First, this is really a statistics question; you should consider posting it on stats.stackexchange.com - you are likely to get a better answer.

Second, the short answer to your question is that "testing the ratio of two density functions for normality" is not a meaningful idea. As mentioned in the comment, the ratio of two density functions is not a density function. Among other things, a density function must integrate to 1 over (-Inf,+Inf), which this ratio will not (generally).

It is meaningful, however, to test if the distribution of the ratio of two random variables is normal. If you know that the numerator is normally distributed and the denominator is uniformly distributed, then the ratio will definitely *not* be normally distributed, as demonstrated below in the discussion of the slash distribution.

If you do not know the distributions of the numerator and denominator, but just have random samples, you should calculate the ratio of the random variates and test that for normality. In your case (with minor edits):

```
set.seed(123)
ht <- runif(3000, 1, 18585056)
hm <- rnorm(3500, 10000000, 5000000)
Z <- sample(hm,1000)/sample(ht,1000) # numer. and denom. must be same length
par(mfrow=c(1,2))
# histogram of Z
hist(Z,xlim=c(-5,5), breaks=c(-Inf,seq(-5,5,0.2),Inf),freq=F, ylim=c(0,.4))
# normal Q-Q plot
qqnorm(Z,ylim=c(-5,5))
qqline(Z,xlim=c(-5,5),lty=2,col="blue")
```

Clearly, the ratio distribution is *not* normal.

**Slash Distribution**

In the special case

X ~ N[0,1] = φ(x) (-Inf ≤ x ≤ Inf), and

Y ~ U[0,1] = 1 (0 ≤ x ≤ 1); 0 elsewhere

Z = X/Y ~ [ φ(0) - φ(x) ]/x^{2}

That is, a random variable formed as the ratio of two other (independent) random variables, the numerator distributed as N(0,1) and the denominator distributed as U(0,1), has the *slash distribution*, defined above. We can show this in R code as follows

```
set.seed(123)
X <- rnorm(10000)
Y <- runif(10000)
Z <- X/Y
dslash <- function(x) (dnorm(0)-dnorm(x))/x^2
x <- seq(-5,5,0.02)
par(mfrow=c(1,2))
hist(Z,xlim=c(-5,5), breaks=c(-Inf,seq(-5,5,0.2),Inf),freq=F, ylim=c(0,.4))
lines(x,dslash(x),xlim=c(-5,5),col="red")
lines(x,dnorm(x),xlim=c(-5,5),col="blue",lty=2)
qqnorm(Z,ylim=c(-5,5))
qqline(Z,xlim=c(-5,5),lty=2,col="blue")
```

The bars represent the histogram of Z = X/Y, the red curve is the slash distribution, and the blue curve is the pdf of N[0,1] for reference. Because the red curve is "bell shaped" there is a temptation to think that Z is normally distributed, just with a larger variance. The Q-Q plot shows clearly that this is *not the case*. The tails of the slash distribution are much larger than would be expected from a normal distribution.

`dnorm(...)`

and`dunif(...)`

. Second, it looks like you want to test a random variable`X`

with`pdf = dnorm/dunif`

. This is not meaningful, because`dnorm/dunif`

is not a density function (it does not integrate to 1). Rather, if you want to test a random variable`Z = X/Y`

where`X ~ normal`

and`Y ~ uniform`

, that is meaningful. Is that what you are trying to do? This problem has already been solved: Z has the so-called "slash" distribution. – jlhoward Mar 12 '14 at 19:01`rnorm`

and`runif`

here are just to show what they may look like. – edc505 Mar 13 '14 at 11:49