CMISS Version 2.1 ipbase File Version 2 Heading: Enter the number of types of basis function [1]: 7 For basis function type 1 the type of nodal interpolation is [1]: (0) Auxiliary basis only (1) Lagrange/Hermite tensor prod (2) Simplex/Serendipity/Sector (3) B-spline tensor product (4) Fourier Series/Lagrange/Hermite tensor prod (5) Boundary Element Lagrange/Hermite tensor pr. (6) Boundary Element Simplex/Serendipity/Sector (7) Extended Lagrange (multigrid collocation) 1 Enter the number of Xi-coordinates [1]: 3 The interpolant in the Xi(1) direction is [1]: (1) Linear Lagrange (2) Quadratic Lagrange (3) Cubic Lagrange (4) Quadratic Hermite (5) Cubic Hermite 5 Enter the number of Gauss points in the Xi(1) direction [3]: 3 The interpolant in the Xi(2) direction is [1]: (1) Linear Lagrange (2) Quadratic Lagrange (3) Cubic Lagrange (4) Quadratic Hermite (5) Cubic Hermite 5 Enter the number of Gauss points in the Xi(2) direction [3]: 3 The interpolant in the Xi(3) direction is [1]: (1) Linear Lagrange (2) Quadratic Lagrange (3) Cubic Lagrange (4) Quadratic Hermite (5) Cubic Hermite 1 Enter the number of Gauss points in the Xi(3) direction [2]: 3 Do you want to set cross derivatives to zero [N]? N Enter the node position indices [111211121221112212122222]: 1 1 1 2 1 1 1 2 1 2 2 1 1 1 2 2 1 2 1 2 2 2 2 2 Enter the derivative order indices [111211121221]: 1 1 1 2 1 1 1 2 1 2 2 1 Enter the number of auxiliary element parameters [0]: 0 For basis function type 1 scale factors are [6]: (1) Unit (2) Read in - Element based (3) Read in - Node based (4) Calculated from angle change (5) Calculated from arc length (6) Calculated from arithmetic mean arc length (7) Calculated from harmonic mean arc length 6 For basis function type 2 the type of nodal interpolation is [1]: (0) Auxiliary basis only (1) Lagrange/Hermite tensor prod (2) Simplex/Serendipity/Sector (3) B-spline tensor product (4) Fourier Series/Lagrange/Hermite tensor prod (5) Boundary Element Lagrange/Hermite tensor pr. (6) Boundary Element Simplex/Serendipity/Sector (7) Extended Lagrange (multigrid collocation) 1 Enter the number of Xi-coordinates [1]: 2 The interpolant in the Xi(1) direction is [1]: (1) Linear Lagrange (2) Quadratic Lagrange (3) Cubic Lagrange (4) Quadratic Hermite (5) Cubic Hermite 5 Enter the number of Gauss points in the Xi(1) direction [3]: 3 The interpolant in the Xi(2) direction is [1]: (1) Linear Lagrange (2) Quadratic Lagrange (3) Cubic Lagrange (4) Quadratic Hermite (5) Cubic Hermite 5 Enter the number of Gauss points in the Xi(2) direction [3]: 3 Do you want to set cross derivatives to zero [N]? N Enter the node position indices [11211222]: 1 1 2 1 1 2 2 2 Enter the derivative order indices [11211222]: 1 1 2 1 1 2 2 2 Enter the number of auxiliary element parameters [0]: 0 For basis function type 2 scale factors are [6]: (1) Unit (2) Read in - Element based (3) Read in - Node based (4) Calculated from angle change (5) Calculated from arc length (6) Calculated from arithmetic mean arc length (7) Calculated from harmonic mean arc length 6 For basis function type 3 the type of nodal interpolation is [1]: (0) Auxiliary basis only (1) Lagrange/Hermite tensor prod (2) Simplex/Serendipity/Sector (3) B-spline tensor product (4) Fourier Series/Lagrange/Hermite tensor prod (5) Boundary Element Lagrange/Hermite tensor pr. (6) Boundary Element Simplex/Serendipity/Sector (7) Extended Lagrange (multigrid collocation) 1 Enter the number of Xi-coordinates [1]: 2 The interpolant in the Xi(1) direction is [1]: (1) Linear Lagrange (2) Quadratic Lagrange (3) Cubic Lagrange (4) Quadratic Hermite (5) Cubic Hermite 5 Enter the number of Gauss points in the Xi(1) direction [3]: 3 The interpolant in the Xi(2) direction is [1]: (1) Linear Lagrange (2) Quadratic Lagrange (3) Cubic Lagrange (4) Quadratic Hermite (5) Cubic Hermite 1 Enter the number of Gauss points in the Xi(2) direction [3]: 3 Enter the node position indices [11211222]: 1 1 2 1 1 2 2 2 Enter the derivative order indices [1121]: 1 1 2 1 Enter the number of auxiliary element parameters [0]: 0 For basis function type 3 scale factors are [6]: (1) Unit (2) Read in - Element based (3) Read in - Node based (4) Calculated from angle change (5) Calculated from arc length (6) Calculated from arithmetic mean arc length (7) Calculated from harmonic mean arc length 6 For basis function type 4 the type of nodal interpolation is [1]: (0) Auxiliary basis only (1) Lagrange/Hermite tensor prod (2) Simplex/Serendipity/Sector (3) B-spline tensor product (4) Fourier Series/Lagrange/Hermite tensor prod (5) Boundary Element Lagrange/Hermite tensor pr. (6) Boundary Element Simplex/Serendipity/Sector (7) Extended Lagrange (multigrid collocation) 1 Enter the number of Xi-coordinates [1]: 2 The interpolant in the Xi(1) direction is [1]: (1) Linear Lagrange (2) Quadratic Lagrange (3) Cubic Lagrange (4) Quadratic Hermite (5) Cubic Hermite 1 Enter the number of Gauss points in the Xi(1) direction [3]: 3 The interpolant in the Xi(2) direction is [1]: (1) Linear Lagrange (2) Quadratic Lagrange (3) Cubic Lagrange (4) Quadratic Hermite (5) Cubic Hermite 5 Enter the number of Gauss points in the Xi(2) direction [3]: 3 Enter the node position indices [11211222]: 1 1 2 1 1 2 2 2 Enter the derivative order indices [1112]: 1 1 1 2 Enter the number of auxiliary element parameters [0]: 0 For basis function type 4 scale factors are [6]: (1) Unit (2) Read in - Element based (3) Read in - Node based (4) Calculated from angle change (5) Calculated from arc length (6) Calculated from arithmetic mean arc length (7) Calculated from harmonic mean arc length 6 For basis function type 5 the type of nodal interpolation is [1]: (0) Auxiliary basis only (1) Lagrange/Hermite tensor prod (2) Simplex/Serendipity/Sector (3) B-spline tensor product (4) Fourier Series/Lagrange/Hermite tensor prod (5) Boundary Element Lagrange/Hermite tensor pr. (6) Boundary Element Simplex/Serendipity/Sector (7) Extended Lagrange (multigrid collocation) 1 Enter the number of Xi-coordinates [1]: 3 The interpolant in the Xi(1) direction is [1]: (1) Linear Lagrange (2) Quadratic Lagrange (3) Cubic Lagrange (4) Quadratic Hermite (5) Cubic Hermite 1 Enter the number of Gauss points in the Xi(1) direction [2]: 3 The interpolant in the Xi(2) direction is [1]: (1) Linear Lagrange (2) Quadratic Lagrange (3) Cubic Lagrange (4) Quadratic Hermite (5) Cubic Hermite 1 Enter the number of Gauss points in the Xi(2) direction [2]: 3 The interpolant in the Xi(3) direction is [1]: (1) Linear Lagrange (2) Quadratic Lagrange (3) Cubic Lagrange (4) Quadratic Hermite (5) Cubic Hermite 1 Enter the number of Gauss points in the Xi(3) direction [2]: 3 Enter the node position indices [111211121221112212122222]: 1 1 1 2 1 1 1 2 1 2 2 1 1 1 2 2 1 2 1 2 2 2 2 2 Enter the number of auxiliary element parameters [0]: 0 For basis function type 6 the type of nodal interpolation is [1]: (0) Auxiliary basis only (1) Lagrange/Hermite tensor prod (2) Simplex/Serendipity/Sector (3) B-spline tensor product (4) Fourier Series/Lagrange/Hermite tensor prod (5) Boundary Element Lagrange/Hermite tensor pr. (6) Boundary Element Simplex/Serendipity/Sector (7) Extended Lagrange (multigrid collocation) 1 Enter the number of Xi-coordinates [1]: 2 The interpolant in the Xi(1) direction is [1]: (1) Linear Lagrange (2) Quadratic Lagrange (3) Cubic Lagrange (4) Quadratic Hermite (5) Cubic Hermite 1 Enter the number of Gauss points in the Xi(1) direction [2]: 3 The interpolant in the Xi(2) direction is [1]: (1) Linear Lagrange (2) Quadratic Lagrange (3) Cubic Lagrange (4) Quadratic Hermite (5) Cubic Hermite 1 Enter the number of Gauss points in the Xi(2) direction [2]: 3 Enter the node position indices [11211222]: 1 1 2 1 1 2 2 2 Enter the number of auxiliary element parameters [0]: 0 For basis function type 7 the type of nodal interpolation is [1]: (0) Auxiliary basis only (1) Lagrange/Hermite tensor prod (2) Simplex/Serendipity/Sector (3) B-spline tensor product (4) Fourier Series/Lagrange/Hermite tensor prod (5) Boundary Element Lagrange/Hermite tensor pr. (6) Boundary Element Simplex/Serendipity/Sector (7) Extended Lagrange (multigrid collocation) 0 Enter the number of auxiliary element parameters [0]: 1 Auxiliary basis is [1]: (1) Legendre (2) Fourier (3) Pressure (4) Unused 3 Enter the number of Xi-coordinates [2]: 3 Enter the number of Gauss points in the Xi(1) direction [2]: 3 Enter the number of Gauss points in the Xi(2) direction [2]: 3 Enter the number of Gauss points in the Xi(3) direction [2]: 3 For auxiliary basis function parameter 1: The polynomial degree in the Xi(1) direction is [0]: 0 The polynomial degree in the Xi(2) direction is [0]: 0 The polynomial degree in the Xi(3) direction is [0]: 0