The document discusses maximum power point tracking (MPPT) techniques used with photovoltaic solar systems. MPPT algorithms aim to maximize solar panel output power by adjusting the load impedance to match the maximum power point. The summary is: 1) MPPT techniques aim to continuously track the maximum power point of solar panels under varying conditions to optimize power extraction. 2) Common MPPT methods include perturb and observe and incremental conductance, which adjust voltage and measure changes in power output to determine the maximum power point. 3) Other MPPT methods include current sweep, constant voltage/open circuit voltage tracking, and techniques using neural networks, fuzzy logic, or temperature measurements.

1. KAMAL C
kamalc1997@gmail.com
64ed0e14e78b11e991174b277ecc527d

2. MPPT-Maximum Power
Point Tracking

3. Introduction:
• Maximum power point tracking (MPPT)or sometimes just power point
tracking (PPT) is a technique used commonly with wind turbines
and photovoltaic (PV) solar systems to maximize power extraction under all
conditions.
• Although solar power is mainly covered, the principle applies generally to sources
with variable power: for example, optical power transmission
and thermophotovoltaics.
• As the amount of sunlight varies, the load characteristic that gives the highest
power transfer efficiency changes, so that the efficiency of the system is optimized
when the load characteristic changes to keep the power transfer at highest
efficiency.
• This load characteristic is called the maximum power point (MPP) and MPPT is
the process of finding this point and keeping the load characteristic there.

4. I-V Characteristics:

5. Maximum Power:
• Photovoltaic cells have a complex relationship between their operating
environment and the maximum power they can produce.
• The fill factor, abbreviated FF, is a parameter which characterizes the non-
linear electrical behavior of the solar cell.
• Fill factor is defined as the ratio of the maximum power from the solar cell
to the product of open circuit voltage Voc and short-circuit current Isc.
• Maximum Power by a cell is given by, P=FF*Voc*Isc.
• For any given set of operational conditions, cells have a single operating
point where the values of the current (I) and voltage (V) of the cell result in
a maximum power output.

6. Maximum Power Point:
• A photovoltaic cell, for the majority of its useful curve, acts
as a constant current source. However, at a photovoltaic cell's
MPP region, its curve has an approximately inverse
exponential relationship between current and voltage.
• From basic circuit theory, the power delivered from or to a
device is optimized where the derivative (graphically, the
slope) dI/dV of the I-V curve is equal and opposite
the I/V ratio (where dP/dV=0).
• This is known as the maximum power point (MPP) and
corresponds to the "knee" of the curve.

7. Block Diagram:
Basic Block
Diagram:
Real Time
MPPT:

8. Classification:
• Perturb and Observe(Hill Climbing)
• Incremental Conductance
• Current Sweep(Short Circuit Current)
• Constant Voltage(Open Circuit Voltage)
• Temperature Method
• Neural Networks
• Fuzzy Logics

9. Perturb And Observe:
• In this method the controller adjusts the voltage by a small amount
from the array and measures power, if the power increases, further
adjustments in that direction are tried until power no longer increases.
• This is called the perturb and observe method and is most common,
although this method can result in oscillations of power output.
• It is referred to as a hill climbing method, because it depends on the
rise of the curve of power against voltage below the maximum power
point, and the fall above that point.
• Perturb and observe method may result in top-level efficiency,
provided that a proper predictive and adaptive hill climbing strategy is
adopted.

10. Flow Chart:

11. Incremental Conductance:
• In the incremental conductance method, the controller measures
incremental changes in PV array current and voltage to predict the
effect of a voltage change.
• This method requires more computation in the controller, but can track
changing conditions more rapidly than the perturb and observe method
(P&O). Like the P&O algorithm, it can produce oscillations in power
output.
• This method utilizes the incremental conductance (dI/dV) of the
photovoltaic array to compute the sign of the change in power with
respect to voltage (dP/dV)

12. Incremental Conductance:
• The incremental conductance method is based on the observation that
at the maximum power point dP/dV = 0, and that P = IV.
• The current from the array can be expressed as a function of the
voltage: P = I(V)V.
• Therefore, dP/dV = VdI/dV + I(V). Setting this equal to zero yields:
dI/dV = -I(V)/V. Therefore, the maximum power point is achieved
when the incremental conductance is equal to the negative of the
instantaneous conductance.

13. Flowchart:

14. Current Sweep:
• The current sweep method uses a
sweep waveform for the PV array
current such that the I-V
characteristic of the PV array is
obtained and updated at fixed time
intervals.
• The maximum power point voltage
can then be computed from the
characteristic curve at the same
intervals.
Flowchart:

15. Backward-Forward Current Sweep
Flowchart:

16. Constant Voltage:
• In the "constant voltage" MPPT method (also
known as the "open voltage method"), the
power delivered to the load is momentarily
interrupted and the open-circuit voltage with
zero current is measured.
• The controller then resumes operation with the
voltage controlled at a fixed ratio, such as 0.76,
of the open-circuit voltage VOC.
• This is usually a value which has been
determined to be the maximum power point,
either empirically or based on modelling, for
expected operating conditions.
• The operating point of the PV array is thus kept
near the MPP by regulating the array voltage
and matching it to the fixed reference voltage
Vref=kVOC.
Flowchart:

17. Temperature Method:
• Temperature Method estimates the MPP
voltage by measuring the temperature of the
solar module and comparing it against a
reference.
• Since changes on irradiation levels have little
effect on the maximum power point voltage,
its influences may be neglect and the voltage
can be assumed to only vary linearly with the
temperature.
• Vmpp(T)=Vmpp(Tref)+uvmpp(T-Tref)
Control Characteristics:

18. Neural Networks for MPPT:
Basic Structure: With MPPT:
• Artificial neural networks or connectionist systems are computing systems inspired
by the biological neural networks that constitute animal brains.
• The neural network itself is not an algorithm, but rather a framework for many
different machine learning algorithms to work together and process complex data
inputs.

19. Fuzzy Logics for MPPT:
• Fuzzy logic is a form of many-valued
logic in which the truth values of variables
may be any real number between 0 and 1
inclusive.
• It is employed to handle the concept of
partial truth, where the truth value may
range between completely true and
completely false.
Boolean Fuzzy
AND(x,y) MIN(x,y)
OR(x,y) MAX(x,y)
NOT(x) 1 – x
Operators in Fuzzy:

20. Comparison:

21. Grid Connected PV with MPPT:

22. THANK YOU