Mid Term Test 2012 Answers File
... b) A flywheel with a moment of inertia I = 5 kg m2 is mounted on a light axle. It is initially stationary. A torque of 100 N m is applied to the axle for 100 s. (i) Calculate the final angular velocity of the flywheel. v = u + at = u + F/m t, so f = I + t = 0 + /I t = 2000 rads–1. (ii) Calculate ...
... b) A flywheel with a moment of inertia I = 5 kg m2 is mounted on a light axle. It is initially stationary. A torque of 100 N m is applied to the axle for 100 s. (i) Calculate the final angular velocity of the flywheel. v = u + at = u + F/m t, so f = I + t = 0 + /I t = 2000 rads–1. (ii) Calculate ...
Newton`s Three Laws of Motion
... Newton’s Second Law of Motion • Newton’s second law relates the applied force on an object, the mass of an object and the acceleration. • It states: F = M x A • Another form of this equation says: ...
... Newton’s Second Law of Motion • Newton’s second law relates the applied force on an object, the mass of an object and the acceleration. • It states: F = M x A • Another form of this equation says: ...
Part I
... Sect. 7.1: Systems & Environments • So far, we’ve expressed Newton’s Laws of Motion in terms of forces & we’ve considered the dynamics properties of a particle by talking about various particle properties. • Now, we take a different approach & talk about Systems & System Properties. • System: A sma ...
... Sect. 7.1: Systems & Environments • So far, we’ve expressed Newton’s Laws of Motion in terms of forces & we’ve considered the dynamics properties of a particle by talking about various particle properties. • Now, we take a different approach & talk about Systems & System Properties. • System: A sma ...
PHY820 Homework Set 5
... modes. Note: gravity plays no role in this problem. 3. [10 pts] (Goldstein) A uniform hoop of mass m and radius r rolls without slipping on a fixed cylinder of radius R as shown in the figure. The only external force is that of gravity. If the smaller cylinder starts rolling from rest on top of the ...
... modes. Note: gravity plays no role in this problem. 3. [10 pts] (Goldstein) A uniform hoop of mass m and radius r rolls without slipping on a fixed cylinder of radius R as shown in the figure. The only external force is that of gravity. If the smaller cylinder starts rolling from rest on top of the ...
PHYS 1443 – Section 501 Lecture #1
... movement some 70 years before Newton, by analyzing data. 1. All planets move in elliptical orbits with the Sun at one focal point. 2. The radius vector drawn from the Sun to a planet sweeps out equal area in equal time intervals. (Angular momentum conservation) 3. The square of the orbital period of ...
... movement some 70 years before Newton, by analyzing data. 1. All planets move in elliptical orbits with the Sun at one focal point. 2. The radius vector drawn from the Sun to a planet sweeps out equal area in equal time intervals. (Angular momentum conservation) 3. The square of the orbital period of ...
6gfield_1.
... 1. It is observed that the projectile motion of the object is actually a part of an __________________ motion. 2. For v1 to v7, observe the change in speed throughout the motion. The speed is (increasing / decreasing ) _____________________ while it is moving near to the earth’s center. This can be ...
... 1. It is observed that the projectile motion of the object is actually a part of an __________________ motion. 2. For v1 to v7, observe the change in speed throughout the motion. The speed is (increasing / decreasing ) _____________________ while it is moving near to the earth’s center. This can be ...
11.1 Laws of Motion
... SUMMARY OF FIRST LAW • MATTER RESISTS ANY CHANGE IN MOTION. • SMALL FORCE REQUIRED TO MOVE SMALL OBJECT, LARGER FORCE FOR LARGER OBJECT • SMALL MASS OBJECT IN MOTION WILL HAVE LESS INERTIA THAN LARGE MASS OBJECT IN MOTION. ...
... SUMMARY OF FIRST LAW • MATTER RESISTS ANY CHANGE IN MOTION. • SMALL FORCE REQUIRED TO MOVE SMALL OBJECT, LARGER FORCE FOR LARGER OBJECT • SMALL MASS OBJECT IN MOTION WILL HAVE LESS INERTIA THAN LARGE MASS OBJECT IN MOTION. ...
Section 8-2 Center of Mass
... Unit 6 Notes: Part 1 – Corresponds to Chapter 7 text - Chapter 7 Rotational Motion / Gravitation 1. Rotational Motion – motion of a body that spins about an axis a. Axis of rotation – line about which rotation occurs i. Perpendicular to motion ii. Through center of motion b. Linear equations will no ...
... Unit 6 Notes: Part 1 – Corresponds to Chapter 7 text - Chapter 7 Rotational Motion / Gravitation 1. Rotational Motion – motion of a body that spins about an axis a. Axis of rotation – line about which rotation occurs i. Perpendicular to motion ii. Through center of motion b. Linear equations will no ...
PPT - LSU Physics & Astronomy
... 3. THE LAW OF PERIODS: The square of the period of any planet is proportional to the cube of the semi-major axis of its orbit. Consider a circular orbit with radius r (the radius of a circle is equivalent to the semimajor axis of an ellipse). Applying Newton’s second law to the orbiting planet yield ...
... 3. THE LAW OF PERIODS: The square of the period of any planet is proportional to the cube of the semi-major axis of its orbit. Consider a circular orbit with radius r (the radius of a circle is equivalent to the semimajor axis of an ellipse). Applying Newton’s second law to the orbiting planet yield ...
PES 3210 Classical Mechanics I
... Be able to find the equations of motion for a particular physical situation. Know the Newtonian method at a minimum in both Cartesian and Polar coordinates. You can use Lagrangian Mechanics, if desired. (It will not be necessary to solve the equations of motion.) Be able to draw a free-body diagram. ...
... Be able to find the equations of motion for a particular physical situation. Know the Newtonian method at a minimum in both Cartesian and Polar coordinates. You can use Lagrangian Mechanics, if desired. (It will not be necessary to solve the equations of motion.) Be able to draw a free-body diagram. ...
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.