Panel Size and Efficiency
Let the reader change the values of parameters in the analysis to see how different
parameter values affect the results.
So far our calculations reflect the theoretical maximum solar radiation available for power
conversion. However, solar panels do not convert 100% of available solar radiation into
electricity. The efficiency of a solar panel is the fraction of the radiation reaching the
panel that is converted into electricity. The efficiency of a solar panel depends on the
design and materials of the cell.
Typically, a residential installation includes 20 m^2 of solar panels with an efficiency of
25%. You can modify the parameters below to see how efficiency and size affect panel
power generation.
eff = 0.36; % Panel efficiency
pSize = 25; % Panel size in m^2
pElec = eff*pSize*pRad; % Panel electric output in kW
disp(['Expected electical output = ' num2str(pElec) ' kW'])
Expected electical output = 8.0901 kW
Power Generation Over Time
Create plots in the Live Editor together with the code that produced them. Double-click a
plot to open it in a separate figure window.
We can now calculate how much power a panel will generate on any day of the year. To
simplify the analysis, we'll use a function called panelRadiation that uses the
equations above to calculate hourly total solar radiation and panel radiation for a given
date and location. The parameter isFixed is set to 1 for fixed panels, 0 for tracking
panels. Try different dates to see how the solar and panel radiation changes depending on
the time of year.
[time, sRad, pRad] = panelRadiation(date, longitude, latitude,
UTCoff, panelTilt, panelAzimuth, isFixed)
isFixed = 1;
selectedYear = 2016;
selectedMonth = 1;
selectedDay = 1;
date = datetime(selectedYear,selectedMonth,selectedDay,'TimeZone',TZ);
[times, sRad, pRad] = panelRadiation(date, lambda, phi, UTCoff, tau, beta, isFixed) ;
19 Live Scripts and Functions