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Data:
112.7 122 134.7 109.8 130.8 118.7 104.4 87.8 134.2 143.9 140.4 111 126.3 124.4 136.1 118.4 127.4 127.9 115 90.2 131 143.3 131.5 98.5 124.9 122.4 128.8 125.9 120.2 120 116 89.2 135.9 148.7 128.1 100.9 125.5 119.8 120.7 125 109 114.2 105.6 80.1 131.1 136.6 119.7 102.4 114.5 112.9 131.8 118.7 107.1 127 104.6 85.9 134 127.6 121.5 104.5 107.3 111.9 120.7 116.9 106.1 122.3 97.8 82.7 128.2 119 127.4 106 108.7 113.5 131.4 111.3 119 130.7 104.5 88.9 135.4 140.6 138.8 107.4 120.8 124.1 139.2 119.9 121 133.7 115.2 96.7 131 147.6 132.9 97.4 123.6 124.9 118.6 127.6 110.2 115.4 106.6 75.5 116.7 118 98.7 81.5 87 86.8 96.8 92.7 82.1 94.1 89.7 67.5 102 103.2 95.6 83 87.2 94 107.7 103.3 94.8 112.7 96.8 75.9 116.7 111.4 108.6 90.9 92.6 95.7 116.7 95.4 105.1 99.7 89.8 74 108 102.1 100.2 83.2 87.9 93.3 98.5 84.5 89.3 94.2 83.5 67.5 89.4 102.4 92 65.9 85.3 87 91.8 88.5 89.1 89.8 88.9 64 93.2 100.1 89.3 68.1 94.3 93.3 98.1 96.8 87.8 95.6 95.7 64.4 108.1 109.6 90.9 75.6 93.5 98.1 104.5 102.7 89.6 108.8 95.4 70.1 104.6 105.5 96.8 79.4 92.3 96.8 103 99.5 91 103.4 82 70.1 98.1 95.7 98 77.3 89.8 91.6 106.5 87.5 99.5 104.4 84.5 68.3
Seasonal period
12
12
1
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9
10
11
12
Number of Forecasts
12
12
1
2
3
4
5
6
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9
10
11
12
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14
15
16
17
18
Algorithm
BFGS
BFGS
L-BFGS-B
Chart options
R Code
require('stsm') require('stsm.class') require('KFKSDS') par1 <- as.numeric(par1) par2 <- as.numeric(par2) nx <- length(x) x <- ts(x,frequency=par1) m <- StructTS(x,type='BSM') print(m$coef) print(m$fitted) print(m$resid) mylevel <- as.numeric(m$fitted[,'level']) myslope <- as.numeric(m$fitted[,'slope']) myseas <- as.numeric(m$fitted[,'sea']) myresid <- as.numeric(m$resid) myfit <- mylevel+myseas mm <- stsm.model(model = 'BSM', y = x, transPars = 'StructTS') fit2 <- stsmFit(mm, stsm.method = 'maxlik.td.optim', method = par3, KF.args = list(P0cov = TRUE)) (fit2.comps <- tsSmooth(fit2, P0cov = FALSE)$states) m2 <- set.pars(mm, pmax(fit2$par, .Machine$double.eps)) (ss <- char2numeric(m2)) (pred <- predict(ss, x, n.ahead = par2)) mylagmax <- nx/2 bitmap(file='test2.png') op <- par(mfrow = c(2,2)) acf(as.numeric(x),lag.max = mylagmax,main='Observed') acf(mylevel,na.action=na.pass,lag.max = mylagmax,main='Level') acf(myseas,na.action=na.pass,lag.max = mylagmax,main='Seasonal') acf(myresid,na.action=na.pass,lag.max = mylagmax,main='Standardized Residals') par(op) dev.off() bitmap(file='test3.png') op <- par(mfrow = c(2,2)) spectrum(as.numeric(x),main='Observed') spectrum(mylevel,main='Level') spectrum(myseas,main='Seasonal') spectrum(myresid,main='Standardized Residals') par(op) dev.off() bitmap(file='test4.png') op <- par(mfrow = c(2,2)) cpgram(as.numeric(x),main='Observed') cpgram(mylevel,main='Level') cpgram(myseas,main='Seasonal') cpgram(myresid,main='Standardized Residals') par(op) dev.off() bitmap(file='test1.png') plot(as.numeric(m$resid),main='Standardized Residuals',ylab='Residuals',xlab='time',type='b') grid() dev.off() bitmap(file='test5.png') op <- par(mfrow = c(2,2)) hist(m$resid,main='Residual Histogram') plot(density(m$resid),main='Residual Kernel Density') qqnorm(m$resid,main='Residual Normal QQ Plot') qqline(m$resid) plot(m$resid^2, myfit^2,main='Sq.Resid vs. Sq.Fit',xlab='Squared residuals',ylab='Squared Fit') par(op) dev.off() bitmap(file='test6.png') par(mfrow = c(3,1), mar = c(3,3,3,3)) plot(cbind(x, pred$pred), type = 'n', plot.type = 'single', ylab = '') lines(x) polygon(c(time(pred$pred), rev(time(pred$pred))), c(pred$pred + 2 * pred$se, rev(pred$pred)), col = 'gray85', border = NA) polygon(c(time(pred$pred), rev(time(pred$pred))), c(pred$pred - 2 * pred$se, rev(pred$pred)), col = ' gray85', border = NA) lines(pred$pred, col = 'blue', lwd = 1.5) mtext(text = 'forecasts of the observed series', side = 3, adj = 0) plot(cbind(x, pred$a[,1]), type = 'n', plot.type = 'single', ylab = '') lines(x) polygon(c(time(pred$a[,1]), rev(time(pred$a[,1]))), c(pred$a[,1] + 2 * sqrt(pred$P[,1]), rev(pred$a[,1])), col = 'gray85', border = NA) polygon(c(time(pred$a[,1]), rev(time(pred$a[,1]))), c(pred$a[,1] - 2 * sqrt(pred$P[,1]), rev(pred$a[,1])), col = ' gray85', border = NA) lines(pred$a[,1], col = 'blue', lwd = 1.5) mtext(text = 'forecasts of the level component', side = 3, adj = 0) plot(cbind(fit2.comps[,3], pred$a[,3]), type = 'n', plot.type = 'single', ylab = '') lines(fit2.comps[,3]) polygon(c(time(pred$a[,3]), rev(time(pred$a[,3]))), c(pred$a[,3] + 2 * sqrt(pred$P[,3]), rev(pred$a[,3])), col = 'gray85', border = NA) polygon(c(time(pred$a[,3]), rev(time(pred$a[,3]))), c(pred$a[,3] - 2 * sqrt(pred$P[,3]), rev(pred$a[,3])), col = ' gray85', border = NA) lines(pred$a[,3], col = 'blue', lwd = 1.5) mtext(text = 'forecasts of the seasonal component', side = 3, adj = 0) dev.off() load(file='createtable') a<-table.start() a<-table.row.start(a) a<-table.element(a,'Structural Time Series Model -- Interpolation',6,TRUE) a<-table.row.end(a) a<-table.row.start(a) a<-table.element(a,'t',header=TRUE) a<-table.element(a,'Observed',header=TRUE) a<-table.element(a,'Level',header=TRUE) a<-table.element(a,'Slope',header=TRUE) a<-table.element(a,'Seasonal',header=TRUE) a<-table.element(a,'Stand. Residuals',header=TRUE) a<-table.row.end(a) for (i in 1:nx) { a<-table.row.start(a) a<-table.element(a,i,header=TRUE) a<-table.element(a,x[i]) a<-table.element(a,mylevel[i]) a<-table.element(a,myslope[i]) a<-table.element(a,myseas[i]) a<-table.element(a,myresid[i]) a<-table.row.end(a) } a<-table.end(a) table.save(a,file='mytable.tab') a<-table.start() a<-table.row.start(a) a<-table.element(a,'Structural Time Series Model -- Extrapolation',4,TRUE) a<-table.row.end(a) a<-table.row.start(a) a<-table.element(a,'t',header=TRUE) a<-table.element(a,'Observed',header=TRUE) a<-table.element(a,'Level',header=TRUE) a<-table.element(a,'Seasonal',header=TRUE) a<-table.row.end(a) for (i in 1:par2) { a<-table.row.start(a) a<-table.element(a,i,header=TRUE) a<-table.element(a,pred$pred[i]) a<-table.element(a,pred$a[i,1]) a<-table.element(a,pred$a[i,3]) a<-table.row.end(a) } a<-table.end(a) table.save(a,file='mytable1.tab')
Compute
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Raw Input
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Raw Output
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Computing time
1 seconds
R Server
Big Analytics Cloud Computing Center
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