It looks like the meat of the work done in this "Simulink" model is actually being performed by your MATLAB function. So the answer to this question is going to largely rely on what that function is actually doing. Specifically, what is the expected input to
vidfunc, and what is this function's output? I suspect that this function may need to be revised to fit into your model.
To debug your model, it's useful to think about what the signal output is from each block. At each time step, your
From Multimedia File block will output a single image frame, which according to the doc looks to be structured as an
M-by-N-by-P color video signal where P is the number of color planes.
Moving downstream, we next come to the
Color Space Conversion block, which in this case looks like it will most likely output an image frame in the form of an M-by-N matrix (where each element of the matrix corresponds to the image's intensity at that pixel).
Now we come to the interesting part -- the
MATLAB Fcn block. As we just saw, the input to this block will be an M-by-N matrix representing a single image frame. When you look in the parameter dialog box for the
MATLAB Fcn block, the input to this block is represented by the variable
u. Therefore, to execute the
vidfunc function on the image frame being input to this block, you would simply enter
vidfunc(u) for your MATLAB function.
Now, based on the input going to the
MATLAB Fcn block, and the fact that you have a Video Viewer block connected to the output,
vidfunc should be structured such that it operates on a single image frame as its input and outputs another single image frame. If
vidfunc is not structured in this way, you will need to edit it (or just re-implement the same functionality using Simulink blocks).
That said, let's assume that
vidfunc is also returning an M-by-N matrix representing a processed image frame. You will want to set the Output Dimensions parameter for your
MATLAB Fcn block to
-1 to indicate that the output will have the same dimensions as the input. Also, (as indicated in the doc) you will want to make sure Collapse 2-D results to 1-D is unchecked or else your image output will be in the form of one long vector rather than an M-by-N matrix.
vidfunc is structured correctly, this should solve your problem.
NOTE: To make your life a lot easier, I would strongly suggest displaying the signal data type and dimensions in your Simulink model. This can help to avoid a lot of confusion. This doc describes exactly how to do this.
After looking at your code, this confirms my suspicion that the inputs/outputs of
vidfunc are inconsistent with what your Simulink model expects. The way that you proceed is highly dependent on what your own design constraints are and what you actually want out of this system. Basically, your Simulink model and MATLAB function disagree... which one is right? I'll give some general thoughts based on my best guesses at what you're aiming for.
First, Simulink is passing an image (in the form of an M-by-N matrix) into
vidfunc. This means that
vidfunc no longer needs to load an image at the start of the code. So I believe that you could update the first few lines of code to be as such:
BW = edge(a,'sobel'); %sobel edge detection
See that now
vidfunc is taking the actual image (not the filename that contains the image) as its input. Basically, you are removing the
a=imread(u); line and jumping right in to processing
The other issue is the output of
vidfunc. Simulink is expecting the output to be an image, but it is not. I'm not 100% sure what
h is supposed to be in this code (when I first glanced at your code I thought these were handles to line objects but that doesn't seem to be the case). It looks to possibly be the y coordinate of the endpoint of one of the houghlines. Nevertheless, it's not what your Simulink model is expecting. This one is not as straight-forward to fix. Possibly you could try to use getframe to grab an image from the plot of your lines.
I actually feel that the best advice that I can give to you is to just scrap the MATLAB function and implement everything in Simulink. I think this will be a lot easier than trying to get
vidfunc to play nicely with your model.
vidfunc does not actually contain that much code, so this should not be too difficult of a task for you. Another benefit is that at the end of this process you'll have a nice Simulink model that explicitly shows all of the image processing steps that you are taking.
I believe that all of the image processing that you are doing with MATLAB functions can also be done with Simulink blocks (see the Simulink Blocks section of this doc).