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This, of course, results in issues when the battery pack is nearing full charge and is drawing a low current from the MPPT. If the MPPT were to continue to try to maintain the same output power, its output voltage would increase without bound and eventually cause a battery overvoltage. The Nomura MPPT thus implements a voltage limiting function, tuned via potentiometers, which prevents the boost converter from continuing to charge up the output capacitor once it has reached a preset limit. From a power perspective, voltage-limit mode is inefficient because it does not use the full power potential of the input PV string.
Additionally, because the MPPT is only capable of boosting, not stepping down the voltage of the input side PV string, there exists a feed-through mode where the MPPT will directly connect the input string to the output in situations where the output voltage is less than the minimum boost voltage, 1.1 x Vin. This bypasses the boost circuitry entirely and results in no power point tracking, but elegantly handles a short-circuit and can still deliver some power in certain cases.
Outside of the overvoltagevoltage-limit and feed-through modes, the MPPT is in constant power mode, where its output current is directly determined by the output voltage and input power. All three regions are shown in the drawing below. Note that the IV curve can be idealized as a doubly-truncated 1/x curve, where the untruncated region corresponds to the constant-power region.
The MPPT also has a fourth mode, not shown in the above drawing, called pass-through mode, which occurs if the input voltage drops below the minimum required voltage for the boost converter. In this case, the output side is shorted so as to prevent the entire MPPT stack from going open-circuit, and the MPPT itself delivers no power.
String Dynamics
When operating in the constant-power region, the MPPTs in a string will naturally converge to the correct voltage distribution based on their input power. As a simple example, consider the case of a stack of two MPPTs connected to a battery. If one MPPT suddenly drops its output voltage, the second MPPT will see a larger portion of the total pack voltage. Initially, this will result in no current being delivered, since the MPPT sees a load with a higher potential than it. The MPPT's built-in diode prevents the battery from driving current into it.
As the output current of the MPPT starts to decrease towards zero, the boost converter will naturally start to charge up its output capacitor until the voltage once again reaches (then slightly exceeds) the new load voltage, at which point current will start to be delivered to the load, acting to discharge the output capacitor. Because the boost converter is now stepping the input side voltage by a larger ratio, it has a decreased output current ability and thus the MPPT reaches a new equilibrium with a reduced current, but the same power.
This balancing only works when all MPPTs in the stack are operating in the constant-power region. If one MPPT saturates and enters voltage-limit mode, it will prevent itself from further boosting its output voltage and thus the voltage of the entire stack may decrease. The same effect will result from an MPPT entering pass-through mode (a large part of its input PV string becomes shaded or damaged).