Question:
Let the population of rabbits surviving at a time $t$ be governed by the differential equation
$\frac {dp(t)}{dt}=\frac {1}{2} p(t)-200.$
If $p(0)=100,$ then $p(t)$ is equal to
Let the population of rabbits surviving at a time $t$ be governed by the differential equation
$\frac {dp(t)}{dt}=\frac {1}{2} p(t)-200.$
If $p(0)=100,$ then $p(t)$ is equal to
Updated On: Feb 14, 2025
- $400-300\,e^{t/2}$
- $300-200\,e^{-t/2}$
- $600-500\,e^t/2$
- $400-300\,e^t/2$
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The Correct Option is A
Solution and Explanation
$\frac{d p(t)}{d t}=\frac{1}{2} p(t)-200$
$\int \frac{d(p(t))}{\left(\frac{1}{2} p(t)-200\right)}=\int dt$
$2 \,\log \left(\frac{p(t)}{2}-200\right)=t+c$
$\frac{p(t)}{2}-200=e^{\frac{t}{2}} k$
Using given condition $p(t)=400-300 \,e^{t / 2}$
$\int \frac{d(p(t))}{\left(\frac{1}{2} p(t)-200\right)}=\int dt$
$2 \,\log \left(\frac{p(t)}{2}-200\right)=t+c$
$\frac{p(t)}{2}-200=e^{\frac{t}{2}} k$
Using given condition $p(t)=400-300 \,e^{t / 2}$
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Concepts Used:
Differential Equations
A differential equation is an equation that contains one or more functions with its derivatives. The derivatives of the function define the rate of change of a function at a point. It is mainly used in fields such as physics, engineering, biology and so on.
Orders of a Differential Equation
First Order Differential Equation
The first-order differential equation has a degree equal to 1. All the linear equations in the form of derivatives are in the first order. It has only the first derivative such as dy/dx, where x and y are the two variables and is represented as: dy/dx = f(x, y) = y’
Second-Order Differential Equation
The equation which includes second-order derivative is the second-order differential equation. It is represented as; d/dx(dy/dx) = d2y/dx2 = f”(x) = y”.
Types of Differential Equations
Differential equations can be divided into several types namely
- Ordinary Differential Equations
- Partial Differential Equations
- Linear Differential Equations
- Nonlinear differential equations
- Homogeneous Differential Equations
- Nonhomogeneous Differential Equations