source: src/mlx/util.py@ 128:e14fcd9d9215

Last change on this file since 128:e14fcd9d9215 was 97:f885322fb296, checked in by István Váradi <ivaradi@…>, 13 years ago

The PIREP can be created and sent.

File size: 4.6 KB
Line 
1# Various utilities
2
3import math
4import time
5
6#------------------------------------------------------------------------------
7
8# The average of the radius at the poles and a the equator, in metres
9#EARTH_RADIUS=6367467.4
10EARTH_RADIUS=6371000
11#EARTH_RADIUS=6378137
12
13#------------------------------------------------------------------------------
14
15def getDegMinSec(degrees):
16 """Break up the given floating point degrees value into a tuple.
17
18 The tuple contains 4 items:
19 - the degrees as an integer
20 - the minutes as an integer
21 - the seconds as an integer
22 - 1.0 if the value was non-negative, -1.0 if it was negative."""
23
24 if degrees<0:
25 degrees = -degrees
26 mul = -1.0
27 else:
28 mul = 1.0
29
30 deg = int(degrees)
31 min = int((degrees*60.0)%60.0)
32 sec = int((degrees*3600.0)%60.0)
33
34 return (deg, min, sec, mul)
35
36#------------------------------------------------------------------------------
37
38def getCoordinateString((latitude, longitude)):
39 """Get the string representation of the given coordinate pair."""
40
41 latitude_str = getLatitudeString(latitude)
42 longitude_str = getLongitudeString(longitude)
43
44 return latitude_str + " " + longitude_str
45
46#------------------------------------------------------------------------------
47
48def getLatitudeString(latitude):
49 """Get a string representation of the given latitude."""
50 return getDegreeString(latitude, ["N", "S"])
51
52#------------------------------------------------------------------------------
53
54def getLongitudeString(longitude):
55 """Get a string representation of the given longitude."""
56
57 return getDegreeString(longitude, ["E", "W"])
58
59#------------------------------------------------------------------------------
60
61def getDegreeString(degree, prefixes):
62 """Get a string representation of the given degree.
63
64 If the sign is positive, prefixes[0], otherwise prefixes[1] will be
65 prepended to the string."""
66
67 if degree<0:
68 prefix = prefixes[1]
69 else:
70 prefix = prefixes[0]
71
72 (deg, min, sec, _sign) = getDegMinSec(degree)
73
74 return u"%s%d\u00b0%02d\u2032%02d\u2033" % (prefix, deg, min, sec)
75
76#------------------------------------------------------------------------------
77
78def getTimestampString(timestamp):
79 """Get the string representation of the given timestamp."""
80 return time.strftime("%H:%M:%S", time.gmtime(timestamp))
81
82#------------------------------------------------------------------------------
83
84def getTimeIntervalString(seconds):
85 """Get a more human-friendly representation of the given time interval
86 expressed in seconds."""
87 hours = int(seconds / 3600)
88 minutes = int((seconds / 60) % 60)
89 seconds = int(seconds % 60)
90 return "%02d:%02d:%02d" % (hours, minutes, seconds)
91
92#------------------------------------------------------------------------------
93
94def km2nm(km):
95 """Convert the given kilometres into nautical miles."""
96 return km/1.852
97
98#------------------------------------------------------------------------------
99
100def nm2km(nm):
101 """Convert the given nautical miles into kilometres."""
102 return nm*1.852
103
104#------------------------------------------------------------------------------
105
106def radians2km(radians):
107 """Convert the given radians into kilometres"""
108 return radians * EARTH_RADIUS / 1000.0
109
110#------------------------------------------------------------------------------
111
112def radians2nm(radians):
113 """Convert the given radians into nautical miles."""
114 return km2nm(radians2km(radians))
115
116#------------------------------------------------------------------------------
117
118def getDistCourse(latitude1, longitude1, latitude2, longitude2):
119 """Get the distance and course between the two geographical coordinates.
120
121 This function calculates the rhumb distance."""
122
123 latitude1 = math.radians(latitude1)
124 longitude1 = math.radians(longitude1)
125
126 latitude2 = math.radians(latitude2)
127 longitude2 = math.radians(longitude2)
128
129 dlon_W = (longitude1 - longitude2) % (math.pi*2)
130 dlon_E = (longitude2 - longitude1) % (math.pi*2)
131
132 dphi = math.log(math.tan(latitude2/2 + math.pi/4)/
133 math.tan(latitude1/2 + math.pi/4))
134
135 if abs(latitude1-latitude2) < math.sqrt(1e-15):
136 q = math.cos(latitude1)
137 else:
138 q = (latitude1-latitude2)/dphi
139
140 if dlon_W < dlon_E:
141 tc = math.atan2(-dlon_W, dphi) % (math.pi*2)
142 d = math.sqrt(math.pow(q*dlon_W, 2) +
143 math.pow(latitude1-latitude2, 2))
144 else:
145 tc = math.atan2(dlon_E, dphi) % (math.pi*2)
146 d = math.sqrt(math.pow(q*dlon_E, 2) +
147 math.pow(latitude1-latitude2, 2))
148
149 return (radians2nm(d), math.degrees(tc))
150
Note: See TracBrowser for help on using the repository browser.