The%20HASP%20Program%20for%20Student%20Built%20Aerospace%20Experiments - PowerPoint PPT Presentation

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The%20HASP%20Program%20for%20Student%20Built%20Aerospace%20Experiments

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Programs in this series. Louisiana Aerospace Catalyst Experiences ... Mentor institutions during academic year. New start next summer, proposal pending at NSF ... – PowerPoint PPT presentation

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Title: The%20HASP%20Program%20for%20Student%20Built%20Aerospace%20Experiments


1
The HASP Program for Student Built Aerospace
Experiments
  • T.G. Guzik and J. P. Wefel
  • Dept. of Physics Astronomy and Louisiana Space
    Consortium, Louisiana State University, Baton
    Rouge, LA U.S.A.

2
The Primary Problem
  • How do we get from

3
Programs in this series
  • Louisiana Aerospace Catalyst Experiences for
    Students (LaACES)
  • Entry level uses small payloads (500 g) with
    sounding balloon vehicle
  • 2006-2007 is the fourth year of operation
  • LSU (10 students, extramural), UNO (5 students,
    one credit), LaTech (11 students, laboratory
    course), McNeese (6 students, extramural), SU (4
    students, extramural)
  • Physics Aerospace Catalyst Experiences for
    Students (PACER)
  • Focus on establishing LaACES-like programs at
    HBCU institutions
  • Bring teams to LSU for 9-week intensive summer
    workshop
  • Mentor institutions during academic year
  • New start next summer, proposal pending at NSF
  • High Altitude Student Platform (HASP)
  • For advanced undergraduates and graduates
  • Support student thesis projects
  • Developed here with support from BOR, LaSPACE,
    Department, and College

4
Build Practical Research Skills
  • First need to establish the technical skills
  • Semi-formal Student Ballooning Course guides
    this process
  • 33 lectures in electronics, programming, design
    and management
  • 33 hands-on activities illustrate all the basic
    concepts
  • Takes place over fall semester
  • Next need to apply these skills
  • Develop an experiment from scratch
  • Must have real science content
  • no cockroaches allowed!
  • Go through all project phases
  • design, development, fabrication, testing,
    operation
  • Series of reviews (written and oral) check
    progress
  • Takes place over spring semester
  • Science results presented after flight
  • Skills apply to all S E research fields.

5
Major HASP Features
  • Support flight test up to 12 student built
    payloads
  • Eight small payloads lt 1 kg four large payloads
    lt 10 kg
  • Fly to an altitude gt 36 km for a duration of 20
    hours
  • Provide payloads with serial uplink/downlink,
    discretes, 28 VDC power, analog downlink
  • Downlink available in near real time
  • Include CosmoCam for real time video during
    launch flight
  • NASA partnership supports three flights
  • First flight September 4, 2006
  • Two more flights, once a year

6
Student Payload Interface
  • Small and large versions are identical except for
    size
  • Base is 6 mm thick PVC plate with bolt hole in
    each corner for mounting plate to HASP
  • DB9 connector provides RS-232 serial
    communication
  • EDAC 516 connector provides 28 VDC power, two
    analog downlink channels and two discrete command
    channels
  • Serial connection provides two way real time
    communication
  • Downlink at up to 4800 baud
  • Uplink serial commands to student payload
  • Mounting plate with wiring pigtail and document
    provided to each student payload group
  • Students can mount and wire as they please within
    the allowed region
  • HASP wiring harness attaches to connectors and
    plate is bolted to frame during integration
  • Small version for 15 cm x 15 cm (footprint) x 30
    cm (tall), 1 kg payloads
  • Large version for 38 cm x 38 cm (footprint) x 30
    cm (tall), 10 kg payloads

7
Fly out of Ft. Sumner NM
8
On-site Assembly Testing
9
Launch Day Sept 4, 2006
10
HASP Launched at 1551 UTC
11
18 hour flight, 15 at float
12
Little damage on recovery
13
Student Payloads
  • This year HASP flew 8 student payloads from 4
    institutions and students are in the early stages
    of analyzing their results.
  • University of Alabama Huntsville
  • Infrared telescopes to remotely study the thermal
    characteristics of the balloon envelope (4 small
    payloads)
  • Texas A M University
  • Video camera system to study remote sensing from
    high altitude (1 small)
  • University of Louisiana Lafayette
  • Nuclear emulsion stack to investigate high energy
    cosmic rays (1 large)
  • Louisiana State University (Mechanical Eng.)
  • Study the flow characteristics of various rocket
    nozzles as a function of altitude (1 large
    payload)
  • Louisiana State University (Physics)
  • Prototype of an accelerometer based inertial
    navigation system (1 small)

14
Very preliminary results
15
Call for Payloads 2006-2007
  • Next HASP flight scheduled for Sept. 2007
  • Student teams need to submit applications by Dec.
    15, 2006
  • CFP document and application materials is
    available on the Participant Info tab of the
    HASP website -- http//laspace.lsu.edu/hasp/Parti
    cipantinfo.html
  • Would also highly recommend downloading and
    reading the other documents referenced on this
    page
  • Provide background information and details that
    will help your students design a successful HASP
    payload.
  • HASP Student Payload Interface Document
  • Balloon Flight Users Handbook (CSBF website)
  • Gondola Design (CSBF website)

16
Application Structure
  • The application should include at least the
    following sections
  • Cover sheet Form is provided in the CFP as well
    as a separate link on the HASP website to a MS
    Word version. Includes title, abstract and
    contact information
  • Payload Description One or two page summary of
    the scientific objective, a high level systems
    description and a description of the principle of
    operation of the experiment.
  • Management Who is involved in the team, how the
    team is structured and managed, organization
    chart, preliminary timeline leading to HASP
    integration and flight, how many personnel will
    be involved in integration and flightline
    operations.
  • Payload Specifications Detail HASP resources
    (weight, dimensions, telemetry, commanding,
    power) required by the experiment, procedures for
    integration and flight operations.
  • Drawings Dimensioned drawings of the payload,
    structure, payload plate modifications, payload
    orientation and location
  • No budget is required as we will not be
    distributing any direct support funds.
  • Use standard 12 pt font and at least 1 margins,
    but otherwise there is no limit on the number of
    pages, appendixes, figures, or tables.

17
Submission Instructions
  • E-mail PDF version of application to
  • guzik_at_phunds.phys.lsu.edu
  • Mail hardcopy of application to
  • T. Gregory Guzik
  • Department of Physics Astronomy
  • Louisiana State University
  • Baton Rouge, LA 70803-4001
  • Applications will be reviewed by HASP Management
    at LSU and the NASA Balloon Program Office
  • Applications will be reviewed for completeness,
    consistency, scientific or technical
    justification, and ability to fit within the HASP
    constraints
  • Priority will be given to payloads that are
    clearly designed, built, managed and operated by
    students
  • Decisions will be announced by January 15, 2007

18
Flight Requirements
  • Successful applications will still need to
    satisfy particular requirements.
  • Integration Plan Due June 1 this document
    provides technical details about all payload
    interfaces and integration test procedures
    including a schedule and identifying personnel
    participating in integration. (Provided by
    student team)
  • Integration Certification At integration all
    interfaces will be documented and validated,
    correct operation of the payload will be
    verified, and any issues identified will be
    detailed. (Provided by HASP following
    integration)
  • Flight Operation Plan Due at integration this
    document details procedures for flightline setup,
    pre-launch checkout, flight operations and
    payload recovery including a schedule and
    identifying personnel participating in flight
    operations. (Provided by student team)
  • Science Report Due in December following the
    flight this report provides analysis of the
    student payload flight and science / technical
    results from the flight. (Provided by student
    team)
  • The Integration Plan, Integration Certification
    and Flight Operation Plan will need to be signed
    off by HASP prior to the flight
  • The Science Report will be required prior to
    submitting an application for a follow-on HASP
    flight.

19
Summary
  • The first flight of HASP was very successful
  • System was assembled, tested and flight ready
    about one week
  • 18 hours from launch to landing, 15 hours at
    altitudes gt 110,000 feet
  • No glitches in telemetry and commanding
    throughout the flight
  • Thermal performance exceeded expectations (e.g.
    battery temp remained above 10o C for most of the
    flight)
  • Student payload data, HASP housekeeping and
    position / altitude information was available in
    real-time on the HASP website
  • Only very minor damage upon landing
  • Yearly flights will support timely student
    payload development
  • NASA BPO continuing support at least for the next
    two flights
  • Anticipate continuing support if sufficient
    demand is shown
  • Further information and updates can be found at
    the HASP website at http//laspace.lsu.edu/HASP/
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