# Sampling on a spline to a given max chordal deviation

I'm looking for a fast way to sample points on a spline such that a polygon or linestring through those points does not exceed a given chordal error to the original spline. I have an algorithm I wrote some time ago that produces the results in the picture (see code below if interested; I'm not expecting anyone to pore over it). It works OK, but fast it is not (~2 seconds on my computer to generate that graphic). Is there something easier, maybe built into numpy or scipy that will accomplish this?

Thanks

``````import numpy as np
from scipy.optimize import brentq
from scipy.interpolate import splev

def get_rhos(ts, tck):
"""Get (signed) rhos (1/rad of curvature) for a given
set of t values.
"""
tanvs = np.array(splev(ts, tck, der=1)).T
accvs = np.array(splev(ts, tck, der=2)).T
if tanvs.ndim == 1:
tanvs = tanvs.reshape(1, -1)
accvs = accvs.reshape(1, -1)

crossp = np.cross(accvs, tanvs, axis=1)
tanvms = np.array([np.sqrt(np.dot(v, v)) for v in tanvs])
rhos = crossp / tanvms**3
return rhos

"""Calculate a radius from three points on the arc.
"""
pt0 = np.array(pt0)
pt1 = np.array(pt1)
pt2 = np.array(pt2)

v0 = pt1 - pt0
v1 = pt2 - pt0
v2 = pt2 - pt1
a = np.sqrt(np.dot(v0, v0))
b = np.sqrt(np.dot(v1, v1))
c = np.sqrt(np.dot(v2, v2))
R = (a*b*c) / np.sqrt(  2 * a**2 * b**2
+ 2 * b**2 * c**2
+ 2 * c**2 * a**2
- a**4 - b**4 - c**4)
if calcdrop:
# Calculate arc drop
drop = R - np.sqrt(R**2 - (b/2.)**2)
return R, drop
else:
return R

def chordal_sample(tck, chordaltol, oversample=10):
"""Given a spline definition and a chordal tolerance
(intol/outol), get the t-values for the spline such
that, when adjacent points are connected, the chordal
tolerance is not violated.

Accomplishes this by bracketing a solution, then using
the brentq solver to find the point where the chordal
error equals the chordal tolerance.

Note that a few extra points may be inserted where there
are inflections in the cubic; these are sometimes missed
by the arc-radius-calculating portion of the code.
"""

# This is the function we'll need when we have to
# go searching for the answer via brentq
def makeerrfunc(st, spt, tck, chordaltol):
def errfunc(et):
mt = (st + et) / 2.0
mpt = np.array(splev(mt, tck))
ept = np.array(splev(et, tck))
_, arcdrop = calc_rad(spt, mpt, ept, calcdrop=True)
diff = arcdrop - chordaltol
return diff
return errfunc

# Make sure we're sampling enough points
# TODO: How can we be sure?
ts = np.linspace(0, 1, oversample * len(tck[1][0]))
newts = [0]
# Loop through the time values
for nt in ts:
st = newts[-1]
rts = ts[ts > st] # Only consider remaining time values
# Step through adjacent pairs of time values and find
# ones that bracket the solution.
for et0, et1 in zip(rts[0:-1], rts[1:]):
# Get a 'middle time' that we can use to calc
# a 'middle point' for our arc calculations
mt0 = (st + et0) / 2.
mt1 = (st + et1) / 2.

# Interpolate points at the critical t values
ipts = np.array(splev([st, mt0, et0, mt1, et1], tck))
spt, mpt0, ept0, mpt1, ept1 = ipts.T

_, arcdrop0 = calc_rad(spt, mpt0, ept0, calcdrop=True)
_, arcdrop1 = calc_rad(spt, mpt1, ept1, calcdrop=True)

# Have we bracketed the solution yet? If so, use
# brentq to find a better one within the bracketed
# range, then move on to a new start t.
if arcdrop0 > chordaltol: # Check the initial pair
errfunc = makeerrfunc(st, spt, tck, chordaltol)
mdt = brentq(errfunc, st, et0)
newts.append(mdt)
break
if arcdrop0 <= chordaltol and arcdrop1 > chordaltol:
errfunc = makeerrfunc(st, spt, tck, chordaltol)
mdt = brentq(errfunc, et0, et1)
newts.append(mdt)
break
# Check for the existence of an inflection point
# in the bracketed range by checking the signs
# of the two calculated curvatures and looking for
# a reversal.
if get_rhos(et0, tck)[0] * get_rhos(et1, tck)[0] < 0:
newts.append((et0 + et1) / 2.0)
break
if et1 == 1.0: # No more points to try
newts.append(1.0)
break
return newts

if __name__ == '__main__':
import matplotlib.pyplot as plt
from scipy.interpolate import splprep

# low-res points and then resample at a higher
# res.
XY = np.array([[0.0,  1.0,  2.0, 3.0, 2.0, 1.0, 0.0],
[0.0, -1.0, -0.5, 0.0, 2.5, 1.2, 2.0]])
tck, u = splprep(XY, s=0)
XY = splev(np.linspace(0, 1, 400), tck)
tck, u = splprep(XY, s=0)

# Get a set of t values that will plot out
# a linestring with no more than 0.1 chordal
# error to the original.
ts = chordal_sample(tck, 0.1)

fig, ax = plt.subplots()
# Plot the hi-res spline
ax.plot(*XY)
# Plot the approximated spline
ax.plot(*np.array(splev(ts, tck)), marker='o')

ax.axis('equal')
ax.grid()
plt.show()
``````
-

I found a great solution in one of my favorite modules - Shapely. There's a `simplify()` method on Shapely geometric objects that takes a tolerance and produces this for the same 0.1 value: