Multi-Feature Data Fusion-Based Load Forecasting of Electric Vehicle Charging Stations Using a Deep Learning Model
Abstract
:1. Introduction
2. System Modelling
2.1. LSTM Model
Algorithm 1 LSTM deep learning classification |
1. Start Operation Sort each trip according to data on temperature, humidity, and wind speed, then assign a certain forecasting network to each cluster. Input: Temperature, humidity, wind speed. Target: Centroid of Clusters 2. Match each input sample of temperature, humidity, and wind speed to its cluster using a deep LSTM network with the aim being the centroid of each cluster. 3. End operation |
2.2. Data Fusion Method
Algorithm 2 The Proposed D-S Theory Algorithm Pseudocode |
input: Frames of Discernment U = {A,B,C} output: Optimal Result 1: n = length (U) 2: function MassFunction(U) 3: 2U= {all subnets of U} 4: X = ∀2U 5: if ∑m(X) = 1 then m: 2U→ [0, 1] 6: end if 7: return m(2U) 8: end function 9: 10: function SynthesisRule(X = ∀2U, m1(X), m2(X)) 11: SynthesisMass = 0 12: K = 0 13: A = ∀2U 14: B = ∀2U 15: if A ∩ B = ∅ then 16: K = K + m1(A) ∗ m2(B) 17: end if 18: if A ∩ B = X then 19: SynthesisMass = SynthesisMass + m1(A) ∗ m2(B) 20: end if 21: SynthesisMass = SynthesisMass/(1 − K) 22: return SynthesisMass 23: end function 24: 25: function ConfidenceInterval (X = ∀2U) 26: A = ∀2U 27: Bel(X) = 0 28: Pls(X) = 0 29: if A ∈ X then 30: Bel(X) = Bel(X) + m(A) 31: else 32: Pls(X) = Pls(X) + m(A) 33: end if 34: Pls(X) = 1 − Pls(X) 35: CI(X) = [Bel(X), Pls(X)] 36: return CI(X) 37: end function |
3. System Implementation
- (1) represents the sample load data of the last moment and the parameters of that moment used to predict the current load.
- (2) represents the sample load data of the last moment and the parameters of the current moment used to predict the current load.
- (3) represents the sample load data of the last several moments and the corresponding parameters of the last several moments used to predict the current load.
4. Simulation Results and Discussion
5. Conclusions
Author Contributions
Funding
Acknowledgments
Conflicts of Interest
References
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D-S Theory | Probability Theory |
---|---|
m(U) does not have to equal 1 | |
If , m(X) ≤ m(Y) is not necessary | If , P(X) ≤ P(Y) is necessary |
there is no relation between m(X) and m(−X) | P(X) + P(¬X) = 1 |
30% | 26% | 44% | |
---|---|---|---|
31% | 9.3% | 8.06% | 13.64% |
34% | 10.2% | 8.84% | 14.95% |
35% | 10.5% | 9.1% | 15.4% |
9.3% | 8.84% | 15.4% | 18.26% | 24.14% | 24.05% | |
---|---|---|---|---|---|---|
24% | 2.23% | 2.12% | 3.70% | 4.38% | 5.79% | 5.77% |
41% | 3.81% | 3.62% | 6.31% | 7.49% | 9.90% | 9.86% |
35% | 3.26% | 3.09% | 5.39% | 6.39% | 8.45% | 8.42% |
2.23% | 3.63% | 5.39% | 17.80% | 21.20% | 27.68% | 22.06% |
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Aduama, P.; Zhang, Z.; Al-Sumaiti, A.S. Multi-Feature Data Fusion-Based Load Forecasting of Electric Vehicle Charging Stations Using a Deep Learning Model. Energies 2023, 16, 1309. https://doi.org/10.3390/en16031309
Aduama P, Zhang Z, Al-Sumaiti AS. Multi-Feature Data Fusion-Based Load Forecasting of Electric Vehicle Charging Stations Using a Deep Learning Model. Energies. 2023; 16(3):1309. https://doi.org/10.3390/en16031309
Chicago/Turabian StyleAduama, Prince, Zhibo Zhang, and Ameena S. Al-Sumaiti. 2023. "Multi-Feature Data Fusion-Based Load Forecasting of Electric Vehicle Charging Stations Using a Deep Learning Model" Energies 16, no. 3: 1309. https://doi.org/10.3390/en16031309
APA StyleAduama, P., Zhang, Z., & Al-Sumaiti, A. S. (2023). Multi-Feature Data Fusion-Based Load Forecasting of Electric Vehicle Charging Stations Using a Deep Learning Model. Energies, 16(3), 1309. https://doi.org/10.3390/en16031309