#-*- coding:utf-8 -*-
"""
道格拉斯算法的实现
程序需要安装shapely模块
"""
import math
from shapely import wkt,geometry
class Point:
"""点类"""
x=0.0
y=0.0
index=0 #点在线上的索引
def __init__(self,x,y,index):
self.x=x
self.y=y
self.index=index
class Douglas:
"""道格拉斯算法类"""
points=[]
D=1 #容差
def readPoint(self):
"""生成点要素"""
g=wkt.loads("LINESTRING(1 4,2 3,4 2,6 6,7 7,8 6,9 5,10 10)")
coords=g.coords
for i in range(len(coords)):
self.points.append(Point(coords[i][0],coords[i][1],i))
def compress(self,p1,p2):
"""具体的抽稀算法"""
swichvalue=False
#一般式直线方程系数 A*x+B*y+C=0
A=(p1.y-p2.y)/math.sqrt(math.pow(p1.y-p2.y,2)+math.pow(p1.x-p2.x,2))
B=(p2.x-p1.x)/math.sqrt(math.pow(p1.y-p2.y,2)+math.pow(p1.x-p2.x,2))
C=(p1.x*p2.y-p2.x*p1.y)/math.sqrt(math.pow(p1.y-p2.y,2)+math.pow(p1.x-p2.x,2))
m=self.points.index(p1)
n=self.points.index(p2)
distance=[]
middle=None
if(n==m+1):
return
#计算中间点到直线的距离
for i in range(m+1,n):
d=abs(A*self.points[i].x+B*self.points[i].y+C)/math.sqrt(math.pow(A,2)+math.pow(B,2))
distance.append(d)
dmax=max(distance)
if dmax>self.D:
swichvalue=True
else:
swichvalue=False
if(not swichvalue):
for i in range(m+1,n):
del self.points[i]
else:
for i in range(m+1,n):
if(abs(A*self.points[i].x+B*self.points[i].y+C)/math.sqrt(math.pow(A,2)+math.pow(B,2))==dmax):
middle=self.points[i]
self.compress(p1,middle)
self.compress(middle,p2)
def printPoint(self):
"""打印数据点"""
for p in self.points:
print "%d,%f,%f"%(p.index,p.x,p.y)
def main():
"""测试"""
#p=Point(20,20,1)
#print '%d,%d,%d'%(p.x,p.x,p.index)
d=Douglas()
d.readPoint()
d.printPoint()
d.compress(d.points[0],d.points[len(d.points)-1])
print "========================\n"
d.printPoint()
if __name__=='__main__':
main()
部分修改后:
#-*- coding:utf-8 -*-
"""
道格拉斯算法的实现
程序需要安装shapely模块
"""
import math
from shapely import wkt,geometry
import matplotlib.pyplot as plt
class Point:
"""点类"""
x=0.0
y=0.0
index=0 #点在线上的索引
def __init__(self,x,y,index):
self.x=x
self.y=y
self.index=index
class Douglas:
"""道格拉斯算法类"""
points=[]
D=1 #容差
def readPoint(self):
"""生成点要素"""
g=wkt.loads("LINESTRING(1 4,2 3,4 2,6 6,7 7,8 6,9 5,10 10)")
coords=g.coords
for i in range(len(coords)):
self.points.append(Point(coords[i][0],coords[i][1],i))
def compress(self,p1,p2):
"""具体的抽稀算法"""
swichvalue=False
#一般式直线方程系数 A*x+B*y+C=0,利用点斜式,分母可以省略约区
#A=(p1.y-p2.y)/math.sqrt(math.pow(p1.y-p2.y,2)+math.pow(p1.x-p2.x,2))
A=(p1.y-p2.y)
#B=(p2.x-p1.x)/math.sqrt(math.pow(p1.y-p2.y,2)+math.pow(p1.x-p2.x,2))
B=(p2.x-p1.x)
#C=(p1.x*p2.y-p2.x*p1.y)/math.sqrt(math.pow(p1.y-p2.y,2)+math.pow(p1.x-p2.x,2))
C=(p1.x*p2.y-p2.x*p1.y)
m=self.points.index(p1)
n=self.points.index(p2)
distance=[]
middle=None
if(n==m+1):
return
#计算中间点到直线的距离
for i in range(m+1,n):
d=abs(A*self.points[i].x+B*self.points[i].y+C)/math.sqrt(math.pow(A,2)+math.pow(B,2))
distance.append(d)
dmax=max(distance)
if dmax>self.D:
swichvalue=True
else:
swichvalue=False
if(not swichvalue):
for i in range(m+1,n):
del self.points[i]
else:
for i in range(m+1,n):
if(abs(A*self.points[i].x+B*self.points[i].y+C)/math.sqrt(math.pow(A,2)+math.pow(B,2))==dmax):
middle=self.points[i]
self.compress(p1,middle)
self.compress(middle,p2)
def printPoint(self):
"""打印数据点"""
for p in self.points:
print "%d,%f,%f"%(p.index,p.x,p.y)
def main():
"""测试"""
#p=Point(20,20,1)
#print '%d,%d,%d'%(p.x,p.x,p.index)
d=Douglas()
d.readPoint()
#d.printPoint()
#结果图形的绘制,抽稀之前绘制
fig=plt.figure()
a1=fig.add_subplot(121)
dx=[]
dy=[]
for i in range(len(d.points)):
dx.append(d.points[i].x)
dy.append(d.points[i].y)
a1.plot(dx,dy,color='g',linestyle='-',marker='+')
d.compress(d.points[0],d.points[len(d.points)-1])
#抽稀之后绘制
dx1=[]
dy1=[]
a2=fig.add_subplot(122)
for p in d.points:
dx1.append(p.x)
dy1.append(p.y)
a2.plot(dx1,dy1,color='r',linestyle='-',marker='+')
#print "========================\n"
#d.printPoint()
plt.show()
if __name__=='__main__':
main()
结果: