tom10 provides a good solution, but could use some improvement.

The key is creates a brace over the range [0,1],[0,1] and then scale it.

This version also lets you tweak the shape a bit. For bonus points, it uses the second derivative to figure out how densely to space the points.

`mid`

sets the balance between the lower and upper parts.

`beta1`

and `beta2`

control how sharp the curves (lower and upper) are.

You can change the `height`

(or just multiply y by a scalar).

Making it vertical instead of horizontal just involves swapping x and y.

`initial_divisions`

and `resolution_factor`

govern how the x values are chosen, but should generally be ignorable.

```
import numpy as NP
def range_brace(x_min, x_max, mid=0.75,
beta1=50.0, beta2=100.0, height=1,
initial_divisions=11, resolution_factor=1.5):
# determine x0 adaptively values using second derivitive
# could be replaced with less snazzy:
# x0 = NP.arange(0, 0.5, .001)
x0 = NP.array(())
tmpx = NP.linspace(0, 0.5, initial_divisions)
tmp = beta1**2 * (NP.exp(beta1*tmpx)) * (1-NP.exp(beta1*tmpx)) / NP.power((1+NP.exp(beta1*tmpx)),3)
tmp += beta2**2 * (NP.exp(beta2*(tmpx-0.5))) * (1-NP.exp(beta2*(tmpx-0.5))) / NP.power((1+NP.exp(beta2*(tmpx-0.5))),3)
for i in range(0, len(tmpx)-1):
t = int(NP.ceil(resolution_factor*max(NP.abs(tmp[i:i+2]))/float(initial_divisions)))
x0 = NP.append(x0, NP.linspace(tmpx[i],tmpx[i+1],t))
x0 = NP.sort(NP.unique(x0)) # sort and remove dups
# half brace using sum of two logistic functions
y0 = mid*2*((1/(1.+NP.exp(-1*beta1*x0)))-0.5)
y0 += (1-mid)*2*(1/(1.+NP.exp(-1*beta2*(x0-0.5))))
# concat and scale x
x = NP.concatenate((x0, 1-x0[::-1])) * float((x_max-x_min)) + x_min
y = NP.concatenate((y0, y0[::-1])) * float(height)
return (x,y)
```

Usage is simple:

```
import pylab as plt
fig = plt.figure()
ax = fig.add_subplot(111)
x,y = range_brace(0, 100)
ax.plot(x, y,'-')
plt.show()
```

PS: Don't forget that you can pass `clip_on=False`

to `plot`

and put it outside of the axis.