Design of a System for Aircraft Fuselage Inspection Reduce Inspection Time
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Design of a System for Aircraft Fuselage Inspection Rui Filipe Fernandes Kevin Keller Manual Inspection Automated Inspection Before jchadwickco.com Jeffrey Robbins Fatigue Damage mechanicsupport.blogspot.com Crack After aerospacetestinginternational.com Computer Aided Detection Reduce Inspection Time Improve Crack Detection Reduce Maintenance Cost gasolinealleyantiques.com Faculty Advisor Dr. Lance Sherry Sponsor Integrity Applications Incorporated Agenda Context • Aging Aircraft & Maintenance • Current Fuselage Inspection Process • Stakeholder Analysis • Problem and Need Concept Of Operations Method of Analysis Project Plan Design of a System for Aircraft Fuselage Inspection 2 Context: Aging Aircraft & Maintenance Aircraft Age Statistics Min: 5.1 years Mean: 10.6 years Max: 24.9 years airsafe.com Average Aircraft Age Continues to Increase Design of a System for Aircraft Fuselage Inspection 3 Context: Aging Aircraft & Maintenance Increasing Average Age Rank Carrier Average Age 4 US Airways 14.7 5 Southwest 14.6 6 United 13.7 International Air Transport Association Bloomberg iata.org bloomberg.com Domestic Carriers among the oldest fleets Design of a System for Aircraft Fuselage Inspection 4 Context: Aging Aircraft & Maintenance Widespread Fatigue Damage Widespread fatigue damage (WFD) is age-related structural fatigue cracking iata.org travelpulse.com WFD Leading to Aircraft Retirement Design of a System for Aircraft Fuselage Inspection 5 Context: Aging Aircraft & Maintenance Aloha Airlines Flight 243 April 28, 1988, Boeing 737-200 lessonslearned.faa.gov lessonslearned.faa.gov Missing fuselage section caused by failure of lap joint at stringer S-10L Improved Maintenance Required Design of a System for Aircraft Fuselage Inspection 6 Context: Aging Aircraft & Maintenance Southwest Airlines Flight 812 Emergency Airworthiness Directive AD 2011-08-51 136 Aircraft Inspected: 4 Found With Cracks Around 1 Rivet 1 Found With Cracks Around 2 Rivets 40,000 – 45,000 Total Cycles ntsb.gov April 1, 2011, Boeing 737-300 Preventative Maintenance Failed to Detect Indicators of Fatigue Design of a System for Aircraft Fuselage Inspection 7 Context: Aging Aircraft & Maintenance Deterioration Factors that contribute to aircraft deterioration include: • Inflight vibrations • Number of takeoffs and landings • Fuselage pressurization cycles 30,000 ft. (4.38 psi) newsweek.com Fatigue Caused by Repeated Pressurization Cycles Design of a System for Aircraft Fuselage Inspection 8 Context: Aging Aircraft & Maintenance Fuselage Pressurization Cycles engineeringtoolbox.com Stress From Change in Pressure Leads to Structural Fatigue Design of a System for Aircraft Fuselage Inspection 9 Context: Aging Aircraft & Preventative Maintenance Scheduled Aircraft Maintenance Programs Inspection Type Time Between Inspections Number of Man Hours Required Time to Complete A 125 flight hours or 200–300 cycles 20–50 man-hours Overnight B Approximately every 6 months 120–150 man-hours 1-3 Days C Approximately every 20–24 months Up to 6,000 man-hours 1–2 weeks D Approximately every 6 years Up to 50,000 man-hours 2 Months faa.gov Maintenance Intervals, A Delicate Balance of Risk and Cost Design of a System for Aircraft Fuselage Inspection 10 Context: Aging Aircraft & Maintenance Median Crack Growth Curve Crack Length Time of Inspection Critical Crack Length Earliest Expected Cracking Latest Expected Cracking Median crack growth curve Time Yang JN, Manning SD (1990) Stochastic Crack Growth Analysis Methodologies For Metallic Structures Minimize Number of Cracks Occurring Before Inspection Design of a System for Aircraft Fuselage Inspection 11 Crack Length Context: Aging Aircraft & Maintenance Distribution of Time to Critical Crack Length Time of Inspection Probability of cracks occurring BEFORE scheduled Maintenance Distribution of Time to Critical Crack Length Critical Crack Length Time Yang JN, Manning SD (1990) Stochastic Crack Growth Analysis Methodologies For Metallic Structures Minimize Probability of Cracks Occurring Before Inspection Design of a System for Aircraft Fuselage Inspection 12 Crack Length Context: Aging Aircraft & Maintenance Distribution of the Crack Length Probability of crack growth beyond critical length Critical Crack Length Distribution of the crack length Time Time of Inspection Yang JN, Manning SD (1990) Stochastic Crack Growth Analysis Methodologies For Metallic Structures Minimize Crack Growth Beyond Critical Length Design of a System for Aircraft Fuselage Inspection 13 Crack Length Context: Aging Aircraft & Maintenance Stochastic Crack Growth Model Probability of cracks occurring BEFORE scheduled Maintenance Probability of crack growth beyond critical length Distribution of Time to Critical Crack Length Critical Crack Length Earliest Expected Cracking Latest Expected Cracking Distribution of the crack length Median crack growth curve Time Time of Inspection Yang JN, Manning SD (1990) Stochastic Crack Growth Analysis Methodologies For Metallic Structures Early Crack Detection Can Minimize Corrective Maintenance Design of a System for Aircraft Fuselage Inspection 14 Context: Aging Aircraft & Maintenance Stochastic Crack Growth Model Yang JN, Manning SD (1990) Stochastic Crack Growth Analysis Methodologies For Metallic Structures The inspection schedule is chosen such that the probability of crack to grow beyond the critical crack size is less than 1 in 10,000,000 Taghipour, S., Banjevic, D., Jardine, A. K. S., “Periodic inspection optimization model for a complex repairable system”, Reliability Engineering and System Safety, Vol 95, 2010, Pg 944-952 Design of a System for Aircraft Fuselage Inspection 15 Context: Aging Aircraft & Corrective Maintenance Airworthiness Directive (AD) Airworthiness Directives are legally enforceable regulations issued by the Federal Aviation Administration (FAA) in accordance with 14 CFR part 39 to correct an unsafe condition in a product When Does FAA Issue Airworthiness Directives? When it finds an unsafe condition exists in the product and the condition is likely to exist or develop in other products of the same type design faa.gov Corrective Maintenance is Disruptive to Airlines and Results in Unplanned Revenue Loss Design of a System for Aircraft Fuselage Inspection 16 Context: Aging Aircraft & Maintenance Title 14 of the Code of Federal Regulations (CFR) Changes in maintenance procedure is regulated by the FAA faa.gov Inspection Process Governed by Title 14 (CFR) Design of a System for Aircraft Fuselage Inspection 17 Context: Current Fuselage Inspection Process Visual Inspection Process • Job Cards Used For Every Component • Many Human Factors/Prone to Errors • 41.8% detected • 14.1% type 1 error (Misdiagnosed) • 43.7% type 2 error (Missed Detection) • Non-Destructive Inspection (NDI) methods used to assess marked regions VISUAL INSPECTION RESEARCH PROJECT REPORT ON BENCHMARK INSPECTIONS FAA Aging Aircraft NDI Validation Center Inspection Process Begins with Visual Inspection Design of a System for Aircraft Fuselage Inspection 18 Context: Current Fuselage Inspection Process Representative Regions of Aircraft FAA Aging Aircraft NDI Validation Center Report JC 501 Midsection Floor JC 502 Main Landing Gear Support JC 503 Midsection Crown (Internal) JC 504 Galley Doors (Internal) JC 505 Rear Bilge (External) JC 506 Left Forward Upper Lobe JC 507 Left Forward Cargo Compartment JC 508/509 Upper and Lower Rear Bulkhead Y-Ring JC 510 Nose Wheel Well Forward Bulkhead JC 511 Lap-Splice Panels ntl.bts.gov Representative Regions Require Different Inspection Techniques Design of a System for Aircraft Fuselage Inspection 19 Context: Current Fuselage Inspection Process Current Visual Inspection Process Inspection Time of Lap-Splice Panels (Minutes) Gamma Shape 5.008 Scale 9.652 N 12 6 Frequency 5 4 3 2 1 0 20 45 70 95 Inspection Time (Minutes) VISUAL INSPECTION RESEARCH PROJECT REPORT ON BENCHMARK INSPECTIONS FAA Aging Aircraft NDI Validation Center Inspection Process Modeled In Simulation Design of a System for Aircraft Fuselage Inspection 20 Context: Stakeholder Analysis Interactions, Tensions and Gap Design of a System for Aircraft Fuselage Inspection 21 Context: Problem and Need Issues Problem Current Inspection Process Consequences Time Heavy D Check Inspection Process Requires up to 2 months to Complete Aircraft maintenance/repair 12-15% of total airline annual expenditures Cost In 2013, 3.5 million flight cycles logged over 2,660 aircraft Average $2,652 per flight cycle Amounts to $9.4 billion total Quality 43.7% Type 2 Error (Missed Detection) 11 Airworthiness Directives Issued to Address Fuselage Cracking Solutions Need Improved Inspection Process Benefits Reduce Time Required for Inspections Decreased Inspection Costs Early Detection of Structural Fatigue Improved Scheduling of Preventive Maintenance / Minimize Corrective Maintenance Required Reduce Human Error Improved Crack Detection Capabilities Win-Win: New Technology Introduced to Inspection Process Design of a System for Aircraft Fuselage Inspection 22 Agenda Context Concept of Operations • Operational Scenario • Design Alternatives • System and Design Requirements • Automated Inspection System IDEF.0 Method of Analysis Project Plan Design of a System for Aircraft Fuselage Inspection 23 Concept of Operations: Operational Scenario Levels of Human Involvement Inspection Method 2 - Enhanced 1 – Manual ntl.bts.gov aviationpros.com aviationpros.com 3 - Autonomous ConOps Introduces New Technology to Inspection Process Design of a System for Aircraft Fuselage Inspection 24 Concept of Operations: Operational Scenario Non-Contact Delivery Method Synthetic Aperture Imaging Device Track Potential Implementation of Synthetic Aperture Imaging Technology Design of a System for Aircraft Fuselage Inspection 25 Concept of Operations: Design Alternatives Exterior vs. Interior Surfaces Exterior Surfaces Interior surfaces Human Visual Human Visual Human Remote Visual Human Enhanced Visual Human Enhanced Visual Robotic Crawler* Non-Contact Automated Scan* * Utilizes Image Processing Software Limitations of Delivery Method Based on Region of Aircraft Design of a System for Aircraft Fuselage Inspection 26 Concept of Operations: Design Alternatives Benefits by Category Inspection Method Time Cost Quality Visual Visual Inspection time Documentation time Hourly wage of inspectors Training Cost Cost of Human Errors Limited by human eyesight Prone to human error Human decision making only Enhanced Visual Increased Inspection Time Imaging Time Evaluation Time Documentation Time Hourly wage of inspectors Training/certification Maintenance Cost Cost of Human Errors Improved by computer aided decision making Interpretation/ Evaluation of data prone to human errors Automated Faster Inspection Time Imaging Time Software Processing Time Acquisition/Development Cost Installation Cost Training Cost Maintenance Cost Software for image processing reduces errors and eliminates dependence on human decision making PRO CON Design of a System for Aircraft Fuselage Inspection 27 Context: System Requirements Mission and Functional Requirements Context: System Requirements M.1 The system shall reduce the airframe maintenance cost per flight hour of an aircraft by 5% Mission & Functional Requirements F.1. The system shall cost no more than $X to operate annually F.2. The system shall accrue no more than $X in Type 1 errors annually F.3. The system shall require an initial investment of no more than $X F.4. The system shall process captured images at a rate of X m2 per Y seconds M.2 The system shall detect cracks in the airframe of aircraft both visible, and not visible, by a human inspector F.1. The system shall detect cracks with a volume exceeding X mm3 F.2. The system shall have a Type 2 error rate of no more than X% F.3. The system shall distinguish between cracks and pre-built parts of the aircraft F.4. The system shall capture an image of the airframe of the aircraft of dimensions X meters by Y meters without repositioning M.3 The system shall reduce the variance of the airframe inspection process by X labor-hours F.1. The system shall maintain the upper bound of a complete visual inspection at no more than X laborhours F.2. The system shall reduce the variance of the visual inspection process by X labor-hours M.4 The system shall allow aircraft to meet Federal Aviation Administration airworthiness standards Design of a System for Aircraft Fuselage Inspection 28 Context: Non-Functional Requirements Non-Functional Requirements Maintainability 1. The system shall produce traceable error codes upon malfunction. 2. The system shall allow the replacement of individual parts. Reliability 1. The system shall experience no more than X system failures per month. 2. The system shall require no more than X hours of preventative maintenance per month. Usability 1. The system shall require no more than 40 hours of training for technician certification. Design of a System for Aircraft Fuselage Inspection 29 Concept of Operations: Design Requirements Design Requirements Enhanced Visual (Handheld) D.1 The system shall weigh no more than X lbs. D.2 The system shall accurately scan from a distance of up to X m. Robotic Automated Inspection System D.1 The system shall inspect at a rate of X cm3/s. D.2 The system shall support autonomous function. D.3 The system shall accept initial input from an operator. D.4 The system shall utilize integrated software. D.5 The system shall store the location of airframe problem areas. Design of a System for Aircraft Fuselage Inspection 30 Concept of Operations: Automated Inspection System IDEF.0 Design of a System for Aircraft Fuselage Inspection 31 Agenda Context Operational Concept/Approach Method of Analysis • Stochastic Simulation • Model Boundaries & Simulation Inputs/Outputs • Simulation Requirements • Simulation of Visual Inspection By Airframe Region • Case Study Variables & Assumptions • Validation • Design of Experiments Project Plan Design of a System for Aircraft Fuselage Inspection 32 Method of Analysis: Stochastic Simulation Model Boundaries and Simulation Inputs/Outputs Uninspected aircraft Aircraft Maintenance Simulation Manual • Human • Handheld Automated • Visual or thermal • Track or crawler Inputs • • Inspected aircraft • Time per inspection • Inspection & Section • Cost per inspection • Labor hours • Implementing alt. • Quality per inspection • Type 1 & 2 errors Outputs What design alternatives are utilized Where design alternative are utilized • • • • • Overall time for inspection Time per section Cracks detected per section Type 1 errors per section Type 2 errors per section Design of a System for Aircraft Fuselage Inspection 33 Method of Analysis: Stochastic Simulation Simulation Requirements Simulation Requirements The simulation shall break down the aircraft into ten sections, each having its own queue The simulation shall support multiple inspectors processing multiple sections The simulation shall assign a set number of cracks to each section of the aircraft The simulation shall terminate upon the inspection of all ten sections of the aircraft The simulation shall collect statistics on total time required for inspection The simulation shall collect statistics on total time to complete each section The simulation shall collect statistics on cracks detected per section The simulation shall collect statistics on crack type one errors Mark a crack where one would not register with an NDT The simulation shall collect statistics on crack type two errors Fail to mark a crack that exists Design of a System for Aircraft Fuselage Inspection 34 Method of Analysis: Stochastic Simulation Visual Inspection By Airframe Region Initialization Statistics Process Design of a System for Aircraft Fuselage Inspection 35 Method of Analysis: Stochastic Simulation Initialization Assignments Manual / Automated (binary) Process Restrictions (binary) Process Distributions (minutes) Crack Detection Rate (%) Type 1 Error Rate (%) Type 2 Error Rate (%) Design of a System for Aircraft Fuselage Inspection 36 Method of Analysis: Stochastic Simulation Process Design of a System for Aircraft Fuselage Inspection 37 Method of Analysis: Stochastic Simulation Statistics Design of a System for Aircraft Fuselage Inspection 38 Method of Analysis: Stochastic Simulation Distributions At a Glance VISUAL INSPECTION RESEARCH PROJECT REPORT ON BENCHMARK INSPECTIONS FAA Aging Aircraft NDI Validation Center Design of a System for Aircraft Fuselage Inspection 39 Method of Analysis Design of Experiments Inputs Outputs Run Internal / External Technology Delivery Method Type One Error Rate Type Two Error Rate 1 Internal Human -- % % External Human -- Internal Human -- External Thermographic Crawler Internal Synthetic Aperture Handheld External Thermographic Crawler 2 3 Inspection Cost of Time Inspection Hours Dollars … Design of a System for Aircraft Fuselage Inspection 40 Simulation Preliminary Results Sample Output (Time per Process) Section Minutes Design of a System for Aircraft Fuselage Inspection Half-Width 41 As-Is Simulation Preliminary Results Validation (Expected vs Simulation) Section Actual (mins) Simulated (mins) Diff (mins) % err 1 122 116.47 -5.53 -4.53 2 28 27.83 -0.17 -0.61 3 75 75.38 0.38 0.51 4 68 67.71 -0.29 -0.43 5 37 36.1 -0.9 -2.43 6 104 105.64 1.64 1.58 7 95 100.23 5.23 5.51 8 35 34.68 -0.32 -0.91 9 16 15.2 -0.8 -5.00 10 48 49.56 1.56 3.25 Actual Total (mins) Sim Total (mins) Diff (mins) % err 628 628.81 Sim Half Width (mins) 0.81 <0.1% 6.18 Design of a System for Aircraft Fuselage Inspection 42 Agenda Context Operational Concept/Approach Method of Analysis Project Plan • WBS/Schedule • Critical Path/Project Risks • Budget/Performance Design of a System for Aircraft Fuselage Inspection 43 Project Plan: Work Breakdown Schedule Aircraft Inspection Project 1.1 Management 1.2 Research 1.2.1 1.3 CONOPS 1.4 Originating Requirements 1.3.1 Context Analysis 1.4.1 Stakeholders Requirements 1.2.2 Kick-off Presenation Research 1.3.2 Stakeholder Analysis 1.4.2 Performance Requirements 1.2.3 Team Research 1.3.3 Problem Statement 1.4.3 Application Requirements 1.3.4 Need Statement 1.1.5 Meetings with Professors 1.5 Design Alternatives 1.6.1 Initial Simulation Analysis 1.7 Test 1.8 Design 1.13 Competitions 1.12.2 Proposal 1.9.3 Simulation Programming 1.11.3 Brief 3 1.13.3 UVA 1.4.4 Analysis of Requirements 1.11.4 Brief 4 1.13.4 West Point 1.3.5 Operational Concept 1.4.5 Qualify the qualification system 1.11.5 Faculty Presentation 1.1.6 Individual Meetings 1.3.6 System Boundary 1.4.6 Obtain Approval of Syst. Documentation 1.11.6 Final Fall Presentation 1.1.7 1.3.7 System Objectives 1.4.7 Functional Requirements 1.3.8 Statement of Work 1.4.8 Design Requirements 1.1.3 Email Communication s 1.1.4 Sponsor Meetings Team Meetings 1.1.8 WBS Upkeep 1.3.9 Budget 1.3.10 Project Risks 1.8.2 Refine DoE 1.12 Documentation 1.11.2 Brief 2 1.6.2 Sensitivity Analysis 1.9.1 Simulation Requirements 1.11 Presentations 1.9.2 Simulation Design 1.1.2 Acc.Summary 1.8.1 Initial Design of Experiment 1.10 Testing 1.12.1 Preliminary Project Plan Lead Initial Research 1.7.1 Verification and Validation 1.9 Simulation 1.11.1 Brief 1 1.1.1 Timesheets 1.5.1 Develop Design Alternatives 1.6 Analysis Simulation Debugging 1.13.1 Conference Paper 1.13.2 Poster 1.1 Management 1.2 Research 1.3 CONOPS 1.4 Originating Requirements 1.5 Design Alternatives 1.6 Analysis 1.7 Test (V/V) 1.8 Design 1.9 Simulation 1.10 Testing (Simulation) 1.11 Competitions Design of a System for Aircraft Fuselage Inspection 44 Project Plan: Critical Path Critical Path 1.4 Originating Requirements 1.5 Design Alternatives 1.6 Analysis 1.7 Test 1.8 Design 1.9 Simulation 1.10 Testing Design of a System for Aircraft Fuselage Inspection 45 Project Plan: Project Risks Critical Tasks Acquire technology specifications Foreseeable Risk Sponsor does not share information from Sponsor Acquire data on inspection tasks Mitigation Routes Alter design to trade off analysis of crack inspection methods Data is not available/accessible Use reasonable estimates based on available data Quantify requirements Data is not available/accessible Use reasonable estimates based on available data Sensitivity Analysis Data does not correspond to industry Ensure simulation is built correctly, practices may need further development Design of a System for Aircraft Fuselage Inspection 46 Project Plan: Budget/Performance 31-Aug 1 $913.40 $608.93 $0.00 $0.00 $0.00 $0.00 $0.00 $0.00 $0.00 $0.00 $86.99 $0.00 $0.00 40 $1,739.80 7-Sep 2 $1,130.87 $565.44 $0.00 $0.00 $0.00 $0.00 $0.00 $0.00 $0.00 $0.00 $86.99 $0.00 $0.00 50 $2,174.75 14-Sep 3 $1,652.81 $565.44 $260.97 $0.00 $0.00 $0.00 $0.00 $0.00 $0.00 $0.00 $1,000.39 $0.00 $0.00 60 $2,609.70 21-Sep 4 $598.06 $521.94 $391.46 $0.00 $0.00 $0.00 $0.00 $521.94 $217.48 $0.00 $391.46 $0.00 $0.00 60 $2,609.70 Cumulative Planned Value (PV) $1,739.80 $3,914.55 $6,524.25 $9,133.95 WBS Task Name TBC 1 2 3 4 5 6 7 8 9 10 11 12 13 Management Research CONOPS Originating Requirements Design Alternatives Analysis Test Design Simulation Testing Presentations Documantation Competitions Total Budgeted Hours Total Budgeted Cost $6,100.17 $3,958.05 $1,652.81 $391.46 $217.48 $0.00 $0.00 $565.44 $1,261.36 $0.00 $3,349.12 $826.41 $0.00 2,125 $92,426.88 Cost Variance (CV = EV - AC) Schedule Variance (SV = EV - PV) Cost Performance Index (CPI = EV/AC) Schedule Performance Index (SPI = EV/PV) Estimated Cost at Completion (EAC) -$518.68 -649.16 0.68 0.63 $136,382.63 -$1,075.78 -1597.72 0.68 0.59 $135,343.48 -$463.95 -115.99 0.93 0.98 $99,118.41 $466.03 846.61 1.05 1.09 $88,111.11 $1,672.74 2118.56 1.14 1.18 $81,273.83 $2,065.16 1858.56 1.15 1.13 $80,653.05 $1,808.75 819.24 1.11 1.05 $83,025.53 $2,674.24 553.86 1.15 1.03 $80,654.84 Hourly Rate: $43.50/hr Design of a System for Aircraft Fuselage Inspection 47 Project Plan: Budget/Performance Earned Value Weeks 1-38 Design of a System for Aircraft Fuselage Inspection 48 Project Plan: Budget/Performance Earned Value Weeks 1-11 Design of a System for Aircraft Fuselage Inspection 49 Project Plan: Budget/Performance CPI/SPI Weeks 1-11 Design of a System for Aircraft Fuselage Inspection 50 Future Work Now • • • • • • Determine attributes of design alternatives Complete design of experiment Sensitivity analysis Quantify requirements Utility - cost analysis Conclusions February 2016 Design of a System for Aircraft Fuselage Inspection 51 Design of a System for Aircraft Fuselage Inspection 52 Utility Hierarchy Utility Time (-) Non-Functional Quality Maintainability (+) Type 1 Error Rate (-) Reliability (+) Type 2 Error Rate (-) (+) – Higher is better (-) – Lower is better Design of a System for Aircraft Fuselage Inspection 53 IDEF0 Analyze Data Design of a System for Aircraft Fuselage Inspection 54 Arena Total Time Design of a System for Aircraft Fuselage Inspection 55 Project Plan: Budget/Performance United States Department of Labor Bureau of Labor Statistics Occupational Outlook Handbook Occupation 2012 Median Pay Aerospace-Engineers $49.07/hr Industrial-Engineers $37.92/hr http://www.bls.gov/ooh/architecture-and-engineering/aerospace-engineers.htm http://www.bls.gov/ooh/architecture-and-engineering/industrial-engineers.htm Average: $43.50/hr Design of a System for Aircraft Fuselage Inspection 56 Concept of Operations: Design Alternatives Design Alternatives Technology Description Thermographic Imaging Heats area 1-2 degrees, algorithm determines if problematic Synthetic Aperture Imaging Captures 2-D images at different angles to create a 3-D image Contact Non-Contact Contact Non-Contact Delivery Method Description Level of Human Involvement Robotic Crawler Travels along outside of aircraft, scans designated areas. Autonomous Synthetic Aperture, Thermographic Robotic Arm Utilizes track to move around. Autonomous Synthetic Aperture Handheld Scanner carried by inspector Enhanced Synthetic Aperture Design of a System for Aircraft Fuselage Inspection Applicable Technology 57
