PHYS-1410 Applied Physics

Joseph Brinkley

Credit Fall 2024

Section(s)

PHYS-1410-001 (91970)
LAB MW 1:30pm - 2:50pm RRC RRC2 2324.00

LEC MW 12:00pm - 1:20pm RRC RRC2 2322.00

PHYS-1410-005 (97033)
LAB TuTh 1:30pm - 2:50pm RRC RRC2 2324.00

LEC TuTh 12:00pm - 1:20pm RRC RRC2 2322.00

Course Requirements

BASIC COURSE INFORMATION

Credit Hours: 4

Classroom Contact Hours: 48 Laboratory Contact Hours: 48

Course Description

 

This is a one-semester survey course in physics intended to give students an overview of physical concepts as well as experience applying those concepts to simple problem solving. Topics include kinematics, Newton’s laws, conservation laws, density and elasticity, fluids, sound, electricity, light and color. PHYS 1405

and PHYS 1410 may not both be taken for credit, nor may PHYS 1407 and PHYS 1410 both be taken for credit.

 

COURSE RATIONALE/OBJECTIVES

 

This course is designed for students who intend to enter the Sonography program of Austin Community College. It is intended to provide an overview of basic physics, to apply proportional reasoning to physics problems, and to apply graphical interpretation in order to fulfill requirements of the Sonography department as well as prepare for further study in Sonography.

 

COURSE PREREQUISITES:

 

Grade of "C" or better in MATH 1314 or equivalent

 

Readings

REQUIRED TEXTS/MATERIALS

  • Physics Classroom: Physics Tutorial
  • Scientific Calculator.  Any kind will do (except the one on your phone).
  • Webassign homework system: Registration information sent out via Blackboard
  • HOMEWORK ASSIGNMENTS will be done online using WebAssign by Cengage.  
    • Each assignment will have a link in Blackboard under ‘Homework’
  • PHYSICS CLASSROOM has the reading list, practice activities and simulations.
    • You should get an invite link by email.  Click the link that says “click here”
    • Fill in the Student Registration form. You MUST login using your ACC email.
    • Follow the registration instructions.  The class code is ff8a9f0

Course Subjects

Date

Reading

Lecture Topics

Lab Assignments

What’s Due

WEEK ONE (1B)

Mon, Aug 26

1

Go over syllabus & Dimensions

Lab safety orientation and Measurements Pre-Lab

Lab Safety

Wed, Aug 28

1

Proportional reasoning

Measurements and Units

  

WEEK TWO (2A – 2B)

Mon, Sep 2

  

Labor Day

  

Lab 1

HW #1

Wed, Sep 4

2 – 4

Reading Graphs, Proportional reasoning, and Misc.

L Proportional Reasoning & Ohms Law (PHET)
 

Mon, Sep 9

2 – 4

Linear Motion Intro

Motion Carts

Moving Man Activity (Phet)

Lab 2

HW #2

Wed, Sep 11

2 – 4

Linear Motion - Acceleration
 

Mon, Sep 16

2 – 4

Linear Motion & Graphs

Motion Graphs (PC)

Kinematics and Graphs

Lab 3A

HW #3 & #4

Wed, Sep 18

4 – 5

Forces and NSL
 

Mon, Sep 23

    

Mass vs. Weight (PC)

Free Fall

Catch Up and Review

Lab 4A – 4B

HW #5

Wed, Sep 25

4 – 5

Forces and NSL
 

Mon, Sep 30

1 – 4

EXAM ONE (1A –4B)

Lab 5A

Exam #1 Review

(due before exam)

Wed, Oct 2

4 – 5

Applying NSL

Free Fall & Air Drag

Newton’s 2nd Law
 

Mon, Oct 7

7

Energy Intro

Energy Terminology

Mechanical Energy

Lab 5B & 6B

HW 5B & 6B

Wed, Oct 9

7

Mechanical Energy Conservation
 

Mon, Oct 14

12

Density

Density Activity (Phet) Hydraulic Activity (Sim)

Labs 7A & 7B

HW 7A & 7B

Wed, Oct 16

13 – 14

Forces and Pressure

WEEK NINE (9A – 9B)

Mon, Oct 21

16

Heat and Temperature

Gas Properties (Phet)

Boyle’s Law Catch Up and Review

Labs 8A – 8B

HW 8A – 8B

Wed, Oct 23

19

Elastic Forces and SHM Intro
 

Mon, Oct 28

7, 12 - 16

EXAM TWO (5B –9A)

Lab 9A & HW 9A

(due before exam)

Wed, Oct 30

19 – 21

SHM and Energy – Waves Intro

Springs and SHM
 

Mon, Nov 4

19 – 21

Waves and Sound I

Slinky Waves Exploring Waves (PC) Speed of Sound

Labs 9B – 10B

HW 9B – 10B

Wed, Nov 6

19 – 21

Waves and Sound II
 

Mon, Nov 11

19 – 21

Standing Waves

Snapshots & Recordings Standing Waves Ratios & Levels

Labs 11A – 11B

HW 11A – 11B

Wed, Nov 13

19 – 21

Intensity & Sound Levels
 

Mon, Nov 18

19 – 21

Reflection & Transmission

Sound Reflection

Labs 12A – 12B

HW 12A – 12B

Wed, Nov 20

19 – 21

EXAM THREE (9B –12B)
   

WEEK FOURTEEN (14A – 14B)

  

Mon, Nov 25

19 – 21

Refraction – Doppler

Reflection Coefficients

Doppler Effect

Labs 13A –13B

HW 13A – 13B

Wed, Nov 27

19 – 21

Doppler Effect
 

Mon, Dec 2

22 – 23

Electric Charge & Current

Doppler Practice

Simple Circuits

Labs 14A – 14B

HW 14A – 14B

Wed, Dec 4

22 – 23

Ohm’s Law & Basic Circuits
 

Mon, Dec 9

Everything!

Final Exam Review

Whatever’s Left

Wed, Dec 11

COMPREHENSIVE FINAL EXAM

 

Student Learning Outcomes/Learning Objectives


 

STUDENT LEARNING OUTCOMES

COURSE-LEVEL STUDENT LEARNING OUTCOMES:

Upon successful completion of this course, the student will be able to:

  • Demonstrate the ability to translate common language descriptions into multiple physical representations (e. g. diagrams, mathematical equations, physical models) and vice versa.
  • Demonstrate the ability to collect, analyze, and interpret data.
  • Demonstrate the ability to communicate findings in terms of fundamental physical concepts.
  • Demonstrate knowledge of Newton's Laws of Motion, and quantitatively solve problems through the application of those laws to simple physical systems.
  • Demonstrate a basic understanding of physical conservation laws, and quantitatively solve problems through the application of those laws to simple physical systems (charge, energy & momentum).
  • Demonstrate understanding of elastic forces and define properties of matter (charge, density, tension, and compression).
  • Demonstrate a basic understanding of the properties of fluids (e.g., pressure, and buoyancy) to solve quantitative problems regarding simple physical systems.
  • Demonstrate a basic understanding of wave motion and oscillations and related properties to solve quantitative problems regarding simple physical systems. (Doppler shift, standing waves, harmonics, reflection, refraction, transmission & reflection coefficients).
  • Demonstrate a basic qualitative understanding of properties of light and optics (e.g., electromagnetic spectrum, converging & diverging lenses, diffraction, & thin film interference).
  • Demonstrate a basic understanding of the properties of electrical circuits to solve quantitative problems involving Ohm’s Law.

 

GENERAL EDUCATION COMPETENCIES:

Upon completion of this course, students will demonstrate competence in:

COMMUNICATION SKILLS

Develop, interpret, and express ideas and information through written, oral and visual communication that is adapted to purpose, structure, audience, and medium.

CRITICAL THINKING SKILLS

Gather, analyze, synthesize, evaluate and apply information for the purposes of innovation, inquiry, and creative thinking.

EMPIRICAL AND QUANTITATIVE SKILLS

Apply mathematical, logical and scientific principles and methods through the manipulation and analysis of numerical data or observable facts resulting in informed conclusions.

TEAMWORK

Consider different points of view to work collaboratively and effectively in pursuit of a shared purpose or goal.

 

Office Hours

M T W Th 11:20 AM - 11:50 AM RRC2 2308.10

NOTE

M T W 3:00 PM - 4:00 PM RRC2 2308.10

NOTE Other times by appointment (please send me an email jbrinkle@austincc.edu)

Office Hours

M T W Th 11:20 AM - 11:50 AM RRC2 2308.10

NOTE

M T W 3:00 PM - 4:00 PM RRC2 2308.10

NOTE Other times by appointment (please send me an email jbrinkle@austincc.edu)

Published: 08/29/2024 16:17:50