1.1 Position, Velocity, and Acceleration
8 min read•december 22, 2022
Daniella Garcia-Loos
Daniella Garcia-Loos
, , and are three fundamental concepts in physics that are related to the motion of an object. Together, these three concepts form the basis for understanding the motion of objects. In AP Physics 1, you will learn more about these concepts and how to use them to solve problems involving the motion of objects.
Frames of Reference 👨💻
All forces share certain common characteristics when considered by observers in inertial reference frames. (A in which a body remains at rest or moves with constant linear unless acted upon by forces)
Key Vocabulary: - a point of view 👀
⟶ Motion involves the change in of an object over a period of time, and it is measured in reference to another object.
EXAMPLE: Two students are in a classroom sitting at their desks. Are they moving relative to each other?
Are they moving relative to the solar system?
|
Essential Knowledge 3.A.1 🏘
An observer in a reference frame can describe the motion of an object using such quantities as , displacement, , , , and .
A is a set of points or objects that are used as a reference for measuring positions and movements. In physics, frames of reference are used to describe the motion of objects and to assign values to physical quantities such as , , and . Here are some key points to remember about frames of reference in AP Physics 1:
- A can be fixed, meaning it does not move, or it can be moving at a constant .
- The choice of a can affect the values of physical quantities such as , , and .
- When describing the motion of an object, it is important to specify the in which the measurements are taken.
- In a non-accelerating , an object's is constant if and only if its is zero.
- In a that is accelerating, an object's will change even if its is zero. This is known as the "" or the " due to the change in ."
- When describing the motion of an object in a that is accelerating, it is useful to use the concept of , which takes into account the of the .
🌎
Key Vocabulary: - a location relative to a fixed point
⟶ You can represent in a (m) vs. Time (s) Graph (pictured below)
Image courtesy of ck12.org
Interpreting the Graph
To determine which way an object is moving look at which way the vs. Time Graph is sloped
A front slash / indicates that an object is moving away from the detector
A black slash \ indicates that an object is moving towards the detector
The slope of a vs. Time Graph is equal to
When the slope is a straight line it has constant
When the slope is a curved lived there is (a change in )
When the slope is zero the object is at rest
The y-intercept is the initial displacement of an object
⟶ Still feeling a little confused on vs. Time Graphs? Don’t worry! Check out this video from Khan Academy for more practice!
Scalar vs. Vector Quantities 💫
Key Vocabulary: Scalar - quantities that are described by magnitude (a numerical value) alone
Example: She is five feet tall
and are scalar quantities
Key Vocabulary: Vector - quantities that are described by a size (magnitude) and a direction (ex. East, Up, Right, etc.)
Example: The gas station is five miles west from the car
Displacement, , and are vector quantities
Vectors can also be represented by arrows, and the length of the arrow should represent the magnitude of the described quantity. From the image below you can see the 5m arrow is smaller in length than the 50m arrow to reflect the difference in magnitude of the two quantities.
Here are some key points to remember about the difference between scalar and vector quantities in AP Physics 1:
- Scalar quantities can be added or subtracted using simple arithmetic, but vector quantities require the use of vector addition or subtraction.
- Vector quantities have a direction associated with them, while scalar quantities do not.
- Scalar quantities are described by a single number, while vector quantities are described by both a magnitude and a direction.
- Examples of scalar quantities include mass, volume, density, and temperature. Examples of vector quantities include displacement, , , and force.
- Scalar quantities can be represented by a single point on a number line, while vector quantities are represented by an arrow with a magnitude and a direction.
- Scalar quantities are often denoted by lowercase letters, while vector quantities are often denoted by uppercase letters.
⟶ Are you still feeling a little confused about Scalar vs. Vector Quantities? Don’t worry! Check out this video from Khan Academy for more practice!
Displacement vs. 🚴♀️
Key Vocabulary: Displacement - how far an object is from its original
Express with a Sign (+ or -) or Direction (North, Down, Left, etc.)
SI Unit: Meter (m)
We use the symbol Δx to indicate displacement
⟶ Typical Displacement Question: How far are you from home?
Key Vocabulary: - how far an object has traveled
Needs no
SI Unit: Meter (m)
⟶ Typical Question: How far did you travel?
Displacement and are two important concepts in physics that are often confused with one another. Here are some key points to remember about the difference between displacement and in AP Physics 1:
- Displacement is a that represents the change in the of an object. It is defined as the final of an object minus its initial .
- is a that represents the total length of the path traveled by an object. It does not take into account the direction of travel.
- Displacement has both a magnitude and a direction, while has only a magnitude.
- Displacement is a measure of the change in the of an object, while is a measure of the total length of the path traveled by an object.
As you can see from the image below, takes into account the journey an object takes whereas displacement is concerned with the of the original .
Image Couretsy of thescienceclassroom.org
EXAMPLE:
|
⟶ Still feeling a little confused about vs. Displacement? Don’t worry! Check out this video from Khan Academy for more practice!
vs. 🏇
Key Vocabulary: - describes how fast a particle is moving
SI Unit: Meters (m)/Seconds (s)
Equation: S = D/t
Key Vocabulary: - in a given direction
SI Unit: Meters (m)/Seconds (s)
Equation: V = x/t
⟶ You can represent in a (m/s) vs. Time (s) Graph (pictured below)
Image Courtesy of ck12.org
Interpreting the Graph
To determine which way the object is moving look at whether the vs. Time Graph is above or below the horizontal axis (x-axis)
An object is moving away from the detector if it’s above
An object is moving towards the detector if it’s below
The y-intercept is the initial of an object
The slope of a graph is equal to the
When the slope is zero the object has constant
When the slope is a straight line it has constant
When the slope is a curved line there is changing
The area under the curve is displacement
The object is stopped when y = 0
The y-intercept is the initial of an object
When the slope is zero the object has constant
The area under the curve is
20 m/s (the area under the curve is 4 x 3 + ½ x 4 x 4)
2 m/s (the area under the curve is ½ x 2 x 2)
⟶ The table below is a type of motion cheat sheet. Memorizing this will help you ace any quizzes or tests with graph interpretation present!
Type of Motion | ||
V = 0 | A = 0 | At rest |
V = (+) or (-) | A = 0 | Constant |
V = (+) | A = (+) | Speeding up |
V = (-) | A = (-) | Speeding up |
V = (+) | A = (-) | Slowing down |
V = (-) | A = (+) | Slowing down |
FRQ PRACTICE: Want more practice with and Average ? Check out these FRQs from the 2016 AP Physics 1 exam. |
🚀
Key Vocabulary: - a change in (magnitude or direction)
Equation: Aavg = V/t
⟶ You can represent in an (m/s/s) vs. Time (s) Graph (pictured below)
Image courtesy of khanacademy.org
Interpreting the Graph
EXAMPLE: (Reference the Graph above to answer the following questions) What is the of the object from 0s - 7s? What is the of the object from 7s - 9s? |
Still Looking for more? Check out Fiveable's Live Streams on this topic:
🎥 Watch AP Physics 1 - &
🎥 Watch AP Physics 1 - vs. Time Graphs
🎥 Watch AP Physics 1 - vs. Time Graphs
Key Terms to Review (15)
Aavg = V/t (Average Acceleration equation)
: The average acceleration equation, Aavg = V/t, determines how quickly an object's velocity changes over time by dividing the change in velocity (V) by the time interval (t).Acceleration
: Acceleration refers to the rate at which an object's velocity changes over time. It can be positive (speeding up), negative (slowing down), or zero (constant speed).Distance
: Distance refers to the amount of space between two points. It is a scalar quantity that only considers magnitude and not direction.Fictitious Force
: Fictitious force (also known as pseudo force) is an apparent force that appears to act on an object but actually arises from the acceleration of the reference frame itself.Frame of Reference
: A frame of reference is a set of coordinates that are used to describe the position and motion of objects. It provides a point from which measurements can be made.Position
: Position refers to the location of an object in relation to a reference point.Relative Velocity
: Relative velocity refers to the velocity of an object as observed from another moving object or reference frame.S = D/t (Speed equation)
: The speed equation, S = D/t, relates speed (S) with distance traveled (D) and time taken (t). It allows us to calculate an object's average speed when we know both distance and time values.Scalar quantity
: A scalar quantity is a physical measurement that only has magnitude and no direction. It can be described by a single value.SI Unit (in context of Meter)
: The SI unit is the International System of Units, which provides a standardized system for measuring physical quantities. In the context of meters, it refers to the fundamental unit used to measure length.Speed
: The rate at which an object moves or changes position over time.V = x/t (Velocity equation)
: The velocity equation, V = x/t, calculates the speed of an object by dividing the distance traveled (x) by the time taken (t).Vector Quantity
: A vector quantity is a physical quantity that has both magnitude and direction. It can be represented by an arrow, where the length of the arrow represents the magnitude and the direction of the arrow represents the direction.Velocity
: Velocity refers to the rate at which an object changes its position in a specific direction. It includes both speed and direction.Δx (Delta x - symbol for displacement)
: Δx represents the change in position or displacement between two points. It is commonly used in physics equations to quantify how far an object has moved from its initial position.1.1 Position, Velocity, and Acceleration
8 min read•december 22, 2022
Daniella Garcia-Loos
Daniella Garcia-Loos
, , and are three fundamental concepts in physics that are related to the motion of an object. Together, these three concepts form the basis for understanding the motion of objects. In AP Physics 1, you will learn more about these concepts and how to use them to solve problems involving the motion of objects.
Frames of Reference 👨💻
All forces share certain common characteristics when considered by observers in inertial reference frames. (A in which a body remains at rest or moves with constant linear unless acted upon by forces)
Key Vocabulary: - a point of view 👀
⟶ Motion involves the change in of an object over a period of time, and it is measured in reference to another object.
EXAMPLE: Two students are in a classroom sitting at their desks. Are they moving relative to each other?
Are they moving relative to the solar system?
|
Essential Knowledge 3.A.1 🏘
An observer in a reference frame can describe the motion of an object using such quantities as , displacement, , , , and .
A is a set of points or objects that are used as a reference for measuring positions and movements. In physics, frames of reference are used to describe the motion of objects and to assign values to physical quantities such as , , and . Here are some key points to remember about frames of reference in AP Physics 1:
- A can be fixed, meaning it does not move, or it can be moving at a constant .
- The choice of a can affect the values of physical quantities such as , , and .
- When describing the motion of an object, it is important to specify the in which the measurements are taken.
- In a non-accelerating , an object's is constant if and only if its is zero.
- In a that is accelerating, an object's will change even if its is zero. This is known as the "" or the " due to the change in ."
- When describing the motion of an object in a that is accelerating, it is useful to use the concept of , which takes into account the of the .
🌎
Key Vocabulary: - a location relative to a fixed point
⟶ You can represent in a (m) vs. Time (s) Graph (pictured below)
Image courtesy of ck12.org
Interpreting the Graph
To determine which way an object is moving look at which way the vs. Time Graph is sloped
A front slash / indicates that an object is moving away from the detector
A black slash \ indicates that an object is moving towards the detector
The slope of a vs. Time Graph is equal to
When the slope is a straight line it has constant
When the slope is a curved lived there is (a change in )
When the slope is zero the object is at rest
The y-intercept is the initial displacement of an object
⟶ Still feeling a little confused on vs. Time Graphs? Don’t worry! Check out this video from Khan Academy for more practice!
Scalar vs. Vector Quantities 💫
Key Vocabulary: Scalar - quantities that are described by magnitude (a numerical value) alone
Example: She is five feet tall
and are scalar quantities
Key Vocabulary: Vector - quantities that are described by a size (magnitude) and a direction (ex. East, Up, Right, etc.)
Example: The gas station is five miles west from the car
Displacement, , and are vector quantities
Vectors can also be represented by arrows, and the length of the arrow should represent the magnitude of the described quantity. From the image below you can see the 5m arrow is smaller in length than the 50m arrow to reflect the difference in magnitude of the two quantities.
Here are some key points to remember about the difference between scalar and vector quantities in AP Physics 1:
- Scalar quantities can be added or subtracted using simple arithmetic, but vector quantities require the use of vector addition or subtraction.
- Vector quantities have a direction associated with them, while scalar quantities do not.
- Scalar quantities are described by a single number, while vector quantities are described by both a magnitude and a direction.
- Examples of scalar quantities include mass, volume, density, and temperature. Examples of vector quantities include displacement, , , and force.
- Scalar quantities can be represented by a single point on a number line, while vector quantities are represented by an arrow with a magnitude and a direction.
- Scalar quantities are often denoted by lowercase letters, while vector quantities are often denoted by uppercase letters.
⟶ Are you still feeling a little confused about Scalar vs. Vector Quantities? Don’t worry! Check out this video from Khan Academy for more practice!
Displacement vs. 🚴♀️
Key Vocabulary: Displacement - how far an object is from its original
Express with a Sign (+ or -) or Direction (North, Down, Left, etc.)
SI Unit: Meter (m)
We use the symbol Δx to indicate displacement
⟶ Typical Displacement Question: How far are you from home?
Key Vocabulary: - how far an object has traveled
Needs no
SI Unit: Meter (m)
⟶ Typical Question: How far did you travel?
Displacement and are two important concepts in physics that are often confused with one another. Here are some key points to remember about the difference between displacement and in AP Physics 1:
- Displacement is a that represents the change in the of an object. It is defined as the final of an object minus its initial .
- is a that represents the total length of the path traveled by an object. It does not take into account the direction of travel.
- Displacement has both a magnitude and a direction, while has only a magnitude.
- Displacement is a measure of the change in the of an object, while is a measure of the total length of the path traveled by an object.
As you can see from the image below, takes into account the journey an object takes whereas displacement is concerned with the of the original .
Image Couretsy of thescienceclassroom.org
EXAMPLE:
|
⟶ Still feeling a little confused about vs. Displacement? Don’t worry! Check out this video from Khan Academy for more practice!
vs. 🏇
Key Vocabulary: - describes how fast a particle is moving
SI Unit: Meters (m)/Seconds (s)
Equation: S = D/t
Key Vocabulary: - in a given direction
SI Unit: Meters (m)/Seconds (s)
Equation: V = x/t
⟶ You can represent in a (m/s) vs. Time (s) Graph (pictured below)
Image Courtesy of ck12.org
Interpreting the Graph
To determine which way the object is moving look at whether the vs. Time Graph is above or below the horizontal axis (x-axis)
An object is moving away from the detector if it’s above
An object is moving towards the detector if it’s below
The y-intercept is the initial of an object
The slope of a graph is equal to the
When the slope is zero the object has constant
When the slope is a straight line it has constant
When the slope is a curved line there is changing
The area under the curve is displacement
The object is stopped when y = 0
The y-intercept is the initial of an object
When the slope is zero the object has constant
The area under the curve is
20 m/s (the area under the curve is 4 x 3 + ½ x 4 x 4)
2 m/s (the area under the curve is ½ x 2 x 2)
⟶ The table below is a type of motion cheat sheet. Memorizing this will help you ace any quizzes or tests with graph interpretation present!
Type of Motion | ||
V = 0 | A = 0 | At rest |
V = (+) or (-) | A = 0 | Constant |
V = (+) | A = (+) | Speeding up |
V = (-) | A = (-) | Speeding up |
V = (+) | A = (-) | Slowing down |
V = (-) | A = (+) | Slowing down |
FRQ PRACTICE: Want more practice with and Average ? Check out these FRQs from the 2016 AP Physics 1 exam. |
🚀
Key Vocabulary: - a change in (magnitude or direction)
Equation: Aavg = V/t
⟶ You can represent in an (m/s/s) vs. Time (s) Graph (pictured below)
Image courtesy of khanacademy.org
Interpreting the Graph
EXAMPLE: (Reference the Graph above to answer the following questions) What is the of the object from 0s - 7s? What is the of the object from 7s - 9s? |
Still Looking for more? Check out Fiveable's Live Streams on this topic:
🎥 Watch AP Physics 1 - &
🎥 Watch AP Physics 1 - vs. Time Graphs
🎥 Watch AP Physics 1 - vs. Time Graphs
Key Terms to Review (15)
Aavg = V/t (Average Acceleration equation)
: The average acceleration equation, Aavg = V/t, determines how quickly an object's velocity changes over time by dividing the change in velocity (V) by the time interval (t).Acceleration
: Acceleration refers to the rate at which an object's velocity changes over time. It can be positive (speeding up), negative (slowing down), or zero (constant speed).Distance
: Distance refers to the amount of space between two points. It is a scalar quantity that only considers magnitude and not direction.Fictitious Force
: Fictitious force (also known as pseudo force) is an apparent force that appears to act on an object but actually arises from the acceleration of the reference frame itself.Frame of Reference
: A frame of reference is a set of coordinates that are used to describe the position and motion of objects. It provides a point from which measurements can be made.Position
: Position refers to the location of an object in relation to a reference point.Relative Velocity
: Relative velocity refers to the velocity of an object as observed from another moving object or reference frame.S = D/t (Speed equation)
: The speed equation, S = D/t, relates speed (S) with distance traveled (D) and time taken (t). It allows us to calculate an object's average speed when we know both distance and time values.Scalar quantity
: A scalar quantity is a physical measurement that only has magnitude and no direction. It can be described by a single value.SI Unit (in context of Meter)
: The SI unit is the International System of Units, which provides a standardized system for measuring physical quantities. In the context of meters, it refers to the fundamental unit used to measure length.Speed
: The rate at which an object moves or changes position over time.V = x/t (Velocity equation)
: The velocity equation, V = x/t, calculates the speed of an object by dividing the distance traveled (x) by the time taken (t).Vector Quantity
: A vector quantity is a physical quantity that has both magnitude and direction. It can be represented by an arrow, where the length of the arrow represents the magnitude and the direction of the arrow represents the direction.Velocity
: Velocity refers to the rate at which an object changes its position in a specific direction. It includes both speed and direction.Δx (Delta x - symbol for displacement)
: Δx represents the change in position or displacement between two points. It is commonly used in physics equations to quantify how far an object has moved from its initial position.
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