plot a 2D circular intensity map

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Sharon on 30 May 2024

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Commented: Adam Danz on 31 May 2024

Dear all,

i would like to plot a 2D map showing below. I have x and y coordinates and z being the intensity showing as in different scale in color.

for the areas without the datapoint, i might need to interpolate the gap.

does anyone know how i can do this?

thanks so much for your help

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Answer 1

Adam Danz on 30 May 2024

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https://au.mathworks.com/matlabcentral/answers/2123936-plot-a-2d-circular-intensity-map#answer_1465516

Edited: Adam Danz on 31 May 2024

Open in MATLAB Online

This demo assumes you have a vector of x-coordinates, a vector of y-coordinates, and a vector of intensity values.

It uses griddata to interpolate the values and organize the intensity values into a grid.

The interpolated grid values are plotted using pcolor.

radius = 10;

N = 5000;

r = radius * rand(N,1).^.5;

th = 2*pi * rand(N,1);

x = r.*cos(th); % x coordinate

y = r.*sin(th); % y coordinate

intensity = hypot(10-x,10-y); % intensity values

% interpolate in a grid

resolution = 500; % resolution of the interpolation

[Xq,Yq,intensityq] = griddata(x,y,intensity,...

linspace(min(x),max(x),resolution),...

linspace(min(y),max(y),resolution)');

% Plot results, use interpolated face color

p = pcolor(Xq,Yq,intensityq);

p.FaceColor = 'interp';

p.EdgeColor = 'none';

axis equal

colorbar()

grid on

Compare that to the original data

figure()

scatter(x,y,10,intensity,'filled')

axis equal

grid on

colorbar()

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Adam Danz on 31 May 2024

Edited: Adam Danz on 31 May 2024

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If you want to expand the regions to fill the range of data, it will result in a square since the range is the min and max along the x and y axes. One easy way to do that is to change the interpolation method in griddata. Below shows the results for "v4" and "nearest" neighbor interpolation methods. The only change is to specify the method in the 6th argument to griddata.

radius = 10;

N = 5000;

r = radius * rand(N,1).^.5;

th = 2*pi * rand(N,1);

x = r.*cos(th); % x coordinate

y = r.*sin(th); % y coordinate

intensity = hypot(10-x,10-y); % intensity values

% interpolate in a grid

resolution = 500; % resolution of the interpolation

[Xq,Yq,intensityq] = griddata(x,y,intensity,...

linspace(min(x),max(x),resolution),...

linspace(min(y),max(y),resolution)', ...

'v4'); % <------------------------------- SPECIFY METHOD

% Plot results, use interpolated face color

p = pcolor(Xq,Yq,intensityq);

p.FaceColor = 'interp';

p.EdgeColor = 'none';

axis equal

colorbar()

grid on

title('griddata interp method: v4')

figure()

resolution = 500; % resolution of the interpolation

[Xq,Yq,intensityq] = griddata(x,y,intensity,...

linspace(min(x),max(x),resolution),...

linspace(min(y),max(y),resolution)', ...

'nearest'); % <------------------------------- SPECIFY METHOD

% Plot results, use interpolated face color

p = pcolor(Xq,Yq,intensityq);

p.FaceColor = 'interp';

p.EdgeColor = 'none';

axis equal

colorbar()

grid on

title('griddata interp method: nearest')

Another method would be to fill in the x, y, and intensity data for each corner of the range of data.

radius = 10;

N = 5000;

r = radius * rand(N,1).^.5;

th = 2*pi * rand(N,1);

x = r.*cos(th); % x coordinate

y = r.*sin(th); % y coordinate

intensity = hypot(10-x,10-y); % intensity values

% Fill in data for each corner of the range of data

% I'll use the minimum intensity for each corner - or you could use 0?

xBounds = [min(x,[],'all'), max(x,[],'all')];

yBounds = [min(y,[],'all'), max(y,[],'all')];

x(end+(1:4)) = xBounds([1 2 2 1]);

y(end+(1:4)) = yBounds([1 1 2 2]);

intensity(end+(1:4)) = min(intensity).*[1,1,1,1];

% interpolate in a grid

figure()

resolution = 500; % resolution of the interpolation

[Xq,Yq,intensityq] = griddata(x,y,intensity,...

linspace(min(x),max(x),resolution),...

linspace(min(y),max(y),resolution)');

% Plot results, use interpolated face color

p = pcolor(Xq,Yq,intensityq);

p.FaceColor = 'interp';

p.EdgeColor = 'none';

axis equal

colorbar()

grid on

title('Assign value to corners')

Adam Danz on 31 May 2024

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If you want to keep the data within a circle, instead of interpolating from min to max of data range, you can interpolate based on points distributed within the circle.

opts = detectImportOptions('datapoints.xlsx');

opts = setvartype(opts,'double');

T = readtable('datapoints.xlsx',opts);

x = T.x;

y = T.y;

intensity = T.z;

% Interpolate gridded points within the circle

radius = 10;

center = [mean(x,'all'), mean(y,'all')]; % Compute center of circle if not known

resolution = 1000; % resolution of the interpolation

[xg,yg] = meshgrid(linspace(min(x),max(x),resolution), linspace(min(y),max(y),resolution));

isOut = hypot(xg-center(1), yg-center(2)) > radius;

xg(isOut) = NaN;

yg(isOut) = NaN;

[Xq,Yq,intensityq] = griddata(x,y,intensity,xg,yg);

figure()

% Plot results, use interpolated face color

p = pcolor(Xq,Yq,intensityq);

p.FaceColor = 'interp';

p.EdgeColor = 'none';

axis equal

colorbar()

grid on

title('Sample points within a circle')

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Answer 2

Shivani on 30 May 2024

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https://au.mathworks.com/matlabcentral/answers/2123936-plot-a-2d-circular-intensity-map#answer_1465426

Edited: Shivani on 30 May 2024

Open in MATLAB Online

Hello @Sharon,

Please note that there are multiple methods for plotting a 2D map in MATLAB, and the most optimal approach depends on the specific characteristics of your data. I might not be able to suggest the most optimal method for plotting the graph described in your question.

Please refer to the code snippet below, which outlines one such approach for plotting a 2D map. This method utilizes `x` and `y` as coordinates, with `z` representing intensity. The snippet also includes code to interpolate the `z` values across the grid.

% Create a grid for x and y coordinates
[X, Y] = meshgrid(linspace(min(x), max(x), 100), linspace(min(y), max(y), 100));
% Interpolate z values on the grid
F = scatteredInterpolant(x', y', z');
Z = F(X, Y);
figure;
imagesc(X(1,:), Y(:,1), Z);
colormap(jet); 
colorbar;
axis equal; 

The following documentation links provide a deeper insight into the functions I've used in the above code snippet. Kindly refer to them for more information on how to customise the plot to your dataset:

Additionally, you can refer to this MATLAB Answer thread for more details: https://www.mathworks.com/matlabcentral/answers/832583-plot-x-y-2d-and-z-where-z-containing-color-intensity

Hope this helps!