doc - Seth Baum
... a. What is 1/si + 1/so = 1/f 18) The speed of light in glass compared to the speed of light in air a. What is slower 19) 270 degrees expressed in radians a. What is 3 pi / 2 20) The equation for magnification given image and object heights a. What is M = hi / ho 21) The energy of a photon a. What i ...
... a. What is 1/si + 1/so = 1/f 18) The speed of light in glass compared to the speed of light in air a. What is slower 19) 270 degrees expressed in radians a. What is 3 pi / 2 20) The equation for magnification given image and object heights a. What is M = hi / ho 21) The energy of a photon a. What i ...
Document
... frame of reference, then and only then, there will actually be a term called “centrifugal force”. ...
... frame of reference, then and only then, there will actually be a term called “centrifugal force”. ...
South Pasadena - cloudfront.net
... 3:00 O’clock with initial velocity, v0. Its final velocity at 1:00 O’clock is V The direction of the Acceleration can be found by finding the direction of the change in velocity V (Remember that acceleration = V/t or (V –V0)/t If we focus on just the v, we have (V –V0) This is the same as V + ( ...
... 3:00 O’clock with initial velocity, v0. Its final velocity at 1:00 O’clock is V The direction of the Acceleration can be found by finding the direction of the change in velocity V (Remember that acceleration = V/t or (V –V0)/t If we focus on just the v, we have (V –V0) This is the same as V + ( ...
Review
... Sample Problem An object acted on by three forces moves with constant velocity. One force acting on the object is in the positive x direction and has a magnitude of 6.5 N; a second force has a magnitude of 4.4 N and points in the negative y direction. Find the direction and magnitude of the third f ...
... Sample Problem An object acted on by three forces moves with constant velocity. One force acting on the object is in the positive x direction and has a magnitude of 6.5 N; a second force has a magnitude of 4.4 N and points in the negative y direction. Find the direction and magnitude of the third f ...
Section 6.2 Word
... Centripetal Acceleration – the Center Seeking acceleration of an object moving in a circle at constant speed. It always points toward the center of the circle. Its magnitude is equal to the square of the speed divided by the radius of motion. ac = v2 / r Period – the time needed for an object to mak ...
... Centripetal Acceleration – the Center Seeking acceleration of an object moving in a circle at constant speed. It always points toward the center of the circle. Its magnitude is equal to the square of the speed divided by the radius of motion. ac = v2 / r Period – the time needed for an object to mak ...
Forces and the Laws of Motion
... Whenever an object moves through a fluid substance, such as air or water, the fluid provides a force that opposes the objects motion Air resistance will increase on an object in free fall as the objects speed increases When ...
... Whenever an object moves through a fluid substance, such as air or water, the fluid provides a force that opposes the objects motion Air resistance will increase on an object in free fall as the objects speed increases When ...
PHYS 307 LECTURE NOTES, Daniel W. Koon, St. Lawrence Univ.
... latitude and hurtling through space around the Sun, which is moving at 43000 mph relative to our galaxy, which is speeding at 600,000 mph relative to nearby galaxies. Now, because the rotation of the earth about its axis and its revolution around the sun are circular motions, the Earth is not strict ...
... latitude and hurtling through space around the Sun, which is moving at 43000 mph relative to our galaxy, which is speeding at 600,000 mph relative to nearby galaxies. Now, because the rotation of the earth about its axis and its revolution around the sun are circular motions, the Earth is not strict ...
An intro to forces
... 2. GRAVITATIONAL force is the force of attraction between two different masses. The larger the mass, the more gravitational force is present. LAW OF UNIVERSAL GRAVITATION: Every object in the universe attracts every other object in the universe with a force that is directly related to the product of ...
... 2. GRAVITATIONAL force is the force of attraction between two different masses. The larger the mass, the more gravitational force is present. LAW OF UNIVERSAL GRAVITATION: Every object in the universe attracts every other object in the universe with a force that is directly related to the product of ...
Physics 51 "Study Guide" for Final Exam ("Laundry List" of important
... Newton's law of gravitation: two bodies, masses m1, m2, distance r apart, attract Fg = G m1 m2 / r2 G, the universal gravitation constant is the same for any two masses G = 6.67 x 10-11 N • m2 / kg2 Weight is the gravitational force on an object of mass m. (eg: @earth's surface) w = Fg = G ME m / RE ...
... Newton's law of gravitation: two bodies, masses m1, m2, distance r apart, attract Fg = G m1 m2 / r2 G, the universal gravitation constant is the same for any two masses G = 6.67 x 10-11 N • m2 / kg2 Weight is the gravitational force on an object of mass m. (eg: @earth's surface) w = Fg = G ME m / RE ...
URL - StealthSkater
... Let’s assume that an observer on Earth watched the disc or spacecraft take off from the Earth’s surface, ascend into space, and enter its gravity field propulsion system generated “black tunnel”. The observer would see the spacecraft come to a virtual stop just short of the location where the spacec ...
... Let’s assume that an observer on Earth watched the disc or spacecraft take off from the Earth’s surface, ascend into space, and enter its gravity field propulsion system generated “black tunnel”. The observer would see the spacecraft come to a virtual stop just short of the location where the spacec ...
Microsoft Word - Phy.. - hrsbstaff.ednet.ns.ca
... The acceleration of both rocks is found by dividing their weight (the force of gravity on them) by their mass. The 2-kg rock has a force of gravity on it that is twice as great as the force of gravity on the 1-kg rock, but also twice as great a mass as the 1-kg rock, so the acceleration is the same ...
... The acceleration of both rocks is found by dividing their weight (the force of gravity on them) by their mass. The 2-kg rock has a force of gravity on it that is twice as great as the force of gravity on the 1-kg rock, but also twice as great a mass as the 1-kg rock, so the acceleration is the same ...