samEL: Training function of Sparse Additive Possion Regression
In HMJiangGatech/sam: Sparse Additive Modelling

samEL

R Documentation

Training function of Sparse Additive Possion Regression

Description

The log-linear model is learned using training data.

Usage

samEL(
  X,
  y,
  p = 3,
  lambda = NULL,
  nlambda = NULL,
  lambda.min.ratio = 0.25,
  thol = 1e-05,
  max.ite = 1e+05,
  regfunc = "L1"
)

Arguments

`X`	The `n` by `d` design matrix of the training set, where `n` is sample size and `d` is dimension.
`y`	The `n`-dimensional response vector of the training set, where `n` is sample size. Responses must be non-negative integers.
`p`	The number of basis spline functions. The default value is 3.
`lambda`	A user supplied lambda sequence. Typical usage is to have the program compute its own lambda sequence based on nlambda and lambda.min.ratio. Supplying a value of lambda overrides this. WARNING: use with care. Do not supply a single value for lambda. Supply instead a decreasing sequence of lambda values. samEL relies on its warms starts for speed, and its often faster to fit a whole path than compute a single fit.
`nlambda`	The number of lambda values. The default value is 20.
`lambda.min.ratio`	Smallest value for lambda, as a fraction of lambda.max, the (data derived) entry value (i.e. the smallest value for which all coefficients are zero). The default is 0.1.
`thol`	Stopping precision. The default value is 1e-5.
`max.ite`	The number of maximum iterations. The default value is 1e5.
`regfunc`	A string indicating the regularizer. The default value is "L1". You can also assign "MCP" or "SCAD" to it.

Details

We adopt various computational algorithms including the block coordinate descent, fast iterative soft-thresholding algorithm, and newton method. The computation is further accelerated by "warm-start" and "active-set" tricks.

Value

`p`	The number of basis spline functions used in training.
`X.min`	A vector with each entry corresponding to the minimum of each input variable. (Used for rescaling in testing)
`X.ran`	A vector with each entry corresponding to the range of each input variable. (Used for rescaling in testing)
`lambda`	A sequence of regularization parameter used in training.
`w`	The solution path matrix (`dp+1` by length of `lambda`) with each column corresponding to a regularization parameter. Since we use the basis expansion with the intercept, the length of each column is `dp+1`.
`df`	The degree of freedom of the solution path (The number of non-zero component function)
`knots`	The `p-1` by `d` matrix. Each column contains the knots applied to the corresponding variable.
`Boundary.knots`	The `2` by `d` matrix. Each column contains the boundary points applied to the corresponding variable.
`func_norm`	The functional norm matrix (`d` by length of `lambda`) with each column corresponds to a regularization parameter. Since we have `d` input variables, the length of each column is `d`.

Examples


## generating training data
n = 200
d = 100
X = 0.5*matrix(runif(n*d),n,d) + matrix(rep(0.5*runif(n),d),n,d)
u = exp(-2*sin(X[,1]) + X[,2]^2-1/3 + X[,3]-1/2 + exp(-X[,4])+exp(-1)-1+1)
y = rep(0,n)
for(i in 1:n) y[i] = rpois(1,u[i])

## Training
out.trn = samEL(X,y)
out.trn

## plotting solution path
plot(out.trn)

## generating testing data
nt = 1000
Xt = 0.5*matrix(runif(nt*d),nt,d) + matrix(rep(0.5*runif(nt),d),nt,d)
ut = exp(-2*sin(Xt[,1]) + Xt[,2]^2-1/3 + Xt[,3]-1/2 + exp(-Xt[,4])+exp(-1)-1+1)
yt = rep(0,nt)
for(i in 1:nt) yt[i] = rpois(1,ut[i])

## predicting response
out.tst = predict(out.trn,Xt)

HMJiangGatech/sam documentation built on April 24, 2022, 9:08 p.m.