1: Principles of Planetary Photometry

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Page ID: 7495

Max Fairbairn & Jeremy Tatum
University of Victoria

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1.1: Introduction
1.2: Radiance and the Equation of Transfer
1.3: Diffuse Reflection and Transmission
1.4: Directions and Notation
1.5: Reflectance Functions
1.6: Diffuse Reflection - the Lommel-Seeliger Law
The Lommel-Seeliger reflectance rule is a time-honoured law which is still very much in use today. It is based on a model which is possibly the simplest from which a solution may be readily obtained for the source function and the equation of transfer. As such it is a single scattering model in which the scattering is isotropic.
1.7: Other Reflectance Functions
1.8: Diffuse Reflection and Transmission
1.9: Radiances of Planetary Spheres
We conclude this chapter by applying some of the work covered so far to a planetary situation. We will consider two hypothetical planets idealised as smooth spheres. One planet will have a surface reflecting according to Lambert’s law, the other the Lommel-Seeliger law. The observer is able to resolve both planets equally well, so that we may compare and contrast the distribution of radiance across the projected discs at various phase angles.

Thumbnail: Surface of Mercury (Public Domain; NASA).

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