Difference between revisions of "Optical Communications Team"

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''The principal focus of SSI's Satellites Team is the development of an Optical Communications system and, ultimately, an OpComms satellite. For information on other satellite projects SSI members have worked on, see [[SSI Satellite Projects]].'' <br/> <br/>
 
 
 
{{opcomms-sidebar}}
 
{{opcomms-sidebar}}
 
[[File:SSI-1E4_Small (175x175).png|frame|left|The OpComms Team's longest successful test transmitted a binary signal over a [[SSI-1E4|10km link]]]]
 
[[File:SSI-1E4_Small (175x175).png|frame|left|The OpComms Team's longest successful test transmitted a binary signal over a [[SSI-1E4|10km link]]]]
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Since its inception, the Optical Communications group has evolved to focus on the establishment of long-distance optical links, with the eventual goal of integrating this technology into a CubeSat form-factor satellite for the purposes of space-based communication. In its first year of existence, the group developed a system involving mechanized altitude/azimuth mounts, an original receiver device consisting of a Fresnel lens and photodetector, and a MATLAB pointing algorithm based on reference point alignment. The group’s final test of the 2014-15 year resulted in the successful establishment of an optical lock over [[SSI-1E4|10 kilometers]].
 
Since its inception, the Optical Communications group has evolved to focus on the establishment of long-distance optical links, with the eventual goal of integrating this technology into a CubeSat form-factor satellite for the purposes of space-based communication. In its first year of existence, the group developed a system involving mechanized altitude/azimuth mounts, an original receiver device consisting of a Fresnel lens and photodetector, and a MATLAB pointing algorithm based on reference point alignment. The group’s final test of the 2014-15 year resulted in the successful establishment of an optical lock over [[SSI-1E4|10 kilometers]].
 
The current team leads are [[User:Smaldonado|Sasha Maldonado]] and [[User:Ehillstrom|Elizabeth Hillstrom]].
 
  
 
<noinclude>[[Category:Optical Communications]]</noinclude>
 
<noinclude>[[Category:Optical Communications]]</noinclude>

Revision as of 02:25, 8 July 2016

Optical Communications
Part of the Optical Communications series
Team Goals
Amateur Optical Communication RecordCubeQuest Challenge
Equipment
OpComms System ISystem IISystem IIISystem IV3 cm Board
Noteworthy Tests
SSI-1E4Test Procedure
Important Concepts
The Field of Optical CommunicationsBeam DivergencePulse Position ModulationScintillationPrecision AimingFogLong Range RFOptical Internet BackhaulSignal-to-Noise Ratio
Field Test Locations
W6YX (also see Amateur Radio) • Skyline Boulevard OverlookProposed Alternate OpComms Test Sites
People
Dr. Simone D'Amico (Team Advisor)Elizabeth Hillstrom (Co-Lead)Sasha Maldonado (Co-Lead)Dr. Joseph KahnDr. Leo Hollberg
Optical Communications Satellites
FitSat-1LADEEARTEMIS and SPOT-4OICETSOPALSJPL 1U Optical Communications Terminal
Astronomy
Las Cumbres Observatory Global Telescope NetworkStanford Astronomy ClubStanford Student Observatory
Miscellaneous
Tactical Cinderblock
VE
The OpComms Team's longest successful test transmitted a binary signal over a 10km link

Optical Communications is a student-led project that aims to develop the capability to establish high-bandwidth data links over free space. The group began work at the beginning of the 2014-2015 academic year, under the leadership of Thomas Teisberg and Logan Herrera. It was initially formed to investigate the possibility of space-based optical communications, with the intent to participate in the NASA CubeQuest Challenge, a competition for small satellite design, but has since moved away from the competition design constraints. The OpComms/Satellites Team Faculty Advisor is Dr. Simone D'Amico.

Since its inception, the Optical Communications group has evolved to focus on the establishment of long-distance optical links, with the eventual goal of integrating this technology into a CubeSat form-factor satellite for the purposes of space-based communication. In its first year of existence, the group developed a system involving mechanized altitude/azimuth mounts, an original receiver device consisting of a Fresnel lens and photodetector, and a MATLAB pointing algorithm based on reference point alignment. The group’s final test of the 2014-15 year resulted in the successful establishment of an optical lock over 10 kilometers.