Photovoltaic output prediction based on multi-convolutional combined large model

doi:10.3969/j.issn.2097-0706.2025.04.005

Abstract

Abstract:

To address the issue of low accuracy in photovoltaic output prediction， a multi-convolutional combined large model is proposed， integrating triple convolutional neural networks（TCNNs）， a weighted fully-connected regression network（WFRN），and improved bidirectional encoder representations from transformers（IBERT）. The TCNNs employed convolutional kernels of multiple sizes to efficiently extract feature information from photovoltaic data， progressing from shallow to deep layers. The weighted fully-connected regression network（WFRN） optimized the weight coefficients of the prediction outputs from two deep neural networks using particle swarm optimization algorithm， thereby enhancing prediction accuracy. The prediction results from TCNNs and WFRN were integrated and input into the IBERT for training. The attention mechanism of IBERT was then employed to perform interpretable feature analysis， determining the final photovoltaic output prediction value. The TCNNs-WFRN-IBERT model was applied to predict the hourly photovoltaic output power for the next day in Natal， Brazil. Simulation tests were conducted using actual photovoltaic output and meteorological data， and the results were compared with those of 38 algorithms. The results showed that the mean absolute error（MAE）， mean squared error（MSE）， and root mean squared error（RMSE） of the TCNNs-WFRN-IBERT model were 22.61 W， 1 818.20 W² and 42.64 W， respectively. Compared with other models， the evaluation metrics of TCNNs-WFRN-IBERT were lower than those of the other models， with its MAE value being at least 2.71% smaller than those of the other 38 comparative models， validating the effectiveness of the proposed model.

Key words: triple convolutional neural network, weighted fully connected regression network, improved model of bidirectional encoder representation from transformers, photovoltaic output prediction, multi-convolutional combined large model, attention mechanism

CLC Number:

TK11：TP399

YIN Linfei, ZHANG Yiling. Photovoltaic output prediction based on multi-convolutional combined large model[J]. Integrated Intelligent Energy, 2025, 47(4): 63-72.

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参数	数值
训练的最大迭代次数	50
小批量大小	100
初始学习率	0.01
梯度阈值	1
硬件环境	CPU
求解器	Adam

模型名称	MAE/W	MSE/W²	RMSE/W	运行时间/s
AlexNet	247.94	194 908.19	441.48	456.31
DarkNet19	158.28	79 600.30	282.13	1 689.57
DarkNet53	102.94	41 210.35	203.00	4 055.35
DenseNet201	174.40	94 239.47	306.98	5 760.14
EffiientNetb0	164.36	85 189.21	291.87	3 093.61
GoogLeNet	100.89	38 372.87	195.89	1 120.91
InceptionV3	83.55	30 628.82	175.01	2 844.36
ResNet18	73.29	21 711.45	147.35	1 164.01
ResNet50	94.87	35 622.48	188.74	3 280.85
ResNet101	93.72	34 791.92	186.53	5 263.96
Xception	141.03	66 242.63	257.38	6 143.48
MobileNetV2	149.72	72 703.32	269.64	2 519.27
NasNetLarge	84.94	29 344.34	171.30	27 451.94
ShuffleNet	155.23	84 872.51	291.33	1 241.64
SqueezeNet	134.37	69 619.88	263.86	498.21
VGG16	83.59	20 866.79	144.45	6 107.52
VGG19	296.71	256 899.42	506.85	91 851.62
Lasso回归	120.13	21 716.37	147.37	0.10
极限梯度提升	64.23	10 810.16	103.97	0.00
ε-支持向量回归	143.34	41 313.54	203.26	2.41
极度随机树回归	58.35	10 083.66	100.42	2.18
自动相关确定	119.43	21 497.23	146.62	0.07
堆叠泛化回归	56.36	24 741.26	157.29	0.90
自适应提升回归	272.40	80 089.26	283.01	1.65
泰尔-森估算回归	129.53	25 046.19	158.26	2.40
随机梯度下降回归	121.75	22 925.57	151.41	0.03
留一交叉验证岭回归	120.05	21 625.31	147.06	0.03
LSTM	134.66	53 872.48	232.10	15.44
Huber回归	140.21	35 503.58	179.23	0.18
贝叶斯岭回归	120.46	21 728.48	147.41	0.01
决策树回归	78.90	22 169.43	148.89	0.09
梯度提升回归	83.15	16 546.94	116.39	2.17
核岭回归	119.28	21 991.92	153.65	2.19
最小角回归	219.83	70 522.80	265.56	0.01
投票回归	83.76	14 088.76	118.70	8.95
Inception-ResNet-V2	166.25	86 644.95	294.36	5 045.47
VMD-TCNNs	49.05	7 403.94	86.05	0.41
WFRN	23.24	2 002.60	44.75	90.89
TCNNs-WFRN-IBERT	22.61	1 818.20	42.64	4.18

丢弃概率	MAE/W	MSE/W²	RMSE/W
0.10	49.59	6 739.62	82.10
0.15	49.75	9 190.44	95.87
0.20	31.69	4 286.61	65.47
0.25	31.64	4 277.12	65.40
0.30	22.61	1 818.20	42.64
0.35	32.04	3 179.08	56.38
0.40	29.61	2 707.83	73.95
0.45	45.71	5 468.10	87.35
0.50	55.46	9 072.08	95.25