To apply Newton’s method for the function f(x) = x² – 10, we need to follow a systematic approach. Newton’s method uses the formula:
xn+1 = xn – (f(xn) / f'(xn))
First, let’s determine the necessary components:
- The function is f(x) = x² – 10.
- The derivative of the function is f'(x) = 2x.
Next, we need an initial approximation. Let’s use x0 = 3.162, which is a rough estimate of the square root of 10.
Now, we will compute the iterations:
- Iteration 1:
- x1 = 3.162 – ((3.162² – 10) / (2 * 3.162))
- x1 = 3.162 – ((10.000244 – 10) / 6.324) = 3.162 – (0.000244 / 6.324) ≈ 3.162 – 0.0000386 ≈ 3.162
- Iteration 2:
- x2 = 3.162 – ((3.162² – 10) / (2 * 3.162))
- x2 ≈ 3.162
- Iteration 3:
- x3 ≈ 3.162
- Iteration 4:
- x4 ≈ 3.162
- Iteration 5:
- x5 ≈ 3.162
- Iteration 6:
- x6 ≈ 3.162
- Iteration 7:
- x7 ≈ 3.162
- Iteration 8:
- x8 ≈ 3.162
- Iteration 9:
- x9 ≈ 3.162
- Iteration 10:
- x10 ≈ 3.162
As you can see, with our initial approximation of 3.162, the value stabilizes to approximately 3.162 after just a couple of iterations, quickly converging to the square root of 10. This demonstrates the efficiency of Newton’s method in finding roots of functions.