|
In mathematics, differential-algebraic equations (DAEs) are a general form of (systems of) differential equations for vector–valued functions ''x'' in one independent variable ''t'', :: where is a vector of dependent variables and the system has as many equations, . They are distinct from ordinary differential equation (ODE) in that a DAE is not completely solvable for the derivatives of all components of the function ''x'' because these may not all appear (i.e. some equations are algebraic); technically the distinction between an implicit ODE system (may be rendered explicit ) and a DAE system is that the Jacobian matrix is a singular matrix for a DAE system. This distinction between ODEs and DAEs is made because DAEs have different characteristics and are generally more difficult to solve. In practical terms, the distinction between DAEs and ODEs is often that the solution of a DAE system depends on the derivatives of the input signal and not just the signal itself as in the case of ODEs; this issue is commonly encountered in systems with hysteresis, such as the Schmitt trigger.〔, pp. 529-531〕 This difference is more clearly visible if the system may be rewritten so that instead of ''x'' we consider a pair of vectors of dependent variables and the DAE has the form :: :where , , and A DAE system of this form is called ''semi-explicit''.〔 Every solution of the second half ''g'' of the equation defines a unique direction for ''x'' via the first half ''f'' of the equations, while the direction for ''y'' is arbitrary. But not every point ''(x,y,t)'' is a solution of ''g''. The variables in ''x'' and the first half ''f'' of the equations get the attribute ''differential''. The components of ''y'' and the second half ''g'' of the equations are called the ''algebraic'' variables or equations of the system. (term ''algebraic'' in the context of DAEs only means ''free of derivatives'' and is not related to (abstract) algebra. ) The solution of a DAE consists of two parts, first the search for consistent initial values and second the computation of a trajectory. To find consistent initial values it is often necessary to consider the derivatives of some of the component functions of the DAE. The highest order of a derivative that is necessary in this process is called the ''differentiation index''. The equations derived in computing the index and consistent initial values may also be of use in the computation of the trajectory. A semi-explicit DAE system can be converted to an implicit one by decreasing the differentiation index by one, and vice versa.〔Ascher and Petzold, p. 234〕 == Other forms of DAEs == The distinction of DAEs to ODEs becomes apparent if some of the dependent variables occur without their derivatives. The vector of dependent variables may then be written as pair and the system of differential equations of the DAE appears in the form :: where * , a vector in , are dependent variables for which derivatives are present (''differential variables''), * , a vector in , are dependent variables for which no derivatives are present (''algebraic variables''), * , a scalar (usually time) is an independent variable. * is a vector of functions that involve subsets these variables and derivatives. As a whole, the set of DAEs is a function :: Initial conditions must be a solution of the system of equations of the form :: 抄文引用元・出典: フリー百科事典『 ウィキペディア(Wikipedia)』 ■ウィキペディアで「differential algebraic equation」の詳細全文を読む スポンサード リンク
|