Electric Fields
... TSW understand and apply the concept of a force field by calculating the field, the force and motion of a particle in a field. ...
... TSW understand and apply the concept of a force field by calculating the field, the force and motion of a particle in a field. ...
Newton`s 1st Law
... Anticipatory Set:(“The Hook” -- something to excite the student about the subject matter) “An object at rest will remain at rest unless acted on by an unbalanced force. An object in motion continues in motion with the same speed and in the same direction unless acted upon by an unbalanced force.” Th ...
... Anticipatory Set:(“The Hook” -- something to excite the student about the subject matter) “An object at rest will remain at rest unless acted on by an unbalanced force. An object in motion continues in motion with the same speed and in the same direction unless acted upon by an unbalanced force.” Th ...
Dynamics Powerpoint - HRSBSTAFF Home Page
... The bus is initially at rest, as is the package. In the absence of any force, the natural state of the package is to remain at rest. When the bus pulls forward, the package remains at rest because of its inertia (until the back of the seat applies a forward force to make it move with the bus). NOT E ...
... The bus is initially at rest, as is the package. In the absence of any force, the natural state of the package is to remain at rest. When the bus pulls forward, the package remains at rest because of its inertia (until the back of the seat applies a forward force to make it move with the bus). NOT E ...
Forces and the Laws of Motion Section 2 Newton`s First Law
... – Objects create force fields that act on other objects. – Gravity, static electricity, magnetism ...
... – Objects create force fields that act on other objects. – Gravity, static electricity, magnetism ...
Rotational Motion Test Review
... 13. A comet orbiting the Sun can be considered an isolated system with no outside forces or torques acting on it. As the comet moves in its highly elliptical orbit, what remains constant? A. Its distant from the Sun B. Its angular speed C. Its linear speed D. Its angular momentum E. The gravitationa ...
... 13. A comet orbiting the Sun can be considered an isolated system with no outside forces or torques acting on it. As the comet moves in its highly elliptical orbit, what remains constant? A. Its distant from the Sun B. Its angular speed C. Its linear speed D. Its angular momentum E. The gravitationa ...
Chapter 4
... the sum of the magnitudes of all the forces acting on an object. B. the difference between two forces that are acting on an object. C. the vector sum of all the forces acting on an object. D. the force with the largest magnitude acting on an object. ...
... the sum of the magnitudes of all the forces acting on an object. B. the difference between two forces that are acting on an object. C. the vector sum of all the forces acting on an object. D. the force with the largest magnitude acting on an object. ...
Resisted Motion - ASK: Academic Skills
... In Section 34.2 we introduced methods of analysing the motion of projectiles on the assumption that air resistance or drag can be neglected. In this Section we will consider the accuracy of this assumption in some particular cases and take a look at the consequences which including air resistance ha ...
... In Section 34.2 we introduced methods of analysing the motion of projectiles on the assumption that air resistance or drag can be neglected. In this Section we will consider the accuracy of this assumption in some particular cases and take a look at the consequences which including air resistance ha ...
The Properties of Matter
... •Mass is constant for an object no matter where it is in the universe. The only way to change the mass of an object is to change the amount of matter that makes up the object. •Weight changes with distance of gravitational force from the Earth or any other large body of the universe The more mass a ...
... •Mass is constant for an object no matter where it is in the universe. The only way to change the mass of an object is to change the amount of matter that makes up the object. •Weight changes with distance of gravitational force from the Earth or any other large body of the universe The more mass a ...
Document
... 2) Compare the magnitudes of the acceleration you experience, aA, to the magnitude of the acceleration of the spacecraft, aS, while you are pushing: 1. aA = aS a=F/m correct 2. aA > aS F same lower mass give larger a 3. aA < aS Physics 101: Lecture 7, Pg 6 ...
... 2) Compare the magnitudes of the acceleration you experience, aA, to the magnitude of the acceleration of the spacecraft, aS, while you are pushing: 1. aA = aS a=F/m correct 2. aA > aS F same lower mass give larger a 3. aA < aS Physics 101: Lecture 7, Pg 6 ...
Gravity Notes
... •One kilogram is the mass of about ___________________ modern pennies. •Everything that has mass is made up of ________________________. •The _______________ mass an object has, the __________________ its gravitational force. •Because the sun’s mass is so great, it exerts a _______________ gravitati ...
... •One kilogram is the mass of about ___________________ modern pennies. •Everything that has mass is made up of ________________________. •The _______________ mass an object has, the __________________ its gravitational force. •Because the sun’s mass is so great, it exerts a _______________ gravitati ...
Problem CP2 Chapt 4 - My Solution PDF with thumbnails 2/29/04
... Basic Solution (Minimum Expected from the student) Ch4 CP2 A rope exerts a constant horizontal force of 250 N to pull a 60-kg crate across the floor. The velocity of the crate is observed to increase from 1 m/s to 3 m/s in a time of 2 seconds under the influence of this force and the frictional forc ...
... Basic Solution (Minimum Expected from the student) Ch4 CP2 A rope exerts a constant horizontal force of 250 N to pull a 60-kg crate across the floor. The velocity of the crate is observed to increase from 1 m/s to 3 m/s in a time of 2 seconds under the influence of this force and the frictional forc ...
Find
... 1. Use Newton’s Law in component form to find the values for any individual forces and/or the acceleration. 2. If necessary, the object’s trajectory (time, velocity, position, acceleration) can be determined by using the equations of kinematics. 3. Reverse # 1 and 2 if necessary (Hint: it is!) ...
... 1. Use Newton’s Law in component form to find the values for any individual forces and/or the acceleration. 2. If necessary, the object’s trajectory (time, velocity, position, acceleration) can be determined by using the equations of kinematics. 3. Reverse # 1 and 2 if necessary (Hint: it is!) ...