In other words if you have East and West facing strings combined then the MPPT for each string is vastly different over the course of a day, but the strings are combined.

So, this is all East facing right?

I noticed the panels the other day when I went to check where the bad weather and
tornado was predicted in your area.

After 4 years google earth has updated. After 4 years can finally see all my solar panels. Even the short
timed test panels; apparently taken around the end of winter. Bruce Roe

By beginning afternoon the WEST system had collected 47 KWH, but the EAST
system had collected only 40 KWH. The difference is the rising sun hitting the WEST system first, completely
clearing the shadows on EAST much later. So WEST is running some 18% ahead for this time. Toward the
end of the day EAST about catches up, which means the same effect is reversed for the setting sun.

It appears that relocating panels can solve most of the discrepancy, without cutting another series of trees.
Bruce Roe

Vclipping/Vmp is a tough number to use. The IV curve is really non-linear near the maximum power point, so the voltage change per watt of power "clipped" is probably not constant, nor solely a function of temperature.

Dan's suggestion helps ballpark the maximum energy that could have been produced on a clear day, but I understand that isn't quite what you want. I'm not sure there is a satisfactory answer without taking enough data to build a single diode model of your specific array across enough conditions to be useful. The CEC model implemented in SAM is a good starting point.

Thanks, there will always be some temp error; if its pretty consistent, most will cancel out. Sensors here are pretty
small, TO92 transistor package can be stuck on and insulated on one square inch. If I want to have a simple
read out, I won't be using super accurate IR readings. Bruce Roe

You're most welcome.

On sensors, temp. measurement and accuracy: I'd keep in mind that thermosensors are better for use in measuring temperature differences at a point under different conditions rather than as an accurate measurement of panel or cell temperature. (More ) Accurate temp. measurements require low or less thermal resistance between the sensor and the panel than between the sensor and the surrounding environment. Hence, the best readings are from instruments in intimate contact with what's being measured and lots of insulation between the sensor and the external environment. The result of all that is that a panel's local temp. around the well applied sensor is higher than the rest of the panel (if in daylight) because of the back insulation that prevents heat transfer to the environment from the back of the panel, raising the panel temp. and so probably a cause of an erroneous temp. that's not as representative of actual panel temps. Conversely, a poorly or loosely affixed and/or uninsulated sensor will give an inaccurately low reading. Relative error from fixation can be estimated as roughly in proportion to the ratio of thermal resistances between the sensor to panel and sensor to environment.

All that's why the best readings ( or at least not the worst) are usually done in the field w/ IR thermometers when other than relative temp. differences are sought, and they're probably not the best choice in those situations either. Regards,