# How to efficiently get 10% of random numbers, then 10% of remaining 90 etc untill all points allocated

This is what I want to do :

I have 300 000 points.

I want 10% of the points.

I then want 10% of the remaining 90% of points.

I then want 10% of the remaining 81% of points

I then want 10% of the remaining 73% of points

etc until i'm finished with all the points.

Is this the fastest way of doing it:

``````#all the points
s = np.arange(len(c_list))
np.random.shuffle(s)

#first 10%
s1 = np.arange(len(c_list)*10/100)
np.random.shuffle(s1)

k = s1

while len(k)<len(s) :

r = [x for x in s if x not in k]#get the remaining points
r = r[0:len(r)*10/100] #third cluster
s2 = r #4th cluster,#5th,6th,7th cluster etc , here i go through each point in this cluster  if i find another 1 point with c value of 1 in a certain radius i delete the point ,but if i dont i assign its c value a 1
k = np.concatenate((k, s2))
``````

here is my actual full point cloud simplification algorithm

``````from sklearn.neighbors import NearestNeighbors
import numpy as np

###Plane Fit Function
def fitPlaneEigen(XYZ):

#Get the covar matrix
average=sum(XYZ)/XYZ.shape[0]
b = np.transpose(XYZ - average)
cov=np.cov(b)

#Get eigen val and vec
e_val,e_vect = np.linalg.eigh(cov)

#diagonlize eigen vals
##    print 'eigenvalues'
e_val_d = np.diag(e_val)
##    print e_val_d

#find min eigen val
h = np.rank(min(e_val))

#Ffind normal
norm =  e_vect[:,h]

#calc curvature
curvature = e_val[0]/(e_val[0]+e_val[1]+e_val[2])

return curvature #return curvature

###Input point cloud and add a colum for information content

f_name = '10 scan rabit'
c_list = np.genfromtxt(str(f_name)+'.txt',autostrip=True)
##
##c_list = np.array([[-0.0369122 ,  0.12751199 , 0.00276757],
## [-0.0398624 ,  0.128204  ,  0.00299348],
## [-0.0328896  , 0.12613    , 0.00300653],
## [-0.0396095 ,  0.12667701 ,-0.00334699],
## [-0.0331765,   0.12681  ,   0.00839958],
## [-0.0400911   ,0.128618  ,  0.00909496],
## [-0.0328901  , 0.124518 ,  -0.00282055]])

##XYZ = np.random.randn(100, 3)
##c_list = XYZ

c_list = np.hstack((c_list, np.zeros((c_list.shape[0], 1), dtype=c_list.dtype))) #add another column to our coordinate list for the informaton content
c_list = np.hstack((c_list, np.zeros((c_list.shape[0], 1), dtype=c_list.dtype))) #add another column to our coordinate list for the keep/delete

#Determine the neighbourhood at each point, fit a plane and work out curvature at each point.

neigh = NearestNeighbors(3) #this means 7 points in neighbourhood
neigh.fit(c_list)

for i in range(0,len(c_list)):
print i*100/len(c_list)
d = neigh.kneighbors(c_list[i])

y = np.zeros((1,3)) #change brackets, to many maybe?

#add coordinates of neighbours to array

for c in range(1,3): #we do not want to include the first neighbour , this is because its our original point
f = d[1][0][c]
g = c_list[f] #get coordinates

y = np.vstack([y,[g[0],g[1],g[2]]])

b = fitPlaneEigen(y) #fit plane

c_list[i][3] = b

###Simplify

#get the max eigen value
eig_max = np.max(c_list[:][3])

eig_min = np.min(c_list[:][3])

#get the point distance for flat areas from user
flat_dist = 0.01

#get the straight line equation
#y=mx+c

##print eig_min
##print x
##

##np.random.shuffle(XYZ)
##points.shape = (10,-1) + points.shape[1:]

##l3 = [x for x in l1 if x not in l2]
#all the points
##s = np.random.choice(len(c_list),size = len(c_list),replace = False)
s = np.arange(len(c_list))
np.random.shuffle(s)

#first seed points - keep - set 1 - 10%
##s1 = np.random.choice(s,size = len(c_list)*10/100,replace = False)

s1 = np.arange(len(c_list)*10/100)
np.random.shuffle(s1)

for i in range(0,len(s1)):
p =  s1[i]
c_list[p][4] =1

#remaining points
##r = [x for x in s if x not in s1]
##
##s2 = np.random.choice(r,size = len(r)*10/100,replace = False)
##
##for i in range (0,len(s2)):
##
##    p =  s1[i]
##    c_list[p][4] =1

k = s1

while len(k)<len(s) :

#keep points

print len(s)-len(k)
r = [x for x in s if x not in k]

r = r[0:len(r)*10/100]
#s2 = np.random.choice(r,size = len(r)*10/100,replace = False)
s2 = r
for i in range (0,len(s2)):

print i*100/len(s2)

p =  s2[i]
x = c_list[p][3]

neigh.fit(c_list[:,0:3])

tt= neigh.radius_neighbors(c_list[p,0:3]) #fit xyz check this
n = [] #empty list to store scalars of neighbouring points
for i in range(0,len(tt[1][0])):
v = tt[1][0][i] #neighbouring point index
n.append(c_list[v][4])

if np.sum(n) < 1:
c_list[p][4] =1

if len(s2)<10:#i.e only 10 points left,keep them all

for i in range (0,len(s2)):
p =  s2[i]
c_list[p][4] =1
break
else:
k = np.concatenate((k, s2))

np.savetxt('letssee.txt',c_list)
``````
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duplucation of stackoverflow.com/questions/18796191/3d-random-sampling ? Can you explain "point cloud simplification algorithm"? –  Jan Kuiken Sep 17 '13 at 14:40

I think you can simplify things quite a bit:

``````# You would have n = 300000 and k = 0.1, changed for a simpler sample output
n = 10
c_list = np.random.rand(n)
k = 0.5

take = []
while n > 1:
# round up to always take at least 1 item
take.append(int(np.ceil(n * k)))
n -= take[-1]
# You can skip the copying if you don't mind shuffling c_list
c_copy = c_list.copy()
np.random.shuffle(c_copy)
groups = np.split(c_copy, np.cumsum(take))

>>> c_list
array([ 0.11444327,  0.82500303,  0.03582646,  0.90688504,  0.98204763,
0.34391556,  0.89169497,  0.30899009,  0.50246339,  0.37812873])
>>> c_copy
array([ 0.98204763,  0.34391556,  0.89169497,  0.11444327,  0.82500303,
0.30899009,  0.37812873,  0.90688504,  0.50246339,  0.03582646])
>>> for group in groups: print group
...
[ 0.98204763  0.34391556  0.89169497  0.11444327  0.82500303]
[ 0.30899009  0.37812873  0.90688504]
[ 0.50246339]
[ 0.03582646]
``````
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thanks bro you such a boss!!! –  West1234 Sep 17 '13 at 16:04