1. Unit 2: Engineering Design Process
Foundations of Technology
Unit 2: Engineering Design Process
Lesson 1: Engineering Design Process
The Engineering Design Process

2. Objectives
Students learn to:
Apply the steps of the design process including defining a problem, brainstorming, researching and generating ideas, identifying criteria and specifying constraints, exploring possibilities, selecting an approach, developing a design proposal, making a model or prototype, testing, and communicating results.
Use symbolic algebra to represent and explain mathematical relationships Contribute to a group endeavor by offering useful ideas, supporting the efforts of others, and focusing on the task.

3. Objectives
Visualize three-dimensional objects and spaces from different perspectives and analyze their cross sections.
Contribute to a group endeavor by offering useful ideas, supporting the efforts of others, and focusing on the task.
Work safely and accurately with a variety of tools, machines, and materials.
Actively participate in group discussions, ideation exercises, and debates.

4. Vocabulary
Engineering Design Process: is a systematic, iterative problem solving method which produces solutions to meet human wants and desires.
Science: the study of the natural world, focuses on how and why things happen.
Scientific Method: is a linear method for conducting an investigation, which involves making an observation and performing an experiment to test a hypothesis.

5. Vocabulary
Technology: the study of the design world. Used to solve practical problems and extend human capabilities. Developments in technology are evolutionary, and are often the result of a series of refinements to an idea or basic invention, focuses on making things happen.

6. Define the Problem: includes developing a problem statement that identifies the what, who, when and how the problem should be addressed.
Brainstorming Solutions: includes working as a group to develop ideas for possible solutions, record your ideas and employ the rules of brainstorming.

7. Criteria: guidelines to help develop a solution.
Constraints: limitations of the design when developing a solution.
Alternative Solutions: are necessary so that ideas remain unique and are not traditional.

8. Select the Approach: determining how to proceed in the engineering design process is based on a schedule or some type of matrix that outlines all ideas based on the criteria and constraints.
Design Proposal: a way to manage simple projects, which includes the who, what, when, where and how to deliver the work, how the solution will be evaluated and often includes descriptions, sketches and technical drawings.

9. Make a Model/Prototype: models and prototypes can be conceptual (are abstract models that use language and graphic-based representations to convey meaning), mathematical (are abstract models that use the language of mathematics to describe the behavior of the solution) or physical (are three-dimensional models, which represent the solution).

10. Test and Evaluate: this step in the engineering design process is used to evaluate the model/prototype against the given criteria and constraints, all tests should be developed during the design proposal phase.

11. Refine/Improve: this is an essential step in the engineering design process, and is what makes this process unique. The design is constantly reviewed and revised throughout the process so that an ideal solution is developed.

12. Create/Make Product: the product produced should clearly match the design and show refinement throughout the engineering design process.
Communicate the Results: the engineering design journal and/or an electronic version of the engineering design journal should be kept to record daily interaction with the design problem. This represents your ideas and thoughts throughout the process.

13. The Big Idea
Big Idea:
The Engineering Design process is a systematic, iterative problem solving method which produces solutions to meet human wants and desires.

14. Interactive Iterative means a repetition of the process.
This often means you must go through the steps numerous times.
Each time you go through the design process, you think of ways to improve your solution to the problem based on performance or testing.

15. Defining Science Science:
Systematic knowledge of the physical or natural world gained through observation and experimentation.
Focuses on how and why things happen.
Scientists answer questions

16. Defining Technology Technology:
Application of knowledge to solve practical problems or to change/manipulate the human environment.
Focuses on making things happen.
Engineers solve problems

17. Scientific Method
The Scientific Method is a linear method for conducting an investigation that involves making an observation and performing an experiment to test a hypothesis.
Make an Observation
Propose a Hypothesis
Design an Experiment
Test the Hypothesis
Accept or Reject the Hypothesis
Revise the Hypothesis or Draw Conclusions

18. Engineering Design Process
The Engineering Design Process is a systematic, iterative problem-solving method that produces solutions to meet human needs and wants.
Systematically applies mathematics and science to produce tangible products that meet human needs or wants.

19. Engineering Design Process
At the beginning of the course, we used a simple version of the Engineering Design Process, which involved five steps.
As problems become more complex so does the process used to solve them.

20. Engineering Design Process
Define Problem
Brainstorm Possible Solutions
Communicate Results
Research Ideas/ Explore Possibilities
Create/ Make Product
Define Problem
Test and Evaluate
Brainstorm Ideas
Refine & Improve
Refine and Improve
Specify Constraints and Identify Criteria
Generate a Solution
Explore Solutions
Test and Evaluate
Consider Alternative Solutions
Make a Model / Prototype
Develop a Written Design Proposal
Select An Approach

21. Scientific Method VS Engineering Process
Match the term to either the Scientific Method or the Engineering Design Process
Hypothesis
Linear Procedure
Involves Criteria and Constraints
Conduct Research
Follow a Process
Defined Starting Point (State the Problem Clearly)
Meets Human Need or Want
Continuous Improvement

22. Scientific Method VS Engineering Process
The Scientific Method:
Defined Starting Point
Hypothesis
Linear Procedure
Conduct Research
Follow a Process
The Engineering Design Process:
Involves Criteria and Constraints
Meets Human Need or Want
Continuous Improvement
Conduct Research
Follow a Process

23. Engineering Design Process
Use the Engineering Design Journal to record each step in the Engineering Design Process.

24. Define the Problem
Develop a problem statement that identifies the what, who, when, and how the problem should be addressed.
The problem statement should be short, descriptive, and referenced as you work through the Engineering Design Process.

25. Brainstorm Solutions
When working as a group, record your ideas and employ the rules of brainstorming:
One conversation at a time; stay focused.
Encourage wild ideas, quantity vs. quality.
Defer judgment and build on the ideas of others.
Use Mind Mapping, the da Vinci Method, or Inventive Problem Solving as appropriate.

26. Research Ideas/Explore Possibilities
Research is essential in determining the best possible solution.
Identify how the problem or a similar problem was addressed in the past.
Determine what mathematical and/or scientific background knowledge is essential to solve the problem.

27. Specify Constraints and Identify Criteria
Good design follows a set of given or identified criteria and constraints:
Criteria = Guidelines
Constraints = Limitations
Document the essential criteria and constraints needed to solve the problem

28. Consider Alternative Solutions
Always consider alternative solutions and DO NOT allow preconceptions to limit your ideas.
It is important to stay open-minded.
Compare each of your design ideas with the criteria and constraints to determine how well they solve the problem.

29. Select the Best Solution
Determining the “best” solution will involve trade-offs.
The “best” solution should:
Align to the problem statement.
Meet the identified criteria and constraints.
Use a Decision Matrix to help identify the best solution.

30. Select an Approach
The Decision Matrix is a simple way to chart your proposed solutions (x axis) against the requirements (y axis).
Establish a point scale to help determine the “best” idea. x y

31. Develop a Documented Design Proposal
Once an idea has been selected, it is important to develop a plan of action.
A Design Proposal is a way to manage simple projects, which includes:
The who, what, when, where, and how to deliver the work.
Often includes descriptions, sketches, and technical drawings.
Begin to plan how the solution will be evaluated.

32. Develop a Documented Design Proposal
When developing a design proposal, you will need to plan ahead to determine how you will evaluate your design.
What tests will be conducted to determine if criteria are being met?
What data will be collected?
How will those data be used to improve the solution?

33. Develop a Documented Design Proposal
Larger projects may require the use of a project management technique or a Gantt Chart.
A Gantt Chart is a type of bar chart that shows a schedule of when/how the project can be completed.

34. Make a Model or Prototype
Models can be conceptual, mathematical, or physical.

35. Make a Model or Prototype
Conceptual models are abstract models that use language and graphic-based representations to convey meaning.
They can include:
Technical Writing
Graphs and Charts
Annotated Sketches
Technical Drawings

36. Make a Model or Prototype
Mathematical models are abstract models that use the language of mathematics to describe the behavior of the solution.
They can include:
Statistical models
Differential equations
Game theoretic models (computer simulation)

37. Make a Model or Prototype
Physical models are three-dimensional models that represent the solution.
They can include:
Mock-Up – a representation of the final solution that does not function.
Prototype – performs the final solution and can be used for testing/evaluation

38. Test and Evaluate Project planning and evaluation go hand-in- hand.
Based on the information you projected in your design proposal you will:
Record and analyze results
Correct problems with the design that are discovered during testing

39. Refine and Improve Employ data-driven decision making.
Use the data collected during the test and evaluate phase to justify improvements to the solution.
The solution should be continuously improved as you move through the Engineering Design Process.
Remember to document all project improvements in your journal.

40. Create and Make Product
Working independently or in a group, develop the final physical solution.
The final solution should represent the revision made as you followed the Engineering Design Process.
The product produced should clearly reflect refinements made to the design throughout the process.

41. Communicate the Results
Use the Engineering Design Journal to record and document each step in the Engineering Design Process.
A more formal presentation or demonstration of the solution may be required, which should:
Summarize your work (includes problem statement, design proposal, evaluation methods, etc…)
Highlight why you chose the final solution.