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Team 503

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Richard Allen IV

Design Engineer

Richard Allen is an undergraduate Mechanical Engineer that has the role of the Design Engineer. After graduating with his Bachelors in the Spring of 2023 he plans to further pursue his education in obtaining a master’s degree focusing on controls and advanced dynamic systems. Upon obtaining a master’s degree he plans to pursue a career in the Automotive industry.

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Micah Hilliard

Structural Engineer

Micah Hilliard is a mechanical engineering major with the role of structural engineer on the project. The responsibilities for this role may include drafting and designing drawings for the design as well as researching the best materials to use for the design. Micah will graduate at the end of the spring semester in May of 2023 and plans to begin working although has not chosen a specific industry yet

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Nicholas Muoio

Controls Engineer

Nicholas Muoio is currently an undergraduate Mechanical Engineering Student. Nicholas has been acting as the controls/design engineer for this capstone project. He will be graduating in Spring of 2023, and continuing to pursue his Masters in Mechanical Engineering at Florida State University in Fall of 2023. After obtaining his Masters he hopes to work in the Automotive Industry.

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David Gordan

Hardware Engineer

David Gordan is Computer Engineering major and serves as the Hardware Engineer. After graduating in May 2023 David plans to continue his education in graduate schoool.

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Chet Iwuagwu

Software Engineer

Chet is a Post-bacc Computer Engineering student and Software Engineer. He will graduate in Spring 2023 with another Bachelors in Computer Engineering before starting a positon at Bank of America as a Software Engineer.

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Kathleen Bodden

Test Engineer

Kathleen Bodden is an undergraduate senior in mechanical engineering who serves as the Research/Test Engineer. After graduating in spring 2023, she plans to continue her education to obtain a masters degree in mechanical engineering, focused on dynamics and controls.

Sponsors

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Shayne McConomy

Senior Design Coordinator

Mechanical Engineering Department

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Camilo Ordoñez

Academic Advisor

Mechanical Engineering Department

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Christian Hubicki

Academic Advisor

Mechanical Engineering Department

Abstract

The shift to autonomy is a primary focus for producers moving forward. Researchers are finding ways to make driverless cars while battling energy consumption. Our team aims to design a small-scale autonomous car that reduces energy losses by keeping a constant speed.Scaling down the project is beneficial to our goals. We can more easily deal with challenges that are hard to test with a larger model. We can also replicate a real environment with software that interacts with the scaled car. This is called hardware-in-the-loop. Hardware-in-the-loop is a testing technique that reproduces different environments based on physical signals. We split the project into two sides. These include the mechanical side of the project and the vision side. The two large sides of the project were broken even further into four parts. Looking at smaller parts of our project allows us to analyze the more complex design. The four parts include object detection, path planning, the steering, and the motor. Our team focuses on the mechanical side of the project while a separate team focuses on the vision side. Communication with the vision team is important to the success of the project. The mechanical side includes a steering design that rotates to a set angle. The angle is provided by the vision team, to adjust the direction the car is heading. The mechanical side also includes a motor design working to propel the car forward. The design should work without actions from a user. The path for the car goes from the back entrance of the Aero-Propulsion, Mechatronics and Energy Building to the B side entrance of the College of Engineering. The project will be successful when an efficient power consumption is achieved. This will happen when less energy is lost from the car's movement.

Photo Gallery

Propulsion SubSystem
Simulations
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Discretion SubSystem
3D printed Camera-Sensor Holder
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Steering SubSystem
Model + Sensor
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This video proves the concept that the microcontroller can receive inputs in the form of bytes and output the value. In this case, Red is extreme left and Green is extreme right. This means that the NVIDIA Jetson would be able to send data that would tell the Tesla model to turn left or right.
This video shows a traditional rack and pinion, Team 503 was able to pull inspiration from this age old design for ideas on the new steering system.
This video shows the calibration sequence set up for the steering system. The teensy microcontroller will step the steering motor to both sides of the rack until both extreme steering angles are hit. After recording both angles, the steering system will center itself in the forward position. This is all done using software, no hardware is used for this calibration sequence.

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The Specifics aspects of each compenent within the Design. This Photo Descibes what is going on within eachaspect of the autonomy process.

Deliverables

Future Work





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