The value of the variable
number_panels starts at 3000 instead of 0 or 1. Thus when you index a matrix with that variable as the index value Matlab thinks you are wanting the 3001st index and thus gives you a matrix that is 3000 zeros with the 3001st being set to what you ask.
If you follow the loop into it's next cycle the value of
number_panels becomes 3500. You now are indexing at 3501, based on your code. This means that all of the places from 3002 to 3500 will be filled with zeros and 3501 will be set to whatever value you give it.
The same logic applies to
number_turbines The only difference is that you'll be indexing by 1 instead of by 500 like you are with
If you want to get back to the size matrix you are expecting you'll need to modify the way you call the index values. This could be done a number of ways. You could have a counter within the for-loop or you could use modulus math. Modulus math doesn't work well when you're using a step size that isn't
1. It also doesn't work when you get to the point where you have an index value that is a multiple of your starting index.
You'll have to work out what will work best for you in that arena. Especially since you want to use a step size that isn't 1. But for the
number_turbines that goes from 5 to 8, you can simple index using
number_turbines - 5 + 1 or more concise
For clarity, here is the code you provided with the necessary tweaks to show the use of what was mentioned in the comments. Please take note that you will need to modify the
-4 for the
number_turbines index value should you start at something other than
5. Also note that you need to index the
number_panels vector now since it's not a looped value.
Hope this helps!
number_of_days = 2;
number_panels = 3000:500:4000;
for idx_number_panels = 1:length(number_panels) % range of PV panel units examined
for number_turbines = 5:8 % range of wind turbine units examined
for h=1:24 %# hours
for d = 1:number_of_days %# which day
n = h + 24*(d-1);
% hourly_deficit_1(...,..., h, d)= Demand(n)-(PV_supply(n)... %
hourly_deficit(idx_number_panels , number_turbines -4, h,d) = hourly_annual_demand(n) - (hourly_annual_PV(n)*number_panels(idx_number_panels)) - (hourly_annual_WT(n)*number_turbines);% hourly power deficit (RES supply with demand)
if hourly_deficit(idx_number_panels, number_turbines -4, h,d)< 0 % zero out negative hourly deficit values (this is power surplus from RES)
hourly_deficit(idx_number_panels, number_turbines -4, h,d) = 0;