Orbital Debris Mitigation Safe Disposal Planning Begins at Concept Design

1. Orbital Debris MitigationSafe Disposal Planning Begins at Concept Design Scott Hull Josephine San GSFC Code 591 Systems Engineering Seminar – Orbital Debris Mitigation Scott Hull and Josephine San, 591 October 7, 2003

2. Agenda • Overview of NPD 8710.3 and NSS 1740.14, Scott Hull And Reentry Analysis Basics • GSFC Safe Disposal Planning Josephine San • Design for Demise Examples Scott Hull • Current Status Scott Hull Systems Engineering Seminar – Orbital Debris Mitigation Scott Hull and Josephine San, 591 October 7, 2003

3. Overview of DocumentationAnd Reentry Analysis Basics Scott Hull / 591 NASA/GSFC Systems Engineering Seminar – Orbital Debris Mitigation Scott Hull and Josephine San, 591 October 7, 2003

4. NASA Policy • Debris assessment shall be done for all missions at mission PDR and CDR • Design for safe disposal at the end of the mission • Notify other government agencies when NASA related hardware reenters • Promote international cooperation on debris related issues Systems Engineering Seminar – Orbital Debris Mitigation Scott Hull and Josephine San, 591 October 7, 2003

5. Applicable Documents • NPD 8710.3A • Recently revised • Requires an ODA to be written • Invokes NSS 1740.14 • NSS 1740.14 (to be replaced by NS 8719.14) • Guidelines for debris mitigation • Evaluation instructions • GSFC ISO Documents • Debris Mitigation • Controlled Reentry • Reentry Survivability Systems Engineering Seminar – Orbital Debris Mitigation Scott Hull and Josephine San, 591 October 7, 2003

6. NPD 8710.3A ResponsibilitiesProgram/Project Manager • Ensuring implementation of NSS1740.14 • Ensuring that an ODA has been performed • Coordinating the ODA results with NASA HQ • Ensuring that environmental assessment is performed • Designing for end of mission disposal and submitting an end of mission plan to Code S/Y/U • Communicating with DOD before significant orbit changes Systems Engineering Seminar – Orbital Debris Mitigation Scott Hull and Josephine San, 591 October 7, 2003

7. NPD 8710.3A ResponsibilitiesNASA Headquarters • Code S/Y/U • Approving ODA reports • Reviewing the cost analysis if applicable • Approving the end of mission plan • Code Q • Establishing policies • Providing guidelines and standards • Reviewing ODA reports and end of mission plans • Providing software tools for evaluating orbital debris • Coordinating NASA reentry information within the agency • Code I • Coordinating international agreements • Developing procedures for coordinating information on significant reentries with other US government agencies • Coordinating pre-reentry press releases with the National Security Council and the White House Office of Science and Technology Policy • Code P • Coordinating pre-reentry press releases Systems Engineering Seminar – Orbital Debris Mitigation Scott Hull and Josephine San, 591 October 7, 2003

8. NPD 8710.3A ResponsibilitiesJSC Orbital Debris Program Office • Maintaining the orbital debris environment models • Providing technical guidance on ODA issues • Providing technical review of ODA reports • Reviewing end of mission plans • Providing technical and policy guidance to all NASA HQ offices and centers • Maintaining a list of reentry predictions • Updated every six months • Sent to Code Q • Promoting the use of international guidelines Systems Engineering Seminar – Orbital Debris Mitigation Scott Hull and Josephine San, 591 October 7, 2003

9. Orbital Debris Assessment (ODA)Report Review Process • Program/Project Manager sends report to Code S/Y/U • Code S/Y/U forwards it to Code Q • Code Q forwards it to JSC-ODPO • JSC-ODPO review comments sent back through Code Q to Code S/Y/U • Code S/Y/U Associate Administrator makes the final decision whether to accept the ODA and disposal plans Systems Engineering Seminar – Orbital Debris Mitigation Scott Hull and Josephine San, 591 October 7, 2003

10. What is in an ODA? • Executive Summary • Section 1: Introduction • Section 2: Spacecraft/Mission Description • Section 3: Operational Debris • Section 4: Accidental Explosions and Intentional Breakups • Section 5: On-orbit Collision Risk • Section 6: Postmission Disposal • Section 7: Reentry Survivability • Conclusion Systems Engineering Seminar – Orbital Debris Mitigation Scott Hull and Josephine San, 591 October 7, 2003

11. ODA Conclusions • Assessment was performed per NPD 8710.3A • Overall findings • All applicable guidelines were met • All but X, Y, and Z were met • Table of findings is recommended • Include all guidelines • Indicate whether each is Met, Not Met, or Not Applicable, and any necessary comments • Always include the DCA and casualty odds Systems Engineering Seminar – Orbital Debris Mitigation Scott Hull and Josephine San, 591 October 7, 2003

12. NSS 1740.14 Guidelines • Basically follows the report structure • Report doesn’t necessarily call out all of the guidelines, though • 14 guidelines, 7 sections • Table of findings helps to prevent holes • Most heavily scrutinized are 4-2, 5-1, 5-2, 6-1, 6-4, and 7-1 Systems Engineering Seminar – Orbital Debris Mitigation Scott Hull and Josephine San, 591 October 7, 2003

13. NSS 1740.14 Guideline 4-2 Accidental Explosions Postmission • Risk to other spacecraft • “All on-board sources of stored energy will be depleted when they are no longer required for mission operations or postmission disposal.” Proposed change: Recommendation to perform propellant depletion burns to reduce orbit lifetime. Systems Engineering Seminar – Orbital Debris Mitigation Scott Hull and Josephine San, 591 October 7, 2003

14. NSS 1740.14 Guideline 6-1 Disposal from orbits passing through LEO (choose one) 6-1 a. Atmospheric reentry • Orbit decay < 25 years after end of mission • Uncontrolled reentry • Controlled reentry 6-1 b. Maneuver to a storage orbit Perigee > 2500 km, Apogee < 35,288 km 6-1 c. Direct retrieval Proposed changes: • Orbital lifetime < 30 years • Specific language on controlled reentry • Perigee > 2000 km, Apogee < 35,588 km Systems Engineering Seminar – Orbital Debris Mitigation Scott Hull and Josephine San, 591 October 7, 2003

15. NSS 1740.14 Guideline 6-4 Reliability of Postmission Disposal • Applies to both spacecraft and upper stages • Identify all credible failure modes • Probability of success > 0.99 Proposed change: Reliability of > 0.90 acceptable if not performing controlled reentry. Systems Engineering Seminar – Orbital Debris Mitigation Scott Hull and Josephine San, 591 October 7, 2003

16. NSS 1740.14 Guideline 7-1 • Risk from Surviving Debris • Only applies to atmospheric reentry • Function of spacecraft construction and materials chosen • Debris Casualty Area < 8 m2 • Complex simulation • Proposed changes: Reentry risk < 1 in 10,000 considering inclination and year of reentry; casualty threshold (> 15J) added officially Systems Engineering Seminar – Orbital Debris Mitigation Scott Hull and Josephine San, 591 October 7, 2003

17. Debris Casualty Area (DCA) The DCA is the portion of the Earth surface on which a person is likely to be injured by a piece of falling debris. When an object survives, a 0.3m “man-border” is essentially added to the circumference of the object Systems Engineering Seminar – Orbital Debris Mitigation Scott Hull and Josephine San, 591 October 7, 2003

18. Reentry Process • Atmosphere entry: 122 km altitude • Appendages breakoff • Catastrophic breakup: Typically ~78 km • Some recent evidence for lower breakup on larger spacecraft • Object burnup: Generally ~80 to 55 km • Cooling / survival: Below ~50 km Systems Engineering Seminar – Orbital Debris Mitigation Scott Hull and Josephine San, 591 October 7, 2003

19. Uncontrolled Reentry When? Where? Controlled Reentry Targeted Time & Place Breakup Burnup Land? Water? Ocean Reentry Terms Systems Engineering Seminar – Orbital Debris Mitigation Scott Hull and Josephine San, 591 October 7, 2003

20. Effort Spent on Reentry Simulation Systems Engineering Seminar – Orbital Debris Mitigation Scott Hull and Josephine San, 591 October 7, 2003

21. Component Modeling • Spacecraft components need to be modeled as one of four shapes: Sphere Cylinder Box Flat Plate • Choice is based on preserving surface area and cross-sectional area • Many real components are difficult to model Systems Engineering Seminar – Orbital Debris Mitigation Scott Hull and Josephine San, 591 October 7, 2003

22. Component ModelingExample - Washer • Circular top view resembles cylinder • Side view resembles a box • If tumbling, sweeps out a sphere • If cut and straightened, flat plate results • JSC recommends using a flat plate model Systems Engineering Seminar – Orbital Debris Mitigation Scott Hull and Josephine San, 591 October 7, 2003

23. Ablation • An object is said to have ablated (demised) when it has fully melted • Heat of Ablation HAblat = Mass x [Cp x (Tmelt – T init) + HFusion] • Heat Balance Equation qnet = qconv + qrad + qox – qrr qconv = average aerodynamic heating qrad = gas cap radiation heating qox = oxidation heating qrr = reradiative cooling Systems Engineering Seminar – Orbital Debris Mitigation Scott Hull and Josephine San, 591 October 7, 2003

24. DAS Software Overview • Debris Assessment Software • Written by JSC ODPO • Very useful for evaluating Guidelines 5, 6, and 7 • Current version is 1.5.3 • Stand-alone software • Downloadable from JSC ODPO web site • Web-based interface • Available to to GSFC domains only at this time • Version 2.0 to be released soon Systems Engineering Seminar – Orbital Debris Mitigation Scott Hull and Josephine San, 591 October 7, 2003

25. DAS SoftwareGuideline 7 (slide 1 of 2) • Program Variables • Breakup Altitude • Object Inputs (saved in a text file) • Name, Shape, Dimensions, Mass, Material • Materials Inputs • Only uses Specific Heat, Heat of Fusion, and Melt Temp • Synthetic Materials • Allows an assembly to be modeled with two masses • Aero mass – total mass of the assembly • Thermal mass – mass of the container/ structure Web-interface version accepts inputs from Excel Systems Engineering Seminar – Orbital Debris Mitigation Scott Hull and Josephine San, 591 October 7, 2003

26. DAS SoftwareGuideline 7 (slide 2 of 2) • Evaluation Results • Simulation Output • Repeats input information • Demise Altitude • Debris Casualty Area • DCA Total • Output can be saved or printed • Easy to make small changes and re-run Systems Engineering Seminar – Orbital Debris Mitigation Scott Hull and Josephine San, 591 October 7, 2003

27. ORSAT SoftwareInputs • All contained in one input file per run • Start / Stop altitudes • Parent object shape, dimensions, mass, material, trajectory • Fragment object shapes, dimensions, masses, materials • Separate file for each new material • If three objects with that material, three files Systems Engineering Seminar – Orbital Debris Mitigation Scott Hull and Josephine San, 591 October 7, 2003

28. ORSAT SoftwareInputs • Additional capabilities over DAS • Directly entered thermal masses (sort of) • More detailed analysis • Up to 15 nodes per object • Multiple material layers per object • Oxidation heating, Radiative cooling • Ability to scale heating factors • Parametric studies • Specified trajectory Systems Engineering Seminar – Orbital Debris Mitigation Scott Hull and Josephine San, 591 October 7, 2003

29. ORSAT SoftwareSimulation Routine • Same basic routine as DAS /MORSAT • Five simultaneous modules • Trajectory: velocity and path of the object • Atmosphere: environment around the object • Aerodynamics: drag experienced by the object • Aerothermodynamics: heating of the object • Thermodynamics: response of the object to heat • Continuous calculations at small time intervals • Concludes when object either completely melts or reaches the stop altitude • Software goes on to next object Systems Engineering Seminar – Orbital Debris Mitigation Scott Hull and Josephine San, 591 October 7, 2003

30. ORSAT SoftwareOutputs As many as nine detailed output files:Detailed Output Basic Output Trajectory Detailed Heating Basic Heating AerodynamicsDetailed Temperature Temperature Atmosphere • Any or all can be disabled • Basic Output file information • Time, Altitude, Heating Rate, Demise Factor • If object demises: Demise Altitude • If object survives: Impact Velocity, DCA, Impact Energy, Maximum Demise Factor Systems Engineering Seminar – Orbital Debris Mitigation Scott Hull and Josephine San, 591 October 7, 2003

31. Safe Disposal Planning GSFC Practical Guidelines Josephine San/591 NASA/GSFC Systems Engineering Seminar – Orbital Debris Mitigation Scott Hull and Josephine San, 591 October 7, 2003

32. Practical Guidelines - Content • Objectives • Background • Concept Design Phase – Safe Disposal Planning begins at Concept Design • Preliminary and Critical Design Phases – Design Considerations and Planning to Successfully Achieve Safe Disposal • Operation and End-of-Mission Phases – Implementation of End-of-Mission Plan Systems Engineering Seminar – Orbital Debris Mitigation Scott Hull and Josephine San, 591 October 7, 2003

33. Objectives and Bases • Objectives • To Provide Practical Guidance in Compliance With NPD 8710.3 and NSS 1740.14 (to Be NASA Standard 8719.14) • To Assist Projects and Engineers in the Planning of Safe Disposal • To Prevent Reinventing the Wheel • Bases • NPD 8710.3 and NSS 1740.14 • Experiences From CGRO, TRMM, ERBS, LandSat • Experiences From GLAST, GPM Systems Engineering Seminar – Orbital Debris Mitigation Scott Hull and Josephine San, 591 October 7, 2003

34. Background - Procedures and Guidelines • Orbital Debris Mitigation PG • Provide Practical Guidelines on Orbital Debris Analysis • Discuss Design Process Flow to Decide on A Safe Disposal Method • Address Design Considerations, Necessary Analysis and Planning to Achieve Safe Disposal Through Concept, to Preliminary and Critical Design Phases • Status: In the Process of AETD Review, and Will Be Ready for Projects and Code 300 Review by the End of the Month • End-of-Mission Planning PG • Discuss Necessary Planning for Safe Disposal at the End of the Mission • Provide Guidance on the Development and Implementation of the End-of-mission Plan • Serve As a Template for End-of-mission Plan • Status: Ready for Peer Review by the End of the Month Systems Engineering Seminar – Orbital Debris Mitigation Scott Hull and Josephine San, 591 October 7, 2003

35. Background - Procedures and Guidelines (cont.) • Guidance, Navigation and Control Safe Disposal PG • Provide Guidance to Assist GN&C Flight Dynamic Engineers in the Mission Planning and End-of-Mission Operation Planning for Safe Disposal • Status: In the Process of Developing • Reentry Survivability Analysis Work Instruction • Provide Detailed Instructions on Reentry Survivability Analysis Using Debris Analysis Software (DAS) and Object Reentry Survivability Analysis Tool (ORSAT) • Clarify Details of NSS 1740.14 • Establish a Standard Approach for All GSFC Reentry Analysis • Status: Ready to Submit to ISO Systems Engineering Seminar – Orbital Debris Mitigation Scott Hull and Josephine San, 591 October 7, 2003

36. Safe Disposal Methods • Controlled Reentry Method • Maneuver the Spacecraft at the End of Mission to a Disposal Orbit With a Perigee Altitude Low Enough to Control the Location of the Reentry and Ground Impact Point • Is Applicable to a Spacecraft which Reenters Earth Atmosphere (Usually Spacecraft at or Passing Through Low Earth Orbit Altitude), and Does Not Meet the 1 in 10,000 Casualty Risk Guideline • Orbit Raising or Lowering Method • Maneuver the Spacecraft to a Storage Orbit by Raising or Lowering Its Final Orbit at the End of Mission; Is Applicable to Spacecraft With Perigee Above 2000 Km • At the End of Mission, Lower the Final Perigee So That It Will Meet the Orbit Life Time Guideline; Is Applicable to Spacecraft With Perigee Below 2000 Km (Uncontrolled Reentry) • Passivation • Put Spacecraft in Passive State With No Energy Source • Is Applicable to a Spacecraft which Meets the NSS Safe Disposal Guidelines • Direct Retrieval • By Shuttle or Other Means Systems Engineering Seminar – Orbital Debris Mitigation Scott Hull and Josephine San, 591 October 7, 2003

37. Concept Design Concept Design Process FlowFor Selection of Safe Disposal Method Casualty risk > 1 in 10,000 Casualty risk > 1 in 10,000 Yes Spacecraft With Perigee < 2000 km, and reenter Earth starts here Re-entry Survivability Analysis Using ORSAT Re-entry Survivability Analysis using DAS Redesign to Reduce Debris Casualty Risk? Controlled Re-entry Method No Casualty risk < 1 in 10,000 Need Orbit Maneuver To Meet 25 Year Orbit Life Or to Remove Spacecraft From Crowded Area? Yes Orbit Lowering/ Raising Method Spacecraft With Perigee > 2000 km, starts here No Spacecraft Passivation Method Systems Engineering Seminar – Orbital Debris Mitigation Scott Hull and Josephine San, 591 October 7, 2003

38. Methods to Reduce Debris Casualty Risk • Design for Demise (D4D) • Alternative Design for Components Made of High Melting Point, Specific Heat or Heat of Fusion, Such As Titanium, Beryllium, Stainless Steel • Composite Tank Design Utilizing Easily Demisable Material • Hybrid Design Using Low Melting Point, High Density Materials for Reaction Wheel Flywheels • Design a Spacecraft Such That It Will Achieve Orbit Safely but Will Burn up Upon Reentry • Possible Alternative for Adhesives or Fasteners • Reduce Area to Mass Ratio • Reduce Impact Energy Below Required Level by Breaking up Large but Thin Components to Smaller Segment Systems Engineering Seminar – Orbital Debris Mitigation Scott Hull and Josephine San, 591 October 7, 2003

39. Controlled Reentry - Cost • Material, Design and Development Costs • Full Cost for Hardware to Meet High Probability of Success • Propulsion System • Structure to Support Propulsion System • ACS Components to Support Controlled Re-entry • Incremental Cost for Hardware to Meet High Probability of Success Including Power, Communication, Thermal, and C&DH Systems • Full Cost for Attitude Controller Design and Development Including Delta V Control Mode for Long Duration Burn, Delta H Mode to Achieve Low Perigee Control, and Mode Transitions • Full Cost for Reentry Software, IncludingFault Management for Controlled Re-entry System, Flight Software for ACS Reentry Controlled Algorithm, and Ground Software for Testing, Simulation, and Re-entry Operation Support • Full Cost for Improved End-of-life Fuel Depletion ComputationMethod Systems Engineering Seminar – Orbital Debris Mitigation Scott Hull and Josephine San, 591 October 7, 2003

40. Controlled Reentry – Cost (cont.) • All Full Costs Will Become Incremental Cost for Missions which Require a Propulsion System for Orbit Maintenance • More Propellant, Larger Tank, and Higher Force Level Thrusters • ACS Components Sized to Support Controlled Reentry • I & T Cost for Safe Disposal Segment • Incremental Cost for Missions Required Propulsion System for Orbit Maintenance Already • Operational cost • Managing and Planning • Implementation, Training, and Simulation • Carrying Out Final Reentry Systems Engineering Seminar – Orbital Debris Mitigation Scott Hull and Josephine San, 591 October 7, 2003

41. Concept Design Phase - Design Considerations • Controlled Reentry • Perform Trades on the Minimum Apogee and Perigee to Ensure the Success of Final Burns and the Debris Footprint Confidence • Propellant • ACS Actuation Authority • Thermal Control at Lowest Perigee • Be Sure Low Battery State of Charge Will Not Be the Trigger Point for Reentry • Passivation • Design a Mission With Orbit Lifetime Less Than 25 Years • Design All Subsystems Such That They Can Be Passivated at the End of Mission • Put Battery in Permanently Discharge State – Disconnect Solar Array • Purge All Fuel, Power Down Wheels, Gyros, and Communication System • Orbit Raising/lowering • Maneuver to Storage Orbit: Incremental Cost to Meet the High Probability of Success • Lower Perigee to Reduce Orbit Life: Trade on Lowest Perigee • Design All Subsystems Such That They Can Be Passivated at the End of Mission Systems Engineering Seminar – Orbital Debris Mitigation Scott Hull and Josephine San, 591 October 7, 2003

42. Preliminary/Critical Design Phase –Design Considerations, Necessary Analysis and Planning • Redo Orbital Debris Analysis and Reconsider Safe Disposal Method If Necessary • Refine Design and Perform Analysis to Verify Design for Safe Disposal • As a Good Practice, Outline a End-of-Mission Plan by PDR and Produce a Draft by CDR • Controlled Reentry • Refine Propellant Budget and End-of-life Fuel Mass Estimation Method • Design Delta V and Delta H Mode, and Lay Out Mode Transition Sequence • Develop Failure Detection and Correction (FDC) Logic • Develop Failure Modes and Perform Failure Effect Analysis Systems Engineering Seminar – Orbital Debris Mitigation Scott Hull and Josephine San, 591 October 7, 2003

43. Operation and End-of-Mission Phase –Implementation of Safe Disposal Plan • Perform Orbital Debris Analysis if not Done Already • Evaluate Spacecraft Hardware and Software • Propose or Re-Evaluate Viable Safe Disposal Options • Perform Risk Analysis • Evaluate Ground and Network System Readiness • Complete End-of-mission Plan Including Nominal and Contingence Plans and Procedures • Prepare for Reviews if Necessary • Implement Safe Disposal Plan at the End of Mission Systems Engineering Seminar – Orbital Debris Mitigation Scott Hull and Josephine San, 591 October 7, 2003

44. End-of-Mission Planning • Management • Manpower Estimation, Assign Roles and Responsibilities, Prepare for Anomaly Investigation • External Interfaces Including Space Command, NIMA (Coast Guard, Airline), Public Affairs, HQ, ISS/JSC and State Department • Disposition of Ground Hardware and Software • Plan to Continue Reentry Prediction If Needed • The First Two Items Are Especially Critical for Controlled Reentry • Trigger Points • Nominal Trigger Point Around Which Safe Disposal Plan Is Designed, E.G. Fuel Level • Off Nominal Trigger Points With Different Criticality Level • Constituent and Actions Associated With Each Trigger Point Systems Engineering Seminar – Orbital Debris Mitigation Scott Hull and Josephine San, 591 October 7, 2003

45. End-of-Mission Planning(cont.) • System Evaluation and Risk Analysis • Ground Based System Evaluation Including Ground System and Network Support • Spacecraft State of Health Including Instrument, Bus Hardware and Software • Assign Trigger Level to Each Critical Component • Perform Risk Analysis for Each Failure • Documentation Management • Configuration Management for Procedures, Timelines • Final Engineering Report Systems Engineering Seminar – Orbital Debris Mitigation Scott Hull and Josephine San, 591 October 7, 2003

46. Implementation of End-of-Mission Plan • Nominal Plans, Procedures, and Timeline Script • Orbit Raising/lowering Option • Maneuver Plan, Maneuver Plan Implementation Procedure, Procedure for Final Jettison of Propellant • Plan to Coordinate Ground, Network and FDF Support • Plan and Procedure for Lowering the Orbit by Other Means • Sequence Plan to Shutdown Hardware, To Put Battery in Permanent Discharge State • Timeline Scripts for on Consol Operation • Passivation Option • Plan to Coordinate Ground, Network and FDF Support • Procedure for Final Jettison of Propellant If Needed • Sequence Plan to Shutdown Hardware, To Put Battery in Permanent Discharge State • Timeline Scripts for on Console Operation Systems Engineering Seminar – Orbital Debris Mitigation Scott Hull and Josephine San, 591 October 7, 2003

47. Implementation of End-of-Mission Plan (cont.) • Nominal Plans, Procedures, and Timeline Script (Cont.) • Controlled Reentry Option • Plan to Coordinate Ground, Network and FDF Support • Mission Design for Controlled Reentry Shall Be Simple and Robust, It Shall Use the Spacecraft As Close to Its Original Design As Possible • Some of the End Products From Mission Design Are Maneuver Plan, Operation Sequence Plan, Mode Transition Plan, Plan to Characterization Burns • Implementation Procedures for All These Plans • Develop Burn Commit and Abort Criteria Systems Engineering Seminar – Orbital Debris Mitigation Scott Hull and Josephine San, 591 October 7, 2003

48. End-of-Mission Planning (cont.)Implementation of End-of-Mission Plan • Contingence Plans • Event Fault Tree and Probability of Success • Debris Field Error Analysis and Effective Delta V Reserve Allocation • Contingency Handling Flow • Contingency Plans for Most Likely and Combination of Most Likely Failures • Training and Simulation Planning • Plans to Train Support Personnel • Plans to Verify Scripts, Procedures and Contingency Plans • Plans to Simulate Interaction Between Teams Systems Engineering Seminar – Orbital Debris Mitigation Scott Hull and Josephine San, 591 October 7, 2003

49. Design for Demise (D4D) Examples Scott Hull / 591 NASA/GSFC Systems Engineering Seminar – Orbital Debris Mitigation Scott Hull and Josephine San, 591 October 7, 2003

50. Design for Demise (D4D) • An effort to create alternate designs with the intent of ensuring complete demise during reentry • Generic designs for perennial survivors • Mission-specific designs for surviving components • Methods • Different material • Multiple materials • Different shape • New technology Systems Engineering Seminar – Orbital Debris Mitigation Scott Hull and Josephine San, 591 October 7, 2003