stroup.nin: RCB experiment of wheat at the Nebraska Intrastate Nursery
In agridat: Agricultural Datasets
stroup.nin R Documentation
RCB experiment of wheat at the Nebraska Intrastate Nursery
Description
The yield data from an advanced Nebraska Intrastate Nursery (NIN) breeding
trial conducted at Alliance, Nebraska, in 1988/89.
Format
- gen
genotype, 56 levels
- rep
replicate, 4 levels
- yield
yield, bu/ac
- col
column
- row
row
Details
Four replicates of 19 released cultivars, 35 experimental
wheat lines and 2 additional triticale lines were laid out in a 22 row
by 11 column rectangular array of plots. The varieties were allocated
to the plots using a randomised complete block (RCB) design.
Each plot was sown in four rows 4.3 m long and 0.3 m apart.
Plots were trimmed down to 2.4 m in length before harvest. The
orientation of the plots is not clear from the paper, but the data in
Littel et al are given in meters and make the orientation clear.
Field length: 11 plots * 4.3 m = 47.3 m
Field width: 22 plots * 1.2 m = 26.4 m
All plots with missing data are coded as being gen = "Lancer".
(For ASREML, missing plots need to be included for spatial analysis and the
level of 'gen' needs to be one that is already in the data.)
These data were first analyzed by Stroup et al (1994) and subsequently
by Littell et al (1996, page 321), Pinheiro and Bates (2000, page 260),
and Butler et al (2004).
This version of the data give the yield in bushels per acre. The yield
values published in Stroup et al (1994) are expressed in kg/ha. For
wheat, 1 bu/ac = 67.25 kg/ha.
Some of the gen names are different in Stroup et al (1994).
(Sometimes an experimental genotype is given a new name when it is
released for commercial use.) At a minimum, the following differences
in gen names should be noted:
stroup.nin Stroup et al
NE83498 Rawhide
KS831374 Karl
Some published versions of the data use long/lat instead of col/row.
To obtain the correct value of 'long', multiply 'col' by 1.2.
To obtain the correct value of 'lat', multiply 'row' by 4.3.
Relatively low yields were clustered in the northwest corner, which is
explained by a low rise in this part of the field, causing increased
exposure to winter kill from wind damage and thus depressed yield.
The genotype 'Buckskin' is a known superior variety, but was
disadvantaged by assignment to unfavorable locations within the
blocks.
Note that the figures in Stroup 2002 claim to be based on this data,
but the number of rows and columns are both off by 1 and the positions
of Buckskin as shown in Stroup 2002 do not appear to be quite right.
Source
Stroup, Walter W., P Stephen Baenziger, Dieter K Mulitze (1994)
Removing Spatial Variation from Wheat Yield Trials: A Comparison of Methods.
Crop Science, 86:62–66.
https://doi.org/10.2135/cropsci1994.0011183X003400010011x
References
Littell, R.C. and Milliken, G.A. and Stroup, W.W. and Wolfinger,
R.D. 1996. SAS system for mixed models, SAS Institute, Cary, NC.
Jose Pinheiro and Douglas Bates, 2000,
Mixed Effects Models in S and S-Plus, Springer.
Butler, D., B R Cullis, A R Gilmour, B J Goegel. (2004)
Spatial Analysis Mixed Models for S language environments
W. W. Stroup (2002).
Power Analysis Based on Spatial Effects Mixed Models: A Tool for
Comparing Design and Analysis Strategies in the Presence of Spatial
Variability. Journal of Agricultural, Biological, and
Environmental Statistics, 7(4), 491-511.
https://doi.org/10.1198/108571102780
See Also
Identical data (except for the missing values) are available
in the nlme package as Wheat2.
Examples
## Not run:
library(agridat)
data(stroup.nin)
dat <- stroup.nin
# Experiment layout. All "Buckskin" plots are near left side and suffer
# from poor fertility in two of the reps.
libs(desplot)
desplot(dat, yield~col*row,
aspect=47.3/26.4, out1="rep", num=gen, cex=0.6, # true aspect
main="stroup.nin - yield heatmap (true shape)")
# Dataframe to hold model predictions
preds <- data.frame(gen=levels(dat$gen))
# -----
# nlme
libs(nlme)
# Random RCB model
lme1 <- lme(yield ~ 0 + gen, random=~1|rep, data=dat, na.action=na.omit)
preds$lme1 <- fixef(lme1)
# Linear (Manhattan distance) correlation model
lme2 <- gls(yield ~ 0 + gen, data=dat,
correlation = corLin(form = ~ col + row, nugget=TRUE),
na.action=na.omit)
preds$lme2 <- coef(lme2)
# Random block and spatial correlation.
# Note: corExp and corSpher give nearly identical results
lme3 <- lme(yield ~ 0 + gen, data=dat,
random = ~ 1 | rep,
correlation = corExp(form = ~ col + row),
na.action=na.omit)
preds$lme3 <- fixef(lme3)
# AIC(lme1,lme2,lme3) # lme2 is lowest
## df AIC
## lme1 58 1333.702
## lme2 59 1189.135
## lme3 59 1216.704
# -----
# SpATS
libs(SpATS)
dat <- transform(dat, yf = as.factor(row), xf = as.factor(col))
# what are colcode and rowcode???
sp1 <- SpATS(response = "yield",
spatial = ~ SAP(col, row, nseg = c(10,20), degree = 3, pord = 2),
genotype = "gen",
#fixed = ~ colcode + rowcode,
random = ~ yf + xf,
data = dat,
control = list(tolerance = 1e-03))
#plot(sp1)
preds$spats <- predict(sp1, which="gen")$predicted.value
# -----
# Template Model Builder
# See the ar1xar1 example:
# https://github.com/kaskr/adcomp/tree/master/TMB/inst/examples
# This example uses dpois() in the cpp file to model a Poisson response
# with separable AR1xAR1. I think this example could be used for the
# stroup.nin data, changing dpois() to something Normal.
# -----
if(require("asreml", quietly=TRUE)){
libs(asreml,lucid)
# RCB analysis
as1 <- asreml(yield ~ gen, random = ~ rep, data=dat,
na.action=na.method(x="omit"))
preds$asreml1 <- predict(as1, data=dat, classify="gen")$pvals$predicted.value
# Two-dimensional AR1xAR1 spatial model
dat <- transform(dat, xf=factor(col), yf=factor(row))
dat <- dat[order(dat$xf, dat$yf),]
as2 <- asreml(yield~gen, data=dat,
residual = ~ar1(xf):ar1(yf),
na.action=na.method(x="omit"))
preds$asreml2 <- predict(as2, data=dat, classify="gen")$pvals$predicted.value
lucid::vc(as2)
## effect component std.error z.ratio constr
## R!variance 48.7 7.155 6.8 pos
## R!xf.cor 0.6555 0.05638 12 unc
## R!yf.cor 0.4375 0.0806 5.4 unc
# Compare the estimates from the two asreml models.
# We see that Buckskin has correctly been shifted upward by the spatial model
plot(preds$as1, preds$as2, xlim=c(13,37), ylim=c(13,37),
xlab="RCB", ylab="AR1xAR1", type='n')
title("stroup.nin: Comparison of predicted values")
text(preds$asreml1, preds$asreml2, preds$gen, cex=0.5)
abline(0,1)
}
# -----
# sommer
# Fixed gen, random row, col, 2D spline
libs(sommer)
dat <- stroup.nin
dat <- transform(dat, yf = as.factor(row), xf = as.factor(col))
so1 <- mmer(yield ~ 0+gen,
random = ~ vs(xf) + vs(yf) + spl2Db(row,col),
data=dat)
preds$so1 <- coef(so1)[,"Estimate"]
# spatPlot
# -----
# compare variety effects from different packages
lattice::splom(preds[,-1], main="stroup.nin")
## End(Not run)
agridat documentation built on Oct. 27, 2024, 5:07 p.m.
R Package Documentation
Browse R Packages
We want your feedback!
Note that we can't provide technical support on individual packages. You should contact the package authors for that.
| stroup.nin | R Documentation |
RCB experiment of wheat at the Nebraska Intrastate Nursery
Description
The yield data from an advanced Nebraska Intrastate Nursery (NIN) breeding trial conducted at Alliance, Nebraska, in 1988/89.
Format
- gen
genotype, 56 levels
- rep
replicate, 4 levels
- yield
yield, bu/ac
- col
column
- row
row
Details
Four replicates of 19 released cultivars, 35 experimental wheat lines and 2 additional triticale lines were laid out in a 22 row by 11 column rectangular array of plots. The varieties were allocated to the plots using a randomised complete block (RCB) design. Each plot was sown in four rows 4.3 m long and 0.3 m apart. Plots were trimmed down to 2.4 m in length before harvest. The orientation of the plots is not clear from the paper, but the data in Littel et al are given in meters and make the orientation clear.
Field length: 11 plots * 4.3 m = 47.3 m
Field width: 22 plots * 1.2 m = 26.4 m
All plots with missing data are coded as being gen = "Lancer". (For ASREML, missing plots need to be included for spatial analysis and the level of 'gen' needs to be one that is already in the data.)
These data were first analyzed by Stroup et al (1994) and subsequently by Littell et al (1996, page 321), Pinheiro and Bates (2000, page 260), and Butler et al (2004).
This version of the data give the yield in bushels per acre. The yield values published in Stroup et al (1994) are expressed in kg/ha. For wheat, 1 bu/ac = 67.25 kg/ha.
Some of the gen names are different in Stroup et al (1994). (Sometimes an experimental genotype is given a new name when it is released for commercial use.) At a minimum, the following differences in gen names should be noted:
| stroup.nin | Stroup et al |
| NE83498 | Rawhide |
| KS831374 | Karl |
Some published versions of the data use long/lat instead of col/row. To obtain the correct value of 'long', multiply 'col' by 1.2. To obtain the correct value of 'lat', multiply 'row' by 4.3.
Relatively low yields were clustered in the northwest corner, which is explained by a low rise in this part of the field, causing increased exposure to winter kill from wind damage and thus depressed yield. The genotype 'Buckskin' is a known superior variety, but was disadvantaged by assignment to unfavorable locations within the blocks.
Note that the figures in Stroup 2002 claim to be based on this data, but the number of rows and columns are both off by 1 and the positions of Buckskin as shown in Stroup 2002 do not appear to be quite right.
Source
Stroup, Walter W., P Stephen Baenziger, Dieter K Mulitze (1994) Removing Spatial Variation from Wheat Yield Trials: A Comparison of Methods. Crop Science, 86:62–66. https://doi.org/10.2135/cropsci1994.0011183X003400010011x
References
Littell, R.C. and Milliken, G.A. and Stroup, W.W. and Wolfinger, R.D. 1996. SAS system for mixed models, SAS Institute, Cary, NC.
Jose Pinheiro and Douglas Bates, 2000, Mixed Effects Models in S and S-Plus, Springer.
Butler, D., B R Cullis, A R Gilmour, B J Goegel. (2004) Spatial Analysis Mixed Models for S language environments
W. W. Stroup (2002). Power Analysis Based on Spatial Effects Mixed Models: A Tool for Comparing Design and Analysis Strategies in the Presence of Spatial Variability. Journal of Agricultural, Biological, and Environmental Statistics, 7(4), 491-511. https://doi.org/10.1198/108571102780
See Also
Identical data (except for the missing values) are available
in the nlme package as Wheat2.
Examples
## Not run:
library(agridat)
data(stroup.nin)
dat <- stroup.nin
# Experiment layout. All "Buckskin" plots are near left side and suffer
# from poor fertility in two of the reps.
libs(desplot)
desplot(dat, yield~col*row,
aspect=47.3/26.4, out1="rep", num=gen, cex=0.6, # true aspect
main="stroup.nin - yield heatmap (true shape)")
# Dataframe to hold model predictions
preds <- data.frame(gen=levels(dat$gen))
# -----
# nlme
libs(nlme)
# Random RCB model
lme1 <- lme(yield ~ 0 + gen, random=~1|rep, data=dat, na.action=na.omit)
preds$lme1 <- fixef(lme1)
# Linear (Manhattan distance) correlation model
lme2 <- gls(yield ~ 0 + gen, data=dat,
correlation = corLin(form = ~ col + row, nugget=TRUE),
na.action=na.omit)
preds$lme2 <- coef(lme2)
# Random block and spatial correlation.
# Note: corExp and corSpher give nearly identical results
lme3 <- lme(yield ~ 0 + gen, data=dat,
random = ~ 1 | rep,
correlation = corExp(form = ~ col + row),
na.action=na.omit)
preds$lme3 <- fixef(lme3)
# AIC(lme1,lme2,lme3) # lme2 is lowest
## df AIC
## lme1 58 1333.702
## lme2 59 1189.135
## lme3 59 1216.704
# -----
# SpATS
libs(SpATS)
dat <- transform(dat, yf = as.factor(row), xf = as.factor(col))
# what are colcode and rowcode???
sp1 <- SpATS(response = "yield",
spatial = ~ SAP(col, row, nseg = c(10,20), degree = 3, pord = 2),
genotype = "gen",
#fixed = ~ colcode + rowcode,
random = ~ yf + xf,
data = dat,
control = list(tolerance = 1e-03))
#plot(sp1)
preds$spats <- predict(sp1, which="gen")$predicted.value
# -----
# Template Model Builder
# See the ar1xar1 example:
# https://github.com/kaskr/adcomp/tree/master/TMB/inst/examples
# This example uses dpois() in the cpp file to model a Poisson response
# with separable AR1xAR1. I think this example could be used for the
# stroup.nin data, changing dpois() to something Normal.
# -----
if(require("asreml", quietly=TRUE)){
libs(asreml,lucid)
# RCB analysis
as1 <- asreml(yield ~ gen, random = ~ rep, data=dat,
na.action=na.method(x="omit"))
preds$asreml1 <- predict(as1, data=dat, classify="gen")$pvals$predicted.value
# Two-dimensional AR1xAR1 spatial model
dat <- transform(dat, xf=factor(col), yf=factor(row))
dat <- dat[order(dat$xf, dat$yf),]
as2 <- asreml(yield~gen, data=dat,
residual = ~ar1(xf):ar1(yf),
na.action=na.method(x="omit"))
preds$asreml2 <- predict(as2, data=dat, classify="gen")$pvals$predicted.value
lucid::vc(as2)
## effect component std.error z.ratio constr
## R!variance 48.7 7.155 6.8 pos
## R!xf.cor 0.6555 0.05638 12 unc
## R!yf.cor 0.4375 0.0806 5.4 unc
# Compare the estimates from the two asreml models.
# We see that Buckskin has correctly been shifted upward by the spatial model
plot(preds$as1, preds$as2, xlim=c(13,37), ylim=c(13,37),
xlab="RCB", ylab="AR1xAR1", type='n')
title("stroup.nin: Comparison of predicted values")
text(preds$asreml1, preds$asreml2, preds$gen, cex=0.5)
abline(0,1)
}
# -----
# sommer
# Fixed gen, random row, col, 2D spline
libs(sommer)
dat <- stroup.nin
dat <- transform(dat, yf = as.factor(row), xf = as.factor(col))
so1 <- mmer(yield ~ 0+gen,
random = ~ vs(xf) + vs(yf) + spl2Db(row,col),
data=dat)
preds$so1 <- coef(so1)[,"Estimate"]
# spatPlot
# -----
# compare variety effects from different packages
lattice::splom(preds[,-1], main="stroup.nin")
## End(Not run)
R Package Documentation
Browse R Packages
We want your feedback!
Note that we can't provide technical support on individual packages. You should contact the package authors for that.
Embedding an R snippet on your website
Add the following code to your website.
For more information on customizing the embed code, read Embedding Snippets.