Improving Semiconductor Device Modeling for Electronic Design Automation by Machine Learning Techniques

Wang, Zeheng; Li, Liang; Leon, Ross C. C.; Yang, Jinlin; Shi, Junjie; van der Laan, Timothy; Usman, Muhammad

doi:10.1109/ted.2023.3307051

Cited by 6 publications

(4 citation statements)

References 29 publications

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“…When a recognizable pattern emerges in the encoded data, VAE has the capability to generate new, synthetic data by sampling from this latent pattern [26]. The efficacy of VAE in augmenting small-scale datasets has been previously demonstrated in the realm of electronics, where it is evident that using VAE was to augment data of semiconductor devices can improve the performance of ML-based modeling [27].…”

Section: Methodsmentioning

confidence: 99%

Advancing Precision Medicine: VAE Enhanced Predictions of Pancreatic Cancer Patient Survival in Local Hospital

Wang,

Li,

Wang

2024

IEEE Access

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In this research, we address the urgent need for accurate prediction of in-hospital survival periods for patients diagnosed with pancreatic cancer (PC), a disease notorious for its late-stage diagnosis and dismal survival rates. Utilizing machine learning (ML) technologies, we focus on the application of Variational Autoencoders (VAE) for data augmentation and ensemble learning techniques for enhancing predictive accuracy. Our dataset comprises biochemical blood test (BBT) results from stage II/III PC patients, which is limited in size, making VAE's capability for data augmentation particularly valuable. The study employs several ML models, including Elastic Net (EN), Decision Trees (DT), and Radial Basis Function Support Vector Machine (RBF-SVM), and evaluates their performance using metrics such as Mean Absolute Error (MAE) and Mean Squared Error (MSE). Our findings reveal that EN, DT, and RBF-SVM are the most effective models within a VAE-augmented framework, showing substantial improvements in predictive accuracy. An ensemble learning approach further optimized the results, reducing the MAE to approximately 10 days. These advancements hold significant implications for the field of precision medicine, enabling more targeted therapeutic interventions and optimizing healthcare resource allocation. The study can also serve as a foundational step towards more personalized and effective healthcare solutions for PC patients.

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Section: Methodsmentioning

confidence: 99%

Advancing Precision Medicine: VAE Enhanced Predictions of Pancreatic Cancer Patient Survival in Local Hospital

Wang,

Li,

Wang

2024

IEEE Access

Self Cite

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“…In the context of this study, the exploration of alternative methodologies may provide avenues for further investigation. Techniques such as transfer learning [29], data augmentation [20,30], and synthetic data generation [31] could potentially be employed to leverage existing data and knowledge for new tasks. Transfer learning, for instance, allows a model trained on one task to be adapted for a second related task, potentially mitigating the need for extensive data in the target domain.…”

Section: Plos Onementioning

confidence: 99%

“…If basic AI models prove inadequate for the task, it would be prudent to exercise caution in relying solely on them. Such shortcomings warrant a deeper investigation into the root causes and may necessitate the development of innovative solutions, such as generative models [15,19,20], transfer learning [21,22], or the use of large language models [23].…”

Section: Introductionmentioning

confidence: 99%

Suboptimal capability of individual machine learning algorithms in modeling small-scale imbalanced clinical data of local hospital

Li,

Wang

et al. 2024

PLoS ONE

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In recent years, artificial intelligence (AI) has shown promising applications in various scientific domains, including biochemical analysis research. However, the effectiveness of AI in modeling small-scale, imbalanced datasets remains an open question in such fields. This study explores the capabilities of eight basic AI algorithms, including ridge regression, logistic regression, random forest regression, and others, in modeling a small, imbalanced clinical dataset (total n = 387, class 0 = 27, class 1 = 360) related to the records of the biochemical blood tests from the patients with multiple wasp stings (MWS). Through rigorous evaluation using k-fold cross-validation and comprehensive scoring, we found that none of the models could effectively model the data. Even after fine-tuning the hyperparameters of the best-performing models, the results remained below acceptable thresholds. The study highlights the challenges of applying AI to small-scale datasets with imbalanced groups in biochemical or clinical research and emphasizes the need for novel algorithms tailored to small-scale data. The findings also call for further exploration into techniques such as transfer learning and data augmentation, and they underline the importance of understanding the minimum dataset scale required for effective AI modeling in biochemical contexts.

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“…Recently, data-based quality management techniques have been applied in various cases, and their utility continues to rise. Among these techniques, machine learning is the most popular approach in fields such as design automation [14], semiconductor analysis [15] and modeling [16]. Especially for classifications, machine learning can be a reliable and scalable solution.…”

Section: Introductionmentioning

confidence: 99%

Classification of LED Packages for Quality Control by Discriminant Analysis, Neural Network and Decision Tree

Shim,

Kim

2024

Micromachines

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This study investigates supervised learning to improve LED classification. A hardware system for testing was built. The data for learning were acquired and then analyzed to show their characteristics. An LED was tested, and the results were categorized into three defective LED groups and one normal LED group. Before classification, electrical and optical data were examined to identify their characteristics. To find out the best way for quality control, an ensemble of methods was used. First, the discriminant analysis using the validation data achieved a 77.9% true positive rate for normal products, inadequate for quality control. Second, neural network-based learning boosted this rate to 97.8%, but the 2.2% false negative rate remained problematic. Finally, a binary decision tree was constructed, achieving a 99.4% true positive rate from just 14 splits, proving highly effective in product classification. The training time was measured as 8.1, 18.2 and 8.2 s for discriminant analysis, neural network and decision tree, respectively. This work has found the binary decision tree is advantageous considering both learning and classification efficiencies.

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Improving Semiconductor Device Modeling for Electronic Design Automation by Machine Learning Techniques

Cited by 6 publications

References 29 publications

Advancing Precision Medicine: VAE Enhanced Predictions of Pancreatic Cancer Patient Survival in Local Hospital

Advancing Precision Medicine: VAE Enhanced Predictions of Pancreatic Cancer Patient Survival in Local Hospital

Suboptimal capability of individual machine learning algorithms in modeling small-scale imbalanced clinical data of local hospital

Classification of LED Packages for Quality Control by Discriminant Analysis, Neural Network and Decision Tree

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