The acceleration of a falling body near the earth’s surface is 9.8 meters per second per...

(1) Starting with the simple model of constant acceleration for a falling body is 9.8 m/sec,...

(1) Starting with the simple model of constant acceleration for a falling body is 9.8 m/sec, use calculus to derive functions for the velocity and distance fallen at any time t (in seconds). (2) Then show two ways in which such a model cannot accurately account for “terminal velocity”, e.g., free fall and final descent rate experienced by a parachutist.

We learned in mechanics that in the absence of air resistance, all objects near Earth’s surface...

We learned in mechanics that in the absence of air resistance, all objects near Earth’s surface fall with the same constant acceleration g = 9.8 m/s 2 . Yet as a student I once dropped a wadded-up tissue from the top of the Eiffel Tower and watched it take minutes to fall 300 m to Earth. (I retrieved it from the riverbank and put it in the poubelle.) In fluids, such as air or water, frictional drag forces grow larger...

Consider the motion of a object able to move along a line under constant acceleration a....

Consider the motion of a object able to move along a line under constant acceleration a. At time t = 0, its initial position and velocity are x0 and v0 respectively. Show that at a later time t, v = v0 + at, x = x0 + v0t + 12at2. Eliminate the time between these two relations to show that a(x − x0) = 12(v2 − v20). Use this to find the minimum stopping distance for a car travelling at...

A particle is launched horizontally, close to the Earth’s surface, with initial speed v(0) = v0...

A particle is launched horizontally, close to the Earth’s surface, with initial speed v(0) = v0 . Find both the normal and the tangential components of acceleration at an instant t > 0. Neglect air drag. Use a geometric argument to relate these components to the Cartesian components of velocity.

a(t) = 2e^ −t + 4 cos(2t) − sin(2t). Find the initial acceleration at t =...

a(t) = 2e^ −t + 4 cos(2t) − sin(2t). Find the initial acceleration at t = 0. If time is measured in seconds and distance is measured in meters, what units is your answer in? Find the velocity v(t) of the object given an initial velocity of 2 meters per second. Find the position s(t) of the object given an initial position of 0 meters.

2. Spencer throws a basketball out of a helicopter hoping to make a basket on the...

2. Spencer throws a basketball out of a helicopter hoping to make a basket on the ground below. He throws it with a downward velocity of 5 meters per second from a height of 100 meters. Note that the acceleration of gravity is a constant 9.8 meters per second squared (downward). (a) Write the above information as an initial value problem for the height (position) s(t) in meters of the ball t seconds after Spencer throws it. (b) Solve the...

A damped harmonic oscillator of mass m has a natural frequency ω0, and it is tuned...

A damped harmonic oscillator of mass m has a natural frequency ω0, and it is tuned so that β = ω0. a) At t = 0, its position is x0 and its velocity is v0. Find x(t) for t > 0 b)If x0 = 0.2 m and ω0 = 3 s−1 , obtain a condition on v0 necessary for the oscillator to pass through the equilibrium position (x(t) = 0) at a finite time t.

Near the surface of the Earth, the magnitude of the acceleration due to gravity is 32...

Near the surface of the Earth, the magnitude of the acceleration due to gravity is 32 ft/s^2. A projectile is shot vertically upward from ground level with an initial velocity of 96 ft/s. A. What is the velocity at t=1 s? B. What is the maximum height attained by the projectile? C. How long is the projectile in the air? D. What is the impact velocity?

An object is undergoing simple harmonic motion along the x-axis. its position is described as a...

An object is undergoing simple harmonic motion along the x-axis. its position is described as a function of time by x(t)= 5.3cos(4.2t-1.9), where x is in meters, the time t, is in seconds, and the argument of the cosine is in radians. c) determine the position of the object, in meters, at the time t=2.6s? d) what the objects velocity, in meters per second, at the time t=2.6s? e) calculate the objects acceleration, in meters per second squared, at time...

A mass of 100 g stretches a spring 5 cm. If the mass is set in...

A mass of 100 g stretches a spring 5 cm. If the mass is set in motion from its equilibrium position with a downward velocity of 10 cm/s, and if there is no damping, determine the position u of the mass at any time t. (Use g = 9.8 m/s2  for the acceleration due to gravity. Let u(t), measured positive downward, denote the displacement in meters of the mass from its equilibrium position at time t seconds.) u(t) = When does...