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0

Here is another possibility which groups rows where the time difference between consecutive rows is less than 4 days. # create date variable df\$date <- with(df, as.Date(paste(YEAR, MONTH, DAY, sep = "-"))) # identify gap between dates larger than 4 df\$gap <- c(0, (diff(df\$date) > 4)*1) # cumulative sum of 'gap' variable df\$group <- ...

0

I would try something along these lines. Since you mention that you only need to figure out the subsetting logic, I haven't bothered to add the correlation coeff calculation. df\$date <- as.Date(paste(df\$YEAR,df\$MONTH,df\$DAY),'%Y %m %d') uniquedates <- unique(df\$date) uniquedatesfourth <- uniquedates + 4 for ( i in seq(length(uniquedates))) { ...

1

You're missing a colon: if n==0: You'll need one after the else too.

1

You obtain 4 values because df_2 has 4 rows. You need to tell R to use, e.g., the first row of df_2 for the w values for plot == 1. The following code produces the expected output: weibull_density <- transform(df, density = as.vector(sapply(unique(plot), function(x) dweibull(w[plot %in% x], scale = df_2\$scale[x], shape = df_2\$shape[x]))))

2

I think this maybe the simplest?? > df3=merge(df, df_2) > res=mapply(dweibull, x=df3\$w, shape=df3\$shape, scale=df3\$scale) > head(res) [1] 0.11900795 0.09575625 0.09021534 0.04742028 0.08339647 0.01091331 > length(res) [1] 1200 maybe???

1

As pointed out in the comments, ddply is good choice, however, the problem is easily solved by a lapply as well: do.call(rbind, lapply(split(dataset, dataset\$Trial.Group), function(tgDf) { do.call(rbind, lapply(c("Trait1", "Trait2", "Trait3"), function(trait) { ## you don't need the trial group, it is already subsetted. AOV_gtx(trait, tgDf) ...

0

Try using EXCEPT. SELECT ColumnA FROM TableA EXCEPT SELECT ColumnB FROM TableB It will give you a list of everything that's in A that's not in B. You can insert the result from the above into a table variable, and then check its COUNT (0 = subset, anything else is not subset).

0

Try following. This basically looks for anything that is in @q but not in @a and gets its count. If the count is more than 0 then it returns No otherwise Yes. SELECT CASE WHEN COUNT(*) > 0 THEN 'No' ELSE 'Yes' END FROM @q q LEFT JOIN @a a ON q.A = a.B WHERE a.B iS NULL Hope it helps.

1

Here's a function for you to play with. Hopefully it's something you can modify to suit your needs: almostComplete <- function(dataset, rowPct, colPct = rowPct, n = 1) { if (sum(is.na(dataset)) == 0) out <- dataset else { CS <- colSums(is.na(dataset))/ncol(dataset) RS <- rowSums(is.na(dataset))/nrow(dataset) if (is.null(rowPct)) ...

0

Maybe you could use apply with the function : count.na <- function(vec) { return (length(which(is.na(vec)))) } And finaly choose colums and rows with a percentage of NA

7

You got the first point right that you can not access v1 when you set .SDcols to be c('v2', 'v3'). As for the second point not returning the the output as you expect, you should use c instead of list because lapply(.SD, mean) already returns a list. sd.cols = c("v1","v2", "v3") dt.out = dt[, c(sum(v1), lapply(.SD,mean)), by = grp, .SDcols = sd.cols] ...

3

Try this: dt[,list(sum(v1), mean(v2), mean(v3)), by=grp] In data.table, using list() in the second argument allows you to describe a set of columns that result in the final data.table. For what it's worth, .SD can be quite slow [^1] so you may want to avoid it unless you truly need all of the data supplied in the subsetted data.table like you might for ...

3

Seems like a good time to pull out sparse matrices, and we can multiply by abs(x) > 9 to zero out all the small elements: require(Matrix) x <- matrix(runif(100), 10,10) x <- Matrix(x * (abs(x) > .9), sparse=TRUE) summary(x) #10 x 10 sparse Matrix of class "dgCMatrix", with 14 entries # i j x #1 3 1 0.9997396283 #2 8 1 ...

1

The data sounds like it should be a matrix set.seed(123) m = matrix(runif(26*26, -1, 1), nrow=26, dimnames=list(letters, LETTERS)) coerce it to a 'long' data.frame df = data.frame(Row=rownames(m)[row(m)], Col=colnames(m)[col(m)], Value=as.vector(m)) and subset as desired df[df\$Value > 0.9,] so > head(df[df\$Value > 0.9,]) ...

3

An attempt: sapply(df,function(x) table(cut(x[x<0.009],c(0,0.000001,0.001,0.002,Inf))) ) # o m l c a aa ep #(0,1e-06] 2 0 0 5 5 0 0 #(1e-06,0.001] 3 4 5 0 0 5 4 #(0.001,0.002] 0 0 0 0 0 0 1 #(0.002,Inf] 0 1 0 0 0 0 0

1

It looks like within() or subset() may help you: data = data.frame(correl = runif(100, -1, 1), y = rnorm(100), z = sample(letters, 100, TRUE)) data = within(data, { label = ifelse(correl > -1.0 & correl < -0.9, 'Neg', ifelse(correl > 0.9 & correl < 1.0, 'Pos', 'None')) }) data = subset(data, label != 'None') require(reshape2) ...

1

Basically, a data frame or matrix containg 3 columns: miRNA_name ; mRNA_name ; Corr_Score You could use melt: cor(longley, method = "spearman") melt(cor(longley, method = "spearman")) And then do the subsetting...

1

Let dat be a data frame and cols a vector of column names or column numbers of interest. Then you can use dat[!rowSums(is.na(dat[cols])), ] to exclude all rows with at least one NA.

0

You can use apply and na.omit: unlist(apply(mat, 2, na.omit)) # [1] 9 2 4 2 2 4 1 2 7 2 32 1 5 2 1 1 4 2 1 1 You can also use na.omit(as.vector(mat))

0

Try this: #dummy data mat <- matrix(rep(c(1,2,3,NA),7),ncol=4) mat # [,1] [,2] [,3] [,4] # [1,] 1 NA 3 2 # [2,] 2 1 NA 3 # [3,] 3 2 1 NA # [4,] NA 3 2 1 # [5,] 1 NA 3 2 # [6,] 2 1 NA 3 # [7,] 3 2 1 NA mat[!is.na(mat)] # [1] 1 2 3 1 2 3 1 2 3 1 2 3 1 2 3 1 2 3 1 2 3

0

If I got it clearly can subset function be of help dataset1 <- data.frame( age=c(44,77,21,55,66,90,23,54,31), height=c(144,177,121,155,166,190,123,154,131) ) data1 <- as.data.frame(subset(dataset1,dataset1\$age>50 | dataset1\$height>140)) colnames(data1) <- c("Age", "Height")

0

I may have missed what you were trying to do need a bit more reproducible data I think. Nevertheless I had a go dataset1 = data.frame(cbind((35:75),(135:175))) colnames(dataset1) = c("Age","Height") Age Height 35 135 36 136 37 137 38 138 39 139 40 140 41 141 42 142 43 143 44 144 and subset data1 = dataset1[dataset1\$Age>50 | ...

2

When using foldr you don't have to test if the input list is empty, foldr takes care of that for you. And this seems like a job better suited for filter: (define (subset_length_n n lst) (filter (lambda (e) (= (length e) n)) (powerset lst))) If you must, you can use foldr for this, but it's a rather contrived solution. You were very close to ...

0

I think you can cover off both the start and end of sequence possibilities with either: # [ based subsetting df[c(FALSE,diff(df\$time) >= 15) | c(diff(df\$time) >= 15,FALSE),] # subset function subset(df, c(FALSE,diff(time) >= 15) | c(diff(time) >= 15,FALSE))

2

You can use sapply() to apply function to each column of d and then calculate difference for range of column values. Then compare it to 99. As result you will get TRUE or FALSE and then use it to subset columns. d[,sapply(d,function(x) diff(range(x))>99)]

1

This is one way: # create some random data df <- data.frame(y=rnorm(100),x1=rnorm(100), x2=rnorm(100),x3=rnorm(100)) # introduce random NA's df[round(runif(10,1,100)),]\$x1 <- NA df[round(runif(10,1,100)),]\$x2 <- NA df[round(runif(10,1,100)),]\$x3 <- NA # this does the actual work... # assumes data is in columns 2:4, but can be anywhere for (i ...

1

Edit: I completely glossed over subset, the built in function that is made for sub-setting things: my.df <- subset(my.df, !(is.na(termA) | is.na(termB) | is.na(termC) ) ) I tend to use with() for things like this. Don't use attach, you're bound to cut yourself. my.df <- my.df[with(my.df, { !(is.na(termA) | is.na(termB) | ...

2

A much easier way to create the matrix is replicate: replicate(10, sample(10)) The first 10 represents the number of columns.

2

Just subset the data using [] brackets and is.na. > train\$Rating[is.na(train\$Rating)] = pred\$Rating[is.na(train\$Rating)] > train ID Rating 1 1 1 2 2 2 3 3 3 4 4 4 5 5 5 6 6 4 7 7 7 8 8 8 9 9 7 10 10 10 Or, going the other way: > pred\$Rating[!is.na(train\$Rating)] = ...

0

You need to convert your data from long to wide format first. You can subset the values from there. The example below finds the average for everything. library(reshape2) library(plyr) pred2 <- melt(pred, id=c("ID", "User.ID", "Rating")) means <- ddply(pred2, .(variable), summarize, mean.values = mean(value)) mean(means\$mean.values) #mean of means ...

0

transform(pred, Rating = Rating + (Rating == 0) * usermean\$Mean[match(User, usermean\$User)]) ID Rating User 1 1 1 1 2 2 2 1 3 3 3 2 4 4 4 2 5 5 5 3 6 6 9 4 7 7 9 4 8 8 7 5

2

pred\$Rating[pred\$Rating == 0 ] <- usermean\$Mean[pred\$User[pred\$Rating == 0 ] ] #> pred # ID Rating User #1 1 1 1 #2 2 2 1 #3 3 3 2 #4 4 4 2 #5 5 5 3 #6 6 9 4 #7 7 9 4 #8 8 7 5

0

Here's a general solution. First, create a data frame by combining trind and pred. test <- rbind(trind, pred) Second, remove the rows associated with duplicated IDs. test <- test[!duplicated(test\$ID), ]

1

Use the "[" extraction function rather than "[[". plot(chnshp[chnshp\$NAME_1=='Hainan', ]) It makes more sense to send a logical vector of length 32 to "[" than to "[[" which is expecting a length one argument. (And it's probably better not to refer to these as 'attributes', since that is a term with particular meaning in R.

2

Let s be a sorted list representing a given subset of 1..n. There are (n-s[0]) choose k subsets with lowest element greater than s[0]. Of the subsets that start with s[0], (n-s[1]) choose (k-1) subsets have second element greater than s[1], and so on. I haven't worked out a proof, but the following function should work: def choose(n, k): ... def ...

1

I think you could do this by recursively narrowing down ranges, right? You know that all subsets beginning with a given integer will be adjacent, and that for a given first element d there will be (n - d) choose (k-1) of them. You can skip ahead as far as necessary in the virtual list of subsets until you're in the range of subsets beginning with the first ...

0

Where df is your data.frame, this will create a list of 20 data.frames with each element being the dataset for one team. This also assumes that the dataset is already ordered, since you mentioned it. setnames(df,c('hometeam','awayteam','homegoals','awaygoals','fixturedate')) allteams <- sort(unique(df\$hometeam)) eachteamlastfive <- vector(mode = ...

0

take a look at sapply sapply(unique(new[,1]), function(team) head(new[new[,1] == team | new[,2] == team,], 5))

4

Step by step: # create some data where some "name" occur more than 3 times df <- data.frame(name = c("a", "a", "a", "b", "b", "c", "c", "c", "c"), x = sample(1:9)) df # count each 'name', assign result to an object 'tt' tt <- table(df\$name) tt # which 'name' in 'tt' occur more than three times? # Result is a logical vector that can be used to subset ...

1

The plyr package offers functions to make the whole split/apply/combine construct easy. To my knowledge, however, you can only split one thing: a list, a data.frame, an array. In your case, what you are trying to do is split two objects, then mapply (or Map), then recombine. Since plyr does not have a ready solution for this more complicated construct, you ...

1

You can use itertools.combinations and list comprehension like this from itertools import combinations def myStrings(s): return ["".join(item) for i in range(1,len(s)) for item in combinations(s,i)] print myStrings('ab') print myStrings('abc') print myStrings('abcd') Output ['a', 'b'] ['a', 'b', 'c', 'ab', 'ac', 'bc'] ['a', 'b', 'c', 'd', 'ab', ...

0

there is a better way to output the local variables of a function into the global environment. R provides a special assignment operator which comes in handy here. myfunct <- function(x, y) { val1 <<- x + y val2 <<- x - y result <- val1 * val2 return(result) } please notice the extra character in the assignment ...

1

You cannot access local variables in the function, but you can return them as needed. For instance if you have: myfunct <- function(x, y) { val1 <- x + y val2 <- x - y result <- val1 * val2 return(result) } The only thing you have access to is the final result. If you want to have access to val1 and val2 ...

4

Even more easily, you can just use the subset argument of glm(): glm(...,data=all,subset=(Year != 1998))

1

Year<-as.factor(c(1996,1997,1998,1999,2000)) Shr<-as.numeric(c(1,32,1,50,42)) dat <- data.frame(Year=Year, Shr = Shr) # your data #> dat # Year Shr #1 1996 1 #2 1997 32 #3 1998 1 #4 1999 50 #5 2000 42 > levels(dat\$Year) #[1] "1996" "1997" "1998" "1999" "2000" Depending on what you want to achieve you can: dat2 <- dat[!(dat\$Year ...

3

Assuming you have your data in a data.frame called da.fr, you can use da.fr2<-da.fr[da.fr\$Year!=1998,] da.fr2\$Year<-droplevels(da.fr2\$Year) The first line makes a new data.frame without any of the 1998 data. The second line will remove 1998 as a factor in Year, as it is no longer in the dataset.

1

In each case, flipped by row or flipping by column, the same number of points need to be moved: only elements in the middle row/column (when N is odd) stay fixed in position. So you are doing the same amount of work either way. Note that you can get a tiny performance boost by using seq.int. flip.by.col2 <- function(x) x[, seq.int(ncol(x), 1)] ...

1

Try ordering the data set by random number : data<-data[order(data\$Random_number),] Then subset by taking out duplicate values of Class data<-subset(data, !duplicated(Class))

1

try this one: import java.io.BufferedReader; import java.io.InputStreamReader; public class Rozwiazanie { public static void main(String[] args) { try { BufferedReader br = new BufferedReader(new InputStreamReader(System.in)); String[] splittedLinia = br.readLine().split((char) 32 + "");//moglaby byc " " ale tak na ...

0

If purpose is just to get average, unique count etc, you don't need to subset.and one more thing, id T factor is is continuous and you need to make the bins? here I am assuming factor here is one approach with plyr ddply(df,~T,summarise,l=length(unique((A)))) ddply(df,~T,summarise,m=mean(thetadeg))

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