I have the function:

```
def g(R, r):
return (np.sqrt(2.0 * (R + r) / (r * R)) - (1 + np.sqrt(R)) / np.sqrt(R) -
np.sqrt(2.0 / (r * (1 + r))) * (1 - r) -
(1.0 / np.sqrt(R) - np.sqrt(2.0) * (1 - R) / np.sqrt(R * (1 + R))
- 1))
```

The function is defined by setting `delta v_B = delta v_H`

where `delta v_B`

is

```
np.sqrt(2.0 * (R + r) / (r * R)) - (1 + np.sqrt(R)) / np.sqrt(R) -
np.sqrt(2.0 / (r * (1 + r))) * (1 - r)
```

and `delta v_H`

is

```
1.0 / np.sqrt(R) - np.sqrt(2.0) * (1 - R) / np.sqrt(R * (1 + R)) - 1
```

Therefore, I wrote `g`

as `delta v_b - delta v_H`

.

Now this is my function and the code I am using below:

```
import pylab
import numby as np
def g(R, r):
return (np.sqrt(2.0 * (R + r) / (r * R)) - (1 + np.sqrt(R)) / np.sqrt(R) -
np.sqrt(2.0 / (r * (1 + r))) * (1 - r) -
(1.0 / np.sqrt(R) - np.sqrt(2.0) * (1 - R) / np.sqrt(R * (1 + R))
- 1))
r = np.linspace(11.9, 16, 500000)
R = np.linspace(1, 20, 500000)
fig2 = pylab.figure()
ax2 = fig2.add_subplot(111)
ax2.plot(R, g(R, r), 'r')
pylab.xlabel('$R_1 = \\frac{r_C}{r_A}$')
pylab.ylabel('$R_2 = \\frac{r_B}{r_A}$')
pylab.xlim((0, 25))
pylab.ylim((0, 100))
pylab.show()
```

The function should asymptote to infinity at about `11.94`

and intersect the line `y = x`

at around `15.58`

How can I make such a plot? I am not familiar with how to do this, and I don't know how to plot such a function.

Is my definition improper for `g`

as `g(R, r)`

? If so, how should it be defined if this isn't the case?