LJ/plugins/planetarium/main.py
2019-03-10 23:06:04 +01:00

694 lines
21 KiB
Python
Executable File

#!/usr/bin/python3
# coding=UTF-8
'''
Multi Laser planetarium in python3 for LJ.
v0.01
Sam Neurohack
Accuracy could be tested against apparent data and starchart at https://www.calsky.com/cs.cgi?cha=7&sec=3&sub=2
Remember to set the same observer position and time.
See Readme for more information
Todo:
- use debug mode and check altaz calculated values against online sites.
- Validate aa2radec() with online calculator. Rewrite it to remove need for Astropy.
- Findout how to use OSC in python 3.
-
- Code WebUI page.
- UpdateStars() in each laser sky. Get magnitude. See UpdateSolar for example.
- All Draw operations should also check visibility in the given laser altitude range.
- Rewrite CityPosition() with proper search in a python dictionnary.
- Better python code. Better varuable to understand easily Update() methods.
LICENCE : CC
Remember : LJ will automatically warp geometry according to alignement data. See webUI.
'''
import redis
import lj3
import numpy as np
import math,time
from astropy.coordinates import SkyCoord, EarthLocation, AltAz
from astropy import units as u
from astropy.time import Time
from skyfield.api import Star, load, Topos,Angle
from skyfield.data import hipparcos
from osc4py3.as_eventloop import *
from osc4py3 import oscbuildparse
#from osc4py3 import oscmethod as osm
from osc4py3.oscmethod import *
import json
'''
is_py2 = sys.version[0] == '2'
if is_py2:
from Queue import Queue
else:
from queue import Queue
'''
#
# Arguments handler
#
import argparse
print ("")
print ("Arguments parsing if needed...")
argsparser = argparse.ArgumentParser(description="Planetarium for LJ")
argsparser.add_argument("-r","--redisIP",help="IP of the Redis server used by LJ (127.0.0.1 by default) ",type=str)
argsparser.add_argument("-c","--client",help="LJ client number (0 by default)",type=int)
argsparser.add_argument("-L","--Lasers",help="Number of lasers connected (1 by default).",type=int)
argsparser.add_argument("-v","--verbose",help="Verbosity level (0 by default)",type=int)
argsparser.add_argument("-i","--input",help="inputs OSC Port (8005 by default)",type=int)
#argsparser.add_argument("-n","--name",help="City Name of the observer",type=str)
#argsparser.add_argument("-r","--redisIP",help="Country code of the observer ",type=str)
args = argsparser.parse_args()
if args.client:
ljclient = args.client
else:
ljclient = 0
if args.Lasers:
lasernumber = args.Lasers
else:
lasernumber = 1
if args.verbose:
debug = args.verbose
else:
debug = 0
if args.input:
OSCinPort = args.input
else:
OSCinPort = 8005
# Redis Computer IP
if args.redisIP != None:
redisIP = args.redisIP
else:
redisIP = '127.0.0.1'
lj3.Config(redisIP,ljclient)
#
# Inits Laser
#
fov = 256
viewer_distance = 2.2
width = 750
height = 750
centerX = width / 2
centerY = height / 2
samparray = [0] * 100
# If you want to use rgb for color :
def rgb2int(r,g,b):
return int('0x%02x%02x%02x' % (r,g,b),0)
white = rgb2int(255,255,255)
red = rgb2int(255,0,0)
blue = rgb2int(0,0,255)
green = rgb2int(0,255,0)
def Proj(x,y,z,angleX,angleY,angleZ):
rad = angleX * math.pi / 180
cosa = math.cos(rad)
sina = math.sin(rad)
y2 = y
y = y2 * cosa - z * sina
z = y2 * sina + z * cosa
rad = angleY * math.pi / 180
cosa = math.cos(rad)
sina = math.sin(rad)
z2 = z
z = z2 * cosa - x * sina
x = z2 * sina + x * cosa
rad = angleZ * math.pi / 180
cosa = math.cos(rad)
sina = math.sin(rad)
x2 = x
x = x2 * cosa - y * sina
y = x2 * sina + y * cosa
""" Transforms this 3D point to 2D using a perspective projection. """
factor = fov / (viewer_distance + z)
x = x * factor + centerX
y = - y * factor + centerY
return (x,y)
#
# All the coordinates base functions
#
'''
To minize number of sky objects coordinates conversion : Change planetarium FOV in Ra Dec to select objects
(planets, hipparcos,..). Then get only those objects in AltAz coordinates.
aa2radec use Astropy to compute Equatorial Right Ascension and Declinaison coordinates from given observator Altitude and Azimuth.
Example ra,dec = aa2radec( azimuth = 0, altitude = 90, lati = 48.85341, longi = 2.3488, elevation = 100, t =AstroPyNow )
with AstroPyNow = Time.now()
'''
def aa2radec(azimuth, altitude, t):
#AstrObserver = EarthLocation(lat=lati * u.deg, lon=longi *u.deg, height= elevation*u.m,)
ObjectCoord = SkyCoord(alt = altitude * u.deg, az = azimuth *u.deg, obstime = t, frame = 'altaz', location = AstrObserver)
#print("icrs",ObjectCoord.icrs)
#print("ICRS Right Ascension", ObjectCoord.icrs.ra)
#print("ICRS Declination", ObjectCoord.icrs.dec)
return ObjectCoord.icrs.ra.degree, ObjectCoord.icrs.dec.degree
# Use Skyfield to compute given object apparent positions (ra,dec,alt,az) and distance from given gps earth position (in decimal degrees) at UTC time (in skyfield format)
def EarthObjPosition(object, t):
#print (object, 'at', t.utc_iso())
#SkyObserver = earth + Topos(gpslat, gpslong)
astrometric = earth.at(t).observe(object)
ra, dec, distance = astrometric.radec()
'''
print("Right ascencion",ra)
print("RA in degree",ra._degrees)
print("RA in radians",ra.radians)
print("declinaison",dec)
print (distance)
'''
ApparentPosition = SkyObserver.at(t).observe(object).apparent()
#alt, az, distance = ApparentPosition.altaz('standard')
alt, az, distance = ApparentPosition.altaz()
'''
print("UTC",t.utc_iso())
print ("Altitude",alt)
print("Altitude in radians",alt.radians)
print("Altitude in degrees",alt.degrees)
print("Altitude in dms",alt.dms(0))
print("Altitude in signed_dms",alt.signed_dms(0))
print("Azimuth", az.dstr())
print ("Distance from position", distance)
'''
# If you want degree hours min : print (object,alt,az)
# or you can do return ra._degrees, dec, alt.degrees, az, distance
return alt.degrees, az.degrees, distance
# Add Radec coordinates for all lasers from user defined Altaz coordinates in LaserSkies variable at given earth position and time.
# LaserSkies : [LeftAzi, RightAzi, TopAlt, BotAlt, LeftRa, RightRa, TopDec, BottomDec]
# 0 1 2 3 4 5 6 7
def RadecSkies(LaserSkies, AstroSkyTime):
print()
print("Converting", lasernumber, "LaserSkies limits in Right Ascension & Declination (radec) coordinates ")
for laser in range(lasernumber):
if debug > 0:
print("Laser",laser)
# Left top point
LaserSkies[laser][4],LaserSkies[laser][6] = aa2radec(azimuth = LaserSkies[laser][0], altitude =LaserSkies[laser][2], t =AstroSkyTime)
if debug > 0:
print(LaserSkies[laser][4],LaserSkies[laser][6])
# Right Bottom point
LaserSkies[laser][5],LaserSkies[laser][7] = aa2radec(azimuth = LaserSkies[laser][1], altitude =LaserSkies[laser][3], t =AstroSkyTime)
if debug > 0:
print(LaserSkies[laser][5],LaserSkies[laser][7])
if debug > 0:
print(LaserSkies)
print ("Done.")
def azimuth2scrX(leftAzi,rightAzi,s):
a1, a2 = leftAzi, rightAzi
b1, b2 = 0, width
#if debug > 0:
# print(leftAzi, rightAzi, s, b1 + ((s - a1) * (b2 - b1) / (a2 - a1)))
return b1 + ((s - a1) * (b2 - b1) / (a2 - a1))
def altitude2scrY(topAlti,botAlti,s):
a1, a2 = topAlti, botAlti
b1, b2 = 0, height
#if debug > 0:
# print(topAlti,botAlti,s, b1 + ((s - a1) * (b2 - b1) / (a2 - a1)))
return b1 + ((s - a1) * (b2 - b1) / (a2 - a1))
#
# Solar System
#
SolarObjectShape = [(-50,30), (-30,-30), (30,-30), (10,30), (-50,30)]
# Planets Radius in km
SolarObjectradius = [
('Sun', 695500.0),
('Mercury', 2440.0),
('Venus', 6051.8),
('Earth', 6371.01),
('Mars', 3389.9),
('Jupiter', 69911.0),
('Saturn', 58232.0),
('Uranus', 25362.0),
('Neptune', 24624.0),
('134340 Pluto', 1195.0),
]
def LoadSolar():
global planets, SolarObjects, earth
print("Loading Solar System (de421)...")
# de421.bps https://naif.jpl.nasa.gov/pub/naif/generic_kernels/spk/planets/a_old_versions/de421.bsp
planets = load('data/de421.bsp')
earth = planets['earth']
print('Loaded.')
# de421 objects
# [Object name, object altitude, object azimuth]
SolarObjects = [['MERCURY',0.0, 0.0], ['VENUS', 0.0, 0.0], ['JUPITER BARYCENTER', 0.0, 0.0], ['SATURN BARYCENTER', 0.0, 0.0], ['URANUS BARYCENTER', 0.0, 0.0], ['NEPTUNE BARYCENTER', 0.0, 0.0], ['PLUTO BARYCENTER', 0.0, 0.0], ['SUN', 0.0, 0.0], ['MOON', 0.0, 0.0], ['MARS', 0.0, 0.0]]
def UpdateSolar():
global SolarObjects
# Compute Alt Az coordinates for all solar objects for obsehttps://www.startpage.com/do/searchrver.
for number,object in enumerate(SolarObjects):
#print(object[0],number)
SolarObjects[number][1], SolarObjects[number][2], distance = EarthObjPosition(planets[object[0]],SkyfieldTime)
if debug > 0:
PrintSolar()
def PrintSolar():
for number,object in enumerate(SolarObjects):
print (SolarObjects[number][0],"is at (alt,az)",SolarObjects[number][1],SolarObjects[number][2])
# Draw the SolarShapeObject for any Solar object is in the laser Sky
def DrawSolar(laser):
for number,object in enumerate(SolarObjects):
# Solar object is in given laser sky azimuth and altitude range ?
if LaserSkies[laser][0] < SolarObjects[number][2] < LaserSkies[laser][1] and LaserSkies[laser][3] < SolarObjects[number][1] < LaserSkies[laser][2]:
#print ("drawing",SolarObjects[number][0],SolarObjects[number][1],SolarObjects[number][2],"on laser",laser)
lj3.rPolyLineOneColor(SolarObjectShape, c = white, PL = laser, closed = False, xpos = azimuth2scrX(LaserSkies[laser][0],LaserSkies[laser][1],SolarObjects[number][2]), ypos = altitude2scrY(LaserSkies[laser][2],LaserSkies[laser][3],SolarObjects[number][1]), resize = 2, rotx =0, roty =0 , rotz=0)
#
# Stars
#
StarsObjectShape = [(-10,10), (-10,-10), (10,-10), (10,10), (-10,10)]
def LoadHipparcos(ts):
global hipdata
print("Loading hipparcos catalog...")
#hipparcosURL = 'ftp://cdsarc.u-strasbg.fr/cats/I/239/hip_main.dat.gz'
hipparcosURL = 'data/hip_main.dat.gz'
with load.open(hipparcosURL) as f:
hipdata = hipparcos.load_dataframe(f)
#print("Loaded.")
hipparcos_epoch = ts.tt(1991.25)
# CODE IMPORTED HERE FROM TESTS. NEEDS TO ADAPT
# Star selection
def StarSelect():
global StarsObjects, hipdatafilt
StarsObjects = [[]]
#hipparcos_epoch = ts.tt(1991.25)
#barnards_star = Star.from_dataframe(hipdata.loc[87937])
#polaris = Star.from_dataframe(hipdata.loc[11767])
print()
print ("Stars selection...")
hipdatafilt = hipdata[hipdata['magnitude'] <= 3.5]
print(('{} stars with magnitude <= 3.5'.format(len(hipdatafilt))))
Starnames = hipdatafilt.index
StarsObjects[0] = [Starnames[0],0,0]
for index in range(len(Starnames)-1):
StarsObjects.append([Starnames[index+1],0,0])
def UpdateStars(ts):
global StarsObjects
hipparcos_epoch = ts.tt(1991.25)
# Compute Alt Az coordinates for all solar objects for obsehttps://www.startpage.com/do/searchrver.
for number,object in enumerate(StarsObjects):
#print(object[0],number)
StarsObjects[number][1], StarsObjects[number][2], distance = EarthObjPosition(Star.from_dataframe(hipdatafilt.loc[StarsObjects[number][0]]),SkyfieldTime)
if debug > 0:
PrintStars()
def PrintStars():
for number,object in enumerate(StarsObjects):
print (StarsObjects[number][0],"is at (alt,az)",StarsObjects[number][1],StarsObjects[number][2])
def DrawStars(laser):
for number,object in enumerate(StarsObjects):
# Star object is in given lasersky altitude range ?
if LaserSkies[laser][3] < StarsObjects[number][1] < LaserSkies[laser][2]:
# Star object is in given lasersky azimuth range ?
if LaserSkies[laser][0] < StarsObjects[number][2] < LaserSkies[laser][1] :
#print ("drawing",StarsObjects[number][0],StarsObjects[number][1],StarsObjects[number][2],"on laser",laser)
lj3.rPolyLineOneColor(StarsObjectShape, c = white, PL = laser, closed = False, xpos = azimuth2scrX(LaserSkies[laser][0],LaserSkies[laser][1],StarsObjects[number][2]), ypos = altitude2scrY(LaserSkies[laser][2],LaserSkies[laser][3],StarsObjects[number][1]), resize = 0.05, rotx =0, roty =0 , rotz=0)
# Star object is in given lasersky North azimuth ?
if LaserSkies[laser][0] > LaserSkies[laser][1] and StarsObjects[number][2] < LaserSkies[laser][1] :
#print ("drawing",StarsObjects[number][0],StarsObjects[number][1],StarsObjects[number][2],"on laser",laser)
lj3.rPolyLineOneColor(StarsObjectShape, c = white, PL = laser, closed = False, xpos = azimuth2scrX(LaserSkies[laser][0],LaserSkies[laser][1],StarsObjects[number][2]), ypos = altitude2scrY(LaserSkies[laser][2],LaserSkies[laser][3],StarsObjects[number][1]), resize = 0.05, rotx =0, roty =0 , rotz=0)
#
# Anything system. Say you want
#
AnythingObjectShape = [(-50,30), (-30,-30), (30,-30), (10,30), (-50,30)]
def LoadAnything():
global planets, AnythingObjects, earth
print("Loading Anything System...")
# de421.bps https://naif.jpl.nasa.gov/pub/naif/generic_kernels/spk/planets/a_old_versions/de421.bsp
# planets = load('data/de421.bsp')
earth = planets['earth']
print('Loaded.')
# [Object name, object altitude, object azimuth]
AnythingObjects = [['MERCURY',0.0, 0.0], ['VENUS', 0.0, 0.0], ['JUPITER BARYCENTER', 0.0, 0.0], ['SATURN BARYCENTER', 0.0, 0.0], ['URANUS BARYCENTER', 0.0, 0.0], ['NEPTUNE BARYCENTER', 0.0, 0.0], ['PLUTO BARYCENTER', 0.0, 0.0], ['SUN', 0.0, 0.0], ['MOON', 0.0, 0.0], ['MARS', 0.0, 0.0]]
def UpdateAnything():
global AnythingObjects
# Compute Alt Az coordinates for all Anything objects for obsehttps://www.startpage.com/do/searchrver.
for number,object in enumerate(AnythingObjects):
#print(object[0],number)
AnythingObjects[number][1], AnythingObjects[number][2], distance = EarthObjPosition(planets[object[0]],SkyfieldTime)
if debug > 0:
PrintAnything()
def PrintAnything():
for number,object in enumerate(AnythingObjects):
print (AnythingObjects[number][0],"is at (alt,az)",AnythingObjects[number][1],AnythingObjects[number][2])
# Draw the AnythingShapeObject for any Anything object is in the laser Sky
def DrawAnything(laser):
for number,object in enumerate(AnythingObjects):
# Anything object is in given laser sky azimuth and altitude range ?
if LaserSkies[laser][0] < AnythingObjects[number][2] < LaserSkies[laser][1] and LaserSkies[laser][3] < AnythingObjects[number][1] < LaserSkies[laser][2]:
#print ("drawing",AnythingObjects[number][0],AnythingObjects[number][1],AnythingObjects[number][2],"on laser",laser)
lj3.rPolyLineOneColor(AnythingObjectShape, c = white, PL = laser, closed = False, xpos = azimuth2scrX(LaserSkies[laser][0],LaserSkies[laser][1],AnythingObjects[number][2]), ypos = altitude2scrY(LaserSkies[laser][2],LaserSkies[laser][3],AnythingObjects[number][1]), resize = 2, rotx =0, roty =0 , rotz=0)
#
# On Earth Gps positions
# from https://github.com/lutangar/cities.json
#
def LoadCities():
global world
print("Loading World Cities GPS position...")
f=open("data/cities.json","r")
s = f.read()
world = json.loads(s)
#print("Loaded.")
# Get longitude and latitude of given City in given country. Need to better understand python dictionnaries.
def CityPositiion(cityname, countrycode):
for city in range(len(world['cities'])):
if world['cities'][city]['name']==cityname and world['cities'][city]['country']==countrycode:
'''
print (world['cities'][city]['country'])
print (world['cities'][city]['name'])
print (world['cities'][city]['lat'])
print (world['cities'][city]['lng'])
'''
return float(world['cities'][city]['lat']), float(world['cities'][city]['lng'])
# Add Kompass orientation to given laser point list if it is in laser sky at Y axis 300
# point lasers to
def DrawOrientation(laser):
#print("LaserSkies 0",LaserSkies[laser][0],"LaserSkies 1",LaserSkies[laser][1])
# North direction is in given laser sky azimuth range?
if LaserSkies[laser][1] < LaserSkies[laser][0]:
#print ("N az",azimuth2scrX(LaserSkies[laser][0],LaserSkies[laser][1],0))
lj3.Text("NORTH",white,laser,azimuth2scrX(LaserSkies[laser][0],LaserSkies[laser][1],359), 770, resize = 0.5, rotx =0, roty =0 , rotz=0)
# East direction is in given laser sky azimuth range ?
if LaserSkies[laser][0] <= 90 < LaserSkies[laser][1]:
#print ("E az",azimuth2scrX(LaserSkies[laser][0],LaserSkies[laser][1],0))
lj3.Text("EAST",white,laser,azimuth2scrX(LaserSkies[laser][0],LaserSkies[laser][1],90), 770, resize = 0.5, rotx =0, roty =0 , rotz=0)
# South direction is in given laser sky azimuth range ?
if LaserSkies[laser][0] <= 180 < LaserSkies[laser][1]:
#print ("S az",azimuth2scrX(LaserSkies[laser][0],LaserSkies[laser][1],0))
lj3.Text("SOUTH",white,laser,azimuth2scrX(LaserSkies[laser][0],LaserSkies[laser][1],180), 770, resize = 0.5, rotx =0, roty =0 , rotz=0)
# West direction is in given laser sky azimuth range ?
if LaserSkies[laser][0] <= 270 < LaserSkies[laser][1]:
#print ("W az",azimuth2scrX(LaserSkies[laser][0],LaserSkies[laser][1],0))
lj3.Text("WEST",white,laser,azimuth2scrX(LaserSkies[laser][0],LaserSkies[laser][1],270), 770, resize = 0.5, rotx =0, roty =0 , rotz=0)
# Compute LaserSkies Coordinates for observer
def InitObserver(SkyCity, SkyCountryCode, time,ts):
global LaserSkies, Skylat, Skylong, SkyfieldTime, AstrObserver, SkyObserver
# Observer position i.e : Paris FR
#Skylat = 48.85341 # decimal degree
#Skylong = 2.3488 # decimal degree
#print()
print("Observer GPS position and time...")
Skylat, Skylong = CityPositiion(SkyCity,SkyCountryCode)
print ("GPS Position of",SkyCity, "in", SkyCountryCode, ":",Skylat,Skylong)
# City GPS altitude not in Cities database... Let's say it's :
Skyelevation = 0 # meters
# Observer Time : Now
# Other time in Astropy style
# times = '1999-01-01T00:00:00.123456789'
# t = Time(times, format='isot', scale='utc')
#print()
AstroSkyTime = time
print ("AstroPy time", AstroSkyTime)
SkyfieldTime = ts.from_astropy(AstroSkyTime)
print("SkyfieldTime from AstropyUTC",SkyfieldTime.utc_iso())
AstrObserver = EarthLocation(lat = Skylat * u.deg, lon = Skylong * u.deg, height = Skyelevation * u.m,)
SkyObserver = earth + Topos(Skylat, Skylong)
# Computer for all Laser "skies" their Right Ascension/Declinaison coordinates from their Altitude/azimuth Coordinates.
# to later select their visible objects in radec catalogs like hipparcos.
# LaserSky definition for one laser (in decimal degrees) : [RightAzi, LeftAzi, TopAlt, BotAlt, LeftRa, RightRa, TopDec, BottomDec]
# With 4 lasers with each one a quarter of the 360 ° real sky, there is 4 LaserSky :
LaserSkies = [[45,135.0,90.0,0.0,0.0,0.0,0.0,0.0],[135,225,90,0,0,0,0,0],[225,315,90,0,0,0,0,0],[305,0,90,0,0,0,0,0]]
RadecSkies(LaserSkies, AstroSkyTime)
# Change Observer position by adding deltas (Gpslong, gpslat, elevation in decimal degree/meters)
def UpdateObserver(gpslatdelta, gpslongdelta, elevationdelta,time,ts):
global LaserSkies, Skylat, Skylong, SkyfieldTime, AstrObserver, SkyObserver
Skylat += gpslatdelta
Skylong += gpslongdelta
Skyelevation += elevationdelta
AstroSkyTime = time
print ("AstroPy time", AstroSkyTime)
SkyfieldTime = ts.from_astropy(AstroSkyTime)
print("SkyfieldTime from AstropyUTC",SkyfieldTime.utc_iso())
AstrObserver = EarthLocation(lat = Skylat * u.deg, lon = Skylong * u.deg, height = Skyelevation * u.m,)
SkyObserver = earth + Topos(Skylat, Skylong)
RadecSkies(LaserSkies, AstroSkyTime)
UpdateSolar()
UpdateStars()
UpdateAnything()
def NewTime(timeshift):
SkyfieldTime += timeshift
if DisplaySolar:
UpdateSolar()
if DisplayStars:
UpdateStars()
if DisplayAnything:
UpdateAnything()
def OSCstart(value):
# Will receive message address, and message data flattened in s, x, y
print("Planetarium OSC server got /planet/start with value", value)
def OSCUI(value):
# Will receive message address, and message data flattened in s, x, y
print("Planetarium OSC server got /planet/planetUI with value", value)
def WebStatus(message):
lj3.Send("/status",message)
#
# Main part
#
try:
WebStatus("Planetarium")
# OSC Server callbacks
print("Starting OSC at 127.0.0.1 port",OSCinPort,"...")
osc_startup()
osc_udp_server("127.0.0.1", OSCinPort, "InPort")
osc_method("/planet/start*", OSCstart)
osc_method("/planet/planetUI*", OSCUI)
WebStatus("Load Cities.")
ts = load.timescale()
LoadCities()
SkyCity = 'Paris'
SkyCountryCode = 'FR'
WebStatus(SkyCity)
WebStatus("Solar System..")
LoadSolar()
WebStatus("Observer..")
InitObserver(SkyCity, SkyCountryCode, Time.now(),ts)
WebStatus("Load Stars..")
LoadHipparcos(ts)
StarSelect()
WebStatus("Updating...")
print("Updating solar system (de421) objects position for observer at", Skylat, Skylong, "time", SkyfieldTime.utc_iso())
UpdateSolar()
print("Updating stars for observer at", Skylat, Skylong, "time", SkyfieldTime.utc_iso())
UpdateStars(ts)
WebStatus("Ready")
lj3.Send("/planet/start",1)
print ("Done.")
# UpdateStars() Todo
DisplayStars = True
DisplaySolar = False
DisplayOrientation = True
DisplayAnything = False
print("Start displaying on",lasernumber,"lasers")
while 1:
for laser in range(lasernumber):
#print ("Drawing laser",lasernumber)
if DisplayOrientation:
DrawOrientation(laser)
lj3.OSCframe()
if DisplaySolar:
DrawSolar(laser)
lj3.OSCframe()
if DisplayStars:
DrawStars(laser)
lj3.OSCframe()
if DisplayAnything:
DrawAnything()
lj3.OSCframe()
lj3.DrawPL(laser)
lj3.OSCframe()
time.sleep(0.01)
except KeyboardInterrupt:
pass
# Gently stop on CTRL C
finally:
WebStatus("Planet Exit")
print("Stopping OSC...")
lj3.OSCstop()
print ("Fin du planetarium.")