#' @title Compute \eqn{\delta_k}
#' @description Compute \eqn{\delta_k} for given vector \eqn{v} and matrix \eqn{Q}.
#'
#' @param Q The given tridiagonal matrix.
#' @param v The column vector on the right hand of equation.
#' @return A list of \eqn{\delta_k} for given vector \eqn{v} and matrix \eqn{Q}.
#'
#' @examples
#' a = c(1:7)^2
#' b = c(1:7)^2
#' c = rep(0, length(a) + 1)
#' c[length(a) + 1] = 8^2
#' N = length(a)
#' Q = tridiag(b, a, -c(b[1] + c[1], a[1:N - 1] + b[2:N] + c[2:N], a[N] + c[N + 1]))
#' find_deltak(Q, v=rep(1,dim(Q)[1]))
#' @export
find_deltak = function(Q, v) {
N = dim(Q)[1] - 1
indx <- seq.int(N)
a = Q[cbind(indx + 1, indx)]
b = c(Q[cbind(indx, indx + 1)], -Q[N + 1, N + 1] - Q[N + 1, N])
if (sum(b[1:N] != a) == 0) {
mu = rep(1, N + 1)
} else {
mu = rep(1, N + 1)
mu[2:(N + 1)] = cumprod(b[1:N]/a)
}
phi = rev(cumsum(rev(1/(mu * b))))
deltapart1 = mu * v
deltapart1sum = cumsum(deltapart1)
deltapart2 = mu * phi * v
deltapart2sum = rev(cumsum(rev(deltapart2)))
delta1 = rep(NA, N + 1)
delta1 = phi[1:N] * deltapart1sum[1:N] + deltapart2sum[2:(N + 1)]
delta1[N + 1] = phi[N + 1] * deltapart1sum[N + 1]
deltak = max(delta1/v)
deltak_prime = min(delta1/v)
return(list(deltak = deltak, deltak_prime = deltak_prime))
}
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