Jacobian Matrix And Determinant
In vector calculus, the Jacobian matrix ( /dʒɨˈkoʊbiən/, /jɨˈkoʊbiən/) is the matrix of all first-order partial derivatives of a vector- or scalar-valued function with respect to another vector. Suppose is a function from Euclidean n-space to Euclidean m-space. Such a function is given by m real-valued component functions, . The partial derivatives of all these functions (if they exist) can be organized in an m-by-n matrix, the Jacobian matrix of, as follows:
This matrix is also denoted by and . If are the usual orthogonal Cartesian coordinates, the i th row (i = 1, ..., m) of this matrix corresponds to the gradient of the ith component function Fi: . Note that some books define the Jacobian as the transpose of the matrix given above.
The Jacobian determinant (often simply called the Jacobian) is the determinant of the Jacobian matrix (if ).
These concepts are named after the mathematician Carl Gustav Jacob Jacobi.
Read more about Jacobian Matrix And Determinant: Jacobian Matrix, Jacobian Determinant, Examples
Famous quotes containing the word matrix:
“As all historians know, the past is a great darkness, and filled with echoes. Voices may reach us from it; but what they say to us is imbued with the obscurity of the matrix out of which they come; and try as we may, we cannot always decipher them precisely in the clearer light of our day.”
—Margaret Atwood (b. 1939)