Tag: AI for Safety

In the current landscape of safety management, traditional practices often fall short in capturing the complex, interconnected nature of workplace safety. Standard methods, relying heavily on site-wide checklists, fail to account for the intricacies and interdependencies that define real-world safety scenarios. This oversight has led to a critical gap in safety management—a gap NIXN aims to bridge using the advanced capabilities of Graph Neural Networks (GNNs).

The Limitations of Traditional Safety Data Collection

Traditional safety management systems (SMS) tools often employ generic checklists that, while useful for broad assessments and site governance, overlook the nuanced interactions between various elements within a workplace. This approach produces data that is not only fragmented but also lacks the depth required to understand the complex dynamics at play. Such limitations hinder the ability to predict and prevent safety incidents effectively, as the critical relational data between entities—such as personnel, equipment, and environmental factors—is not captured.

A real-world example of where this approach has shown limitations is in the case of trench collapses. Trench work is one of the most hazardous construction operations, and while a checklist might confirm the presence of shoring or trench boxes, it may not adequately assess the suitability of these measures against the specific soil type, depth of the trench, or proximity to other excavation work. The collapse of a trench at a construction site in Boston in 2016, which resulted in fatalities, highlighted the inadequacy of generic checklists. Investigations revealed a complex set of factors including the trench's depth, the nearby placement of heavy equipment, and recent changes to the trench's structure—none of which were adequately captured by the standard safety checklist in use.  For further information on the 2016 trench collapse in Boston, please refer to the articles from the  U.S. Department of Labor's Occupational Safety and Health Administration (OSHA) and WBUR

• Operational Interdependencies: How the operation of one piece of equipment or process can affect the safety and functionality of another. For example, the failure of a ventilation system can increase the risk associated with the use of volatile substances in a nearby process.
• Human-System Interdependencies: The relationship between human operators and the technical systems they manage. The design of equipment, the layout of a workspace, and the usability of safety systems can significantly affect human performance and, consequently, safety outcomes.
• Environmental Interdependencies: How external environmental factors, such as weather conditions, can influence the operational safety of equipment and the effectiveness of safety measures. For example, extreme temperatures can affect the performance of safety critical components, such as emergency shutdown systems.
• Organizational Interdependencies: The influence of organizational structures, policies, and culture on safety practices and outcomes. The alignment of safety protocols across different departments and the communication channels for safety concerns are examples of organizational interdependencies that can impact safety.

NIXN Approach

NIXN leverages the power of Graph Neural Networks (GNNs) to revolutionize safety management by ingesting safety-related data in graph formats, where the relationships between different data points are emphasized with risk weights determined by machine learning algorithms. Utilizing proprietary datasets from over 25 industries, alongside workers’ compensation loss history, NIXN constructs a comprehensive, interconnected model of workplace safety dynamics. This approach enables the system to identify subtle patterns and predict potential risks with remarkable accuracy, offering tailored recommendations to mitigate these risks effectively. Through this sophisticated analysis, NIXN provides a nuanced understanding of safety management, transforming raw data into actionable insights.

Structure Sampling

In this phase, NIXN’s GNN begins by sampling the structure of a partitioned graph. The nodes within this graph represent different entities such as workplace locations, types of equipment, and employees, while the edges signify the relationships and interactions between these entities. The structure sampling is crucial for reducing computational complexity, focusing on relevant subgraphs (or sections) that contain significant relational data pertinent to safety management.

Feature Sampling

Concurrently, the GNN performs feature sampling. Each node in the graph has associated features that could include variables like the frequency of safety training, equipment age, or incident history. Sampling these features is an essential step to prepare data for efficient processing, allowing the GNN to selectively analyze the most impactful attributes that influence safety outcomes.

Computation

The computation stage is where the heavy lifting occurs. The sampled subgraph and features are transferred to the GPU for high-performance computation. This process involves mini-batch data processing, where the GNN computes node representations by aggregating information from their neighbors. The GNN employs layers of neural networks to learn from the complex and rich features of the data. Through a combination of local CPU and remote machine computations, NIXN’s GNN effectively scales to handle extensive datasets across various industries.

Aggregation

Aggregation is a pivotal step in GNNs where the node features are updated based on the features of neighboring nodes. This is how the interdependencies and the influence of related entities are captured. In NIXN’s use case, this would involve synthesizing information across various nodes to predict risks and safety outcomes more accurately.

Neural Network (NN) Combination

Finally, the aggregated features are passed through one or more neural network layers to synthesize and output the final node embeddings. These embeddings are high-dimensional vectors that encode the risk levels, potential safety incident hotspots, and other relevant safety metrics. The NN essentially combines the learned representations into a predictive model that can, for instance, forecast the likelihood of an incident at a particular site or suggest where to allocate safety resources effectively.

The Future

NIXN’s Graph Neural Network approach is transforming the landscape of risk management and underwriting in profound ways. By harnessing the intricate web of workplace safety data, NIXN enables companies to not only enhance their safety protocols but also significantly influence the underwriting process in the insurance industry. The benefits of this advanced AI technology extend beyond the immediate workplace, fostering a ripple effect that enhances safety benchmarks, reduces risk profiles, and catalyzes more informed underwriting practices.

Through NIXN’s predictive capabilities, stakeholders can expect a range of transformative outcomes:

• Tailored Risk Assessment: Companies can obtain a nuanced understanding of their unique risk factors, leading to more personalized safety measures.
• Data-Driven Underwriting: Insurers gain access to a richer, real-time data set, facilitating more accurate risk evaluations and policy customization.
• Dynamic Premiums: Premiums can be adjusted to reflect current safety practices and risk levels, incentivizing companies to maintain high safety standards.
• Improved Claim Predictability: A clearer forecast of potential incidents allows for better financial planning and reserve allocation for insurers.
• Enhanced Loss Prevention: Identifying potential risks before they materialize helps in implementing preventative strategies, reducing the likelihood of incidents.
• Cost Savings: Both companies and insurers can benefit financially from the reduction in incidents and improved risk management.
• Safety Culture Evolution: As companies strive for lower premiums through better safety practices, a culture of safety becomes deeply ingrained within the organization.
• Regulatory Compliance: With GNN insights, companies can ensure they not only meet but exceed industry regulations and standards.

NIXN's GNN-driven model marks a shift towards a more proactive, predictive, and personalized approach in safety management. By leveraging the power of AI, both companies and insurers can navigate the complexities of risk with unprecedented clarity and sophistication, setting a new standard in safety and underwriting.