, * the creator of these routines, Ka-Ping Yee, authorized these routines to be * distributed under the GPL. */ /** * @file * Trigonometry for calculating geographical distances. * All function arguments and return values measure distances in metres * and angles in degrees. The ellipsoid model is from the WGS-84 datum. * Ka-Ping Yee, 2003-08-11 */ //$earth_radius_semimajor = 6378137.0; //$earth_flattening = 1/298.257223563; //$earth_radius_semiminor = $earth_radius_semimajor * (1 - $earth_flattening); //$earth_eccentricity_sq = 2*$earth_flattening - pow($earth_flattening, 2); // I don't know what's up: PHP is hating on my global variables (commented out above), // so I have to write functions that return them! (-Ankur) // Commenting out the global variables above and replacing them with functions that // return the same values is the only thing I changed since, for some reason, my // PHP wasn't acknowledging these global variables. // This library is an original implementation of UCB CS graduate student, Ka-Ping Yee (http://www.zesty.ca). function earth_radius_semimajor() { return 6378137.0; } function earth_flattening() { return (1/298.257223563); } function earth_radius_semiminor() { return (earth_radius_semimajor() * (1 - earth_flattening())); } function earth_eccentricity_sq() { return (2*earth_flattening() - pow(earth_flattening(), 2)); } // Latitudes in all of U. S.: from -7.2 (American Samoa) to 70.5 (Alaska). // Latitudes in continental U. S.: from 24.6 (Florida) to 49.0 (Washington). // Average latitude of all U. S. zipcodes: 37.9. function earth_radius($latitude=37.9) { //global $earth_radius_semimajor, $earth_radius_semiminor; // Estimate the Earth's radius at a given latitude. // Default to an approximate average radius for the United States. $lat = deg2rad($latitude); $x = cos($lat)/earth_radius_semimajor(); $y = sin($lat)/earth_radius_semiminor(); return 1 / (sqrt($x*$x + $y*$y)); } function earth_xyz($longitude, $latitude, $height = 0) { // Convert longitude and latitude to earth-centered earth-fixed coordinates. // X axis is 0 long, 0 lat; Y axis is 90 deg E; Z axis is north pole. //global $earth_radius_semimajor, $earth_eccentricity_sq; $long = deg2rad($longitude); $lat = deg2rad($latitude); $coslong = cos($long); $coslat = cos($lat); $sinlong = sin($long); $sinlat = sin($lat); $radius = earth_radius_semimajor() / sqrt(1 - earth_eccentricity_sq() * $sinlat * $sinlat); $x = ($radius + $height) * $coslat * $coslong; $y = ($radius + $height) * $coslat * $sinlong; $z = ($radius * (1 - earth_eccentricity_sq()) + $height) * $sinlat; return array($x, $y, $z); } function earth_arclength($angle, $latitude=37.9) { // Convert a given angle to earth-surface distance. return deg2rad($angle) * earth_radius($latitude); } function earth_distance($longitude1, $latitude1, $longitude2, $latitude2) { // Estimate the earth-surface distance between two locations. $long1 = deg2rad($longitude1); $lat1 = deg2rad($latitude1); $long2 = deg2rad($longitude2); $lat2 = deg2rad($latitude2); $radius = earth_radius(($latitude1 + $latitude2) / 2); $cosangle = cos($lat1)*cos($lat2) * (cos($long1)*cos($long2) + sin($long1)*sin($long2)) + sin($lat1)*sin($lat2); return acos($cosangle) * $radius; } /* * Returns the SQL fragment needed to add a column called 'distance' * to a query that includes the location table * * @param $longitude The measurement point * @param $latibude The measurement point * @param $tbl_alias If necessary, the alias name of the location table to work from. Only required when working with named {location} tables */ function earth_distance_sql($longitude, $latitude, $tbl_alias = '') { // Make a SQL expression that estimates the distance to the given location. $long = deg2rad($longitude); $lat = deg2rad($latitude); $radius = earth_radius($latitude); // If the table alias is specified, add on the separator. $tbl_alias = empty($tbl_alias) ? $tbl_alias : ($tbl_alias .'.'); $coslong = cos($long); $coslat = cos($lat); $sinlong = sin($long); $sinlat = sin($lat); return "(IFNULL(ACOS($coslat*COS(RADIANS({$tbl_alias}latitude))*($coslong*COS(RADIANS({$tbl_alias}longitude)) + $sinlong*SIN(RADIANS({$tbl_alias}longitude))) + $sinlat*SIN(RADIANS({$tbl_alias}latitude))), 0.00000)*$radius)"; } function earth_longitude_range($longitude, $latitude, $distance) { // Estimate the min and max longitudes within $distance of a given location. $long = deg2rad($longitude); $lat = deg2rad($latitude); $radius = earth_radius($latitude); $angle = $distance / $radius; $diff = asin(sin($angle)/cos($lat)); $minlong = $long - $diff; $maxlong = $long + $diff; if ($minlong < -pi()) { $minlong = $minlong + pi()*2; } if ($maxlong > pi()) { $maxlong = $maxlong - pi()*2; } return array(rad2deg($minlong), rad2deg($maxlong)); } function earth_latitude_range($longitude, $latitude, $distance) { // Estimate the min and max latitudes within $distance of a given location. $long = deg2rad($longitude); $lat = deg2rad($latitude); $radius = earth_radius($latitude); $angle = $distance / $radius; $minlat = $lat - $angle; $maxlat = $lat + $angle; $rightangle = pi()/2; if ($minlat < -$rightangle) { // wrapped around the south pole $overshoot = -$minlat - $rightangle; $minlat = -$rightangle + $overshoot; if ($minlat > $maxlat) { $maxlat = $minlat; } $minlat = -$rightangle; } if ($maxlat > $rightangle) { // wrapped around the north pole $overshoot = $maxlat - $rightangle; $maxlat = $rightangle - $overshoot; if ($maxlat < $minlat) { $minlat = $maxlat; } $maxlat = $rightangle; } return array(rad2deg($minlat), rad2deg($maxlat)); }