Send output to:
Browser Blue - Charts White
Browser Black/White
CSV
Data X:
'f' 'wb' 58 'f' 'wb' 53 'f' 'wb' 59 'f' 'wb' 64 'f' 'wb' 52 'f' 'wb' 65 'f' 'wb' 62 'f' 'wb' 61 'f' 'wb' 61 'f' 'wb' 54 'f' 'wb' 50 'f' 'wb' 63 'f' 'wb' 58 'f' 'wb' 39 'f' 'wb' 71 'f' 'wb' 52 'f' 'wb' 68 'f' 'wb' 56 'f' 'wb' 54 'f' 'wb' 63 'f' 'wb' 54 'f' 'wb' 49 'f' 'wb' 54 'f' 'wb' 75 'f' 'wb' 56 'f' 'wb' 66 'f' 'wb' 78 'f' 'wb' 60 'f' 'wb' 64 'f' 'wb' 64 'f' 'wb' 52 'f' 'wb' 62 'f' 'wb' 55 'f' 'wb' 56 'f' 'wb' 50 'f' 'wb' 50 'f' 'wb' 50 'f' 'wb' 63 'f' 'wb' 61 'f' 'wb' 53 'f' 'wb' 60 'f' 'wb' 56 'f' 'wb' 53 'f' 'wb' 57 'f' 'wb' 57 'f' 'wb' 56 'f' 'wb' 56 'f' 'wb' 50 'f' 'wb' 52 'f' 'wb' 55 'f' 'wb' 55 'f' 'wb' 47 'f' 'wb' 45 'f' 'wb' 62 'f' 'wb' 53 'f' 'wb' 52 'f' 'wb' 57 'f' 'wb' 64 'f' 'wb' 59 'f' 'wb' 55 'f' 'wb' 76 'f' 'wb' 62 'f' 'wb' 68 'f' 'wb' 55 'f' 'wb' 52 'f' 'wb' 47 'f' 'wb' 45 'f' 'wb' 68 'f' 'wb' 44 'f' 'wb' 62 'f' 'wb' 56 'f' 'wb' 50 'f' 'wb' 53 'f' 'wb' 64 'f' 'wb' 62 'f' 'wb' 52 'f' 'wb' 53 'f' 'wb' 54 'f' 'wb' 64 'f' 'wb' 55 'f' 'wb' 55 'f' 'wb' 59 'f' 'wb' 70 'f' 'wb' 57 'f' 'wb' 47 'f' 'wb' 47 'f' 'wb' 55 'f' 'wb' 48 'f' 'wb' 59 'f' 'wb' 58 'f' 'wb' 57 'f' 'wb' 51 'f' 'wb' 54 'f' 'wb' 53 'f' 'wb' 59 'f' 'wb' 59 'f' 'wb' 63 'f' 'wb' 66 'f' 'wb' 53 'f' 'wb' 54 'f' 'wb' 60 'f' 'wb' 43 'f' 'wb' 63 'f' 'wb' 56 'f' 'wb' 60 'f' 'wb' 58 'f' 'wb' 50 'f' 'wb' 59 'f' 'wb' 51 'f' 'wb' 62 'm' 'wb' 77 'm' 'wb' 68 'm' 'wb' 76 'm' 'wb' 76 'm' 'wb' 69 'm' 'wb' 71 'm' 'wb' 65 'm' 'wb' 70 'm' 'wb' 92 'm' 'wb' 76 'm' 'wb' 119 'm' 'wb' 65 'm' 'wb' 66 'm' 'wb' 101 'm' 'wb' 75 'm' 'wb' 79 'm' 'wb' 64 'm' 'wb' 69 'm' 'wb' 88 'm' 'wb' 65 'm' 'wb' 80 'm' 'wb' 78 'm' 'wb' 85 'm' 'wb' 73 'm' 'wb' 82 'm' 'wb' 74 'm' 'wb' 102 'm' 'wb' 64 'm' 'wb' 65 'm' 'wb' 73 'm' 'wb' 75 'm' 'wb' 57 'm' 'wb' 68 'm' 'wb' 71 'm' 'wb' 71 'm' 'wb' 97 'm' 'wb' 80 'm' 'wb' 66 'm' 'wb' 69 'm' 'wb' 69 'm' 'wb' 55 'm' 'wb' 59 'm' 'wb' 62 'm' 'wb' 70 'm' 'wb' 84 'm' 'wb' 69 'm' 'wb' 88 'm' 'wb' 103 'm' 'wb' 63 'm' 'wb' 84 'm' 'wb' 79 'm' 'wb' 67 'm' 'wb' 83 'm' 'wb' 96 'm' 'wb' 75 'm' 'wb' 65 'm' 'wb' 78 'm' 'wb' 69 'm' 'wb' 67 'm' 'wb' 87 'm' 'wb' 83 'm' 'wb' 90 'm' 'wb' 85 'm' 'wb' 66 'm' 'wb' 88 'm' 'wb' 54 'm' 'wb' 69 'm' 'wb' 56 'm' 'wb' 96 'm' 'wb' 76 'm' 'wb' 61 'm' 'wb' 82 'm' 'wb' 62 'm' 'wb' 71 'm' 'wb' 66 'm' 'wb' 81 'm' 'wb' 68 'm' 'wb' 80 'm' 'wb' 82 'm' 'wb' 70 'm' 'wb' 76 'm' 'wb' 88 'm' 'wb' 89 'm' 'wb' 74 'm' 'wb' 83 'm' 'wb' 81 'm' 'wb' 90 'm' 'wb' 79 'f' 'rw' 51 'f' 'rw' 54 'f' 'rw' 59 'f' 'rw' 64 'f' 'rw' 57 'f' 'rw' 66 'f' 'rw' 62 'f' 'rw' 61 'f' 'rw' 61 'f' 'rw' 59 'f' 'rw' 50 'f' 'rw' 61 'f' 'rw' 60 'f' 'rw' 41 'f' 'rw' 71 'f' 'rw' 52 'f' 'rw' 63 'f' 'rw' 54 'f' 'rw' 53 'f' 'rw' 59 'f' 'rw' 55 'f' 'rw' 56 'f' 'rw' 75 'f' 'rw' 57 'f' 'rw' 65 'f' 'rw' 75 'f' 'rw' 59 'f' 'rw' 63 'f' 'rw' 62 'f' 'rw' 51 'f' 'rw' 61 'f' 'rw' 54 'f' 'rw' 57 'f' 'rw' 50 'f' 'rw' 55 'f' 'rw' 64 'f' 'rw' 60 'f' 'rw' 52 'f' 'rw' 55 'f' 'rw' 56 'f' 'rw' 53 'f' 'rw' 59 'f' 'rw' 56 'f' 'rw' 56 'f' 'rw' 57 'f' 'rw' 50 'f' 'rw' 52 'f' 'rw' 55 'f' 'rw' 47 'f' 'rw' 45 'f' 'rw' 63 'f' 'rw' 51 'f' 'rw' 51 'f' 'rw' 55 'f' 'rw' 64 'f' 'rw' 55 'f' 'rw' 57 'f' 'rw' 77 'f' 'rw' 62 'f' 'rw' 68 'f' 'rw' 55 'f' 'rw' 56 'f' 'rw' 45 'f' 'rw' 68 'f' 'rw' 44 'f' 'rw' 61 'f' 'rw' 53 'f' 'rw' 47 'f' 'rw' 53 'f' 'rw' 62 'f' 'rw' 53 'f' 'rw' 55 'f' 'rw' 55 'f' 'rw' 66 'f' 'rw' 55 'f' 'rw' 55 'f' 'rw' 55 'f' 'rw' 67 'f' 'rw' 58 'f' 'rw' 47 'f' 'rw' 45 'f' 'rw' 44 'f' 'rw' 56 'f' 'rw' 50 'f' 'rw' 54 'f' 'rw' 52 'f' 'rw' 58 'f' 'rw' 59 'f' 'rw' 62 'f' 'rw' 66 'f' 'rw' 50 'f' 'rw' 59 'f' 'rw' 56 'f' 'rw' 55 'f' 'rw' 54 'f' 'rw' 49 'f' 'rw' 59 'f' 'rw' 51 'f' 'rw' 61 'm' 'rw' 77 'm' 'rw' 70 'm' 'rw' 76 'm' 'rw' 77 'm' 'rw' 73 'm' 'rw' 71 'm' 'rw' 64 'm' 'rw' 75 'm' 'rw' 101 'm' 'rw' 75 'm' 'rw' 124 'm' 'rw' 66 'm' 'rw' 70 'm' 'rw' 100 'm' 'rw' 73 'm' 'rw' 76 'm' 'rw' 65 'm' 'rw' 69 'm' 'rw' 86 'm' 'rw' 67 'm' 'rw' 80 'm' 'rw' 80 'm' 'rw' 82 'm' 'rw' 85 'm' 'rw' 73 'm' 'rw' 107 'm' 'rw' 64 'm' 'rw' 74 'm' 'rw' 70 'm' 'rw' 58 'm' 'rw' 69 'm' 'rw' 71 'm' 'rw' 76 'm' 'rw' 98 'm' 'rw' 76 'm' 'rw' 66 'm' 'rw' 70 'm' 'rw' 70 'm' 'rw' 56 'm' 'rw' 61 'm' 'rw' 66 'm' 'rw' 68 'm' 'rw' 86 'm' 'rw' 71 'm' 'rw' 87 'm' 'rw' 101 'm' 'rw' 63 'm' 'rw' 90 'm' 'rw' 79 'm' 'rw' 67 'm' 'rw' 83 'm' 'rw' 94 'm' 'rw' 76 'm' 'rw' 66 'm' 'rw' 77 'm' 'rw' 73 'm' 'rw' 89 'm' 'rw' 84 'm' 'rw' 91 'm' 'rw' 83 'm' 'rw' 68 'm' 'rw' 86 'm' 'rw' 58 'm' 'rw' 68 'm' 'rw' 58 'm' 'rw' 95 'm' 'rw' 75 'm' 'rw' 61 'm' 'rw' 64 'm' 'rw' 68 'm' 'rw' 67 'm' 'rw' 82 'm' 'rw' 68 'm' 'rw' 78 'm' 'rw' 70 'm' 'rw' 75 'm' 'rw' 93 'm' 'rw' 86 'm' 'rw' 71 'm' 'rw' 80 'm' 'rw' 91 'm' 'rw' 81
Names of X columns:
Gender weight measure
Response : Variable 1
Factor : Variable 2
Factor : Variable 3
Include Intercept Term ?
TRUE
TRUE
FALSE
Chart options
Title:
Label y-axis:
Label x-axis:
R Code
par4 <- 'FALSE' par3 <- '2' par2 <- '1' par1 <- '3' cat1 <- as.numeric(par1) # cat2<- as.numeric(par2) # cat3 <- as.numeric(par3) intercept<-as.logical(par4) x <- t(x) x1<-as.numeric(x[,cat1]) f1<-as.character(x[,cat2]) f2 <- as.character(x[,cat3]) xdf<-data.frame(x1,f1, f2) (V1<-dimnames(y)[[1]][cat1]) (V2<-dimnames(y)[[1]][cat2]) (V3 <-dimnames(y)[[1]][cat3]) names(xdf)<-c('Response', 'Treatment_A', 'Treatment_B') if(intercept == FALSE) (lmxdf<-lm(Response ~ Treatment_A * Treatment_B- 1, data = xdf) ) else (lmxdf<-lm(Response ~ Treatment_A * Treatment_B, data = xdf) ) (aov.xdf<-aov(lmxdf) ) (anova.xdf<-anova(lmxdf) ) load(file='createtable') a<-table.start() a<-table.row.start(a) a<-table.element(a,'ANOVA Model', length(lmxdf$coefficients)+1,TRUE) a<-table.row.end(a) a<-table.row.start(a) a<-table.element(a, lmxdf$call['formula'],length(lmxdf$coefficients)+1,TRUE) a<-table.row.end(a) a<-table.row.start(a) a<-table.element(a, 'means',,TRUE) for(i in 1:length(lmxdf$coefficients)){ a<-table.element(a, round(lmxdf$coefficients[i], digits=3),,FALSE) } a<-table.row.end(a) a<-table.end(a) table.save(a,file='mytable.tab') a<-table.start() a<-table.row.start(a) a<-table.element(a,'ANOVA Statistics', 5+1,TRUE) a<-table.row.end(a) a<-table.row.start(a) a<-table.element(a, ' ',,TRUE) a<-table.element(a, 'Df',,FALSE) a<-table.element(a, 'Sum Sq',,FALSE) a<-table.element(a, 'Mean Sq',,FALSE) a<-table.element(a, 'F value',,FALSE) a<-table.element(a, 'Pr(>F)',,FALSE) a<-table.row.end(a) for(i in 1 : length(rownames(anova.xdf))-1){ a<-table.row.start(a) a<-table.element(a,rownames(anova.xdf)[i] ,,TRUE) a<-table.element(a, anova.xdf$Df[1],,FALSE) a<-table.element(a, round(anova.xdf$'Sum Sq'[i], digits=3),,FALSE) a<-table.element(a, round(anova.xdf$'Mean Sq'[i], digits=3),,FALSE) a<-table.element(a, round(anova.xdf$'F value'[i], digits=3),,FALSE) a<-table.element(a, round(anova.xdf$'Pr(>F)'[i], digits=3),,FALSE) a<-table.row.end(a) } a<-table.row.start(a) a<-table.element(a, 'Residuals',,TRUE) a<-table.element(a, anova.xdf$'Df'[i+1],,FALSE) a<-table.element(a, round(anova.xdf$'Sum Sq'[i+1], digits=3),,FALSE) a<-table.element(a, round(anova.xdf$'Mean Sq'[i+1], digits=3),,FALSE) a<-table.element(a, ' ',,FALSE) a<-table.element(a, ' ',,FALSE) a<-table.row.end(a) a<-table.end(a) table.save(a,file='mytable1.tab') bitmap(file='anovaplot.png') boxplot(Response ~ Treatment_A + Treatment_B, data=xdf, xlab=V2, ylab=V1, main='Boxplots of ANOVA Groups') dev.off() bitmap(file='designplot.png') xdf2 <- xdf # to preserve xdf make copy for function names(xdf2) <- c(V1, V2, V3) plot.design(xdf2, main='Design Plot of Group Means') dev.off() bitmap(file='interactionplot.png') interaction.plot(xdf$Treatment_A, xdf$Treatment_B, xdf$Response, xlab=V2, ylab=V1, trace.label=V3, main='Possible Interactions Between Anova Groups') dev.off() if(intercept==TRUE){ thsd<-TukeyHSD(aov.xdf) names(thsd) <- c(V2, V3, paste(V2, ':', V3, sep='')) bitmap(file='TukeyHSDPlot.png') layout(matrix(c(1,2,3,3), 2,2)) plot(thsd, las=1) dev.off() } if(intercept==TRUE){ ntables<-length(names(thsd)) a<-table.start() a<-table.row.start(a) a<-table.element(a,'Tukey Honest Significant Difference Comparisons', 5,TRUE) a<-table.row.end(a) a<-table.row.start(a) a<-table.element(a, ' ', 1, TRUE) for(i in 1:4){ a<-table.element(a,colnames(thsd[[1]])[i], 1, TRUE) } a<-table.row.end(a) for(nt in 1:ntables){ for(i in 1:length(rownames(thsd[[nt]]))){ a<-table.row.start(a) a<-table.element(a,rownames(thsd[[nt]])[i], 1, TRUE) for(j in 1:4){ a<-table.element(a,round(thsd[[nt]][i,j], digits=3), 1, FALSE) } a<-table.row.end(a) } } # end nt a<-table.end(a) table.save(a,file='hsdtable.tab') }#end if hsd tables if(intercept==FALSE){ a<-table.start() a<-table.row.start(a) a<-table.element(a,'TukeyHSD Message', 1,TRUE) a<-table.row.end(a) a<-table.start() a<-table.row.start(a) a<-table.element(a,'Must Include Intercept to use Tukey Test ', 1, FALSE) a<-table.row.end(a) a<-table.end(a) table.save(a,file='mytable2.tab') } library(car) lt.lmxdf<-levene.test(lmxdf) a<-table.start() a<-table.row.start(a) a<-table.element(a,'Levenes Test for Homogeneity of Variance', 4,TRUE) a<-table.row.end(a) a<-table.row.start(a) a<-table.element(a,' ', 1, TRUE) for (i in 1:3){ a<-table.element(a,names(lt.lmxdf)[i], 1, FALSE) } a<-table.row.end(a) a<-table.row.start(a) a<-table.element(a,'Group', 1, TRUE) for (i in 1:3){ a<-table.element(a,round(lt.lmxdf[[i]][1], digits=3), 1, FALSE) } a<-table.row.end(a) a<-table.row.start(a) a<-table.element(a,' ', 1, TRUE) a<-table.element(a,lt.lmxdf[[1]][2], 1, FALSE) a<-table.element(a,' ', 1, FALSE) a<-table.element(a,' ', 1, FALSE) a<-table.row.end(a) a<-table.end(a) table.save(a,file='mytable3.tab')
Compute
Summary of computational transaction
Raw Input
view raw input (R code)
Raw Output
view raw output of R engine
Computing time
0 seconds
R Server
Big Analytics Cloud Computing Center
Click here to blog (archive) this computation