deriv                  package:base                  R Documentation

_S_y_m_b_o_l_i_c _a_n_d _A_l_g_o_r_i_t_h_m_i_c _D_e_r_i_v_a_t_i_v_e_s _o_f _S_i_m_p_l_e _E_x_p_r_e_s_s_i_o_n_s

_D_e_s_c_r_i_p_t_i_o_n:

     Compute derivatives of simple expressions, symbolically.

_U_s_a_g_e:

        D (expr, name)
     deriv(expr, namevec, function.arg = NULL, tag = ".expr")

_A_r_g_u_m_e_n_t_s:

    expr: `expression' or `call' which should be differentiated.

name,namevec: character vector, giving the variable names (only one for
          `D(.)') with respect to which derivatives will be computed.

function.arg: If specified, a character vector of arguments for a
          function return. Note: this is incompatible with S.

     tag: character; the prefix to be used for the locally created
          variables in result.

_D_e_t_a_i_l_s:

     `D' is modelled after its S namesake for taking simple symbolic
     derivatives.

     `deriv' is a generic function with a default and a `formula'
     method.  It returns a `call' for computing the `expr' and its
     (partial) derivatives, simultaneously.  It uses so-called
     ``algorithmic derivatives''.

     Currently, `deriv.formula' just calls `deriv.default' after
     extracting the expression to the right of `~'.

_V_a_l_u_e:

     `D' returns a call and therefore can easily be iterated for higher
     derivatives.

     `deriv' normally returns an `expression' object. Its evaluation
     returns the function values with a `".gradient"' attribute
     containing the gradient matrix. If `function.arg' is specified, it
     returns a function.

_N_o_t_e:

     This help page should be fixed up by one of R&R or someone else
     who fluently speaks the language in `$R_HOME/src/main/deriv.c'.

     Its author, MM, has only got a vague idea and thinks that a help
     page is better than none.

_R_e_f_e_r_e_n_c_e_s:

     Griewank, A.  and  Corliss, G. F. (1991) Automatic Differentiation
     of Algorithms: Theory, Implementation, and Application. SIAM
     proceedings, Philadelphia.

_S_e_e _A_l_s_o:

     `nlm' and `optim' for numeric minimization which could make use of
     derivatives, `nls' in package `nls'.

_E_x_a_m_p_l_e_s:

     ## formula argument :
     dx2x <- deriv(~ x^2, "x") ; dx2x
     expression({
              .value <- x^2
              .grad <- array(0, c(length(.value), 1), list(NULL, c("x")))
              .grad[, "x"] <- 2 * x
              attr(.value, "gradient") <- .grad
              .value
     })
     mode(dx2x)
     x <- -1:2
     eval(dx2x)

     ## Something `tougher':
     trig.exp <- expression(sin(cos(x + y^2)))
     ( D.sc <- D(trig.exp, "x") )
     all.equal(D(trig.exp[[1]], "x"), D.sc)

     ( dxy <- deriv(trig.exp, c("x", "y")) )
     y <- 1
     eval(dxy)
     eval(D.sc)
     stopifnot(eval(D.sc) ==
               attr(eval(dxy),"gradient")[,"x"])

     ## function returned:
     deriv(y ~ b0 + b1 * 2^(-x/th), c("b0", "b1", "th"),
          c("b0", "b1", "th", "x") )

     ## Higher derivatives:
     DD <- function(expr,name, order = 1) {
        if(order < 1) stop("`order' must be >= 1")
        if(order == 1) D(expr,name)
        else DD(D(expr, name), name, order - 1)
     }
     DD(expression(sin(x^2)), "x", 3)
     ## showing the limits of the internal "simplify()" :

     -sin(x^2) * (2 * x) * 2 + ((cos(x^2) * (2 * x) * (2 * x) + sin(x^2) *
         2) * (2 * x) + sin(x^2) * (2 * x) * 2)

