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This study explores realistic image transformations for testing autonomous vehicle deep neural networks (DNNs). Findings reveal how these transformations impact neuron coverage and model output, crucial for enhancing DNN reliability and trust.

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Area of Science:

  • Artificial Intelligence
  • Computer Vision
  • Software Engineering

Background:

  • Deep Neural Networks (DNNs) in autonomous vehicles operate as complex "black boxes," necessitating methods to ensure their reliability and trustworthiness.
  • Traditional software testing techniques are being adapted for DNNs, with neuron coverage proposed as a key metric for evaluating test suite effectiveness in detecting failures.

Purpose of the Study:

  • To investigate the impact of realistic image transformations on neuron coverage for autonomous vehicle DNNs.
  • To assess how these transformations affect the output of trained autonomous vehicle DNNs.
  • To contribute to methods for increasing the reliability and trust in DNN models.

Main Methods:

  • Utilized realistic image transformations to generate novel datasets for testing.
  • Applied these transformations to a trained autonomous vehicle DNN.
  • Measured the resulting neuron coverage and analyzed changes in model output.

Main Results:

  • Realistic image transformations significantly alter neuron coverage metrics.
  • The chosen transformations demonstrably impact the classification or prediction outputs of the DNN.
  • Neuron coverage levels varied depending on the specific image transformation applied.

Conclusions:

  • Realistic transformations are valuable for uncovering potential failures in autonomous vehicle DNNs.
  • The study provides insights into the sensitivity of DNNs to input variations.
  • Findings support the use of input transformation-based testing to improve DNN robustness and reliability.