# Solve systems of non-linear equations in R / Black-Scholes-Merton Model

I am writing my masters thesis and I got stuck with this problem in my R code. Mathematically, I want to solve this system of non-linear equations with the R-package “nleqslv”:

``````fnewton <- function(x){

y <- numeric(2)

d1 = (log(x[1]/D1)+(R+x[2]^2/2)*T)/x[2]*sqrt(T)

d2 = d1-x[2]*sqrt(T)

y1 <- SO1 - (x[1]*pnorm(d1) - exp(-R*T)*D1*pnorm(d2))

y2 <- sigmaS*SO1 - pnorm(d1)*x[2]*x[1]

y}

xstart <- c(21623379, 0.526177094846878)

nleqslv(xstart, fnewton, control=list(btol=.01), method="Newton")
``````

I have tried several versions of this code and right now I get the error:

`error: error in pnorm(q, mean, sd, lower.tail, log.p): not numerical.`

Pnorm is meant to be the cumulative standard Normal distribution of d1and d2 respectively. I really don’t know, what I am doing wrong as I oriented my model on Teterevas slides ( on slide no.5 is her model code), who’s presentation is the first result by googeling

Like me, however more successfull, she calculates the Distance to Default risk measure via the Black-Scholes-Merton approach. In this model, the value of equity (usually represented by the market capitalization, ->SO1) can be written as a European call option – what I labeled y2 in the above code, however, the equation before is set to 0!

The other variables are:

x[1] -> the variable I want to derive, value of total assets

x[2] -> the variable I want to derive, volatility of total assets

D1 -> the book value of debt (1998-2009)

R -> a risk-free interest rate

T -> is set to 1 (time)

sigmaS -> estimated (historical) equity volatility

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Don't call a variable `T`. That's an alias for `TRUE` in R and overwriting that could have unforeseen consequences. However, you need to check if all variables used for calculating `d1` and `d2` are numeric. –  Roland Sep 23 '13 at 12:13
None of D1, R, T, or SO1 are defined in code. –  BondedDust Sep 23 '13 at 12:34
@Roland: Thanks, I will try this. –  schloni Sep 23 '13 at 12:42
Great, .... except that doesn't help people who are trying to help you. –  BondedDust Sep 23 '13 at 12:46
You do not seem to assign anything to `y`: your function is just returning `c(0,0)` each time. –  Vincent Zoonekynd Sep 23 '13 at 12:48

I am the author of nleqslv and I'm quite suprised at how you are using it. As mentioned by others you are not returning anything sensible.

y1 should be y[1] and y2 should be y[2]. If you want us to say sensible things you will have to provide numerical values for D1, R, T, sigmaS and SO1. I have tried this:

``````T <- 1; D1 <- 1000; R <- 0.01;sigmaS <- .1;SO1 <- 1000 .
``````

These have been entered before the function definition. See this

``````library(nleqslv)

T <- 1
D1 <- 1000
R <- 0.01

sigmaS <- .1
SO1 <- 1000

fnewton <- function(x){
y <- numeric(2)
d1 <- (log(x[1]/D1)+(R+x[2]^2/2)*T)/x[2]*sqrt(T)
d2 <- d1-x[2]*sqrt(T)
y[1] <- SO1 - (x[1]*pnorm(d1) - exp(-R*T)*D1*pnorm(d2))
y[2] <- sigmaS*SO1 - pnorm(d1)*x[2]*x[1]
y
}

xstart <- c(21623379, 0.526177094846878)
``````

`nleqslv` has no problem in finding a solution in this case. Solution found is : c(1990.04983,0.05025). There appears to be no need to set the `btol` parameter and you can use method `Broyden`.

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Thanks for your help! It worked, finally:-) –  schloni Oct 5 '13 at 12:35