메소드 | 설명 | |
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Add ( Matrix Mat1, Matrix Mat2 ) : Matrix |
Returns the summation of two matrices with compatible dimensions. In case of an error the error is raised as an exception.
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Add ( double Mat1, double Mat2 ) : ].double[ |
Returns the summation of two matrices with compatible dimensions. In case of an error the error is raised as an exception.
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CrossProduct ( Matrix V1, Matrix V2 ) : Matrix |
Returns the cross product of two vectors whose dimensions should be [3] or [3x1]. In case of an error the error is raised as an exception.
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CrossProduct ( double V1, double V2 ) : ].double[ |
Returns the cross product of two vectors whose dimensions should be [3] or [3x1]. In case of an error the error is raised as an exception.
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CrossProduct ( double V1, double V2 ) : double[] |
Returns the cross product of two vectors whose dimensions should be [3] or [3,1]. In case of an error the error is raised as an exception.
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Det ( Matrix Mat ) : double |
Returns the determinant of a matrix with [n,n] dimension. In case of an error the error is raised as an exception.
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Det ( double Mat ) : double |
Returns the determinant of a matrix with [n,n] dimension. In case of an error the error is raised as an exception.
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DotProduct ( Matrix V1, Matrix V2 ) : double |
Returns the dot product of two vectors whose dimensions should be [3] or [3,1]. In case of an error the error is raised as an exception.
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DotProduct ( double V1, double V2 ) : double |
Returns the dot product of two vectors whose dimensions should be [3] or [3,1]. In case of an error the error is raised as an exception.
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Eigen ( Matrix Mat, Matrix &d, Matrix &v ) : void |
Returns the Eigenvalues and Eigenvectors of a real symmetric matrix, which is of dimensions [n,n]. In case of an error the error is raised as an exception. Note: This method is based on the 'Eigenvalues and Eigenvectors of a TridiagonalMatrix' section of Numerical Recipes in C by William H. Press, Saul A. Teukolsky, William T. Vetterling and Brian P. Flannery, University of Cambridge Press 1992.
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Eigen ( double Mat, double &d, double &v ) : void |
Returns the Eigenvalues and Eigenvectors of a real symmetric matrix, which is of dimensions [n,n]. In case of an error the error is raised as an exception. Note: This method is based on the 'Eigenvalues and Eigenvectors of a TridiagonalMatrix' section of Numerical Recipes in C by William H. Press, Saul A. Teukolsky, William T. Vetterling and Brian P. Flannery, University of Cambridge Press 1992.
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Equals ( Object obj ) : bool |
Tests whether the specified object is a MatrixLibrary.Matrix object and is identical to this MatrixLibrary.Matrix object.
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GetHashCode ( ) : int | ||
Identity ( int n ) : ].double[ |
Returns an Identity matrix with dimensions [n,n] in the from of an array.
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Inverse ( Matrix Mat ) : Matrix |
Returns the inverse of a matrix with [n,n] dimension and whose determinant is not zero. In case of an error the error is raised as an exception.
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Inverse ( double Mat ) : ].double[ |
Returns the inverse of a matrix with [n,n] dimension and whose determinant is not zero. In case of an error the error is raised as an exception.
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IsEqual ( Matrix Mat1, Matrix Mat2 ) : bool |
Checks if two matrices of equal dimensions are equal or not. In case of an error the error is raised as an exception.
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IsEqual ( double Mat1, double Mat2 ) : bool |
Checks if two Arrays of equal dimensions are equal or not. In case of an error the error is raised as an exception.
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LU ( Matrix Mat, Matrix &L, Matrix &U, Matrix &P ) : void |
Returns the LU Decomposition of a matrix. the output is: lower triangular matrix L, upper triangular matrix U, and permutation matrix P so that P*X = L*U. In case of an error the error is raised as an exception. Note: This method is based on the 'LU Decomposition and Its Applications' section of Numerical Recipes in C by William H. Press, Saul A. Teukolsky, William T. Vetterling and Brian P. Flannery, University of Cambridge Press 1992.
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LU ( double Mat, double &L, double &U, double &P ) : void |
Returns the LU Decomposition of a matrix. the output is: lower triangular matrix L, upper triangular matrix U, and permutation matrix P so that P*X = L*U. In case of an error the error is raised as an exception. Note: This method is based on the 'LU Decomposition and Its Applications' section of Numerical Recipes in C by William H. Press, Saul A. Teukolsky, William T. Vetterling and Brian P. Flannery, University of Cambridge Press 1992.
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Matrix ( double Mat ) : System |
Matrix object constructor, constructs a matrix from an already defined array object.
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Matrix ( int noRows, int noCols ) : System |
Matrix object constructor, constructs an empty matrix with dimensions: rows = noRows and cols = noCols.
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Multiply ( Matrix Mat1, Matrix Mat2 ) : Matrix |
Returns the multiplication of two matrices with compatible dimensions OR the cross-product of two vectors. In case of an error the error is raised as an exception.
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Multiply ( double Mat1, double Mat2 ) : ].double[ |
Returns the multiplication of two matrices with compatible dimensions. In case of an error the error is raised as an exception.
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OneD_2_TwoD ( double Mat ) : ].double[ |
Returns the 2D form of a 1D array. i.e. array with dimension[n] is returned as an array with dimension [n,1]. In case of an error the error is raised as an exception.
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PINV ( Matrix Mat ) : Matrix |
Returns the pseudoinverse of a matrix, such that X = PINV(A) produces a matrix 'X' of the same dimensions as A' so that A*X*A = A, X*A*X = X. In case of an error the error is raised as an exception.
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PINV ( double Mat ) : ].double[ |
Returns the pseudoinverse of a matrix, such that X = PINV(A) produces a matrix 'X' of the same dimensions as A' so that A*X*A = A, X*A*X = X. In case of an error the error is raised as an exception.
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PrintMat ( Matrix Mat ) : string |
Returns a matrix as a string, so it can be viewed in a multi-text textbox or in a richtextBox (preferred). In case of an error the error is raised as an exception.
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PrintMat ( double Mat ) : string |
Returns a matrix as a string, so it can be viewed in a multi-text textbox or in a richtextBox (preferred). In case of an error the error is raised as an exception.
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Rank ( Matrix Mat ) : int |
Returns the rank of a matrix. In case of an error the error is raised as an exception.
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Rank ( double Mat ) : int |
Returns the rank of a matrix. In case of an error the error is raised as an exception.
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SVD ( Matrix Mat, Matrix &S, Matrix &U, Matrix &V ) : void |
Evaluates the Singular Value Decomposition of a matrix, returns the matrices S, U and V. Such that a given Matrix = U x S x V'. In case of an error the error is raised as an exception. Note: This method is based on the 'Singular Value Decomposition' section of Numerical Recipes in C by William H. Press, Saul A. Teukolsky, William T. Vetterling and Brian P. Flannery, University of Cambridge Press 1992.
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SVD ( double Mat_, double &S_, double &U_, double &V_ ) : void |
Evaluates the Singular Value Decomposition of a matrix, returns the matrices S, U and V. Such that a given Matrix = U x S x V'. In case of an error the error is raised as an exception. Note: This method is based on the 'Singular Value Decomposition' section of Numerical Recipes in C by William H. Press, Saul A. Teukolsky, William T. Vetterling and Brian P. Flannery, University of Cambridge Press 1992.
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ScalarDivide ( double Value, Matrix Mat ) : Matrix |
Returns the division of a matrix or a vector (i.e dimension [3,1]) by a scalar quantity. In case of an error the error is raised as an exception.
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ScalarDivide ( double Value, double Mat ) : ].double[ |
Returns the division of a matrix or a vector (i.e dimension [3,1]) by a scalar quantity. In case of an error the error is raised as an exception.
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ScalarMultiply ( double Value, Matrix Mat ) : Matrix |
Returns the multiplication of a matrix or a vector (i.e dimension [3,1]) with a scalar quantity. In case of an error the error is raised as an exception.
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ScalarMultiply ( double Value, double Mat ) : ].double[ |
Returns the multiplication of a matrix or a vector (i.e dimension [3,1]) with a scalar quantity. In case of an error the error is raised as an exception.
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SolveLinear ( Matrix MatA, Matrix MatB ) : Matrix |
Solves a set of n linear equations A.X = B, and returns X, where A is [n,n] and B is [n,1]. In the same manner if you need to compute: inverse(A).B, it is better to use this method instead, as it is much faster. In case of an error the error is raised as an exception. Note: This method is based on the 'LU Decomposition and Its Applications' section of Numerical Recipes in C by William H. Press, Saul A. Teukolsky, William T. Vetterling and Brian P. Flannery, University of Cambridge Press 1992.
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SolveLinear ( double MatA, double MatB ) : ].double[ |
Solves a set of n linear equations A.X = B, and returns X, where A is [n,n] and B is [n,1]. In the same manner if you need to compute: inverse(A).B, it is better to use this method instead, as it is much faster. In case of an error the error is raised as an exception. Note: This method is based on the 'LU Decomposition and Its Applications' section of Numerical Recipes in C by William H. Press, Saul A. Teukolsky, William T. Vetterling and Brian P. Flannery, University of Cambridge Press 1992.
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Subtract ( Matrix Mat1, Matrix Mat2 ) : Matrix |
Returns the difference of two matrices with compatible dimensions. In case of an error the error is raised as an exception.
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Subtract ( double Mat1, double Mat2 ) : ].double[ |
Returns the difference of two matrices with compatible dimensions. In case of an error the error is raised as an exception.
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ToString ( ) : string |
Returns the matrix as a string, so it can be viewed in a multi-text textbox or in a richtextBox (preferred). In case of an error the error is raised as an exception.
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Transpose ( Matrix Mat ) : Matrix |
Returns the transpose of a matrix. In case of an error the error is raised as an exception.
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Transpose ( double Mat ) : ].double[ |
Returns the transpose of a matrix. In case of an error the error is raised as an exception.
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TwoD_2_OneD ( double Mat ) : double[] |
Returns the 1D form of a 2D array. i.e. array with dimension[n,1] is returned as an array with dimension [n]. In case of an error the error is raised as an exception.
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VectorMagnitude ( Matrix V ) : double |
Returns the magnitude of a vector whose dimension is [3] or [3,1]. In case of an error the error is raised as an exception.
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VectorMagnitude ( double V ) : double |
Returns the magnitude of a vector whose dimension is [3] or [3,1]. In case of an error the error is raised as an exception.
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operator ( ) : Matrix |
Returns the multiplication of two matrices with compatible dimensions OR the cross-product of two vectors. In case of an error the error is raised as an exception.
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operator ( ) : bool |
Checks if two matrices of equal dimensions are not equal. In case of an error the error is raised as an exception.
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this ( int Row, int Col ) : double |
Set or get an element from the matrix
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메소드 | 설명 | |
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Find_R_C ( double Mat, int &Row ) : void | ||
Find_R_C ( double Mat, int &Row, int &Col ) : void | ||
PYTHAG ( double a, double b ) : double | ||
ROT ( double g, double h, double s, double tau, double a, int i, int j, int k, int l ) : void | ||
SQR ( double a ) : double | ||
Sign ( double a, double b ) : double | ||
SwapRows ( double Mat, int Row, int toRow ) : void |
public static Add ( Matrix Mat1, Matrix Mat2 ) : Matrix | ||
Mat1 | Matrix | First matrix in the summation |
Mat2 | Matrix | Second matrix in the summation |
리턴 | Matrix |
public static Add ( double Mat1, double Mat2 ) : ].double[ | ||
Mat1 | double | First array in the summation |
Mat2 | double | Second array in the summation |
리턴 | ].double[ |
public static CrossProduct ( Matrix V1, Matrix V2 ) : Matrix | ||
V1 | Matrix | First Matrix (dimensions [3,1]) in the cross product |
V2 | Matrix | Second Matrix (dimensions [3,1]) in the cross product |
리턴 | Matrix |
public static CrossProduct ( double V1, double V2 ) : ].double[ | ||
V1 | double | First vector array (dimensions [3,1]) in the cross product |
V2 | double | Second vector array (dimensions [3,1]) in the cross product |
리턴 | ].double[ |
public static CrossProduct ( double V1, double V2 ) : double[] | ||
V1 | double | First vector array (dimension [3]) in the cross product |
V2 | double | Second vector array (dimension [3]) in the cross product |
리턴 | double[] |
public static Det ( Matrix Mat ) : double | ||
Mat | Matrix | /// Matrix object with [n,n] dimension whose determinant is to be found /// |
리턴 | double |
public static Det ( double Mat ) : double | ||
Mat | double | /// Array with [n,n] dimension whose determinant is to be found /// |
리턴 | double |
public static DotProduct ( Matrix V1, Matrix V2 ) : double | ||
V1 | Matrix | First Matrix object (dimension [3,1]) in the dot product |
V2 | Matrix | Second Matrix object (dimension [3,1]) in the dot product |
리턴 | double |
public static DotProduct ( double V1, double V2 ) : double | ||
V1 | double | First vector array (dimension [3]) in the dot product |
V2 | double | Second vector array (dimension [3]) in the dot product |
리턴 | double |
public static Eigen ( Matrix Mat, Matrix &d, Matrix &v ) : void | ||
Mat | Matrix | /// The Matrix object whose Eigenvalues and Eigenvectors are to be found /// |
d | Matrix | A Matrix object where the eigenvalues are returned |
v | Matrix | A Matrix object where the eigenvectors are returned |
리턴 | void |
public static Eigen ( double Mat, double &d, double &v ) : void | ||
Mat | double | /// The array whose Eigenvalues and Eigenvectors are to be found /// |
d | double | An array where the eigenvalues are returned |
v | double | An array where the eigenvectors are returned |
리턴 | void |
public Equals ( Object obj ) : bool | ||
obj | Object | The object to compare with the current object |
리턴 | bool |
public static Identity ( int n ) : ].double[ | ||
n | int | the no. of rows or no. cols in the matrix |
리턴 | ].double[ |
public static Inverse ( Matrix Mat ) : Matrix | ||
Mat | Matrix | /// Matrix object with [n,n] dimension whose inverse is to be found /// |
리턴 | Matrix |
public static Inverse ( double Mat ) : ].double[ | ||
Mat | double | /// Array with [n,n] dimension whose inverse is to be found /// |
리턴 | ].double[ |
public static IsEqual ( Matrix Mat1, Matrix Mat2 ) : bool | ||
Mat1 | Matrix | First Matrix in equality check |
Mat2 | Matrix | Second Matrix in equality check |
리턴 | bool |
public static IsEqual ( double Mat1, double Mat2 ) : bool | ||
Mat1 | double | First array in equality check |
Mat2 | double | Second array in equality check |
리턴 | bool |
public static LU ( Matrix Mat, Matrix &L, Matrix &U, Matrix &P ) : void | ||
Mat | Matrix | Matrix object which will be LU Decomposed |
L | Matrix | A Matrix object where the lower traingular matrix is returned |
U | Matrix | A Matrix object where the upper traingular matrix is returned |
P | Matrix | A Matrix object where the permutation matrix is returned |
리턴 | void |
public static LU ( double Mat, double &L, double &U, double &P ) : void | ||
Mat | double | Array which will be LU Decomposed |
L | double | An array where the lower traingular matrix is returned |
U | double | An array where the upper traingular matrix is returned |
P | double | An array where the permutation matrix is returned |
리턴 | void |
public Matrix ( double Mat ) : System | ||
Mat | double | the array the matrix will contain |
리턴 | System |
public Matrix ( int noRows, int noCols ) : System | ||
noRows | int | no. of rows in this matrix |
noCols | int | no. of columns in this matrix |
리턴 | System |
public static Multiply ( Matrix Mat1, Matrix Mat2 ) : Matrix | ||
Mat1 | Matrix | /// First matrix or vector (i.e: dimension [3,1]) object in /// multiplication /// |
Mat2 | Matrix | /// Second matrix or vector (i.e: dimension [3,1]) object in /// multiplication /// |
리턴 | Matrix |
public static Multiply ( double Mat1, double Mat2 ) : ].double[ | ||
Mat1 | double | First array in multiplication |
Mat2 | double | Second array in multiplication |
리턴 | ].double[ |
public static OneD_2_TwoD ( double Mat ) : ].double[ | ||
Mat | double | /// the array to convert, with dimesion [n] /// |
리턴 | ].double[ |
public static PINV ( Matrix Mat ) : Matrix | ||
Mat | Matrix | a Matrix object whose pseudoinverse is to be found |
리턴 | Matrix |
public static PINV ( double Mat ) : ].double[ | ||
Mat | double | An array whose pseudoinverse is to be found |
리턴 | ].double[ |
public static PrintMat ( Matrix Mat ) : string | ||
Mat | Matrix | The Matrix object to be viewed |
리턴 | string |
public static PrintMat ( double Mat ) : string | ||
Mat | double | The array to be viewed |
리턴 | string |
public static Rank ( Matrix Mat ) : int | ||
Mat | Matrix | a Matrix object whose rank is to be found |
리턴 | int |
public static Rank ( double Mat ) : int | ||
Mat | double | An array whose rank is to be found |
리턴 | int |
public static SVD ( Matrix Mat, Matrix &S, Matrix &U, Matrix &V ) : void | ||
Mat | Matrix | Matrix object whose SVD is to be computed |
S | Matrix | A Matrix object where the S matrix is returned |
U | Matrix | A Matrix object where the U matrix is returned |
V | Matrix | A Matrix object where the V matrix is returned |
리턴 | void |
public static SVD ( double Mat_, double &S_, double &U_, double &V_ ) : void | ||
Mat_ | double | Array whose SVD is to be computed |
S_ | double | An array where the S matrix is returned |
U_ | double | An array where the U matrix is returned |
V_ | double | An array where the V matrix is returned |
리턴 | void |
public static ScalarDivide ( double Value, Matrix Mat ) : Matrix | ||
Value | double | The scalar value to divide the array with |
Mat | Matrix | Matrix which is to be divided by a scalar |
리턴 | Matrix |
public static ScalarDivide ( double Value, double Mat ) : ].double[ | ||
Value | double | The scalar value to divide the array with |
Mat | double | Array which is to be divided by a scalar |
리턴 | ].double[ |
public static ScalarMultiply ( double Value, Matrix Mat ) : Matrix | ||
Value | double | The scalar value to multiply the array |
Mat | Matrix | Matrix which is to be multiplied by a scalar |
리턴 | Matrix |
public static ScalarMultiply ( double Value, double Mat ) : ].double[ | ||
Value | double | The scalar value to multiply the array |
Mat | double | Array which is to be multiplied by a scalar |
리턴 | ].double[ |
public static SolveLinear ( Matrix MatA, Matrix MatB ) : Matrix | ||
MatA | Matrix | Matrix object 'A' on the left side of the equations A.X = B |
MatB | Matrix | Matrix object 'B' on the right side of the equations A.X = B |
리턴 | Matrix |
public static SolveLinear ( double MatA, double MatB ) : ].double[ | ||
MatA | double | The array 'A' on the left side of the equations A.X = B |
MatB | double | The array 'B' on the right side of the equations A.X = B |
리턴 | ].double[ |
public static Subtract ( Matrix Mat1, Matrix Mat2 ) : Matrix | ||
Mat1 | Matrix | First matrix in the subtraction |
Mat2 | Matrix | Second matrix in the subtraction |
리턴 | Matrix |
public static Subtract ( double Mat1, double Mat2 ) : ].double[ | ||
Mat1 | double | First array in the subtraction |
Mat2 | double | Second array in the subtraction |
리턴 | ].double[ |
public static Transpose ( Matrix Mat ) : Matrix | ||
Mat | Matrix | Matrix object whose transpose is to be found |
리턴 | Matrix |
public static Transpose ( double Mat ) : ].double[ | ||
Mat | double | Array whose transpose is to be found |
리턴 | ].double[ |
public static TwoD_2_OneD ( double Mat ) : double[] | ||
Mat | double | /// the array to convert, with dimesions [n,1] /// |
리턴 | double[] |
public static VectorMagnitude ( Matrix V ) : double | ||
V | Matrix | Matrix object (dimension [3,1]) whose magnitude is to be found |
리턴 | double |
public static VectorMagnitude ( double V ) : double | ||
V | double | The vector array (dimension [3]) whose magnitude is to be found |
리턴 | double |