International Journal of Aerospace Science, Technology and Engineering(IJASTE)
Aims and Scope
Aim: The International Journal of Aerospace Science, Technology, and Engineering aims to provide a premier platform for researchers and professionals to present their latest findings and methodologies in the field of aerospace. Our objectives include:
- Advancing the scientific understanding of aerospace technologies and their applications.
- Promoting interdisciplinary collaboration and research that addresses challenges in aerospace engineering.
- Encouraging practical applications of research findings to improve aerospace safety, efficiency, and sustainability.
- Supporting the development of innovative solutions in aerospace systems and operations.
Scope: The scope of IJASTE encompasses a wide range of topics related to aerospace science and technology, including but not limited to:
Aerospace Engineering: Structural analysis, materials selection, manufacturing processes, and system integration.
Aerodynamics: Computational fluid dynamics, wind tunnel testing, and aerodynamic performance optimization.
Propulsion Systems: Jet engines, rocket propulsion, fuel efficiency, and sustainable propulsion technologies.
Avionics: Navigation systems, communication technologies, and avionics software development.
Space Technologies: Satellite design, space missions, extraterrestrial exploration, and space systems engineering.
Types of Contributions: We welcome various contributions, including:
- Original research articles presenting new findings.
- Comprehensive reviews summarizing existing knowledge.
- Technical notes detailing preliminary results or novel methodologies.
- Case studies illustrating practical applications and engineering challenges.
Editorial Standards All submissions to IJASTE undergo a thorough peer-review process to maintain the highest standards of quality and ethical integrity. We are committed to upholding transparency and reproducibility in all research published in our journal. We invite you to submit your manuscript and contribute to the advancement of knowledge in aerospace science and technology.
Some of the subject areas that the journal focuses on include:
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Aerospace engineering |
Rocket design |
Wind energy applications |
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Aerodynamics |
In-orbit servicing |
Aerospace regulations |
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Propulsion systems |
Aviation security |
Aerospace policy |
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Avionics |
Environmental assessment |
Autonomous systems |
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Space exploration |
Flight operations |
Human factors engineering |
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Satellite technology |
Model-based systems engineering |
Safety management systems |
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Fluid dynamics |
Satellite applications |
Reliability engineering |
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Aircraft design |
Aerospace telecommunications |
Failure analysis |
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Spacecraft systems |
Advanced flight controls |
Ground testing |
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Aerospace materials |
Landing gear design |
Aerodynamic drag |
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Computational fluid dynamics |
Flight path optimization |
Flight control algorithms |
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Rocket propulsion |
Spacecraft design |
Space debris mitigation |
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Navigation systems |
Robotic exploration |
Propellant technology |
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Control systems |
Ground support equipment |
Environmental monitoring |
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Structural analysis |
Space system engineering |
Health monitoring systems |
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Airframe design |
Crew resource management |
Space law |
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Aerodynamic performance |
Hypersonic vehicles |
Space policy |
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Environmental impact |
Space tourism |
Aerospace manufacturing |
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Sustainable aviation |
Aerial surveys |
Aeronautical research |
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Composite materials |
Flight profile analysis |
Flight testing |
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Aerodynamic optimization |
Aerodynamic testing |
Configuration management |
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Wind tunnel testing |
Aerospace maintenance |
Spacecraft propulsion |
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Flight dynamics |
Satellite deployment |
Aerospace safety |
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Flight simulation |
Atmospheric reentry |
Interplanetary travel |
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Turbomachinery |
Reusable launch vehicles |
Planetary exploration |
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Jet engines |
Aerospace performance metrics |
Crew safety |
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Engine efficiency |
Human-robot interaction |
Space mission architecture |
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Flight safety |
Space science |
Space logistics |
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Air traffic management |
Environmental sustainability |
Engine design |
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Space mission design |
Flight mission analysis |
Propulsion efficiency |
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Launch systems |
Aeropropulsion |
Spacecraft navigation |
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Ground control systems |
Aircraft performance |
Satellite communications |
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Hypersonic flight |
Space technology transfer |
Electric propulsion |
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Aerospace robotics |
Satellite imaging |
Advanced materials |
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Space habitats |
Aerospace cluster development |
Cryogenic propulsion |
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Remote sensing |
Advanced flight systems |
Advanced avionics |
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Orbital mechanics |
Spacecraft systems engineering |
Aerospace simulation |
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Systems engineering |
Control theory in aerospace |
Data analytics in aerospace |
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Multidisciplinary design optimization |
Aerospace quality assurance |
Rocket staging |
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Composite structures |
Flight simulator technology |
Lift-off dynamics |
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Thermal analysis |
Satellite orbits |
Orbital insertion |
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Structural health monitoring |
Telemetry systems |
Aerothermodynamics |
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Materials science |
Remote piloting |
Hypersonics |
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Smart materials |
Spacecraft thermal management |
Aerospace research funding |
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Additive manufacturing |
Collaborative design |
Aerospace startups |
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Aeronautical engineering |
Aviation industry trends |
Space innovation |
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Drone technology |
Space environment effects |
Payload deployment |
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Unmanned aerial vehicles (UAVs) |
Aerospace workforce development |
Test and evaluation |
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Aircraft maintenance |
Aerospace investment |
International space law |
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Avionic systems |
Astronaut training |
Space industry growth |
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Mission planning |
Aerospace conferences |
Aerospace ethics |
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Payload integration |
Airworthiness certification |
Multiphysics simulations |
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Aerospace education |
Remote sensing technologies |
Air transportation systems |
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Aircraft safety systems |
Aerospace partnerships |
International space collaborations |
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Research and development in aerospace |
Data fusion in aerospace |
Environmental impacts of aviation |
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Advanced composites |
Air vehicle design |
Aircraft systems integration |
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Aircraft structural integrity |
Space entrepreneurship |
Orbital dynamics |
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Space communication networks |
Flight data monitoring |
Aerospace predictive modeling |
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Cybersecurity in aerospace |
Aerospace patents |
Space exploration technologies |
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Engineering ethics in aerospace |
Space and aviation policies |
Urban air mobility |
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Aerospace project funding |
Composite fabrication techniques |
Aerospace project management |
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Flight training systems |
Satellite network design |
Space robotics |
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Satellite telemetry |
Aerospace product lifecycle management |
Aviation human factors |
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Rocket science |
Innovation in aerospace education |
Space technology innovations |
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Aeronautical innovations |
Climate change impacts on aviation |
Aviation maintenance |
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Aerospace technology assessment |
Rocket staging technology |
Aerospace product development |
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Space operations |
Space law and policy |
Air traffic control systems |
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Spacecraft autonomy |
Space-related technologies |
Flight systems engineering |