MCP Stargazing

A tool for calculating the altitude, azimuth, rise, and set times of celestial bodies (sun, moon, planets, stars, and deep - sky objects) at any location on Earth, supporting light - pollution analysis.

Education and learning tools Research and data #Astronomical observation #Light pollution #Celestial position #Time calculation .Python

rating : 2 points

downloads : 7

update time : 2025-04-29

What is MCP Stargazing?

MCP Stargazing is an astronomical observation auxiliary tool that can calculate the altitude, azimuth, and rise/set times of the sun, moon, planets, stars, and deep - sky objects. It is especially suitable for astronomy enthusiasts and professional observers to plan observation activities.

How to use MCP Stargazing?

Just provide your location and observation time, and the tool can calculate the precise positions of celestial bodies. You can also load a light - pollution map to evaluate the observation conditions.

Use cases

Suitable for scenarios such as astronomical observation planning, photography timing selection, educational demonstrations, and light - pollution research.

Main features

Celestial position calculationCalculate the altitude and azimuth of any celestial body to help you accurately locate the position of the celestial body in the sky

Rise/set timesPredict when a celestial body will appear above or disappear below the horizon

Light - pollution analysisLoad a light - pollution map (in GeoTIFF format) to evaluate the sky quality at the observation location

Support for multiple celestial bodiesSupports solar system objects, stars, and deep - sky objects (such as the Andromeda Galaxy, Orion Nebula, etc.)

Advantages and limitations

Advantages

Accurate celestial position calculation based on authoritative astronomical libraries

Supports calculations for any location worldwide

Time - zone awareness function that automatically handles local time conversion

Open - source and easy to expand

Limitations

Requires an internet connection to obtain certain celestial data

Users need to provide their own light - pollution maps

Calculations for celestial bodies at extremely low angles (<0.5°) may not be accurate enough

How to use

Install dependencies

First, you need to install the necessary Python libraries

Set the observation location

Create an EarthLocation object to specify your latitude and longitude

Calculate the celestial position

Specify the celestial body and time to obtain the altitude and azimuth

Get the rise/set times (optional)

Calculate the rise and set times of a celestial body within a specific date

Analyze light pollution (optional)

Load a light - pollution map to evaluate the observation conditions

Usage examples

Plan sunrise photographyA photographer wants to determine the best time and direction for sunrise photography at a certain place

Astronomical observation planningAn astronomy enthusiast wants to find the best time to observe the Andromeda Galaxy

Light - pollution assessmentEvaluate the light - pollution level at an observation location

Frequently Asked Questions

Which celestial bodies are supported?

Is an internet connection required?

What is the accuracy?

Where can I get the light - pollution map?

Related resources

Astropy documentation

The core astronomical library used in this project

Light - pollution map data

Free light - pollution map resources

GitHub repository

Project source code and issue tracking

🚀 MCP - Stargazing

Calculate the altitude angle, rising time, and setting time of celestial bodies (the sun, moon, planets, stars, and deep - space objects) at any location on Earth, and support optional light pollution analysis.

🚀 Quick Start

MCP - Stargazing is a powerful tool that enables users to calculate various celestial parameters and conduct light pollution analysis. It supports multiple celestial body types and is timezone - aware, providing flexibility for users around the world.

✨ Features

Altitude/Azimuth Calculation: Obtain the elevation and direction of celestial bodies.
Rise/Set Time Calculation: Determine the time when a celestial body appears above the horizon and disappears.
Light Pollution Analysis: Load and analyze light pollution maps (in GeoTIFF format).
Supported Celestial Body Types:
- Solar system objects (the sun, moon, planets)
- Stars (e.g., "sirius")
- Deep - space objects (e.g., "andromeda", "orion_nebula")
Timezone - Aware: Support local time or UTC time.

📦 Installation

pip install astropy pytz numpy astroquery rasterio geopy

💻 Usage Examples

Basic Usage

Calculate Altitude/Azimuth

from src.celestial import celestial_pos
from astropy.coordinates import EarthLocation
import pytz
from datetime import datetime

# Observer location (New York)
location = EarthLocation(lat=40.7128, lon=-74.0060)

# Time (local time with timezone)
local_time = pytz.timezone("America/New_York").localize(datetime(2023, 10, 1, 12, 0))
altitude, azimuth = celestial_pos("sun", location, local_time)
print(f"Sun position: Altitude={altitude:.1f}°, Azimuth={azimuth:.1f}°")

Calculate Rise/Set Time

from src.celestial import celestial_rise_set

rise, set_ = celestial_rise_set("andromeda", location, local_time.date())
print(f"Andromeda: Rise time={rise.iso}, Set time={set_.iso}")

Load Light Pollution Map

from src.light_pollution import load_map

# Load a light pollution map in GeoTIFF format
vriis_data, bounds, crs, transform = load_map("path/to/map.tif")
print(f"Map bounds: {bounds}")

📚 Documentation

API Reference

`celestial_pos(celestial_object, observer_location, time)` (`src/celestial.py`)

Input Parameters:
- celestial_object: Name (e.g., "sun", "andromeda").
- observer_location: EarthLocation object.
- time: datetime (with timezone) or Astropy Time.
Return Value: (Altitude in degrees, Azimuth in degrees)

`celestial_rise_set()` (`src/celestial.py`)

Input Parameters:
- celestial_object: Name.
- observer_location: EarthLocation object.
- date: Date object.
Return Value: (Rise time, Set time)