[talweg.git] / pkg / R / Forecaster.R

#' Forecaster
#'
#' Forecaster (abstract class, implemented by all forecasters).
#'
#' A Forecaster object encapsulates parameters (which can be of various kinds, for
#' example "Neighbors" method stores informations about the considered neighborhood for
#' the current prediction task) and one main function: \code{predictSerie()}. This last
#' function (by default) calls \code{predictShape()} to get a forecast of a centered
#' serie, and then calls the "jump prediction" function -- see "field" section -- to
#' adjust it based on the last observed values.
#'
#' @usage # Forecaster$new(pjump) #warning: predictShape() is unimplemented
#'
#' @field .params List of computed parameters (if applicable).
#' @field .pjump Function: how to predict the jump at day interface? The arguments of
#'   this function are -- in this order:
#'   \itemize{
#'     \item data : object output of \code{getData()},
#'     \item today : index (integer or date) of the last known day in data,
#'     \item memory : number of days to use in the past (including today),
#'     \item horizon : number of time steps to predict,
#'     \item params : optimized parameters in the main method \code{predictShape()},
#'     \item ... : additional arguments.
#'   }
#'   .pjump returns an estimation of the jump after the last observed value.
#'
#' @section Methods:
#' \describe{
#' \item{\code{initialize(data, pjump)}}{
#'   Initialize a Forecaster object with a Data object and a jump prediction function.}
#' \item{\code{predictSerie(today,memory,horizon,...)}}{
#'   Predict a new serie of \code{horizon} values at day index \code{today} using
#'   \code{memory} days in the past.}
#' \item{\code{predictShape(today,memory,horizon,...)}}{
#'   Predict a new shape of \code{horizon} values at day index \code{today} using
#'   \code{memory} days in the past.}
#' \item{\code{getParameters()}}{
#'   Return (internal) parameters.}
#' }
#'
#' @docType class
#' @format R6 class
#'
Forecaster = R6::R6Class("Forecaster",
	private = list(
		.params = list(),
		.pjump = NULL
	),
	public = list(
		initialize = function(pjump)
		{
			private$.pjump <- pjump
			invisible(self)
		},
		predictSerie = function(data, today, memory, horizon, ...)
		{
			# Parameters (potentially) computed during shape prediction stage
			predicted_shape = self$predictShape(data, today, memory, horizon, ...)
			predicted_delta = private$.pjump(data,today,memory,horizon,private$.params,...)
			# Predicted shape is aligned it on the end of current day + jump
			predicted_shape+tail(data$getSerie(today),1)-predicted_shape[1]+predicted_delta
		},
		predictShape = function(data, today, memory, horizon, ...)
			NULL #empty default implementation: to implement in inherited classes
		,
		getParameters = function()
			private$.params
	)
)
Commit	Line	Data
	1	#' Forecaster
	2	#'
	3	#' Forecaster (abstract class, implemented by all forecasters).
	4	#'
	5	#' A Forecaster object encapsulates parameters (which can be of various kinds, for
	6	#' example "Neighbors" method stores informations about the considered neighborhood for
	7	#' the current prediction task) and one main function: \code{predictSerie()}. This last
	8	#' function (by default) calls \code{predictShape()} to get a forecast of a centered
	9	#' serie, and then calls the "jump prediction" function -- see "field" section -- to
	10	#' adjust it based on the last observed values.
	11	#'
	12	#' @usage # Forecaster$new(pjump) #warning: predictShape() is unimplemented
	13	#'
	14	#' @field .params List of computed parameters (if applicable).
	15	#' @field .pjump Function: how to predict the jump at day interface? The arguments of
	16	#' this function are -- in this order:
	17	#' \itemize{
	18	#' \item data : object output of \code{getData()},
	19	#' \item today : index (integer or date) of the last known day in data,
	20	#' \item memory : number of days to use in the past (including today),
	21	#' \item horizon : number of time steps to predict,
	22	#' \item params : optimized parameters in the main method \code{predictShape()},
	23	#' \item ... : additional arguments.
	24	#' }
	25	#' .pjump returns an estimation of the jump after the last observed value.
	26	#'
	27	#' @section Methods:
	28	#' \describe{
	29	#' \item{\code{initialize(data, pjump)}}{
	30	#' Initialize a Forecaster object with a Data object and a jump prediction function.}
	31	#' \item{\code{predictSerie(today,memory,horizon,...)}}{
	32	#' Predict a new serie of \code{horizon} values at day index \code{today} using
	33	#' \code{memory} days in the past.}
	34	#' \item{\code{predictShape(today,memory,horizon,...)}}{
	35	#' Predict a new shape of \code{horizon} values at day index \code{today} using
	36	#' \code{memory} days in the past.}
	37	#' \item{\code{getParameters()}}{
	38	#' Return (internal) parameters.}
	39	#' }
	40	#'
	41	#' @docType class
	42	#' @format R6 class
	43	#'
	44	Forecaster = R6::R6Class("Forecaster",
	45	private = list(
	46	.params = list(),
	47	.pjump = NULL
	48	),
	49	public = list(
	50	initialize = function(pjump)
	51	{
	52	private$.pjump <- pjump
	53	invisible(self)
	54	},
	55	predictSerie = function(data, today, memory, horizon, ...)
	56	{
	57	# Parameters (potentially) computed during shape prediction stage
	58	predicted_shape = self$predictShape(data, today, memory, horizon, ...)
	59	predicted_delta = private$.pjump(data,today,memory,horizon,private$.params,...)
	60	# Predicted shape is aligned it on the end of current day + jump
	61	predicted_shape+tail(data$getSerie(today),1)-predicted_shape[1]+predicted_delta
	62	},
	63	predictShape = function(data, today, memory, horizon, ...)
	64	NULL #empty default implementation: to implement in inherited classes
	65	,
	66	getParameters = function()
	67	private$.params
	68	)
	69	)