/*******************************************************************************
NAME                            LAMBERT CONFORMAL CONIC

PURPOSE:	Transforms input longitude and latitude to Easting and
		Northing for the Lambert Conformal Conic projection.  The
		longitude and latitude must be in radians.  The Easting
		and Northing values will be returned in meters.

PROGRAMMER	DATE	REASON
----------	----	------
T. Mittan	2-26-93
S. Nelson	1-98	Corrected misspelling in error message

ALGORITHM REFERENCES

1.  Snyder, John P., "Map Projections--A Working Manual", U.S. Geological
    Survey Professional Paper 1395 (Supersedes USGS Bulletin 1532), United
    State Government Printing Office, Washington D.C., 1987.

2.  Snyder, John P. and Voxland, Philip M., "An Album of Map Projections",
    U.S. Geological Survey Professional Paper 1453 , United State Government
*******************************************************************************/
#include "cproj.h"

/* Variables common to all subroutines in this code file
  -----------------------------------------------------*/
  static double r_major;                /* major axis                   */
  static double r_minor;                /* minor axis                   */
  static double es;                     /* eccentricity squared         */
  static double e;                      /* eccentricity                 */
  static double center_lon;             /* center longituted            */
  static double center_lat;             /* cetner latitude              */
  static double ns;                     /* ratio of angle between meridian*/
  static double f0;                     /* flattening of ellipsoid      */
  static double rh;                     /* height above ellipsoid       */
  static double false_easting;          /* x offset in meters           */
  static double false_northing;         /* y offset in meters           */

/* Initialize the Lambert Conformal conic projection
  ------------------------------------------------*/
long lamccforint(r_maj,r_min,lat1,lat2,c_lon,c_lat,false_east,false_north)

double r_maj;                   /* major axis                           */
double r_min;                   /* minor axis                           */
double lat1;                    /* first standard parallel              */
double lat2;                    /* second standard parallel             */
double c_lon;                   /* center longitude                     */
double c_lat;                   /* center latitude                      */
double false_east;              /* x offset in meters                   */
double false_north;             /* y offset in meters                   */
{
double sin_po;                  /* sin value                            */
double cos_po;                  /* cos value                            */
double con;                     /* temporary variable                   */
double ms1;                     /* small m 1                            */
double ms2;                     /* small m 2                            */
double temp;                    /* temporary variable                   */
double ts0;                     /* small t 0                            */
double ts1;                     /* small t 1                            */
double ts2;                     /* small t 2                            */
r_major = r_maj;
r_minor = r_min;
false_northing = false_north;
false_easting = false_east;

/* Standard Parallels cannot be equal and on opposite sides of the equator
------------------------------------------------------------------------*/
if (fabs(lat1+lat2) < EPSLN)
   {
   p_error("Equal latitudes for St. Parallels on opposite sides of equator",
	   "lamcc-for");
   return(41);
   }
   
temp = r_minor / r_major;
es = 1.0 - SQUARE(temp);
e = sqrt(es);

center_lon = c_lon;
center_lat = c_lat;
sincos(lat1,&sin_po,&cos_po);
con = sin_po;
ms1 = msfnz(e,sin_po,cos_po);
ts1 = tsfnz(e,lat1,sin_po);
sincos(lat2,&sin_po,&cos_po);
ms2 = msfnz(e,sin_po,cos_po);
ts2 = tsfnz(e,lat2,sin_po);
sin_po = sin(center_lat);
ts0 = tsfnz(e,center_lat,sin_po);

if (fabs(lat1 - lat2) > EPSLN)
    ns = log (ms1/ms2)/ log (ts1/ts2);
else
    ns = con;
f0 = ms1 / (ns * pow(ts1,ns));
rh = r_major * f0 * pow(ts0,ns);


/* Report parameters to the user
  -----------------------------*/
ptitle("LAMBERT CONFORMAL CONIC");
radius2(r_major, r_minor);
stanparl(lat1,lat2);
cenlonmer(center_lon);
origin(c_lat);
offsetp(false_easting,false_northing);

return(OK);
}
/* Lambert Conformal conic forward equations--mapping lat,long to x,y
  -----------------------------------------------------------------*/
long lamccfor(lon, lat, x, y)
double lon;                     /* (I) Longitude                */
double lat;                     /* (I) Latitude                 */
double *x;                      /* (O) X projection coordinate  */
double *y;                      /* (O) Y projection coordinate  */

{
double con;                     /* temporary angle variable             */
double rh1;                     /* height above ellipsoid               */
double sinphi;                  /* sin value                            */
double theta;                   /* angle                                */
double ts;                      /* small value t                        */

con  = fabs( fabs(lat) - HALF_PI);
if (con > EPSLN)
  {
  sinphi = sin(lat);
  ts = tsfnz(e,lat,sinphi);
  rh1 = r_major * f0 * pow(ts,ns);
  }
else
  {
  con = lat * ns;
  if (con <= 0)
    {
    p_error("Point can not be projected","lamcc-for");
    return(44);
    }
  rh1 = 0;
  }
theta = ns * adjust_lon(lon - center_lon);
*x = rh1 * sin(theta) + false_easting;
*y = rh - rh1 * cos(theta) + false_northing;

return(OK);
}