source: fact/tools/pyscripts/pyfact/coor.py@ 14530

Last change on this file since 14530 was 14115, checked in by neise, 12 years ago
added member euch2chid and debugges map file access
  • Property svn:executable set to *
File size: 6.3 KB
Line 
1#!/usr/bin/python -tt
2#
3# Dominik Neise
4#
5import os.path
6import numpy as np
7import math
8from euclid import *
9import sys
10
11class Coordinator(object):
12 """ class to transform chid <-> hexagonal coordinates and vice versa """
13
14 def __init__(self, map_file_path = "../map.txt"):
15 """ read map text file and generate from the three columns
16 chid, xe and ye
17 3 dictionaries: chid2coor, coor2chid, chid2nn
18 chid2nn means 'chid_to_next_neighbor_chids'
19
20 this is done by calculating the hexagonal coordinates
21 from the euclidian coordinates given in xe & ye.
22 the center and the two base vectors are hard coded to be:
23 center = Vector2( 0. , 1./2.)
24 ey = Vector2( 0. , 1. )
25 ex = Vector2( sqrt(3)/2. , 1./2. )
26 """
27 _CheckPath(map_file_path)
28 path = os.path.abspath(__file__)
29 path = os.path.dirname(path)
30 map_file_path = os.path.join(path, map_file_path)
31 chid, xe, ye = np.loadtxt(map_file_path, unpack=True)
32 # -ye in order to correct for the sign difference between my mapping file
33 # and FACTmap111030.txt
34 self.x = xe
35 self.y = ye
36 coors = zip(xe,-ye,chid)
37
38 # this list will contain vectors pointing to the center of pixel
39 # in euclidian space. The coordinate system is in the focalplane of the
40 # camera, the unit is not mm, but something like 9mm.
41 # actually the list will not only contain these vectors, but also
42 # also the CHID of the according pixel, both bundled in a tuple
43 vectors_and_chids = []
44 for c in coors:
45 vectors_and_chids.append( (Vector2(c[0], c[1]) , int(c[2])) )
46
47 # In the next few lines, I will calculate hexagonal coordinates from
48 # the euclidian coordinates. The reason is, that I like to work with
49 # integers.
50 # I could have read these numbers from a file instead of calculating,
51 # but this is error prone, because one has to make sure, the different
52 # coordinates in a file are always conincident.
53
54 # The center of the coordinate system is not 0. / 0. since there
55 # is not pixel :-) We decided to define the upper one of the two
56 # central pixels, as 'The Center' :-)
57 center = Vector2( 0. , 1./2.)
58 # the y-axis goes up
59 ey = Vector2( 0. , 1. )
60 # but the x-axis is turned 30degrees up, wrt the euclidian x-axis.
61 ex = Vector2( math.sqrt(3)/2. , 1./2. )
62 self.center = ( center.x , center.y )
63 self.ey = ( ey.x, ey.y)
64 self.ex = ( ex.x, ex.y )
65
66 # these dicts will serve as translators,
67 # e.g. put a chid into chid2coor and you get a Vector2 out, which points
68 # to the center of the according pixel.
69 coor2chid = {}
70 chid2coor = {}
71 chid2coor_np = {}
72 chid2vec = {}
73 euc2chid = {}
74 # we will fill these translators now.
75 for vector_and_chid in vectors_and_chids:
76 vec = vector_and_chid[0]
77 chid = vector_and_chid[1]
78
79 # translating from euclidian into hexagonal
80 # coordinates here...
81 x = (vec-center).x / float(ex.x)
82 y = ((vec-center)-x*ex).y / float(ey.y)
83
84 # I want them to be integger, so I think I have to
85 # treat the values, which are almost zero special,
86 # but maybe rounding is just sufficient, as it is done
87 # in the line after these...
88 if abs(x) < 0.01:
89 x=0.0
90 if abs(y) < 0.01:
91 y=0.0
92
93 # okay, now coor, is the hexagonal coordinate pair of the current pixel
94 # as a tuple
95 coor = (int(round(x)),int(round(y)))
96 # as Vector2
97 coor_vec = Vector2(coor[0], coor[1])
98
99 # since we just calculated this coordinate, we should make
100 # sure, that we did not make an error such, that two pixels have the
101 # same coordinates
102 # other errors like holes in the camera plane cannot be detected so easily
103 if coor in coor2chid:
104 print 'error while filling "coor2chid":'
105 print 'coor:',coor,'of chid:',chid,
106 print 'is equal to coor of chid:',coor2chid[coor]
107
108 # now we fill the translators
109 chid2coor[ chid ] = coor
110 chid2coor_np[ chid ] = np.array(coor)
111 chid2vec[ chid ] = coor_vec
112 # this translator is hardly used by people, but the next step
113 # the calculation of the neighbors needs it
114 coor2chid[ coor ] = chid
115 euc2chid[(vec[0],vec[1])] = chid
116
117
118 # hard code the offsets to the next neighbors
119 # in hexagonal coordinates, the coordinates of neighbors are easily calculated.
120 # just add one of the Vectors below.
121 offsets = [ Vector2(1,0) , # right and up
122 Vector2(-1,0) , # left and down
123 Vector2(1,-1) , # right and down
124 Vector2(0,1) , # up
125 Vector2(0,-1) , # down
126 Vector2(-1,1) ] # left and up
127 # this dict serves as a neighbor look up table
128 # put a CHID in and get a list of neighboring CHIDs out.
129 chid2nn = {}
130 for chid in chid2coor.keys():
131 coor = Vector2( chid2coor[chid][0] , chid2coor[chid][1] )
132 nn_coors = []
133 nn_chids = []
134 for offset in offsets:
135 nn_coors.append( ((coor+offset).x , (coor+offset).y) )
136 for coor in nn_coors:
137 if coor in coor2chid:
138 nn_chids.append( coor2chid[coor] )
139 chid2nn[chid] = nn_chids
140 self.nn = chid2nn
141
142 self.chid2coor = chid2coor
143 self.chid2coor_np = chid2coor_np
144 self.coor2chid = coor2chid
145 self.chid2vec = chid2vec
146 self.euc2chid = euc2chid
147
148# for chid in chid2nn.keys():
149# print chid, '->',chid2nn[chid]
150
151def first(a):
152 return a[0]
153
154def second(a):
155 return a[1]
156
157
158def _CheckPath( inpath ):
159 path = os.path.abspath(__file__)
160 path = os.path.dirname(path)
161 inpath = os.path.join(path, inpath)
162 if not os.path.isfile(inpath):
163 raise IOError('not able to find file: '+inpath)
164
Note: See TracBrowser for help on using the repository browser.