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Journal of library and information science in agriculture ›› 2026, Vol. 38 ›› Issue (6): 86-97.doi: 10.13998/j.cnki.issn1002-1248.25-0536

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Optimization of Subversive Technology Identification Model Based on Data Balancing and Integrated Learning

CHEN Yuanyuan1, HU Shaohuang2, CHEN Xiaohong1   

  1. 1. Shanghai Publishing and Media Research Institute, Shanghai Publishing and Printing College, Shanghai 200093
    2. School of Computer Science and Technology, Xinjiang Normal University, Urumqi 830054
  • Received:2025-12-09 Online:2026-06-05 Published:2026-06-17

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Abstract:

[Purpose/Significance] Disruptive technology identification has become an increasingly important research topic in the context of rapid technological evolution and strategic decision-making for governments and enterprises. However, existing data-driven identification approaches often suffer from two critical limitations. First, disruptive technology datasets are typically characterized by severe class imbalance, where truly disruptive cases constitute only a small fraction of the total samples, leading to biased learning and poor generalization. Second, most existing studies rely on a single machine learning model, which limits the ability to capture complex and heterogeneous patterns embedded in high-dimensional technical text features. These issues restrict the robustness, accuracy, and practical applicability of current identification frameworks. To address these challenges, this study aims to construct an optimized disruptive technology identification model that jointly considers data imbalance mitigation and model performance enhancement, thereby improving the reliability and stability of predictive results and contributing to methodological advancements in technology intelligence and innovation management research. [Method/Process] Based on the reproduction of a widely used baseline model built upon XGBoost, this study proposed a two-stage optimization framework integrating data resampling and ensemble learning. In the data preprocessing stage, a hybrid SMOTE-ENN sampling strategy was employed to reconstruct the training dataset. The SMOTE component synthetically generated minority class samples to enhance class representation, while the ENN component removed ambiguous and noisy samples from overlapping regions, thus achieving a balance between noise reduction and information preservation. This strategy effectively alleviated the adverse impact of class imbalance on model learning without excessively distorting the original data distribution. In the modeling stage, a stacking-based ensemble learning framework was constructed by integrating multiple heterogeneous base learners, including XGBoost, LightGBM, Extra Trees, and Support Vector Machines. These base models were selected to capture complementary decision boundaries and feature interactions from different learning perspectives. A Random Forest model was further employed as a meta-learner to aggregate the outputs of the base learners and perform higher-level feature integration. Through this hierarchical learning mechanism, the proposed framework enhanced both representation capability and predictive robustness, enabling more accurate identification of disruptive technologies under complex and noisy data conditions. [Results/Conclusions] Extensive experimental evaluations demonstrate that the proposed optimization model significantly outperforms the baseline XGBoost model across multiple core performance metrics, including Accuracy, Precision, Recall, and F1-Score. Notably, the F1-Score, which is substantially improved from 0.63 to 0.98, indicates a marked enhancement in the model's ability to correctly identify minority disruptive technology samples while maintaining high overall stability. The results confirm that the combined application of hybrid resampling and ensemble learning effectively addresses the challenges of sample imbalance and model bias in disruptive technology identification tasks. In conclusion, the proposed framework provides a robust and scalable solution for identifying disruptive technologies in high-dimensional, imbalanced data scenarios. Beyond improving prediction accuracy, this study offers methodological insights for technical text modeling and innovation analytics. Its approach can be easily adapted to other fields with similar data imbalance and complexity issues. Future research may further explore adaptive sampling strategies and deep learning-based ensemble architectures to enhance temporal and semantic representation capabilities.

Key words: data balance, integrated learning, subversive technology identification, model performance optimization, machine learning

CLC Number: 

  • G305

Fig.1

Experimental framework diagram"

Fig.2

SMOTE-ENN algorithm flow chart"

Fig.3

Stacking frame diagram"

Table 1

Reproduction results of original scheme (threshold is 0.22)"

类别 准确率 精确率 召回率 F1值
0(非颠覆性) 0.80 0.88 0.89 0.89
1(颠覆性) 0.21 0.19 0.20
macro avg 0.55 0.54 0.54
weighted avg 0.80 0.80 0.80

Fig.4

Comparison flow chart of sampling methods"

Table 2

Training results of SMOTE and SMOTE-ENN methods"

方法 准确率 负样本精确率 负样本召回率 负样本F1分数 正样本精确率 正样本召回率 正样本F1分数
原方法 0.63 0.90 0.65 0.76 0.18 0.52 0.26
增加SMOTE 0.85 0.86 0.83 0.85 0.84 0.87 0.85
增加SMOTE-ENN 0.95 0.92 0.96 0.94 0.95 0.95 0.95

Fig.5

Stacking training flow chart"

Fig.6

ROC and PRC curves"

Table 3

Comparison of model training results"

模型 准确率 召回率 精确率 F分数 ROC曲线下面积 P曲线下面积
xgb 0.945 361 0.936 283 0.968 864 0.952 295 0.947 154 0.944 245
lgb 0.952 577 0.953 982 0.964 222 0.959 075 0.952 300 0.946 655
rfb 0.946 392 0.962 832 0.946 087 0.954 386 0.943 144 0.932 572
extra 0.978 351 0.976 991 0.985 714 0.981 333 0.978 619 0.976 436
svm 0.849 485 0.890 265 0.856 899 0.873 264 0.841 429 0.826 786
knn 0.940 206 0.907 965 0.988 439 0.946 494 0.946 575 0.951 076
mlp 0.868 041 0.874 336 0.896 552 0.885 305 0.866 798 0.857 084
cat 0.952 577 0.962 832 0.956 063 0.959 436 0.950 552 0.942 178
stack 0.978 351 0.968 142 0.994 545 0.981 166 0.980 367 0.981 418

Fig.7

Ablation experiment results"

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