An application of modeling with differential equations from physics

On question 37 in 2.5 of A First Course in Differential Equations with Modeling Applicatiosn 11th...

On question 37 in 2.5 of A First Course in Differential Equations with Modeling Applicatiosn 11th edition, how do we decide that the substitution to use is u=v^(1-n)? In general, how do we decide what to substitute when solving differential equations or using Bernoulli's equation?

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 /...

Solve an engineering technology application of a separable differential equation. Use first order linear differential equations...

Solve an engineering technology application of a separable differential equation. Use first order linear differential equations for solving engineering technology problems. In 1986, the world's worst nuclear accident occurred in Chernobyl, Ukraine. Since then, over 20,000 people have died from radioactivity of Cesium 137, which has a half-life of 30.1 years. What percent of Cesium 137 released in 1986 remain in 2016?

On question 23 of 4.1.2 problems from 11th edition of A First Course in Differential Equations...

On question 23 of 4.1.2 problems from 11th edition of A First Course in Differential Equations with modeling applications by Zill, why do we make the Wronskian only to the first derivative? Why don't we have to do it do the second derivative and get a 2 by 3 matrix since the original equation given includes 2nd derivative of y?

Application of first order differential equations. 1. A body of mass 14.7 kg is released with...

Application of first order differential equations. 1. A body of mass 14.7 kg is released with an initial speed of 0.5 m/sec and finds a force due to the air resistance given by 8v2. Find the speed for time = root of 2 seconds (t =√2 seconds) The correct answer is = 4,23m/sec. Please help me solving this step by step, because I'm studying for an important test tomorrow. Thank you so much.

6 - Illustrate (By giving an application example) the four steps of the ML modeling process

6 - Illustrate (By giving an application example) the four steps of the ML modeling process

Define ordinary differential equations and partial differential equations. How do they differ? What are the most...

Define ordinary differential equations and partial differential equations. How do they differ? What are the most important aspects of each?

Differential Equations A 12-cm pendulum is released from rest at an angle 20/pi from the vertical....

Differential Equations A 12-cm pendulum is released from rest at an angle 20/pi from the vertical. Assuming that g = 10m/s^2 find the maximum angular velocity from the vertical and the time when this maximum velocity occurs first for the pendulum.(solve using Differential Equations)

This question is for my differential equations class so please use differential equations to solve the...

This question is for my differential equations class so please use differential equations to solve the problem. A mass of 4 kg is attached to a spring hanging from a ceiling, thereby stretching the spring 9.8 cm on coming to rest at equilibrium. The mass is then lifted up 10 cm above the equilibrium point and given a downward velocity of 1 m/sec. Determine the equation of motion of the mass.

Give four general objectives of the topic 'Modeling Proximate Determinants of Income Poverty : An Application...

Give four general objectives of the topic 'Modeling Proximate Determinants of Income Poverty : An Application of Small Area Estimation'.