Find the potential distribution between two surfaces if V(x = 0) = 0 and V(x = 1) = 3. There is no charge distribution in the space 0 ≤ x ≤ 1.

Question

Find the potential distribution between two surfaces if V(x = 0) = 0 and V(x = 1) = 3. There is no charge distribution in the space 0 ≤ x ≤ 1 .

Accepted Answer

Let us use only three points for the first iteration: [latex]x_{0} = 0, x_{1} = 0.5[/latex], and [latex]x_{2} = 1[/latex]. Using the central difference method with a step size h = 0.5, we write Laplace's equation as

[latex]\frac{d^{2} V}{dx^{2}} |_{x_{1}} = \frac{V_{2} - 2 V_{1} + V_{0}}{0.5^{2}} = 0[/latex]

The boundary conditions imply [latex]V_{0} = V(x_{0} = 0) = 0[/latex] and [latex]V_{2} = V(x_{2} = 1) = 3[/latex]. Hence

[latex] V_{1} = 0.5 (V_{0} + V_{2}) = 1.5 [/latex]

which demonstrates the principle of the average value for the middle point [latex]x_{1}[/latex]. The second iteration with the smaller steps size h = 0.25 is applied to fi ve points in the same interval. The boundary conditions, which are now [latex]V_{0} = 0[/latex] and [latex]V_{4} = 3[/latex], lead to three simultaneous equations

[latex] V_{1} = 0.5 (V_{0} + V_{2});[/latex] [latex] V_{2} = 0.5 (V_{1} + V_{3});[/latex] [latex] V_{3} = 0.5 (V_{2} + V_{4});[/latex]

In this case, the boundary conditions specify [latex]V_{0}[/latex] and [latex]V_{4}[/latex], and the voltage [latex]V_{2}[/latex] was calculated in the previous iteration. The solutions for the three intermediate points and the two end points are

[latex]V_{0} = 0;[/latex] [latex] V_{1} = 0.75 [/latex]; [latex]V_{2} = 1.50[/latex]; [latex] V_{3} = 2.25 [/latex]; [latex] V_{4} = 3[/latex]

A comparison of these computed values is in agreement with the analytical solution V(x) = 3x obtained in Example 4-6. The MATLAB calculation produces the following results:

V=	NaN	1.5000	NaN	3.0000
V=	0.7500	1.5000	NaN	3.0000
V=	0.7500	1.5000	2.2500	3.0000

The voltage distribution is shown below.

Question 4.9: Find the potential distribution between two surfaces if V(x ...

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