# Tag Info

13

Try this: function gini(wagedistarray) nrows = size(wagedistarray,1) Swages = zeros(nrows) for i in 1:nrows for j in 1:i Swages[i] += wagedistarray[j,2]*wagedistarray[j,1] end end Gwages=Swages[1]*wagedistarray[1,2] for i in 2:nrows Gwages+=wagedistarray[i,2]*(Swages[i]+Swages[i-1]) end ...

9

The distribution of the sum of n 0-1 random variables, each with probability p is called a binomial distribution with parameters n and p. I believe numpy.random.binomial will do what you want.

8

Question 1 - why does ntree show 1?: summary(rf) shows you the length of the objects that are included in your rf variable. That means that rf\$ntree is of length 1. If you type on your console rf\$tree you will see that it shows 800. Question 2 - does a negative %IncMSE show a "bad" variable? IncMSE: The way this is calculated is by computing the MSE of ...

7

This may seem a little magical, but actually uses some common idioms: since pandas doesn't yet have nice native support for a contiguous groupby, you often find yourself needing something like this. >>> y * (y.groupby((y != y.shift()).cumsum()).cumcount() + 1) 0 0 1 0 2 1 3 2 4 3 5 0 6 0 7 1 8 0 9 1 10 2 ...

7

You can use addmargins after converting to matrix addmargins(as.matrix(df1),2) # Food Dress Car Sum #[1,] 235 564 532 1331 #[2,] 452 632 719 1803 Or use rowSums df1\$Total <- rowSums(df1) Or with Reduce df1\$Total <- Reduce(`+`, df1)

7

Individual elements can be accessed as below data = read.table("HW6.txt", header = TRUE) data\$X sum(data\$X)

7

This solution takes advantage of the hard work ggplot2 does for you: library(sp) # we have to build the plot first so ggplot can do the calculations ggplot(df,aes(mpg,cyl)) + geom_point() + geom_smooth() -> gg # do the calculations gb <- ggplot_build(gg) # get the CI data p <- gb\$data[[2]] # make a polygon out of it poly <- data.frame( ...

7

x = np.random.rand(3,2) x Out[37]: array([[ 0.03196827, 0.50048646], [ 0.85928802, 0.50081615], [ 0.11140678, 0.88828011]]) x = x[:,1] x Out[39]: array([ 0.50048646, 0.50081615, 0.88828011]) So what that line did is sliced the array, taking all rows (:) but keeping the second column (1)

6

Disclaimer: You have not specified data characteristics, so my answer will assume that it is not too large(more than 1,000,000 sentences, each at most 1,000). Also Description is a bit complicated and I might have not understood the problem fully. Solution: Instead of focusing on different combinations, why don't you create a hashMap(dict in python) for ...

6

I had to take a deep dive into the github repo but I finally got it. In order to do this you need to know how stat_smooth works. In this specific case the loess function is called to do the smoothing (the different smoothing functions can be constructed using the same process as below): So, using loess on this occasion we would do: #data df <- ...

6

The countmap operation is a standard operation in any programming language. Additionally, it is also "raw", like sorting, which means it has to do a basic popular operation over the input data. Operations of this kind are hard to optimize, as they are done similarly in most languages - and if they are not fast enough in the source language, a specialized ...

6

If you want to do the equivalent ANOVA you have to set it up differently. t.test(sam.a,sam.b, var.equal = TRUE)\$p.value #[1] 0.01819264 You need to construct a variable, which describes to which vector a value belongs: samples <- c(sam.a, sam.b) fac <- c(rep("a", length(sam.a)), rep("b", length(sam.b))) summary(aov(samples ~ ...

6

When you do length(dataset) you will return the number of columns in your dataframe, not the number of rows. To fix your loop, you can do 1:nrow(dataset). But actually you can get rid of the for loop entirely in this case and do dataset\$EMAIL <- as.character(dataset\$EMAIL) dataset\$EMAIL[grepl("test", dataset\$EMAIL, ignore.case=T)] <- "TEST"

6

Use right aligment with partial=TRUE, i.e. rollapplyr(..., partial=TRUE) or rollapply(..., align = "right", partial=TRUE). Here we use rollapplyr: rollapplyr(df\$a, 4, mean, partial = TRUE)

6

Let's start with a reproducible example: # Sample data (9 15-element subsets of the letters stored in a list) set.seed(144) (dfs <- replicate(9, sample(letters, 15), simplify=FALSE)) # [[1]] # [1] "b" "r" "y" "l" "g" "n" "a" "u" "z" "s" "j" "c" "h" "x" "m" # # [[2]] # [1] "b" "n" "m" "t" "i" "f" "a" "l" "k" "u" "o" "c" "g" "v" "p" # ... The venn ...

6

Assuming your time were a variable "X", you can use round or trunc. Try: round(X, "hour") trunc(X, "hour") This would still require some work to determine whether the values had actually been rounded up or down (for round). So, If you don't want to have to think about that, you can consider using the "lubridate" package: X <- ...

6

I know this is a very old question, but I think there's a neat trick to do this in O(n) time if you apply a little math! The exponential distribution has two very useful properties. Given n samples from different exponential distributions with different rate parameters, the probability that a given sample is the minimum is equal to its rate parameter ...

6

qnorm is a function, so it is insightful to look for a function that follows the S3 convention of plot.function. If you read the help, you'll see that this function: Draws a curve corresponding to a function over the interval '[from, to]'. 'curve' can plot also an expression in the variable 'xname', default 'x'. Since you are not ...

6

scikit-learn's LinearRegression doesn't calculate this information but you can easily extend the class to do it: from sklearn import linear_model from scipy import stats import numpy as np class LinearRegression(linear_model.LinearRegression): """ LinearRegression class after sklearn's, but calculate t-statistics and p-values for model ...

6

There are lots of things wrong here. for(i in 1:simsize=simsize) should be throwing an error: > for(i in 1:simsize=simsize) { print(i)} Error: unexpected '=' in "for(i in 1:simsize=" Better is for(i in seq_len(simsize)) Then x <- function(ran.func) is not doing what you thought it was; it is returning a function with xbars[i]<-mean(x) as ...

5

It appears that R's qt may use a completely different algorithm than Matlab's tinv. I think that you and others should report this deficiency to The MathWorks by filing a service request. By the way, in R2014b and R2015a, -Inf is returned instead of NaN for small values (about eps/8 and less) of the first argument, p. This is more sensible, but I think they ...

5

Use source instead of source with echo in R Studio.

5

While stats.chisqprob() and 1-stats.chi2.cdf() appear comparable for small chi-square values, for large chi-square values the former is preferable. The latter cannot provide a p-value smaller than machine epsilon,and will give very inaccurate answers close to machine epsilon. As shown by others, comparable values result for small chi-squared values with the ...

5

Tabulating and collapsing Your example vector is vec <- letters[c(1,2,2,2,3,3,4,5,6)] To get a tabulation, use tab <- table(vec) To collapse infrequent items (say, with counts below two), use res <- c(tab[tab>=2],other=sum(tab[tab<2])) # b c other # 3 2 4 Displaying in two columns resdf <- data.frame(count=res) # ...

5

I would go with the following wrapper using base R (you can specify your time zone using the tz argument within the strptime function) Myfunc <- function(x){x <- strptime(x, format = "%F %H") ; c(x, x + 3600L)} Myfunc("2015-01-01 01:50:50") ## [1] "2015-01-01 01:00:00 IST" "2015-01-01 02:00:00 IST"

5

Using the broom package for converting statistical analysis objects into data.frames and dplyr for bind_rows: library(dplyr) ; library(broom) cbind( state = attr(models, "split_labels"), bind_rows(lapply(models, function(x) cbind( intercept = tidy(x)\$estimate[1], beta = tidy(x)\$estimate[2], glance(x)))) ) state intercept beta ...

5

And another way with base-R and regular expressions: all <- c(' 183746IGH','105928759UBS') numeric <- sapply(a, function(x) sub('[[:alpha:]]+','', x)) alphabetic <- sapply(a, function(x) sub('[[:digit:]]+','', x)) > data.frame(all,alphabetic,numeric) all alphabetic numeric 183746IGH 183746IGH IGH ...

5

Other options include tstrsplit from the devel version of data.table library(data.table)#v1.9.5+ setDT(df)[,tstrsplit(V1,'(?<=\\d)(?=\\D)', perl=TRUE, type.convert=TRUE)] # V1 V2 #1: 131341 adad #2: 45365 adadar #3: 425 cavsbsb #4: 46567567 daadvsv If there are elements were 'non-numeric' part appears first and 'numeric' last, ...

5

For random variables X and Y use the fact that E(X-Y) = EX - EY, sd(X) = sqrt(var(X)) and var(X-Y) = var(X) + var(Y). The last equation assumes X and Y are uncorrelated. Now, if we label the peaks A, B, C then there exist the differences A-B, A-C and B-C which is 3 difference values, not 2 (6 differences if A-B and B-A etc. are distinguised). They are ...

5

You would want to build a data.frame containing the intervals and then add a layer of horizontal error bars to plot them. First, i transform your ranges into a data.frame xx<-llply(1:20, function(x) my_confidence_intervals()) xx<-data.frame(y=1:20*50, x=do.call(rbind, xx)) Now I add them to the plot ggplot(data.frame(x = ...

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