Q3/A/We wish to coat a glass surface with an appropriate dielectric layer to provide total transmission from air to the glass at a free-space wavelength of 570 nm. The glass has refractive index n3 = 1.45 . Determine the required index for the coating and its minimum thickness. B/A 150-MHz uniform plane wave is normally incident from air onto a material whose intrinsic impedance is unknown. Measurements yield a standing wave ratio of 3 and the appearance of an electric field minimum at 0.3 wavelengths in front of the interface. Determine the impedance of the unknown material.
Q3/A/We wish to coat a glass surface with an appropriate dielectric layer to provide total transmission from air to the glass at a free-space wavelength of 570 nm. The glass has refractive index n3 = 1.45 . Determine the required index for the coating and its minimum thickness. B/A 150-MHz uniform plane wave is normally incident from air onto a material whose intrinsic impedance is unknown. Measurements yield a standing wave ratio of 3 and the appearance of an electric field minimum at 0.3 wavelengths in front of the interface. Determine the impedance of the unknown material.
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Transcribed Image Text:Q3/A/We wish to coat a glass surface with an appropriate dielectric layer to provide total transmission from
air to the glass at a free-space wavelength of 570 nm. The glass has refractive index n3 = 1.45 .
Determine the required index for the coating and its minimum thickness.
B/A 150-MHz uniform plane wave is normally incident from air onto a material whose intrinsic impedance
is unknown. Measurements yield a standing wave ratio of 3 and the appearance of an electric field
minimum at 0.3 wavelengths in front of the interface. Determine the impedance of the unknown
material.
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