Open resonators, open waveguides and open diffraction gratings are used extensively in modern millimetre and submillimetre technology, spectroscopy and radio engineering. The physical principles of open electrodynamic structures are different from those of closed ones because of radiation loss, edges, multiconnected cross-sections and the need to take into account the behaviour of electromagnetic fields at infinity. The eigenoscillation and eigenwave spectra become complex, there are additional demands on the energy relations and the statements of spectral problems change.

• Part 1: Foundations of spectral theory
• Chapter 1: Spectral theory and excitation of open resonators
• Chapter 2: Excitation of oscillations: physical properties of openresonators
• Chapter 3: Eigenwaves in open waveguides
• Part 2: Eigenoscillations and excitation of open waveguide resonators
• Chapter 4: Qualitative spectra characteristics of open waveguideresonators and the local expansion theorems
• Chapter 5: Solution of spectral problems for open waveguideresonators
• Chapter 6: Free oscillations and resonance excitation of openwaveguide resonators
• Part 3: Spectral theory and excitation of diffraction gratings
• Chapter 7: Diffraction by gratings in the complex frequencydomain
• Chapter 8: Stationary resonance wave scattering by gratings
• Chapter 9: Local excitation of diffraction gratings
• Chapter 10: Intertype oscillations and waves of gratings and theMorse critical points