Program synthesis using inputs and outputs is a fundamental problem in computer science. Towards that end, we present a framework, called NetSyn, that synthesizes programs using an evolutionary algorithm. NetSyn makes several novel contributions. First, NetSyn uses neural networks as a fitness function. This addresses the principal challenge of evolutionary algorithm: how to design the most effective fitness function. Second, NetSyn combines an evolutionary algorithm with neighborhood search to expedite the convergence process. Third, NetSyn can support a variety of neural network fitness functions uniformly. We evaluated NetSyn to generate programs in a list-based domain specific language. We compared the proposed approach against a state-of-the-art approach to show that NetSyn performs better in synthesizing programs.

Classical anomaly detection is principally concerned with point-based anomalies, those anomalies that occur at a single point in time. Yet, many real-world anomalies are range-based, meaning they occur over a period of time. Motivated by this observation, we present a new mathematical model to evaluate the accuracy of time series classification algorithms. Our model expands the well-known Precision and Recall metrics to measure ranges, while simultaneously enabling customization support for domain-specific preferences.

Classical anomaly detection is principally concerned with point-based anomalies, those anomalies that occur at a single point in time. Yet, many real-world anomalies are range-based, meaning they occur over a period of time. Motivated by this observation, we present a new mathematical model to evaluate the accuracy of time series classification algorithms. Our model expands the well-known Precision and Recall metrics to measure ranges, while simultaneously enabling customization support for domain-specific preferences.

Classical anomaly detection is principally concerned with point-based anomalies, those anomalies that occur at a single point in time. Yet, many real-world anomalies are range-based, meaning they occur over a period of time. Motivated by this observation, we present a new mathematical model to evaluate the accuracy of time series classification algorithms. Our model expands the well-known Precision and Recall metrics to measure ranges, while simultaneously enabling customization support for domain-specific preferences.