Navigation
  • Home
  • Recent
  • Most Active
  • Popular
  • Blog
  • Credits
  • RSS
    		•
      Interaction
  • Register
  • Statistics
    		•
      Help
  • Suggestions
  • Contact Us
  • How to Edit
  • Help
    		•



    [Edit]




    In calculus, a differential is an infinitesimally small change in a variable.
    A differential is a change in a variable much like the familiar Δx. The difference is that a differential (dx) is infinitely small and thus does not have an actual value.


        Differential (calculus)
            Uses
            The differential as a local linear transformation
            Confusion
            History
            See also

    top

    Uses
    A derivative (of a single variable equation) is a ratio of two differentials, typically denoted rac which is the Leibniz notation equivalent of y' ig( x ig) = dot y in Newton's notation for differentiation. This is a consequence of the slope equation m = rac where the only difference is the replacement of Deltas with differentials to reflect the fact that the x and y values are at one point, not across two. For a more in-depth explanation see derivative.

    Integrals also use differentials. In fact, single variable integrals require a differential at the end. This differential represents the thickness of the rectangles making up the Riemann integral.

    top

    The differential as a local linear transformation
    Several authors have attempted to define the differential without reference to infinitesimals. This definition is based on the definition in Apostol's book:

    Consider a real-valued function f defined on an open subset S of mathbb^n. If mathbf in S is a point in S, then we say that f has a differential at mathbf if there exists g_mathbf satisfying:

      g_mathbf is a real-valued function defined in the whole of mathbb^n
      g_mathbf is linear. That is given mathbf, mathbf in mathbb^n and alpha, eta in mathbb:
      g_mathbfleft(alpha mathbf + eta mathbf
    ight) = alpha g_mathbf(mathbf) + eta g_mathbf(mathbf)
      For every epsilon > 0, there exists a neighborhood N(mathbf) of mathbf such that:
      mathbf in N(mathbf) Longrightarrow left|f(mathbf)-f(mathbf)-g_mathbf(mathbf-mathbf)
    ight| ight|

    g_mathbf left(mathbf
    ight) is often thought of as a function of two n-dimensional variables and written g left(mathbf; mathbf
    ight). Note, however, that it may not be defined over the whole of S. It is common to write the variables mathbf = left(t_1,t_2, dots t_n
    ight) as dmathbf = left(dx_1,dx_2, dots dx_n
    ight) and the differential, if it exists as dfleft(mathbf; dmathbf
    ight). It is then possible to prove that it is unique and satisfies:
    dfleft(mathbf; dmathbf

    ight) = sum_^n D_k fleft(mathbf
    ight)dx_k,
    Where D_kfleft(mathbf
    ight) are the the n partial derivatives at mathbf. This can be written more briefly using the following notation:
    df = racdx_1 + racdx_2 + dots racdx_n .

    In the one dimensional case this becomes:
    df = racdx.

    This notation is very suggestive but it should be realised that rac is a complete symbol whereas dx is a linear transformation of a one dimensional space. Thus there is no question of "cancelling" the dx.

    The existence of all the partial derivatives of fleft(mathbf
    ight) at mathbf is a necessary condition for the existence of a differential at mathbf. However it is not a sufficient condition. It is possible to prove that if fleft(mathbf
    ight) has a differential at mathbf then it is continuous at mathbf. However the following function:
    f(x,y)= leftegin rac, & mboxx

    eq0,\
    0, & mbox x=0
    end
    ight.
    has finite directional derivatives in all directions at left(0,0
    ight), and therefore has all partial derivatives at the origin. However it is not continuous at the origin since it has value rac at every point on the parabola x = y^2, except at the origin, where it has value 0. It therefore does not possess a differential at the origin.

    top

    Confusion
    It is common for math students (especially first year calculus students) to confuse differential and derivative. Although they sound similar, the mathematic meanings are distinct.

    Although in some cases certain algebraic functions such as cancellation in fractions are applicable to differentials, it is important not to carry this convenient property too far. Differentials are not numbers (or variables) and cannot always be treated as numbers. Differentials have the same unit as the variable they are associated with.

    top

    History
    Differentials were essential to the development of calculus and were discovered in the same time frame. However, the math innovation that made differentials more apparent and visible was Leibniz notation.

    top

    See also




     
    Search more:
     

       
    Source Privacy License Download Contact Us Atlas
    Scientus.org Dictionary (Yet Another Wiki) RC : 1.39
    MIT OpenCourseWare
    This article is licensed under the GNU Free Documentation License [copyleft]. It uses material from the Wikipedia article "Differential (calculus)". link