OVERVIEW & MODEL
Study of anomaly registration detection based on multilayer kernel autoencoder extreme learning machine model
The deep integration of artificial intelligence (AI) and health informatics has driven the digital transformation of hospital services, but improper registration practices (scalpers) exacerbate the uneven allocation of appointment resources. The paper proposes an integrated machine learning algorithm DKELM-PSS for advanced feature mining of high-dimensional massive health information system (HIS) data in hospital to enable detection of anomalous registration behavior. First, Sparse Principal Component Analysis (Sparse PCA) is employed to preprocess the raw data, thereby performing data denoising and dimensionality reduction. Then, the deep kernel extreme learning machine model (DKELM) is constructed for deep feature extraction by stacking multiple kernel self-coders (KELM-AE) for multilayer forward coding. Kernel-based mappings in the hidden space enhance the linear separability of the raw data in high-dimensional feature space. Unsupervised extraction of deep features by autoencoder structure for advanced feature representation learning. The optimal parameter configuration of DKELM is realized by Salp Swarm Algorithm (SSA) to improve the classification accuracy and model stability. Compared with traditional detection methods such as SVM-RBF, XGBoost, and ResNet, experimental results validate that DKELM-PSS attains the optimal accuracy of 0.9942 on HIS anomaly detection, corroborating its effectiveness and robustness. The paper proposes an efficient anomaly detection method, which is conducive to optimizing the allocation of medical resources and promoting the intelligent development of hospitals.
Executive Impact & Core Findings
This research introduces DKELM-PSS, an advanced AI model for detecting anomalous registration behavior in hospital systems. By leveraging Sparse PCA for data preprocessing and a deep kernel extreme learning machine optimized with Salp Swarm Algorithm, the model achieves superior accuracy (0.9942) compared to traditional methods. This translates to optimized resource allocation, improved patient experience, and enhanced operational efficiency for healthcare providers facing 'scalper' issues.
Key Metrics
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Anomaly Detection Accuracy
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Feature Extraction Efficiency
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Computational Resource Savings
Deep Analysis & Enterprise Applications
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Overview & Model
Data Preprocessing
Performance Analysis
The core of this study is the DKELM-PSS model, an integrated machine learning algorithm designed to detect anomalous registration behavior in hospital information systems. It combines deep learning with optimization techniques for robust performance.
DKELM (Deep Kernel Extreme Learning Machine) is constructed for deep feature extraction using stacked kernel self-coders (KELM-AE). This enhances linear separability in high-dimensional feature space.
The model leverages Salp Swarm Algorithm (SSA) for optimal parameter configuration, improving classification accuracy and model stability. This meta-heuristic approach fine-tunes the DKELM's performance effectively.
Sparse PCA is employed to preprocess raw data, performing denoising and dimensionality reduction. This crucial step improves the efficiency of feature extraction and offers more precise feature representation for identifying anomalous registration behavior.
By effectively controlling noise and redundancy, Sparse PCA enhances the data mining algorithm's ability to accurately identify potential fraudulent behaviors, guaranteeing the effectiveness and credibility of the intelligent monitoring system.
Experimental results demonstrate that DKELM-PSS achieves an optimal accuracy of 0.9942 on HIS anomaly detection, corroborating its effectiveness and robustness. This superior performance is validated against traditional methods such as SVM-RBF, XGBoost, and ResNet.
The integration of Sparse PCA significantly improves all performance metrics, including accuracy, precision, recall, and F1-score, by providing a cleaner, more discriminative representation of the input data.
Enterprise Process Flow
HPR Data Collection
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Data Cleaning
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Sparse PCA for Dimensionality Reduction
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Training/Testing Split
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DKELM Model Construction
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SSA Optimization
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Anomaly Detection Results
99.42%
Achieved Anomaly Detection Accuracy with DKELM-PSS
| Model | Accuracy | Precision | Recall | F1-score |
|---|---|---|---|---|
| DKELM-PSS | 0.9942 | 0.9708 | 0.9815 | 0.9761 |
| KELM | 0.9854 | 0.9249 | 0.9557 | 0.9402 |
| XGBoost | 0.9823 | 0.9081 | 0.9484 | 0.9277 |
| GoogLeNet | 0.9810 | 0.9071 | 0.9372 | 0.9219 |
Impact on Hospital Operations
The deployment of DKELM-PSS offers significant benefits to hospital operations, primarily by optimizing medical resource allocation. By accurately identifying anomalous registrations ('scalpers'), hospitals can ensure that genuine patients have fair access to appointments, reducing wait times and improving overall patient satisfaction.
This system helps in reducing operational overhead by automating the detection of fraudulent activities, which traditionally required manual review. The high accuracy of the model minimizes false positives and negatives, making the detection process highly reliable and efficient.
Ultimately, DKELM-PSS contributes to a more intelligent and fair healthcare ecosystem, aligning with the goals of digital transformation in healthcare. It allows hospital administrators to make data-driven decisions to combat improper practices and enhance service delivery.
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