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I have a function which must be called in a matrix form. I have tried using multiroot from package rootSolve to compute the roots but its not working at all. Is there a way I would redefine the function below or is there another alternative that is based on Newton-Raphson technique?

library(rootSolve)

  f <- function(q,m){
      c(F1 = 12 * ((exp(q[, 1]) * m[1])/(exp(q[, 1]) * m[1] + exp(q[, 2]) * m[2] + m[3])) - c(1,2),
        F2 = 12 * ((exp(q[, 2]) * m[2])/(exp(q[, 1]) * m[1] + exp(q[, 2]) * m[2] + m[3])) -c(3,3))
    }
    m = c(0.1,0.2,0.7)

2 Answers 2

1

Your function does not have a solution. You can see that the numerators in the expressions of your function values are identical and always positive given the values for m. So you are trying to solve exp(q[, 1]) * m[1]=0) and exp(q[, 2]) * m[2]=0. That is not possible since exp(...) is always larger than zero.

If you try different starting values for q you will get different answers.

1
  • I just noticed it and I have edited it. But again the exp only covers q's. I mean (exp(q[, 1]). I hope this makes more sense after the correction
    – Muhamd
    Nov 14, 2020 at 21:05
1

Wrap it in an outer function that performs the conversion. Since the question was changed note that we use the original data shown in the Note at the end.

multiroot(function(q) f(t(q), m), c(1,1))

giving:

$root
[1] -14.67979 -14.67979

$f.root
          F1           F2 
5.618059e-06 1.123612e-06 

$iter
[1] 13

$estim.precis
[1] 3.370836e-06

Note

f and m are assumed to be:

library(rootSolve)

f <- function(q,m){
  c(F1 = 12 * ((exp(q[, 1]) * m[1])/(exp(q[, 1]) * m[1] + exp(q[, 2]) * m[2] + m[3])),
    F2 = 12 * ((exp(q[, 2]) * m[2])/(exp(q[, 1]) * m[1] + exp(q[, 2]) * m[2] + m[3])))
}
m = c(1,0.2,0.9)
5
  • what does t() do? I thought it might be doing the transpose but I don't get my expected results. I expect -0.1335314, 0.6931472 From the first function and 0.2719337, 0.4054651 from the second function. But I also notice that I get something similar to these when c(1,2) from the first function is replace with c(1,3). With the second function c(3,3) being replaced by c(2,3). Clearly some transpose.
    – Muhamd
    Nov 15, 2020 at 13:03
  • t(x) is the transpose of x. For a plain vector it is the same as matrix(x, 1). Note that multiroot(function(q) f(t(q), m), c(1,1))$f.root, is c(0, 0) to 6 digits using f and m from the question. You are not going to get exactly zero as explained in the other answer, i.e. the ratio of two positive numbers cannot be zero, and also even if the solution existed the solution can only be expected up to numeric approximation. Nov 15, 2020 at 13:41
  • I actually edited the question but as soon as I did that I received an error. My expected solution for q is q <- matrix(c(-0.1335314,0.6931472,0.2719337,0.4054651), nrow=2) But when I ran the code as it is I get Error in stode(y, times, func, parms = parms, ...) but without the transpose I get Error in q[, 1]incorrect number of dimensions. What could be the problem?
    – Muhamd
    Nov 16, 2020 at 20:35
  • another thing I realized from your explanation. q is a matrix and getting its transpose changes everything. If it was a vector there wouldn't be any problem.
    – Muhamd
    Nov 17, 2020 at 11:39
  • If you change the problem then you need to change the answer to correspond. If f and m are as in the revised question and q is the matrix shown in your comment then use multiroot(function(q) f(matrix(q, 2),m), q) Nov 17, 2020 at 14:24

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