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ідея - Financial data analysis - # Bankruptcy prediction

Efficient Missing Data Imputation and AI-Driven Pipeline for Accurate Bankruptcy Prediction


Основні поняття
A novel method for missing data imputation using granular semantics and an AI-driven pipeline to accurately predict bankruptcy in large, high-dimensional, and imbalanced financial datasets.
Анотація

The paper presents a two-stage approach for bankruptcy prediction:

  1. Missing Data Imputation with Granular Semantics:
  • The method leverages the merits of granular computing to form contextual granules around missing values, considering the most semantically relevant features and a small set of reliable observations.
  • This enables efficient imputation within the small granules, without the need to access the entire large dataset repeatedly for each missing value.
  • The granular imputation method is shown to outperform other benchmark imputation techniques, especially with increasing rates of missing data.
  1. AI-Driven Bankruptcy Prediction Pipeline:
  • After filling in the missing values, the pipeline performs feature selection using Random Forest to reduce dimensionality.
  • It then balances the highly imbalanced dataset using the Synthetic Minority Oversampling Technique (SMOTE).
  • Finally, the pipeline tests six different classifiers, including Logistic Regression, Random Forest, and Deep Neural Network, for bankruptcy prediction.
  • The proposed pipeline achieves accuracy around 90% and AUC around 0.8-0.9 across the five-year Polish bankruptcy dataset, demonstrating its effectiveness in handling large, high-dimensional, and imbalanced financial data.
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Статистика
The Polish bankruptcy dataset contains 64 quantitative features and observations from 2007-2013, with significant missing values ranging from 4,666 to 12,157 across the five years.
Цитати
"The merits of granular computing have been explored here to define this method. The missing values have been predicted using the feature semantics and reliable observations in a low-dimensional space, that is, in the granular space." "The granules are formed around every missing entry, considering a few of the highly correlated features to that of the missing value. A small set of the most reliable closest observations is used in granule formation to preserve the relevance and reliability, that is, the context, of the database against the missing entries within those small granules."

Ключові висновки, отримані з

by Debarati Cha... о arxiv.org 04-02-2024

https://arxiv.org/pdf/2404.00013.pdf
Missing Data Imputation With Granular Semantics and AI-driven Pipeline  for Bankruptcy Prediction

Глибші Запити

How can the proposed granular semantics-based imputation method be extended to handle categorical features and mixed data types

The proposed granular semantics-based imputation method can be extended to handle categorical features and mixed data types by incorporating techniques such as one-hot encoding for categorical variables and developing specific rules for handling mixed data types. For categorical features, the method can involve converting them into numerical values using techniques like label encoding or one-hot encoding. This conversion allows the categorical data to be represented in a format that can be utilized in the granular imputation process. When forming granules around missing values, the method can consider the semantics of both numerical and categorical features to predict missing entries accurately. To handle mixed data types, the method can incorporate a preprocessing step that separates the numerical and categorical features. The granular imputation process can then be adapted to consider the semantics of each data type separately while forming granules and predicting missing values. By incorporating specific handling mechanisms for different data types, the method can effectively address the challenges posed by mixed data types in the imputation process.

What are the potential limitations of the granular approach, and how can it be further improved to handle extremely high rates of missing data (e.g., over 50%)

The granular approach, while effective in handling missing data with contextual semantics, may have limitations when dealing with extremely high rates of missing data, such as over 50%. In such cases, the method may face challenges in forming granules with sufficient relevant information due to the large proportion of missing values. To improve the method's capability to handle extremely high rates of missing data, several enhancements can be considered: Adaptive Granule Formation: Develop adaptive strategies to adjust the size and composition of granules based on the extent of missing data. This flexibility can help in capturing relevant information even in data sets with a high percentage of missing values. Ensemble Approaches: Integrate ensemble techniques that combine multiple imputation models to enhance the robustness and accuracy of predictions. By leveraging the strengths of different models, the method can provide more reliable imputations even in scenarios with extensive missing data. Advanced Data Imputation Models: Explore advanced imputation models, such as deep learning-based approaches or probabilistic graphical models, to capture complex relationships and patterns in the data. These models can offer more sophisticated imputation strategies to handle high rates of missing data effectively. By incorporating these enhancements, the granular approach can be further improved to address the challenges associated with extremely high rates of missing data and enhance its performance in such scenarios.

Can the AI-driven bankruptcy prediction pipeline be adapted to other financial risk prediction tasks, such as credit risk assessment or fraud detection, and how would the performance compare to domain-specific solutions

The AI-driven bankruptcy prediction pipeline can be adapted to other financial risk prediction tasks, such as credit risk assessment or fraud detection, with appropriate modifications to the feature selection, data balancing, and model selection components. Feature Selection: Tailor the feature selection process to the specific requirements of credit risk assessment or fraud detection datasets. Identify the most relevant features that contribute to predicting the target variable in these domains. Data Balancing: Adjust the data balancing techniques, such as SMOTE, to address the class imbalance issues specific to credit risk assessment or fraud detection datasets. Ensure that the models are trained on balanced data to improve prediction accuracy. Model Selection: Choose classification models that are well-suited for credit risk assessment or fraud detection tasks, such as logistic regression, decision trees, or ensemble methods. Evaluate the performance of these models in comparison to domain-specific solutions. When adapted to credit risk assessment or fraud detection, the pipeline's performance may vary based on the characteristics of the datasets and the complexity of the prediction tasks. Domain-specific solutions may offer tailored features or algorithms that could outperform the generalized pipeline. However, the AI-driven pipeline provides a versatile framework that can be customized and optimized for different financial risk prediction tasks.
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