A 6-cm by 5-cm rectangular silver plate has being uniformly generated at each point at the rate cal q= 1.5. cm³ ..sec. Let x represent the distance along the edge of the plate of length 6 cm and y be the distance along the edge of the plate of length 5 cm. Suppose the temperature u along the edges is kept at the following temperatures: u(x, 0) = x(6x), u(x, 5) = 0, u(0, y) = y(5-y), u(6,y) = 0, 0 ≤ x ≤ 6, 0 ≤ y ≤ 5, where the origin lies at the corner of the plate with coordinates (0,0) and the edges lie along the positive x- and y-axes. The steady-state temperature u = u(x, y) satisfies Poisson's equation: q 0 < x < 6, 0 < y < 5, K Uxx (x, y) + Uyy (x, y) = cal cm deg sec where K, the thermal conductivity, is 1.04 difference method with Ax = 3 and 4y = 2.5. Approximate the temperature u(x, y) using the finite

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A 6-cm by 5-cm rectangular silver plate has being uniformly generated at each point at the rate q 1.5 · sec. Let x represent the distance along the edge of the plate of length 6 cm and y be the cal cm³ distance along the edge of the plate of length 5 cm. Suppose the temperature u along the edges is kept at the following temperatures: u(x, 0) = x(6 − x), u(0, y) = y(5 — y), 0 ≤ x ≤ 6, 0 ≤ y ≤ 5, where the origin lies at the corner of the plate with coordinates (0,0) and the edges lie along the positive x- and y-axes. The steady-state temperature u = u(x, y) satisfies Poisson's equation: q Uxx (x, y) + Uyy (x, y) 0 < x < 6, 0 < y < 5, K' u(x,5) = 0, u(6,y) = 0, cal cm.deg.sec where K, the thermal conductivity, is 1.04 difference method with Ax = 3 and 4y = 2.5. Approximate the temperature u(x, y) using the finite