amnet: Adaptive MCP-Net

Description Usage Arguments Value Author(s) Examples

View source: R/amnet.R

Description

Adaptive MCP-Net

Usage

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amnet(x, y, family = c("gaussian", "binomial", "poisson", "cox"),
  init = c("mnet", "ridge"), gammas = 3, alphas = seq(0.05, 0.95, 0.05),
  tune = c("cv", "ebic", "bic", "aic"), nfolds = 5L, ebic.gamma = 1,
  scale = 1, eps = 1e-04, max.iter = 10000L, seed = 1001,
  parallel = FALSE, verbose = FALSE)

Arguments

x

Data matrix.

y

Response vector if family is "gaussian", "binomial", or "poisson". If family is "cox", a response matrix created by Surv.

family

Model family, can be "gaussian", "binomial", "poisson", or "cox".

init

Type of the penalty used in the initial estimation step. Can be "mnet" or "ridge".

gammas

Vector of candidate gammas (the concavity parameter) to use in MCP-Net. Default is 3.

alphas

Vector of candidate alphas to use in MCP-Net.

tune

Parameter tuning method for each estimation step. Possible options are "cv", "ebic", "bic", and "aic". Default is "cv".

nfolds

Fold numbers of cross-validation when tune = "cv".

ebic.gamma

Parameter for Extended BIC penalizing size of the model space when tune = "ebic", default is 1. For details, see Chen and Chen (2008).

scale

Scaling factor for adaptive weights: weights = coefficients^(-scale).

eps

Convergence threshhold to use in MCP-net.

max.iter

Maximum number of iterations to use in MCP-net.

seed

Random seed for cross-validation fold division.

parallel

Logical. Enable parallel parameter tuning or not, default is FALSE. To enable parallel tuning, load the doParallel package and run registerDoParallel() with the number of CPU cores before calling this function.

verbose

Should we print out the estimation progress?

Value

List of model coefficients, ncvreg model object, and the optimal parameter set.

Author(s)

Nan Xiao <https://nanx.me>

Examples

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dat = msaenet.sim.gaussian(
  n = 150, p = 500, rho = 0.6,
  coef = rep(1, 5), snr = 2, p.train = 0.7,
  seed = 1001)

amnet.fit = amnet(
  dat$x.tr, dat$y.tr,
  alphas = seq(0.2, 0.8, 0.2), seed = 1002)

print(amnet.fit)
msaenet.nzv(amnet.fit)
msaenet.fp(amnet.fit, 1:5)
msaenet.tp(amnet.fit, 1:5)
amnet.pred = predict(amnet.fit, dat$x.te)
msaenet.rmse(dat$y.te, amnet.pred)
plot(amnet.fit)

msaenet documentation built on May 14, 2018, 9:04 a.m.