function [out1,out2,savepts] = wagner4(mstruct,in1,in2,object,direction,savepts) %WAGNER4 Wagner IV Pseudocylindrical Projection % % This is an equal area projection. Scale is true along the 42 deg, % 59 min parallels, and is constant along any parallel and between % any pair of parallels equidistant from the Equator. Distortion is % not as extreme near the outer meridians at high latitudes as for % pointed-polar pseudocylindrical projections, but there is considerable % distortion throughout polar regions. It is free of distortion only % at the two points where the 42 deg, 59 min parallels intersect the % central meridian. This projection is not conformal or equidistant. % % This projection was presented by Karlheinz Wagner in 1932. % Copyright 1996-2003 The MathWorks, Inc. % $Revision: 1.9.4.1 $ % Written by: E. Byrns, E. Brown if nargin == 1 % Set the default structure entries mstruct.trimlat = angledim([ -90 90],'degrees',mstruct.angleunits); mstruct.trimlon = angledim([-180 180],'degrees',mstruct.angleunits); mstruct.mapparallels = angledim(4259,'dms',mstruct.angleunits); mstruct.nparallels = 0; mstruct.fixedorient = []; out1 = mstruct; return elseif nargin ~= 5 & nargin ~= 6 error('Incorrect number of arguments') end units = mstruct.angleunits; aspect = mstruct.aspect; radius = rsphere('authalic',mstruct.geoid); origin = angledim(mstruct.origin,units,'radians'); trimlat = angledim(mstruct.flatlimit,units,'radians'); trimlon = angledim(mstruct.flonlimit,units,'radians'); scalefactor = mstruct.scalefactor; falseeasting = mstruct.falseeasting; falsenorthing = mstruct.falsenorthing; % Adjust the origin latitude to the auxiliary sphere origin(1) = geod2aut(origin(1),mstruct.geoid,'radians'); trimlat = geod2aut(trimlat ,mstruct.geoid,'radians'); switch direction case 'forward' lat = angledim(in1,units,'radians'); lat = geod2aut(lat,mstruct.geoid,'radians'); long = angledim(in2,units,'radians'); [lat,long] = rotatem(lat,long,origin,direction); % Rotate to new origin [lat,long,clipped] = clipdata(lat,long,object); % Clip at the date line [lat,long,trimmed] = trimdata(lat,trimlat,long,trimlon,object); % Construct the structure of altered points savepts.trimmed = trimmed; savepts.clipped = clipped; % Projection transformation convergence = epsm('radians'); maxsteps = 100; steps = 1; thetanew = lat; converged = 0; const = (4*pi + 3*sqrt(3))/6; while ~converged & steps <= maxsteps steps = steps + 1; thetaold = thetanew; deltheta = -(thetaold + sin(thetaold) - const*sin(lat)) ./ ... (1 + cos(thetaold)); if max(abs(deltheta(:))) <= convergence; converged = 1; else; thetanew = thetaold + deltheta; end end thetanew = thetanew / 2; x = 0.86310 * radius * long .* cos(thetanew); y = 1.56548 * radius * sin(thetanew); % Apply scale factor, false easting, northing x = x*scalefactor+falseeasting; y = y*scalefactor+falsenorthing; % Set the output variables switch aspect case 'normal', out1 = x; out2 = y; case 'transverse', out1 = y; out2 = -x; otherwise, error('Unrecognized aspect string') end case 'inverse' switch aspect case 'normal', x = in1; y = in2; case 'transverse', x = -in2; y = in1; otherwise, error('Unrecognized aspect string') end % Apply scale factor, false easting, northing x = (x-falseeasting)/scalefactor; y = (y-falsenorthing)/scalefactor; % Inverse projection theta = asin(y ./ (1.56548*radius)); const = (4*pi + 3*sqrt(3))/6; lat = asin((2*theta +sin(2*theta))/const); long = x ./(0.86310*radius*cos(theta)); % Undo trims and clips [lat,long] = undotrim(lat,long,savepts.trimmed,object); [lat,long] = undoclip(lat,long,savepts.clipped,object); % Rotate to Greenwich and transform to desired units [lat,long] = rotatem(lat,long,origin,direction); lat = aut2geod(lat,mstruct.geoid,'radians'); out1 = angledim(lat, 'radians', units); out2 = angledim(long,'radians', units); otherwise error('Unrecognized direction string') end % Some operations on NaNs produce NaN + NaNi. However operations % outside the map may product complex results and we don't want % to destroy this indicator. indx = find(isnan(out1) | isnan(out2)); out1(indx) = NaN; out2(indx) = NaN;