NOVEMBER1954 American Telephone and Telegraph Company n u m b e r G Copyright, Waveguide as a Communication Medium (Manuscript received March 23, 1954) By S. E.
A waveguide avalanche photodiode with a gain-bandwidth product of 320GHz has been demonstrated.
For many years, waveguide bends for most microwave installations have been difficult and expensive to produce.
An understanding of microwave breakdown in gases has existed for many years 1,2 and has been successfully applied to the design of many high-power microwave systems operating at low duty cycles wit
Heavy metal halide glass fibers have the potential of 0.001- 0.01 dB/km optical loss in the 2-10 micron region.
The rapid growth of single-mode optical fiber transmission since the printing of the first edition of this book has been nothing short of explosive.
We will discuss optical devices based on waveguide grating routers (also called PHASARs or AWGs) in silica, silicon, and indium-phosphide waveguides.
A high-speed waveguide In0.53Ga0.47As-In-0.52 Al0.48As Separate absorption, charge, and multiplication avalanche photodiode suitable for operation at 1.55 mu m has been demonstrated.
A novel infrared photodetector structure is proposed.
We present selectively grown Ge p-i-n photodetectors coupled to high index contrast Si(core)/SiO2(cladding) waveguides on a silicon-on-insulator (SOI) platform.
Explore more
Video
AI-enhance wireless reliability: joint source and channel coding for robust 6G air interface
Blog
Blog
Podcast