(a) Explanation Given: The velocity v ( t ) of the rocket is given by d v d t + k − λ m 0 − λ t v = − g + R m 0 − λ t . Here, k is the air resistance constant of proportionality, λ is the constant rate at which fuel is consumed, R is the thrust of the rocket, m ( t ) = m 0 − λ t , m 0 is the total mass of the rocket at t = 0 , and g is the acceleration due to gravity. The mass of the rocket is m 0 = 200 kg . The thrust of the rocket is R = 2000 N . The constant at which fuel is consumed is λ = 1 kg / s . The acceleration due to gravity is g = 9.8 m / s 2 . The air resistance constant of proportionality is k = 3 kg / s . The initial velocity is v ( 0 ) = 0 . Calculation: Substitute 200 for m 0 , 2000 for R , 1 for λ , 9.8 for g , 3 for k in the formula for v ( t ) . d v d t + 3 − 1 200 − 1 ⋅ t v = − 9.8 + 2000 200 − 1 ⋅ t d v d t + 2 200 − t v = − 9.8 + 2000 200 − t d v d t + 2 200 − t ( v − 1000 ) = − 9.8 The differential equation is of the form d v d t + p ( t ) ( v − c ) = g ( t ) . The integrating factor F is obtained as follows (b) To determine The height s ( t ) of the rocket at time t .

Differential Equations with Boundary-Value Problems (MindTap Course List)

9th Edition

ISBN: 9781305965799

Author: Dennis G. Zill

Publisher: Cengage Learning

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Differential Equations

Have you ever observed the movement of the satellites and rockets or how the planets go around the sun in their orbits? How will you determine their motion? Definitely they follow some scientific laws and these kinds of problems are framed as differentia…

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Chapter 3.1, Problem 39E

(a)

To determine

The velocity v(t).

(b)

To determine

The height s(t) of the rocket at time t.

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Chapter 3.1, Problem 38E

Chapter 3.1, Problem 40E

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Differential Equations with Boundary-Value Problems (MindTap Course List)

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The velocity v ( t ) .

Solution Summary: The author calculates the velocity of the rocket, v(t), and the air resistance constant of proportionality.