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This page contains all of the online content for my College Prep Physics course. Dowd keeps all of his content on Flickr, the photo sharing site. Each course has its own album each year. If you click the link to the album, you'll be taken to it. The tables contain the major units in the course. Clicking on this link will bring you to a header photo in the album. To see the course content, scroll forward.
2018-2019
To view the syllabus for the course, please click here
Google Classroom (Must be logged into mpspride.org)
To access the Flickr album, click here
Students: Do not watch the videos at the link below. Check Google Classroom and EdPuzzle instead to recieve credit!
| Unit |
Videos |
Description |
| One Dimensional Motion/Graphing |
Introduction to Physics Introduction to the One D Motion Variables Measuring One-D motion variables by hand Analyzing hand-graphed motion data How to write a lab report Collecting Data Automatically (Ticker Tape Timer Lab) Using a Spreadsheet to Analyze Data (Ticker Tape Timer Lab) Introduction to Force's Role in Acceleration Collecting Motion Data using Video Analysis (1/2) Collecting Motion Data using Video Analysis (2/2) Step by Step Screenshots of How to Use Tracker Constant Acceleration Motion (Angry Bird Lab Conclusion) Air Resistance Constant Velocity and Constant Acceleration Equations as a Model One Dimensional Motion Practice Problem № 1 One Dimensional Motion Practice Problem № 2 Other One D Motion Practice Problems |
In this unit, we look at objects moving in just one dimension. We practice measuring their position and time at various moments and look for patterns that will help us understand motion more generally |
| One Dimensional Kinematics & Dynamics | Mass and Weight Mass on a Spring Lab Simple Newton's Second Law Lab Introduction to Free Body Diagrams and ΣF=ma One Dimensional ΣF=ma Practice Problems Solving MultiForce Problems (The Elevator Problem.) (1/2) Solving MultiForce Problems (The Elevator Problem.) (2/2) Newton's First Law One Dimensional Force Quiz Study Guide Fictitious Forces Video № 1 Fictitious Forces Video № 2 |
A dimension is something that can be quantified using a number line. We'd usually call it "horizontal" or "vertical" or maybe "the x-axis" or "the y-axis." In this unit we study one dimension at a time. The motion from the previous unit is the "kinematics" part. The "dynamics" part is where we introduce the concept of force (a push or pull) and go through Newton's first two laws for understanding how these pushes and pulls interact. |
| Momentum | Newton's 3rd Law Conservation of Momentum Conservation of Momentum Example Problems Deciding whether to use Conservation of Momentum or Impulse Momentum Test Review |
This concept is useful for helping to understand situations where complex forces are acting, forces that increase and decrease during the interaction. We'll see it is especially helpful for collisions and explosions. There are two main topics: first, where momentum is changed by an outside force, and second, where there are no outside forces and momentum remains constant. For this latter topic we'll introduce Newton's 3rd law, which relates to how forces affect more than one object. |
| Projectile Motion | Horizontal Launch Projectile Motion Problem (the Doll Problem) Angled Launch Projectile Example Problem Projectile Motion and Launch Angle Projectile Motion Review |
This is a brief return to vectors to discuss motion in two dimensions. No new concepts are introduced, merely the application of the vegas rule "what happens in x stays in x and what happens in y stays in y" to motion, rather than forces. |
| Energy | Energy Intro Work and Potential Energy (No Calculus) What is Kinetic Energy? Conservation of Energy Example Problem Energy and Circular Motion on a Roller Coaster Energy Review |
This is the most important unit in the course for helping us be better citizens. It goes through what "doing work" means in physics and discusses what objects or phenomena have the ability to do work. The ability to do work is called energy, and it's the reason energy is so important in our society: if we we want to change our environment, we need energy to do it. It will also be a valuable tool in solving problems that were too difficult to do using the concept of forces. |
| Power | The Importance of Power Power Quiz Review |
In this unit we examine power, the speed of energy |
| Gravitation & Satellite Motion | Phases of the Moon Introduction to Newton's Law of Gravity The Inverse Square Law (Honors/AP Version) Finding the Gravitational Constant (G) Finding g on other worlds Gravitation Review |
This section introduces Newton's Law of Universal Gravitation. It uses this new force combined with the ideas of circular motion to help us understand ideas of planetary motion. A complete treatment of planetary motion doesn't come until later in the year, when we study the concepts of energy and momentum. |
| Electrostatics | Using an Electroscope № 1 Using an Electroscope № 2 Electrostatic Induction Capacitors Wimshurst Machine Van de Graaff Generators Mapping Electric Fields How a Lightning Rod Works Electrostatic Review |
This topic is about how charges can be separated, and how charged objects behave physically. There's a discussion of the electric force (Coulomb's law,) of how much charge an object can hold, and of the electric field, which we'll understand as being very similar to the gravitational field. We'll also discuss lightning and dielectric breakdown |
| DC Electric Circuits | The Meaning of Voltage in a Circuit Using a Breadboard Resistance and Ohm's Law Drawing a Schematic Kirchhoff's Loop Rule Parallel Circuits |
This unit discusses the kind of electricity that comes from a battery, where charge always flows in one direction. We call the movement of charge current, and since the charge is always going in one direction we call it direct current. Batteries, light bulbs, resistors, and capacitors are discussed. We discuss Ohm's law for determining current in a branch of a circuit and qualitatively mention Kirchhoff's rules |
| Current Progress |
As of |
2019-05-10 |
--
2017-2018
To view the syllabus for the course, click here.
| One Dimensional Motion/Graphing |
In this unit, we look at objects
moving in just one dimension. We practice measuring their position and
time at various moments and look for patterns that will help us
understand motion more generally |
| One Dimensional Kinematics/Dynamics |
A dimension is something that can be quantified using a number line. We'd usually call it "horizontal" or "vertical" or maybe "the x-axis" or "the y-axis." In this unit we study one dimension at a time. The motion from the previous unit is the "kinematics" part. The "dynamics" part is where we introduce the concept of force (a push or pull) and go through Newton's first two laws for understanding how these pushes and pulls interact. |
| Momentum |
This concept is useful for helping to understand situations where complex forces are acting, forces that increase and decrease during the interaction. We'll see it is especially helpful for collisions and explosions. There are two main topics: first, where momentum is changed by an outside force, and second, where there are no outside forces and momentum remains constant. For this latter topic we'll introduce Newton's 3rd law, which relates to how forces affect more than one object. |
| Projectile Motion |
In this unit, we work with motion in two dimensions. It's a relatively minor part of the course, but we'll spend a large amount of time on it, because it's the first topic that requires us to organize our thinking. We'll also introduce what I call the Vegas rule: "what happens in horizontal stays in horizontal, and what happens in vertical stays in vertical." |
| More One Dimensional Forces |
A quick return to forces to examine some more important aspects, like friction |
| Energy |
This is the most important unit in the course for helping us be better citizens. It goes through what "doing work" means in physics and discusses what objects or phenomena have the ability to do work. The ability to do work is called energy, and it's the reason energy is so important in our society: if we we want to change our environment, we need energy to do it. It will also be a valuable tool in solving problems that were too difficult to do using the concept of forces.Finally, Power (the "velocity" of energy) is discussed. |
| Atomic Energy |
This is a discussion of radioactivity and radiation, along with a description of the nuclear chain reaction and how nuclear power stations and nuclear weapons are produced. |
| Gravitation and Satellite Motion |
This section introduces Newton's Law of Universal Gravitation. It uses this new force combined with the ideas of circular motion to help us understand ideas of planetary motion. A complete treatment of planetary motion doesn't come until later in the year, when we study the concepts of energy and momentum. |
| Electrostatics |
This topic is about how charges can be separated, and how charged objects behave physically. There's a discussion of the electric force (Coulomb's law,) of how much charge an object can hold, and of the electric field, which we'll understand as being very similar to the gravitational field. We'll also discuss lightning and dielectric breakdown |
| Electric Circuits Videos: 1.) Wimshurst Machine (9/2017) 2.) Capacitor (3/2016) 3.) Measuring Voltage and Current in a Circuit (4/2018) 4.) The Meaning of Voltage in a Circuit (9/2017) 5.) Resistance and Ohm's Law (9/2017) 6.) Drawing a Schematic (5/2017) 7.) Series Circuits (10/2017) 8.) Kirchhoff's Loop Rule (3/2016) 9.) Parallel Circuits (3/2018) 10.) Kirchhoff's Junction Rule (3/2016) 11.) Power (4/2017) 13.) Calculating Voltage, Current, and Power in a Series Circuit (5/2017) 14.) Calculating Voltage, Current, and Power in a Parallel Circuit (5/2017) |
This unit discusses the kind of electricity that comes from a battery, where charge always flows in one direction. We call the movement of charge current, and since the charge is always going in one direction we call it direct current. Batteries, light bulbs, resistors, and capacitors are discussed. We discuss Ohm's law for determining current in a branch of a circuit |
| Magnetism 1.) Ørsted's Law 2.) Magnetic Force on a Charged Particle and Motors |
In this unit, we begin by mapping magnetic fields. We then discuss Orsted's discovery that moving charge causes magentism, and go through a bit of atomic theory to understand how permanent magents are caused by electronic currents in atoms. We talk about the direction of force on moving charged particles and how this enables a DC electric motor to work. |
| AC Electric Circuits 1.) Faraday's Law and Generators 2.) Generators 3.) Motors and Generators 4.) Lenz's Law 5.) Transformers |
This unit gets put into the middle of the magnetism unit. Michael Faraday and Joesph Henry figured out in the middle of the 19th century how Orsted's discovery could work in reverse, that is, how magnets could be used to produce electricity. This allowed us to make the generators that supply us with power. The electricity produced by a generator doesn't all flow in one direction, it alternates going one way and then another, so we call it alternating current. This focuses on the amplitude and frequency of AC, how generators work, how transformers work, and how your cell phone charger converts AC power from the wall outlet to DC power for your phone to use. Magnetic braking and how an electric guitar works are part of this unit too. It wraps up with the phenomenon of electromagnetic waves, which are actually light waves, and will be talked about later on. |
| Sound 1.) Wave Reflections and Natural Frequencies 2.) Standing Waves and Resonance 3.) Beat Frequencies |
This unit discusses resonance in musical instruments, and Beat Frequencies |
| Current Progress |
This is how far we've gotten. |
--
2016-2017
To view the syllabus for this course, click here.
To see the daily journal for CP Physics, click here.
To access the entire course album, click here.
| One Dimensional Motion/Graphing |
We explore the meaning of the
slopes of (t,d) graphs and introduce the concept of "area under the
curve." We also define some important ideas: position, velocity, and
acceleration. |
| One Dimensional Kinematics & Dynamics |
A dimension is something that can be quantified using a number line. We'd usually call it "horizontal" or "vertical" or maybe "the x-axis" or "the y-axis." In this unit we study one dimension at a time. We look at the two most common types of motion, constant acceleration and constant velocity motion. That's all the "kinematics" part. The "dynamics" part is where we introduce the concept of force (a push or pull) and go through Newton's 3 laws for dealing with forces. |
| Momentum |
This concept is useful for helping to understand situations where complex forces are acting, forces that increase and decrease during the interaction. We'll see it is especially helpful for collisions and explosions. There are two main topics: first, where momentum is changed by an outside force, and second, where there are no outside forces and momentum remains constant. |
| Vectors |
An introduction in how to handle quantities with direction that act in more than one dimension |
| Two Dimensional Kinematics & Dynamics |
In this unit we use a force board to see how forces add in two dimensions, which is an introduction to how all vectors add and subtract. We then learn about forces in two dimensions, including a new force, the frictional force. |
| Projectile Motion |
In this unit, we work with motion in two dimensions. It's a relatively minor part of the course, but we'll spend a large amount of time on it, because it's the first topic that requires us to organize our thinking. We'll also introduce what I call the Vegas rule: "what happens in horizontal stays in horizontal, and what happens in vertical stays in vertical." |
| Gravitation & Satellite Motion |
This section introduces Newton's Law of Universal Gravitation. It uses this new force combined with the ideas of circular motion to help us understand ideas of planetary motion. |
| Energy |
This is the most important unit in the course for helping us be better citizens. It goes through what "doing work" means in physics and discusses what objects or phenomena have the ability to do work. The ability to do work is called energy, and it's the reason energy is so important in our society: if we we want to change our environment, we need energy to do it. It will also be a valuable tool in solving problems that were too difficult to do using the concept of forces.Finally, Power (the "velocity" of energy) is discussed. |
| Atomic Energy |
This is a discussion of radioactivity and radiation, along with a description of the nuclear chain reaction and how nuclear power stations and nuclear weapons are produced. |
| Electrostatics |
This topic is about how charges can be separated, and how charged objects behave physically. There's a discussion of the electric force (Coulomb's law,) of how much charge an object can hold, and of the electric field, which we'll understand as being very similar to the gravitational field. We'll also discuss lightning and dielectric breakdown |
| DC Electric Circuits |
This unit discusses the kind of electricity that comes from a battery, where charge always flows in one direction. We call the movement of charge current, and since the charge is always going in one direction we call it direct current. Batteries, light bulbs, resistors, and capacitors are discussed. We discuss Ohm's law for determining current in a branch of a circuit |
| Final Review |
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