# Can we generate “foveated Image” in Mathematica

"Foveated imaging is a digital image processing technique in which the image resolution, or amount of detail, varies across the image according to one or more "fixation points." A fixation point indicates the highest resolution region of the image and corresponds to the center of the eye's retina, the fovea."

I want to use such image to illustrate humans visual acuity, The bellow diagram shows the relative acuity of the left human eye (horizontal section) in degrees from the fovea (Wikipedia) :

Is there a way to create a foveated image in Mathematica using its image processing capabilities ?

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Something along the following lines may work for you. The filtering details should be adjusted to your tastes.

``````lena = ExampleData[{"TestImage", "Lena"}]
``````

``````ImageDimensions[lena]

==> {512, 512}

mask = DensityPlot[-Exp[-(x^2 + y^2)/5], {x, -4, 4}, {y, -4, 4},
Axes -> None, Frame -> None, Method -> {"ShrinkWrap" -> True},
ColorFunction -> GrayLevel, ImageSize -> 512]
``````

``````Show[ImageFilter[Mean[Flatten[#]] &, lena, 20, Masking -> mask], ImageSize -> 512]
``````

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Thank You very much, I felt this one would come from you ! –  500 Sep 13 '11 at 1:07
Sjoerd, I need a nice plot of the photoreceptor density in the eye in 2D such as : oculist.net/downaton502/prof/ebook/duanes/pages/v3/ch001/… Do you know about such plot of higher quality ? Or a trick to use those and make a better one ? Thanks for your attention anyway ! –  500 Sep 13 '11 at 2:56
@500 Please note that this technique only fakes a position-dependent blur. The blur itself is constant everywhere, but is blended in with a position-dependent alpha. At least that's how I assume `Masking` works. So I don't think it's worthwhile trying to come up with very accurate density maps as they cannot really be used to make an accurate representation of vision acuity with this method. What you would need is a position dependent filter and I haven't found one in the mma's image processing function set. I don't think it is too difficult to program one yourself. It will be a bit slower. –  Sjoerd C. de Vries Sep 13 '11 at 6:45
Thank You Sjoerd ! –  500 Sep 13 '11 at 18:55

Following on Sjoerd's answer, you can `Fold[]` a radius-dependent blur as follows.

A model for the acuity (very rough model):

``````Clear[acuity];
With[{\[Theta] = ArcTan[distance, Sqrt[x^2 + y^2]]},
Clip[(Chop@Exp[-Abs[\[Theta]]/(15. Degree)] - .05)/.95,
{0,1}] (1. - Boole[(x + 100.)^2 + y^2 <= blindspotradius^2])]

Plot3D[acuity[250., x, y, 25], {x, -256, 256}, {y, -256, 256},
PlotRange -> All, PlotPoints -> 40, ExclusionsStyle -> Automatic]
``````

The example image:

``````size = 100;
lena = ImageResize[ExampleData[{"TestImage", "Lena"}], size];

Manipulate[
ImageResize[
Fold[Function[{ima, r},
ImageFilter[(Mean[Flatten[#]] &), ima,
7*(1 - acuity[size*5, r, 0, 0]),
PlotRange -> {{0, size}, {0, size}}]
]],
lena, Range[10, size, 5]],
200],
{{p, {size, size}}, Locator}]
``````

Some examples:

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Thank you very much!Locator is so sweet ! –  500 Sep 13 '11 at 17:20
Thanks for the typo fixes, Sjoerd. –  JxB Sep 13 '11 at 20:28
Very clever extension! Am I mistaken to conclude that the outer areas are blurred multiple times? Wouldn't that give more blurring than specified by acuity? Perhaps the acuity function could be adapted to correct for that? BTW {"TestImage", "ResolutionChart"} makes for a nice test image too. –  Sjoerd C. de Vries Sep 13 '11 at 20:40
Indeed, there is overlapping of the blurring; it is not as pronounced if you work outward-in, i.e., replacing the Range[10,size,5] with Range[size,10,-5]. But it does need to be accounted for. –  JxB Sep 13 '11 at 21:01
Alternatively, Sjoerd, one could use annular masks so there is no overlap. –  JxB Sep 13 '11 at 21:06

`WaveletMapIndexed` can give a spatially-varying blur, as shown in the Mathematica documentation (WaveletMapIndexed->Examples->Applications->Image Processing). Here is an implementation of a `foveatedBlur`, using a compiled version of the `acuity` function from the other answer:

``````Clear[foveatedBlur];
foveatedBlur[image_, d_, cx_, cy_, blindspotradius_] :=
Module[{sx, sy},
{sy, sx} = ImageDimensions@image;
InverseWaveletTransform@WaveletMapIndexed[ImageMultiply[#,
Image[acuityC[d, sx, sy, -cy + sy/2, cx - sx/2, blindspotradius]]] &,
StationaryWaveletTransform[image, Automatic, 6], {___,  1 | 2 | 3 | 4 | 5 | 6}]]
``````

where the compiled acuity is

``````Clear[acuityC];
acuityC = Compile[{{distance, _Real}, {sx, _Integer}, {sy, _Integer}, {x0, _Real},
Table[With[{\[Theta] = ArcTan[distance, Sqrt[(x - x0)^2 + (y - y0)^2]]},
(Exp[-Abs[\[Theta]]/(15 Degree)] - .05)/.95
*(1. - Boole[(x - x0)^2 + (y - y0 + 0.25 sy)^2 <= blindspotradius^2])],
{x, Floor[-sx/2], Floor[sx/2 - 1]}, {y, Floor[-sy/2], Floor[sy/2 - 1]}]];
``````

The distance parameter sets the rate of falloff of the acuity. Focusing point `{cx,cy}`, and blind-spot radius are self-explanatory. Here is an example using `Manipulate`, looking right at Lena's right eye:

``````size = 256;
lena = ImageResize[ExampleData[{"TestImage", "Lena"}], size];

Manipulate[foveatedBlur[lena, d, p[[1]], p[[2]], 20], {{d, 250}, 50,
500}, {{p, ImageDimensions@lena/2}, Locator, Appearance -> None}]
``````

See the blind spot?

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I think the basic technique is sufficiently different from ImageFilter to justify its own answer. –  JxB Apr 12 '12 at 23:17