# How to avoid uniroot-function stopping when assumptions not fulfilled?

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I have this function which calculates internal rates of returns for non-periodic cashflows..

xirr <- function(cf, t) {
npv <- function(cf, t, r) sum(cf/((r)^(t/365.25)))
irr <- uniroot(f=npv, interval=c(0,10), cf=cf, t=t, maxiter=100)\$root - 1
return(irr)
}

The problem is, the mathematical assumptions of this formula are not satisfied if the return on the cashflows are less than -100%. I need the function to NOT STOP (throw an error) even if these assumptions aren't fulfilled. I need it to return 0 or something when this happens. At present..

mycashflow <- c(2000, 2000, 3000,4000, -10000)
mydates <-as.integer( c(0,101,200,300,400))

xirr(mycashflow, mydates)

..it throws the error :

Error in uniroot(f = npv, interval = c(0, 10), cf = cf, t = t, maxiter = 100) : f.lower = f(lower) is NA

-

Try catching the error and return directly:

xirr <- function(cf, t) {
npv <- function(cf, t, r) sum(cf/((r)^(t/365.25)))
tryCatch(
irr <- uniroot(f=npv, interval=c(0,10), cf=cf, t=t, maxiter=100)\$root - 1,
error=return(0)
)
return(irr)
}
-

You could try:

irr <- NA

try(irr <- uniroot(f=npv, interval=c(0,10), cf=cf, t=t, maxiter=100)\$root - 1, silent=T)

if(is.na(irr)) irr <- 0

which will try to calulate the irr and assign it to 0 if the unirott function fails.

-

The problem lies with using uniroot itself to find the IRR. You are limiting the solution between a fixed interval of 0% and 1000%

It would be better if you programmed the code to find the XIRR rather than rely on a built-in function to find internal rate of return for irregular cash flows

EDIT

After reading a comment from OP, I am editing this reply to show why you do not need to specify a lower and upper bound to locate a root.

f(i) = 2000 + 2000(1+i)^-0.277 + 3000(1+i)^-0.548 + 4000(1+i)^-0.822 - 10000(1+i)^-1.096
f'(i) = - 553.425(1+i)^-1.277 - 1(1+i)^-1.548 - 3(1+i)^-1.822 + 10(1+i)^-2.096

i(N-1) ############## f(x) ############# f'(x) ############ i(N-1) - f(x)/f'(x)
0 ################### 1000 ############# 5473.97260274 #### -0.182682682683
-0.182682682683 #### -287.317250921 #### 9015.5263858 ##### -0.150813522899
-0.150813522899 #### -13.1104684396 ##### 8209.8448578 #### -0.149216602535
-0.149216602535 #### -0.0301760416678 ### 8172.09143372 ### -0.149212909962
-0.149212909962 #### -1.60673153005E-7 ## 8172.00440952 ### -0.149212909943

IRR = -14.921%

As you can see, the XIRR calculation does not make use of any specific interval in which to locate or find the root of the function.

-
 Actually, I think I'm limiting it to be between -100% to +900%. The problem is that there is no IRR (no root) when the return is less than -100%, this is true whether or not the root-finding function is custom. – ytrew Jan 16 at 9:37 For this particular instance there may not be a root below -100% but still you are restricting the solution between a given interval. Thus for cash flows where the IRR is outside the boundary of -100% and 900% your code will be rendered useless. I am editing my answer above to display a XIRR calculation for your cash flows with code that does not use boundaries to locate a root. – Abraham A Jan 16 at 12:46