gr-air-modes/python/modes_kml.py

158 lines
7.0 KiB
Python

#
# Copyright 2010 Nick Foster
#
# This file is part of gr-air-modes
#
# gr-air-modes is free software; you can redistribute it and/or modify
# it under the terms of the GNU General Public License as published by
# the Free Software Foundation; either version 3, or (at your option)
# any later version.
#
# gr-air-modes is distributed in the hope that it will be useful,
# but WITHOUT ANY WARRANTY; without even the implied warranty of
# MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
# GNU General Public License for more details.
#
# You should have received a copy of the GNU General Public License
# along with gr-air-modes; see the file COPYING. If not, write to
# the Free Software Foundation, Inc., 51 Franklin Street,
# Boston, MA 02110-1301, USA.
#
import sqlite3
import string, math, threading, time
from air_modes.modes_sql import modes_output_sql
class modes_kml(threading.Thread):
def __init__(self, filename, localpos, timeout=5):
threading.Thread.__init__(self)
self._filename = filename
self.my_coords = localpos
self._timeout = timeout
self._dbname = 'adsb.db'
self._sqlobj = modes_output_sql(self.my_coords, self._dbname)
self.done = False
self.setDaemon(1)
self.start()
def run(self):
while self.done is False:
self.output()
time.sleep(self._timeout)
self.done = True
def output(self):
self._db = sqlite3.connect(self._dbname)
kmlstr = self.genkml()
if kmlstr is not None:
f = open(self._filename, 'w')
f.write(kmlstr)
f.close()
self._db.close()
def draw_circle(self, center, rng):
retstr = ""
steps=30
#so we're going to do this by computing a bearing angle based on the steps, and then compute the coordinate of a line extended from the center point to that range.
[center_lat, center_lon] = center
esquared = (1/298.257223563)*(2-(1/298.257223563))
earth_radius_mi = 3963.19059
#here we figure out the circumference of the latitude ring
#which tells us how wide one line of longitude is at our latitude
lat_circ = earth_radius_mi * math.cos(center_lat)
#the circumference of the longitude ring will be equal to the circumference of the earth
lat_rad = math.radians(center_lat)
lon_rad = math.radians(center_lon)
tmp0 = rng / earth_radius_mi
for i in range(0, steps+1):
bearing = i*(2*math.pi/steps) #in radians
lat_out = math.degrees(math.asin(math.sin(lat_rad)*math.cos(tmp0) + math.cos(lat_rad)*math.sin(tmp0)*math.cos(bearing)))
lon_out = center_lon + math.degrees(math.atan2(math.sin(bearing)*math.sin(tmp0)*math.cos(lat_rad), math.cos(tmp0)-math.sin(lat_rad)*math.sin(math.radians(lat_out))))
retstr += " %.8f, %.8f, 0" % (lon_out, lat_out,)
retstr = string.lstrip(retstr)
return retstr
def genkml(self):
#first let's draw the static content
retstr="""<?xml version="1.0" encoding="UTF-8"?>\n<kml xmlns="http://www.opengis.net/kml/2.2">\n<Document>\n\t<Style id="airplane">\n\t\t<IconStyle>\n\t\t\t<Icon><href>airports.png</href></Icon>\n\t\t</IconStyle>\n\t</Style>\n\t<Style id="rangering">\n\t<LineStyle>\n\t\t<color>9f4f4faf</color>\n\t\t<width>2</width>\n\t</LineStyle>\n\t</Style>\n\t<Style id="track">\n\t<LineStyle>\n\t\t<color>5fff8f8f</color>\n\t\t<width>4</width>\n\t</LineStyle>\n\t</Style>"""
retstr += """\t<Folder>\n\t\t<name>Range rings</name>\n\t\t<open>0</open>"""
for rng in [100, 200, 300]:
retstr += """\n\t\t<Placemark>\n\t\t\t<name>%inm</name>\n\t\t\t<styleUrl>#rangering</styleUrl>\n\t\t\t<LinearRing>\n\t\t\t\t<coordinates>%s</coordinates>\n\t\t\t</LinearRing>\n\t\t</Placemark>""" % (rng, self.draw_circle(self.my_coords, rng),)
retstr += """\t</Folder>\n\t<Folder>\n\t\t<name>Aircraft locations</name>\n\t\t<open>0</open>"""
#read the database and add KML
q = "select distinct icao from positions where seen > datetime('now', '-5 minute')"
c = self._db.cursor()
c.execute(q)
icaolist = c.fetchall()
#now we have a list icaolist of all ICAOs seen in the last 5 minutes
for icao in icaolist:
#print "ICAO: %x" % icao
q = "select * from positions where icao=%i and seen > datetime('now', '-2 hour') ORDER BY seen DESC" % icao
c.execute(q)
track = c.fetchall()
#print "Track length: %i" % len(track)
if len(track) != 0:
lat = track[0][3]
if lat is None: lat = 0
lon = track[0][4]
if lon is None: lon = 0
alt = track[0][2]
if alt is None: alt = 0
metric_alt = alt * 0.3048 #google earth takes meters, the commie bastards
trackstr = ""
for pos in track:
trackstr += " %f, %f, %f" % (pos[4], pos[3], pos[2]*0.3048)
trackstr = string.lstrip(trackstr)
else:
alt = 0
metric_alt = 0
lat = 0
lon = 0
trackstr = str("")
#now get metadata
q = "select ident from ident where icao=%i" % icao
c.execute(q)
r = c.fetchall()
if len(r) != 0:
ident = r[0][0]
else: ident=""
#if ident is None: ident = ""
#get most recent speed/heading/vertical
q = "select seen, speed, heading, vertical from vectors where icao=%i order by seen desc limit 1" % icao
c.execute(q)
r = c.fetchall()
if len(r) != 0:
seen = r[0][0]
speed = r[0][1]
heading = r[0][2]
vertical = r[0][3]
else:
seen = 0
speed = 0
heading = 0
vertical = 0
#now generate some KML
retstr+= "\n\t\t<Placemark>\n\t\t\t<name>%s</name>\n\t\t\t<styleUrl>#airplane</styleUrl>\n\t\t\t<description>\n\t\t\t\t<![CDATA[Altitude: %s<br/>Heading: %i<br/>Speed: %i<br/>Vertical speed: %i<br/>ICAO: %x<br/>Last seen: %s]]>\n\t\t\t</description>\n\t\t\t<Point>\n\t\t\t\t<altitudeMode>absolute</altitudeMode>\n\t\t\t\t<extrude>1</extrude>\n\t\t\t\t<coordinates>%s,%s,%i</coordinates>\n\t\t\t</Point>\n\t\t</Placemark>" % (ident, alt, heading, speed, vertical, icao[0], seen, lon, lat, metric_alt, )
retstr+= "\n\t\t<Placemark>\n\t\t\t<styleUrl>#track</styleUrl>\n\t\t\t<LineString>\n\t\t\t\t<extrude>0</extrude>\n\t\t\t\t<altitudeMode>absolute</altitudeMode>\n\t\t\t\t<coordinates>%s</coordinates>\n\t\t\t</LineString>\n\t\t</Placemark>" % (trackstr,)
retstr+= '\n\t</Folder>\n</Document>\n</kml>'
return retstr