Try to run a Fourier transform for the image. The screen will produce very sharp frequency peaks. With those peaks you will get the screen frequency and angle quite accurately even from a noisy image.
I just transformed your image back to a grayscale image:
Then I run a 2D fft over it:
The bright dots at (20,27) and its mirror positions are very strong peaks, orders of magnitude stronger than anything else in the image. This curve shows the power spectrum over row 20:
So the screen frequency in the y direction is approximately 193/20 = 9.7 pixels (image height 193), and in the x direction 263/27 = 9.7 pixels. This is the inter-dot distance in each direction, and a bit of trigonometry is usually needed to calculate the axes. The peak position can be interpolated more accurately from the Fourier power spectrum by using the area around the peaks, if needed. The peaks can also be folded on top of each other to reduce noise.
FFT is a rather quick transform to calculate (at least compared to Hough & al.), but with large images it takes a lot of space and time. You may use it on several smallish areas (e.g. 10 dots across), which also helps you in case the screen is not even. At least in that case it will be fast. On my computer it takes 418 us to run a 128x128 pixel 2D FFT.
Notes on FFT
Readers not familiar with the Fourier transform should be aware of the fact that I have used some sloppy language above and in the comments. The transform itself is "Fourier transform", FFT is just one algorithm (de facto standard in image processing) to perform a discrete Fourier transform (DFT).
One thing that tends to confuse people when calculating FFTs and comparing the results to literature is the position of the zero frequency in the image. In most textbooks the zero frequency (actually the sum of the image pixel values) is in the center of the image. Most FFT libraries put the zero frequency to the upper left hand corner (as in my example).
So, in the textbooks zero frequency components are usually close to the centre of the transformed image. With most FFT libraries low frequencies are close to each corner of the image. (There are usually functions with names like
fftshiftto transform between these two representations.)
FT is a complex transformation. If a real-valued signal (such as a single image) is transformed, there will be a lot of symmetry in the resulting transformed image. This is usually not very important, but sometimes it can be used to speed things up or save some memory.
Complexity of single-dimensional FFT is O(n log n). In the two-dimensional case the FFT is first run for each column, and then each row and is thus O(x y log y + y x log x) = O(x y (log x + log y)) or O(n^2 log n) for a square image. Modern computers are very fast with FFTs (and can be boosted even further by using the GPUs), but large FFTs with thousands of points to each direction are a warning sign of one using the wrong algorithm.