479.575 PEOPLE
People | Locations | Statistics |
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Ziakopoulos, Apostolos | Athens |
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Vigliani, Alessandro | Turin |
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Catani, Jacopo | Rome |
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Statheros, Thomas | Stevenage |
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Utriainen, Roni | Tampere |
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Guglieri, Giorgio | Turin |
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Martínez Sánchez, Joaquín |
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Tobolar, Jakub |
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Volodarets, M. |
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Piwowar, Piotr |
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Tennoy, Aud | Oslo |
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Matos, Ana Rita |
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Cicevic, Svetlana |
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Sommer, Carsten | Kassel |
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Liu, Meiqi |
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Pirdavani, Ali | Hasselt |
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Niklaß, Malte |
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Lima, Pedro | Braga |
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Turunen, Anu W. |
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Antunes, Carlos Henggeler |
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Krasnov, Oleg A. |
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Lopes, Joao P. |
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Turan, Osman |
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Lučanin, Vojkan | Belgrade |
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Tanaskovic, Jovan |
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Stappert, Sven
in Cooperation with on an Cooperation-Score of 37%
Topics
- aircraft
- modeling
- propulsion
- simulation
- flight
- trajectory
- altitude
- profit
- aerodynamic
- launch vehicle
- rope
- sea
- ocean
- weight
- landing
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- drone
- velocity
- system design
- flight test
- data
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- geometry
- data file
- deviation
- fluid
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- angle of attack
- beltway
- control device
- vibration
- region
- industry
- stakeholder
- definition
- recommendation
- airplane
- technological innovation
- control system
- gust
- estimating
- takeoff
- costs
- Research Context United States of America
- deceleration
- state of the art
- atmosphere
- desert
- high speed vehicle
- engine
- implementation
- research project
- insulating material
- astronautics
- system analysis
- assessment
- ship
- infrastructure
- production
- turbine
- turbine engine
- aircraft operation
- workload
- ship operation
- emergency
- passenger
- chemical element
- behavior
- vehicle occupant
- architecture
- engineering
- passenger traffic
- iterative method
- ejection
- vehicle occupant rescue
- history
- shipment
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Publications (17/17 displayed)
- 2022Simulation and Analysis of Pull-Up Manoeuvre during In-Air Capturing of a Reusable Launch Vehicle
- 2022In-Air-Capturing Development Roadmap (Update)
- 2022Full-scale simulation and analysis of formation flight during in-air-capturing of a winged reusable launch vehicle
- 2022Developing an innovative and high-performance method for recovering reusable launcher stages: The in-air-capturing method
- 2022A Superposition Approach to Aerodynamic Modelling of a Capturing Device used for In-Air Capturing of a Reusable Launch Vehicle
- 2022Control Design and Analysis of a Capturing Device Performing In-Air Capturing of a Reusable Launch Vehicle
- 2022RLV-Return Mode “In-Air-Capturing” and Definition of its Development Roadmap
- 2021DYNAMIC MODELLING AND CONTROL OF AN AERODYNAMICALLY CONTROLLED CAPTURING DEVICE FOR ‘IN-AIR-CAPTURING’ OF A REUSABLE LAUNCH VEHICLE
- 2021A Full-Scale Simulation and Analysis of Formation Flight during In-Air Capturing
- 2020In-Air-Capturing Development Roadmap (State of the Art)
- 2019Highly Efficient RLV-Return Mode “In-Air-Capturing” Progressing by Preparation of Subscale Flight Tests
- 2019Focused research on RLV-technologies: the DLR project AKIRA
- 2019A Systematic Assessment and Comparison of Reusable First Stage Return Options
- 2019Ultra-Fast Passenger Transport Options Enabled by Reusable Launch Vehicles
- 2019Status of DLR investigations: „in-air-capturing“ history, interest for RLV, simulation & analyses
- 2018Bringing Highly Efficient RLV-Return Mode "In-Air-Capturing" to Reality
- 2017FORSCHUNG AN SYSTEMEN UND TECHNOLOGIEN FÜR WIEDERVERWENDBARE RAUMTRANSPORTSYSTEME IM DLR-PROJEKT AKIRA
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