Individual Project

\[ \begin{align}\begin{aligned}\newcommand\blank{~\underline{\hspace{1.2cm}}~}\\% Bold symbols (vectors) \newcommand\bs[1]{\mathbf{#1}}\\% Poor man's siunitx \newcommand\unit[1]{\mathrm{#1}} \newcommand\num[1]{#1} \newcommand\qty[2]{#1~\unit{#2}}\\\newcommand\per{/} \newcommand\squared{{}^2} \newcommand\cubed{{}^3} % % Scale \newcommand\milli{\unit{m}} \newcommand\centi{\unit{c}} \newcommand\kilo{\unit{k}} \newcommand\mega{\unit{M}} % % Percent \newcommand\percent{\unit{\%}} % % Angle \newcommand\radian{\unit{rad}} \newcommand\degree{\unit{{}^\circ}} % % Time \newcommand\second{\unit{s}} \newcommand\s{\second} \newcommand\minute{\unit{min}} \newcommand\hour{\unit{h}} % % Distance \newcommand\meter{\unit{m}} \newcommand\m{\meter} \newcommand\inch{\unit{in}} \newcommand\foot{\unit{ft}} % % Force \newcommand\newton{\unit{N}} \newcommand\kip{\unit{kip}} % kilopound in "freedom" units - edit made by Sri % % Mass \newcommand\gram{\unit{g}} \newcommand\g{\gram} \newcommand\kilogram{\unit{kg}} \newcommand\kg{\kilogram} \newcommand\grain{\unit{grain}} \newcommand\ounce{\unit{oz}} % % Temperature \newcommand\kelvin{\unit{K}} \newcommand\K{\kelvin} \newcommand\celsius{\unit{{}^\circ C}} \newcommand\C{\celsius} \newcommand\fahrenheit{\unit{{}^\circ F}} \newcommand\F{\fahrenheit} % % Area \newcommand\sqft{\unit{sq\,\foot}} % square foot % % Volume \newcommand\liter{\unit{L}} \newcommand\gallon{\unit{gal}} % % Frequency \newcommand\hertz{\unit{Hz}} \newcommand\rpm{\unit{rpm}} % % Voltage \newcommand\volt{\unit{V}} \newcommand\V{\volt} \newcommand\millivolt{\milli\volt} \newcommand\mV{\milli\volt} \newcommand\kilovolt{\kilo\volt} \newcommand\kV{\kilo\volt} % % Current \newcommand\ampere{\unit{A}} \newcommand\A{\ampere} \newcommand\milliampereA{\milli\ampere} \newcommand\mA{\milli\ampere} \newcommand\kiloampereA{\kilo\ampere} \newcommand\kA{\kilo\ampere} % % Resistance \newcommand\ohm{\Omega} \newcommand\milliohm{\milli\ohm} \newcommand\kiloohm{\kilo\ohm} % correct SI spelling \newcommand\kilohm{\kilo\ohm} % "American" spelling used in siunitx \newcommand\megaohm{\mega\ohm} % correct SI spelling \newcommand\megohm{\mega\ohm} % "American" spelling used in siunitx % % Inductance \newcommand\henry{\unit{H}} \newcommand\H{\henry} \newcommand\millihenry{\milli\henry} \newcommand\mH{\milli\henry} % % Power \newcommand\watt{\unit{W}} \newcommand\W{\watt} \newcommand\milliwatt{\milli\watt} \newcommand\mW{\milli\watt} \newcommand\kilowatt{\kilo\watt} \newcommand\kW{\kilo\watt} % % Energy \newcommand\joule{\unit{J}} \newcommand\J{\joule} % % Composite units % % Torque \newcommand\ozin{\unit{\ounce}\,\unit{in}} \newcommand\newtonmeter{\unit{\newton\,\meter}} % % Pressure \newcommand\psf{\unit{psf}} % pounds per square foot \newcommand\pcf{\unit{pcf}} % pounds per cubic foot \newcommand\pascal{\unit{Pa}} \newcommand\Pa{\pascal} \newcommand\ksi{\unit{ksi}} % kilopound per square inch \newcommand\bar{\unit{bar}} \end{aligned}\end{align} \]

Dec 03, 2024 | 317 words | 3 min read

16. Individual Project#

Using the knowledge that you have gained this semester, you will create a program in either Python or MATLAB. The intent of this project is for each student to demonstrate that you can apply your computing skills to address a topic or challenge that interests you.

Please let your GTA or Instructor know if you have any questions or issues.

Topics Covered

  • Programming in Python or MATLAB

  • Input/Output Data Handling (file reading, user input, data display, saving outputs)

  • Control Structures (loops, conditionals, nested structures)

  • Function Development and Application (main program with at least three user-defined functions)

  • Error Handling and Validation

  • Integration of New Libraries or Modules

  • Project Documentation and Technical Communication

Learning Objectives and Course Outcomes

At the end of this module, you will be able to:

  • Create a complete program in Python or MATLAB that fulfills specified objectives and applies programming techniques effectively.

  • Use loops, conditionals, and nested structures to solve a complex problem.

  • Ensure robust program functionality with effective error-checking algorithms for user inputs, outputs, and intermediate data.

  • Expand knowledge by incorporating a new module, library, or feature beyond the course curriculum, enhancing program functionality and scope.

  • Document the project with a clear report that explains the purpose, methodologies, results, and insights gained.

These learning objectives are directly connected to the following Course Outcomes:

CO 1.1:

Visually represent data and derive meaningful information from data.

CO 1.3:

Use evidence to develop and optimize solutions. Evaluate solutions, test and optimize chosen solution based on evidence.

CO 3.1:

Communicate engineering concepts, ideas and decisions effectively and professionally in diverse ways such as written, visual and oral.

CO 3.2:

Seek, find, use, and document appropriate and trustworthy information.

CO 4.1:

Develop code solutions that address engineering questions and follow professional programming standards.

CO 4.2:

Understand and implement basic and intermediate programming structures: sequential structures, selection structures, repetition structures, and nested structures.

CO 4.3:

Create adaptable, reusable programming routines.

CO 4.4:

Apply design ideas to programming solutions.