Question:
The population \( P(t) \) of a certain mouse species at time \( t \) satisfies the differential equation
\[
\frac{dP(t)}{dt} = 0.5P(t) - 450. \quad \text{If} \, P(0) = 850, \, \text{then the time at which the population becomes zero is}
\]
The population \( P(t) \) of a certain mouse species at time \( t \) satisfies the differential equation
\[
\frac{dP(t)}{dt} = 0.5P(t) - 450. \quad \text{If} \, P(0) = 850, \, \text{then the time at which the population becomes zero is}
\]
Show Hint
In solving differential equations, always separate the variables and integrate carefully. The solution will give you the behavior of the population over time.
Updated On: Jan 26, 2026
- \( \frac{1}{2} \log 18 \)
- \( \log 18 \)
- \( 2 \log 18 \)
- \( \log 9 \)
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The Correct Option is C
Solution and Explanation
Step 1: Solve the differential equation.
We have the equation \( \frac{dP}{dt} = 0.5P(t) - 450 \). To solve it, we separate the variables and integrate.
Step 2: Apply the initial condition.
Using the initial condition \( P(0) = 850 \), we solve for the constant of integration. After solving, we find that the time when the population becomes zero is \( 2 \log 18 \).
Step 3: Conclusion.
The correct answer is (C) \( 2 \log 18 \).
We have the equation \( \frac{dP}{dt} = 0.5P(t) - 450 \). To solve it, we separate the variables and integrate.
Step 2: Apply the initial condition.
Using the initial condition \( P(0) = 850 \), we solve for the constant of integration. After solving, we find that the time when the population becomes zero is \( 2 \log 18 \).
Step 3: Conclusion.
The correct answer is (C) \( 2 \log 18 \).
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