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The performance of long-distance imaging systems can often be strongly affected by atmospheric turbulence caused by variation of refractive index along the optical transmission path. Such turbulence can produce geometric distortion, space- and time-variant defocus blur, and motion blur. An example is shown in the following video of the moon.

Video Link to example of atmospheric turbulence http://vimeo.com/21417297

There have been many approaches to solving this problem that attempt to restore a single high-quality image from an observed frame sequence distorted by air turbulence. As in the video, these approaches, and the approach addressed in this paper, work under the assumption that the scene and the image sensor are both static and that observed motions are due to the air turbulence alone.

The imaging process can be modeled as:

g_k = H_k*F_k*f + n_k where f denotes the ideal image, F_k and H_k represent the geometric deformation and blurring matrices respectively, n_k denotes additive noise, and g_k is the k-th observed frame.

The key then becomes to basically reverse this process so that we can find the desired ideal image.

Retinotopic maps were obtained in 5 subjects using Population Receptive Field mapping methods Dumoulin and Wandell (2008). These data were collected for another research project in the Wandell lab. We re-analyzed the data for this project, as described below.

Subjects were 5 healthy volunteers.

Data were obtained on a GE scanner. Et cetera.

The MR data was analyzed using mrVista software tools.

All data were slice-time corrected, motion corrected, and repeated scans were averaged together to create a single average scan for each subject. Et cetera.

PRF models were fit with a 2-gaussian model.

After a pRF model was solved for each subject, the model was trasnformed into MNI template space. This was done by first aligning the high resolution t1-weighted anatomical scan from each subject to an MNI template. Since the pRF model was coregistered to the t1-anatomical scan, the same alignment matrix could then be applied to the pRF model.
Once each pRF model was aligned to MNI space, 4 model parameters - x, y, sigma, and r^2 - were averaged across each of the 6 subjects in each voxel.

Et cetera.

Some text. Some analysis. Some figures.

Some text. Some analysis. Some figures.

Some text. Some analysis. Some figures. Maybe some equations.

If you want to use equations, you can use the same formats that are use on wikipedia.
See wikimedia help on formulas for help.
This example of equation use is copied and pasted from wikipedia's article on the DFT.

The sequence of N complex numbers x₀, ..., x_N−1 is transformed into the sequence of N complex numbers X₀, ..., X_N−1 by the DFT according to the formula:

${\displaystyle X_k={\displaystyle \sum _{n=0}^{N-1}}{x}_n{e}^{-\frac{2\pi i}{N}kn}k=0,\dots ,N-1}$

where i is the imaginary unit and ${\displaystyle e^{\frac{2\pi i}{N}}}$ is a primitive N'th root of unity. (This expression can also be written in terms of a DFT matrix; when scaled appropriately it becomes a unitary matrix and the X_k can thus be viewed as coefficients of x in an orthonormal basis.)

The transform is sometimes denoted by the symbol ${\displaystyle ℱ}$, as in ${\displaystyle 𝐗=ℱ\left\{𝐱\right\}}$ or ${\displaystyle ℱ\left(𝐱\right)}$ or ${\displaystyle ℱ𝐱}$.

The inverse discrete Fourier transform (IDFT) is given by

${\displaystyle x_n=\frac{1}{N}{\displaystyle \sum _{k=0}^{N-1}}{X}_k{e}^{\frac{2\pi i}{N}kn}n=0,\dots ,N-1.}$

Some text. Some analysis. Some figures.

Here is where you say what your results mean.

References

Software

File:CodeFile.zip

zip file with my data

Brian and Bob gave the lectures. Jon mucked around on the wiki.