AP Physics 1 Unit 2: Force and Translational Dynamics PDF

Summary

This document is a unit of the AP Physics 1 course, covering Force and Translational Dynamics. It includes learning objectives, essential knowledge, and suggested skills for students. The content is suitable for secondary school physics.

Full Transcript

AP PHYSICS 1

UNIT 2
Force and
Translational
Dynamics

18–23%
AP EXAM WEIGHTING

~22–27
CLASS PERIODS

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 Remember to go to AP Classroom
to assign students the online
Progress Check for this unit.
Whether assigned as homework or
completed in class, the Progress
Check provides each student with
immediate feedback related to this
unit’s topics and science practices.

Progress Check 2
Multiple-choice: ~30 questions
Free-response: 4 questions
§ Mathematical Routines
§ Translation Between
Representations
§ Experimental Design and
Analysis
§ Qualitative/Quantitative
Translation

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 UNIT

2 18–23% AP EXAM WEIGHTING ~22–27 CLASS PERIODS

Force and
Translational
Dynamics
Developing Understanding
ESSENTIAL In Unit 2, students are introduced to the concept of force, which is an interaction between
QUESTIONS two objects or systems of objects. Part of the larger study of dynamics, forces provide
§ Why do we feel pulled thecontextinwhichstudentsanalyzeandcometounderstandavarietyofphysical
toward Earth but not phenomena. This understanding is accomplished by revisiting and building upon the models
toward a pencil? andrepresentationspresentedinUnit1—specificallythroughtheintroductionofthefree-
§§ Whyisitmoredifficult
bodydiagram.Studentswillfurtheranalyzetheeffectofforcesonsystemswhenthey
to stop a fully loaded
encounter Newton’s second law in rotational form in Unit 5.
dump truck than a small in the domain. This skill appears in the fourth
passenger car?
Building the Science
questionofthefree-responsesection,
§§ Whyisitdifficulttowalk
Practices the Qualitative/Quantitative Translation
on ice? 2.A 2.D 3.B 3.C (QQT) question. In this question, students
§§ Why will a delivery truck Translation between models and demonstrate translation between words and
filledwithbirdssitting representations is key in this unit. Students will mathematicsbydescribingandanalyzing
onitsfloorbethesame continue to use models and representations a scenario. Using content from any unit,
weight as a truck with the thatwillhelpthemfurtheranalyzesystems, theQQTfirstrequiresstudentstomakea
samebirdsflyingaround the interactions between systems, and how claim and provide evidence and reasoning
inside? these interactions result in change. Alongside to support their claim without reference
gainingproficiencyintheuseofspecificforce to equations. Students are then asked to
equations, Unit 2 also encourages students derive an equation or set of equations to
to derive new expressions from fundamental mathematically represent the scenario.
principles (2.A) to help them make Lastly, students are required to make a
predictions using functional dependence connection between the claim made in the
between variables (2.D). The skills of making firstpartofthequestionandtheequation(s)
claims (3.B) and supporting those claims derived in the second part. Students
using evidence (3.C) can be developed exposed primarily to numerical problem
throughout the unit by providing students solving often struggle with the QQT because
with opportunities such as having them it requires them to express a conceptual
make predictions about the acceleration of a understanding of course content and
system based on the forces exerted on that representations. Opportunities to translate
system, and then justifying those predictions betweendifferentrepresentations,including
with appropriate physics principles. equations, diagrams, graphs, and verbal
descriptions, can help students prepare for
Preparing for the AP Exam the QQT question.

The AP Physics 1 Exam requires students
tore-expresskeyelementsofphysical
phenomena across multiple representations
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 UNIT

2 Force and Translational Dynamics

UNIT AT A GLANCE

Topic Suggested Skills

2.1 Systems and Center 1.B Create quantitative graphs with appropriate scales and units, including plotting data.
of Mass
2.B Calculate or estimate an unknown quantity with units from known quantities, by selecting
and following a logical computational pathway.

2.C Comparephysicalquantitiesbetweentwoormorescenariosoratdifferenttimesand
locations in a single scenario.

3.B

2.2 Forces and 1.A Create diagrams, tables, charts, or schematics to represent physical situations.
Free-Body Diagrams
2.B Calculate or estimate an unknown quantity with units from known quantities, by selecting
and following a logical computational pathway.

2.C

3.C Justify or support a claim using evidence from experimental data, physical
representations, or physical principles or laws.

2.3 Newton’s Third Law 1.A Create diagrams, tables, charts, or schematics to represent physical situations.

2.D Predict new values or factors of change of physical quantities using functional
dependence between variables.

3.B Applyanappropriatelaw,definition,theoreticalrelationship,ormodeltomakeaclaim.

3.C Justify or support a claim using evidence from experimental data, physical
representations, or physical principles or laws.

2.4 Newton’s First Law 1.C Create qualitative sketches of graphs that represent features of a model or the behavior of a
physicalsystem.

2.A Derive a symbolic expression from known quantities by selecting and following a logical
mathematical pathway.

3.B

3.C Justify or support a claim using evidence from experimental data, physical
representations, or physical principles or laws.

continued on next page

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 UNIT
Force and Translational Dynamics
2
UNIT AT A GLANCE (cont’d)

Topic Suggested Skills

2.5 Newton’s Second 1.A Create diagrams, tables, charts, or schematics to represent physical situations.
Law
2.A Derive a symbolic expression from known quantities by selecting and following a logical
mathematical pathway.

2.D Predict new values or factors of change of physical quantities using functional
dependence between variables.

3.B Applyanappropriatelaw,definition,theoreticalrelationship,ormodeltomakeaclaim.

2.6 Gravitational Force 1.A Create diagrams, tables, charts, or schematics to represent physical situations.

2.A Derive a symbolic expression from known quantities by selecting and following a logical
mathematical pathway.

2.D Predict new values or factors of change of physical quantities using functional
dependence between variables.

3.C Justify or support a claim using evidence from experimental data, physical
representations, or physical principles or laws.

2.7 Kinetic and Static 1.C Create qualitative sketches of graphs that represent features of a model or the behavior of a
Friction physical system.

2.B Calculate or estimate an unknown quantity with units from known quantities, by selecting
and following a logical computational pathway.

2.C Comparephysicalquantitiesbetweentwoormorescenariosoratdifferenttimesand
locations in a single scenario.

3.B Applyanappropriatelaw,definition,theoreticalrelationship,ormodeltomakeaclaim.

continued on next page

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2 Force and Translational Dynamics

UNIT AT A GLANCE (cont’d)

Topic Suggested Skills

2.8 Spring Forces 1.B Create quantitative graphs with appropriate scales and units, including plotting data.

2.A Derive a symbolic expression from known quantities by selecting and following a logical
mathematical pathway.

2.C Comparephysicalquantitiesbetweentwoormorescenariosoratdifferenttimesand
locations in a single scenario.

3.A Createexperimentalproceduresthatareappropriateforagivenscientificquestion.

3.B Applyanappropriatelaw,definition,theoreticalrelationship,ormodeltomakeaclaim.

2.9 Circular Motion 1.B Create quantitative graphs with appropriate scales and units, including plotting data.

2.A Derive a symbolic expression from known quantities by selecting and following a logical
mathematical pathway.

2.D Predict new values or factors of change of physical quantities using functional
dependence between variables.

3.A Createexperimentalproceduresthatareappropriateforagivenscientificquestion.

3.C Justify or support a claim using evidence from experimental data, physical
representations, or physical principles or laws.

Go to AP Classroom to assign the Progress Check for Unit 2.
Review the results in class to identify and address any student misunderstandings.

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Force and Translational Dynamics
2
SAMPLE INSTRUCTIONAL ACTIVITIES
Thesampleactivitiesonthispageareoptionalandareofferedtoprovidepossiblewaysto
incorporate various instructional approaches in the classroom. Teachers do not need to use
these activities or instructional approaches and are free to alter or edit them. The examples
below were developed in partnership with teachers from the AP community to share ways
that they approach teaching some of the topics in this unit. Please refer to the Instructional
Approaches section beginning on p. 153 for more examples of activities and strategies.

Activity Topic Sample Activity

1 2.2 Changing Representations
Havestudentsconsideranacceleratingtwo-objectsystemfromeverydaylife(e.g.,person
pushes a shopping cart, car pulls a trailer). Have them draw the forces on one object, then
ontheother,andthentheexternalforcesexertedonthetwo-objectsystem.

2 2.5 Working Backward
Put students in pairs. Have student A write a Newton’s second law equation either with
symbolsorplugged-innumbersincludingunits.Then,havestudentBdescribeasituation
that the equation applies to, including the object’s velocity direction and how velocity is
changing,adiagram,andafree-bodydiagram.

3 2.5 What, If Anything, Is Wrong?
Havestudentsidentifysomeforce-relatedproblemfromtheirhomeworkortextbook(that
requires setting up Newton’s second law and maybe more). Ask students to write out a
detailed solution that has exactly one mistake in it (not a calculation error). Post everyone’s
problems/solutions, and then ask students to identify everyone else’s errors. The last
student to have their error found wins.

4 2.7 Desktop Experiment Task
Havestudentsmeasurethecoefficientofstaticfrictionoftheirshoeonawoodplankor
metal track. Level 1: Use a spring scale. Level 2: Use a pulley, a spring, a toy bucket, and an
electronic balance. Level 3: Use a protractor.

5 2.6/2.9 Desktop Experiment Task
Have students use the “My Solar System” PhET applet to create circular orbits of varying
radii around the central star and record radius, period, and planet mass for various trials.
Next, have them calculate the speed using v = 2 r/T and force using F = mv 2 /r. Using the
data, have students show that gravitational force is directly proportional to the mass of
each object and inversely proportional to the square of the radius.

6 2.9 Construct an Argument
Askstudentstoconsidertwoidenticalobjectsmovingincircles(orpartsofcircles)ofdifferent
radii. Then, ask them to think of a situation where the object with the smaller radius has a
greater net force and another situation where the object with the larger radius has a greater
net force.

7 2.9 Changing Representations
Describe something a driver could be doing in a car (e.g., “turning the steering wheel to the
right while pressing the brake”). Have students walk out the motion while holding out one arm
representing the velocity vector and the other arm representing the acceleration vector.

8 2.9 Predict and Explain
Attach an object of known weight (say, 2 N) to a force sensor and cause the object to swing
ina180-degreearc.Askstudents,“Atthebottom,theobjectisneitherspeedingupnor
slowing down, so what force is registered at the bottom?” Expect students to (incorrectly)
answer, “2 N” and discuss, as a class, why this answer is incorrect.

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2 Force and Translational Dynamics

SUGGESTED SKILLS
1.B TOPIC 2.1
Systems and
Create quantitative graphs
with appropriate scales
and units, including plotting

Center of Mass
data.
2.B
Calculate or estimate an
unknown quantity with units
from known quantities, by
selecting and following
a logical computational
pathway.
2.C
Compare physical
Required Course Content
quantities between two
or more scenarios or
atdifferenttimesand
locations in a single LEARNING OBJECTIVE ESSENTIAL KNOWLEDGE
scenario.
2.1.A 2.1.A.1
3.B
Describe the properties and System properties are determined by the
Apply an appropriate law,
interactions of a system. interactions between objects within the
definition,theoretical
system.
relationship, or model to
make a claim. 2.1.A.2
If the properties or interactions of the
constituent objects within a system are not
important in modeling the behavior of the
macroscopic system, the system can itself be
treated as a single object.
2.1.A.3
Systems may allow interactions between
constituent parts of the system and the
environment, which may result in the transfer of
energy or mass.
2.1.A.4
Individual objects within a chosen system may
behavedifferentlyfromeachotheraswellas
from the system as a whole.
2.1.A.5
Theinternalstructureofasystemaffectsthe
analysis of that system.
2.1.A.6
As variables external to a system are changed,
the system’s substructure may change.

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Force and Translational Dynamics
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LEARNING OBJECTIVE ESSENTIAL KNOWLEDGE
2.1.B 2.1.B.1
Describe the location of a For systems with symmetrical mass
system’s center of mass distributions, the center of mass is located on
with respect to the system’s lines of symmetry.
constituent parts. 2.1.B.2
The location of a system’s center of mass
along a given axis can be calculated using the
equation


x cm =
∑mi x i
∑mi
2.1.B.3
A system can be modeled as a singular object
that is located at the system’s center of mass.

BOUNDARY STATEMENT
AP Physics 1 only expects students to calculate the center of mass for systems of
five or fewer particles arranged in a two-dimensional configuration or for systems
that are highly symmetrical.

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2 Force and Translational Dynamics

SUGGESTED SKILLS
1.A TOPIC 2.2
Forces and
Create diagrams, tables,
charts, or schematics
to represent physical

Free-Body Diagrams
situations.
2.B
Calculate or estimate an
unknown quantity with units
from known quantities, by
selecting and following
a logical computational
pathway.
2.C
Compare physical
Required Course Content
quantities between two
or more scenarios or
atdifferenttimesand
locations in a single LEARNING OBJECTIVE ESSENTIAL KNOWLEDGE
scenario.
2.2.A 2.2.A.1
3.C
Describe a force as an Forces are vector quantities that describe the
Justify or support a claim
interaction between two interactions between objects or systems.
using evidence from
objects or systems.
experimental data, physical 2.2.A.1.i
representations, or physical A force exerted on an object or system is
principles or laws. always due to the interaction of that object
with another object or system.
2.2.A.1.ii
An object or system cannot exert a net
force on itself.

2.2.A.2
Contact forces describe the interaction of
an object or system touching another object
orsystemandaremacroscopiceffectsof
interatomic electric forces.

2.2.B 2.2.B.1
Describe the forces exerted Free-bodydiagramsareusefultoolsfor
on an object or system using visualizingforcesbeingexertedonasingle
afree-bodydiagram. object or system and for determining the
equations that represent a physical situation.
2.2.B.2
Thefree-bodydiagramofanobjectorsystem
shows each of the forces exerted on the object
by the environment.
2.2.B.3
Forces exerted on an object or system are
represented as vectors originating from the
representation of the center of mass, such as
a dot. A system is treated as though all of its
mass is located at the center of mass.

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Force and Translational Dynamics
2
LEARNING OBJECTIVE ESSENTIAL KNOWLEDGE
2.2.B 2.2.B.4
Describe the forces exerted A coordinate system with one axis parallel to
on an object using a free- the direction of acceleration of the object or
body diagram. systemsimplifiesthetranslationfromfree-
body diagram to algebraic representation. For
example,inafree-bodydiagramofanobject
on an inclined plane, it is useful to set one axis
parallel to the surface of the incline.

BOUNDARY STATEMENT
AP Physics 1 only expects students to depict the forces exerted on objects, not
the force components on free-body diagrams. On the AP Physics exams, individual
forces represented on a free-body diagram must be drawn as individual straight
arrows, originating on the dot and pointing in the direction of the force. Individual
forces that are in the same direction must be drawn side by side, not overlapping.

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2 Force and Translational Dynamics

SUGGESTED SKILLS
1.A TOPIC 2.3
Newton’s Third Law
Create diagrams, tables,
charts, or schematics
to represent physical
situations.
2.D
Predict new values or
factors of change of
physical quantities using
functional dependence
between variables.
3.B
Apply an appropriate law,
definition,theoretical
Required Course Content
relationship, or model to
make a claim.
3.C
Justify or support a claim
LEARNING OBJECTIVE ESSENTIAL KNOWLEDGE
using evidence from 2.3.A 2.3.A.1
experimental data, physical Describe the interaction of Newton’s third law describes the interaction of
representations, or physical
two objects using Newton’s two objects in terms of the paired forces that
principles or laws.
third law and a representation each exerts on the other.
of paired forces exerted on
each object.
2.3.A.2
Interactions between objects within a system
(internalforces)donotinfluencethemotionof
a system’s center of mass.
2.3.A.3
Tension is the macroscopic net result of forces
that segments of a string, cable, chain, or
similar system exert on each other in response
to an external force.
2.3.A.3.i
An ideal string has negligible mass and
does not stretch when under tension.
2.3.A.3.ii
The tension in an ideal string is the same at
all points within the string.
2.3.A.3.iii
In a string with nonnegligible mass, tension
may not be the same at all points within the
string.
2.3.A.3.iv
An ideal pulley is a pulley that has negligible
mass and rotates about an axle through its
center of mass with negligible friction.

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Force and Translational Dynamics
2
LEARNING OBJECTIVE ESSENTIAL KNOWLEDGE
2.3.A
Describe the interaction of
two objects using Newton’s
third law and a representation
of paired forces exerted on
each object.

BOUNDARY STATEMENT
AP Physics 1 only expects students to describe tension qualitatively in a string,
cable, chain, or similar system with mass. For example, students might note that the
tension in a hanging chain is greater toward the top of the chain.

BOUNDARY STATEMENT
The interaction between objects or systems at a distance is limited to gravitational
forces in AP Physics 1. In AP Physics 2, gravitational, electric, and magnetic forces
may be considered.

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2 Force and Translational Dynamics

SUGGESTED SKILLS
1.C TOPIC 2.4
Newton’s First Law
Create qualitative sketches
of graphs that represent
features of a model or
the behavior of a physical
system.
2.A
Derive a symbolic
expression from known
quantities by selecting
and following a logical
mathematical pathway.
3.B
Apply an appropriate law,
Required Course Content
definition,theoretical
relationship, or model to
make a claim.
3.C LEARNING OBJECTIVE ESSENTIAL KNOWLEDGE
Justify or support a claim 2.4.A 2.4.A.1
using evidence from Describe the conditions The net force on a system is the vector sum of
experimental data, physical
under which a system’s all forces exerted on the system.
representations, or physical
velocity remains constant.
principles or laws. 2.4.A.2
Translationalequilibriumisaconfigurationof
forces such that the net force exerted on a
systemiszero.
Derived equation:

i
2.4.A.3
Newton’sfirstlawstatesthatifthenetforce
exertedonasystemiszero,thevelocityofthat
system will remain constant.
2.4.A.4
Forces may be balanced in one dimension
but unbalanced in another. The system’s
velocity will change only in the direction of the
unbalanced force.
2.4.A.5
An inertial reference frame is one from which
anobserverwouldverifyNewton’sfirstlawof
motion.

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Force and Translational Dynamics
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TOPIC 2.5 SUGGESTED SKILLS
1.A

Newton’s Second Law
Create diagrams, tables,
charts, or schematics
to represent physical
situations.
2.A
Derive a symbolic
expression from known
quantities by selecting
and following a logical
mathematical pathway.
2.D

Required Course Content Predict new values or
factors of change of
physical quantities using
functional dependence
between variables.
LEARNING OBJECTIVE ESSENTIAL KNOWLEDGE 3.B
2.5.A 2.5.A.1 Apply an appropriate law,
Describe the conditions Unbalancedforcesareaconfigurationof definition,theoretical
relationship, or model to
under which a system’s forces such that the net force exerted on a
make a claim.
velocity changes. systemisnotequaltozero.
2.5.A.2
Newton’s second law of motion states that the
acceleration of a system’s center of mass has
a magnitude proportional to the magnitude of
the net force exerted on the system and is in
the same direction as that net force.
Relevant equation:

2.5.A.3
The velocity of a system’s center of mass will
onlychangeifanonzeronetexternalforceis
exerted on that system.

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SUGGESTED SKILLS
1.A TOPIC 2.6
Gravitational Force
Create diagrams, tables,
charts, or schematics
to represent physical
situations.
2.A
Derive a symbolic
expression from known
quantities by selecting
and following a logical
mathematical pathway.
2.D
Predict new values or
factors of change of
Required Course Content
physical quantities using
functional dependence
between variables.
3.C LEARNING OBJECTIVE ESSENTIAL KNOWLEDGE
Justify or support a claim 2.6.A 2.6.A.1
using evidence from Describe the gravitational Newton’s law of universal gravitation describes
experimental data, physical
interaction between two the gravitational force between two objects
representations, or physical
objects or systems with or systems as directly proportional to each of
principles or laws.
mass. their masses and inversely proportional to the
square of the distance between the systems’
centers of mass.
Relevant equation:

2.6.A.1.i
The gravitational force is attractive.
2.6.A.1.ii
The gravitational force is always exerted
along the line connecting the centers of
mass of the two interacting systems.
2.6.A.1.iii
The gravitational force on a system can be
considered to be exerted on the system’s
center of mass.

2.6.A.2
Afieldmodelstheeffectsofanoncontact
force exerted on an object at various positions
in space.
2.6.A.2.i
The magnitude of the gravitational field
created by a system of mass M at a
point in space is equal to the ratio of the
gravitational force exerted by the system
on a test object of mass m to the mass of
the test object.

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Force and Translational Dynamics
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LEARNING OBJECTIVE ESSENTIAL KNOWLEDGE
2.6.A Derived equation:
Describe the gravitational
interaction between two
objects with mass.
2.6.A.2.ii
If the gravitational force is the only force
exerted on an object, the observed
acceleration of the object (in m/s2) is
numerically equal to the magnitude of the
gravitationalfieldstrength(inN/kg)atthat
location.

2.6.A.3
The gravitational force exerted by an
astronomical body on a relatively small nearby
object is called weight.
Derived Equation:
Weight = Fg = mg

2.6.B 2.6.B.1
Describe situations in which If the gravitational force between two systems’
the gravitational force can be centers of mass has a negligible change as the
considered constant. relative position of the two systems changes,
the gravitational force can be considered
constant at all points between the initial and
finalpositionsofthesystems.
2.6.B.2
Near the surface of Earth, the strength of the
gravitationalfieldis g ≈ 10 N/kg

2.6.C 2.6.C.1
Describe the conditions The magnitude of the apparent weight of a
under which the magnitude of system is the magnitude of the normal force
a system’s apparent weight is exerted on the system.
differentfromthemagnitude 2.6.C.2
of the gravitational force
If the system is accelerating, the apparent weight
exerted on that system.
of the system is not equal to the magnitude of
the gravitational force exerted on the system.
2.6.C.3
A system appears weightless when there are no
forces exerted on the system or when the force
of gravity is the only force exerted on the system.
2.6.C.4
The equivalence principle states that an
observer in a noninertial reference frame is
unable to distinguish between an object’s
apparent weight and the gravitational force
exertedontheobjectbyagravitationalfield.

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LEARNING OBJECTIVE ESSENTIAL KNOWLEDGE
2.6.D 2.6.D.1
Describe inertial and Objects have inertial mass, or inertia, a
gravitational mass. property that determines how much an object’s
motion resists changes when interacting with
another object.
2.6.D.2
Gravitational mass is related to the force of
attraction between two systems with mass.
2.6.D.3
Inertial mass and gravitational mass have been
experimentallyverifiedtobeequivalent.

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Force and Translational Dynamics
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TOPIC 2.7 SUGGESTED SKILLS
1.C

Kinetic and
Create qualitative sketches
of graphs that represent
features of a model or

Static Friction
the behavior of a physical
system.
2.B
Calculate or estimate an
unknown quantity with units
from known quantities, by
selecting and following
a logical computational
pathway.
Required Course Content 2.C
Compare physical
quantities between two
or more scenarios or
LEARNING OBJECTIVE ESSENTIAL KNOWLEDGE atdifferenttimesand
locations in a single
2.7.A 2.7.A.1
scenario.
Describe kinetic friction Kinetic friction occurs when two surfaces in 3.B
between two surfaces contact move relative to each other.
Apply an appropriate law,
2.7.A.1.i definition,theoretical
The kinetic friction force is exerted in a relationship, or model to
direction opposite to the motion of each make a claim.
surface relative to the other surface.
2.7.A.1.ii
The force of friction between two surfaces
doesnotdependonthesizeofthesurface
area of contact.

2.7.A.2
The magnitude of the kinetic friction force
exerted on an object is the product of the
normal force the surface exerts on the object
andthecoefficientofkineticfriction.
Relevant equation:

2.7.A.2.i
Thecoefficientofkineticfrictiondepends
on the material properties of the surfaces
that are in contact.
2.7.A.2.ii
Normal force is the perpendicular
component of the force exerted on an
object by the surface with which it is
in contact; it is directed away from the
surface.

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LEARNING OBJECTIVE ESSENTIAL KNOWLEDGE
2.7.B 2.7.B.1
Describe static friction Static friction may occur between the
between two surfaces. contacting surfaces of two objects that are not
moving relative to each other.
2.7.B.2
Static friction adopts the value and direction
required to prevent an object from slipping or
sliding on a surface.
Relevant equation:

f ,s s n

2.7.B.2.i
Slipping and sliding refer to situations in
which two surfaces are moving relative to
each other.
2.7.B.2.ii
There exists a maximum value for which
static friction will prevent an object from
slipping on a given surface.
Derived equation:
F f ,s ,max = µ s Fn

2.7.B.3
Thecoefficientofstaticfrictionistypically
greaterthanthecoefficientofkineticfriction
for a given pair of surfaces.

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Force and Translational Dynamics
2
TOPIC 2.8 SUGGESTED SKILLS
1.B

Spring Forces
Create quantitative graphs
with appropriate scales
and units, including plotting
data.
2.A
Derive a symbolic
expression from known
quantities by selecting
and following a logical
mathematical pathway.
2.C

Required Course Content Compare physical
quantities between two
or more scenarios or
atdifferenttimesand
locations in a single
LEARNING OBJECTIVE ESSENTIAL KNOWLEDGE scenario.

2.8.A 2.8.A.1 3.A

Describe the force exerted on An ideal spring has negligible mass and exerts Create experimental
procedures that are
an object by an ideal spring a force that is proportional to the change in its
appropriate for a given
length as measured from its relaxed length.
scientificquestion.
2.8.A.2
3.B
The magnitude of the force exerted by an ideal Apply an appropriate law,
spring on an object is given by Hooke’s law: definition,theoretical
relationship, or model to
make a claim.
2.8.A.3
The force exerted on an object by a spring is
always directed toward the equilibrium position
of the object–spring system.

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2 Force and Translational Dynamics

SUGGESTED SKILLS
1.B TOPIC 2.9
Circular Motion
Create quantitative graphs
with appropriate scales
and units, including plotting
data.
2.A
Derive a symbolic
expression from known
quantities by selecting
and following a logical
mathematical pathway.
2.D
Predict new values or
factors of change of
Required Course Content
physical quantities using
functional dependence
between variables.
3.A LEARNING OBJECTIVE ESSENTIAL KNOWLEDGE
Create experimental 2.9.A 2.9.A.1
procedures that are Describe the motion of an Centripetal acceleration is the component of
appropriate for a given
object traveling in a circular an object’s acceleration directed toward the
scientificquestion.
path. center of the object’s circular path.
3.C
2.9.A.1.i
Justify or support a claim
using evidence from The magnitude of centripetal acceleration
experimental data, physical for an object moving in a circular path is
representations, or physical the ratio of the object’s tangential speed
principles or laws. squared to the radius of the circular path.
Relevant equation:

2.9.A.1.ii
Centripetal acceleration is directed toward
the center of an object’s circular path.

2.9.A.2
Centripetal acceleration can result from
a single force, more than one force, or
components of forces exerted on an object in
circular motion.
2.9.A.2.i
At the top of a vertical, circular loop, an
object requires a minimum speed to
maintain circular motion. At this point, and
with this minimum speed, the gravitational
force is the only force that causes the
centripetal acceleration.
Derived equation:

continued on next page

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Force and Translational Dynamics
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LEARNING OBJECTIVE ESSENTIAL KNOWLEDGE
2.9.A 2.9.A.2.ii

Describe the motion of an Components of the static friction force and
object traveling in a circular the normal force can contribute to the net
path. force producing centripetal acceleration of
an object traveling in a circle on a banked
surface.
2.9.A.2.iii
A component of tension contributes
to the net force producing centripetal
acceleration experienced by a conical
pendulum.

2.9.A.3
Tangential acceleration is the rate at which
an object’s speed changes and is directed
tangent to the object’s circular path.
2.9.A.4
The net acceleration of an object moving in
a circle is the vector sum of the centripetal
acceleration and tangential acceleration.
2.9.A.5
The revolution of an object traveling in a
circular path at a constant speed (uniform
circular motion) can be described using period
and frequency.
2.9.A.5.i
The time to complete one full circular path,
one full rotation, or a full cycle of oscillatory
motionisdefinedasperiod,T.
2.9.A.5.ii
The rate at which an object is completing
revolutionsisdefinedasfrequency,f.
Relevant equation:
T=1
f
2.9.A.5.iii
For an object traveling at a constant speed
in a circular path, the period is given by the
derived equation

continued on next page

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2 Force and Translational Dynamics

LEARNING OBJECTIVE ESSENTIAL KNOWLEDGE
2.9.B 2.9.B.1
Describe circular orbits using For a satellite in circular orbit around a central
Kepler’s third law. body, the satellite’s centripetal acceleration
is caused only by gravitational attraction.
The period and radius of the circular orbit are
related to the mass of the central body.
Derived equation:

BOUNDARY STATEMENT
AP Physics 1 only expects students to quantitatively analyze banked curves in which
no friction is required to maintain uniform circular motion. Analysis of situations in
which friction is required on a banked curve is limited to qualitative descriptions.

BOUNDARY STATEMENT
AP Physics 1 does not expect students to know Kepler’s first or second laws of
planetary motion.

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