Publication Library
Interactive Public Transport Infrastructure Analysis through Mobility Profiles Making the Mobility Transition Transparent
Description: Efficient public transport systems are crucial for sustainable urban development as cities face increasing mobility demands. Yet, many public transport networks struggle to meet diverse user needs due to historical development, urban constraints, and financial limitations. Traditionally, planning of transport network structure is often based on limited surveys, expert opinions, or partial usage statistics. This provides an incomplete basis for decision-making. We introduce an data-driven approach to public transport planning and optimization, calculating detailed accessibility measures at the individual housing level. Our visual analytics workflow combines population-group-based simulations with dynamic infrastructure analysis, utilizing a scenario-based model to simulate daily travel patterns of varied demographic groups, including schoolchildren, students, workers, and pensioners. These population groups, each with unique mobility requirements and routines, interact with the transport system under different scenarios traveling to and from Points of Interest (POI), assessed through travel time calculations. Results are visualized through heatmaps, density maps, and network overlays, as well as detailed statistics. Our system allows us to analyze both the underlying data and simulation results on multiple levels of granularity, delivering both broad insights and granular details. Case studies with the city of Konstanz, Germany reveal key areas where public transport does not meet specific needs, confirmed through a formative user study. Due to the high cost of changing legacy networks, our analysis facilitates the identification of strategic enhancements, such as optimized schedules or rerouting, and few targeted stop relocations, highlighting consequential variations in accessibility to pinpointing critical service gaps.
Created At: 11 December 2024
Updated At: 11 December 2024
Challenges and Opportunities for Visual Analytics in Jurisprudence
Description: Exploring, analyzing, and interpreting law can be tedious and challenging, even for legal scholars, since legal texts contain domain-specific language, require knowledge of tacit legal concepts, and are sometimes intentionally ambiguous. In related, text-based domains, Visual Analytics (VA) and large language models (LLMs) have become essential for working with documents as they support data navigation, knowledge representation, and analytical reasoning. However, legal scholars must simultaneously manage hierarchical information sources, leverage implicit domain knowledge, and document complex reasoning processes, which are neither adequately accessible through existing VA designs nor sufficiently supported by current LLMs. To address the needs of legal scholars, we identify previously unexamined challenges and opportunities when applying VA to jurisprudence. We conducted semi-structured interviews with nine experts from the legal domain and found that they lacked the ability to articulate their tacit domain knowledge as explicit, machine-interpretable knowledge. Hence, we propose leveraging interactive visualization for this articulation, teaching the machine relevant semantic relationships between legal documents. These relationships inform the predictions of VA and LLMs, facilitating the navigation between the hierarchies of legal document collections. The enhanced navigation can uncover additional relevant legal documents, reinforcing the legal reasoning process by generating legal insights that reflect internalized, tacit domain knowledge. In summary, we provide a human-is-the-loop VA workflow for jurisprudence that recognizes tacit domain knowledge as essential for deriving legal insights. More broadly, we compare this workflow with related text-based research practices, revealing research gaps and guiding visualization researchers in knowledge-assisted VA for law and beyond.
Created At: 11 December 2024
Updated At: 11 December 2024
Human-Computer Interaction and Human-AI Collaboration in Advanced Air Mobility A Comprehensive Review
Description: The increasing rates of global urbanization and vehicle usage are leading to a shift of mobility to the third dimension-through Advanced Air Mobility (AAM)-offering a promising solution for faster, safer, cleaner, and more efficient transportation. As air transportation continues to evolve with more automated and autonomous systems, advancements in AAM require a deep understanding of human-computer interaction and human-AI collaboration to ensure safe and effective operations in complex urban and regional environments. There has been a significant increase in publications regarding these emerging applications; thus, there is a need to review developments in this area. This paper comprehensively reviews the current state of research on human-computer interaction and human-AI collaboration in AAM. Specifically, we focus on AAM applications related to the design of human-machine interfaces for various uses, including pilot training, air traffic management, and the integration of AI-assisted decision-making systems with immersive technologies such as extended, virtual, mixed, and augmented reality devices. Additionally, we provide a comprehensive analysis of the challenges AAM encounters in integrating human-computer frameworks, including unique challenges associated with these interactions, such as trust in AI systems and safety concerns. Finally, we highlight emerging opportunities and propose future research directions to bridge the gap between human factors and technological advancements in AAM.
Created At: 11 December 2024
Updated At: 11 December 2024
Machine Theory of Mind for Autonomous Cyber-Defence
Description: Intelligent autonomous agents hold much potential for the domain of cyber-security. However, due to many state-of-the-art approaches relying on uninterpretable black-box models, there is growing demand for methods that offer stakeholders clear and actionable insights into their latent beliefs and motivations. To address this, we evaluate Theory of Mind (ToM) approaches for Autonomous Cyber Operations. Upon learning a robust prior, ToM models can predict an agent's goals, behaviours, and contextual beliefs given only a handful of past behaviour observations. In this paper, we introduce a novel Graph Neural Network (GNN)-based ToM architecture tailored for cyber-defence, Graph-In, Graph-Out (GIGO)-ToM, which can accurately predict both the targets and attack trajectories of adversarial cyber agents over arbitrary computer network topologies. To evaluate the latter, we propose a novel extension of the Wasserstein distance for measuring the similarity of graph-based probability distributions. Whereas the standard Wasserstein distance lacks a fixed reference scale, we introduce a graph-theoretic normalization factor that enables a standardized comparison between networks of different sizes. We furnish this metric, which we term the Network Transport Distance (NTD), with a weighting function that emphasizes predictions according to custom node features, allowing network operators to explore arbitrary strategic considerations. Benchmarked against a Graph-In, Dense-Out (GIDO)-ToM architecture in an abstract cyber-defence environment, our empirical evaluations show that GIGO-ToM can accurately predict the goals and behaviours of various unseen cyber-attacking agents across a range of network topologies, as well as learn embeddings that can effectively characterize their policies.
Created At: 11 December 2024
Updated At: 11 December 2024
Incentivized Symbiosis A Paradigm for Human-Agent Coevolution
Description: Cooperation is vital to our survival and progress. Evolutionary game theory offers a lens to understand the structures and incentives that enable cooperation to be a successful strategy. As artificial intelligence agents become integral to human systems, the dynamics of cooperation take on unprecedented significance. Decentralized frameworks like Web3, grounded in transparency, accountability, and trust, offer a foundation for fostering cooperation by establishing enforceable rules and incentives for humans and AI agents. Guided by our Incentivized Symbiosis model, a paradigm aligning human and AI agent goals through bidirectional incentives and mutual adaptation, we investigate mechanisms for embedding cooperation into human-agent coevolution. We conceptualize Incentivized Symbiosis as part of a contemporary moral framework inspired by Web3 principles, encoded in blockchain technology to define and enforce rules, incentives, and consequences for both humans and AI agents. By integrating these principles into the very architecture of human-agent interactions, Web3 ecosystems catalyze an environment ripe for collaborative innovation. Our study traverses several transformative applications of Incentivized Symbiosis, from decentralized finance to governance and cultural adaptation, illustrating how AI agents can coevolve with humans to forge a trajectory of shared, sustainable progress.
Created At: 11 December 2024
Updated At: 11 December 2024