Emma Izquierdo Verdiguier (voc.)
• Programa de doctorado: Programa de Doctorado en Ingeniería Electrónica por la Universitat de València (Estudi General)
• Materias:
  • Ciencias de la tierra y del espacio
    • Geología
      • Teledetección (geología)
• Enlaces
  • Tesis en acceso abierto en: webges.uv.es (pdf)
• Resumen

  • Earth observation through satellite sensors, models and in situ measurements provides a way to monitor our planet with unprecedented spatial and temporal resolution. The amount and diversity of the data which is recorded and made available is ever-increasing. This data allows us to perform crop yield prediction, track land-use change such as deforestation, monitor and respond to natural disasters and predict and mitigate climate change. The last two decades have seen a large increase in the application of machine learning algorithms in Earth observation in order to make efficient use of the growing data-stream. Machine learning algorithms, however, are typically model agnostic and too flexible and so end up not respecting fundamental laws of physics. On the other hand there has, in recent years, been an increase in research attempting to embed physics knowledge in machine learning algorithms in order to obtain interpretable and physically meaningful solutions. The main objective of this thesis is to explore different ways of encoding physical knowledge to provide machine learning methods tailored for specific problems in remote sensing.Ways of expressing expert knowledge about the relevant physical systems in remote sensing abound, ranging from simple relations between reflectance indices and biophysical parameters to complex models that compute the radiative transfer of electromagnetic radiation through our atmosphere, and differential equations that explain the dynamics of key parameters. This thesis focuses on inversion problems, emulation of radiative transfer models, and incorporation of the above-mentioned domain knowledge in machine learning algorithms for remote sensing applications. We explore new methods that can optimally model simulated and in-situ data jointly, incorporate differential equations in machine learning algorithms, handle more complex inversion problems and large-scale data, obtain accurate and computationally efficient emulators that are consistent with physical models, and that efficiently perform approximate Bayesian inversion over radiative transfer models.