Chapter 2
... Newton’s First Law of Motion: A body continues in a state of rest or uniform motion in a straight line unless made to change that state by forces acting on it ...
... Newton’s First Law of Motion: A body continues in a state of rest or uniform motion in a straight line unless made to change that state by forces acting on it ...
Chapters 4&5
... that forces - pushes and pulls - caused motion • The Aristotelian view prevailed for some 2000 years • Galileo first discovered the correct relation between force and motion • Force causes not motion itself but change in motion ...
... that forces - pushes and pulls - caused motion • The Aristotelian view prevailed for some 2000 years • Galileo first discovered the correct relation between force and motion • Force causes not motion itself but change in motion ...
Abby AII1 C083 Ye, Zi Topic: Energy in Simple harmonic motion
... Simple harmonic motion (SHM) is the motion of a simple harmonic oscillator, a motion that is neither driven nor damped. The motion is periodic - as it repeats itself at standard intervals in a specific manner - and sinusoidal, with constant amplitude; the acceleration of a body executing SHM is dire ...
... Simple harmonic motion (SHM) is the motion of a simple harmonic oscillator, a motion that is neither driven nor damped. The motion is periodic - as it repeats itself at standard intervals in a specific manner - and sinusoidal, with constant amplitude; the acceleration of a body executing SHM is dire ...
sample lab report
... the pulley, keeps moving along the track at a constant speed. (This balances out the friction force.) Then hook the string to the cart. 3. Activate the “smart pulley” program in Logger Pro. Adjust the photogate so the spokes in the pulley cut through the photogate beam. Part 1: Varying total mass wi ...
... the pulley, keeps moving along the track at a constant speed. (This balances out the friction force.) Then hook the string to the cart. 3. Activate the “smart pulley” program in Logger Pro. Adjust the photogate so the spokes in the pulley cut through the photogate beam. Part 1: Varying total mass wi ...
mi05
... resistance, lumpy, constant, atoms, normal, experimentally, lubricants, static, reforming, kinetic, maximum, coefficients, feet Friction When you’re driving a car at _______ speed all the petrol or gas you’re burning is being used just to overcome frictional forces, such as air _______ and friction ...
... resistance, lumpy, constant, atoms, normal, experimentally, lubricants, static, reforming, kinetic, maximum, coefficients, feet Friction When you’re driving a car at _______ speed all the petrol or gas you’re burning is being used just to overcome frictional forces, such as air _______ and friction ...
Problems on uniform circular motion
... plane is parallel to the ground. If the string can withstand a maximum tension of 4.5 N before breaking. At what speed is the rock traveling just as the string breaks? ...
... plane is parallel to the ground. If the string can withstand a maximum tension of 4.5 N before breaking. At what speed is the rock traveling just as the string breaks? ...
Stacey Carpenter - University of Hawaii System
... Later, the proportionality was made into an equation a = F/m, or F = ma and force was defined as more than a push or pull. The units for force are taken from ma, kgm/s2, which are called Newtons, in honor of Isaac Newton. For example, a net force of 1 N acting on a 1 kg object causes it to accele ...
... Later, the proportionality was made into an equation a = F/m, or F = ma and force was defined as more than a push or pull. The units for force are taken from ma, kgm/s2, which are called Newtons, in honor of Isaac Newton. For example, a net force of 1 N acting on a 1 kg object causes it to accele ...
Test 2 Review Test 2 Review_9
... (A) There is no force to the right and the frictional force is zero or nearly zero. (B) The force to the right is larger than the frictional force. (C) The force of motion is proportional to the speed of the puck. (D) The force to the right must be equal to the force from friction. (26) ___________ ...
... (A) There is no force to the right and the frictional force is zero or nearly zero. (B) The force to the right is larger than the frictional force. (C) The force of motion is proportional to the speed of the puck. (D) The force to the right must be equal to the force from friction. (26) ___________ ...
Unit 3 PowerPoint
... 2. Only forces parallel to the acceleration of the individual object affect the motion 3. Forces perpendicular to motion do not affect it 4. Internal forces do not affect motion (only ...
... 2. Only forces parallel to the acceleration of the individual object affect the motion 3. Forces perpendicular to motion do not affect it 4. Internal forces do not affect motion (only ...
lecture-no-4-Quiz-law-of-newton
... on block of mass 3 kg. Find the resultant force and acceleration of the block ? 2. A girl of 50kg mass is running with speed 7m/s on a rough horizontal floor skids a distance 4 m till stopped . Find the force of friction 3. An box of mass m=10Kg is pulled by a force F on a smooth horizontal floor. I ...
... on block of mass 3 kg. Find the resultant force and acceleration of the block ? 2. A girl of 50kg mass is running with speed 7m/s on a rough horizontal floor skids a distance 4 m till stopped . Find the force of friction 3. An box of mass m=10Kg is pulled by a force F on a smooth horizontal floor. I ...
Tri 3 Study Guide 2014
... Ch. 10 Section 3: Newton’s First & Second Laws (pp.389-392) Newton’s First Law of Motion: Newton’s first law states… ___________________________________________________________ o Examples: ___________________________________________________________________ o Newton’s first law is also called the ...
... Ch. 10 Section 3: Newton’s First & Second Laws (pp.389-392) Newton’s First Law of Motion: Newton’s first law states… ___________________________________________________________ o Examples: ___________________________________________________________________ o Newton’s first law is also called the ...
File
... (Linear) Velocity – rate at which displacement is covered eq’n: v = Δx/Δt units: m/s Tangential Velocity – rate at which distance is covered as something moves in a circular path – so the distance would amount to some multiple of the circumference of a circle eq’n: v = 2∏r/T, tangent to circle units ...
... (Linear) Velocity – rate at which displacement is covered eq’n: v = Δx/Δt units: m/s Tangential Velocity – rate at which distance is covered as something moves in a circular path – so the distance would amount to some multiple of the circumference of a circle eq’n: v = 2∏r/T, tangent to circle units ...
