# Determine distance from coastline in Matlab

In MATLAB, I have an array of latitude and longitude pairs that represents locations in the United States. I need to determine the distance to the nearest coastline.

I think MATLAB has a built in database of lat/lon points of the United States. How do I access it and use it?

Also any suggestions on how to efficiently determine the distance?

Update: Follow-up question : Determine center of bins when using meshm

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``````load coast;
axesm('mercator');
plotm(lat,long)
``````

There are other datasets in the same directory as coast.mat that might be more useful.

I would then just find the distance to all the points in the dataset, and take the shortest distance. This would assume that coastlines outside of the US are acceptable answers. You will want to use the distance function since Euclidean geometry does not apply here.

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Are those files and functions in the Mapping Toolbox? –  gnovice Aug 26 '10 at 15:02
Yes, these are mapping toolbox. Was about to edit the answer to reflect that, but you caught me already! –  MatlabDoug Aug 26 '10 at 15:07
I had to do plotm(long,lat) to get North up. –  Marc Aug 26 '10 at 15:50
@Marc, That is odd. I just tried again and my method gets north up. –  MatlabDoug Aug 27 '10 at 13:38
@Marc, I used `plotm(lat,long)` and North was up –  Elpezmuerto Aug 27 '10 at 14:23

Since I don't have access to the Mapping Toolbox, which would be ideal to solve this problem, I came up with a solution that is independent of any toolboxes, including the Image Processing Toolbox.

Steve Eddins has an image processing blog at The MathWorks where last year he had a series of pretty cool posts devoted to using digital elevation maps. Specifically, he pointed out where to get them and how to load and process them. Here are the relevant blog posts:

With this DEM data, you can find out the latitude and longitude for where the edges of the oceans are, find the distance from an inland map point to the closest of these coastal points, then make a sweet visualization. I used the function FILTER2 to help find the edges of the oceans via convolution with the ocean mask, and the equations for computing great-circle distances to get the distance between map points along the surface of the Earth.

Using some of the sample code from the above blog posts, here's what I came up with:

``````%# Load the DEM data:

data_size = [6000 10800 1];  %# The data has 1 band.
precision = 'int16=>int16';  %# Read 16-bit signed integers into a int16 array.
interleave = 'bsq';          %# Band sequential. Not critical for 1 band.
byte_order = 'ieee-le';
dem = [E F];  %# The digital elevation map for tile E and F
clear E F;    %# Clear E and F (they are huge!)

%# Crop the DEM data and get the ranges of latitudes and longitudes:

[r,c] = size(dem);      %# Size of DEM
rIndex = [1 4000];      %# Row range of DEM to keep
cIndex = [6000 14500];  %# Column range of DEM to keep
dem = dem(rIndex(1):rIndex(2),cIndex(1):cIndex(2));  %# Crop the DEM
latRange = (50/r).*(r-rIndex+0.5);     %# Range of pixel center latitudes
longRange = (-180/c).*(c-cIndex+0.5);  %# Range of pixel center longitudes

%# Find the edge points of the ocean:

ocean_mask = dem == -500;        %# The ocean is labeled as -500 on the DEM
kernel = [0 1 0; 1 1 1; 0 1 0];  %# Convolution kernel
[latIndex,longIndex] = ...       %# Find indices of points on ocean edge
coastLat = latRange(1)+diff(latRange).*...     %# Convert indices to
(latIndex-1)./diff(rIndex);         %#   latitude values
coastLong = longRange(1)+diff(longRange).*...  %# Convert indices to
(longIndex-1)./diff(cIndex);       %#   longitude values

%# Find the distance to the nearest coastline for a set of map points:

lat = [39.1407 35 45];        %# Inland latitude points (in degrees)
long = [-84.5012 -100 -110];  %# Inland longitude points (in degrees)
nPoints = numel(lat);         %# Number of map points
scale = pi/180;               %# Scale to convert degrees to radians
distanceToCoast = zeros(1,nPoints);   %# Preallocate distance measure
coastIndex = zeros(1,nPoints);        %# Preallocate a coastal point index
for iPoint = 1:nPoints                %# Loop over map points
rho = cos(scale.*lat(iPoint)).*...  %# Compute central angles from map
cos(scale.*coastLat).*...     %#   point to all coastal points
cos(scale.*(coastLong-long(iPoint)))+...
sin(scale.*lat(iPoint)).*...
sin(scale.*coastLat);
d = radiusEarth.*acos(rho);         %# Compute great-circle distances
[distanceToCoast(iPoint),coastIndex(iPoint)] = min(d);  %# Find minimum
end

%# Visualize the data:

image(longRange,latRange,dem,'CDataMapping','scaled');  %# Display the DEM
set(gca,'DataAspectRatio',[1 1 1],'YDir','normal',...   %# Modify some axes
'XLim',longRange,'YLim',fliplr(latRange));          %#   properties
colormap([0 0.8 0.8; hot]);  %# Add a cyan color to the "hot" colormap
xlabel('Longitude');         %# Label the x axis
ylabel('Latitude');          %# Label the y axis
hold on;                     %# Add to the plot
plot([long; coastLong(coastIndex).'],...    %'# Plot the inland points and
[lat; coastLat(coastIndex).'],...      %'#   nearest coastal points
'wo-');
str = strcat(num2str(distanceToCoast.',...  %'# Make text for the distances
'%0.1f'),{' miles'});
text(long,lat,str,'Color','w','VerticalAlignment','bottom');  %# Plot the text
``````

And here's the resulting figure:

I guess that puts me almost 400 miles from the nearest "ocean" coastline (in actuality, it's probably the Intracoastal Waterway).

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You are a determined man to solve the question without the Matlab toolbox, I salute you –  Elpezmuerto Aug 27 '10 at 19:06
how'd you figure out how to calculate latRange and longRange. I am now using the Alaskan NOAA DEM dataset (50-90N, 90-180N), but I can't get the correct latRange and longRange. Where did you get the 0.5 or the 50/r or -180/c? I modified the data_size parameter to account for the A title, but still lost –  Elpezmuerto Sep 23 '10 at 21:09
I am currently using: `latRange = (40/r).*(r-rIndex+0.5) + 50;` and `longRange = (-90/c).*(c-cIndex+0.5)-90;` They are close, but I am not confident :( –  Elpezmuerto Sep 23 '10 at 21:29
@Elpezmuerto: My example uses tiles E and F. These tiles together span 0-50N, 0-180W. This is where the `50/r` and `-180/c` scale factors come from. For your example using tile A, they would be `40/r` and `-90/c`, respectively. The factor of `0.5` is there so that coordinate ranges are computed from the center of the first pixel to the center of the last pixel. The coordinates in `coastLat` and `coastLong` are also computed at the pixel centers. –  gnovice Sep 23 '10 at 21:33
thanks! I am glad I was able to figure it out and thanks for the confirmation!!! –  Elpezmuerto Sep 23 '10 at 21:38

Gnovice's answer was nice and useful for the future but I did not need that high of fidelity and didn't want to spend extra timing converting from pixel distance to latitude/longitude distance. Taking MatlabDoug's answer, I wrote the following script:

``````% Get Data

% Preallocate
coast_indexes = nan(size(locations.lat));
distancefromcoast = nan(size(locations.lat));

% Find distance and corresponding coastal point
for i=1:1:numel(locations.lat)
[dist, az] = distance(locations.lat(i), locations.long(i), coast.lat, coast.long);
[distancefromcoast(i),coast_indexes(i)] = min(dist);
end
``````
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You could use the second output from MIN to get your index: `[distancefromcoast(i),coast_indexes(i)] = min(dist);` –  gnovice Aug 27 '10 at 19:08
@Gnovice, thanks and updated accordingly –  Elpezmuerto Aug 27 '10 at 19:17
If you want to compute geodesic distances without the mapping toolbox, use geoddistance in mathworks.com/matlabcentral/fileexchange/39108. This is more accurate than distance and works even for nearly antipodal points (unlike distance). –  cffk Dec 21 '13 at 15:56