A Novel Module Independent Straight Line-Based Fast Maximum Power Point Tracking Algorithm for Photovoltaic Systems
Abstract
:1. Introduction
- (i)
- Number of iterations in reaching the MPP s are way less than conventional MPPT algorithm
- (ii)
- Reduction of oscillations around the MPP is much better than conventional, less than
- (iii)
- Module independence, therefore the algorithm can be used in any PV modules without knowing the module data
- (iv)
- Highly efficient and easily implementable
2. Development of Proposed Algorithm and Description of the P&O
2.1. Development of the Proposed Algorithm
- At first, it senses voltage and by voltage and current sensors, respectively, and measured the power, . Then the voltage is perturbed by a small amount, b and another voltage, , is taken. The the power, is measured.
- If P = , the operating point is at the left of MPP, else the operating point is at the right of the MPP.
- Afterwards, the algorithm perturbs the voltage by a bigger step size c and senses the new voltage, followed by a small perturbation b. Then it measures voltage and calculates .
- If , the desired four points (, ), (, ) and (, ), (, ) are found to draw the two straight lines. The algorithm will find then the intersecting point by solving the equations. The intersecting point should be close to the MPP. If , step 3 needs to be repeated until is fulfilled.
- The point is not the desired MPP, rather it is very close to MPP. To track the MPP, the algorithm will perturb the voltage by a small amount b and calculate P again.
- If , the operating point is at the right side of MPP, else the operating point is at the left side of the MPP.
- If the operating point lies at the left side of MPP (), the algorithm will keep on perturbing the voltage by a small amount ‘b’ until is satisfied. Once it reaches to that condition, the algorithm stops and will be the desired MPP. However, if it starts from the right side of MPP (), the algorithm will then keep on perturbing the voltage by a small amount ‘b’ to the left side. Once is satisfied, the algorithm stops and is the desired MPP.
2.1.1. Mathematical Model of the Proposed Algorithm
2.1.2. Response of the Proposed Algorithm When Irradiance Increases Rapidly
2.2. The Conventional P&O Algorithm
3. Simulation Results Using the Proposed Algorithm
3.1. Simulation Results under Normal and Rapid Weather Conditions
3.2. Comparison of the Proposed Algorithm with Conventional Perturb and Observe Algorithm
3.3. Comparison between Proposed and Perturb and Observe Algorithm in Terms of Duty and Maximum Power Point
3.4. Validation of the Proposed MPPT Algorithm
4. Conclusions
Author Contributions
Funding
Conflicts of Interest
References
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Maximum Power () | 150 W |
---|---|
Voltage at | V |
Current at | A |
Open Circuit Voltage | V |
Short Circuit Current | A |
P&O (Step Size = 0.1) | Proposed (Step Size = 2, 0.1) | Exact Value | |
---|---|---|---|
MPP Voltage | 34.6 | 34.5346 | 34.5 |
MPP Power | 149.9709 | 149.9825 | 149.9858 |
Intersection Voltage | NA | 32.2346 | NA |
NA | 15 | NA | |
NA | 22 | NA | |
Total of iterations | 296 | 37 | NA |
P&O (Step Size = 0.1) | Proposed (Step Size = 2, 0.1) | Exact Value | |
---|---|---|---|
MPP Voltage | 34.6 | 34.3498 | 34.5 |
MPP Power | 149.9709 | 149.9784 | 149.9858 |
Intersection Voltage | NA | 32.2346 | NA |
NA | 3 | NA | |
NA | 29 | NA | |
Total of iterations | 54 | 32 | NA |
G and T (kW/m, C) | ||||||
---|---|---|---|---|---|---|
(0.3, 0) | 0.3177 | 0.3201 | 0.3100 | 46.8442 | 46.8059 | 46.4333 |
(0.3, 10) | 0.3228 | 0.3200 | 0.3100 | 44.8187 | 44.7739 | 43.8932 |
(0.3, 20) | 0.3275 | 0.3280 | 0.3310 | 42.7801 | 42.7802 | 42.7203 |
(0.5, 0) | 0.3725 | 0.3720 | 0.3730 | 80.4209 | 80.4200 | 80.4165 |
(0.5, 10) | 0.3774 | 0.3780 | 0.3790 | 77.1584 | 77.1546 | 77.1326 |
(0.5, 20) | 0.3824 | 0.3820 | 0.3790 | 73.8728 | 73.8702 | 73.7657 |
(0.8, 10) | 0.4314 | 0.4320 | 0.4270 | 126.4301 | 126.4219 | 126.1785 |
(0.8, 20) | 0.4367 | 0.4350 | 0.4390 | 121.3375 | 121.3139 | 121.2492 |
(0.8, 30) | 0.4415 | 0.4420 | 0.4390 | 116.2146 | 116.2139 | 116.1323 |
(1.0, 20) | 0.4627 | 0.4620 | 0.4630 | 153.1360 | 153.1256 | 153.1357 |
(1.0, 30) | 0.4683 | 0.4680 | 0.4690 | 146.8280 | 146.8288 | 146.8160 |
(1.0, 40) | 0.4734 | 0.4720 | 0.4750 | 140.4862 | 140.4611 | 140.4538 |
(1.2, 20) | 0.4848 | 0.4850 | 0.4870 | 184.8904 | 184.8890 | 184.7909 |
(1.2, 30) | 0.4897 | 0.4890 | 0.4870 | 177.4167 | 177.4042 | 177.2795 |
(1.2,40) | 0.4948 | 0.4950 | 0.4990 | 169.9001 | 169.9017 | 169.6730 |
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Debnath, A.; Olowu, T.O.; Parvez, I.; Dastgir, M.G.; Sarwat, A. A Novel Module Independent Straight Line-Based Fast Maximum Power Point Tracking Algorithm for Photovoltaic Systems. Energies 2020, 13, 3233. https://doi.org/10.3390/en13123233
Debnath A, Olowu TO, Parvez I, Dastgir MG, Sarwat A. A Novel Module Independent Straight Line-Based Fast Maximum Power Point Tracking Algorithm for Photovoltaic Systems. Energies. 2020; 13(12):3233. https://doi.org/10.3390/en13123233
Chicago/Turabian StyleDebnath, Anjan, Temitayo O. Olowu, Imtiaz Parvez, Md Golam Dastgir, and Arif Sarwat. 2020. "A Novel Module Independent Straight Line-Based Fast Maximum Power Point Tracking Algorithm for Photovoltaic Systems" Energies 13, no. 12: 3233. https://doi.org/10.3390/en13123233
APA StyleDebnath, A., Olowu, T. O., Parvez, I., Dastgir, M. G., & Sarwat, A. (2020). A Novel Module Independent Straight Line-Based Fast Maximum Power Point Tracking Algorithm for Photovoltaic Systems. Energies, 13(12), 3233. https://doi.org/10.3390/en13123233