[Vectis-commits] r9 - pkg/R
noreply at r-forge.r-project.org
noreply at r-forge.r-project.org
Mon Apr 1 23:49:52 CEST 2013
Author: cbattles
Date: 2013-04-01 23:49:52 +0200 (Mon, 01 Apr 2013)
New Revision: 9
Modified:
pkg/R/Cap_anal.R
Log:
Plotting layouts added
Modified: pkg/R/Cap_anal.R
===================================================================
--- pkg/R/Cap_anal.R 2013-04-01 05:07:14 UTC (rev 8)
+++ pkg/R/Cap_anal.R 2013-04-01 21:49:52 UTC (rev 9)
@@ -1,339 +1,474 @@
-#Function to generate text and graphical capabilities analyses on a data set
-vectis.cap <- function(data,
- distribution = "normal",
- USL = NA,
- LSL = NA,
- target = NA,
- main = "Capabilities Analysis",
- sub = "",
- groupsize = 1,
- mrlength = 2,
- alpha = 0.05,
- tol = 5.15,
- unbias_sub = TRUE,
- unbias_overall = FALSE,
- density = FALSE,
- binwidth = -1,
- plot = TRUE
- )
-{
- library(ggplot2)
- library(grid)
-
- if (is.na(target)){
- stop("Target not specified")
- }
- if (is.na(LSL) && is.na(USL)){
- stop("Upper and Lower Specification Limits not specified")
- }
- if (groupsize < 1 || groupsize > 50){
- stop("Group Size must be between 1 and 50")
- }
- if (mrlength < 2){
- stop("Moving Range Length must be greater than or equal to 2")
- }
-
- Lookup <-
- structure(list(N = 1:100,
- c4 = c(NA, 0.797885, 0.886227, 0.921318,
- 0.939986, 0.951533, 0.959369, 0.96503, 0.969311, 0.972659, 0.97535,
- 0.977559, 0.979406, 0.980971, 0.982316, 0.983484, 0.984506, 0.98541,
- 0.986214, 0.986934, 0.987583, 0.98817, 0.988705, 0.989193, 0.98964,
- 0.990052, 0.990433, 0.990786, 0.991113, 0.991418, 0.991703, 0.991969,
- 0.992219, 0.992454, 0.992675, 0.992884, 0.99308, 0.993267, 0.993443,
- 0.993611, 0.99377, 0.993922, 0.994066, 0.994203, 0.994335, 0.99446,
- 0.99458, 0.994695, 0.994806, 0.994911, 0.995013, 0.99511, 0.995204,
- 0.995294, 0.995381, 0.995465, 0.995546, 0.995624, 0.995699, 0.995772,
- 0.995842, 0.99591, 0.995976, 0.99604, 0.996102, 0.996161, 0.996219,
- 0.996276, 0.99633, 0.996383, 0.996435, 0.996485, 0.996534, 0.996581,
- 0.996627, 0.996672, 0.996716, 0.996759, 0.9968, 0.996841, 0.99688,
- 0.996918, 0.996956, 0.996993, 0.997028, 0.997063, 0.997097, 0.997131,
- 0.997163, 0.997195, 0.997226, 0.997257, 0.997286, 0.997315, 0.997344,
- 0.997372, 0.997399, 0.997426, 0.997452, 0.997478),
- c5 = c(NA, 0.603, 0.463, 0.389, 0.341, 0.308, 0.282, 0.262, 0.246, 0.232,
- 0.22, 0.21, 0.202, 0.194, 0.187, 0.181, 0.175, 0.17, 0.166, 0.161,
- 0.157, 0.153, 0.15, 0.147, 0.144, NA, NA, NA, NA, NA, NA, NA,
- NA, NA, NA, NA, NA, NA, NA, NA, NA, NA, NA, NA, NA, NA, NA, NA,
- NA, NA, NA, NA, NA, NA, NA, NA, NA, NA, NA, NA, NA, NA, NA, NA,
- NA, NA, NA, NA, NA, NA, NA, NA, NA, NA, NA, NA, NA, NA, NA, NA,
- NA, NA, NA, NA, NA, NA, NA, NA, NA, NA, NA, NA, NA, NA, NA, NA,
- NA, NA, NA, NA),
- d2 = c(1, 1.128, 1.693, 2.059, 2.326, 2.534,
- 2.704, 2.847, 2.97, 3.078, 3.173, 3.258, 3.336, 3.407, 3.472,
- 3.532, 3.588, 3.64, 3.689, 3.735, 3.778, 3.819, 3.858, 3.895,
- 3.931, 3.965, 3.997, 4.028, 4.058, 4.086, 4.113, 4.139, 4.164,
- 4.189, 4.213, 4.236, 4.258, 4.28, 4.301, 4.322, 4.342, 4.361,
- 4.38, 4.398, 4.415, 4.432, 4.449, 4.466, 4.482, 4.498, NA, NA,
- NA, NA, NA, NA, NA, NA, NA, NA, NA, NA, NA, NA, NA, NA, NA, NA,
- NA, NA, NA, NA, NA, NA, NA, NA, NA, NA, NA, NA, NA, NA, NA, NA,
- NA, NA, NA, NA, NA, NA, NA, NA, NA, NA, NA, NA, NA, NA, NA, NA),
- d3 = c(0.82, 0.8525, 0.8884, 0.8794, 0.8641, 0.848, 0.8332,
- 0.8198, 0.8078, 0.7971, 0.7873, 0.7785, 0.7704, 0.763, 0.7562,
- 0.7499, 0.7441, 0.7386, 0.7335, 0.7287, 0.7242, 0.7199, 0.7159,
- 0.7121, 0.7084, NA, NA, NA, NA, NA, NA, NA, NA, NA, NA, NA, NA,
- NA, NA, NA, NA, NA, NA, NA, NA, NA, NA, NA, NA, NA, NA, NA, NA,
- NA, NA, NA, NA, NA, NA, NA, NA, NA, NA, NA, NA, NA, NA, NA, NA,
- NA, NA, NA, NA, NA, NA, NA, NA, NA, NA, NA, NA, NA, NA, NA, NA,
- NA, NA, NA, NA, NA, NA, NA, NA, NA, NA, NA, NA, NA, NA, NA),
- d4 = c(1, 0.954, 1.588, 1.978, 2.257, 2.472, 2.645, 2.791,
- 2.915, 3.024, 3.121, 3.207, 3.285, 3.356, 3.422, 3.482, 3.538,
- 3.591, 3.64, 3.686, 3.73, 3.771, 3.811, 3.847, 3.883, NA,
- NA, NA, NA, NA, NA, NA, NA, NA, NA, NA, NA, NA, NA, NA, NA,
- NA, NA, NA, NA, NA, NA, NA, NA, NA, NA, NA, NA, NA, NA, NA,
- NA, NA, NA, NA, NA, NA, NA, NA, NA, NA, NA, NA, NA, NA, NA,
- NA, NA, NA, NA, NA, NA, NA, NA, NA, NA, NA, NA, NA, NA, NA,
- NA, NA, NA, NA, NA, NA, NA, NA, NA, NA, NA, NA, NA, NA)),
- .Names = c("N", "c4", "c5", "d2", "d3", "d4"), class = "data.frame",
- row.names = c(NA, -100L))
-
-# x <- c(3,5,2,3,7,4,9,1,7,5,8,3)
-# distribution = "normal"
-# USL = 9
-# LSL = 1
-# target = 5
-# main = "Capabilities Analysis"
-# sub = ""
-# groupsize = 1
-# mrlength = 2
-# alpha = 0.05
-# tol = 5.15
-# unbias_sub = TRUE
-# unbias_overall = TRUE
-
- # Estimate the standard deviation within subgroups by the average of the moving range
- # Add other methods here for subgroup size of 1
-
-
- if (groupsize == 1){
- R_i <- vector(mode = "numeric", length = (length(data[!is.na(data)])-(mrlength-1)))
- range_temp <- vector(mode = "numeric", length = mrlength)
- for(i in 1:(length(data[!is.na(data)])-(mrlength-1))){
- for(j in i:(i+mrlength-1)){
- range_temp[j+1-i]<-data[j]
- }
- R_i[i] <- max(range_temp) - min(range_temp)
- }
- Rbar <- sum(R_i)/(length(data[!is.na(data)])-(mrlength-1))
-
- if (unbias_sub) {
- S_within <<- Rbar/(Lookup$d2[mrlength])
- } else {
- S_within <<- Rbar
- }
- }
-
- if (groupsize > 1){
- #Add Here
- }
-
- # Calculate overall standard deviation and apply the unbiasing constant if desired
- if (unbias_overall) {
- S_overall <- sd(data)/(Lookup$c4[length(data[!is.na(data)])])
- } else {
- S_overall <- sd(data)
- }
-
- mu <- mean(data)
-
- # Process Data
- Proc_Data <- vector(mode = "numeric", length = 8)
- names(Proc_Data) <- c("LSL","Target","USL","Sample Mean","Number of Obs.",
- "StDev(Within)","StDev(Overall)","Group Size")
- Proc_Data["LSL"] <- LSL
- Proc_Data["Target"] <- target
- Proc_Data["USL"] <- USL
- Proc_Data["Sample Mean"] <- mu
- Proc_Data["Number of Obs."] <- length(data[!is.na(data)])
- Proc_Data["StDev(Within)"] <- S_within
- Proc_Data["StDev(Overall)"] <- S_overall
- Proc_Data["Group Size"] <- groupsize
-
- # Potential Capability Matrix
- CPS <- vector(mode = "numeric", length = 5)
- names(CPS) <- c("Cp","CPL", "CPU", "Cpk", "CCpk")
- CPS["Cp"] <- (USL - LSL)/(tol*S_within)
- CPS["CPL"] <- (mu - LSL)/(.5*tol*S_within)
- CPS["CPU"] <- (USL - mu)/(.5*tol*S_within)
- CPS["Cpk"] <- min(CPS["CPU"],CPS["CPL"])
- CPS["CCpk"] <- min(USL-target,target-LSL)/(.5*tol*S_within)
-
- # Overall Capability Matrix
- PPS <- vector(mode = "numeric", length = 5)
- names(PPS) <- c("Pp","PPL", "PPU", "Ppk", "Cpm")
- PPS["Pp"] <- (USL - LSL)/(tol*S_overall)
- PPS["PPL"] <- (mu - LSL)/(.5*tol*S_overall)
- PPS["PPU"] <- (USL - mu)/(.5*tol*S_overall)
- PPS["Ppk"] <- min(PPS["PPU"],PPS["PPL"])
- PPS["Cpm"] <- min(USL-target,target-LSL)/(.5*tol*sd(data))
-
- #Expected Within/Overall/Observed Performance
- PERF <- vector(mode = "numeric", length = 9)
- names(PERF) <- c("PWLL","PWGU","PWT","POLL","POGU","POT","OBLL","OBGU","OBT")
- PERF["PWLL"] <- 1e6*(1-pnorm((mu-LSL)/S_within))
- PERF["PWGU"] <- 1e6*(1-pnorm((USL-mu)/S_within))
- PERF["PWT"] <- sum(PERF["PWLL"],PERF["PWGU"])
- PERF["POLL"] <- 1e6*(1-pnorm((mu-LSL)/S_overall))
- PERF["POGU"] <- 1e6*(1-pnorm((USL-mu)/S_overall))
- PERF["POT"] <- sum(PERF["POLL"],PERF["POGU"])
- PERF["OBLL"] <- 1e6*(length(data[data<LSL])/length(data[!is.na(data)]))
- PERF["OBGU"] <- 1e6*(length(data[data>USL])/length(data[!is.na(data)]))
- PERF["OBT"] <- sum(PERF["OBLL"],PERF["OBGU"])
-
- if(plot){
-
- #Determine max densities for plot limits
- if(density) dens_max <- max(density(data)[[2]]) else dens_max <- 0
- freq_max <- max(hist(as.vector(data), plot = FALSE)$density)
- with_max <- dnorm(mean(data), mean = mean(data),sd = S_within)
- over_max <- dnorm(mean(data), mean = mean(data),sd = S_overall)
-
- #Calculate the binwidth if not specified
- if (binwidth == -1) {
- #Freedman-Diaconis
- binwidth = 2 * IQR(data) / (length(data[!is.na(data)])^(1/3))
- #Square-root choice
- #binwidth = diff(range(data))/sqrt(length(data[!is.na(data)]))
- }
-
- #Create Plots
- data <- as.data.frame(data)
-
- #define function for aes that evaluates expressions
- aes_now <- function(...) {structure(list(...), class = "uneval")}
-
- #Initial plot definition
- p <- ggplot(data, aes(x = data)) +
- theme(plot.margin = unit(c(3,1,1,1), "lines"),
- panel.grid.minor = element_blank(),
- panel.grid.major = element_blank(),
- panel.background = element_rect(fill = NA, color = "gray0"),
- axis.title.y = element_blank(),
- axis.title.x = element_blank(),
- axis.ticks.y = element_blank(),
- axis.text.y = element_blank(),
- axis.text.x = element_text(size = 15),
- legend.position = "none") +
- coord_cartesian(ylim = c(0, max(1.05 * dens_max, 1.05 * freq_max,
- 1.05 * with_max, 1.05 * over_max)),
- xlim = c(min(min(data),1.1 * LSL - 0.1 * USL, target - 3 * S_within,
- target - 3 * S_overall),
- max(max(data),1.1 * USL - 0.1 * LSL, target + 3 * S_within,
- target + 3 * S_overall))) +
- xlim(min(min(data),1.1 * LSL - 0.1 * USL, target - 3 * S_within, target - 3 * S_overall),
- max(max(data),1.1 * USL - 0.1 * LSL, target + 3 * S_within, target + 3 * S_overall)) +
- ylim(0, max(1.05 * dens_max, 1.05 * freq_max,
- 1.05 * with_max, 1.05 * over_max))
-
- #Add histogram
- p <- p + geom_histogram(aes(y=..density..),
- binwidth = binwidth,
- color = "black", fill = "slategray1", position = "identity")
-
- #Add Density
- if(density) {p <- p + geom_line(stat="density", size = 1.1,
- aes(color = "density"), position="identity")}
- #Add Spec Limits and labels
- p <- p + geom_vline(xintercept = LSL, linetype = 5, size = .65, color = "red3")
- p <- p + geom_vline(xintercept = target, linetype = 5, size = .65, color = "green3")
- p <- p + geom_vline(xintercept = USL, linetype = 5, size = .65, color = "red3")
-
- p <- p + geom_text(aes_now(label = c("USL"), x = c(USL), y = Inf, family = "sans"),
- hjust = .5, vjust = -1, color = "red3", size=5)
- p <- p + geom_text(aes_now(label = c("LSL"), x = c(LSL), y = Inf, family = "sans"),
- hjust = .5, vjust = -1, color = "red3", size=5)
- p <- p + geom_text(aes_now(label = c("Target"), x = c(target), y = Inf, family = "sans"),
- hjust = .5, vjust = -1, color = "green3", size=5)
-
- #Add within and overall distribution lines
- p <- p + stat_function(fun = dnorm,args=list(mean = mu, sd = S_within),
- aes(color = "d_with"), size = 1.1, linetype = 1)
- p <- p + stat_function(fun = dnorm,args=list(mean = mu, sd = S_overall),
- aes(color = "d_over"), size = 1.1, linetype = 2)
-
- #Add Legend (currently disabled by theme)
- p <- p + scale_color_manual("Legend",
- labels = c("Within","Overall","Density"),
- values = c("d_with"="red3",
- "d_over"="gray0",
- "density"="dodgerblue3"))
-
-# #Disable Clipping
-# gt <- ggplot_gtable(ggplot_build(p))
-# gt$layout$clip[gt$layout$name == "panel"] <- "off"
-# grid.draw(gt)
-
- .ss.prepCanvas<-function(main="Six Sigma graph", sub="My Six Sigma Project",
- ss.col=c("#666666", "#BBBBBB", "#CCCCCC", "#DDDDDD", "#EEEEEE")){
- #Plot
- grid.newpage()
- grid.rect(gp=gpar(col=ss.col[2], lwd=2, fill=ss.col[5]))
- vp.canvas<-viewport(name="canvas",
- width=unit(1,"npc")-unit(6,"mm"),
- height=unit(1,"npc")-unit(6,"mm"),
- layout=grid.layout(3,1,
- heights=unit(c(3,1,2), c("lines", "null", "lines"))
- ))
- pushViewport(vp.canvas)
- grid.rect(gp=gpar(col="#FFFFFF", lwd=0, fill="#FFFFFF"))
-
- #Title
- vp.title<-viewport(layout.pos.col=1, layout.pos.row=1, name="title")
- pushViewport(vp.title)
- grid.text (main, gp=gpar(fontsize=20))
- popViewport()
-
- #Subtitle
- vp.subtitle<-viewport(layout.pos.col=1, layout.pos.row=3, name="subtitle")
- pushViewport(vp.subtitle)
- grid.text ( sub, gp=gpar(col=ss.col[1]))
- popViewport()
-
- #Container
- vp.container<-viewport(layout.pos.col=1, layout.pos.row=2, name="container")
- pushViewport(vp.container)
- }
-
-
- .ss.prepCanvas()
- #grid.rect()##########
- vp.plots<-viewport(name="plots",
- layout=grid.layout(2,2,c(0.6,0.4),c(0.6,0.4)))
- pushViewport(vp.plots)
-
- vp.hist <- viewport(name="hist", layout.pos.row=1, layout.pos.col=1)
- pushViewport(vp.hist)
- #grid.rect()##########
- grid.text("Histogram & Density", y=1, just=c("center", "top") )
-
-
- print(p, newpage=FALSE)
-
- popViewport()
- vp.norm<-viewport(name="normal",layout.pos.row=2, layout.pos.col=1,
- layout=grid.layout(2,2,c(0.6,0.4),c(0.1, 0.9)))
- pushViewport(vp.norm)
- grid.text("Check Normality", y=1,just=c("center","top"))
-
- #Render plot
-# print(gt, vp = viewport(layout.pos.row = 2, layout.pos.col = 2))
-# print(p, vp = viewport(layout.pos.row = 1, layout.pos.col = 1))
-}
-
- #Define output
- output <- list(Proc_Data,CPS,PPS,PERF)
- class(output) <- 'myclass'
- return(output)
-}
-
-#Format Text Output
-print.myclass <- function(x) {
- cat("Capabiliy Analysis","\n")
- print(noquote(cbind(`Process Data` = unlist(x[[1]]))), digits = 4)
- cat("\n")
- print(noquote(cbind(`Potential Capability` = unlist(x[[2]]))), digits = 4)
- cat("\n")
- print(noquote(cbind(`Overall Capability` = unlist(x[[3]]))), digits = 4)
- cat("\n")
- print(noquote(cbind(`Performance` = unlist(x[[4]]))), digits = 4)
- return(invisible(x))
+#Function to generate text and graphical capabilities analyses on a data set
+vectis.cap <- function(data,
+ distribution = "normal",
+ USL = NA,
+ LSL = NA,
+ target = NA,
+ main = "Process Capability",
+ sub = "",
+ groupsize = 1,
+ mrlength = 2,
+ alpha = 0.05,
+ tol = 5.15,
+ unbias_sub = TRUE,
+ unbias_overall = FALSE,
+ density = FALSE,
+ binwidth = -1,
+ plot = TRUE,
+ name = "Measurement",
+ footer = TRUE
+ )
+{
+ library(ggplot2)
+ library(grid)
+
+ if (is.na(target)){
+ stop("Target not specified")
+ }
+ if (is.na(LSL) && is.na(USL)){
+ stop("Upper and Lower Specification Limits not specified")
+ }
+ if (groupsize < 1 || groupsize > 50){
+ stop("Group Size must be between 1 and 50")
+ }
+ if (mrlength < 2){
+ stop("Moving Range Length must be greater than or equal to 2")
+ }
+
+ Lookup <-
+ structure(list(N = 1:100,
+ c4 = c(NA, 0.797885, 0.886227, 0.921318,
+ 0.939986, 0.951533, 0.959369, 0.96503, 0.969311, 0.972659, 0.97535,
+ 0.977559, 0.979406, 0.980971, 0.982316, 0.983484, 0.984506, 0.98541,
+ 0.986214, 0.986934, 0.987583, 0.98817, 0.988705, 0.989193, 0.98964,
+ 0.990052, 0.990433, 0.990786, 0.991113, 0.991418, 0.991703, 0.991969,
+ 0.992219, 0.992454, 0.992675, 0.992884, 0.99308, 0.993267, 0.993443,
+ 0.993611, 0.99377, 0.993922, 0.994066, 0.994203, 0.994335, 0.99446,
+ 0.99458, 0.994695, 0.994806, 0.994911, 0.995013, 0.99511, 0.995204,
+ 0.995294, 0.995381, 0.995465, 0.995546, 0.995624, 0.995699, 0.995772,
+ 0.995842, 0.99591, 0.995976, 0.99604, 0.996102, 0.996161, 0.996219,
+ 0.996276, 0.99633, 0.996383, 0.996435, 0.996485, 0.996534, 0.996581,
+ 0.996627, 0.996672, 0.996716, 0.996759, 0.9968, 0.996841, 0.99688,
+ 0.996918, 0.996956, 0.996993, 0.997028, 0.997063, 0.997097, 0.997131,
+ 0.997163, 0.997195, 0.997226, 0.997257, 0.997286, 0.997315, 0.997344,
+ 0.997372, 0.997399, 0.997426, 0.997452, 0.997478),
+ c5 = c(NA, 0.603, 0.463, 0.389, 0.341, 0.308, 0.282, 0.262, 0.246, 0.232,
+ 0.22, 0.21, 0.202, 0.194, 0.187, 0.181, 0.175, 0.17, 0.166, 0.161,
+ 0.157, 0.153, 0.15, 0.147, 0.144, NA, NA, NA, NA, NA, NA, NA,
+ NA, NA, NA, NA, NA, NA, NA, NA, NA, NA, NA, NA, NA, NA, NA, NA,
+ NA, NA, NA, NA, NA, NA, NA, NA, NA, NA, NA, NA, NA, NA, NA, NA,
+ NA, NA, NA, NA, NA, NA, NA, NA, NA, NA, NA, NA, NA, NA, NA, NA,
+ NA, NA, NA, NA, NA, NA, NA, NA, NA, NA, NA, NA, NA, NA, NA, NA,
+ NA, NA, NA, NA),
+ d2 = c(1, 1.128, 1.693, 2.059, 2.326, 2.534,
+ 2.704, 2.847, 2.97, 3.078, 3.173, 3.258, 3.336, 3.407, 3.472,
+ 3.532, 3.588, 3.64, 3.689, 3.735, 3.778, 3.819, 3.858, 3.895,
+ 3.931, 3.965, 3.997, 4.028, 4.058, 4.086, 4.113, 4.139, 4.164,
+ 4.189, 4.213, 4.236, 4.258, 4.28, 4.301, 4.322, 4.342, 4.361,
+ 4.38, 4.398, 4.415, 4.432, 4.449, 4.466, 4.482, 4.498, NA, NA,
+ NA, NA, NA, NA, NA, NA, NA, NA, NA, NA, NA, NA, NA, NA, NA, NA,
+ NA, NA, NA, NA, NA, NA, NA, NA, NA, NA, NA, NA, NA, NA, NA, NA,
+ NA, NA, NA, NA, NA, NA, NA, NA, NA, NA, NA, NA, NA, NA, NA, NA),
+ d3 = c(0.82, 0.8525, 0.8884, 0.8794, 0.8641, 0.848, 0.8332,
+ 0.8198, 0.8078, 0.7971, 0.7873, 0.7785, 0.7704, 0.763, 0.7562,
+ 0.7499, 0.7441, 0.7386, 0.7335, 0.7287, 0.7242, 0.7199, 0.7159,
+ 0.7121, 0.7084, NA, NA, NA, NA, NA, NA, NA, NA, NA, NA, NA, NA,
+ NA, NA, NA, NA, NA, NA, NA, NA, NA, NA, NA, NA, NA, NA, NA, NA,
+ NA, NA, NA, NA, NA, NA, NA, NA, NA, NA, NA, NA, NA, NA, NA, NA,
+ NA, NA, NA, NA, NA, NA, NA, NA, NA, NA, NA, NA, NA, NA, NA, NA,
+ NA, NA, NA, NA, NA, NA, NA, NA, NA, NA, NA, NA, NA, NA, NA),
+ d4 = c(1, 0.954, 1.588, 1.978, 2.257, 2.472, 2.645, 2.791,
+ 2.915, 3.024, 3.121, 3.207, 3.285, 3.356, 3.422, 3.482, 3.538,
+ 3.591, 3.64, 3.686, 3.73, 3.771, 3.811, 3.847, 3.883, NA,
+ NA, NA, NA, NA, NA, NA, NA, NA, NA, NA, NA, NA, NA, NA, NA,
+ NA, NA, NA, NA, NA, NA, NA, NA, NA, NA, NA, NA, NA, NA, NA,
+ NA, NA, NA, NA, NA, NA, NA, NA, NA, NA, NA, NA, NA, NA, NA,
+ NA, NA, NA, NA, NA, NA, NA, NA, NA, NA, NA, NA, NA, NA, NA,
+ NA, NA, NA, NA, NA, NA, NA, NA, NA, NA, NA, NA, NA, NA)),
+ .Names = c("N", "c4", "c5", "d2", "d3", "d4"), class = "data.frame",
+ row.names = c(NA, -100L))
+
+# x <- c(3,5,2,3,7,4,9,1,7,5,8,3)
+# distribution = "normal"
+# USL = 9
+# LSL = 1
+# target = 5
+# main = "Capabilities Analysis"
+# sub = ""
+# groupsize = 1
+# mrlength = 2
+# alpha = 0.05
+# tol = 5.15
+# unbias_sub = TRUE
+# unbias_overall = TRUE
+
+ # Estimate the standard deviation within subgroups by the average of the moving range
+ # Add other methods here for subgroup size of 1
+
+
+ if (groupsize == 1){
+ R_i <- vector(mode = "numeric", length = (length(data[!is.na(data)])-(mrlength-1)))
+ range_temp <- vector(mode = "numeric", length = mrlength)
+ for(i in 1:(length(data[!is.na(data)])-(mrlength-1))){
+ for(j in i:(i+mrlength-1)){
+ range_temp[j+1-i]<-data[j]
+ }
+ R_i[i] <- max(range_temp) - min(range_temp)
+ }
+ Rbar <- sum(R_i)/(length(data[!is.na(data)])-(mrlength-1))
+
+ if (unbias_sub) {
+ S_within <<- Rbar/(Lookup$d2[mrlength])
+ } else {
+ S_within <<- Rbar
+ }
+ }
+
+ if (groupsize > 1){
+ #Add Here
+ }
+
+ # Calculate overall standard deviation and apply the unbiasing constant if desired
+ if (unbias_overall) {
+ S_overall <- sd(data)/(Lookup$c4[length(data[!is.na(data)])])
+ } else {
+ S_overall <- sd(data)
+ }
+
+ mu <- mean(data)
+
+
+ # Process Data
+ Proc_Data <- vector(mode = "numeric", length = 8)
+ names(Proc_Data) <- c("LSL","Target","USL","Sample Mean","Number of Obs.",
+ "StDev(Within)","StDev(Overall)","Group Size")
+ Proc_Data["LSL"] <- LSL
+ Proc_Data["Target"] <- target
+ Proc_Data["USL"] <- USL
+ Proc_Data["Sample Mean"] <- mu
+ Proc_Data["Number of Obs."] <- length(data[!is.na(data)])
+ Proc_Data["StDev(Within)"] <- S_within
+ Proc_Data["StDev(Overall)"] <- S_overall
+ Proc_Data["Group Size"] <- groupsize
+
+ # Potential Capability Matrix
+ CPS <- vector(mode = "numeric", length = 5)
+ names(CPS) <- c("Cp","CPL", "CPU", "Cpk", "CCpk")
+ CPS["Cp"] <- (USL - LSL)/(tol*S_within)
+ CPS["CPL"] <- (mu - LSL)/(.5*tol*S_within)
+ CPS["CPU"] <- (USL - mu)/(.5*tol*S_within)
+ CPS["Cpk"] <- min(CPS["CPU"],CPS["CPL"])
+ CPS["CCpk"] <- min(USL-target,target-LSL)/(.5*tol*S_within)
+
+ # Overall Capability Matrix
+ PPS <- vector(mode = "numeric", length = 5)
+ names(PPS) <- c("Pp","PPL", "PPU", "Ppk", "Cpm")
+ PPS["Pp"] <- (USL - LSL)/(tol*S_overall)
+ PPS["PPL"] <- (mu - LSL)/(.5*tol*S_overall)
+ PPS["PPU"] <- (USL - mu)/(.5*tol*S_overall)
+ PPS["Ppk"] <- min(PPS["PPU"],PPS["PPL"])
+ PPS["Cpm"] <- min(USL-target,target-LSL)/(.5*tol*sd(data))
+
+ #Expected Within/Overall/Observed Performance
+ PERF <- vector(mode = "numeric", length = 9)
+ names(PERF) <- c("PWLL","PWGU","PWT","POLL","POGU","POT","OBLL","OBGU","OBT")
+ PERF["PWLL"] <- 1e6*(1-pnorm((mu-LSL)/S_within))
+ PERF["PWGU"] <- 1e6*(1-pnorm((USL-mu)/S_within))
+ PERF["PWT"] <- sum(PERF["PWLL"],PERF["PWGU"])
+ PERF["POLL"] <- 1e6*(1-pnorm((mu-LSL)/S_overall))
+ PERF["POGU"] <- 1e6*(1-pnorm((USL-mu)/S_overall))
+ PERF["POT"] <- sum(PERF["POLL"],PERF["POGU"])
+ PERF["OBLL"] <- 1e6*(length(data[data<LSL])/length(data[!is.na(data)]))
+ PERF["OBGU"] <- 1e6*(length(data[data>USL])/length(data[!is.na(data)]))
+ PERF["OBT"] <- sum(PERF["OBLL"],PERF["OBGU"])
+
+ if(plot){
+
+ #Determine max densities for plot limits
+ if(density) dens_max <- max(density(data)[[2]]) else dens_max <- 0
+ freq_max <- max(hist(as.vector(data), plot = FALSE)$density)
+ with_max <- dnorm(mean(data), mean = mean(data),sd = S_within)
+ over_max <- dnorm(mean(data), mean = mean(data),sd = S_overall)
+
+ #Calculate the binwidth if not specified
+ if (binwidth == -1) {
+ #Freedman-Diaconis
+ binwidth = 2 * IQR(data) / (length(data[!is.na(data)])^(1/3))
+ #Square-root choice
+ #binwidth = diff(range(data))/sqrt(length(data[!is.na(data)]))
+ }
+
+ #Create Plots
+ data <- as.data.frame(data)
+
+ #define function for aes that evaluates expressions
+ aes_now <- function(...) {structure(list(...), class = "uneval")}
+
+ #Initial plot definition
+ p <- ggplot(data, aes(x = data)) +
+ theme(plot.margin = unit(c(3,0,.5,0), "lines"),
+ panel.grid.minor = element_blank(),
+ panel.grid.major = element_blank(),
+ panel.background = element_rect(fill = "white", color = "gray0"),
+ plot.background = element_rect(fill = "cornsilk", color = NA),
+ axis.title.y = element_blank(),
+ axis.title.x = element_blank(),
+ axis.ticks.y = element_blank(),
+ axis.text.y = element_blank(),
+ axis.text.x = element_text(size = 15),
+ legend.background = element_rect(fill = "white", color = "gray0"),
+ legend.key = element_rect(fill = NA, color = NA),
+ legend.key.width = unit(3,"lines"),
+ legend.key.height = unit(1,"lines")
+# legend.position = c(0,0)
+ ) +
+ coord_cartesian(ylim = c(0, max(1.05 * dens_max, 1.05 * freq_max,
+ 1.05 * with_max, 1.05 * over_max)),
+ xlim = c(min(min(data),1.1 * LSL - 0.1 * USL, target - 3 * S_within,
+ target - 3 * S_overall),
+ max(max(data),1.1 * USL - 0.1 * LSL, target + 3 * S_within,
+ target + 3 * S_overall))) +
+ xlim(min(min(data),1.1 * LSL - 0.1 * USL, target - 3 * S_within, target - 3 * S_overall),
+ max(max(data),1.1 * USL - 0.1 * LSL, target + 3 * S_within, target + 3 * S_overall)) +
+ ylim(0, max(1.05 * dens_max, 1.05 * freq_max,
+ 1.05 * with_max, 1.05 * over_max))
+
+ #Add histogram
+ p <- p + geom_histogram(aes(y=..density..),
+ binwidth = binwidth,
+ color = "black", fill = "slategray1", position = "identity")
+
+ #Add Density
+ if(density) {p <- p + geom_line(stat="density", size = 1.1,
+ aes(color = "density"), position="identity", linetype = 1)}
+ #Add Spec Limits and labels
+ p <- p + geom_vline(xintercept = LSL, linetype = 5, size = .65, color = "red3")
+ p <- p + geom_vline(xintercept = target, linetype = 5, size = .65, color = "green3")
+ p <- p + geom_vline(xintercept = USL, linetype = 5, size = .65, color = "red3")
+
+ p <- p + geom_text(aes_now(label = c("USL"), x = c(USL), y = Inf, family = "sans"),
+ hjust = .5, vjust = -1, color = "red3", size=4)
+ p <- p + geom_text(aes_now(label = c("LSL"), x = c(LSL), y = Inf, family = "sans"),
+ hjust = .5, vjust = -1, color = "red3", size=4)
+ p <- p + geom_text(aes_now(label = c("Target"), x = c(target), y = Inf, family = "sans"),
+ hjust = .5, vjust = -1, color = "green3", size=4)
+
+ #Add within and overall distribution lines
+ p <- p + stat_function(fun = dnorm,args=list(mean = mu, sd = S_within),
+ aes(color = "dwith", linetype = "dwith"), size = 1.1, linetype = 2)
+ p <- p + stat_function(fun = dnorm,args=list(mean = mu, sd = S_overall),
+ aes(color = "dover", linetype = "dover"), size = 1.1, linetype = 1)
+
+ #Add Legend (currently disabled by theme)
+ p <- p +
+# scale_linetype_manual(values = c(2,1,1))+
+
+ scale_color_manual("Legend",
+ labels = c("Within","Overall","Density"),
+ breaks = c("dwith","dover","density"),
+ values = c("dwith"="red3",
+ "dover"="gray0",
+ "density"="dodgerblue3"))
+
+
+
+ Proc_leg <- ggplot()+
+ xlim(c(0,1))+ylim(c(.2,1))+
+ theme(plot.margin = unit(c(3,0.1,1,0), "lines"),
+ panel.grid.minor = element_blank(),
+ panel.grid.major = element_blank(),
+ panel.background = element_rect(fill = "white", color = "gray0"),
+ plot.background = element_rect(fill = NA, color = NA),
+ axis.title.y = element_blank(),
+ axis.title.x = element_blank(),
+ axis.ticks.x = element_blank(),
+ axis.text.x = element_blank(),
+ axis.ticks.y = element_blank(),
+ axis.text.y = element_blank(),
+ legend.position = "none") +
+ geom_text(aes(label = c("Process Data"),
+ x = .5, y = 1,
+ family = "sans"),
+ hjust = .5, vjust = 1,
+ color = "gray0", size=4)+
+ geom_text(aes(label = c("LSL"),
+ x = .05, y = .9,
+ family = "sans"),
+ hjust = -.0, vjust = 1,
+ color = "gray0", size=4)+
+ geom_text(aes(label = c("Target"),
+ x = .05, y = .8,
+ family = "sans"),
+ hjust = -.0, vjust = 1,
+ color = "gray0", size=4)+
+ geom_text(aes(label = c("USL"),
+ x = .05, y = .7,
+ family = "sans"),
+ hjust = -.0, vjust = 1,
+ color = "gray0", size=4)+
+ geom_text(aes(label = c("Sample Mean"),
+ x = .05, y = .6,
+ family = "sans"),
+ hjust = -.0, vjust = 1,
+ color = "gray0", size=4)+
+ geom_text(aes(label = c("Sample N"),
+ x = .05, y = .5,
+ family = "sans"),
+ hjust = -.0, vjust = 1,
+ color = "gray0", size=4)+
+ geom_text(aes(label = c("StDev(Within)"),
+ x = .05, y = .4,
+ family = "sans"),
+ hjust = -.0, vjust = 1,
+ color = "gray0", size=4)+
+ geom_text(aes(label = c("StDev(Overall)"),
+ x = .05, y = .3,
+ family = "sans"),
+ hjust = -.0, vjust = 1,
+ color = "gray0", size=4)+
+
+ geom_text(aes_now(label = sprintf("%.3f",LSL),
+ x = .6, y = .9,
+ family = "sans"),
+ hjust = -.0, vjust = 1,
+ color = "gray0", size=4)+
+ geom_text(aes_now(label = sprintf("%.3f",target),
+ x = .6, y = .8,
+ family = "sans"),
+ hjust = -.0, vjust = 1,
+ color = "gray0", size=4)+
+ geom_text(aes_now(label = sprintf("%.3f",USL),
+ x = .6, y = .7,
+ family = "sans"),
+ hjust = -.0, vjust = 1,
+ color = "gray0", size=4)+
+ geom_text(aes_now(label = sprintf("%.6f",mu),
+ x = .6, y = .6,
+ family = "sans"),
+ hjust = -.0, vjust = 1,
+ color = "gray0", size=4)+
+ geom_text(aes_now(label = length(data[!is.na(data)]),
+ x = .6, y = .5,
+ family = "sans"),
+ hjust = -.0, vjust = 1,
+ color = "gray0", size=4)+
+ geom_text(aes_now(label = sprintf("%.8f",S_within),
+ x = .6, y = .4,
+ family = "sans"),
+ hjust = -.0, vjust = 1,
+ color = "gray0", size=4)+
+ geom_text(aes_now(label = sprintf("%.8f",S_overall),
+ x = .6, y = .3,
+ family = "sans"),
+ hjust = -.0, vjust = 1,
+ color = "gray0", size=4)
+
+
+ Leg_leg <- ggplot()+
+ xlim(c(0,1))+ylim(c(.2,1))+
+ theme(plot.margin = unit(c(3,2,5,0), "lines"),
[TRUNCATED]
To get the complete diff run:
svnlook diff /svnroot/vectis -r 9
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