Chapter Objectives
... 1. From position and time, calculate displacement, average velocity, and average acceleration 2. Find distance given velocity and time 3. Distinguish between velocity and speed 4. Distinguish between average speed and instantaneous speed 5. Distinguish between velocity and acceleration 6. Find the v ...
... 1. From position and time, calculate displacement, average velocity, and average acceleration 2. Find distance given velocity and time 3. Distinguish between velocity and speed 4. Distinguish between average speed and instantaneous speed 5. Distinguish between velocity and acceleration 6. Find the v ...
Section 17.1 - Gordon State College
... PHYSICAL EXAMPLES OF VECTOR FIELDS • Velocity fields describe the motions of systems of particles in the plane or space. • Gravitational fields are described by Newton’s Law of Gravitation, which states that the force of attraction exerted on a particle of mass m located at x = x, y, z by a particl ...
... PHYSICAL EXAMPLES OF VECTOR FIELDS • Velocity fields describe the motions of systems of particles in the plane or space. • Gravitational fields are described by Newton’s Law of Gravitation, which states that the force of attraction exerted on a particle of mass m located at x = x, y, z by a particl ...
Experiment 1G Uniform Circular Motion
... By substituting this for v in the equation for centripetal force, we arrive at formula (1): ...
... By substituting this for v in the equation for centripetal force, we arrive at formula (1): ...
moments and circular motion – test
... Add an arrow, from the centre of the ball, to show the direction in which the ball would move if the string broke at this instant. ...
... Add an arrow, from the centre of the ball, to show the direction in which the ball would move if the string broke at this instant. ...
Weightlessness
Weightlessness, or an absence of 'weight', is an absence of stress and strain resulting from externally applied mechanical contact-forces, typically normal forces from floors, seats, beds, scales, and the like. Counterintuitively, a uniform gravitational field does not by itself cause stress or strain, and a body in free fall in such an environment experiences no g-force acceleration and feels weightless. This is also termed ""zero-g"" where the term is more correctly understood as meaning ""zero g-force.""When bodies are acted upon by non-gravitational forces, as in a centrifuge, a rotating space station, or within a space ship with rockets firing, a sensation of weight is produced, as the contact forces from the moving structure act to overcome the body's inertia. In such cases, a sensation of weight, in the sense of a state of stress can occur, even if the gravitational field was zero. In such cases, g-forces are felt, and bodies are not weightless.When the gravitational field is non-uniform, a body in free fall suffers tidal effects and is not stress-free. Near a black hole, such tidal effects can be very strong. In the case of the Earth, the effects are minor, especially on objects of relatively small dimension (such as the human body or a spacecraft) and the overall sensation of weightlessness in these cases is preserved. This condition is known as microgravity and it prevails in orbiting spacecraft.