1 / 13

The High Altitude Student Platform (HASP) for Student-Built Payloads

The High Altitude Student Platform (HASP) for Student-Built Payloads. T.G. Guzik and J.P. Wefel Dept. of Physics & Astronomy Louisiana State University Baton Rouge, LA U.S.A. Student-Built Payload Limitations.

nitesh
Download Presentation

The High Altitude Student Platform (HASP) for Student-Built Payloads

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript


  1. The High Altitude Student Platform (HASP) for Student-Built Payloads T.G. Guzik and J.P. Wefel Dept. of Physics & Astronomy Louisiana State University Baton Rouge, LA U.S.A. COSPAR 2004, HASP Presentation

  2. Student-Built Payload Limitations • Many higher education institutions across U.S. are engaging students in design, construction and operation of aerospace payloads (See ACES presentation, this conference) • Small payloads launched on sounding balloons • Compact Earth-orbiting satellites • Development life cycle needs to be limited to one year to conform with student schedule • Feasible with small sounding balloon payloads • Difficult for satellites where launch schedule is uncertain, but could be flight tested on a balloon COSPAR 2004, HASP Presentation

  3. Sounding Balloon Limitations • Sounding balloons have limited “hang time” • Total flight time about 2 ½ hours • Time above 24 km about ½ hour • Inappropriate for testing student-built satellites or new technologies • At most only cursory evaluation of power, data acquisition & telemetry subsystems • No test of day-night thermal cycling COSPAR 2004, HASP Presentation

  4. HASP Addresses These Issues • Support & flight test multiple student built payloads • Altitude > 36 km, duration of ~20 hours • Make use of NASA National Scientific Balloon Facility (NSBF) experience • Provide standard power, data, mechanical interface • Use CubeSat model for design • Developed by Stanford and CalPoly • Size is 10 cm cube • Max weight is 1 kg • Power is ~650 mW COSPAR 2004, HASP Presentation

  5. Configuration & Structure • Core aluminum frame provides platform integrity • Mounting for flight data / control systems • Attachment for swivel harness and ballast hopper • Composite braces to support student payloads COSPAR 2004, HASP Presentation

  6. Concept Student Payload Interface • Mounting plate consistent with CubeSat model • Held at corner beams so faces are unobstructed • Mounting plate includes power & data interface • Can be sent to institution for pre-integration • Alternate mounting is also possible • Specify hole pattern on support braces • Heavier payloads could be mounted on top of Al structure • ICD determined during student payload application COSPAR 2004, HASP Presentation

  7. Weight & Size • HASP dimensions • Core frame is 112 cm (44”) by 91.5 cm (36”) by 51 cm (20”) tall • Student payload braces extend 112 cm away from frame • Total dimensions are, thus, ~3.4 m x 3.2 m x 0.5 m • Weight determined mostly by measured values • Total is 211 kg (465 lbs) COSPAR 2004, HASP Presentation

  8. Command and Control • Heritage from ATIC scientific balloon payload systems • Directly adopt flight proven hardware and software design • Flight Control Unit (FCU) • Handles commands • Monitors power system • Serial link with payloads • Collects status information • Data Archive Unit (DAU) • On-board data recording • LOS transmission of HASP & student payload data to ground at rate up to ~ 300 kilobits per second • NSBF supplied CIP controls balloon systems COSPAR 2004, HASP Presentation

  9. FCU Hardware Flight Control Unit front (left) and back (right) flown on the ATIC-02 experiment from December 29, 2002 to January 18, 2003 COSPAR 2004, HASP Presentation

  10. DAU Hardware Data Archive Unit (left) and Hard Disk Pressure Vessel (right) flown on the ATIC-02 experiment from December 29, 2002 to January 18, 2003 COSPAR 2004, HASP Presentation

  11. Power System • Route 28V buss and convert power locally • Power budget from measured values & includes an 80% efficiency factor • 24 hour lifetime with two 10 cell lithium battery packs COSPAR 2004, HASP Presentation

  12. Anticipated Flight Operations • Flight Ops take place at NSBF or Ft. Sumner • Initially HASP is setup & integrated with NSBF systems • Student payload integration & testing follows • Launch tries to target “turn-around” conditions COSPAR 2004, HASP Presentation

  13. Summary • The High Altitude Student Platform supports advanced student-built payloads • Regular schedule of launches at least once per year • Provide high altitude (~36 km) and reasonable duration (~15 to 20 hours) • Flight test student-built satellite • Fly payloads too heavy for sounding balloons • Existing flight designs and experience minimize cost of development and operation • Hardware / software from flight proven ATIC payload • Use time-tested NSBF balloon vehicle hardware • Capitalize on decades of NSBF experience with flight operations • Could be easily adapted for LDB (~15 – 30 days) flights • Could become major part of Aerospace Workforce Development COSPAR 2004, HASP Presentation

More Related