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| {{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|Mission patch for the Satellites Team's first successful [[SSI-1E4|10km optical link]], which achieved an optical lock]] |
| + | [[File:SSI-1E4-2.png|thumb|175px|left|On a subsequent test, the team was able to bidirectionally encode and decode a string of bits.]] |
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− | 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]]. | + | 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. |
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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 group was able to successfully transmit encoded data over 10 kilometers in August 2015. |
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| <noinclude>[[Category:Optical Communications]]</noinclude> | | <noinclude>[[Category:Optical Communications]]</noinclude> |