splinefun package:stats R Documentation _I_n_t_e_r_p_o_l_a_t_i_n_g _S_p_l_i_n_e_s _D_e_s_c_r_i_p_t_i_o_n: Perform cubic (or Hermite) spline interpolation of given data points, returning either a list of points obtained by the interpolation or a _function_ performing the interpolation. _U_s_a_g_e: splinefun(x, y = NULL, method = c("fmm", "periodic", "natural", "monoH.FC"), ties = mean) spline(x, y = NULL, n = 3*length(x), method = "fmm", xmin = min(x), xmax = max(x), xout, ties = mean) splinefunH(x, y, m) _A_r_g_u_m_e_n_t_s: x,y: vectors giving the coordinates of the points to be interpolated. Alternatively a single plotting structure can be specified: see 'xy.coords.' m: (for 'splinefunH()'): vector of _slopes_ m[i] at the points (x[i],y[i]); these together determine the *H*ermite "spline" which is piecewise cubic, (only) _once_ differentiable continuously. method: specifies the type of spline to be used. Possible values are '"fmm"', '"natural"', '"periodic"' and '"monoH.FC"'. n: if 'xout' is left unspecified, interpolation takes place at 'n' equally spaced points spanning the interval ['xmin', 'xmax']. xmin, xmax: left-hand and right-hand endpoint of the interpolation interval (when 'xout' is unspecified). xout: an optional set of values specifying where interpolation is to take place. ties: Handling of tied 'x' values. Either a function with a single vector argument returning a single number result or the string '"ordered"'. _D_e_t_a_i_l_s: The inputs can contain missing values which are deleted, so at least one complete '(x, y)' pair is required. If 'method = "fmm"', the spline used is that of Forsythe, Malcolm and Moler (an exact cubic is fitted through the four points at each end of the data, and this is used to determine the end conditions). Natural splines are used when 'method = "natural"', and periodic splines when 'method = "periodic"'. The new (R 2.8.0) method '"monoH.FC"' computes a _monotone_ Hermite spline according to the method of Fritsch and Carlson. It does so by determining slopes such that the Hermite spline, determined by (x[i],y[i],m[i]), is monotone (increasing or decreasing) *iff* the data are. These interpolation splines can also be used for extrapolation, that is prediction at points outside the range of 'x'. Extrapolation makes little sense for 'method = "fmm"'; for natural splines it is linear using the slope of the interpolating curve at the nearest data point. _V_a_l_u_e: 'spline' returns a list containing components 'x' and 'y' which give the ordinates where interpolation took place and the interpolated values. 'splinefun' returns a function with formal arguments 'x' and 'deriv', the latter defaulting to zero. This function can be used to evaluate the interpolating cubic spline ('deriv'=0), or its derivatives ('deriv'=1,2,3) at the points 'x', where the spline function interpolates the data points originally specified. This is often more useful than 'spline'. _R_e_f_e_r_e_n_c_e_s: Becker, R. A., Chambers, J. M. and Wilks, A. R. (1988) _The New S Language_. Wadsworth & Brooks/Cole. Forsythe, G. E., Malcolm, M. A. and Moler, C. B. (1977) _Computer Methods for Mathematical Computations_. Fritsch, F. N. and Carlson, R. E. (1980) Monotone piecewise cubic interpolation, _SIAM Journal on Numerical Analysis_ *17*, 238-246. _S_e_e _A_l_s_o: 'approx' and 'approxfun' for constant and linear interpolation. Package 'splines', especially 'interpSpline' and 'periodicSpline' for interpolation splines. That package also generates spline bases that can be used for regression splines. 'smooth.spline' for smoothing splines. _E_x_a_m_p_l_e_s: require(graphics) op <- par(mfrow = c(2,1), mgp = c(2,.8,0), mar = .1+c(3,3,3,1)) n <- 9 x <- 1:n y <- rnorm(n) plot(x, y, main = paste("spline[fun](.) through", n, "points")) lines(spline(x, y)) lines(spline(x, y, n = 201), col = 2) y <- (x-6)^2 plot(x, y, main = "spline(.) -- 3 methods") lines(spline(x, y, n = 201), col = 2) lines(spline(x, y, n = 201, method = "natural"), col = 3) lines(spline(x, y, n = 201, method = "periodic"), col = 4) legend(6,25, c("fmm","natural","periodic"), col=2:4, lty=1) y <- sin((x-0.5)*pi) f <- splinefun(x, y) ls(envir = environment(f)) splinecoef <- get("z", envir = environment(f)) curve(f(x), 1, 10, col = "green", lwd = 1.5) points(splinecoef, col = "purple", cex = 2) curve(f(x, deriv=1), 1, 10, col = 2, lwd = 1.5) curve(f(x, deriv=2), 1, 10, col = 2, lwd = 1.5, n = 401) curve(f(x, deriv=3), 1, 10, col = 2, lwd = 1.5, n = 401) par(op) ## Manual spline evaluation --- demo the coefficients : .x <- splinecoef$x u <- seq(3,6, by = 0.25) (ii <- findInterval(u, .x)) dx <- u - .x[ii] f.u <- with(splinecoef, y[ii] + dx*(b[ii] + dx*(c[ii] + dx* d[ii]))) stopifnot(all.equal(f(u), f.u)) ## An example with ties (non-unique x values): set.seed(1); x <- round(rnorm(30), 1); y <- sin(pi * x) + rnorm(30)/10 plot(x,y, main="spline(x,y) when x has ties") lines(spline(x,y, n= 201), col = 2) ## visualizes the non-unique ones: tx <- table(x); mx <- as.numeric(names(tx[tx > 1])) ry <- matrix(unlist(tapply(y, match(x,mx), range, simplify=FALSE)), ncol=2, byrow=TRUE) segments(mx, ry[,1], mx, ry[,2], col = "blue", lwd = 2) ## An example of monotone interpolation n <- 20 set.seed(11) x. <- sort(runif(n)) ; y. <- cumsum(abs(rnorm(n))) plot(x.,y.) curve(splinefun(x.,y.)(x), add=TRUE, col=2, n=1001) curve(splinefun(x.,y., method="mono")(x), add=TRUE, col=3, n=1001) legend("topleft", paste("splinefun( \"", c("fmm", "monoH.CS"), "\" )", sep=''), col=2:3, lty=1)