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.npmignore
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.npmignore
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src/
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test.js
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README.md
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README.md
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# solar-spa
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The solar-spa package provides a Node.js module for calculating solar position and related parameters using the National Renewable Energy Laboratory (NREL) Solar Position Algorithm (SPA). This implementation uses WebAssembly (WASM) to achieve high performance and accuracy.
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The SPA calculates the solar zenith angle, azimuth angle, incidence angle, sunrise time, sunset time, solar noon time, and sun transit altitude for a given date, time, and location.
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## Installation
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To install the solar-spa package, use the following command:
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```sh
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npm install solar-spa
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```
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## Usage
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```
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const spa = require('solar-spa');
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// Define input parameters for a specific date, time, and location
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const date = new Date(2023, 3, 1, 0, 0, 0); // April 1, 2023 at Midnight
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const latitude = 40.7128; // Latitude of New York City, USA
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const longitude = -74.0060; // Longitude of New York City, USA
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// Optional input parameters (default values provided if not specified)
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const elevation = 10; // Elevation in meters (approximately)
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const temperature = 20; // Temperature (degrees Celsius)
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const pressure = 1013.25; // Atmospheric pressure (millibars)
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const refraction = 0.5667; // Atmospheric refraction (degrees)
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// Call the 'spa' function and log the results
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spa(date, latitude, longitude, elevation, temperature, pressure, refraction)
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.then(result => {
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console.log(result);
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})
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.catch(error => {
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console.error(error);
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});
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```
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## Example Output
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```
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{
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zenith: 132.82035808538367,
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azimuth: 339.3841959764823,
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incidence: 132.82035808538367,
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sun_transit_alt: 53.91557045916343,
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sunrise: 6.665306569794356,
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solar_noon: 12.99818246332967,
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sunset: 19.342862135890314
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}
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```
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## Helper (function not included)
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If you would like to translate the sunrise, solar_noon, or sunset to a normal time output you can convert fractional hours to formatted time string like below:
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```
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function formatTime(hours) {
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const milliseconds = hours * 60 * 60 * 1000;
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const date = new Date(milliseconds);
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return date.toISOString().substr(11, 12);
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}
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```
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# Repository
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The source code for this package is available on GitHub: github.com/acamarata/solar-spa
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# License
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MIT
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package.json
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package.json
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{
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"name": "solar-spa",
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"version": "1.0.0",
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"description": "NREL Solar Position Algorithm (SPA) in WebAssembly",
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"main": "solar-spa.js",
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"scripts": {
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"test": "node test.js"
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},
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"author": "Ali Camarata",
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"license": "MIT"
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}
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solar-spa.js
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solar-spa.js
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const spaModule = require('./spa.js');
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module.exports = function spa(
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date,
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latitude,
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longitude,
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elevation = 0,
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temperature = 20,
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pressure = 1013.25,
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refraction = 0.5667
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) {
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return new Promise((resolve) => {
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spaModule.onRuntimeInitialized = function () {
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const spa_calculate = spaModule.cwrap(
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'spa_calculate_wrapper',
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'number',
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[
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'number', 'number', 'number', 'number', 'number',
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'number', 'number', 'number', 'number', 'number',
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'number', 'number', 'number', 'number', 'number'
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]
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);
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const spa_free_result = spaModule.cwrap(
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'spa_free_result',
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null,
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['number']
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);
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const year = date.getFullYear();
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const month = date.getMonth() + 1;
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const day = date.getDate();
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const hour = date.getHours();
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const minute = date.getMinutes();
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const second = date.getSeconds();
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const timezone = -date.getTimezoneOffset() / 60;
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const slope = 0;
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const azm_rotation = 0;
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const resultPtr = spa_calculate(
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year, month, day, hour, minute, second, timezone,
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latitude, longitude, elevation, pressure, temperature,
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slope, azm_rotation, refraction
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);
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const result = {
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zenith: spaModule.getValue(resultPtr, 'double'),
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azimuth: spaModule.getValue(resultPtr + 8, 'double'),
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incidence: spaModule.getValue(resultPtr + 16, 'double'),
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sunrise: spaModule.getValue(resultPtr + 24, 'double'),
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sunset: spaModule.getValue(resultPtr + 32, 'double'),
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solar_noon: spaModule.getValue(resultPtr + 40, 'double'),
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sun_transit_alt: spaModule.getValue(resultPtr + 48, 'double'),
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};
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spa_free_result(resultPtr);
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resolve(result);
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};
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});
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};
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BIN
spa.wasm
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BIN
spa.wasm
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src/spa.h
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src/spa.h
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/////////////////////////////////////////////
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// HEADER FILE for SPA.C //
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// //
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// Solar Position Algorithm (SPA) //
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// for //
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// Solar Radiation Application //
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// //
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// May 12, 2003 //
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// //
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// Filename: SPA.H //
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// //
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// Afshin Michael Andreas //
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// afshin_andreas@nrel.gov (303)384-6383 //
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// //
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// Measurement & Instrumentation Team //
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// Solar Radiation Research Laboratory //
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// National Renewable Energy Laboratory //
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// 1617 Cole Blvd, Golden, CO 80401 //
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/////////////////////////////////////////////
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////////////////////////////////////////////////////////////////////////
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// //
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// Usage: //
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// //
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// 1) In calling program, include this header file, //
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// by adding this line to the top of file: //
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// #include "spa.h" //
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// //
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// 2) In calling program, declare the SPA structure: //
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// spa_data spa; //
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// //
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// 3) Enter the required input values into SPA structure //
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// (input values listed in comments below) //
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// //
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// 4) Call the SPA calculate function and pass the SPA structure //
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// (prototype is declared at the end of this header file): //
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// spa_calculate(&spa); //
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// //
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// Selected output values (listed in comments below) will be //
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// computed and returned in the passed SPA structure. Output //
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// will based on function code selected from enumeration below. //
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// //
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// Note: A non-zero return code from spa_calculate() indicates that //
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// one of the input values did not pass simple bounds tests. //
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// The valid input ranges and return error codes are also //
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// listed below. //
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// //
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////////////////////////////////////////////////////////////////////////
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#ifndef __solar_position_algorithm_header
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#define __solar_position_algorithm_header
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//enumeration for function codes to select desired final outputs from SPA
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enum {
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SPA_ZA, //calculate zenith and azimuth
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SPA_ZA_INC, //calculate zenith, azimuth, and incidence
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SPA_ZA_RTS, //calculate zenith, azimuth, and sun rise/transit/set values
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SPA_ALL, //calculate all SPA output values
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};
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typedef struct
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{
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//----------------------INPUT VALUES------------------------
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int year; // 4-digit year, valid range: -2000 to 6000, error code: 1
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int month; // 2-digit month, valid range: 1 to 12, error code: 2
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int day; // 2-digit day, valid range: 1 to 31, error code: 3
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int hour; // Observer local hour, valid range: 0 to 24, error code: 4
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int minute; // Observer local minute, valid range: 0 to 59, error code: 5
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double second; // Observer local second, valid range: 0 to <60, error code: 6
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double delta_ut1; // Fractional second difference between UTC and UT which is used
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// to adjust UTC for earth's irregular rotation rate and is derived
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// from observation only and is reported in this bulletin:
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// http://maia.usno.navy.mil/ser7/ser7.dat,
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// where delta_ut1 = DUT1
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// valid range: -1 to 1 second (exclusive), error code 17
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double delta_t; // Difference between earth rotation time and terrestrial time
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// It is derived from observation only and is reported in this
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// bulletin: http://maia.usno.navy.mil/ser7/ser7.dat,
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// where delta_t = 32.184 + (TAI-UTC) - DUT1
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// valid range: -8000 to 8000 seconds, error code: 7
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double timezone; // Observer time zone (negative west of Greenwich)
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// valid range: -18 to 18 hours, error code: 8
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double longitude; // Observer longitude (negative west of Greenwich)
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// valid range: -180 to 180 degrees, error code: 9
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double latitude; // Observer latitude (negative south of equator)
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// valid range: -90 to 90 degrees, error code: 10
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double elevation; // Observer elevation [meters]
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// valid range: -6500000 or higher meters, error code: 11
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double pressure; // Annual average local pressure [millibars]
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// valid range: 0 to 5000 millibars, error code: 12
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double temperature; // Annual average local temperature [degrees Celsius]
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// valid range: -273 to 6000 degrees Celsius, error code; 13
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double slope; // Surface slope (measured from the horizontal plane)
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// valid range: -360 to 360 degrees, error code: 14
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double azm_rotation; // Surface azimuth rotation (measured from south to projection of
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// surface normal on horizontal plane, negative east)
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// valid range: -360 to 360 degrees, error code: 15
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double atmos_refract;// Atmospheric refraction at sunrise and sunset (0.5667 deg is typical)
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// valid range: -5 to 5 degrees, error code: 16
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int function; // Switch to choose functions for desired output (from enumeration)
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//-----------------Intermediate OUTPUT VALUES--------------------
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double jd; //Julian day
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double jc; //Julian century
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double jde; //Julian ephemeris day
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double jce; //Julian ephemeris century
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double jme; //Julian ephemeris millennium
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double l; //earth heliocentric longitude [degrees]
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double b; //earth heliocentric latitude [degrees]
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double r; //earth radius vector [Astronomical Units, AU]
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double theta; //geocentric longitude [degrees]
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double beta; //geocentric latitude [degrees]
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double x0; //mean elongation (moon-sun) [degrees]
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double x1; //mean anomaly (sun) [degrees]
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double x2; //mean anomaly (moon) [degrees]
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double x3; //argument latitude (moon) [degrees]
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double x4; //ascending longitude (moon) [degrees]
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double del_psi; //nutation longitude [degrees]
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double del_epsilon; //nutation obliquity [degrees]
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double epsilon0; //ecliptic mean obliquity [arc seconds]
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double epsilon; //ecliptic true obliquity [degrees]
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double del_tau; //aberration correction [degrees]
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double lamda; //apparent sun longitude [degrees]
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double nu0; //Greenwich mean sidereal time [degrees]
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double nu; //Greenwich sidereal time [degrees]
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double alpha; //geocentric sun right ascension [degrees]
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double delta; //geocentric sun declination [degrees]
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|
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double h; //observer hour angle [degrees]
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double xi; //sun equatorial horizontal parallax [degrees]
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double del_alpha; //sun right ascension parallax [degrees]
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|
double delta_prime; //topocentric sun declination [degrees]
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double alpha_prime; //topocentric sun right ascension [degrees]
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double h_prime; //topocentric local hour angle [degrees]
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|
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double e0; //topocentric elevation angle (uncorrected) [degrees]
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double del_e; //atmospheric refraction correction [degrees]
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double e; //topocentric elevation angle (corrected) [degrees]
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|
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double eot; //equation of time [minutes]
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double srha; //sunrise hour angle [degrees]
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double ssha; //sunset hour angle [degrees]
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double sta; //sun transit altitude [degrees]
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|
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//---------------------Final OUTPUT VALUES------------------------
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|
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||||||
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double zenith; //topocentric zenith angle [degrees]
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double azimuth_astro;//topocentric azimuth angle (westward from south) [for astronomers]
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double azimuth; //topocentric azimuth angle (eastward from north) [for navigators and solar radiation]
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double incidence; //surface incidence angle [degrees]
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double suntransit; //local sun transit time (or solar noon) [fractional hour]
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double sunrise; //local sunrise time (+/- 30 seconds) [fractional hour]
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double sunset; //local sunset time (+/- 30 seconds) [fractional hour]
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} spa_data;
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//-------------- Utility functions for other applications (such as NREL's SAMPA) --------------
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double deg2rad(double degrees);
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double rad2deg(double radians);
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double limit_degrees(double degrees);
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double third_order_polynomial(double a, double b, double c, double d, double x);
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double geocentric_right_ascension(double lamda, double epsilon, double beta);
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double geocentric_declination(double beta, double epsilon, double lamda);
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double observer_hour_angle(double nu, double longitude, double alpha_deg);
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|
void right_ascension_parallax_and_topocentric_dec(double latitude, double elevation,
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double xi, double h, double delta, double *delta_alpha, double *delta_prime);
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double topocentric_right_ascension(double alpha_deg, double delta_alpha);
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double topocentric_local_hour_angle(double h, double delta_alpha);
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double topocentric_elevation_angle(double latitude, double delta_prime, double h_prime);
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double atmospheric_refraction_correction(double pressure, double temperature,
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double atmos_refract, double e0);
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double topocentric_elevation_angle_corrected(double e0, double delta_e);
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||||||
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double topocentric_zenith_angle(double e);
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double topocentric_azimuth_angle_astro(double h_prime, double latitude, double delta_prime);
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||||||
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double topocentric_azimuth_angle(double azimuth_astro);
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|
|
||||||
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||||||
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//Calculate SPA output values (in structure) based on input values passed in structure
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int spa_calculate(spa_data *spa);
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||||||
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#endif
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77
src/spa_wrapper.c
Normal file
77
src/spa_wrapper.c
Normal file
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|
@ -0,0 +1,77 @@
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// src/spa_wrapper.c
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#include "spa.h"
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||||||
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#include <stdlib.h> // For malloc and free
|
||||||
|
|
||||||
|
typedef struct {
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||||||
|
double zenith;
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||||||
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double azimuth;
|
||||||
|
double incidence;
|
||||||
|
double sunrise;
|
||||||
|
double sunset;
|
||||||
|
double solar_noon;
|
||||||
|
double sun_transit_alt;
|
||||||
|
} spa_result;
|
||||||
|
|
||||||
|
spa_result* spa_calculate_wrapper(
|
||||||
|
int year, int month, int day,
|
||||||
|
int hour, int minute, double second,
|
||||||
|
double timezone,
|
||||||
|
double latitude, double longitude, double elevation,
|
||||||
|
double pressure, double temperature,
|
||||||
|
double slope, double azm_rotation, double atmos_refract)
|
||||||
|
{
|
||||||
|
// Allocate memory for the result
|
||||||
|
spa_result* result = (spa_result*)malloc(sizeof(spa_result));
|
||||||
|
if (!result) return NULL;
|
||||||
|
|
||||||
|
spa_data spa;
|
||||||
|
spa.year = year;
|
||||||
|
spa.month = month;
|
||||||
|
spa.day = day;
|
||||||
|
spa.hour = hour;
|
||||||
|
spa.minute = minute;
|
||||||
|
spa.second = second;
|
||||||
|
spa.timezone = timezone;
|
||||||
|
spa.latitude = latitude;
|
||||||
|
spa.longitude = longitude;
|
||||||
|
spa.elevation = elevation;
|
||||||
|
|
||||||
|
// Set default values for optional inputs if they are not given
|
||||||
|
spa.pressure = (pressure == 0.0) ? 820.0 : pressure; // Standard atmospheric pressure
|
||||||
|
spa.temperature = (temperature == 0.0) ? 11.0 : temperature; // Standard temperature
|
||||||
|
spa.slope = slope; // Surface slope angle (default 0.0)
|
||||||
|
spa.azm_rotation = azm_rotation; // Surface azimuth angle (default 0.0)
|
||||||
|
spa.atmos_refract = (atmos_refract == 0.0) ? 0.5667 : atmos_refract;
|
||||||
|
|
||||||
|
// Set the calculation mode to SPA_ALL
|
||||||
|
spa.function = SPA_ALL;
|
||||||
|
|
||||||
|
// Calculate SPA values
|
||||||
|
int result_code = spa_calculate(&spa);
|
||||||
|
|
||||||
|
if (result_code == 0) {
|
||||||
|
result->zenith = spa.zenith;
|
||||||
|
result->azimuth = spa.azimuth;
|
||||||
|
result->incidence = spa.incidence;
|
||||||
|
result->sunrise = spa.sunrise;
|
||||||
|
result->sunset = spa.sunset;
|
||||||
|
result->solar_noon = spa.suntransit;
|
||||||
|
result->sun_transit_alt = spa.sta;
|
||||||
|
} else {
|
||||||
|
// Error handling (fill with zeros or other default values)
|
||||||
|
result->zenith = 0;
|
||||||
|
result->azimuth = 0;
|
||||||
|
result->incidence = 0;
|
||||||
|
result->sunrise = 0;
|
||||||
|
result->sunset = 0;
|
||||||
|
result->solar_noon = 0;
|
||||||
|
result->sun_transit_alt = 0;
|
||||||
|
}
|
||||||
|
|
||||||
|
return result;
|
||||||
|
}
|
||||||
|
|
||||||
|
// Function to free the allocated result memory
|
||||||
|
void spa_free_result(spa_result* result) {
|
||||||
|
free(result);
|
||||||
|
}
|
||||||
36
test.js
Normal file
36
test.js
Normal file
|
|
@ -0,0 +1,36 @@
|
||||||
|
// test.js
|
||||||
|
// Import the 'solar-spa' module
|
||||||
|
const spa = require('./solar-spa.js');
|
||||||
|
|
||||||
|
// Define input parameters for a specific date, time, and location
|
||||||
|
const date = new Date(2023, 3, 1, 0, 0, 0); // April 1, 2023 at Midnight
|
||||||
|
const latitude = 40.7128; // Latitude of New York City, USA
|
||||||
|
const longitude = -74.0060; // Longitude of New York City, USA
|
||||||
|
const elevation = 10; // Elevation in meters (approximately)
|
||||||
|
const pressure = 1013.25; // Optional input: Atmospheric pressure (millibars)
|
||||||
|
const temperature = 20; // Optional input: Temperature (degrees Celsius)
|
||||||
|
const refraction = 0.5667; // Optional input: Atmospheric refraction (degrees)
|
||||||
|
|
||||||
|
// Convert fractional hours to formatted time string for sunrise, sunset, solar_noon
|
||||||
|
function formatTime(hours) {
|
||||||
|
const milliseconds = hours * 60 * 60 * 1000;
|
||||||
|
const date = new Date(milliseconds);
|
||||||
|
return date.toISOString().substr(11, 12);
|
||||||
|
}
|
||||||
|
|
||||||
|
// Call the 'spa' function and log the results
|
||||||
|
spa(date, latitude, longitude, elevation, temperature, pressure, refraction)
|
||||||
|
.then(result => {
|
||||||
|
console.log({
|
||||||
|
zenith: result.zenith,
|
||||||
|
azimuth: result.azimuth,
|
||||||
|
incidence: result.incidence,
|
||||||
|
sun_transit_alt: result.sun_transit_alt,
|
||||||
|
sunrise: result.sunrise,
|
||||||
|
solar_noon: result.solar_noon,
|
||||||
|
sunset: result.sunset
|
||||||
|
});
|
||||||
|
})
|
||||||
|
.catch(error => {
|
||||||
|
console.error(error);
|
||||||
|
});
|
||||||
Loading…
Reference in a new issue