Drawing braces with Pyx

How can I draw a “braced” line between two arbitrary points with Pyx?

It would look something like this:

Brace example http://tof.canardpc.com/view/d16770a8-0fc6-4e9d-b43c-a11eaa09304d

• Looks like you create a canvas, find the point between the two endpoints, draw a vertical line for p1 to halfway, draw some sort of nipple at the halfway point, and then draw a vertical line from halfway to p2. Use c.stroke(path.line(p1.x, p2.y, halfway.x, halfway.y))) and c.stroke(path.line(halfway.x, halfway.y, p1.x, p2.y))). Or something. I'm not installing this package to answer this question. Commented Aug 17, 2009 at 18:55
• @hughbrown: Why didn't you post your answer as an answer? Commented Aug 17, 2009 at 19:00
• I don't have this package installed. I figured I could sketch out an approximate answer and Bastien could run with it. Commented Aug 17, 2009 at 19:53

You can draw pretty braces using sigmoidals. I don't have Pyx installed so I'll just plot these using matplotlib (pylab here). Here `beta` controls the sharpness of the curves in the braces.

``````import numpy as nx
import pylab as px

def half_brace(x, beta):
x0, x1 = x[0], x[-1]
y = 1/(1.+nx.exp(-1*beta*(x-x0))) + 1/(1.+nx.exp(-1*beta*(x-x1)))
return y

xmax, xstep = 20, .01
xaxis = nx.arange(0, xmax/2, xstep)
y0 = half_brace(xaxis, 10.)
y = nx.concatenate((y0, y0[::-1]))

px.plot(nx.arange(0, xmax, xstep), y)
px.show()
``````

I plotted this along the x-axis to save screen space, but to get braces along the y-axis just swap x and y. Finally, Pyx has plenty of path drawing functionality built-in which coould also work for your needs.

• Hey, I am particularly interested in knowing how did you wrote half_brace method. Is the math you do is a common standard stuff? Can you help pointing me out some resources to learn this? Commented Aug 28, 2009 at 9:10
• @Vadi - I added a link to sigmoid functions in the first line of the answer. The half_brace function is the sum of two sigmoidals, and I just thought it was easier to do the sum than break this into four parts. Sigmoidals themselves are fairly common, but this depends on your perspective. In physics, for example (but in topics more advanced than basic undergrad), these appear directly as the Fermi-Dirac distribution function. Commented Aug 28, 2009 at 21:26

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()
PS: Don't forget that you can pass `clip_on=False` to `plot` and put it outside of the axis.