def erro_maximo_uds(numberOfNodes,angularVelocity): ############################## # Setting input paramethers ############################## yNumberOfNodes = numberOfNodes xNumberOfNodes = numberOfNodes re = 0.1 #[m] ri = 0.04 #[m] L = mt.sin(0.25*mt.pi)*(re-ri)#[m] k = 15.0#[W/mºC] Ti = 250.0 #[ºC] Te = 30.0 #[ºC] omega = angularVelocity #[rad/s] rho = 800.0 #[kg/m^3] cp = 2000.0 #[J/kgK] gamma = k/cp ############################# # Mesh generation in y ############################# yNodesPositions = [] deltaY = L/(yNumberOfNodes - 1); ySum = mt.sin(0.25*mt.pi)*ri for i in range(yNumberOfNodes): yNodesPositions.append(ySum) ySum += deltaY ySurfacePositions = [] ySum = mt.cos(0.25*mt.pi)*ri + 0.5*deltaY for i in range(yNumberOfNodes - 1): ySurfacePositions.append(ySum) ySum += deltaY ############################# # Mesh generation in x ############################# xNodesPositions = [] deltaX = L/(float(xNumberOfNodes) - 1); xSum = mt.cos(0.25*mt.pi)*ri; for i in range(xNumberOfNodes): xNodesPositions.append(xSum) xSum += deltaX xSurfacePositions = [] xSum = mt.cos(0.25*mt.pi)*ri + 0.5*deltaX for i in range(xNumberOfNodes - 1): xSurfacePositions.append(xSum) xSum += deltaX ############################################################## # Generating the matrix of coefficients and independent vector ############################################################## A = [] b = [] numberOfNodes = xNumberOfNodes * yNumberOfNodes for i in range(numberOfNodes): A.append([]) for j in range(numberOfNodes): A[i].append(0.0) b.append(0.0) #bottom for j in range(xNumberOfNodes): ap = 1.0 A[j][j] = ap b[j] = aux.analyticSolution(xNodesPositions[j],yNodesPositions[0]) #center for i in range(1,yNumberOfNodes-1): for j in range(xNumberOfNodes): if j == 0 or j == (xNumberOfNodes - 1): ap = 1.0 A[i*xNumberOfNodes+j][i*xNumberOfNodes+j] = ap b[i*xNumberOfNodes+j] = aux.analyticSolution(xNodesPositions[j],yNodesPositions[i]) else: uw = aux.uVelocity(omega,xSurfacePositions[j-1],yNodesPositions[i]) ue = aux.uVelocity(omega,xSurfacePositions[j],yNodesPositions[i]) vs = aux.vVelocity(omega,xNodesPositions[j],ySurfacePositions[i-1]) vn = aux.vVelocity(omega,xNodesPositions[j],ySurfacePositions[i]) Mw = rho*uw*deltaY Me = rho*ue*deltaY Ms = rho*vs*deltaX Mn = rho*vn*deltaX De = gamma*deltaY/deltaX Dw = De Dn = gamma*deltaY/deltaX Ds = Dn aEast = De - Me aWest = Dw aSouth = Ds + Ms aNorth = Dn ap = aEast + aWest + aSouth + aNorth A[i*xNumberOfNodes+j][j+xNumberOfNodes*(i-1)] = -aSouth A[i*xNumberOfNodes+j][i*xNumberOfNodes+j-1] = -aWest A[i*xNumberOfNodes+j][i*xNumberOfNodes+j] = ap A[i*xNumberOfNodes+j][i*xNumberOfNodes+j+1] = -aEast A[i*xNumberOfNodes+j][j+xNumberOfNodes*(i+1)] = -aNorth #top for j in range(xNumberOfNodes): ap = 1.0 A[(yNumberOfNodes-1)*xNumberOfNodes+j][(yNumberOfNodes-1)*xNumberOfNodes+j] = ap b[(yNumberOfNodes-1)*xNumberOfNodes+j] = aux.analyticSolution(xNodesPositions[j],yNodesPositions[yNumberOfNodes - 1]) ############################# # Solving the linear system ############################ solution = np.linalg.solve(np.array(A),np.array(b)) temperatureField = [] for i in range(yNumberOfNodes): temperatureField.append([]) for j in range(xNumberOfNodes): temperatureField[i].append(solution[i*xNumberOfNodes+j]) ######################################### # Error with respect to the 1D solution ######################################### errors = [] for i in range(yNumberOfNodes): errors.append([]) for j in range(xNumberOfNodes): exactTemperature = aux.analyticSolution(xNodesPositions[i],yNodesPositions[j]) aproxTemperature = temperatureField[i][j] diff = (exactTemperature - aproxTemperature)/(Ti - Te) errors[i].append(abs(diff)) errors = np.array(errors) maximumError = errors.max() return maximumError
#bottom for j in range(xNumberOfNodes): ap = 1.0 A[j][j] = ap b[j] = aux.analyticSolution(xNodesPositions[j], yNodesPositions[0]) #center for i in range(1, yNumberOfNodes - 1): for j in range(xNumberOfNodes): if j == 0 or j == (xNumberOfNodes - 1): ap = 1.0 A[i * xNumberOfNodes + j][i * xNumberOfNodes + j] = ap b[i * xNumberOfNodes + j] = aux.analyticSolution( xNodesPositions[j], yNodesPositions[i]) else: uw = aux.uVelocity(omega, xSurfacePositions[j - 1], yNodesPositions[i]) ue = aux.uVelocity(omega, xSurfacePositions[j], yNodesPositions[i]) vs = aux.vVelocity(omega, xNodesPositions[j], ySurfacePositions[i - 1]) vn = aux.vVelocity(omega, xNodesPositions[j], ySurfacePositions[i]) Mw = rho * uw * deltaY Me = rho * ue * deltaY Ms = rho * vs * deltaX Mn = rho * vn * deltaX De = gamma * deltaY / deltaX Dw = De Dn = gamma * deltaY / deltaX Ds = Dn aEast = De - 0.5 * Me aWest = Dw + 0.5 * Mw aSouth = Ds + 0.5 * Ms