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I am trying to find a way to create an overlay for Google Maps API V3 that shows the sunlit areas of the world. This is the basic result I am looking for:

http://www.daylightmap.com/index.php

But want more control over the appearance (ideally just a 10% black overlay with no city lights). I can draw the shape in a canvas element but can not figure out how to calculate the shape based on earth's tilt and rotation etc.

Any help would be appreciated.

EDIT: Javascript

I still don't know where to implement the y-offset variable below. I also need to figure out how to adjust/stretch the y-offset from this (equal distant latitudinal lines) to mercator (closer at poles).

// Get the canvas element
var ctx = document.getElementById('canvas').getContext('2d');
ctx.clearRect( 0, 0, 800, 620 );

// Current time
var map_width = $("#canvas").width();
var map_height = $("#canvas").height();
var now = new Date();
var cur_hour = now.getHours();
var cur_min = now.getMinutes();
var cur_sec = now.getSeconds();
var cur_jul = now.julianDate() - 1;
var equinox_jul = new Date(now.getFullYear(),2,20,24,-now.getTimezoneOffset(),0,0).julianDate() - 1;

var offset_x = Math.round(((cur_hour*3600 + cur_min*60 + cur_sec)/86400) * map_width); // Resulting offset X
var offset_sin = ((365.25 - equinox_jul + cur_jul)%365.25)/365.25; // Day offset, mapped on the equinox offset
var offset_sin_factor = Math.sin(offset_sin * 2 * Math.PI); // Sine wave offset
var offset_y = offset_sin_factor * 23.44; // Map onto angle. Maximum angle is 23.44° in both directions

var degrees_per_radian = 180.0 / Math.PI;
var offset_y_mercator = Math.atan( offset_y.sinh() ) * degrees_per_radian;


// Global wave variables
var period = 1 / 6.28291;   // Original value 2Pi: 6.28291
var amplitude = (map_height/2);

// Draw vertical lines: One for each horizontal pixel on the map
for( var x = 0; x <= map_width; x++ ) {
    ctx.beginPath();

    // Start at the bottom of the map
    ctx.moveTo(x,map_height);

    // Get the y value for the x pixel on the sine wave
    var y = (map_height/2) - (Math.sin( (offset_x / map_width) / period ) * amplitude);

    offset_x++;

    // Draw the line up to the point on the sine wave
    ctx.lineTo(x,y);
    ctx.stroke();
}
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2 Answers 2

up vote 6 down vote accepted
+25

If you want it to be physically accurate, you actually need to consider two offsets: a vertical (depending on the current date) and a horizontal (depending on the current time).

The horizontal offset X may be calculated by looking at the current time on some fixed geographic location on earth. The shadow offset will be 0 at midnight and will increase by 1/86400 for each seconds after midnight. So the formular is

offsetX = (curHour*3600 + curMinute*60 + curSeconds)/86400

The vertical offset will change between the Solstices on June 21st and Dec 22nd (if it's not a leap year, where the Solstices are on June 20th and Dec 21st). The maximum angles are 23.44° in both directions. We have 90° per hemisphere and 365/2 = 182.5 days between the two solstices, and we are working with a mapping of a circular motion, so a sin()-function has to be used. The wavelength of a sinus wave is 2pi, so we need pi for half the vertical offset Y of one year.

Please note, that I did not take leap seconds into account, so the calculation might be a bit off in the distant past/future.

// current time
$curHour = date("H");
$curMin  = date("i");
$curSec  = date("s");

// resulting offset X
$offsetX = ($curHour*3600 + $curMin*60 + $curSec)/86400;


echo "======== OFFSET X ==========\n";
echo "curHour:      $curHour\n";
echo "curMin:       $curMin\n";
echo "curSec:       $curSec\n";
echo "offsetX:      $offsetX\n\n";


// spring equinox date as day of year
$equinox = date("z", mktime(0, 0, 0, 3, 20));

// current day of year
    // first line is for testing purposes
//$curDay = date("z", mktime(0, 0, 0, 6, 21));
    $curDay = date("z");

// Day offset, mapped on the equinox offset
$offsetSin = ((365.25 - $equinox + $curDay)%365.25)/365.25;

// sinus wave offset
$offsetSinFactor = sin($offsetSin * 2 * pi());

// map onto angle
$offsetY = $offsetSinFactor * 23.44;

// optional: Mercator projection
$degreesPerRadian = 180.0 / pi();
$offsetYmercator = atan(sinh($offsetY)) * $degreesPerRadian;

// missing: mapping onto canvas height (it's currently
// mapped on $offsetY = 90 as the total height of the
// canvas.


echo "========= OFFSET Y =========\n";
echo "equinox day:  $equinox\n";
echo "curDay:       $curDay\n";
echo "offsetSin:    $offsetSin\n";
echo "offsetSinFac: $offsetSinFactor\n";
echo "offsetY:      $offsetY\n";
echo "offsetYmerc:  $offsetYmercator\n";

You should be able to port this calculation to any language you want.

share|improve this answer
    
Thank you so much, that is exactly what I was looking for! I have implemented it here with javascript but am having some issues with how to adjust the x-offset. Also, I used an amplitude of half the map height... it that correct? Any further assistance you could provide based on the code in that link would be greatly appreciated. Also, I assumed your math is built for a mercator projection, right? –  RANGER Aug 27 '11 at 21:44
    
The x-offset is on the width of the map and should be a factor between 0 and 1 to multiply with your map width: $finalOffsetX = $offsetX * $mapWidth. I assumed a map with equi-distant angle lines for the Y-Offset. If you want it to work with the mercator projection, you'll have to add another factor to map the non-equi-distant angle lines in the y-axis and need to dynamically stretch your shadow canvas to get the correct result, as the shadow will change according to the projection angle and y-Offset. Question is: how physically correct do you want it to be? –  Lars Aug 29 '11 at 14:42
    
Great, I now understand and will implement the x-offset. I actually looked at my code again and I don't think I am using the y-offset correctly. Where in the sin formula do I plug that number in? See the edit of the initial question for my current code. I need this to be fairly accurate and yes, with the mercator projection (what google maps uses) the y angle line distances diminish towards the poles... any ideas as to how the formula could be changed to fit the projection? –  RANGER Aug 29 '11 at 17:01
    
It's a gudermannian function for getting the projection, but something is still wrong there I think. I'll see if I can check it tomorrow again. –  Lars Aug 29 '11 at 23:39
    
I have incorporated the gudermannian function as you described in your example... but still am unaware as to how to implement this number into my wave calculation. Let me know if you have a chance to look at the code I posted. Thanks again! –  RANGER Aug 30 '11 at 19:12

You asked for more control over appearance

Check out the Geocommons JS api, which may be more suited to your purpose than Google Maps.

If you're going for flexibility, GEOS would be preferable to drawing the shape for a specific projection. I know there are php bindings, but I haven't used them myself.

Helmer Aslaksen has a great writeup about heavenly mathematics that should help you create an alorithm to draw a sunlit-area polygon using geos. You can test your code against measured sunrise/sunset times for accuracy.

Edit 1

Must be Python and Google Maps, you say?

share|improve this answer
    
Thanks! I am stuck for this project with Google Maps, JS and Python unfortunately although your links look useful. I find it so hard to believe there is not a Google Maps overlay out there for this... seems so practical. –  RANGER Aug 29 '11 at 17:13

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