Thanks so much for spending all this time looking at my data. Allow me to answer some of your questions.
The experimental design is basically: 5 coral colonies broken up into 25 2-g fragments, a subset of 18 of which were used in experiments (n=90 coral fragments). I actually took some of Jian Cao's suggestions to look at the nesting random coefficients feature to ensure that the corals essentially all started off similarly (this could very well NOT be the case since different fragments could display differentially recovery from being torn off their parent colony).
30 corals fragments were placed in each of three tanks. Within each tank, 10 fragments were placed at each of three depths (which correspond to different light levels). Half of the 10 colonies in each light x tank group are fed. Feed is actually done by transporting them somewhere else, so it's not as if there is a physically stratified light x food "bin" in each tank. So "bin" in my table is actually just "tank x light x food" = 3 x 3 x 2 = 18 bins, each with 5 fragments. In other words, there are six fixed-factor treatments (food x light groups) with three tanks. So I think you are right: it is tank as the whole plot and light x food as the within-tank subplot. Fragment is the repeated subject and time is the repeated measure. Does that mean that, under random effects in the mixed model platform, I should include tank AND light x food(tank)? I think it is just the latter since light x food(tank) is literally the whole design (subplot nested within whole plot). I have attached a new data table with this script. The last one perhaps didn't save properly.
Your figures look similar to mine. What jumps out is that food seems to have a stronger effect than light. That is the main point of the study, in fact. I had never seen these control and variability plots before, but this could be a good way of showing relative influence of time and tank. I usually use predictor screening or fit-model+random effects for all parameters to get at this in a different way (i.e., which factors drove the most variation in your responses). Actually, if you look at BW alone, light has a stronger effect than food (which is not significant), which is why the "specific growth rate" found in the second table I'm attaching might be the way to go (i.e., relative rate of size increase rather than raw size data).
Two factors correlate so much as to be redundant. I think I didn't include one of them (TLE) in the file I sent. Basically, we looked at size 2-3 different ways since analyzing size of corals is surprisingly disputed. But in the end, they respond similarly to treatment. Fv/Fm is a proxy for photosynthesis, and, while statistically significant, we are talking about a range of 0.7=mean low to 0.74=mean high. I literally wrote a sentence in the manuscript saying that "Although highly significantly influenced by the experimental factors, it was unclear whether such differences are biologically relevant." The photosynthesis people will butcher me because it has become the norm to build huge stories on minuscule changes in this response variable (which I obviously disagree with). In contrast, the weight increased from 2 g to 9 g over 140 days (over 4-fold), which will likely to be the selling point of the whole paper because it's unprecedentedly high.
I have been box-cox transforming the decidedly non-normally distributed data. The color scores are themselves essentially ranks, which I guess makes the color analysis non-parametric.
The second file "linear extension split by time" is really the "meat" because this reflects all the data as a relative or percent change (i.e., the temporal element has been removed). The exception is Fv/Fm, where I just show the file data. One could argue that the actual time by time temporal changes are less important (and will probably end up as an online supplemental figure) vs. the overall effects shown in this second table so I am going to try out the aforementioned split plot with this table (as well as with your pooled summary file).
Anderson B. Mayfield
