Research on Multi-process Product Quality Prediction Based on Improved BiLSTM

doi:10.16182/j.issn1004731x.joss.23-FZ0805

Abstract

Abstract:

In response to the complex manufacturing process of multi-process products, a multi-process product quality prediction model based on the kernel principal component analysis (KPCA)- and improved sparrow search algorithm (ISSA) optimized bi-directional long short-term memory (BiLSTM) was proposed to address the uncertain factors that affect product quality, while improving the capacity for each process and ensuring the stability, in multi-process production. Firstly, KPCA was used for data preprocessing, and a kernel function was established on the basis of principal component analysis together with kernel methods. As redundant features were removed through dimension reduction, an improved Gaussian mutation and the uniform mutation operator η were introduced to improve the sparrow search algorithm. Secondly, the ISSA was introduced into the BiLSTM, and the dimensionality reduced data were imported into the ISSA-BiLSTM model to achieve the quality prediction of multi-process products. Finally, the TFT-LCD manufacturing process was analyzed as an example and compared with the existing methods. The experimental results show that the prediction model has a high prediction accuracy, with the root mean square error less than 10%, effectively improving the accuracy of multi-process product quality prediction.

Key words: multi-process production, quality prediction, kernel principal component analysis (KPCA), improved sparrow search algorithm (ISSA), bi-directional long short-term memory (BiLSTM)

CLC Number:

TP391.9

Zhang Tianrui, Liu Yuting, Wang Yike. Research on Multi-process Product Quality Prediction Based on Improved BiLSTM[J]. Journal of System Simulation, 2023, 35(11): 2321-2332.

Figures/Tables 19

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Table 1

Parameter setting

参数名称	参数数值
$i t e r m a x$ 迭代最大次数	200
种群数量	30
搜索维度	[-5，5]
发现者比例	0.2
安全阙值	0.8
BiLSTM输入层节点数	5
BiLSTM隐含层节点数	11
BiLSTM输出层节点数	1

Table 1

Table 2

Fig. 6

Fig. 7

Fig. 8

Fig. 9

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Fig. 13

Fig. 14

Table 3

Comparison of experimental errors

模型	RMSE	MAE	MAPE	$R 2$	NSE	t/s
ISSA-BiLSTM	0.008 031 7	0.006 451 1	0.002 276 4	0.998 39	0.998 28	89.76
SSA-BiLSTM	0.040 674	0.034 72	0.012 15	0.956 29	0.955 98	124.54
BiLSTM	0.076 886	0.064 401	0.022 63	0.842 74	0.842 7	165.49

Table 3

Fig. 15

Table 4

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ID编号	TOOL-ID	210T1	210T2	210T3	…	750T1451	750T1452	Y
1	N	102.05	0.465	0.27	…	0.000 72	2.40E+12	2.945 08
2	M	100.95	0.805	0.22	…	0.000 72	2.40E+12	2.955 09
3	L	98.56	0.555	0.24	…	0.000 64	2.40E+12	2.741 26
4	M	100.35	0.901	0.22	…	0.000 72	2.40E+12	2.799 34
5	M	100.25	0.854	0.23	…	0.000 72	2.40E+12	2.692 09

模型	t/s	准确率/%
ISSA-BiLSTM	89.76	99.658
SSA-BiLSTM	124.54	96.841
BiLSTM	165.49	91.056
LSTM	174.32	87.459
SVM	210.81	81.734
RBF	185.19	86.791
BP	254.29	64.752

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