A body falls from rest against a resistance that is proportional to the speed at any...

Solve the following exercise by applying differential equations: A person weighing 67 kg falls from a...

Solve the following exercise by applying differential equations: A person weighing 67 kg falls from a building measuring 40m with an initial speed of 3m / sec. Let's suppose: The air resistance is proportional to the speed of the body. The limit speed at which it can fall is 40 m / sec. Find: a) the expression of the velocity of the object in a time t, b) the expression for the position of the body at a time t...

An iron robot falls from rest at a great height. Neglecting air resistance, what is its...

An iron robot falls from rest at a great height. Neglecting air resistance, what is its speed after it has fallen for 3.5 seconds? Use 9.8m/s/s for g. 9.8 m/s 9.8 m/s2 13.3 m/s 34.3 m/s

A ball is dropped from rest and falls 20 s. What are its position and velocity...

A ball is dropped from rest and falls 20 s. What are its position and velocity at that instant? (Ignore the effects of air resistance.)

A rock with mass m = 2.60 kg falls from rest in a viscous medium. The...

A rock with mass m = 2.60 kg falls from rest in a viscous medium. The rock is acted on by a net constant downward force of F = 19.8 N (a combination of gravity and the buoyant force exerted by the medium) and by a fluid resistance force f=kv, where v is the speed in m/s and k = 2.69 N×s/m a)Find the initial acceleration a0. b) Find the acceleration when the speed is 3.50 m/s . c)Find the...

Consider an object with mass m dropped from rest. Assume that air resistance is proportional to...

Consider an object with mass m dropped from rest. Assume that air resistance is proportional to the square of the velocity of the object, with positive proportionality constant k. Let v(t) be the velocity after t seconds, and let g be the acceleration of the object due to gravity. The corresponding initial value problem is mdv =mg−kv2; v(0)=0. dt (a) Solve the initial value problem. Your answer will be in terms of m, k, and g. (b) Compute lim v(t)....

Application of the first order differential equations, from "Differential Equations", by Isabel Carmona. 2. A body...

Application of the first order differential equations, from "Differential Equations", by Isabel Carmona. 2. A body with a mass of 9.7 kg is released from a height of 300 m without initial speed. The body finds an air resistance proportional to its speed. If the speed limit must be 95 m/sec... Find A) body speed at a time t B) the position of the body at a time t The correct answers are: A) v = 95 (1-e(- t /...

1. A raindrop of mass m falls while receiving resistance. Gravitational acceleration is g and it...

1. A raindrop of mass m falls while receiving resistance. Gravitational acceleration is g and it falls to the ground at the final velocity. (1) Find the final velocity of raindrops when the resistance is air resistance that is proportional to the square of the velocity. Let b be the constant of proportionality. (2) Find the final velocity of raindrops when the resistance is a viscous resistance proportional to velocity. Let β be the constant of proportionality.

A sack of potatoes weighing 13.1-kg falls from a very tall building. At a certain point...

A sack of potatoes weighing 13.1-kg falls from a very tall building. At a certain point at the motion downwards, its measured acceleration is 3.7 m/s2 and its velocity is 70.4 m/s. Assuming that the magnitude of the drag force due to air resistance is proportional to the square of its speed, What is its terminal speed? Select one: a. 89.20 m/s b. 70.40 m/s c. 10.63 m/s d. The sack keeps accelerating until it reaches the bottom

with a complete solution A body of mass 2 gr attached to a vertical spring stretches...

with a complete solution A body of mass 2 gr attached to a vertical spring stretches it 1000/4 cm to reach an equilibrium position. When the body moves in the air it experiences a resistance opposite to its movement, proportional to its speed, with a damping constant d = 10 gr/sec. Approximate the acceleration of gravity by g = 1000 c m / s e c 2 . b. Find a differential equation of the form y ′′ = F...

An object of mass 120 kg is released from rest 480000 m above the ground and...

An object of mass 120 kg is released from rest 480000 m above the ground and allowed to fall under the influence of gravity. Assume the gravitational force is constant, with g=9.8 m/sec2 , and the force due to air resistance is proportional to the velocity of the object with proportionality constant k= 3 kg/sec. Approximate the speed (in m/sec) of the object when it strikes the ground.