| summary.fptl {fptdApprox} | R Documentation |
Locating a Conditioned First-Passage-Time Variable
Description
summary.fptl summary method for class “fptl”.
is.summary.fptl tests if its argument is an object of class “summary.fptl”.
print.summary.fptl shows an object of class “summary.fptl”.
Usage
## S3 method for class 'fptl'
summary(object, zeroSlope = 0.01, p0.tol = 8, k = 3, ...)
is.summary.fptl(obj)
## S3 method for class 'summary.fptl'
print(x, ...)
Arguments
object |
an object of class ‘fptl’, a result of a call to |
obj |
an R object to be tested. |
x |
an object of class ‘summary.fptl’, a result of a call to |
zeroSlope |
maximum slope required to consider that a growing function is constant. |
p0.tol |
controls where the First-Passage-Time Location function begins to increase significantly. |
k |
controls whether the First-Passage-Time Location function decreases very slowly. |
... |
other arguments passed to functions. |
Details
The summary.fptl function extracts the information contained in object about the
location of the variation range of a conditioned first-passage-time (f.p.t.) variable.
It makes an internal call to growth.intervals function in order to determine the time instants
t_i, \ i=1, \ldots, m, from which the First-Passage-Time Location (FPTL)
function starts growing, and its local maximums t_{max,i}. For this, zeroSlope argument
is considered.
If there is no growth subinterval, the execution of the function summary.fptl is stopped and an error is reported.
Otherwise, for each of the subintervals I_{i} = [t_{i},t_{i+1}] the function determines:
The first time instant
t_i^* \in [t_i, t_{max,i}]at which the function is bigger than or equal top_i^* = p_i + 10^{-p0.tol}(p_{max,i} - p_i) \ ,where
p_i = FPTL(t_i)andp_{max,i} = FPTL(t_{max,i}) \ .
10^{-p0.tol}is the ratio of the global increase of the function in the growth subinterval[t_i, t_{max,i}]that should be reached to consider that it begins to increase significantly.The first time instant
t_{max,i}^{-} \in [t_i, t_{max,i}]at which the FPTL function is bigger than or equal top_{max,i}^{-} = p_{max,i} \big( 1 - 0.05(p_{max,i} - p_i) \big) \ .The last time instant
t_{max,i}^{+} \in \big[ t_{max,i}, \thinspace T_i \big]at which the FPTL function is bigger than or equal top_{max,i}^{+} = max \left\{ 1 - (1 - p_{max,i}^2)^{(1+q)/2}, FPTL(T_i) \right\},where
T_i = min \big\{ t_{max,i} + k \thinspace (t_{max,i}-t_i^*)(1 - p_{max,i}), \thinspace t_{i+1} \big\}and
q = \displaystyle{\frac{p_{max,i} - p_i}{p_{max,i}}} \ .
print.summary.fptl displays an object of class “summary.fptl” for immediate understanding of the information it contains.
Value
The summary.fptl function computes and returns an object of class “summary.fptl” and length 1.
An object of class “summary.fptl” is a list of length 1 for a conditioned f.p.t problem, or of the same length as the number of
values selected from the non-degenerate initial distribution for an unconditioned f.p.t problem.
Each component of the list is again a named list with two components:
instants |
a matrix whose columns correspond to |
FPTLValues |
the matrix of values of the FPTL function on |
It also includes four additional attributes:
Call | a list of the unevaluated calls to the summary.fptl function, substituting each name |
| in these calls by its value when the latter has length 1. | |
FPTLCall | a list of the unevaluated calls to the FPTL function that resulted in the objects |
used as object argument in Call. |
|
dp | the common object used as dp argument in the unevaluated calls to the FPTL |
function in FPTLCall. |
|
vars | NULL or a list containing the common values of names in FPTLCall for those names |
| with values of length greater than 1. | |
For an unconditioned f.p.t problem, the object includes the additional attribute id specifying the non-degenerate initial distribution.
The attribute “summary.fptl” of the value (of class “fpt.density”) of the Approx.fpt.density function is
an object of class summary.fptl of length 1 for a conditioned problem, and of length greather than 1 for an unconditioned problem.
It is created from one or successive internal calls to the summary.fptl function.
is.summary.fptl returns TRUE or FALSE depending on whether its argument is an object of class
“summary.fptl” or not.
Author(s)
Patricia Román-Román, Juan J. Serrano-Pérez and Francisco Torres-Ruiz.
References
Román, P., Serrano, J. J., Torres, F. (2008) First-passage-time location function: Application to determine first-passage-time densities in diffusion processes. Comput. Stat. Data Anal., 52, 4132–4146.
P. Román-Román, J.J. Serrano-Pérez, F. Torres-Ruiz. (2012) An R package for an efficient approximation of first-passage-time densities for diffusion processes based on the FPTL function. Applied Mathematics and Computation, 218, 8408–8428.
P. Román-Román, J.J. Serrano-Pérez, F. Torres-Ruiz. (2014) More general problems on first-passage times for diffusion processes: A new version of the fptdApprox R package. Applied Mathematics and Computation, 244, 432–446.
See Also
Approx.cfpt.density to approximate densities of f.p.t. variables conditioned to a fixed initial value
from objects of class “summary.fptl” and create objects of class “fpt.density”.
Approx.fpt.density to approximate densities of conditioned or unconditioned f.p.t. variables and create objects of
class “fpt.density” from objects of class “dp”.
FPTL to evaluate the FPTL function and create objects of class “fptl”.
report.summary.fptl to generate a report.
growth.intervals to study the growth of the vector of values resulting from the evaluation of a function.
Examples
## Continuing the FPTL(.) example:
## Summarizing an object of class fptl
yy <- summary(y)
yy
print(yy, digits=10)
yy1 <- summary(y, zeroSlope = 0.001)
yy1
yy2 <- summary(y, zeroSlope = 0.001, p0.tol = 10)
yy2
zz <- summary(z)
zz
## Testing summary.fptl objects
is.summary.fptl(yy)
is.summary.fptl(zz)