Machine learning calibration for Islamic prayer times. Fits Fajr/Isha depression angles to observed mosque data via weighted least-squares regression.
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Aric Camarata 1d48dc5b2e Expand dataset to 4,527 Fajr / 82 Isha records across 112 locations (Batches 8-10)
Batch 8: Saksono & Fulazzaky 2020 (NRIAG J Astron Geophys 9:238-244)
- Depok, West Java, Indonesia (6.383°S, 106.83°E): 8 aggregate Fajr records
- SQM, 26 nights Jun-Jul 2015, D0=14.0° ± 0.6°, suburban LP

Batch 9: Rashed et al. 2022 (IJMET 13(10):8-24)
- Fayum (Wadi al-Hitan), Egypt (29.283°N, 30.050°E): 6 Fajr records
- SQM-LU-DL + naked eye, Dec 2018-2019, D0=14.7°, remote desert

Batch 10: Abdel-Hadi & Hassan 2022 (IJAA 12(1):7-29)
- Per-date D0 values from Shariff 2008 SQM-LE data (M.Sc. Univ. Malaya)
- 8 Fajr records: Merang, Kuala Lipis, Port Klang (3 new sites)
- 12 Isha records: Teluk Kemang, Kuala Lumpur, Kuala Lipis, Port Klang
- Malaysia, May 2007 - April 2008, UTC+8
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pray-calc-ml

A Python data science project that collects and back-calculates solar depression angles from human-verified Fajr and Isha prayer sightings. The goal is to find the real empirical patterns in how the solar depression angle at Fajr and Isha varies with latitude, season, and elevation — then use machine learning to refine the DPC (Dynamic Pray Calc) algorithm in pray-calc.

What this is

Most Islamic prayer time calculators use a fixed angle (e.g. 15° or 18°) for Fajr and Isha. Peer-reviewed observation studies consistently find the real angle is lower and varies with latitude, season, and atmospheric conditions. This project compiles the most complete dataset of actual human-verified sightings and back-calculates the solar depression angle at each observed moment.

The training data comes exclusively from confirmed human sightings with explicit dates, locations, and times. No aggregated statistics or calculated-angle guesses are used as ground truth. Each record is back-calculated independently using PyEphem.

Datasets

Two clean CSV files are generated by the pipeline:

data/processed/fajr_angles.csv — One confirmed Fajr sighting per row

Column Description
date YYYY-MM-DD (local calendar date)
utc_dt ISO 8601 UTC datetime
lat Decimal degrees (north positive)
lng Decimal degrees (east positive)
elevation_m Metres above sea level
day_of_year 1-366 (seasonality feature)
fajr_angle Solar depression angle at moment of sighting (degrees)
source Citation
notes Observer notes

data/processed/isha_angles.csv — Same schema with isha_angle.

Current dataset size

  • Fajr: ~4,100 records, 35 unique locations, latitude range -37.8° to 53.7°
  • Isha: ~43 records, 20+ locations
  • Date range: 1984 to 2026

The dominant Fajr source is the OpenFajr Project — 4,000+ community-reviewed daily observations from Birmingham, UK. The remaining records are manually compiled from peer-reviewed studies spanning Egypt, Saudi Arabia, Malaysia, Indonesia, Turkey, Morocco, and other locations across five continents.

Setup

python -m venv .venv
source .venv/bin/activate
pip install -r requirements.txt

Running the pipeline

python -m src.pipeline

This fetches the OpenFajr iCal feed (network required), loads the compiled sighting records, back-calculates depression angles, and writes both CSVs.

python -m src.pipeline --no-elevation-lookup

Skip the Open-Elevation API calls and use pre-set elevations from the source records.

Project structure

pray-calc-ml/
├── src/
│   ├── angle_calc.py          Back-calculation: observed time -> depression angle (PyEphem)
│   ├── elevation.py           Open-Elevation API lookup
│   ├── pipeline.py            Master pipeline: collect -> enrich -> filter -> export
│   └── collect/
│       ├── openfajr.py        OpenFajr iCal feed parser
│       └── verified_sightings.py  Manually compiled records from peer-reviewed studies
├── data/
│   ├── raw/sources.md         Full data source documentation
│   └── processed/             Generated CSVs (not committed to git)
├── notebooks/
│   └── 01_exploratory_analysis.ipynb  Latitude, TOY, and elevation pattern analysis
├── research/                  Academic paper summaries (not training data)
└── requirements.txt

Back-calculation method

For each confirmed sighting (date, location, observed local time):

  1. Convert observed local time to UTC using the documented UTC offset
  2. Set up a PyEphem observer at the sighting location with standard atmosphere (1013.25 hPa, 15°C)
  3. Compute solar altitude at the UTC moment, including atmospheric refraction
  4. Depression angle = negative altitude (positive when sun is below the horizon)

Records where the depression angle is below 7° (Fajr) or 10° (Isha) are dropped as data entry errors. This catches DST clock-change artifacts in the OpenFajr feed and a small number of mis-estimated observation times.

Key findings so far

The data shows three main patterns:

  1. Latitude matters. Near-equatorial sites (Malaysia, Indonesia, 2°-7°) show mean Fajr angles of 16°-17°. Mid-latitude sites (UK at 52°N) average ~13°. This counter-intuitive result occurs because the sun rises at a steeper angle at low latitudes, compressing the twilight interval.

  2. Season matters. At fixed latitude, Fajr angle is lower in summer than winter. Birmingham's 10-year dataset shows a clear sinusoidal seasonal pattern with a ~3° peak-to-trough range.

  3. Elevation has a smaller but real effect. High-altitude desert sites (Hail 1020m, Tehran 1191m, Kottamia 477m) consistently trend toward the high end of the angle distribution.

Data sources

See data/raw/sources.md for the full source table.

Primary sources:

  • OpenFajr Project — Birmingham, UK, community astrophotography
  • NRIAG Egypt (Hassan et al. 2014, 2016; Rashed et al. 2022, 2025)
  • Khalifa 2018, NRIAG J. — Hail, Saudi Arabia
  • Kassim Bahali et al. 2018, Sains Malaysia — Malaysia/Indonesia DSLR study
  • Saksono 2020, NRIAG J. — Depok, Indonesia (SQM)
  • Asim Yusuf 2017 — Exmoor UK (multi-observer)
  • Hizbul Ulama UK 1987-1989 — Blackburn, Lancashire
  • Moonsighting.com / Khalid Shaukat — global network (Chicago, Buffalo, Toronto, Karachi, Cape Town, Auckland, Trinidad)
  • OIF UMSU 2017-2020 — Medan, North Sumatra
  • Various national religious body timetables (Turkey, Morocco, Jordan, Iran, UAE, Oman)
  • pray-calc — Islamic prayer times calculator; this project feeds its DPC algorithm
  • nrel-spa — NREL Solar Position Algorithm used inside pray-calc
  • moon-sighting — Lunar crescent visibility

License

MIT. Copyright (c) 2026 Aric Camarata.