Research on Short⁃Term Natural Gas Load Forecasting Based on Wavelet Transform and Deep Learning

doi:10.3969/j.issn.1672-6952.2021.05.016

Abstract

Abstract:

As natural gas accounts for an increasing proportion of energy consumption, how to accurately predict the future natural gas consumption is of great significance to the rational planning of natural gas. For this problem,a short?term natural gas load forecasting model based on wavelet transform and deep learning was proposed. First,the collected natural gas load was decomposed by using different wavelets , and then normalized it.Secondly, the data wes trained and predictd by using the deep learning algorithm Long Short?Term Memory (LSTM); then the predicted data was separately integrated by using wavelet reconstruction.Finally, the average absolute percentage error, average absolute error and root mean square error were used as evaluation indicators to evaluate the prediction results of different wavelets, and the optimal order and number of layers of the optimal wavelet were calculated.The examples show that the 22nd?order 6th layer of Fk wavelet transforms has higher prediction accuracy than other wavelets transforms and direct use of LSTM for prediction.

Key words: Deep learning, LSTM, Wavelet, Orders, Number of layers

摘要：

随着天然气在能源消耗中占比越来越大，如何准确预知未来的天然气消耗量，对天然气资源合理规划具有重大意义。针对此问题，提出一种基于小波变换和深度学习的短期天然气负荷预测模型。首先对所收集的天然气负荷数据利用不同小波变换进行分解，之后对其进行归一化处理；其次利用深度学习算法对数据进行训练与预测；然后利用小波重构对预测的数据分别进行整合；最后以平均绝对百分误差、平均绝对误差和均方根误差为评价指标，评价不同小波变换的预测结果，计算最优小波变换的最优阶数和层数。结果表明，Fk小波变换第22阶第6层相对于其他小波变换和直接利用LSTM进行预测具有更高的预测精度。

关键词: 深度学习, LSTM, 小波, 阶数, 层数

CLC Number:

TE82

Wencai Tian, Weibiao Qiao, Guofeng Zhou, Wei Liu. Research on Short⁃Term Natural Gas Load Forecasting Based on Wavelet Transform and Deep Learning[J]. Journal of Liaoning Petrochemical University, 2021, 41(5): 91-96.

田文才, 乔伟彪, 周国峰, 刘伟. 基于小波变换和深度学习的短期天然气负荷预测研究[J]. 辽宁石油化工大学学报, 2021, 41(5): 91-96.

Figures/Tables 8

References 23

1	Ye Z H， Li Y K， Yan Q. Global natural gas consumption history and energy consumption pattern［M］. De Gruyter， Sydney：ESSE，2017：241⁃246.
2	黄献智，杜书成. 全球天然气和LNG供需贸易现状及展望［J］. 油气储运，2019，38（1）：12⁃19.
3	Jie G， Chen J， Hui S， et al. Current state and prospect of China natural gas industry［J］. China Oil & Gas， 2016， 23（1）：22⁃28.
4	Balitskiy S， Bilan Y， Strielkowski W， et al. Energy efficiency and natural gas consumption in the context of economic development in the European Union［J］. Renewable and Sustainable Energy Reviews， 2016， 55：156⁃168.
5	Fadiran G， Adebusuyi A T， Fadiran D. Natural gas consumption and economic growth： Evidence from selected natural gas vehicle markets in Europe［J］. Energy， 2019， 169：467⁃477.
6	王中元，罗东坤，刘璘璘. 我国城市燃气发展阶段及其主要特征［J］. 油气储运，2016，35（2）：115⁃123.
7	Kumar P， Dhal S， Kumar N. Neural network based forecasting model for natural gas consumption［J］. Communications on Applied Electronics， 2017， 7（11）：1⁃8.
8	Baldacci L， Golfarelli M， Lombardi D， et al. Natural gas consumption forecasting for anomaly detection［J］. Expert Systems with Application， 2016， 62（15）：190⁃201.
9	Furuoka F. Natural gas consumption and economic development in China and Japan： An empirical examination of the Asian context［J］. Renewable & Sustainable Energy Reviews， 2016， 56：100⁃115.
10	Akpinar M， Yumusak N. Day⁃ahead natural gas forecasting using nonseasonal exponential smoothing methods［C］// IEEE International Conference on Environment & Electrical Engineering， Milan：IEEE Press， 2017：1⁃4.
11	Hribar R， Papa G， Silc J. Prediction of natural gas consumption using empirical models［C］// 2017 International Conference on Smart Systems and Technologies （SST）， Osijek： IEEE Press， 2017.
12	Őzmen A， Yilmaz Y， Ozmen， Weber G W， et al. Natural gas consumption forecast with MARS and CMARS models for residential users［J］. Energy Economics， 2018， 70：357⁃381..
13	Sen D， Gunay M E， Tunc K. Forecasting annual natural gas consumptioin using socio⁃economic indicator for making future policies［J］. Energy，2019，173：1106⁃1118.
14	Beyca O F， Ervural B C， Tatoglu E， et al. Using machine learning tools for forecasting natural gas consumption in the province of Istanbul［J］. Energy Economics， 2019， 80：937⁃949.
15	杨梅，李忠，吴昊. 基于多尺度时间特征的LSTM短期负荷预测［EB/OL］.（2020⁃11⁃23）［2020⁃12⁃19］. https：//doi.org/10.14107/j.cnki.kzgc.20200542.
16	余凤，徐晓钟. 基于优化小波BP神经网络的燃气短期负荷预测［J］.计算机仿真. 2015，32（1），372⁃376.
17	乔伟彪，陈保东，卢泓方. 基于混沌理论和Volterra自适应滤波器的天然气负荷预测［J］. 中国科学（技术科学），2015，45（1），91⁃102.
18	Brinks P. Potential⁃analysis of grey energy limits for residential buildings in Germany［J］. Energy and Buildings，2016，127：571⁃579.
19	乔伟彪，陈保东.基于Haar小波变换和ARIMA⁃RBF的天然气时负荷预测［J］.石油化工高等学校学报，2015，28（4）：75⁃80.
20	刘春霞，李军，党伟超，等. 基于遗传算法优化小波神经网络的短期天然气负荷预测［J］. 计算机系统应用，2020，29（4）：175⁃180.
21	涂建维，高经纬，李召，等. 基于长短时记忆网络的结构智能控制算法研究［J］. 华中科技大学学报（自然科学版），2019，47（12）：110⁃115.
22	周帆，赵荣普，杨文镪，等. 长、短期电力负荷大数据下的智能预测实例分析［J］. 电气工程与自动化， 2019，36（6）：27⁃30.
23	罗航，王厚军，龙兵. 基于“松散型”小波神经网络的时间序列预测研究［J］. 计算机工程与应用， 2008， 44（8）： 16⁃19.

预测方法及阶层	MAPE/%	MAE	RMSE
SLSTM直接预测	3.51	181.33	49 906.45
Sym2阶6层	1.60	123.58	21 215.74
Sym3阶6层	1.15	104.08	15 503.20
Sym4阶9层	1.12	104.13	15 602.73
Sym5阶6层	0.89	93.14	12 411.02
Sym6阶6层	0.97	96.24	13 531.50
Sym7阶8层	0.81	87.77	10 510.65
Sym8阶6层	0.90	92.75	12 554.18
Coif1阶9层	1.58	123.14	21 394.27
Coif2阶9层	1.24	108.49	17 131.71
Coif3阶5层	0.99	97.13	14 305.03
Coif4阶6层	1.00	91.67	12 602.55
Coif5阶5层	0.82	88.75	11 819.61
Fk4阶3层	1.76	130.85	24 691.33
Fk6阶6层	1.10	102.25	14 920.89
Fk8阶6层	1.02	98.16	13 402.37
Fk14阶7层	0.77	85.41	10 212.18
Fk18阶6层	0.77	85.46	10 128.55
Fk22阶6层	0.71	82.19	9 222.59

预测方法及阶层	MAPE/%	MAE	RMSE
SLSTM直接预测	3.51	181.33	49 906.45
Sym2阶6层	1.60	123.58	21 215.74
Sym3阶6层	1.15	104.08	15 503.20
Sym4阶9层	1.12	104.13	15 602.73
Sym5阶6层	0.89	93.14	12 411.02
Sym6阶6层	0.97	96.24	13 531.50
Sym7阶8层	0.81	87.77	10 510.65
Sym8阶6层	0.90	92.75	12 554.18
Coif1阶9层	1.58	123.14	21 394.27
Coif2阶9层	1.24	108.49	17 131.71
Coif3阶5层	0.99	97.13	14 305.03
Coif4阶6层	1.00	91.67	12 602.55
Coif5阶5层	0.82	88.75	11 819.61
Fk4阶3层	1.76	130.85	24 691.33
Fk6阶6层	1.10	102.25	14 920.89
Fk8阶6层	1.02	98.16	13 402.37
Fk14阶7层	0.77	85.41	10 212.18
Fk18阶6层	0.77	85.46	10 128.55
Fk22阶6层	0.71	82.19	9 222.59

小波类型及阶层	MAPE/%	MAE	RMSE
直接预测误差	6.28	149.04	31 782.80
Sym 8阶5层	1.14	71.25	6 615.22
Coif 5阶6层	1.35	69.92	6 210.37
Fk 22阶6层	1.13	64.48	5 301.71

小波类型及阶层	MAPE/%	MAE	RMSE
直接预测误差	6.28	149.04	31 782.80
Sym 8阶5层	1.14	71.25	6 615.22
Coif 5阶6层	1.35	69.92	6 210.37
Fk 22阶6层	1.13	64.48	5 301.71

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