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sondehub-infra/lambda/predict_updater/__init__.py
Michaela Wheeler ffd606d60c
Fixes #145 (#147) 
Co-authored-by: xssfox <xss@sprocketfox.io>
2024-10-16 11:04:49 +11:00

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import sys
sys.path.append("sns_to_mqtt/vendor")
import paho.mqtt.client as mqtt
import json
from datetime import datetime
import http.client
import math
import logging
from math import radians, degrees, sin, cos, atan2, sqrt, pi
import es
import asyncio
import functools
import os
import random
import time
import traceback
import config_handler
client = mqtt.Client(transport="websockets")
connected_flag = False
import socket
socket.setdefaulttimeout(1)
## MQTT functions
def connect():
client.on_connect = on_connect
client.on_disconnect = on_disconnect
client.on_publish = on_publish
#client.tls_set()
client.username_pw_set(username=config_handler.get("MQTT","USERNAME"), password=config_handler.get("MQTT","PASSWORD"))
HOSTS = config_handler.get("MQTT","HOST").split(",")
PORT = int(config_handler.get("MQTT","PORT", default="8080"))
if PORT == 443:
client.tls_set()
HOST = random.choice(HOSTS)
print(f"Connecting to {HOST}")
client.connect(HOST, PORT, 5)
client.loop_start()
print("loop started")
def on_disconnect(client, userdata, rc):
global connected_flag
print("disconnected")
connected_flag=False #set flag
def on_connect(client, userdata, flags, rc):
global connected_flag
if rc==0:
print("connected")
connected_flag=True #set flag
else:
print("Bad connection Returned code")
def on_publish(client, userdata, mid):
pass
# setup MQTT
connect()
# FLIGHT PROFILE DEFAULTS
#
# If we have no better estimates for flight profile, use these:
PREDICT_DEFAULTS = {'ascent_rate': 5.0, 'burst_altitude': 26000.0, 'descent_rate': 6.0}
# For some sonde types we can make better assumptions
SONDE_TYPE_PREDICT_DEFAULTS = {
'LMS6': {'ascent_rate': 5.0, 'burst_altitude': 32000.0, 'descent_rate': 3.0},
}
#
# LAUNCH SITE ALLOCATION SETTINGS
#
# Immediately allocate a launch site if it is within this distance (straight line)
# of a known launch site.
LAUNCH_ALLOCATE_RANGE_MIN = 4000 # metres
LAUNCH_ALLOCATE_RANGE_MAX = 30000 # metres
LAUNCH_ALLOCATE_RANGE_SCALING = 1.5 # Scaling factor - launch allocation range is min(current alt * this value , launch allocate range max)
# Do not run predictions if the ascent or descent rate is less than this value
ASCENT_RATE_THRESHOLD = 0.8
def flight_profile_by_type(sonde_type):
"""
Determine the appropriate flight profile based on radiosonde type
"""
for _def_type in SONDE_TYPE_PREDICT_DEFAULTS:
if _def_type in sonde_type:
return SONDE_TYPE_PREDICT_DEFAULTS[_def_type].copy()
return PREDICT_DEFAULTS.copy()
def getDensity(altitude):
"""
Calculate the atmospheric density for a given altitude in metres.
This is a direct port of the oziplotter Atmosphere class
"""
# Constants
airMolWeight = 28.9644 # Molecular weight of air
densitySL = 1.225 # Density at sea level [kg/m3]
pressureSL = 101325 # Pressure at sea level [Pa]
temperatureSL = 288.15 # Temperature at sea level [deg K]
gamma = 1.4
gravity = 9.80665 # Acceleration of gravity [m/s2]
tempGrad = -0.0065 # Temperature gradient [deg K/m]
RGas = 8.31432 # Gas constant [kg/Mol/K]
R = 287.053
deltaTemperature = 0.0
# Lookup Tables
altitudes = [0, 11000, 20000, 32000, 47000, 51000, 71000, 84852]
pressureRels = [
1,
2.23361105092158e-1,
5.403295010784876e-2,
8.566678359291667e-3,
1.0945601337771144e-3,
6.606353132858367e-4,
3.904683373343926e-5,
3.6850095235747942e-6,
]
temperatures = [288.15, 216.65, 216.65, 228.65, 270.65, 270.65, 214.65, 186.946]
tempGrads = [-6.5, 0, 1, 2.8, 0, -2.8, -2, 0]
gMR = gravity * airMolWeight / RGas
# Pick a region to work in
i = 0
if altitude > 0:
while altitude > altitudes[i + 1]:
i = i + 1
# Lookup based on region
baseTemp = temperatures[i]
tempGrad = tempGrads[i] / 1000.0
pressureRelBase = pressureRels[i]
deltaAltitude = altitude - altitudes[i]
temperature = baseTemp + tempGrad * deltaAltitude
# Calculate relative pressure
if math.fabs(tempGrad) < 1e-10:
pressureRel = pressureRelBase * math.exp(
-1 * gMR * deltaAltitude / 1000.0 / baseTemp
)
else:
pressureRel = pressureRelBase * math.pow(
baseTemp / temperature, gMR / tempGrad / 1000.0
)
# Add temperature offset
temperature = temperature + deltaTemperature
# Finally, work out the density...
speedOfSound = math.sqrt(gamma * R * temperature)
pressure = pressureRel * pressureSL
density = densitySL * pressureRel * temperatureSL / temperature
return density
def seaLevelDescentRate(descent_rate, altitude):
""" Calculate the descent rate at sea level, for a given descent rate at altitude """
rho = getDensity(altitude)
return math.sqrt((rho / 1.225) * math.pow(descent_rate, 2))
# Earthmaths code by Daniel Richman (thanks!)
# Copyright 2012 (C) Daniel Richman; GNU GPL 3
def position_info(listener, balloon):
"""
Calculate and return information from 2 (lat, lon, alt) tuples
Returns a dict with:
- angle at centre
- great circle distance
- distance in a straight line
- bearing (azimuth or initial course)
- elevation (altitude)
Input and output latitudes, longitudes, angles, bearings and elevations are
in degrees, and input altitudes and output distances are in meters.
"""
# Earth:
radius = 6371000.0
(lat1, lon1, alt1) = listener
(lat2, lon2, alt2) = balloon
lat1 = radians(lat1)
lat2 = radians(lat2)
lon1 = radians(lon1)
lon2 = radians(lon2)
# Calculate the bearing, the angle at the centre, and the great circle
# distance using Vincenty's_formulae with f = 0 (a sphere). See
# http://en.wikipedia.org/wiki/Great_circle_distance#Formulas and
# http://en.wikipedia.org/wiki/Great-circle_navigation and
# http://en.wikipedia.org/wiki/Vincenty%27s_formulae
d_lon = lon2 - lon1
sa = cos(lat2) * sin(d_lon)
sb = (cos(lat1) * sin(lat2)) - (sin(lat1) * cos(lat2) * cos(d_lon))
bearing = atan2(sa, sb)
aa = sqrt((sa ** 2) + (sb ** 2))
ab = (sin(lat1) * sin(lat2)) + (cos(lat1) * cos(lat2) * cos(d_lon))
angle_at_centre = atan2(aa, ab)
great_circle_distance = angle_at_centre * radius
# Armed with the angle at the centre, calculating the remaining items
# is a simple 2D triangley circley problem:
# Use the triangle with sides (r + alt1), (r + alt2), distance in a
# straight line. The angle between (r + alt1) and (r + alt2) is the
# angle at the centre. The angle between distance in a straight line and
# (r + alt1) is the elevation plus pi/2.
# Use sum of angle in a triangle to express the third angle in terms
# of the other two. Use sine rule on sides (r + alt1) and (r + alt2),
# expand with compound angle formulae and solve for tan elevation by
# dividing both sides by cos elevation
ta = radius + alt1
tb = radius + alt2
ea = (cos(angle_at_centre) * tb) - ta
eb = sin(angle_at_centre) * tb
elevation = atan2(ea, eb)
# Use cosine rule to find unknown side.
distance = sqrt((ta ** 2) + (tb ** 2) - 2 * tb * ta * cos(angle_at_centre))
# Give a bearing in range 0 <= b < 2pi
if bearing < 0:
bearing += 2 * pi
return {
"listener": listener,
"balloon": balloon,
"listener_radians": (lat1, lon1, alt1),
"balloon_radians": (lat2, lon2, alt2),
"angle_at_centre": degrees(angle_at_centre),
"angle_at_centre_radians": angle_at_centre,
"bearing": degrees(bearing),
"bearing_radians": bearing,
"great_circle_distance": great_circle_distance,
"straight_distance": distance,
"elevation": degrees(elevation),
"elevation_radians": elevation,
}
def compare_launch_sites(sites, launch_estimate, altitude=0):
"""
Compare a provided launch position estimate with all known launch sites
If a launch site is within a threshold, return the launch site.
"""
launch_site = None
launch_site_range = 999999999999999
for _site in sites:
try:
_site_pos = [sites[_site]['position'][1], sites[_site]['position'][0], sites[_site]['alt']]
_pos_info = position_info(_site_pos, launch_estimate)
if _pos_info['straight_distance'] < launch_site_range:
launch_site = _site
launch_site_range = _pos_info['straight_distance']
except Exception as e:
logging.error(f"Error comparing launch site with estimate: {str(e)}")
print(_site_pos)
print(launch_estimate)
continue
# print(sites[launch_site])
# print(launch_site_range)
_allocate_range = min(LAUNCH_ALLOCATE_RANGE_MAX, max(LAUNCH_ALLOCATE_RANGE_MIN, altitude*LAUNCH_ALLOCATE_RANGE_SCALING))
if launch_site_range < _allocate_range:
return {'site':launch_site, 'range': launch_site_range}
else:
return None
def get_standard_prediction(timestamp, latitude, longitude, altitude, current_rate=5.0, ascent_rate=PREDICT_DEFAULTS['ascent_rate'], burst_altitude=PREDICT_DEFAULTS['burst_altitude'], descent_rate=PREDICT_DEFAULTS['descent_rate']):
"""
Request a standard flight path prediction from Tawhiri.
Notes:
- The burst_altitude must be higher than the current altitude.
- Longitude is in the range 0-360.0
- All ascent/descent rates must be positive.
"""
try:
# Bomb out if the rates are too low.
if ascent_rate < ASCENT_RATE_THRESHOLD:
return None
if descent_rate < ASCENT_RATE_THRESHOLD:
return None
# Shift longitude into the appropriate range for Tawhiri
if longitude < 0:
longitude += 360.0
# Generate the prediction URL
url = f"/api/v1/?launch_latitude={latitude}&launch_longitude={longitude}&launch_datetime={timestamp}&launch_altitude={altitude:.2f}&ascent_rate={ascent_rate:.2f}&burst_altitude={burst_altitude:.2f}&descent_rate={descent_rate:.2f}"
logging.debug(url)
conn = http.client.HTTPSConnection("tawhiri.v2.sondehub.org")
conn.request("GET", url)
res = conn.getresponse()
data = res.read()
if res.code != 200:
logging.debug(data)
return None
pred_data = json.loads(data.decode("utf-8"))
path = []
if 'prediction' in pred_data:
for stage in pred_data['prediction']:
# Probably don't need to worry about this, it should only result in one or two points
# in 'ascent'.
if stage['stage'] == 'ascent' and current_rate < 0: # ignore ascent stage if we have already burst
continue
else:
for item in stage['trajectory']:
path.append({
"time": int(datetime.fromisoformat(item['datetime'].split(".")[0].replace("Z","")).timestamp()),
"lat": item['latitude'],
"lon": item['longitude'] - 360 if item['longitude'] > 180 else item['longitude'],
"alt": item['altitude'],
})
pred_data['path'] = path
return pred_data
else:
return None
except:
traceback.print_exc()
logging.error(f"Error turnning standard prediction for {url}")
return None
def get_launch_estimate(timestamp, latitude, longitude, altitude, ascent_rate=PREDICT_DEFAULTS['ascent_rate'], current_rate=5.0):
"""
Estimate the launch site of a sonde based on a current ascent position.
Notes:
- Longitude is in the range 0-360.0
- All ascent/descent rates must be positive.
UNTESTED
"""
# Bomb out if the rates are too low.
if ascent_rate < ASCENT_RATE_THRESHOLD:
return None
# Shift longitude into the appropriate range for Tawhiri
if longitude < 0:
longitude += 360.0
# Generate the prediction URL
url = f"/api/v1/?profile=reverse_profile&launch_latitude={latitude}&launch_longitude={longitude}&launch_datetime={timestamp}&launch_altitude={altitude:.2f}&ascent_rate={ascent_rate:.2f}"
logging.debug(url)
conn = http.client.HTTPSConnection("tawhiri.v2.sondehub.org")
conn.request("GET", url)
res = conn.getresponse()
data = res.read()
if res.code != 200:
logging.debug(data)
return None
pred_data = json.loads(data.decode("utf-8"))
path = []
if 'prediction' in pred_data:
for stage in pred_data['prediction']:
# Probably don't need to worry about this, it should only result in one or two points
# in 'ascent'.
if stage['stage'] == 'ascent' and current_rate < 0: # ignore ascent stage if we have already burst
continue
else:
for item in stage['trajectory']:
path.append({
"time": int(datetime.fromisoformat(item['datetime'].split(".")[0].replace("Z","")).timestamp()),
"lat": item['latitude'],
"lon": item['longitude'] - 360 if item['longitude'] > 180 else item['longitude'],
"alt": item['altitude'],
})
pred_data['path'] = path
return pred_data
else:
return None
# return a dict key'd by serial with reverse prediction data
def get_reverse_predictions():
path = "reverse-prediction-*/_search"
payload = {
"size": 1000,
"sort": [
{
"datetime": {
"order": "asc",
"unmapped_type": "boolean"
}
}
],
"query": {
"bool": {
"filter": [
{
"range": {
"datetime": {
"gte": "now-1d",
"lte": "now",
"format": "strict_date_optional_time"
}
}
}
]
}
}
}
logging.debug("Start ES Request")
results = es.request(json.dumps(payload), path, "POST")
logging.debug("Finished ES Request")
return { x['_source']['serial'] : x['_source'] for x in results['hits']['hits']}
# Example data structure from get_launch_sites
# {
# '01028': {'station': '01028', 'rs_types': ['23'], 'position': [19.0012, 74.5038], 'alt': 20, 'station_name': 'Bjornoya (Norway)', 'times': ['0:00:00', '0:06:00', '0:12:00', '0:18:00']},
# '-3': {'station': '-3', 'rs_types': ['17'], 'position': [-1.23813, 44.35714], 'alt': 15, 'station_name': 'DGA Essais de missiles (France)', 'burst_altitude': 20000},
# '-2': {'station': '-2', 'rs_types': ['63', '77'], 'position': [2.60012, 48.337861], 'alt': 118, 'station_name': 'METEOMODEM Headquarters (France)'},
# ...
# }
def get_launch_sites():
path = "sites/_search"
payload = {
"size": 10000
}
logging.debug("Start ES Request")
results = es.request(json.dumps(payload), path, "POST")
logging.debug("Finished ES Request")
return {x['_source']['station']: x['_source'] for x in results['hits']['hits']}
def bulk_upload_es(index_prefix,payloads):
body=""
for payload in payloads:
body += "{\"index\":{}}\n" + json.dumps(payload) + "\n"
body += "\n"
date_prefix = datetime.now().strftime("%Y-%m")
result = es.request(body, f"{index_prefix}-{date_prefix}/_bulk", "POST")
if 'errors' in result and result['errors'] == True:
error_types = [x['index']['error']['type'] for x in result['items'] if 'error' in x['index']] # get all the error types
error_types = [a for a in error_types if a != 'mapper_parsing_exception'] # filter out mapper failures since they will never succeed
if error_types:
print(result)
raise RuntimeError
def predict(event, context):
client.loop(timeout=0.05, max_packets=1) # make sure MQTT reconnects
# Use asyncio.run to synchronously "await" an async function
result = asyncio.run(predict_async(event, context))
time.sleep(0.5) # give paho mqtt 500ms to send messages this could be improved on but paho mqtt is a pain to interface with
return result
async def predict_async(event, context):
sem = asyncio.Semaphore(5)
path = "telm-*/_search"
interval = 10
lag = 3 # how many samples to use
payload = {
"aggs": {
"2": {
"terms": {
"field": "serial.keyword",
"order": {
"_key": "desc"
},
"size": 1000
},
"aggs": {
"3": {
"date_histogram": {
"field": "datetime",
"fixed_interval": f"{interval}s"
},
"aggs": {
"1": {
"top_hits": {
"docvalue_fields": [
{
"field": "alt"
}
],
"_source": "alt",
"size": 1,
"sort": [
{
"datetime": {
"order": "desc"
}
}
]
}
},
"4": {
"serial_diff": {
"buckets_path": "4-metric",
"gap_policy": "skip",
"lag": lag
}
},
"5": {
"top_hits": {
"docvalue_fields": [
{
"field": "position"
}
],
"_source": {"includes": ["position", "type", "subtype"]},
"size": 1,
"sort": [
{
"datetime": {
"order": "desc"
}
}
]
}
},
"4-metric": {
"avg": {
"field": "alt"
}
}
}
}
}
}
},
"size": 0,
"stored_fields": [
"*"
],
"script_fields": {},
"docvalue_fields": [
{
"field": "@timestamp",
"format": "date_time"
},
{
"field": "datetime",
"format": "date_time"
},
{
"field": "log_date",
"format": "date_time"
},
{
"field": "time_received",
"format": "date_time"
},
{
"field": "time_server",
"format": "date_time"
},
{
"field": "time_uploaded",
"format": "date_time"
}
],
"_source": {
"excludes": []
},
"query": {
"bool": {
"must_not":[
{
"match": {
"lat": 0,
}
},
{
"match": {
"lon": 0,
}
},
{
"match": {
"sats": 0,
}
}
],
# "must": [
# {
# "exists": {
# "field": "sats"
# }
# },
# {
# "range": {
# "sats": {
# "gte": 1,
# "lt": None
# }
# }
# }
# ],
"filter": [
{
"match_all": {}
},
{
"range": {
"datetime": {
"gte": "now-10m",
"lte": "now",
"format": "strict_date_optional_time"
}
}
}
],
"should": []
}
},
"size": 0
}
logging.debug("Start ES Request")
results = es.request(json.dumps(payload), path, "GET")
logging.debug("Finished ES Request")
serials = { }
for x in results['aggregations']['2']['buckets']:
try:
serials[x['key']] = {
"alt": sorted(x['3']['buckets'], key=lambda k: k['key_as_string'])[-1]['1']['hits']['hits'][0]['fields']['alt'][0],
"position": sorted(x['3']['buckets'], key=lambda k: k['key_as_string'])[-1]['5']['hits']['hits'][0]['fields']['position'][0].split(","),
"rate": sorted(x['3']['buckets'], key=lambda k: k['key_as_string'])[-1]['4']['value']/(lag*interval), # as we bucket for every 5 seconds with a lag of 5
"time": sorted(x['3']['buckets'], key=lambda k: k['key_as_string'])[-1]['key_as_string'],
"type": sorted(x['3']['buckets'], key=lambda k: k['key_as_string'])[-1]['5']['hits']['hits'][0]["_source"]["type"],
"subtype": sorted(x['3']['buckets'], key=lambda k: k['key_as_string'])[-1]['5']['hits']['hits'][0]["_source"]["subtype"] if "subtype" in sorted(x['3']['buckets'], key=lambda k: k['key_as_string'])[-1]['5']['hits']['hits'][0]["_source"] else None
}
except:
pass
launch_sites = get_launch_sites()
reverse_predictions = get_reverse_predictions()
serial_data={}
reverse_serial_data = {}
logging.debug("Start Predict")
jobs=[]
for serial in serials:
jobs.append(run_predictions_for_serial(sem, serial, serials[serial], reverse_predictions, launch_sites))
output = await asyncio.gather(*jobs)
for data in output:
if data:
serial_data[data[0]] = data[1]
if data[2]:
reverse_serial_data[data[0]] = data[2]
logging.debug("Stop Predict")
# Collate and upload forward predictions
output = []
for serial in serial_data:
value = serial_data[serial]
if value is not None:
output.append(
{
"serial": serial,
"type": serials[serial]['type'],
"subtype": serials[serial]['subtype'],
"datetime": value['request']['launch_datetime'],
"position": [
value['request']['launch_longitude'] - 360 if value['request']['launch_longitude'] > 180 else value['request']['launch_longitude'],
value['request']['launch_latitude']
],
"altitude": value['request']['launch_altitude'],
"ascent_rate": value['request']['ascent_rate'],
"descent_rate": value['request']['descent_rate'],
"burst_altitude": value['request']['burst_altitude'],
"descending": True if serials[serial]['rate'] < 0 else False,
"landed": False, # I don't think this gets used anywhere?
"data": value['path']
}
)
# Collate and upload reverse predictions
output_reverse = []
for serial in reverse_serial_data:
value = reverse_serial_data[serial]
if value is not None:
_tmp = {
"serial": serial,
"type": serials[serial]['type'],
"subtype": serials[serial]['subtype'],
"datetime": value['request']['launch_datetime'],
"position": [
value['request']['launch_longitude'] - 360 if value['request']['launch_longitude'] > 180 else value['request']['launch_longitude'],
value['request']['launch_latitude']
],
"altitude": value['request']['launch_altitude'],
"ascent_rate": value['request']['ascent_rate'],
"data": value['path']
}
if 'launch_site' in value:
_tmp['launch_site'] = value['launch_site']
if 'launch_site_range_estimate' in value:
_tmp['launch_site_range_estimate'] = value['launch_site_range_estimate']
output_reverse.append(_tmp)
if len(output) > 0:
bulk_upload_es("predictions", output)
if len(output_reverse) > 0:
bulk_upload_es("reverse-prediction", output_reverse)
# upload to mqtt
while not connected_flag:
time.sleep(0.01) # wait until connected
for prediction in output:
logging.debug(f'Publishing prediction for {prediction["serial"]} to MQTT')
client.publish(
topic=f'prediction/{prediction["serial"]}',
payload=json.dumps(prediction),
qos=0,
retain=False
)
logging.debug(f'Published prediction for {prediction["serial"]} to MQTT')
for prediction in output_reverse:
logging.debug(f'Publishing reverse prediction for {prediction["serial"]} to MQTT')
client.publish(
topic=f'reverse-prediction/{prediction["serial"]}',
payload=json.dumps(prediction),
qos=0,
retain=False
)
logging.debug(f'Published reverse prediction for {prediction["serial"]} to MQTT')
logging.debug("Finished")
return
async def run_predictions_for_serial(sem, serial, value, reverse_predictions, launch_sites):
async with sem:
loop = asyncio.get_event_loop()
#
# Flight Profile selection
#
# Fallback Option - use flight profile data based on sonde type.
_flight_profile = flight_profile_by_type(value['type'])
reverse_serial_data = None
# Check if we have already run a reverse prediction on this serial
if serial in reverse_predictions:
logging.debug(f"Found reverse prediction for {serial}.")
_rev_pred = reverse_predictions[serial]
#print(_rev_pred)
if 'launch_site' in _rev_pred:
# This serial number has been assigned to a launch site!
# Grab the launch site information
try:
_site_info = launch_sites[_rev_pred['launch_site']]
# If we have flight profile data, update the default flight profile
if 'ascent_rate' in _site_info:
_flight_profile['ascent_rate'] = _site_info['ascent_rate']
if 'burst_altitude' in _site_info:
_flight_profile['burst_altitude'] = _site_info['burst_altitude']
if 'descent_rate' in _site_info:
_flight_profile['descent_rate'] = _site_info['descent_rate']
logging.debug(f"{serial} - Using Flight Profile data for Launch site: {_site_info['station_name']}")
except KeyError:
logging.info(f"Possible missing launch site {_rev_pred['launch_site'] } for sonde {serial}")
else:
# No launch site was allocated...
# TODO - Try again?
pass
else:
# No reverse prediction data!
# We can only run a reverse prediction with a sonde on ascent.
#print(f"{serial}: {value['rate']}")
if value['rate'] > ASCENT_RATE_THRESHOLD:
# Try and run a reverse prediction
logging.info(f"Running reverse predict for {serial}")
longitude = float(value['position'][1].strip())
latitude = float(value['position'][0].strip())
_rev_pred = get_launch_estimate(
value['time'],
latitude,
longitude,
value['alt'],
current_rate=value['rate'],
ascent_rate=value['rate']
)
if _rev_pred:
# Attempt to find a launch site near to the launch estimate.
_launch_estimate = [_rev_pred['launch_estimate']['latitude'], _rev_pred['launch_estimate']['longitude'], _rev_pred['launch_estimate']['altitude']]
_alloc_site = compare_launch_sites(launch_sites, _launch_estimate, value['alt'])
if _alloc_site:
# We have found the launch site!
# {'site':_site, 'range': launch_site_range}
logging.info(f"Allocated {serial} to launch site {launch_sites[_alloc_site['site']]['station_name']} ({_alloc_site['site']}) with range {_alloc_site['range']:.1f}.")
# Add launch site into the prediction data
_rev_pred['launch_site'] = _alloc_site['site']
_rev_pred['launch_site_range_estimate'] = _alloc_site['range']
# If we have flight profile data, update the default flight profile
_site_info = launch_sites[_alloc_site['site']]
if 'ascent_rate' in _site_info:
_flight_profile['ascent_rate'] = _site_info['ascent_rate']
if 'burst_altitude' in _site_info:
_flight_profile['burst_altitude'] = _site_info['burst_altitude']
if 'descent_rate' in _site_info:
_flight_profile['descent_rate'] = _site_info['descent_rate']
# Add to dict for upload later.
reverse_serial_data = _rev_pred
else:
# Launch estimate prediction failed.
pass
#print(value)
#print(_flight_profile)
logging.debug(f"Running prediction for {serial} using flight profile {str(_flight_profile)}.")
# skip when close to 0.
if value['rate'] < ASCENT_RATE_THRESHOLD and value['rate'] > -ASCENT_RATE_THRESHOLD:
logging.debug(f"Skipping {serial} due to ascent rate limiting.")
return False
# Determine current ascent rate
# If the value is < 0.5 (e.g. we are on descent, or not moving), we just use a default value.
ascent_rate=value['rate'] if value['rate'] > ASCENT_RATE_THRESHOLD else _flight_profile['ascent_rate']
# If we are on descent, estimate the sea-level descent rate from the current descent rate
# Otherwise, use the flight profile descent rate
descent_rate= seaLevelDescentRate(abs(value['rate']),value['alt']) if value['rate'] < 0 else _flight_profile['descent_rate']
# If the resultant sea-level descent rate is very small, it means we're probably landed
# so dont run a prediction for this sonde.
if descent_rate < ASCENT_RATE_THRESHOLD:
return False
# Now to determine the burst altitude
if value['rate'] < 0:
# On descent (rate < 0), we need to set the burst altitude just higher than our current altitude for
# the predictor to be happy
burst_altitude = value['alt']+0.05
else:
# Otherwise, on ascent we either use the expected burst altitude, or we
# add a little bit on to our current altitude.
burst_altitude = (value['alt']+0.05) if value['alt'] > _flight_profile['burst_altitude'] else _flight_profile['burst_altitude']
longitude = float(value['position'][1].strip())
latitude = float(value['position'][0].strip())
#print(f"Prediction Parameters for {serial} at {latitude}, {longitude}, {value['alt']}: {ascent_rate}/{burst_altitude}/{descent_rate}")
# Run prediction! This will return None if there is an error
return [serial, await loop.run_in_executor(None, functools.partial(get_standard_prediction,
value['time'],
latitude,
longitude,
value['alt'],
current_rate=value['rate'],
ascent_rate=ascent_rate,
burst_altitude=burst_altitude,
descent_rate=descent_rate
)), reverse_serial_data]
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