| Time Series Analysis and Control Examples |
A description of each TIMSAC package follows.
Each description includes a list of the programs provided
in the TIMSAC version.
- TIMSAC-72
-
analyzes and controls the feedback systems (for example,
cement kiln process).
Univariate- and multivariate-AR models are employed in this original
TIMSAC package. The final prediction error (FPE) criterion is used
for model selection.
- AUSPEC
estimates the power spectrum by the Blackman-Tukey procedure.
- AUTCOR
computes autocovariance and autocorrelation.
- DECONV
computes the impulse response function.
- FFTCOR
computes autocorrelation and crosscorrelation via the fast Fourier transform.
- FPEAUT
computes AR coefficients and FPE for the univariate AR model.
- FPEC
computes AR coefficients and FPE for the control system or
multivariate AR model.
- MULCOR
computes multiple covariance and correlation.
- MULNOS
computes relative power contribution.
- MULRSP
estimates the rational spectrum for multivariate data.
- MULSPE
estimates the cross spectrum by Blackman-Tukey procedure.
- OPTDES
performs optimal controller design.
- OPTSIM
performs optimal controller simulation.
- RASPEC
estimates the rational spectrum for univariate data.
- SGLFRE
computes the frequency response function.
- WNOISE
performs white noise simulation.
- TIMSAC-74
-
estimates and forecasts the univariate and multivariate ARMA models
by fitting
the canonical Markovian model.
A locally stationary autoregressive model is also analyzed.
Akaike's information criterion (AIC) is used for model selection.
- AUTARM
performs automatic univariate ARMA model fitting.
- BISPEC
computes bispectrum.
- CANARM
performs univariate canonical correlation analysis.
- CANOCA
performs multivariate canonical correlation analysis.
- COVGEN
computes the covariance from gain function.
- FRDPLY
plots the frequency response function.
- MARKOV
performs automatic multivariate ARMA model fitting.
- NONST
estimates the locally stationary AR model.
- PRDCTR
performs ARMA model prediction.
- PWDPLY
plots the power spectrum.
- SIMCON
performs optimal controller design and simulation.
- THIRMO
computes the third-order moment.
- TIMSAC-78
-
uses the Householder transformation to estimate the
time series models. This package also contains Bayesian modeling
and the exact maximum likelihood estimation of the ARMA model.
Minimum AIC or Akaike Bayesian Information Criterion (ABIC) modeling
is extensively used.
- BLOCAR
estimates the locally stationary univariate AR model using
the Bayesian method.
- BLOMAR
estimates the locally stationary multivariate AR model
using the Bayesian method.
- BSUBST
estimates the univariate subset regression model using
the Bayesian method.
- EXSAR
estimates the univariate AR model using the exact
maximum likelihood method.
- MLOCAR
estimates the locally stationary univariate AR model using
the minimum AIC method.
- MLOMAR
estimates the locally stationary multivariate AR model
using the minimum AIC method.
- MULBAR
estimates the multivariate AR model using the
Bayesian method.
- MULMAR
estimates the multivariate AR model using the
minimum AIC method.
- NADCON
performs noise adaptive control.
- PERARS
estimates the periodic AR model using the minimum AIC method.
- UNIBAR
estimates the univariate AR model using the Bayesian method.
- UNIMAR
estimates the univariate AR model using the minimum AIC method.
- XSARMA
estimates the univariate ARMA model using the exact maximum
likelihood method.
In addition, the following test subroutines are available:
TSSBST, TSWIND, TSROOT, TSTIMS, and TSCANC.
- TIMSAC-84
-
contains the Bayesian time series modeling procedure, the point process
data analysis, and the seasonal adjustment procedure.
- ADAR
estimates the amplitude dependent AR model.
- BAYSEA
performs Bayesian seasonal adjustments.
- BAYTAP
performs Bayesian tidal analysis.
- DECOMP
performs time series decomposition analysis using
state space modeling.
- EPTREN
estimates intensity rates of either the exponential
polynomial or exponential Fourier series of the nonstationary
Poisson process model.
- LINLIN
estimates linear intensity models of the self-exciting
point process with another process input and with
cyclic and trend components.
- LINSIM
performs simulation of the point process estimated by
the subroutine LINLIN.
- LOCCAR
estimates the locally constant AR model.
- MULCON
performs simulation, control, and prediction of
the multivariate AR model.
- NONSPA
performs nonstationary spectrum analysis using the
minimum Bayesian AIC procedure.
- PGRAPH
performs graphical analysis for point process data.
- PTSPEC
computes periodograms of point process data with
significant bands.
- SIMBVH
performs simulation of bivariate Hawkes' mutually
exciting point process.
- SNDE
estimates the stochastic nonlinear differential equation model.
- TVCAR
estimates the time-varying AR coefficient model using
state space modeling.
Refer to Kitagawa and Akaike (1981) and Ishiguro (1987) for more information
about TIMSAC programs.
Copyright © 1999 by SAS Institute Inc., Cary, NC, USA. All rights reserved.
