Metadata-Version: 2.1
Name: pypredict
Version: 1.7.2
Summary: Interface to the Predict satellite tracking and orbital prediction library
Home-page: https://github.com/nsat/pypredict
Author: Jesse Trutna
Author-email: jesse@spire.com
Maintainer: Spire Global Inc
Maintainer-email: opensource@spire.com
License: UNKNOWN
Platform: UNKNOWN
Classifier: License :: OSI Approved :: GNU General Public License v2 or later (GPLv2+)
Classifier: Programming Language :: Python :: 2.7
Classifier: Programming Language :: Python :: 3.7
Classifier: Programming Language :: Python :: 3.8
Classifier: Programming Language :: Python :: 3.9
Classifier: Programming Language :: Python :: 3.10
Classifier: Programming Language :: Python :: 3.11
Description-Content-Type: text/markdown

[![ci](https://github.com/nsat/pypredict/actions/workflows/python-app.yml/badge.svg)](https://github.com/nsat/pypredict/actions/workflows/python-app.yml)

PyPredict
=======

><b>NOTE</b>: To preserve compatibility with `predict`, pypredict uses __north__ latitude and __west__ longitude for terrestrial coordinates.

Do you want accurate and time-tested satellite tracking and pass prediction in a convenient python wrapper?
You're in the right place.

PyPredict is a C Python extension directly adapted from the ubiquitous [predict](http://www.qsl.net/kd2bd/predict.html) satellite tracking command line application.
Originally written for the commodore 64, predict has a proven pedigree; We just aim to provide a convenient API.
PyPredict is a port of the predict codebase and should yield identical results.

If you think you've found an error in `pypredict`, please include output from `predict` on same inputs to the bug report.  
If you think you've found a bug in predict, please report and we'll coordinate with upstream.

### Installation

```bash
sudo apt-get install python-dev
sudo python setup.py install
```

## Usage

#### Observe a satellite (relative to a position on earth)

```python
import predict
tle = """0 LEMUR 1
1 40044U 14033AL  15013.74135905  .00002013  00000-0  31503-3 0  6119
2 40044 097.9584 269.2923 0059425 258.2447 101.2095 14.72707190 30443"""
qth = (37.771034, 122.413815, 7)  # lat (N), long (W), alt (meters)
predict.observe(tle, qth) # optional time argument defaults to time.time()
# => {'altitude': 676.8782276657903,
#     'azimuth': 96.04762045174824,
#     'beta_angle': -27.92735429908726,
#     'decayed': 0,
#     'doppler': 1259.6041017128405,
#     'eci_obs_x': -2438.227652191655,
#     'eci_obs_y': -4420.154476060397,
#     'eci_obs_z': 3885.390601342013,
#     'eci_sun_x': 148633398.020844,
#     'eci_sun_y': -7451536.44122029,
#     'eci_sun_z': -3229999.50056359,
#     'eci_vx': 0.20076213530665032,
#     'eci_vy': -1.3282146055077213,
#     'eci_vz': 7.377067234096598,
#     'eci_x': 6045.827328897242,
#     'eci_y': -3540.5885778261277,
#     'eci_z': -825.4065096776636,
#     'eclipse_depth': -87.61858291647795,
#     'elevation': -43.711904591801726,
#     'epoch': 1521290038.347793,
#     'footprint': 5633.548906707907,
#     'geostationary': 0,
#     'has_aos': 1,
#     'latitude': -6.759563817939698,
#     'longitude': 326.1137007912563,
#     'name': '0 LEMUR 1',
#     'norad_id': 40044,
#     'orbit': 20532,
#     'orbital_model': 'SGP4',
#     'orbital_phase': 145.3256815318047,
#     'orbital_velocity': 26994.138671706416,
#     'slant_range': 9743.943478523843,
#     'sunlit': 1,
#     'visibility': 'D'
#    }
```

#### Show upcoming transits of satellite over ground station

```python
# start and stop transit times as UNIX timestamp
transit_start = 1680775200
transit_stop = 1681034400

p = predict.transits(tle, qth, transit_start, transit_stop)

print("Start of Transit\tTransit Duration (s)\tPeak Elevation")
for transit in p:
    print(f"{transit.start}\t{transit.duration()}\t{transit.peak()['elevation']}")
```


#### Modeling an entire constellation

Generating transits for a lot of satellites over a lot of ground stations can be slow.
Luckily, generating transits for each satellite-groundstation pair can be parallelized for a big speed-up.

```python
import itertools
from multiprocessing.pool import Pool
import time

import predict
import requests

# Define a function that returns arguments for all the transits() calls you want to make
def _transits_call_arguments():
    now = time.time()
    tle = requests.get('http://tle.spire.com/25544').text.rstrip()
    for latitude in range(-90, 91, 15):
        for longitude in range(-180, 181, 15):
            qth = (latitude, longitude, 0)
            yield {'tle': tle, 'qth': qth, 'ending_before': now+60*60*24*7}

# Define a function that calls the transit function on a set of arguments and does per-transit processing
def _transits_call_fx(kwargs):
    try:
        transits = list(predict.transits(**kwargs))
        return [t.above(10) for t in transits]
    except predict.PredictException:
        pass

# Map the transit() caller across all the arguments you want, then flatten results into a single list
pool = Pool(processes=10)
array_of_results = pool.map(_transits_call_fx, _transits_call_arguments())
flattened_results = list(itertools.chain.from_iterable(filter(None, array_of_results)))
transits = flattened_results
```

NOTE: If precise accuracy isn't necessary (for modeling purposes, for example) setting the tolerance argument
      to the `above` call to a larger value, say 1 degree, can provide a significant performance boost.

#### Call predict analogs directly

```python
predict.quick_find(tle.split('\n'), time.time(), (37.7727, 122.407, 25))
predict.quick_predict(tle.split('\n'), time.time(), (37.7727, 122.407, 25))
```

## API
<pre>
<b>observe</b>(<i>tle, qth[, at=None]</i>)  
    Return an observation of a satellite relative to a groundstation.
    <i>qth</i> groundstation coordinates as (lat(N),long(W),alt(m))
    If <i>at</i> is not defined, defaults to current time (time.time())
    Returns an "observation" or dictionary containing:  
        <i>altitude</i> _ altitude of satellite in kilometers
        <i>azimuth</i> - azimuth of satellite in degrees from perspective of groundstation.
        <i>beta_angle</i>
        <i>decayed</i> - 1 if satellite has decayed out of orbit, 0 otherwise.
        <i>doppler</i> - doppler shift between groundstation and satellite.
        <i>eci_obs_x</i>
        <i>eci_obs_y</i>
        <i>eci_obs_z</i>
        <i>eci_sun_x</i>
        <i>eci_sun_y</i>
        <i>eci_sun_z</i>
        <i>eci_vx</i>
        <i>eci_vy</i>
        <i>eci_vz</i>
        <i>eci_x</i>
        <i>eci_y</i>
        <i>eci_z</i>
        <i>eclipse_depth</i>
        <i>elevation</i> - elevation of satellite in degrees from perspective of groundstation.
        <i>epoch</i> - time of observation in seconds (unix epoch)
        <i>footprint</i>
        <i>geostationary</i> - 1 if satellite is determined to be geostationary, 0 otherwise.
        <i>has_aos</i> - 1 if the satellite will eventually be visible from the groundstation
        <i>latitude</i> - north latitude of point on earth directly under satellite.
        <i>longitude</i> - west longitude of point on earth directly under satellite.
        <i>name</i> - name of satellite from first line of TLE.
        <i>norad_id</i> - NORAD id of satellite.
        <i>orbit</i>
        <i>orbital_phase</i>
        <i>orbital_model</i>
        <i>orbital_velocity</i>
        <i>slant_range</i> - distance to satellite from groundstation in meters.
        <i>sunlit</i> - 1 if satellite is in sunlight, 0 otherwise.
        <i>visibility</i>
<b>transits</b>(<i>tle, qth[, ending_after=None][, ending_before=None]</i>)  
    Returns iterator of <b>Transit</b> objects representing passes of tle over qth.  
    If <i>ending_after</i> is not defined, defaults to current time  
    If <i>ending_before</i> is not defined, the iterator will yield until calculation failure.
</pre>
><b>NOTE</b>: We yield passes based on their end time.  This means we'll yield currently active passes in the two-argument invocation form, but their start times will be in the past.

<pre>
<b>Transit</b>(<i>tle, qth, start, end</i>)  
    Utility class representing a pass of a satellite over a groundstation.
    Instantiation parameters are parsed and made available as fields.
    <b>duration</b>()  
        Returns length of transit in seconds
    <b>peak</b>(<i>epsilon=0.1</i>)  
        Returns epoch time where transit reaches maximum elevation (within ~<i>epsilon</i>)
    <b>at</b>(<i>timestamp</i>)  
        Returns observation during transit via <b>quick_find</b>(<i>tle, timestamp, qth</i>)
    <b>above</b>b(<i>elevation</i>, <i>tolerance</i>)
        Returns portion of transit above elevation. If the entire transit is below the target elevation, both
        endpoints will be set to the peak and the duration will be zero. If a portion of the transit is above
        the elevation target, the endpoints will be between elevation and elevation + tolerance (unless
        endpoint is already above elevation, in which case it will be unchanged)
<b>quick_find</b>(<i>tle[, time[, (lat, long, alt)]]</i>)  
    <i>time</i> defaults to current time   
    <i>(lat, long, alt)</i> defaults to values in ~/.predict/predict.qth  
    Returns observation dictionary equivalent to observe(tle, time, (lat, long, alt))
<b>quick_predict</b>(<i>tle[, time[, (lat, long, alt)]]</i>)  
        Returns an array of observations for the next pass as calculated by predict.
        Each observation is identical to that returned by <b>quick_find</b>.
</pre>


