Apr 25, 2024  
2023-2024 Schoolcraft Catalog 
    
Catalog Navigation
  Catalog Home
  Important Academic Dates
  Location and Maps

  Career and Educational Pathways
  Programs and Areas of Study
  Course Descriptions
  Distance Learning Courses
  Degree Graduation Requirements
  General Education and Michigan Transfer Agreement Requirements
  MiTransfer Pathways

  Transfer Options
  Ocelot Access (Register for Classes)
  Student Handbook
  Financial Aid & Scholarships
  Catalog User Guide & Archives
  Catalog Addendum
  My Catalog
HELP
2023-2024 Schoolcraft Catalog [ARCHIVED CATALOG]

Facebook this Page (opens a new window)
Tweet this Page (opens a new window)
Add to My Catalog (opens a new window)

PHYS 211 - Physics for Scientists and Engineers 1

Credits: 5
Lecture Contact Hours: 5
Lab Contact Hours: 2
Description: This first semester, calculus-based course is designed for engineering students and science majors. Traditional topics of kinematics, dynamics, energy, fluids, heat and sound are investigated through lecture demonstrations, simulations and laboratory work.

Prerequisites: PHYS 123  or one year of high school physics. MATH 150  or high school calculus.
Corequisites: None.
Recommended: None.

Course Category: Liberal Arts | Science with Lab
This course counts toward Schoolcraft’s General Education Requirements.
This course counts toward a Michigan Transfer Agreement General Education Requirement.

This Course is Typically Offered: Winter, Spring, Fall
Check Course Availability

Course Competencies
  1. Analyze the motion of an object in terms of its position, velocity and acceleration.
  2. Analyze a system’s mechanics using Newton’s Laws of Motion.
  3. Organize forces using a free body diagram.
  4. Analyze a system’s mechanics using conservation of energy.
  5. Analyze collisions using both conservation of energy and conservation of momentum.
  6. Analyze simple harmonic motion.
  7. Analyze orbital motion of satellites using Newton’s Law of Universal Gravitation.
  8. Use the principle of superposition to explain various wave phenomena.
  9. Assign the appropriate SI unit to a physical characteristic.
  10. Use significant figures when reporting calculated values.
  11. Classify a physical quantity either as a scalar or a vector.
  12. Change between polar and Cartesian vector notation.
  13. Add two vectors graphically and algebraically.
  14. Use computer simulation to model motion.
  15. Use a Vernier caliper.
  16. Use DataStudio for data acquisition.
  17. Develop data tables and graphs to portray the results of experimental data collection.
  18. Use curve fitting to analyze data.
  19. Identify sources of experimental error.
  20. Compare measured results from an experiment with calculated values derived from a mathematical model.
  21. Develop a conclusion based on analysis of experimental data.


Facebook this Page (opens a new window)
Tweet this Page (opens a new window)
Add to My Catalog (opens a new window)