Find distance to the ocean/ Intersection of vectors

I am interested in the W, NW, SW distances to ocean for many points in the continental USA. For testing purposes, I'm looping through a 1/8th deg dem at 500 m (32x32 pixels) GMTED2010 and a vertical coastline. I looked around this site and consequently implemented the pdist2 function however I'm not getting what I expect. So my first question is if I'm conceptually wrong and second is my pdist2 implementation incorrect? I'm also open to other solutions.

I expect to see the same pattern for all 3 directions given the directional constraint. The western most column of pixels will have the same distance, the next column will be the same, etc so when I plot a 32x32 matrix of `dlong` usiing `imagesc` I get a gradient low to high, left to right.

``````%**************
%For those truly interested, you can download the DEM and get Z and R accordingly:
Z=[Z150 Z120];
R=R120;
Z=Z(:,6001:4800+7200); %crop Z from -100 to -125. use latlon2pix to confirm between sub-z and z
R.Lonlim=[-125, -100];
R.RasterSize=size(Z);
clear Z150 Z120 R150 R120

%******* HERE STARTS THE ALGORITHM
%coastline (ultimately will be from the coast library)
latlim=[0.25:.25:60];
lonlim=ones(length(latlim),1)*-110

%variables r and c are the row and column indices for the point I'm interested in. r and c are relative to a DEM for the entire western USA so a point in Colorado is something like 2370,4350.
rstart=2370;
cstart=4350;

for r=2370:2370+31
for c=4350:4350+31
%rows and cols are the vectors in the NW direction from point r,c.
%in the SW direction, rows=r+[1:min(r,c)-1]. cols is the same.
%W direction, rows=ones(r,1)*r; cols=c-[1:c-1];
rows= r-[1:min(r,c)-1];
cols= c-[1:min(r,c)-1];

%Use referencing object R for DEM Z of the western USA to convert rows and cols to lat and long.
[NWcoord(:,1) NWcoord(:,2)]=pix2latlon(R,rows,cols);

%use pdist2 to find the shortest distance between any two points in the two vectors
[D,i]=pdist2(lonlim,NWcoord(:,2),'euclidean','smallest',1);
[~, mi]=min(D);

sta.NWcoast=[latlim(i(mi)) lonlim(i(mi))];
dlong(r-rstart+1,c-cstart+1)=distance(lat,long,latlim(i(mi)),lonlim(i(mi))); %great arc distance on earth's surface. radians
end
end
``````
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Why do you need a DEM (Digital Elevation Model) to find the distance (air distance?) to the coast polygon? The DEM contains Height Data. For what do you need them? –  AlexWien Feb 20 '13 at 18:35
Good question. This routine is part of a series of variables I am deriving from the DEM. I need a suite of variables for each pixel in a subset of the DEM. Because it's part of the rest of the function, I was using the size of the DEM as a reference for the size of the NWcoord vector. This is partly because I won't know how long the NWcoord vector needs to be to ensure it crosses the coast vector and I know the DEM covers the full domain I'm interested in. –  Dominik Feb 20 '13 at 18:57

My suggestion:

Solve it whitout DEM.

1) You have given a location loc with latidude and longitude in decimal degrees WGS84.
2) You have given the coats line polygon in WGS84, to.

Now to find the East West Distance from loc to polygon:
You want to find the crossing of the latitude value of loc with the border poly (east of current position):

Start at the beginning of border poly point 0: Find the line where `border[i].lat<= loc.lat and border[i+1] > loc.lat AND border[i].longitude >= loc.longitude`. If you found the line, make a linear interpolation between (i, and i+1) to find the exact (lat/long) intersection.

Now you have the intersection to the ocean: Calculate the distance loc -> intersection with `haversine` formula.

(Once this works you can later decide if you want to speed up with a binary search)

Same you do for the other 3 direction, with exchange lat/long and greater/smaller

For NW and others: Run along the ocean border points and calculate the bearing from loc to border point(search for aviation formulas or greater circle bearing calculations)

store the line /or two points where bearing steps over the 315 degrees. This line then intersects the 315°, Theretically ther ecould be more than one such line store all such lines, and take the one whoch is closest to location (

Now interpolate both points to get exact cut with 315.

Update: Bearing formula

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I need it constrained to the 3 directions, how does this take that into account? also, what is p? –  Dominik Feb 20 '13 at 20:21
Updated p, I showed it for Direction Point to Ocean in East direction. Try to understand how it works, then the othe rthree direction: to N, to S, to W, are analog. –  AlexWien Feb 20 '13 at 20:44
I understand how it works. The cardinal directions are easy because you only need to compare one variable. This approach works for W but I really need help with NW and SW (315 deg and 225 deg) for which it does not work as far as I can tell. `loc` changes based on how far away you are from the coast. –  Dominik Feb 20 '13 at 21:10
Updates now it works for all angles, it runs along the border with a bearing to formula (greater circle) which stores when the bearing is found. –  AlexWien Feb 20 '13 at 22:04
Here is a picture of my output. Units are degrees. West looks right but I expected NW and SW to look similar. I can't decide if it's right...why the striations? Code for NWd2O looks as follows: `for i=length(latlim):-1:1 if azimuth(lat,long,latlim(i),lonlim(i)) >= 314.5 && azimuth(lat,long,latlim(i),lonlim(i))<315.5 [sta_o.NWd2O sta_o.NWaz]=distance(lat,long,latlim(i),lonlim(i)); break end end` –  Dominik Mar 2 '13 at 0:47

The following works if you have a referencing object R. Thanks to @AlexWein for the azimuth idea. The reason for the striping in the previously posted picture was the scale of the coastal vector. Notice I'm using 0.0042 deg increments (same as dem resolution). The 5 stripes were indicating that I was only finding the distance using 5 coastal coord points and the stepped stripes happened because I was bouncing from nearest point below to nearest point above and back again.

``````    latlim=[0.25:.0042:60];
lonlim=ones(length(latlim),1)*-110

for r=1:32
for c=1:32

[lat long]=pix2latlon(R,r,c)
[d, az]=distance(lat,long,latlim,lonlim);

[~, azi]=min(abs(az-270));
sta_o.Wd2O=d(azi);
sta_o.Waz=az(azi);

[~, azi]=min(abs(az-315));
sta_o.NWd2O=d(azi);
sta_o.NWaz=az(azi);

[~, azi]=min(abs(az-225));
sta_o.SWd2O=d(azi);
sta_o.SWaz=az(azi);

end
end
``````
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