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6th International Conference on Aerospace & Aerodynamics, will be organized around the theme “Assisting to achieve new avenues of Aerospace”
Aerospace 2018 is comprised of keynote and speakers sessions on latest cutting edge research designed to offer comprehensive global discussions that address current issues in Aerospace 2018
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Energy materials within the past meant high energy explosive materials utilized in detonation and alternative energy storage applications. Such energy cannot be regulated for extended period. Currently energy materials embody wide selection of advanced and novel materials for the generation and storage of electric power. Energy generation, management and distribution are the quickest evolving industries of recent times. The demand to develop parts and sub-assemblies for novel product across the energy sector is increasing.
2nd Global Summit and Expo on Fluid Dynamics and Aerodynamics Conferences, October 19-20, 2017, Rome, Italy; 3rdWorld Conferences on Green Energy, September 28-29, 2017, Berlin, Germany;
- Track 1-1Solar energy
- Track 1-2Wind energy
- Track 1-3Chemical looping
- Track 1-4Application of renewable energy in Aerospace Industries
- Track 1-5Thermoelectric Materials
- Track 2-1Aeronautical engineering
- Track 2-2Astronautical engineering
- Track 2-3Electrotechnology
- Track 2-4Aeroelasticity
The aerospace design process is the engineering design process by which aircrafts or spacecrafts are designed. These depend on many factors such as customer and manufacturer demand, safety protocols, physical and economic constraints etc. Designing is done by taking into account some constraints these consist of Purpose, Aircraft regulations, Financial factors and market, Environmental factors and safety.
- Track 3-1Wing design
- Track 3-2Fuselage
- Track 3-3Aircraft Structure
- Track 3-4Advanced flow diagnostics and instrumentation
- Track 3-5Aircraft icing physics and anti-/de-icing technology
- Track 3-6Aircraft and wind turbine icing
Aeronautics is the study of the science of flight. Aeronautics is the method of designing an airplane or other flying machine. There are four basic areas that aeronautical engineers must understand in order to be able to design planes. To design a plane, engineers must understand all of these elements. These include Stability and control, Materials and structures, Propulsion and Aerodynamics.
Aeronautical engineering deals with construction, design, as well as the study of aircraft that is purposed to stay within the atmosphere of the earth, while performing the necessary operations and tasks. These aircrafts include helicopters and airplanes.
- Track 4-1Aeronautical physics
- Track 4-2ATC (Air Traffic Control)
- Track 4-3Airfoil Technology
- Track 4-4Aircraft structures
Communications Satellite relays and amplifies radio telecommunications signals through a transponder. It creates a communication channel between source transmitter and receiver at different locations on Earth. Wireless Communication utilizes electromagnetic waves to carry signals. The purpose of communications satellites is to relay the signal around the curvature of the Earth allowing communication between widely separated points. To avoid signal interference, International organizations have regulations for which Frequency Bands are allotted to use. This allocation of bands minimizes the risk of signal interference.
Satellites orbit Earth at different heights, speeds and along different paths. The two most common types of orbit are "geostationary and "polar." A Geostationary Satellite travels from west to east over the equator. Following are the applications:
Fixed Service Satellite: FSS is the official classification for geostationary communications satellites used chiefly for broadcast feeds for television and radio stations and networks, as well as for telecommunication, Data Communications, and also for Direct-To-Home (DTH) cable and satellite TV channels.
Direct Broadcast Satellite: DBS is a term used to refer to satellite television broadcasts intended for home reception, also referred to as direct-to-home signals. It covers both analogue and Digital Television and radio reception, and is often extended to other services provided by modern digital television systems, including video-on-demand and interactive features. A "DBS service" usually refers to either a commercial service or a group of free channels available from one orbital position targeting one country.
Satellite Broadband: In recent years, Satellite Communication Technology has been used as a means to connect to the internet via broadband data connections. This is very useful for users to test who are located in very remote areas, and can't access a wire line broadband or dialup connection.
4thInternational Conference on Actual Problems Of Unmanned Aerial Vehicles Developments, 17 Oct 2017 - 19 Oct 2017 ,Kiev, Ukraine ; Aerospace Structural Impact Dynamics International Conference,17 Oct 2017 - 19 Oct 2017, Wichita, Kansas, United States;
- Track 5-1
- Track 5-2
- Track 5-3Earth Observation Satellites
- Track 5-4Mobile Satellite Technology
- Track 5-5Space Communication and Navigation
- Track 5-6Space Communication and Navigation
Astronautical engineering often deals with the main design, manufacturing, as well as the science of aircraft needed in order to perform and function outside the atmosphere of the earth. This sub field of aerospace engineering generally deals with space stations and rocket satellites
Aerospace Conference, 03 Mar 2018 - 10 Mar 2018, Big Sky, MT, United States; China Air Logistics Development Conference And Exhibition 2018, 28 Mar 2018 - 29 Mar 2018, Beijing, China;
- Track 6-1Astrodynamics
- Track 6-2Spacecraft design
- Track 6-3Atmospheric entry
- Track 6-4Spacecraft propulsion
Climate change reffers to change in average weather conditions. Climate change is caused by biotic processes, variations in solar radiation received by Earth, Plate Tectonics, and volcanic eruptions .Weather Forecasting is the application of science and technology to predict the state of the atmosphere for a given location. Weather warnings are important forecasts because they are used to protect life and property. However, satellite imagery can also undergo various types of quantitative processing to obtain information on important Meteorological variables such as wind speed and direction, cloud height, surface temperature, sea ice cover, vegetation cover, precipitation, etc.
2nd International Conference On Mechanical, Material And Aerospace Engineering, 10 May 2018 - 13 May 2018, Wuhan, China; International Conference On Unmanned Aircraft Systems, 12 Jun 2018 - 15 Jun 2018, Dallas, TX, United States; Aviation Electronics Europe, 19 Jun 2018 - 20 Jun 2018, Munich, Germany;
- Track 7-1Weather Forecasting Satellite Payloads
- Track 7-2Image Processing and Analysis
- Track 7-3Weather Forecasting Satellite Applications
- Track 7-4Weather Forecasting Satellite Missions
Materials Science and Engineering is an acclaimed scientific discipline, expanding in recent decades to surround polymers, ceramics, glass, composite materials and biomaterials. Material science and engineering, involves the discovery and design of new materials. Many of the most pressing scientific problems humans currently face are due to the limitations of the materials that are available and, as a result, major breakthroughs in materials science are likely to affect the future of technology significantly. Materials scientists lay stress on understanding how the history of a material influences its structure, and thus its properties and performance. All engineered products from airplanes to musical instrumets, alternative energy sources related to ecologically-friendly manufacturing processes, medical devices to artificial tissues, computer chips to data storage devices and many more are made from materials. In fact, all new and altered materials are often at the heart of product innovation in highly diverse applications. The global market is projected to reach $6,000 million by 2020 and lodge a CAGR of 10.2% between 2015 and 2020 in terms of worth. The North American region remains the largest market, accompanied by Asia-Pacific. The Europe market is estimated to be growth at a steady rate due to economic redeem in the region along with the expanding concern for the building insulation and energy savings.
- Track 8-1Electrical and magnetic properties of materials
- Track 8-2Organic materials
- Track 8-3Heat treatment
- Track 8-4Phase transformation
- Track 8-5Semiconductor materials
- Track 8-6Theory of alloys
- Track 8-7Deformation of materials
It is a field that explains about the specialized side of aviation missions instead of flight preparing or support administration. It Includes Communications satellite applications, Remote detecting satellite applications, Navigation satellite applications, Satellite and launcher innovation, Ultra wideband advances for space applications, Astrophysics and Astrobiology.
- Track 9-1Communications satellite applications
- Track 9-2Remote sensing satellite applications
- Track 9-3Navigation satellite applications
- Track 9-4Satellite and launcher technology
- Track 9-5Ultra wideband technologies for space applications
- Track 9-6Science & astronomy
- Track 9-7Astrobiology
Fluid Mechanics deals with the mechanical properties of gasses and fluids. Fluid Mechanics can be divided into liquid statics,( the investigation of liquids very still) or liquid motion,( the investigation of the impact of powers on smooth movement.) It incorporates these sub tracks Fluid-strong mechanics, Knots and connects in liquid mechanics, Stress and strain in liquid mechanics, Thermo liquid mechanics, Computational liquid progress and Fluid elements. of gasses and fluids. Fluid Mechanics can be divided into liquid statics,( the investigation of liquids very still) or liquid motion,( the investigation of the impact of powers on smooth movement.) It incorporates these sub tracks Fluid-strong mechanics, Knots and connects in liquid mechanics, Stress and strain in liquid mechanics, Thermo liquid mechanics, Computational liquid progress and Fluid elements.
Fluid dynamics helps us to understand the various aspects of nature like ocean currents, weather pattern and even blood circulation. Some of the technological and industrial features are
1 calculating mass flow rate in the pipeline
2 calculating various forces on aircrafts
42nd Cospar Scientific Assembly And Associated Events, 14 Jul 2018 - 22 Jul 2018, Pasadena, United States; 2018 IEEE Autotestcon, 17 Sep 2018 - 20 Sep 2018, National Harbor (Oxin Hill), MD, United States; Avionics And Vehicle Fiber-Optics And Photonics Conference, 06 Nov 2018 - 08 Nov 2018, Portland, OR, United States;
- Track 10-1Fluid Kinematics
- Track 10-2Computational fluid dynamics
- Track 10-3Fluid-solid mechanics
- Track 10-4incompressible fluids
- Track 10-5Critical fluid connective flow
- Track 10-6Astrodynamics
- Track 10-7Mach Regimes
Aerodynamics is the method air travels around things. A streamlined feature is a sub-field of liquid elements and gas flow, and numerous parts of optimal design hypothesis are normal to these fields. It contains Projectile streamlined features, Aero warming, Aero-motor combustors and Aero-versatile displaying.
Aerodynamics provides an understanding of the aerodynamic behaviour of aircraft, coupled with knowledge of flow control, flow assessment and simulation techniques will be essential for the design of the next generation of manned aircraft and Unmanned Aerial Vehicles (UAVs).
- Track 11-1Projectile aerodynamics
- Track 11-2Aero-elastic modelling
- Track 11-3Wind tunnel
- Track 11-4Supersonic flight
- Track 11-5Flight envelope
- Track 11-6Supercritical wings
Avionics is a field concerned with all electrical equipment used in missiles, aircraft and spacecraft. Avionics deals with components the pilot directly uses, such as weather, navigation, radar, and radio communication equipment. In addition, avionics also encompasses of other electronic systems not directly used by the pilot like the ones for control and monitoring of flight and engine performance
- Track 12-1Navigation Systems
- Track 12-2Autopilots and flight management system
- Track 12-3Unmanned Aerial Vehicles
- Track 12-4Avionics Systems Integration
Heat transfer happens usually by three methods. Conduction in solids ,Convection in fluids (liquids or gases), and radiation through anything that will allow radiation to pass. These selection of method used to transfer heat is usually done by considering the efficiency delivered. Heat Transfer plays a major role in designing aerospace vehicles since high heat generation occurs during its operation.
- Track 13-1Heat transfer in electronic equipment
- Track 13-2Heat transfer in fire and combustion
- Track 13-3Heat transfer in multiphase systems
- Track 13-4Aerothermodynamics
- Track 13-5Aerodynamic heating
- Track 14-1aeroacoustic measurements
- Track 14-2Aerodynamic sound mitigation
- Track 14-3Sonic boom
- Track 14-4Acoustic-vortical waves
- Track 14-5Thermoacoustics
- Track 14-6Computational Aeroacoustics
This is a method used to accelerate spacecraft and artificial satellites. There are many different methods. Each method has drawbacks and advantages, and spacecraft propulsion is an active area of research. However, most spacecraft today are propelled by forcing a gas from the back/rear of the vehicle at very high speed.
- Track 15-1Hybrid Rockets
- Track 15-2Non conventional Propulsion Techniques
- Track 15-3Solid and Liquid Propellants
- Track 15-4Nuclear Thermal Rocket Technology
- Track 15-5Electric Propulsion
- Track 15-6Rocket engines
- Track 15-7Air Breathing Propulsion
The UAV is an acronym for Unmanned Aerial Vehicle, which is an aircraft with no pilot on board. UAVs can be remote controlled aircraft (e.g. flown by a pilot at a ground control station) or can fly autonomously based on pre-programmed flight plans or more complex dynamic automation systems. UAVs are currently used for a number of missions, including reconnaissance and attack roles. For the purposes of this article, and to distinguish UAVs from missiles, a UAV is defined as being capable of controlled, sustained level flight and powered by a jet or reciprocating engine. Also a cruise missile can be considered to be a UAV, but is treated separately on the basis that the vehicle is the weapon. The acronym UAV has been expanded in some cases to UAVS (Unmanned Aircraft Vehicle System). The FAA has adopted the acronym UAS (Unmanned Aircraft System) to reflect the fact that these complex systems include ground stations and other elements besides the actual air borne vehicles.
- Track 16-1Aerodynamics and air frame configurations
- Track 16-2Design for stealth
- Track 16-3Payload types
- Track 16-4Control station for UAV
- Track 16-5Communication between Control station and UAV
- Track 16-6Control and Stability of UAV
- Track 16-7State Space Control
An airship or aircraft is a type of aerostat or lighter-than-air aircraft which can circumnavigate through the air under its own power. It includes remotely organized airship design, Bio inspired and bio-mimetic micro flyers, Electric aircraft concept for unmanned air vehicles and armed flight, Remotely organized airship design and Design and modeling of solar-powered aircrafts
- Track 17-1Remotely controlled airship design
- Track 17-2Bio inspired and bio-mimetic micro flyers
- Track 17-3Trajectory optimization for stratospheric airship
- Track 17-4Electric aircraft concept for unmanned air vehicles and military aviation
- Track 17-5Design and modelling of solar-powered aircrafts
- Track 17-6Hydrogen powered aircrafts- future technology
- Track 17-7Thermal Protection System
Fundamentally we have to discern between the stability of the aircraft to external impetus, with and without the pilot responding to the perturbation. Here we will limit ourselves to the inherent stability of the aircraft. Hence the aircraft is said to be stable if it returns back to its original equilibrium state after a small perturbing displacement, without the pilot intervening. Thus, the aircraft’s response arises purely from the inherent design. At level flight we tend to refer to this as static stability. In effect the airplane is statically stable when it returns to the original steady flight condition after a small disturbance; statically unstable when it continues to move away from the original steady flight condition upon a disturbance; and neutrally stable when it remains steady in a new condition upon a disturbance. The second and more pernicious type of stability is dynamic stability. The airplane may converge continuously back to the original steady flight state; it may overcorrect and then converge to the original configuration in a oscillatory manner; or it can diverge completely and behave uncontrollably, in which case the pilot is well-advised to intervene. Static instability naturally implies dynamic instability, but static stability does not generally guarantee dynamic stability.
- Track 18-1Static analysis
- Track 18-2Dynamic Analysis
- Track 18-3Aircraft dynamics
- Track 18-4Control of Aircraft Motions
- Track 18-5Vibration Control Engineering
Mechanics of space flight deals with motion of space vehicles. These include satellites, probes and capsules, which belong to the category of non-winged re-entry vehicles (RV-NW), orbiters from the category of winged re-entry vehicles (RV-W), but also air breathing cruise and acceleration vehicles (CAV).Flight mechanics is the application of Newton’s laws (F=ma and M=Iα) to the study of vehicle trajectories (performance), stability, and aerodynamic control. This field includes research that establishes new theoretical results, defines new computational algorithms, performs unique analysis and experiments, and creates technology that changes engineering practice. Advancements from this research are applied to airplanes, rotorcraft, launch vehicles, satellites, space probes, missiles, projectiles, parachutes, Para foils, the air transportation system, and others.
- Track 19-1Satellite Tracking
- Track 19-2Orbital Maneuvers
- Track 19-3Trajectory analysis
- Track 19-4Stability and control
- Track 19-5Flight controls
Aerospace manufacturers are now facing with a backlog of orders. To address that dilemma, they need to automate their factories. The industry is investing heavily in flexible systems that reduce cost, improve quality and boost productivity
Given the importance of safety for the aircraft industry, achieving maximum precision is essential for aerospace manufacturers. Needless to say, cost also plays a major role in determining priorities along the value chain.
- Track 20-1Control Engineering
- Track 20-2Industrial Automation
- Track 20-3Robotics
- Track 20-4Micro-Electro-Mechanical System
SpaceX is developing a family of launch vehicles intended to reduce the cost and increase the reliability of access to space. The SpaceX design and manufacturing facilities are located in Southern California, near the Los Angeles airport, and the propulsion development and structural test facilities are located in Central Texas.The Falcon 9 is a 2-stage launch vehicle powered by LOX/RP engines. The first stage generates 765,000 1bf of thrust (sea-level) using nine Merlin engines, and the second stage generates 96,000 1bf (vacuum) using a single Merlin engine. Both stages use gimbaled engines for guidance. Falcon 9 offers engine-out capability for the first stage.
- Track 21-1Planets and Moon
- Track 21-2Solar system
- Track 21-3Space weather
- Track 21-4Asteroids and comets
- Track 21-5Mars Exploration
- Track 21-6Astrophysics
- Track 21-7Robotics Application