Linear Regression in R for Date and some dependant output - r

Actually I need to calculate the parameters theta0 and theta1 using linear regression.
My data frame (data.1) consists of two columns, first one is a date-time and the second one is a result which is dependent on this date.
Like this:
data.1[[1]] data.1[[2]]
2004-07-08 14:30:00 12.41
Now, I have this code for which iterates over a number of times to calculate the parameter theta0, theta1
x=as.vector(data.1[[1]])
y=as.vector(data.1[[2]])
plot(x,y)
theta0=10
theta1=10
alpha=0.0001
initialJ=100000
learningIterations=200000
J=function(x,y,theta0,theta1){
m=length(x)
sum=0
for(i in 1:m){
sum=sum+((theta0+theta1*x[i]-y[i])^2)
}
sum=sum/(2*m)
return(sum)
}
updateTheta=function(x,y,theta0,theta1){
sum0=0
sum1=0
m=length(x)
for(i in 1:m){
sum0=sum0+(theta0+theta1*x[i]-y[i])
sum1=sum1+((theta0+theta1*x[i]-y[i])*x[i])
}
sum0=sum0/m
sum1=sum1/m
theta0=theta0-(alpha*sum0)
theta1=theta1-(alpha*sum1)
return(c(theta0,theta1))
}    
for(i in 1:learningIterations){
thetas=updateTheta(x,y,theta0,theta1)
tempSoln=0
tempSoln=J(x,y,theta0,theta1)
if(tempSoln<initialJ){
initialJ=tempSoln
}
if(tempSoln>initialJ){
break
}
theta0=thetas[1]
theta1=thetas[2]
#print(thetas)
#print(initialJ)
plot(x,y)
lines(x,(theta0+theta1*x), col="red")
}
lines(x,(theta0+theta1*x), col="green")
Now I want to calculate theta0 and theta1 using the following scenarios:
y=data.1[[2]] and x=dates which are similar irrespective of the year
y=data.1[[2]] and x=months which are similar irrespective of the year
Please suggest..

As #Nicola said, you need to use the lm function for linear regression in R.
If you'd like to learn more about linear regression check out this or follow this tutorial
First you would have to determine your formula. You want to calculate Theta0 and Theta1 using data.1[[2]] and dates/months.
Your first formula would be something along the lines of:
formula <- Theta0 ~ data.1[[2]] + dates
Then you would create the linear model
variablename <- lm(formula, dataset)
After this you can use the output for various calculations.
For example you can calculate anova, or just print the summary:
anova(variablename)
summary(variablename)
Sidenote:.
I noticed your assigning variables by using =. This is not recommended parenthesis. For more information check out Google's R Style Guide
In R it would be preferred to use <- to assign variables.
Taking the first bit of your code, it would become:
x <- as.vector(data.1[[1]])
y <- as.vector(data.1[[2]])
plot(x,y)
theta0 <- 10
theta1 <- 10
alpha <- 0.0001
initialJ <- 100000
learningIterations <- 200000

Related

Using for loop to randomize a variable and run a linear model many times

I'm really new to R and I've got a task but I've got no idea how to go about it.
I've created a scatterplot, and I need to randomize a variable, and run a linear model of this randomized variable with another (unchanged) variable, before plotting a linear regression line (1,000 of them) on my one scatter plot, using a loop.
This is where I'm at:
asample <-numeric(1000)
for (i in 1:1000) {
Randomised_sample <- sample(MYdata$Variable1)
Linearmodel <- lm(Randomised_sample~(MYdata$Variable2)
summary(Linearmodel)
asample[i] <- coefficients(Linearmodel)
}
As you can probably see, I have no idea what I'm doing. Any help is much appreciated, I've been searching for hours. I know I need an abline with the slope etc., but I don't know where to put this / how to make the above work.
I think this is what you are looking for? But I have to admit, I'm still a little confused what exactly you are trying to do.
set.seed(12345)
x1<-rnorm(n=1000, mean=1, sd=1) #simulating data
y <-rnorm(n=1000, mean=2, sd=2) #simulating data
mydata<-as.data.frame(cbind(y, x)) #combining data into data frame
coefs<-matrix(nrow=1000, ncol=2) #coefficient matrix to hold betas
for(i in 1:1000){ #for loop
samp<-sample(1:1000, 10) #collecting a sample of size 10 without replacement
fit<-lm(y~x, data=mydata, subset=samp)#finding the fit for the 10 sampled observatoins
coefs[i,1]<-as.numeric(fit$coefficients[1]) #saving beta0
coefs[i,2]<-as.numeric(fit$coefficients[2]) #saving beta1
}
Does this help?

Bootstrapping regression coefficients from random subsets of data

I’m attempting to perform a regression calibration on two variables using the yorkfit() function in the IsoplotR package. I would like to estimate the confidence interval of the bootstrapped slope coefficient from this model; however, instead of using the typical bootstrap method below, I’d like to only perform the iterations on 75% of the data (randomly selected) at a time. So far, using the following sample data, I managed to bootstrap the slope coefficient result of the yorkfit() function:
library(boot)
library(IsoplotR)
X <- c(9.105,8.987,8.974,8.994,8.996,8.966,9.035,9.215,9.239,
9.307,9.227,9.17, 9.102)
Y <- c(28.1,28.9,29.6,29.5,29.0,28.8,28.5,27.3,27.1,26.5,
27.0,27.5,28.4)
n <- length(X)
sX <- X*0.02
sY <- Y*0.05
rXY <- rep(0.8,n)
dat <- cbind(X,sX,Y,sY,rXY)
fit <- york(dat)
boot.test <- function(data,indices){
sample = data[indices,]
mod = york(sample)
return (mod$b)
}
result <- boot(data=dat, statistic = boot.test, R=1000)
boot.ci(result, type = 'bca')
...but I'm not really sure where to go from here. Any help to move me in the right direction would be greatly appreciated. I’m new to R so I apologize if question is ambiguous. Thanks.
Based on the package documentation, you should be able to use the ran.gen argument, with sim="parametric", to sample using a custom function. In this case, the sample is a certain percent of the total observations, chosen at random. Something like the following should accomplish what you want:
result <- boot(
data=dat,
statistic =boot.test,
R=1000,
sim="parametric",
ran.gen=function(data, percent){
n=nrow(data)
indic=runif(n)
data[rank(indic, ties.method="random")<=round(n*percent,0),]
},
percent=0.75)

Fit distribution to given frequency values in R

I have frequency values changing with the time (x axis units), as presented on the picture below. After some normalization these values may be seen as data points of a density function for some distribution.
Q: Assuming that these frequency points are from Weibull distribution T, how can I fit best Weibull density function to the points so as to infer the distribution T parameters from it?
sample <- c(7787,3056,2359,1759,1819,1189,1077,1080,985,622,648,518,
611,1037,727,489,432,371,1125,69,595,624)
plot(1:length(sample), sample, type = "l")
points(1:length(sample), sample)
Update.
To prevent from being misunderstood, I would like to add little more explanation. By saying I have frequency values changing with the time (x axis units) I mean I have data which says that I have:
7787 realizations of value 1
3056 realizations of value 2
2359 realizations of value 3 ... etc.
Some way towards my goal (incorrect one, as I think) would be to create a set of these realizations:
# Loop to simulate values
set.values <- c()
for(i in 1:length(sample)){
set.values <<- c(set.values, rep(i, times = sample[i]))
}
hist(set.values)
lines(1:length(sample), sample)
points(1:length(sample), sample)
and use fitdistr on the set.values:
f2 <- fitdistr(set.values, 'weibull')
f2
Why I think it is incorrect way and why I am looking for a better solution in R?
in the distribution fitting approach presented above it is assumed that set.values is a complete set of my realisations from the distribution T
in my original question I know the points from the first part of the density curve - I do not know its tail and I want to estimate the tail (and the whole density function)
Here is a better attempt, like before it uses optim to find the best value constrained to a set of values in a box (defined by the lower and upper vectors in the optim call). Notice it scales x and y as part of the optimization in addition to the Weibull distribution shape parameter, so we have 3 parameters to optimize over.
Unfortunately when using all the points it pretty much always finds something on the edges of the constraining box which indicates to me that maybe Weibull is maybe not a good fit for all of the data. The problem is the two points - they ares just too large. You see the attempted fit to all data in the first plot.
If I drop those first two points and just fit the rest, we get a much better fit. You see this in the second plot. I think this is a good fit, it is in any case a local minimum in the interior of the constraining box.
library(optimx)
sample <- c(60953,7787,3056,2359,1759,1819,1189,1077,1080,985,622,648,518,
611,1037,727,489,432,371,1125,69,595,624)
t.sample <- 0:22
s.fit <- sample[3:23]
t.fit <- t.sample[3:23]
wx <- function(param) {
res <- param[2]*dweibull(t.fit*param[3],shape=param[1])
return(res)
}
minwx <- function(param){
v <- s.fit-wx(param)
sqrt(sum(v*v))
}
p0 <- c(1,200,1/20)
paramopt <- optim(p0,minwx,gr=NULL,lower=c(0.1,100,0.01),upper=c(1.1,5000,1))
popt <- paramopt$par
popt
rms <- paramopt$value
tit <- sprintf("Weibull - Shape:%.3f xscale:%.1f yscale:%.5f rms:%.1f",popt[1],popt[2],popt[3],rms)
plot(t.sample[2:23], sample[2:23], type = "p",col="darkred")
lines(t.fit, wx(popt),col="blue")
title(main=tit)
You can directly calculate the maximum likelihood parameters, as described here.
# Defining the error of the implicit function
k.diff <- function(k, vec){
x2 <- seq(length(vec))
abs(k^-1+weighted.mean(log(x2), w = sample)-weighted.mean(log(x2),
w = x2^k*sample))
}
# Setting the error to "quite zero", fulfilling the equation
k <- optimize(k.diff, vec=sample, interval=c(0.1,5), tol=10^-7)$min
# Calculate lambda, given k
l <- weighted.mean(seq(length(sample))^k, w = sample)
# Plot
plot(density(rep(seq(length(sample)),sample)))
x <- 1:25
lines(x, dweibull(x, shape=k, scale= l))
Assuming the data are from a Weibull distribution, you can get an estimate of the shape and scale parameter like this:
sample <- c(7787,3056,2359,1759,1819,1189,1077,1080,985,622,648,518,
611,1037,727,489,432,371,1125,69,595,624)
f<-fitdistr(sample, 'weibull')
f
If you are not sure whether it is distributed Weibull, I would recommend using the ks.test. This tests whether your data is from a hypothesised distribution. Given your knowledge of the nature of the data, you could test for a few selected distributions and see which one works best.
For your example this would look like this:
ks = ks.test(sample, "pweibull", shape=f$estimate[1], scale=f$estimate[2])
ks
The p-value is insignificant, hence you do not reject the hypothesis that the data is from a Weibull distribution.
Update: The histograms of either the Weibull or exponential look like a good match to your data. I think the exponential distribution gives you a better fit. Pareto distribution is another option.
f<-fitdistr(sample, 'weibull')
z<-rweibull(10000, shape= f$estimate[1],scale= f$estimate[2])
hist(z)
f<-fitdistr(sample, 'exponential')
z = rexp(10000, f$estimate[1])
hist(z)

Errors running Maximum Likelihood Estimation on a three parameter Weibull cdf

I am working with the cumulative emergence of flies over time (taken at irregular intervals) over many summers (though first I am just trying to make one year work). The cumulative emergence follows a sigmoid pattern and I want to create a maximum likelihood estimation of a 3-parameter Weibull cumulative distribution function. The three-parameter models I've been trying to use in the fitdistrplus package keep giving me an error. I think this must have something to do with how my data is structured, but I cannot figure it out. Obviously I want it to read each point as an x (degree days) and a y (emergence) value, but it seems to be unable to read two columns. The main error I'm getting says "Non-numeric argument to mathematical function" or (with slightly different code) "data must be a numeric vector of length greater than 1". Below is my code including added columns in the df_dd_em dataframe for cumulative emergence and percent emergence in case that is useful.
degree_days <- c(998.08,1039.66,1111.29,1165.89,1236.53,1293.71,
1347.66,1387.76,1445.47,1493.44,1553.23,1601.97,
1670.28,1737.29,1791.94,1849.20,1920.91,1967.25,
2036.64,2091.85,2152.89,2199.13,2199.13,2263.09,
2297.94,2352.39,2384.03,2442.44,2541.28,2663.90,
2707.36,2773.82,2816.39,2863.94)
emergence <- c(0,0,0,1,1,0,2,3,17,10,0,0,0,2,0,3,0,0,1,5,0,0,0,0,
0,0,0,0,1,0,0,0,0,0)
cum_em <- cumsum(emergence)
df_dd_em <- data.frame (degree_days, emergence, cum_em)
df_dd_em$percent <- ave(df_dd_em$emergence, FUN = function(df_dd_em) 100*(df_dd_em)/46)
df_dd_em$cum_per <- ave(df_dd_em$cum_em, FUN = function(df_dd_em) 100*(df_dd_em)/46)
x <- pweibull(df_dd_em[c(1,3)],shape=5)
dframe2.mle <- fitdist(x, "weibull",method='mle')
Here's my best guess at what you're after:
Set up data:
dd <- data.frame(degree_days=c(998.08,1039.66,1111.29,1165.89,1236.53,1293.71,
1347.66,1387.76,1445.47,1493.44,1553.23,1601.97,
1670.28,1737.29,1791.94,1849.20,1920.91,1967.25,
2036.64,2091.85,2152.89,2199.13,2199.13,2263.09,
2297.94,2352.39,2384.03,2442.44,2541.28,2663.90,
2707.36,2773.82,2816.39,2863.94),
emergence=c(0,0,0,1,1,0,2,3,17,10,0,0,0,2,0,3,0,0,1,5,0,0,0,0,
0,0,0,0,1,0,0,0,0,0))
dd <- transform(dd,cum_em=cumsum(emergence))
We're actually going to fit to an "interval-censored" distribution (i.e. probability of emergence between successive degree day observations: this version assumes that the first observation refers to observations before the first degree-day observation, you could change it to refer to observations after the last observation).
library(bbmle)
## y*log(p) allowing for 0/0 occurrences:
y_log_p <- function(y,p) ifelse(y==0 & p==0,0,y*log(p))
NLLfun <- function(scale,shape,x=dd$degree_days,y=dd$emergence) {
prob <- pmax(diff(pweibull(c(-Inf,x), ## or (c(x,Inf))
shape=shape,scale=scale)),1e-6)
## multinomial probability
-sum(y_log_p(y,prob))
}
library(bbmle)
I should probably have used something more systematic like the method of moments (i.e. matching the mean and variance of a Weibull distribution with the mean and variance of the data), but I just hacked around a bit to find plausible starting values:
## preliminary look (method of moments would be better)
scvec <- 10^(seq(0,4,length=101))
plot(scvec,sapply(scvec,NLLfun,shape=1))
It's important to use parscale to let R know that the parameters are on very different scales:
startvals <- list(scale=1000,shape=1)
m1 <- mle2(NLLfun,start=startvals,
control=list(parscale=unlist(startvals)))
Now try with a three-parameter Weibull (as originally requested) -- requires only a slight modification of what we already have:
library(FAdist)
NLLfun2 <- function(scale,shape,thres,
x=dd$degree_days,y=dd$emergence) {
prob <- pmax(diff(pweibull3(c(-Inf,x),shape=shape,scale=scale,thres)),
1e-6)
## multinomial probability
-sum(y_log_p(y,prob))
}
startvals2 <- list(scale=1000,shape=1,thres=100)
m2 <- mle2(NLLfun2,start=startvals2,
control=list(parscale=unlist(startvals2)))
Looks like the three-parameter fit is much better:
library(emdbook)
AICtab(m1,m2)
## dAIC df
## m2 0.0 3
## m1 21.7 2
And here's the graphical summary:
with(dd,plot(cum_em~degree_days,cex=3))
with(as.list(coef(m1)),curve(sum(dd$emergence)*
pweibull(x,shape=shape,scale=scale),col=2,
add=TRUE))
with(as.list(coef(m2)),curve(sum(dd$emergence)*
pweibull3(x,shape=shape,
scale=scale,thres=thres),col=4,
add=TRUE))
(could also do this more elegantly with ggplot2 ...)
These don't seem like spectacularly good fits, but they're sane. (You could in principle do a chi-squared goodness-of-fit test based on the expected number of emergences per interval, and accounting for the fact that you've fitted a three-parameter model, although the values might be a bit low ...)
Confidence intervals on the fit are a bit of a nuisance; your choices are (1) bootstrapping; (2) parametric bootstrapping (resample parameters assuming a multivariate normal distribution of the data); (3) delta method.
Using bbmle::mle2 makes it easy to do things like get profile confidence intervals:
confint(m1)
## 2.5 % 97.5 %
## scale 1576.685652 1777.437283
## shape 4.223867 6.318481
dd <- data.frame(degree_days=c(998.08,1039.66,1111.29,1165.89,1236.53,1293.71,
1347.66,1387.76,1445.47,1493.44,1553.23,1601.97,
1670.28,1737.29,1791.94,1849.20,1920.91,1967.25,
2036.64,2091.85,2152.89,2199.13,2199.13,2263.09,
2297.94,2352.39,2384.03,2442.44,2541.28,2663.90,
2707.36,2773.82,2816.39,2863.94),
emergence=c(0,0,0,1,1,0,2,3,17,10,0,0,0,2,0,3,0,0,1,5,0,0,0,0,
0,0,0,0,1,0,0,0,0,0))
dd$cum_em <- cumsum(dd$emergence)
dd$percent <- ave(dd$emergence, FUN = function(dd) 100*(dd)/46)
dd$cum_per <- ave(dd$cum_em, FUN = function(dd) 100*(dd)/46)
dd <- transform(dd)
#start 3 parameter model
library(FAdist)
## y*log(p) allowing for 0/0 occurrences:
y_log_p <- function(y,p) ifelse(y==0 & p==0,0,y*log(p))
NLLfun2 <- function(scale,shape,thres,
x=dd$degree_days,y=dd$percent) {
prob <- pmax(diff(pweibull3(c(-Inf,x),shape=shape,scale=scale,thres)),
1e-6)
## multinomial probability
-sum(y_log_p(y,prob))
}
startvals2 <- list(scale=1000,shape=1,thres=100)
m2 <- mle2(NLLfun2,start=startvals2,
control=list(parscale=unlist(startvals2)))
summary(m2)
#graphical summary
windows(5,5)
with(dd,plot(cum_per~degree_days,cex=3))
with(as.list(coef(m2)),curve(sum(dd$percent)*
pweibull3(x,shape=shape,
scale=scale,thres=thres),col=4,
add=TRUE))

Using anova() on gamma distributions gives seemingly random p-values

I am trying to determine whether there is a significant difference between two Gamm distributions. One distribution has (shape, scale)=(shapeRef,scaleRef) while the other has (shape, scale)=(shapeTarget,scaleTarget). I try to do analysis of variance with the following code
n=10000
x=rgamma(n, shape=shapeRef, scale=scaleRef)
y=rgamma(n, shape=shapeTarget, scale=scaleTarget)
glmm1 <- gam(y~x,family=Gamma(link=log))
anova(glmm1)
The resulting p values keep changing and can be anywhere from <0.1 to >0.9.
Am I going about this the wrong way?
Edit: I use the following code instead
f <- gl(2, n)
x=rgamma(n, shape=shapeRef, scale=scaleRef)
y=rgamma(n, shape=shapeTarget, scale=scaleTarget)
xy <- c(x, y)
anova(glm(xy ~ f, family = Gamma(link = log)),test="F")
But, every time I run it I get a different p-value.
You will indeed get a different p-value every time you run this, if you pick different realizations every time. Just like your data values are random variables, which you'd expect to vary each time you ran an experiment, so is the p-value. If the null hypothesis is true (which was the case in your initial attempts), then the p-values will be uniformly distributed between 0 and 1.
Function to generate simulated data:
simfun <- function(n=100,shapeRef=2,shapeTarget=2,
scaleRef=1,scaleTarget=2) {
f <- gl(2, n)
x=rgamma(n, shape=shapeRef, scale=scaleRef)
y=rgamma(n, shape=shapeTarget, scale=scaleTarget)
xy <- c(x, y)
data.frame(xy,f)
}
Function to run anova() and extract the p-value:
sumfun <- function(d) {
aa <- anova(glm(xy ~ f, family = Gamma(link = log),data=d),test="F")
aa["f","Pr(>F)"]
}
Try it out, 500 times:
set.seed(101)
r <- replicate(500,sumfun(simfun()))
The p-values are always very small (the difference in scale parameters is easily distinguishable), but they do vary:
par(las=1,bty="l") ## cosmetic
hist(log10(r),col="gray",breaks=50)

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