A. Speed
... amount of force applied. 1. Force=Mass*Acceleration (F=ma, a=F/m, m=F/a) 2. The harder you push something, the more it accelerates. 3. The more mass something has, the harder it is to accelerate. 4. These relationships are proportional. 2x Force means 2x acceleration. 2x mass means ½x acceleration. ...
... amount of force applied. 1. Force=Mass*Acceleration (F=ma, a=F/m, m=F/a) 2. The harder you push something, the more it accelerates. 3. The more mass something has, the harder it is to accelerate. 4. These relationships are proportional. 2x Force means 2x acceleration. 2x mass means ½x acceleration. ...
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). From ...
... 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). From ...
Projectile Motion
... Relationship Between Variables of Uniform Circular Motion Suppose two identical objects go around in horizontal circles of identical diameter but one object goes around the circle twice as fast as the other. The force required to keep the faster object on the circular path is The answer is E. As th ...
... Relationship Between Variables of Uniform Circular Motion Suppose two identical objects go around in horizontal circles of identical diameter but one object goes around the circle twice as fast as the other. The force required to keep the faster object on the circular path is The answer is E. As th ...
Moments of INERTIA
... • Step 3: Find accelerations and Moments of inertia – Since it is not just the object’s mass, but shape determines how an object resists a net torque we will normally have to calculate the object’s moment of inertia. – We normal will have to find the angular acceleration in the system, sometimes we ...
... • Step 3: Find accelerations and Moments of inertia – Since it is not just the object’s mass, but shape determines how an object resists a net torque we will normally have to calculate the object’s moment of inertia. – We normal will have to find the angular acceleration in the system, sometimes we ...
4. DYNAMICS: NEWTON`S LAWS OF MOTION. Key words
... The real weight Wr of an object is the gravitational force that acts on it Wr = mg. The apparent weight of the object Wa is the force object exerts on whatever it rests on. Think about apparent weight as the reading on a scale an object is placed on (see Fig. 4-1 on which the object is shown situat ...
... The real weight Wr of an object is the gravitational force that acts on it Wr = mg. The apparent weight of the object Wa is the force object exerts on whatever it rests on. Think about apparent weight as the reading on a scale an object is placed on (see Fig. 4-1 on which the object is shown situat ...
Acceleration,
... • I have a paper clip tied to one end of a long string, and three paperclips attached to the other end. • I will hold the single paper clip in the middle of my lab desk and let the other end hang over the edge. • What happens as I let go of the paper clip? • What happens after I add a fourth paper c ...
... • I have a paper clip tied to one end of a long string, and three paperclips attached to the other end. • I will hold the single paper clip in the middle of my lab desk and let the other end hang over the edge. • What happens as I let go of the paper clip? • What happens after I add a fourth paper c ...
Slide 1 - Soran University
... 6.5 Potential energy of a system Week15 We introduced the concept of kinetic energy associated with motion of objects. Now we introduce potential energy, the energy associated with the configuration of a system of objects that exert forces on each other. Potential energy Consider a system consists ...
... 6.5 Potential energy of a system Week15 We introduced the concept of kinetic energy associated with motion of objects. Now we introduce potential energy, the energy associated with the configuration of a system of objects that exert forces on each other. Potential energy Consider a system consists ...
Newton's theorem of revolving orbits
In classical mechanics, Newton's theorem of revolving orbits identifies the type of central force needed to multiply the angular speed of a particle by a factor k without affecting its radial motion (Figures 1 and 2). Newton applied his theorem to understanding the overall rotation of orbits (apsidal precession, Figure 3) that is observed for the Moon and planets. The term ""radial motion"" signifies the motion towards or away from the center of force, whereas the angular motion is perpendicular to the radial motion.Isaac Newton derived this theorem in Propositions 43–45 of Book I of his Philosophiæ Naturalis Principia Mathematica, first published in 1687. In Proposition 43, he showed that the added force must be a central force, one whose magnitude depends only upon the distance r between the particle and a point fixed in space (the center). In Proposition 44, he derived a formula for the force, showing that it was an inverse-cube force, one that varies as the inverse cube of r. In Proposition 45 Newton extended his theorem to arbitrary central forces by assuming that the particle moved in nearly circular orbit.As noted by astrophysicist Subrahmanyan Chandrasekhar in his 1995 commentary on Newton's Principia, this theorem remained largely unknown and undeveloped for over three centuries. Since 1997, the theorem has been studied by Donald Lynden-Bell and collaborators. Its first exact extension came in 2000 with the work of Mahomed and Vawda.