To more effectively tailor courses involving antennas, wireless communications, optics, and applied electromagnetics to a mixed audience of engineering and physics students, the Friis transmission equation—which quantifies the power received in a free-space communication link—is developed from principles of optical radiometry and scalar diffraction. This approach places more emphasis on the physics and conceptual understanding of the Friis equation than is provided by the traditional derivation based on antenna impedance. Specifically, it shows that the wavelength-squared dependence can be attributed to diffraction at the antenna aperture and illustrates the important difference between the throughput (product of area and solid angle) of a single antenna or telescope and the throughput of a transmitter-receiver pair.
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January 2013
PAPERS|
January 01 2013
Radiometry and the Friis transmission equation
Joseph A. Shaw
Joseph A. Shaw
Department of Electrical & Computer Engineering, Montana State University
, Bozeman, Montana
59717
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Am. J. Phys. 81, 33–37 (2013)
Article history
Received:
July 01 2011
Accepted:
September 13 2012
Citation
Joseph A. Shaw; Radiometry and the Friis transmission equation. Am. J. Phys. 1 January 2013; 81 (1): 33–37. https://doi.org/10.1119/1.4755780
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