Enhancing Drone Safety Measures with Parachute Functionality

This project focuses on ensuring safety measures during critical scenarios by activating the parachute function embedded within the drone's software. By replicating and simulating this action in a virtual environment, the effectiveness and reliability of the drone's emergency protocols are enhanced. The project faced challenges with the initial system, PX4, but successfully transitioned to ArduPilot for improved sustainability. Further development requires a physical drone for implementation.

• Drone Safety
• Parachute Functionality
• Emergency Protocols
• Simulation Testing
• ArduPilot

rory_23 Follow

Uploaded on Sep 26, 2024 | 0 Views

Download Presentation

Please find below an Image/Link to download the presentation.

The content on the website is provided AS IS for your information and personal use only. It may not be sold, licensed, or shared on other websites without obtaining consent from the author. Download presentation by click this link. If you encounter any issues during the download, it is possible that the publisher has removed the file from their server.

Presentation Transcript

1. Dronix Drones project Tony Hasson 316047281 Shahar Michel 315327957 Yanir Nachshon - 206083214

2. Table of Contents Page 3 - Goal Page 4 - Video Documentation Page 5 - Project Schedule Page 6 - Unexpected problems Page 7 - Coping and Solving Page 8 - Conclusion

3. General description of the software Goal - To ensure safety measures during critical scenarios, it is mandatory to activate the parachute function embedded within the drone's software. This action serves as a crucial response mechanism in emergency situations, safeguarding both the drone and its surroundings. Furthermore, it is essential to replicate and simulate this action within a virtual environment, allowing for thorough testing and optimization of the parachute's functionality. By prioritizing such measures, we enhance the reliability and effectiveness of the drone's emergency protocols, thereby promoting overall operational resilience.

4. Video documentation https://www.youtube.com/watch?v=b6BOHOm6E-A

5. Project progress schedule In our project, we had a mission to fly a drone and open the parachute . we decided to start our journey with PX4 Autopilot, QGroundControl , jMAVSim with SITL. after a few months, we learned those programs and a lot of attempts on PX4 we didn t succeed in operating the drone on the stimulation and the combination of server collapse of PX4 for a long time we decided to switch to Ardupilot. we started over from the beginning with Ardupilot and Gazeebo and QGC. After many attempts and failures, we succeeded to fly the drone and open the parachute on the stimulation. The hardware that we had is the CubeOrange, QPilot here 3+ and the parachute. we didn t have a drone so we were unable to use the CubeOrange due lack of electrical voltage according to Ofer.

6. Unexpected problems Unexpected problems that appeared during the implementation of the project We started the project using the operation system PX4. After investing a lot of our time learning the system , the website did not work for Several days , hence we were unable to continue our project.

7. Coping and Solving To solve the issue explained in the previous page , we changed our operation system from PX4 to ArduPilot , a Much more sustainable system.

8. Conclusions for further development In order to continue with the project , there is a need for a physical drone. Because if there is no physical drone present , the CubeOrange and the physical parachute can not be activated. Also , continue using the ArduPilot operating system rather than PX4 , because it has better documentation and more sustainable.