Difference between revisions of "Private Bee 3D GPS"
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Presentation of work done for a 3D GPS | Presentation of work done for a 3D GPS | ||
+ | Project is to calculate an optimized flight path with IA. | ||
− | + | ||
+ | == Path Flight Optimization == | ||
+ | |||
+ | Presentation : | ||
+ | [[File:BELMANT-CLERC-DIAPORAMA.pdf]] | ||
+ | |||
+ | Final report : | ||
+ | [[File:Insa minibee gps final.pdf]] | ||
+ | |||
+ | |||
+ | Objectives | ||
+ | Develop a Hybrid VTOL (Vertical Take-Off and Landing) aircraft for flying ambulance applications. | ||
+ | Navigate optimally in a 3D environment from point S to F. | ||
+ | Key Features | ||
+ | 3D collaborative GPS system. | ||
+ | Obstacle avoidance, accounting for static and dynamic objects. | ||
+ | Meteorological constraints integrated into the flight model. | ||
+ | Fuel consumption and flight time minimization. | ||
+ | Methodology | ||
+ | Physical Modeling: Uses control inputs for thrust and angular velocity to define state equations | ||
+ | Cost Function: Linear combination of flight time and fuel consumption for optimization. | ||
+ | Constraints: Involves end-to-end states, control bounds, and obstacle avoidance. | ||
+ | Optimization Techniques | ||
+ | Generalized LQR, Approximate Dynamic Programming, Finite Elements, and Pseudospectral methods reviewed. | ||
+ | Legendre Pseudospectral method chosen for resolution due to proven convergence. | ||
+ | Resolution | ||
+ | Transformation to Finite Dimensional Problem using polynomial basis. | ||
+ | Legendre Pseudospectral method applied for solving nonlinear optimization problem. | ||
+ | Challenges | ||
+ | Complex constraints on flight parameters. | ||
+ | Ensuring real-time collaboration and efficient flight management. | ||
+ | Applications | ||
+ | Use case in flying ambulance service. | ||
+ | Applicable to broader range of aerial navigation tasks, such as drone routing, search and rescue. | ||
+ | This summary aligns well with existing optimization concerns in supply chain management and other industrial applications, particularly in navigating complex constraint environments. | ||
+ | |||
+ | == 3D GPS == | ||
[[File:Présentation 14 03 2019.pdf]] | [[File:Présentation 14 03 2019.pdf]] | ||
Line 15: | Line 52: | ||
* Aircraft takeoff<BR> | * Aircraft takeoff<BR> | ||
[[File:Rapport Bee-plane.pdf]] | [[File:Rapport Bee-plane.pdf]] | ||
+ | |||
+ | == Presentation of 3D GPS Flight Optimization Project == | ||
+ | |||
+ | In our relentless pursuit of cutting-edge aviation technology, we present the remarkable work accomplished in the realm of 3D GPS flight optimization, specifically designed to calculate an optimized flight path using artificial intelligence (AI). | ||
+ | |||
+ | === Path Flight Optimization === | ||
+ | Presentation: [[File:BELMANT-CLERC-DIAPORAMA.pdf]] | ||
+ | Final Report: [[File:Insa minibee gps final.pdf]] | ||
+ | |||
+ | Objectives | ||
+ | Our primary objective was to develop a Hybrid VTOL (Vertical Take-Off and Landing) aircraft with a specific focus on its application as a flying ambulance. This project aimed to navigate optimally in a complex 3D environment from point S to F. | ||
+ | |||
+ | Key Features | ||
+ | |||
+ | 3D collaborative GPS system. | ||
+ | Advanced obstacle avoidance capabilities, considering both static and dynamic objects. | ||
+ | Integration of meteorological constraints into the flight model. | ||
+ | Minimization of fuel consumption and flight time. | ||
+ | Methodology | ||
+ | The project's methodology included: | ||
+ | |||
+ | Physical modeling, utilizing control inputs for thrust and angular velocity to define state equations. | ||
+ | A cost function that combined flight time and fuel consumption for optimization. | ||
+ | Comprehensive constraints, covering end-to-end states, control bounds, and obstacle avoidance. | ||
+ | Optimization Techniques | ||
+ | We explored a range of optimization techniques, including Generalized LQR, Approximate Dynamic Programming, Finite Elements, and Pseudospectral methods. Ultimately, the Legendre Pseudospectral method was selected for resolution due to its proven convergence. | ||
+ | |||
+ | Resolution | ||
+ | To solve the nonlinear optimization problem, we employed the Legendre Pseudospectral method, transforming it into a finite-dimensional problem using polynomial basis functions. | ||
+ | |||
+ | Challenges | ||
+ | The project was not without its challenges, particularly in managing complex flight parameter constraints and ensuring real-time collaboration for efficient flight management. | ||
+ | |||
+ | Applications | ||
+ | While initially designed for use in flying ambulance services, the insights and technology developed in this project hold broader applications in the field of aerial navigation. These extend to drone routing, search and rescue operations, and beyond. | ||
+ | |||
+ | This summary underscores the project's alignment with existing optimization concerns in supply chain management and various industrial applications, especially in navigating intricate constraint environments. | ||
+ | |||
+ | [[Category:Private Bee 3D GPS]] |
Latest revision as of 14:52, 29 September 2023
Presentation of work done for a 3D GPS
Project is to calculate an optimized flight path with IA.
Path Flight Optimization
Presentation : File:BELMANT-CLERC-DIAPORAMA.pdf
Final report : File:Insa minibee gps final.pdf
Objectives
Develop a Hybrid VTOL (Vertical Take-Off and Landing) aircraft for flying ambulance applications.
Navigate optimally in a 3D environment from point S to F.
Key Features
3D collaborative GPS system.
Obstacle avoidance, accounting for static and dynamic objects.
Meteorological constraints integrated into the flight model.
Fuel consumption and flight time minimization.
Methodology
Physical Modeling: Uses control inputs for thrust and angular velocity to define state equations
Cost Function: Linear combination of flight time and fuel consumption for optimization.
Constraints: Involves end-to-end states, control bounds, and obstacle avoidance.
Optimization Techniques
Generalized LQR, Approximate Dynamic Programming, Finite Elements, and Pseudospectral methods reviewed.
Legendre Pseudospectral method chosen for resolution due to proven convergence.
Resolution
Transformation to Finite Dimensional Problem using polynomial basis.
Legendre Pseudospectral method applied for solving nonlinear optimization problem.
Challenges
Complex constraints on flight parameters.
Ensuring real-time collaboration and efficient flight management.
Applications
Use case in flying ambulance service.
Applicable to broader range of aerial navigation tasks, such as drone routing, search and rescue.
This summary aligns well with existing optimization concerns in supply chain management and other industrial applications, particularly in navigating complex constraint environments.
3D GPS
File:Présentation 14 03 2019.pdf
- Aircraft parametrical configuration
File:TMO02.pdf File:Rapport finalv2.pdf
- Aircraft takeoff
Presentation of 3D GPS Flight Optimization Project
In our relentless pursuit of cutting-edge aviation technology, we present the remarkable work accomplished in the realm of 3D GPS flight optimization, specifically designed to calculate an optimized flight path using artificial intelligence (AI).
Path Flight Optimization
Presentation: File:BELMANT-CLERC-DIAPORAMA.pdf Final Report: File:Insa minibee gps final.pdf
Objectives Our primary objective was to develop a Hybrid VTOL (Vertical Take-Off and Landing) aircraft with a specific focus on its application as a flying ambulance. This project aimed to navigate optimally in a complex 3D environment from point S to F.
Key Features
3D collaborative GPS system. Advanced obstacle avoidance capabilities, considering both static and dynamic objects. Integration of meteorological constraints into the flight model. Minimization of fuel consumption and flight time. Methodology The project's methodology included:
Physical modeling, utilizing control inputs for thrust and angular velocity to define state equations. A cost function that combined flight time and fuel consumption for optimization. Comprehensive constraints, covering end-to-end states, control bounds, and obstacle avoidance. Optimization Techniques We explored a range of optimization techniques, including Generalized LQR, Approximate Dynamic Programming, Finite Elements, and Pseudospectral methods. Ultimately, the Legendre Pseudospectral method was selected for resolution due to its proven convergence.
Resolution To solve the nonlinear optimization problem, we employed the Legendre Pseudospectral method, transforming it into a finite-dimensional problem using polynomial basis functions.
Challenges The project was not without its challenges, particularly in managing complex flight parameter constraints and ensuring real-time collaboration for efficient flight management.
Applications While initially designed for use in flying ambulance services, the insights and technology developed in this project hold broader applications in the field of aerial navigation. These extend to drone routing, search and rescue operations, and beyond.
This summary underscores the project's alignment with existing optimization concerns in supply chain management and various industrial applications, especially in navigating intricate constraint environments.