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= Balloons =
 
= Balloons =
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'''Note: the below listing is no longer maintained and is out of date. Please see the [[Balloons]] page for an updated list.'''
    
== HABMC ==
 
== HABMC ==
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== ValBal ==
 
== ValBal ==
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'''Note: the below project is no longer active in SSI. Please see the [[Balloons]] page for an updated list of projects.'''
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ValBal (Valve and Ballast), is a world record-breaking high-altitude balloon payload that autonomously maintains a set altitude for days of flight by venting helium gas and dropping ballast. If you are interested in MechE, EE, CS, Physics, or even MatSci or ChemE, there's a place for you on the ValBal team!
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*MechE -- '''Lead: Paige Brown'''
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ValBal's current design is a 3 part 3D printed nylon structure that uses motors to vent helium gas directly from the balloon neck, cut down the payload in the event of an emergency, and turn a wheel to dispense bb pellets as ballast from a lower compartment. The structure supports, at its heart, the avionics, which powers and control the motors and sensors. Contact {{slack-user|paigebrown}} if you're interested in:
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**Computer Aided Design (CAD) in SolidWorks
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**3D printing
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**Messing with dry ice
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**Laser cutting
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**Random jank manufacturing tricks
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**and everything else that goes into making ValBal mechanics run smoothly
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*EE -- '''Lead: Aria Tedjarati'''
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ValBal’s current electrical system consists of two compact, low-cost, 4 layer printed circuit boards with a custom avionics platform and a prototype digital radio communication link.  The avionics consist of a multitude of sensors, a GPS, a two-way satellite communications system, motor drivers, power regulation, an embedded micro-controller, and much, much more!  The digital radio system consists of a 433 MHz GFSK modulated, Reed-Solomon error corrected link that has been proven to reach ranges of 200 km at data-rates significantly greater than that of the Iridium constellation at 1/5th of the power consumption and 1/20th the cost.  There are a multitude of ways to join the electrical engineering aspect of ValBal, so if any of this stuff interests you, join! Contact {{slack-user|ariatedjarati}} for more information.
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*CS -- '''Lead: Davy Ragland'''
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With ValBal CS, you will learn how to design and build robust, reliable, and flight critical embedded systems code. Since we cannot simply patch the firmware when it is flying, and if something goes wrong we could literally crash, we have to model our system in a way that accounts for complex states, edge cases, and emergent properties. From smart subsystem rebooting to bidirectional comms with parameter tuning, and from a multitude of flight modes to heavily optimized processor and memory behavior, ValBal is the perfect place to hone your skills building something that not only works, but works to industry standards.
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Contact {{slack-user|dragland}} to get involved!
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*Physics -- As a physics major, there are plenty of opportunities for you to work on ValBal. It is an insanely complex system; the flight dynamics are not yet completely understood and require simulating atmospheric and thermal effects. Good models are critical to create a good controller, another key component to ValBal that limits our possible endurance. At the same time, you can help with the design of the payload itself, considering how to optimize it for the harsh environment and coming up with good designs. Contact {{slack-user|jcreus}} for more inforation and a good dose of jank.
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*MatSci/ChemE -- '''Lead: Paige Brown'''
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ValBal has a '''fatal problem''': latex balloons are quickly weakened by UV radiation and ozone at high altitudes, leading to mission ending failure in just a few days. If this sounds like an interesting problem to you, and you want to be an integral part of helping us circumnavigate the world someday, come help us figure out how to strengthen or alter the latex balloon with s c i e n c e. Contact {{slack-user|paigebrown}} if you're interested!
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== HABEES ==
 
== HABEES ==
HABEES (High Altitude Balloon Electrical Engineering Systems) is the the umbrella project for all EE & CS projects outside of ValBal (that is, largely oriented at standard profile balloon launches). Because of this, there is a nearly limitless number of possibilities and projects to pursue within HABEES -- with that said, if you're new to EE or CS, or a veteran, and just generally want some ideas of what you can make, here's a bunch! Contact {{slack-user|kirillsafin}} to discuss working on any of these!
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'''Note: the below project is no longer active in SSI. Please see the [[Balloons]] page for an updated list of projects.'''
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HABEES (High Altitude Balloon Electrical Engineering Systems) is the umbrella project for all EE & CS projects outside of ValBal (that is, largely oriented at standard profile balloon launches). Because of this, there is a nearly limitless number of possibilities and projects to pursue within HABEES -- with that said, if you're new to EE or CS, or a veteran, and just generally want some ideas of what you can make, here's a bunch! Contact {{slack-user|kirillsafin}} to discuss working on any of these!
    
* HONEY EE -- the primary electronics in HABEES revolve around the HONEY architecture. If you're interested in EE, you can test circuits and/or make PCB's for this architecture and have it fly with other boards. Head over to the [[Gen_2_Architecture | HONEY]] page to understand more about it. Below are some project ideas for circuits/boards you can make for HONEY!
 
* HONEY EE -- the primary electronics in HABEES revolve around the HONEY architecture. If you're interested in EE, you can test circuits and/or make PCB's for this architecture and have it fly with other boards. Head over to the [[Gen_2_Architecture | HONEY]] page to understand more about it. Below are some project ideas for circuits/boards you can make for HONEY!
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== BUZZ ==
 
== BUZZ ==
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'''Note: the below project is no longer active in SSI. Please see the [[Balloons]] page for an updated list of projects.'''
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BUZZ is the umbrella subteam for balloons radio projects. It operated as part of HABEES, and works to develop/try/test new radio technologies within balloons. ValBal also develops independent and system-specific radio systems. Some ideas for possible projects, as well as ongoing projects, are below: Talk to {{slack-user|kirillsafin}} and {{slack-user|ariatedjarati}} about them!
 
BUZZ is the umbrella subteam for balloons radio projects. It operated as part of HABEES, and works to develop/try/test new radio technologies within balloons. ValBal also develops independent and system-specific radio systems. Some ideas for possible projects, as well as ongoing projects, are below: Talk to {{slack-user|kirillsafin}} and {{slack-user|ariatedjarati}} about them!
 
* Improved ATV link quality
 
* Improved ATV link quality
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= Rockets =
 
= Rockets =
== Onboarding ==
      
== Daedalus ==
 
== Daedalus ==
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== Competition (IREC/SA Cup) ==
 
== Competition (IREC/SA Cup) ==
* Structures
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* Structures, '''Lead: Will'''
* Payload
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** Design and test all airframe hardware
* Recovery
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** Design and build tools for integration of the rocket
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** Ensure all subsystems are designed and build to correct dimensions
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* Payload, '''Lead: WANTED'''
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** Design and execute an interesting research project of your choice
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** Design a payload of 8.8lbs to be carried to 30,000ft
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* Recovery, '''Lead: Saylor'''
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** Design and sew a parachute and test it to confirm its Coefficient of Drag
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** Design and test a deployment mechanism for our rocket
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** Ensure our rocket comes down in one piece
 
* Avionics, '''Leads: Sharon, Julea''' {{slack-user|splatt}} {{slack-user|juleachin}}
 
* Avionics, '''Leads: Sharon, Julea''' {{slack-user|splatt}} {{slack-user|juleachin}}
 
** Design, implement, and test all the hardware and software that goes into our flight computers
 
** Design, implement, and test all the hardware and software that goes into our flight computers
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** Design and test radio communications system for our rocket to talk to the ground  
 
** Design and test radio communications system for our rocket to talk to the ground  
 
** Write software to parse and visualize data, build a protective cooling case for laptops & other electronics so they don't die in the blazing desert heat and dust (yes there's a story here)
 
** Write software to parse and visualize data, build a protective cooling case for laptops & other electronics so they don't die in the blazing desert heat and dust (yes there's a story here)
* Launch Operations, '''Lead: WANTED'''
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* Launch Operations, '''Lead: Tylor Jilk'''
 
** Work with each subteam to coordinate and prepare launch materials
 
** Work with each subteam to coordinate and prepare launch materials
 
** Plan & execute travel and launch logistics  
 
** Plan & execute travel and launch logistics  
 
** Oversee launch procedures, checklists, and go/no calls
 
** Oversee launch procedures, checklists, and go/no calls
 
** Many more additional projects for ground support designable around personal interests
 
** Many more additional projects for ground support designable around personal interests
* Simulations
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* Simulations, '''Lead: Ruqayya'''
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** Develop computer simulations to predict the flight path of our rocket
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** Inform the decision making of the team with analysis of motors, weights and design
    
= Satellites =
 
= Satellites =
=== STAR-CROSSED===
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The Stanford Timing And Ranging –Cross-linking Optical Small Satellite Demonstration mission is an ambitious proposal seeking to place two cubesats in low Earth orbit and establish a laser-based data link between them across hundreds of kilometers. Such a mission has never before been attempted. If successful, the technology developed will enable a dramatic leap forward in the capabilities of both cubesats and larger satellitesto communicate high volumes of data across long distances.
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Optical links using lasers are capable of dramatically higher data transmission speeds than existing radio systems, but have never been successfully demonstrated at the cubesat scale. A cubesat-sized optical communications system willenable high-speed links between cubesats, allowing for networks built from affordable satellites.Miniaturizing an optical communications system to fit in a cubesat would also make it far easier for larger satellites to add optical networking capabilities, an almost essential component of proposed internet satellite constellations.
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Satellites with optical links can not only transmit data faster, but also better synchronize their timekeeping with each other and measure their separation distance, important features of boththe GPS system and groups of scientific satellites. With an optical network, satellites could conduct previously impossible scientific missions and significantly improve the accuracy of GPS
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Now is the perfect time to get involved with STAR-CROSSD. A number of subsystems need to be analyzed, designed, built, and tested, with opportunities to learn about electrical, mechanical, and software engineering, satellite operations, and more.
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=== POINTR ===
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Polar Orbiting INfrared Tracking Receiver (POINTR) has been Satellites’ primary focus since February. POINTR is an in flight demonstration of an optical receiver pointing, acquisition and tracking (PAT) system. The optical receiver payload hosted on Audacy’s 3U cubesat would be pointed to the ground to acquire and track a beacon laser sent from a suitable ground facility, currently proposed as NASA JPL’s OCTL facility. This mission would demonstrate the operational and technical requirements related to two satellites establishing an optical communications link with each other. The requirements include mission planning, command and execution of a pointing maneuver, acquisition of an incoming optical signal and tracking of the optical signal. This mission can be broken into four main goals:
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* Demonstrate a subset of technology for full bidirectional optical communications mission within the constraints placed by Audacy’s primary mission.
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===🌲🛰Sequoia 🛰🌲===
 
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We are build a small satellite for earth observation and machine learning. Check out our page for more info! [[Satellites]]
* Increase chance of bidirectional optical communications mission success.
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* Develop experience within SSI designing and building space hardware.
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* Contribute to the cubesat and satellite optical communications technical fields.
      
=== Our Subteams ===
 
=== Our Subteams ===
* '''Avoinics'''
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* '''Avionics'''
**'''The Jist'''The Avionics group works on all of the core electrical systems for the Satellites team, including electrical power distribution, sensors, and computing. Learn how to design and reflow Printed Circuit Boards (PCBs) and work with signal-processing to understand light signals in the inky darkness of space!  
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**'''The Gist'''The Avionics group works on all of the core electrical systems for the Satellites team, including electrical power distribution, sensors, and computing. Learn how to design and reflow Printed Circuit Boards (PCBs) and work with signal-processing to understand light signals in the inky darkness of space!  
***'''The People To Talk to''' Sasha, Shi, Meera
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**'''The People To Talk to''' {{slack-user|}}[https://ssi-teams.slack.com/messages/Akasha Akasha], {{slack-user|}}[https://app.slack.com/client/T04HYQ78L/DPXT9NFJ8/details/top Ian]
    
* '''GNC'''
 
* '''GNC'''
**'''The Jist''' The GNC group ("Guidance, Navigation, and Control") is responsible for determining and controlling the position and rotation of satellites in space even while hundreds or sometimes thousands of miles away. Join GNC to work with us on cutting-edge technologies and a system to control our satellites in orbit from the comfort of the SSI space bunker.
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**'''The Gist''' The GNC group ("Guidance, Navigation, and Control") is responsible for determining and controlling the position and rotation of satellites in space even while hundreds or sometimes thousands of miles away. Join GNC to work with us on cutting-edge technologies and a system to control our satellites in orbit from the comfort of the SSI space bunker.
**'''The People To Talk to''' Sasha
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**'''The People To Talk to''' Alec, Rodrigo
 
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* '''Optics'''
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**'''The Jist''' Optics is all about putting light to work - starting from simple laser pointers to finally sending a communications signal across 10 kilometers in space! We use lasers, lenses, filters, sensors and even moving mirrors to send light flying through space and catch it on the other side.
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**'''The People To Talk to''' Michael Taylor
      
* '''Software'''
 
* '''Software'''
**'''The Jist''' The software team tackles the many different challenges of software needed for satellites: from flight software to web development, we do it all. For flight software, we take advantage of parallel communications modules to manage real-time requirements on pointing control. For web development, we are partnering with the ground operations team to build thorough mission control software and web interface. If any of this seems daunting or complicated, don’t worry. We all started from scratch. Join software and get your code in space!
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**'''The Gist''' The software team tackles the many different challenges of software needed for satellites: from flight software to web development, we do it all. For flight software, we take advantage of parallel communications modules to manage real-time requirements on pointing control. For web development, we are partnering with the ground operations team to build thorough mission control software and web interface. If any of this seems daunting or complicated, don’t worry. We all started from scratch. Join software and get your code in space!
**'''The People To Talk to''' Orien, Joan
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**'''The People To Talk to''' Moritz, Langston
 
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* '''Ground Ops'''
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**'''The Jist''' The Ground Operations team will build mission control software and web interface to analyze satellite behavior in-flight and react accordingly. Aside from software, physics and orbital mechanics are crucial parts of this team’s ability. This team is responsible for testing spacecraft stability, fault tolerance, and final mission success.
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**'''The People To Talk to''' Orien
      
*'''Structures'''
 
*'''Structures'''
**'''The Jist''' The Structures team designs and builds all necessary flight mechanics, ranging from the overall structure to individual component mounts. We go through the full development process - whiteboard drawings, SolidWorks, and finally manufacturing.The Structures team is also responsible for many of the environmental considerations, such as the thermal and vacuum requirements of space, as well as the shock and vibration profile of launch.
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**'''The Gist''' The Structures team designs and builds all necessary flight mechanics, ranging from the overall structure to individual component mounts. We go through the full development process - whiteboard drawings, Fusion 360, and finally manufacturing. The Structures team is also responsible for many of the environmental considerations, such as the thermal and vacuum requirements of space, as well as the shock and vibration profile of launch.
**'''The People To Talk to''' Anjali, Sandip
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**'''The People To Talk to''' Connor, TaNia
    
= Biology =
 
= Biology =
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* Enzymatic DNA Synthesis Methods, '''Lead: Michael Uttmark''' {{slack-user|uttmark}}
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== Enzymatic DNA Synthesis Methods ==
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'''Lead: Michael Uttmark''' {{slack-user|uttmark}}
 
** Test commercial blocking groups for compatibility with [[Terminal Deoxynucleotidyl Transferase]]
 
** Test commercial blocking groups for compatibility with [[Terminal Deoxynucleotidyl Transferase]]
 
** Chemically synthesize nucleotides with different reversible blocking groups
 
** Chemically synthesize nucleotides with different reversible blocking groups
 
** Characterize and optimize [[Enzymatic Synthesis Methods | enzymatic DNA synthesis]] reaction efficiency
 
** Characterize and optimize [[Enzymatic Synthesis Methods | enzymatic DNA synthesis]] reaction efficiency
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** Build and run stochastic computer models of DNA synthesis to optimize reaction parameters
 
** Research purification methods for synthesized DNA  
 
** Research purification methods for synthesized DNA  
 
** Design and test your own synthesis method!
 
** Design and test your own synthesis method!
* Sequence Verification
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== Sequence Verification ==
 
** Execute and optimize any one of our existing verification procedures--[[Polyacrylamide Gel Electrophoresis]], [[Pyrosequencing]], or [[Ligation and Sequencing]]
 
** Execute and optimize any one of our existing verification procedures--[[Polyacrylamide Gel Electrophoresis]], [[Pyrosequencing]], or [[Ligation and Sequencing]]
 
** Adapt LCMS or MALDI-TOF procedures for detecting single-base addition or determining the sequence of a sample.  
 
** Adapt LCMS or MALDI-TOF procedures for detecting single-base addition or determining the sequence of a sample.  
 
** Come up with new ways to verify single-base addition to a starting strand of DNA
 
** Come up with new ways to verify single-base addition to a starting strand of DNA
* Microfluidic Device Design
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== Microfluidic Device Design ==
 
** Design and program an [[Electrowetting on Dielectric]] microfluidic PCB
 
** Design and program an [[Electrowetting on Dielectric]] microfluidic PCB
 
** Simulate and test how a microfluidic system would work in microgravity
 
** Simulate and test how a microfluidic system would work in microgravity
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** Research and test other automated [https://en.wikipedia.org/wiki/Microfluidics fluid handling methods], like [https://en.wikipedia.org/wiki/Acoustic_droplet_ejection acoustic droplet ejection] or [https://en.wikipedia.org/wiki/Optoelectrowetting optoelectrowetting].
 
** Research and test other automated [https://en.wikipedia.org/wiki/Microfluidics fluid handling methods], like [https://en.wikipedia.org/wiki/Acoustic_droplet_ejection acoustic droplet ejection] or [https://en.wikipedia.org/wiki/Optoelectrowetting optoelectrowetting].
 
** Build a system for cooling and temperature control of the device, perhaps using [https://en.wikipedia.org/wiki/Thermoelectric_cooling Peltiers]
 
** Build a system for cooling and temperature control of the device, perhaps using [https://en.wikipedia.org/wiki/Thermoelectric_cooling Peltiers]
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** Write an algorithm to minimize the number of groups of compatible templates needed for the [[Enzymatic Synthesis Methods | exonuclease method]]
 
** Figure out how to power our PCB from a cubesat or other launch vehicle
 
** Figure out how to power our PCB from a cubesat or other launch vehicle
 
** Build testing rigs for DNA synthesis methods that are needed for experiments in lab
 
** Build testing rigs for DNA synthesis methods that are needed for experiments in lab
    
= Policy =
 
= Policy =
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== DC Trip ==
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* Be a lead/co-lead for our DC trip in partnership with Citizens for Space
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== [[SpaceJams]] ==
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* Be a Discussion Lead(s) for a week and do a deep dive on a topic/news article of your choice
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== Your Project Here ==
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* Message {{slack-user|rebeccawong}} and let's chat about what you're interested in doing!
    
= Operations =
 
= Operations =
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* Plan and run general community events like Trivia Night, Pathfinder, and Movie Night
 
* Plan and run general community events like Trivia Night, Pathfinder, and Movie Night
 
== Diversity ==
 
== Diversity ==
* Build connections with engineering diversity groups on campus
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* Find diverse speakers to bring to campus
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* Organize diversity mixers (including with other engineering groups)
 
* Help {{slack-user|ruqayyatoorawa}} run workshops
 
* Help {{slack-user|ruqayyatoorawa}} run workshops
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== Events ==
 
== Events ==
 
* Find an interesting company and arrange a tour or talk
 
* Find an interesting company and arrange a tour or talk

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