Mixture Model Identification using Segmented Regression

Description

This function uses piecewise linear regression to divide the data into subgroups. See 'Details'.

Usage

## Default S3 method:
mixmod_regression(
  x,
  y,
  status,
  distribution = c("weibull", "lognormal", "loglogistic"),
  conf_level = 0.95,
  k = 2,
  control = segmented::seg.control(),
  ...
)

Arguments

Details

The segmentation process is based on the lifetime realizations of failed units and their corresponding estimated failure probabilities for which intact items are taken into account. It is performed with the support of segmented.lm.

Segmentation can be done with a specified number of subgroups or in an automated fashion (see argument k). The algorithm tends to overestimate the number of breakpoints when the separation is done automatically (see 'Warning' in segmented.lm).

In the context of reliability analysis it is important that the main types of failures can be identified and analyzed separately. These are

• early failures,

• random failures and

• wear-out failures.

In order to reduce the risk of overestimation as well as being able to consider the main types of failures, a maximum of three subgroups (k = 3) is recommended.

Value

A list with classes wt_model and wt_rank_regression if no breakpoint was detected. See rank_regression. The returned tibble data is of class wt_cdf_estimation and contains the dummy columns cdf_estimation_method and id. The former is filled with NA_character, due to internal usage and the latter is filled with "XXXXXX" to point out that unit identification is not possible when using the vector-based approach.

A list with classes wt_model and wt_mixmod_regression if at least one breakpoint was determined. The length of the list depends on the number of identified subgroups. Each list contains the information provided by rank_regression. The returned tibble data of each list element only retains information on the failed units and has modified and additional columns:

• id : Modified id, overwritten with "XXXXXX" to point out that unit identification is not possible when using the vector-based approach.

• cdf_estimation_method : A character that is always NA_character. Only needed for internal use.

• q : Quantiles of the standard distribution calculated from column prob.

• group : Membership to the respective segment.

References

Doganaksoy, N.; Hahn, G.; Meeker, W. Q., Reliability Analysis by Failure Mode, Quality Progress, 35(6), 47-52, 2002

See Also

mixmod_regression

Examples

# Vectors:
## Data for mixture model:
hours <- voltage$hours
status <- voltage$status

## Data for simple unimodal distribution:
distance <- shock$distance
status_2 <- shock$status

# Probability estimation with one method:
prob_mix <- estimate_cdf(
  x = hours,
  status = status,
  method = "johnson"
)

prob <- estimate_cdf(
  x = distance,
  status = status_2,
  method = "johnson"
)

 # Example 1 - Mixture identification using k = 2 two-parametric Weibull models:
mix_mod_weibull <- mixmod_regression(
   x = prob_mix$x,
   y = prob_mix$prob,
   status = prob_mix$status,
   distribution = "weibull",
   conf_level = 0.99,
   k = 2
)

# Example 2 - Mixture identification using k = 3 two-parametric lognormal models:
mix_mod_lognorm <- mixmod_regression(
   x = prob_mix$x,
   y = prob_mix$prob,
   status = prob_mix$status,
   distribution = "lognormal",
   k = 3
)

# Example 3 - Mixture identification using control argument:
mix_mod_control <- mixmod_regression(
  x = prob_mix$x,
  y = prob_mix$prob,
  status = prob_mix$status,
  distribution = "weibull",
  k = 2,
  control = segmented::seg.control(display = TRUE)
)

# Example 4 - Mixture identification performs rank_regression for k = 1:
mod <- mixmod_regression(
  x = prob$x,
  y = prob$prob,
  status = prob$status,
  distribution = "weibull",
  k = 1
)