Question
Determine the approximate solution to the equation 2⋅3^x=10 using a graph.
Answers
GPT-4o mini
To find an approximate solution to the equation \(2 \cdot 3^x = 10\) using a graph, we can follow these steps:
1. **Rewrite the equation**: First, isolate \(3^x\):
\[
3^x = \frac{10}{2} = 5
\]
2. **Graph the functions**: We can graph the functions on both sides of the equation. This means we will plot \(y = 3^x\) and \(y = 5\).
3. **Analyze the graphs**:
- The graph of \(y = 3^x\) is an exponential curve that rises rapidly as \(x\) increases.
- The line \(y = 5\) is a horizontal line.
4. **Find the intersection**: We are looking for the point where these two graphs intersect, as the \(x\)-coordinate of this intersection will give us the value of \(x\) that satisfies the original equation.
5. **Estimate the solution**: You can use graphing software or a graphing calculator to visualize these functions. Upon plotting, we find the intersection occurs around \(x \approx 1.464\).
### Conclusion
The approximate solution to the equation \(2 \cdot 3^x = 10\) is:
\[
x \approx 1.464
\]
This value can be checked to ensure it satisfies the original equation by substituting back into it.
1. **Rewrite the equation**: First, isolate \(3^x\):
\[
3^x = \frac{10}{2} = 5
\]
2. **Graph the functions**: We can graph the functions on both sides of the equation. This means we will plot \(y = 3^x\) and \(y = 5\).
3. **Analyze the graphs**:
- The graph of \(y = 3^x\) is an exponential curve that rises rapidly as \(x\) increases.
- The line \(y = 5\) is a horizontal line.
4. **Find the intersection**: We are looking for the point where these two graphs intersect, as the \(x\)-coordinate of this intersection will give us the value of \(x\) that satisfies the original equation.
5. **Estimate the solution**: You can use graphing software or a graphing calculator to visualize these functions. Upon plotting, we find the intersection occurs around \(x \approx 1.464\).
### Conclusion
The approximate solution to the equation \(2 \cdot 3^x = 10\) is:
\[
x \approx 1.464
\]
This value can be checked to ensure it satisfies the original equation by substituting back into it.