Deep Learning Based Models for Cognitive Autonomy and Cybersecurity Intelligence in Autonomous Systems

Ganapathy Mani (8840606)

21 June 2022

Cognitive autonomy of an autonomous system depends on its cyber module's ability to comprehend the actions and intent of the applications and services running on that system. The autonomous system should be able to accomplish this without or with limited human intervention. These mission-critical autonomous systems are often deployed in unpredictable and dynamic environments and are vulnerable to evasive cyberattacks. In particular, some of these cyberattacks are Advanced Persistent Threats where an attacker conducts reconnaissance for a long period time to ascertain system features, learn system defenses, and adapt to successfully execute the attack while evading detection. Thus an autonomous system's cognitive autonomy and cybersecurity intelligence depend on its capability to learn, classify applications (good and bad), predict the attacker's next steps, and remain operational to carryout the mission-critical tasks even under cyberattacks. In this dissertation, we propose novel learning and prediction models for enhancing cognitive autonomy and cybersecurity in autonomous systems. We develop (1) a model using deep learning along with a model selection framework that can classify benign and malicious operating contexts of a system based on performance counters, (2) a deep learning based natural language processing model that uses instruction sequences extracted from the memory to learn and profile the behavior of evasive malware, (3) a scalable deep learning based object detection model with data pre-processing assisted by fuzzy-based clustering, (4) fundamental guiding principles for cognitive autonomy using Artificial Intelligence (AI), (5) a model for privacy-preserving autonomous data analytics, and finally (6) a model for backup and replication based on combinatorial balanced incomplete block design in order to provide continuous availability in mission-critical systems. This research provides effective and computationally efficient deep learning based solutions for detecting evasive cyberattacks and increasing autonomy of a system from application-level to hardware-level. <br>

Private policing and security services

Knowledge representation and reasoning

Pattern recognition

System and network security

Data mining and knowledge discovery

Artificial Intelligence

Cybersecurity

Deep Learning

Machine Learning

Cryptomining

Cryptojacking

Natural Language Processing

Malware

Combinatorics

Autonomous Systems

Cognitive Autonomy

Applied Computer Science

Computer System Security

Private Policing and Security Services

Pattern Recognition and Data Mining

3D OBJECT DETECTION USING VIRTUAL ENVIRONMENT ASSISTED DEEP NETWORK TRAINING

Ashley S Dale (8771429)

07 January 2021

<div> <div> <div> <p>An RGBZ synthetic dataset consisting of five object classes in a variety of virtual environments and orientations was combined with a small sample of real-world image data and used to train the Mask R-CNN (MR-CNN) architecture in a variety of configurations. When the MR-CNN architecture was initialized with MS COCO weights and the heads were trained with a mix of synthetic data and real world data, F1 scores improved in four of the five classes: The average maximum F1-score of all classes and all epochs for the networks trained with synthetic data is F1∗ = 0.91, compared to F1 = 0.89 for the networks trained exclusively with real data, and the standard deviation of the maximum mean F1-score for synthetically trained networks is σ∗ _F1= 0.015, compared to σF 1 = 0.020 for the networks trained exclusively with real data. Various backgrounds in synthetic data were shown to have negligible impact on F1 scores, opening the door to abstract backgrounds and minimizing the need for intensive synthetic data fabrication. When the MR-CNN architecture was initialized with MS COCO weights and depth data was included in the training data, the net- work was shown to rely heavily on the initial convolutional input to feed features into the network, the image depth channel was shown to influence mask generation, and the image color channels were shown to influence object classification. A set of latent variables for a subset of the synthetic datatset was generated with a Variational Autoencoder then analyzed using Principle Component Analysis and Uniform Manifold Projection and Approximation (UMAP). The UMAP analysis showed no meaningful distinction between real-world and synthetic data, and a small bias towards clustering based on image background. </p></div></div></div>

Computer Engineering

Software Engineering

Applied Computer Science

Information Systems

Signal Processing

Computer Graphics

Computer Vision

Image Processing

Pattern Recognition and Data Mining

Simulation and Modelling

Virtual Reality and Related Simulation

Applied Discrete Mathematics

Coding and Information Theory

Conceptual Modelling

Information Engineering and Theory

Machine Learning

Mask R-CNN

Artificial Intelligence

Image Processing

3D Image

Multispectral Data

Signal Processing

CNN

DNN

Object Detection

Threat Detection

Virtual Environments

Synthetic Dataset

F1 score

image segmentation methods

Image Segmentation

RGBD

RGBD video

RGBZ

Algorithms

MS COCO

Microsoft Common Objects in Context

Transfer Learning