dumbacher2012 pmchallenge
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National Aeronautics and Space Administration
Exploration Systems DevelopmentProgram Management Overview
Dan DumbacherFebruary 2012
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The NASA Vision
NASA Strategic Goals1. Extend and sustain human activities across the solar system.2. Expand scientific understanding of the Earth and the universe in which
we live.3. Create the innovative new space technologies for our exploration,
science, and economic future.4. Advance aeronautics research for societal benefit.5. Enable program and institutional capabilities to conduct NASA’s
aeronautics and space activities.6. Share NASA with the public, educators, and students to provide
opportunities to participate in our mission, foster innovation, and contribute to a strong national economy
To reach for new heights and reveal the unknown, so that what we do and learn will benefit all humankind.
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Stepping Stone Exploration
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Human Exploration & Operations: Organization
Current as of February 2012
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Exploration Systems Development
These programs will develop the launch and spaceflight vehicles that will provide the initial capability for crewed exploration missions beyond LEO.
– The Space Launch System (SLS) program is developing the heavy lift vehicle that will launch the crew vehicle, other modules, and cargo for these missions
– The Orion Multi-Purpose Crew Vehicle (MPCV) program is developing the vehicle that will carry the crew to orbit, provide emergency abort capability, sustain the crew while in space, and provide safe re-entry from deep space return velocities
– The Ground Systems Development and Operations (GSDO) program is developing the necessary launch site infrastructure to prepare, assemble, test, launch and recover the SLS and Orion MPCV flight systems
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Organization and InterfacesESD Division and Programs
Cross-Program Systems Integration
(CSI)
Program Level
HEO/ESD Level
Space Launch System(SLS)
Line of AuthorityLine of Communication
Multi-Purpose Crew Vehicle(MPCV)
Ground Systems Development &
Operations(GSDO)
ESD HQ Agents
(Reach back Support)
Program to
Program Technical Working Groups
PP&C Integration Team (PIT)
Budget Integration WG
Risk Integration WG
Transition Integration WG
Schedule Integration WG
Config Mgt & Document Mgt
WG
Integrated Programmatic
Communication
Exploration Systems Development
(ESD)HEO RMAO
Programmatic and Strategic Integration
(PSI)ESD RMO
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Analysis of Alternatives Overview
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Objectives of Analysis of Alternatives (AoA)
• Focus on delivering beyond Low Earth Orbit (BEO) capability for human exploration as expeditiously and safely as possible
• Assume a flat-line budget
• Develop an integrated capability by aligning MPCV, SLS, and GSDO concepts through a set of common ground rules and assumptions
• Develop a budget profile to enable a wedge to be created for future in-space systems development
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FY 2011FEB MAR APR MAY JUN JUL AUG SEPT
Integrated Plan Leading to Orion, SLS, and GSDO Information & Decisions
FORMULATION PLAN
SLS, Orion, 21CGS ALT
ASSESSMENT OF OPTIONS
INTEGRATED SLS, Orion, GSDO ALTERNATIVE
FINAL ASSESSMENT OF OPTIONS
INTEGRATED SLS, Orion, GSDO
DRAFT PRG GUIDANCE
SLS ACQUISITION
Integrate SLS, Orion, GSDO
INDEPENDENT COST ASSESSMENT (ICA)
ARCHITECURE SELECTION
SECTION 309 REPORT
FINAL REPORT TO NASA
ARCHITECURE ANNOUNCEMENT
December 23
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Orion MPCV Analysis Approach
• The MPCV Analysis sought to validate or challenge whether the beyond-LEO version of the Orion Crew Exploration Vehicle (the Reference Vehicle Design) is the most effective approach through:
– Understanding progress to date on the Orion development effort
– Validating whether the Orion requirements closely match MPCV requirements consistent with the Authorization Act
– Examining and implementing ways to be able to deliver an affordable and achievable crew vehicle as soon as possible. For example:
• Streamlining government oversight and insight activities to ensure we are focusing on the key-risk items
• Implementing an incremental approach to developing and building vehicle capabilities• Planning a more innovative and cost-effective vehicle qualification plan, utilizing
distributed test labs, for example• NASA is also exploring other affordability measures including consolidating facilities
and re-using test assets
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Decision for Orion as MPCV
• Examined technical, risk and cost implications of replacing functionality of MPCV with in-space vehicle and planned Commercial Crew capabilities
• CC-Based Approach produces large increases in required mission mass and associated number of launches (factor of 2 - 3) over Capability-Driven Reference with significant impacts on safety risk and P&O cost
– Increases complexity of in-space vehicle assembly and number of elements required implying lower reliability system
– Increases ground launch infrastructure and/or technology development– Introduces unique mission-critical events and additional Loss-of-Crew scenarios– “Launch-on-Demand” CC capability required to assure crew survivability in many
abort scenarios– Parametric costs estimates indicate recurring cost delta per mission provides
insufficient P&O funding for SLS and eliminates funding wedge for future capabilities given the flat-line budget
Assessment confirms the requirements for an MPCV
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SLS Analysis Approach
Approach: • Leverage three government Requirement Analysis Cycle (RAC) Teams to create and
study different design concepts that leverage capability across American industry• In parallel, solicit industry input and concepts via study contract input
Implementation:• Team studies (Fall 2010) concluded without architecture decisions• Government Requirements Analysis Cycle (RAC)
– Three competing configurations with fourth team looking at cross-cutting affordability– Approaches to affordability addressed by all 3 teams– Common requirements, goals/threshold approach - tradable– Incorporate incremental inputs from NASA Heavy Lift study contracts– Out brief to SLS Feb 16-18
• Contractor Heavy Lift Study Contracts–awarded November 2010– 13 Contractors, $650K each, 6 month studies – broad SOW ideas– Initial Out briefs Feb 22-24– Final Out briefs Apr 25-28
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Analyzed SLS Concepts
LOX/H2 – Reference Vehicle Design LOX/RP Modular
DescriptionHydrogen core configuration with
solid strap-on boosters; multiple evolution paths
Large RP configuration (large diameter tanks) with multiple
engine options, incl. NASA/USAF common engine
Modular RP configuration (smaller diameter tanks) with multiple engine options, incl. NASA/USAF common engine
Lift Capability 70 mT – 150 mT 100 mT – 172 mT 70 mT – 130 mT
Note: Images based on government design solutions from RAC teams
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SLS DecisionPhilosophy/Rationale
• Maintains US leadership in LOX/LH2 technology– LOX/LH2 core uses RS-25E engines; LOX/LH2 Upper Stage uses J-2X– Establishes fixed central design path with logical use of existing strength in design and
manufacture– Maintains existing knowledge base, skills, infrastructure, workforce, and industrial base
for existing state of the art systems • Minimizes Unique Configurations
– Evolutionary Path to 130mT allows incremental development; thus progress to be made even with constrained budgets
– Allows early flight tests for MPCV – Provides flexible/modular design and system for varying launch needs– Gains synergy, thus reducing DDTE by building core and upper stage in parallel,
allowing common tooling and engine feed components• Provides a Balanced Approach for Acquisition
– Opportunity for use of existing contracts for development phase enabling a fast start– ASM will provide official agency decision on acquisition strategy– Allows for competition for best value to the government
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Orion MPCV Overview
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Orion MPCV Vehicle
Launch Abort System• Provide protection for the CM
from atmospheric loads and heating during first stage flight
• Safely jettison after successful pad operations and first stage flight
Service Module (SM)• Provide support to the CM from
launch through CM separation to missions with minimal impact to the CM
Crew Module (CM)
• Provide safe habitat from launch through landing and recovery
• Conduct reentry and landing as a stand alone module
Spacecraft Adapter• Provide structural connection to the launch vehicle
from ground operations through CM Separation• Provide protection for SM components from
atmospheric loads and heating during first stage flight
The Orion MPCV design divides critical functions among multiple modules to maximize the performance of the integrated spacecraft design
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Orion MPCV Technology Advancements
PropulsionAbort Motor, Attitude Control Motor,High Burn Rate Propellant for SolidRocket MotorsBenefits: High reliability launch abort, steerable solid rocket motors
AvionicsAlgorithmic Autocode Generation, ARINC-653/DO-178 Standard Operating System, Baseband Processor, High Speed/High Density Memory Devices, Honeywell HX5000 Northstar ASICBenefits: Low cost, high performance, open architecture
NavigationAtmospheric Skip Entry, Flash Lidar, Vision Navigation Sensors, Autonomous Rendezvous and Docking, Fast Acquisition GPS Receiver, High Density Camera SensorsBenefits: Low cost, high reliability, autonomous docking
CommunicationsInteroperable Communications, Communication Network Router Card, Digital Video Recorder, Phased Array AntennasBenefits: Low cost, high reliability, open architecture
Life Support & SafetySolid Amine Swing-Bed, Backup and Survival Systems, Closed Loop Life Support, Contingency Land Landing, Enhanced Waste Management, Environmental Control, Hazard Detection, Isolation and RecoveryBenefits: Low consumables, long mission duration, high reliability, low operations cost
StructuresComposite Spacecraft Structures, Human Rated Spacecraft Primary Structures Development, Advanced ManufacturingBenefits: Low cost, low mass
Thermal Protection SystemAblative Heatshield with CompositeCarrier StructureBenefits: Low cost, high reliability, high energy (Beyond LEO) entry
PowerHigh Energy Density Lithium Ion Batteries, Column Grid Array Packaging (CGA), Direct Energy Power Transfer SystemBenefits: Low cost, high reliability, low mass, long mission duration
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SLS Overview
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SLS Planned Evolution
Block 1A – 105 t incorporates
Advanced Boosters
Block 1 – 70 t Block 2 – 130 t
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SLS Key Characteristics
• Human-Rated
• Affordable– Constrained budget environment– Maximum use of common elements and existing assets,
infrastructure and workforce– Competitive opportunities for affordability on-ramps
• Initial Capability: 70-100 metric tons (t), 2017-2021– Serves as primary transportation for Orion and exploration missions– Provides back-up capability for crew/cargo to ISS
• Evolved capability: 105 t, post-2021– Includes Advanced Booster– Allows incorporation of any products from the Advanced
Development NRA focusing on risk reduction
• Evolved capability: 130 t, post-2021– Offers large volume for science missions and payloads– Modular and flexible, right-sized for mission requirements
SLS First Flight (Non-crewed) in 2017
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Summary by Element:Risk Reduction Incorporated in Design
• Boosters (3-phased approach)– Phase I: 5-segment Solid Rocket Booster in-scope modification to existing Ares contract with ATK for initial flights
through 2021– Phases II and III: Advanced Boosters
• II: Engineering demonstration and risk reduction via NASA Research Announcement (NRA): Full and Open Competition in FY12; award by FY13
• III: Design, Development, Test & Evaluation (DDT&E): Full and Open Competition (RFP target FY15)
• Stages– Core/Upper Stage: Justification for Other Than Full and Open Competition (JOFOC) to Boeing, modifying current
Ares Upper Stage contract– Instrument Unit Avionics: In-scope modification to existing Ares contract with Boeing; consolidated with Stages
contract to Boeing
• Engines– Core Stage Engine: RS-25d JOFOC to existing Space Shuttle contract with Pratt & Whitney Rocketdyne (PWR)– Upper Stage Engine: J-2X in-scope modification to existing Ares contract with PWR– Future Core Stage Engine: Separate contract activity to be held in the future
• Spacecraft and Payload adapter and Fairing– Initial design: Adapter and Fairing design and development in-house through early design phase– Fairing Full and Open Competition planned for FY13
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SLS Trades and Vehicle Reliability
SLS Trades consider impacts on performance, safety and budget.• SLS has multiple trade studies (20+) on-going
– Number of engines, stage testing at SSC vs. FRF, etc. • Results of all trades must be reconciled prior to establishing a complete
baseline configuration addressing all 3 factors• Planning to baseline configuration at end of SRR/SDR – May 2012• SLS Program is still in formulation phase
Reliability predictions for all vehicles • Models use STS data for heritage and heritage derived hardware, e.g. SSME• Model includes flight path and time• Model used to predict LOM and LOC for 4 cases for each vehicle configuration:
No Engine-Out (EO), Core EO, Upper Stage EO, and Both Stages EO• Estimates used to trade against performance and costs• Estimates will be used to develop reliability allocations for Elements post SDR
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SLS Procurement Milestones
• SLS Acquisition Overview Synopsis, posted September 22, 2011
• Industry Day at Marshall Space Flight Center on September 29
• SLS Advanced Development RFI, posted October 7, 2011
• SLS Advanced Booster Engineering Demonstration and Risk Reduction RFI, posted October 7, 2011
• Industry Day at Michoud Assembly Facility on November 14
• SLS Advanced Booster Engineering Demonstration and Risk Reduction Draft NRA, posted December 12, 2011
• SLS Advanced Development Draft NRA, posted February 1, 2012
• SLS Advanced Booster Engineering Demonstration and Risk Reduction NRA, posted February 9, 2012
• Industry Day at Marshall Space Flight Center on February 14
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Block 1 Design/DevelopmentAdvanced DevelopmentBlock 1 Requirements
Block 2 Design/Development Advanced DevelopmentBlock 2 Requirements
Block 1 Mission
Block 2 Mission
Block 3 Design/Developmen
t Advanced DevelopmentBlock 3
Requirements
Advanced DevelopmentBlock 4 Requirements
Missions Requirements Block 0 Design/Development Block 0 Mission
Improvements in Affordability, Reliability, and Performance
Stakeholders &
Customer Needs
* NASA, Office of Chief Technologist
TechnologyMaturation*
Technology Maturation*
Technology Maturation*
SLS Philosophy for Evolutionary Upgrades
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SLS Development Key Tenets
• Utilize an evolutionary development strategy that allows for incremental progress within constrained budgets
• Incorporate mature technical solutions into SLS program-phased block upgrades
• Optimize use of common elements and existing assets for a flexible/modular design
Improve Affordability, Reliability, or Performance
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Ground Systems Development and Operations(GSDO) Overview
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Horizontal Launch & Landing Small Vehicle LaunchClean Floor Processing
Heavy Class Launch Capability
Flexible Approach
Multi-Use Integration (VAB)
Flexible Launch Capability
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GSDO Program Highlights
• The demolition of the Fixed Service Structure/Rotating Service Structure (FSS/RSS) at Launch Complex 39-B was completed.
• Multi-Purpose Processing Facility (MPPF) Phase 1 modifications (HVAC) are progressing.
• Space Shuttle Program facility turnover is underway.
• Provided significant contribution to the Interagency Working Group Launch Infrastructure Modernization Report
Before After
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Orion MPCV Ground Test Article
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SLS Configurations
• 385 ft
• 315 ft
• 209 ft
• 0• 130t_Block ll cargo• 105 - Block lA cargo • 130t Block ll crew• 105t - Block IA crew• 70t - Block l crew
Notional GSDO Range
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Overall Flight Test Strategy
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Mission/Flight Test Objectives
• Flights are needed to test critical mission events and demonstrate performance in relevant environments– Abort, jettison, separation, chute deploy, Re-entry and TPS performance in
BEO conditions, Integrated vehicle systems performance, and environments validation
– Data collected from flights will be used to eliminate additional SLS test flights as the SLS configuration evolves
– Dedicated flight tests will not be required for incorporation of competitive boosters, RS-25E, or the upper stage (with J-2X)
• Four missions/test flights planned to meet minimum mission/flight test– Exploration Flight Test-1 (EFT-1), an orbital, uncrewed test flight in 2014
provides MPVC system level tests and risk reduction opportunity– Ascent Abort-2 (AA-2), an abort test in high dynamic pressure environment – Exploration Mission-1 (EM-1), an Un-crewed BEO (lunar flyby) and EM-2,
a crewed BEO flight (includes 3-4 day lunar orbit) will provide more system level testing and shakedown
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MPCV Test Campaign Reduces Risk While Maturing the Design
GTA Acoustic, Modal, Vibe TestingEnvironment compatibility
Water Drop TestsCorrelate structural math models in water landing conditions
Parachute TestsNominal and contingency parachute performance tests
Wind Tunnel Testing Aero/aerothermal database validation for Orion configuration
TPS Arc Jet TestingHeatshield model correlation for entry performance
EFT-1 Test Article Manufacturing and AssemblyFirst production primary structure built for orbital flight
Pad Abort Test - May 6, 2010Demo abort capability with prototype LAS
Exploration Flight Test 1
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Exploration Mission – 1 (EM-1)BEO Un-crewed Flight
• Mission description– Un-crewed circumlunar flight – free return trajectory– Mission duration ~7 days
• Mission objectives– Demonstrate integrated spacecraft systems performance prior to
crewed flight– Demonstrate high speed entry (~11 km/s) and TPS prior to
crewed flight• Spacecraft configuration
– Orion “Block 0 Lunar”• Launch vehicle configuration
– SLS Block 0, 5 segment SRBs, 3 SSMEs, 70-80 t– Interim Cryogenic Propulsion Stage (ICPS)
• Launch site– KSC LC-39B
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Exploration Mission – 2 (EM-2) BEO Crewed Flight
• Mission description– Crewed lunar orbit mission– Mission duration 10-14 days
• Mission objectives– Demonstrate crewed flight beyond LEO
• Spacecraft configuration– Orion “Block 0 Lunar”
• Launch vehicle configuration– SLS Block 0, 5 segment SRBs, 3 SSMEs, 70-80 t– Interim Cryogenic Propulsion Stage (ICPS)
• Launch site– KSC LC-39B
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Affordability
Accelerate Decision-Making Velocity
Manage Program RQ & Contractor Interfaces
Maintain Competition & Improve Acquisitions
Incentivize Contractors for Effective Cost MgmtIdentify Best Practices &
Implement Lessons Learned
Flatten Organization - Clear Authority &
Accountability
Maximize Use of Industry Standards
Eliminate Non-Value Added NASA & FAR RQ
Develop Mitigation Plans for High Risks / Cost Drivers
Streamline Certificate of Flight Readiness Process
Implement “Should Cost” Based Management
Capitalize on Progress Payment Structures
Define Strategy & Clear Roles for Oversight/Insight
Focus on Key Driving Requirements
Make Affordability a Requirement
Push Reserves to Programs
Leverage Use of In-House Capability
Maximize Competition thru the Life of Program
Adopt Appropriate Safety & Risk Posture
Improving Affordability of Human Spaceflight Programs
Reduce Frequency of Agency-level Reviews
Accelerate Decision-Making
•Overhauled the Governance Structure–Flattened organization – removed a layer–Clear authority and accountability–Fewer decision-boards–Pushed reserves to the programs–Fewer meetings and streamlined reporting
•Implementing a New, Efficient, Distributed Integration Approach–ESD leads with reach back to the Programs & Centers through -
•ESD Office of Cross Program Systems Integration (CSI)•ESD Office of Programmatic & Strategic Integration (PSI)
•Leveraging Lessons Learned–Constellation Program–Ares 1X Flight Demonstration Project–Standing Review Board–Booz Allen Hamilton–Industry Input on Affordability – 1-on-1 meetings and SLS BAA input–DoD Better Buying Power Initiatives–NASA/DAU Program Executability Workshop
Manage Program RQ & Contractor Interfaces
•Including Affordability as a Requirement– Encouraging commonality and utilization of industry standards vs NASA
unique requirements.–Streamlined and Minimized Key Driving Requirements
• ESD issued only 21 level one requirements; CxP had several hundred.
• Strategically focused staffing of insight / oversight of contractor performance
–Minimize number of Gov’t staff performing insight/oversight–Follow a Risk-based or a Hybrid approach
– Focus and clarify Government roles pertaining to interactions with and direction to contractor.
•Risk Management– ESD cannot afford to mitigate all risks; risk acceptance needs to be
approved and documented.– Connecting risk approach to use of reserves will allow ESD to strategically
choose the most important risks to mitigate.
Maintain Competition & Improve Acquisitions-
•Conducting ‘Will Cost’ and ‘Should Cost’ Reviews–Conducted a ‘Should Cost’ training session–Booz Allen support of Independent Cost Assessment–DoD Price Fighters assisting SLS IATs–DCMA to assist with ‘Should Cost’ review of Contractor overhead
•Implementing Contract Incentives for Cost Reductions
•Issuing Multiple Lower-Level Contracts vs Large System Level–Reduces pass through of subcontracting overhead & fees–Enables greater insight and ability to define requirements–Enable direct employment of contractor performance incentives–Improves competition
•SLS: Element-level contracts•Ground Dev & Ops: FP IDIQ contracts
•Leveraging Existing Assets
ESD - A fresh start to improve affordability…
• Major cost drivers in human space flight are organizational structures, requirements and acquisition strategy / contract management.
• ESD and its programs are new, very different development programs in comparison to prior NASA experiences
• This new beginning has enabled NASA to pursue a more efficient and affordable future to human space flight by implementing approaches to secure better buying power, such as: – Accelerating Decision-Making Velocity– Better Managing Program Requirements & Contractor Interfaces, and– Improving Acquisition Strategy and Implementation
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Space Launch SystemAffordability Begins with Accountability• Evolvable Development Approach
– Manage requirements within constrained, flat budgets– Leverage existing National capabilities
• Liquid oxygen/hydrogen propulsion infrastructure• Manufacturing and launch-site facilities
– Infuse new design solutions for affordability• Robust Designs and Margins
– Performance traded for cost and schedule– Heritage hardware and manufacturing solutions– Adequate management reserves controlled at lower levels
• Risk-Informed Government Insight/Oversight Model– Insight based on:
• Historic failures• Industry partner past performance and gaps• Complexity and design challenges
– Judicious oversight:• Discrete oversight vs. near continuous• Timely and effective decisions
• Right-Sized Documentation and Standards– 80% Reduction in the number of Type 1 Data Requirement Documents from the Ares Projects– Increased use of industry practices and tailored NASA standards
• Lean, Integrated Teams with Accelerated Decision Making– Simple, clear technical interfaces with contractors– Integrated Systems Engineering & Integration organization– Empowered decision makers at all levels– Fewer control Boards and streamlined change process
8094_Affordability.44National Aeronautics and Space Administration
Multi-Purpose Crew VehicleAffordability Actions
• Orion/MPCV affordability initiatives over the past 12 months have reduced DDT&E cost and enabled schedule acceleration.
• Initiatives include:
– Streamlined government oversight and insight that focuses on key-risk items and collocation with Prime contractor in selected areas
– Incremental approach to building and testing vehicle capabilities
– Reduction in formal deliverables and simplified processes while retaining adequate rigor
– Partnering with suppliers to analyze cost drivers and possible efficiencies
– Consolidation of test labs and re-use of test articles
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Ground Systems Development and Operations Approach to Affordability
• Architecture leverages existing Shuttle/ISS and Constellation assets and avoids unnecessary costs to be affordable.– Relies heavily on “grandfathering” of these heritage systems with respect to
code compliance.• LC39 Pad B (clean pad)• Uses modified Ares 1-ML• Integration: VAB – High Bay-3• Utilizes CxP Crew/Crew Module Recovery Approach
• Civil Servants perform the traditional “Prime” role for management & integration– Allows Ground Operations to quickly respond to changing program direction
with minimal cost/schedule impact– Avoids overhead costs on subcontracts, and is different from the Shuttle-USA
experience• Acquisition approach enables flexibility and maximizes competition.
– Reduce schedule and procurement costs through ‘best value’ fixed-price IDIQ contracts. Pre-qualify and pre-stage supplier pools (designers, fabricators, constructors):• Design IDIQ contracts (in place)• Construction IDIQ contracts (in place)• GSE Fabrication IDIQ contracts (in place)• Craft Labor contract for installation support (in planning)
Near-Earth Asteroids:– Compelling science questions:
How did the Solar System form? Where did Earth’s water and organics come from?
– Planetary defense: Understanding and mitigating the threat of impact
– Potential for valuable space resources– Excellent stepping stone for Mars
We Can Reach Multiple Destinations
Increasing Our Reach and Expanding Our Boundaries
High-Earth Orbit (HEO)/Geosynchronous-Earth Orbit (GEO)/Lagrange Points:– Microgravity destinations beyond LEO– Opportunities for construction, fueling,
and repair of complex in-space systems – Excellent locations for advanced space
telescopes and Earth observatories
Earth’s Moon:– Witness to the birth of the Earth and
inner planets– Has critical resources to sustain humans– Significant opportunities for commercial
and international collaboration
Mars and Its Moons,Phobos and Deimos:– A premier destination for discovery:
Is there life beyond Earth? How did Mars evolve?
– True possibility for extended, even permanent, stays
– Significant opportunities for international collaboration
– Technological driver for space systems
8032 SLS 101 Briefing.47
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MPCV Test Campaign - Status Reduces Risk While Maturing the Design
GTA Acoustic, Modal, Vibe TestingEnvironment compatibility
Water Drop TestsCorrelate structural math models in water landing conditions
Parachute TestsNominal and contingency parachute performance tests
Wind Tunnel Testing Aero/aerothermal database validation for Orion configuration
TPS Arc Jet TestingHeatshield model correlation for entry performance
EFT-1 Test Article Manufacturing and AssemblyFirst production primary structure built for orbital flight
Pad Abort Test - May 6, 2010Demo abort capability with prototype LAS
SLS Status•SLS Program Office
– Presented “Pass the Torch” lecture at U.S. Space and Rocket Center’s Davidson Center for Space Exploration on Feb 2– Kickoff meeting on Feb 15 for System Requirements Review (SRR) / System Definition Review (SDR) in Mar 2012
•Program Planning & Control– Baselined SLS Program Plan at the Program Control Board on Jan 26– Hosted technical interchange meeting (TIM) for the Exploration Systems Division’s integrated programmatic communications
working group from Jan 30 – 31
•Procurement– Held SLS Industry Days for the SLS Program, Stages, and NASA Research Announcement (NRA) Advanced Booster
Engineering Demonstration and Risk Reduction (EDRR), attended by over 670 companies and potential partners– Conducted SLS Advanced Development and Academia Industry Day on Feb 14
• Boosters– Held kick-off for Integrated Acquisition Team on Jan 13– Discussed systems engineering and integration at ATK-Lakeside from Jan 23 – 26
• Engines– Completed 10 tests for J-2X Upper Stage Engine E10001 (~1,040 sec cumulative hot-fire time)– Successfully demonstrated full flight mission duration (500 sec) and 100 percent power level (235 sec) in 2011– Conducting engine to facility control system checkouts in preparation for PPA-2 Test #1
• Stages– Baselined Integrated Acquisition Team Board on Jan 17
• Spacecraft & Payload Integration– Successfully tested 3’ by 5’ Manufacturing Test Panel 6003 at LaRC on Jan 19– Baselined Exploration Flight Test 1 (EFT-1) MPCV-To-Stage Adapter (MSA) detailed schedule on Jan 20
• Mobile Launcher move to Pad B
• Vehicle Assembly Building (VAB) designs for cable removal and VAB door modifications complete
• Crawler Transporter-2 moved into VAB HB-2 to continue modification
• VAB Door Project contract awarded to USA
• Pad B LH2/LO2 Cross Country Pedestal Refurbishment complete
• Tank Refurbishment sandblasting and painting started
• ML Structural Design Contract awarded to RS&H
• Received tilt-up umbilical arm test article at the the Launch Equipment Test Facility (LETF)
•LETF Testing is scheduled to start beginning of May, 2012
• Initiated construction on CRF facility to support Orion Launch Abort System (LAS) assembly for EFT1
• Orion Ground Test Article (GTA) at KSC for GSE development
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GSDO Status
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www.nasa.gov
Questions?