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#!/usr/bin/env python
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import json
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import requests
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import ephem
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import math
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import random
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from datetime import datetime, timedelta
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import matplotlib.pyplot as plt
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from matplotlib.patches import Rectangle
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from matplotlib.dates import DayLocator, HourLocator, DateFormatter, drange
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from matplotlib import colors as mcolors
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class satellite:
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"""Satellite class"""
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def __init__(self, tle0, tle1, tle2):
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"""Define a satellite"""
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self.tle0 = tle0
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self.tle1 = tle1
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self.tle2 = tle2
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if tle0[:2]=="0 ":
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self.name = tle0[2:]
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else:
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self.name = tle0
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self.id = tle1.split(" ")[1][:5]
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def get_scheduled_passes_from_network(ground_station, tmin, tmax):
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# Get first page
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client = requests.session()
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# Loop
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start = True
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scheduledpasses = []
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while True:
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if start:
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r = client.get("https://network.satnogs.org/api/observations/?ground_station=%d"%ground_station)
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start=False
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else:
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nextpage = r.links.get("next")
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r = client.get(nextpage["url"])
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# r.json() is a list of dicts
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for o in r.json():
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satpass = {"id": o['norad_cat_id'],
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"tr": datetime.strptime(o['start'].replace("Z", ""), "%Y-%m-%dT%H:%M:%S"),
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"ts": datetime.strptime(o['end'].replace("Z", ""), "%Y-%m-%dT%H:%M:%S"),
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"scheduled": True}
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if satpass['ts']>tmin and satpass['tr']<tmax:
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scheduledpasses.append(satpass)
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if satpass['ts']<tmin:
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break
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return scheduledpasses
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def overlap(satpass, scheduledpasses):
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# No overlap
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overlap = False
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# Loop over scheduled passes
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for scheduledpass in scheduledpasses:
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# Test pass falls within scheduled pass
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if satpass['tr']>=scheduledpass['tr'] and satpass['ts']<scheduledpass['ts']:
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overlap = True
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# Scheduled pass falls within test pass
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elif scheduledpass['tr']>=satpass['tr'] and scheduledpass['ts']<satpass['ts']:
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overlap = True
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# Pass start falls within pass
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elif satpass['tr']>=scheduledpass['tr'] and satpass['tr']<scheduledpass['ts']:
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overlap = True
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# Pass end falls within end
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elif satpass['ts']>=scheduledpass['tr'] and satpass['ts']<scheduledpass['ts']:
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overlap = True
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if overlap == True:
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break
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return overlap
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def ordered_scheduler(passes, scheduledpasses):
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"""Loop through a list of ordered passes and schedule each next one that fits"""
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# Loop over passes
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for satpass in passes:
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# Schedule if there is no overlap with already scheduled passes
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if overlap(satpass, scheduledpasses)==False:
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scheduledpasses.append(satpass)
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return scheduledpasses
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def random_scheduler(passes, scheduledpasses):
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"""Schedule passes based on random ordering"""
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# Shuffle passes
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random.shuffle(passes)
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return ordered_scheduler(passes, scheduledpasses)
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def efficiency(passes):
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# Loop over passes
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start = False
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for satpass in passes:
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if start==False:
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dt = satpass['ts']-satpass['tr']
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tmin = satpass['tr']
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tmax = satpass['ts']
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start = True
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else:
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dt += satpass['ts']-satpass['tr']
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if satpass['tr']<tmin: tmin=satpass['tr']
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if satpass['ts']>tmax: tmax=satpass['ts']
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# Total time covered
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dttot = tmax-tmin
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return dt.total_seconds(),dttot.total_seconds(), dt.total_seconds()/dttot.total_seconds()
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if __name__ == "__main__":
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# Settings
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tlefile = "uhf.txt"
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observer_longitude = "6.379"
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observer_latitude = "53.834"
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observer_elevation = 10
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minimum_altitude = 10
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ground_station = 40
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tmin = datetime.now()
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tmax = datetime.now()+timedelta(hours=24)
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# Read satellites
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with open(tlefile, "r") as f:
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lines = f.readlines()
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satellites = [satellite(lines[i], lines[i+1], lines[i+2])
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for i in range(0, len(lines), 3)]
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# Set observer
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observer = ephem.Observer()
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observer.lon = observer_longitude
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observer.lat = observer_latitude
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observer.elevation = observer_elevation
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# Loop over satellites
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passes = []
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passid = 0
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for satellite in satellites:
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# Set start time
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observer.date = ephem.date(tmin)
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# Load TLE
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try:
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sat_ephem = ephem.readtle(str(satellite.tle0),
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str(satellite.tle1),
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str(satellite.tle2))
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except (ValueError, AttributeError):
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continue
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# Loop over passes
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keep_digging = True
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while keep_digging:
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try:
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tr, azr, tt, altt, ts, azs = observer.next_pass(sat_ephem)
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except ValueError:
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break # there will be sats in our list that fall below horizon, skip
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except TypeError:
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break # if there happens to be a non-EarthSatellite object in the list
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except Exception:
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break
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if tr is None:
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break
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# using the angles module convert the sexagesimal degree into
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# something more easily read by a human
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try:
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elevation = format(math.degrees(altt), '.0f')
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azimuth_r = format(math.degrees(azr), '.0f')
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azimuth_s = format(math.degrees(azs), '.0f')
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except TypeError:
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break
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passid += 1
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# show only if >= configured horizon and in next 6 hours,
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# and not directly overhead (tr < ts see issue 199)
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if tr < ephem.date(tmax):
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if (float(elevation) >= minimum_altitude and tr < ts):
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valid = True
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if tr < ephem.Date(datetime.now() +
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timedelta(minutes=5)):
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valid = False
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satpass = {'passid': passid,
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'mytime': str(observer.date),
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'name': str(satellite.name),
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'id': str(satellite.id),
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'tle1': str(satellite.tle1),
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'tle2': str(satellite.tle2),
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'tr': tr.datetime(), # Rise time
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'azr': azimuth_r, # Rise Azimuth
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'tt': tt.datetime(), # Max altitude time
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'altt': elevation, # Max altitude
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'ts': ts.datetime(), # Set time
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'azs': azimuth_s, # Set azimuth
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'valid': valid,
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'scheduled': False}
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passes.append(satpass)
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observer.date = ephem.Date(ts).datetime() + timedelta(minutes=1)
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else:
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keep_digging = False
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# Priorities
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# priorities = {"40069": 1.000, "25338": 0.990, "28654": 0.990, "33591": 0.990, "43017": 0.980, "43137": 0.980, "40967": 0.980, "40074": 0.970, "42017": 0.970, "39444": 0.970, "40903": 0.960, "40906": 0.960, "40907": 0.960, "40909": 0.960, "40910": 0.960, "40911": 0.960, "42778": 0.950, "00965": 0.950, "42759": 0.940, "42761": 0.940, "25544": 0.000}
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priorities = {"40043": 1.000, "40012": 1.000, "42768": 1.000, "40968": 1.000, "40014": 1.000, "40379": 1.000, "42789": 1.000, "27844": 0.900, "27848": 0.900, "35935": 0.900, "43589": 0.900, "43590": 0.900, "43591": 0.900, "41935": 1.000, "24278": 0.900, "43156": 0.900, "42775": 0.900, "43596": 0.800, "40377": 0.800, "40378": 0.800, "43156": 0.800, "43468": 0.800, "43552": 0.800, "43466": 0.800}
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# List of scheduled passes
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# scheduledpasses = []
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scheduledpasses = get_scheduled_passes_from_network(ground_station, tmin, tmax)
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print("Found %d scheduled passes between %s and %s on ground station %d\n"%(len(scheduledpasses), tmin, tmax, ground_station))
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# Get passes of priority objects
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prioritypasses = []
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normalpasses = []
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for satpass in passes:
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# Get user defined priorities
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if satpass['id'] in priorities:
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satpass['priority'] = priorities[satpass['id']]
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prioritypasses.append(satpass)
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else:
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satpass['priority'] = float(satpass['altt'])/90.0
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normalpasses.append(satpass)
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# Priority scheduler
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prioritypasses = sorted(prioritypasses, key=lambda satpass: -satpass['priority'])
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scheduledpasses = ordered_scheduler(prioritypasses, scheduledpasses)
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# Random scheduler
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normalpasses = sorted(normalpasses, key=lambda satpass: -satpass['priority'])
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scheduledpasses = ordered_scheduler(normalpasses, scheduledpasses)
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dt, dttot, eff = efficiency(scheduledpasses)
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print("%d passes scheduled out of %d, %.0f s out of %.0f s at %.3f%% efficiency"%(len(scheduledpasses), len(passes), dt, dttot, 100*eff))
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# Find unique objects
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satids = sorted(set([satpass['id'] for satpass in passes]))
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# Set up figure
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fig = plt.figure(figsize=(20,len(satids)*0.2))
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ax = fig.add_subplot(111)
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ax.set_xlim(tmin, tmax)
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ax.set_ylim(-3,len(satids)+1)
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ax.xaxis.set_major_locator(HourLocator(xrange(0, 25, 3)))
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ax.xaxis.set_minor_locator(HourLocator(xrange(0, 25, 1)))
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ax.xaxis.set_major_formatter(DateFormatter('%Y-%m-%d %H:%M:%S'))
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ax.grid()
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ax.get_yaxis().set_visible(False)
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fig.autofmt_xdate(rotation=0, ha='center')
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plt.xlabel("Time (UTC) for station #%d"%ground_station)
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# Get list of colors
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colors = [key for key in mcolors.BASE_COLORS.keys() if key!='w']
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# Loop over objects
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for i, satid in enumerate(satids):
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plt.text(tmax+timedelta(minutes=5), i-0.25, satid, color=colors[i%len(colors)])
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for satpass in passes:
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if satpass['id']==satid:
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width = satpass['ts']-satpass['tr']
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ax.add_patch(Rectangle((satpass['tr'], i-0.4), width, 0.8, color=colors[i%len(colors)]))
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# Plot scheduled passes
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if satpass in scheduledpasses:
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ax.add_patch(Rectangle((satpass['tr'], -2.4), width, 0.8, color=colors[i%len(colors)]))
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# Time axis setter
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plt.savefig("schedule.png")
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# print("%d passes scheduled out of %d, %.0f s out of %.0f s at %.3f%% efficiency"%(len(scheduledpasses), len(passes), dt, dttot, 100*eff))
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# for satpass in scheduledpasses:
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for satpass in sorted(scheduledpasses, key=lambda satpass: satpass['tr']):
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if satpass['scheduled']==False:
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print("%s %s %3d %3d %3d %5.2f | %s %s"%(satpass['tr'].strftime("%Y-%m-%dT%H:%M:%S"), satpass['ts'].strftime("%Y-%m-%dT%H:%M:%S"), float(satpass['azr']), float(satpass['altt']), float(satpass['azs']),satpass['priority'],satpass['id'], satpass['name'].rstrip()))
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else:
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print("%s %s %3d %3d %3d %5.2f | %s %s"%(satpass['tr'].strftime("%Y-%m-%dT%H:%M:%S"), satpass['ts'].strftime("%Y-%m-%dT%H:%M:%S"), 0.0, 0.0, 0.0, 0.0, satpass['id'], ""))
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# Print schedule commands
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for satpass in sorted(scheduledpasses, key=lambda satpass: satpass['tr']):
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if satpass['scheduled']==False:
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print("firefox \"https://network.satnogs.org/observations/new/?norad=%s&ground_station=%d&start_date=%s&end_date=%s\""%(satpass['id'], ground_station, (satpass['tr']-timedelta(minutes=1)).strftime("%Y/%m/%d%%20%H:%M"), (satpass['ts']+timedelta(minutes=1)).strftime("%Y/%m/%d%%20%H:%M")))
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