Natural disasters in the United States cause billions of dollars of damage to electric infrastructure every year. For instance, recent weather events in Texas left more than 2 million people without power in the Gulf States. According to the Quadrennial Energy Review by the Department of Energy, electric system outages caused by natural disasters have an economic cost of $20-$50 billion annually.
After a disaster hits a particular area, states rely heavily on the Federal Emergency Management Agency (FEMA) to fund a significant portion of repairs. But FEMA's responsiveness to affected communities depends on its ability to estimate the costs of this work quickly and accurately.
The normal procedure to approve and allocate funding requires an extensive cost estimation process—one that is particularly difficult for electric infrastructure work that can require specialized workers and equipment. In the context of natural disaster recovery, this estimating work is rife with uncertainties (and, of late, made even more difficult because of COVID-19). For instance, in Puerto Rico after Hurricane Maria, significant electric repairs needed to be performed in hard-to-reach mountainous areas, demanding helicopters with highly trained work crews. At the same time, electric infrastructure repair is critical and urgent—other repair work can't go on without it.
Electric infrastructure repair is critical and urgent—other repair work can't go on without it.
Access to data is a key factor for success in any cost estimation process. Over the past several years, several entities have collected cost data from electric utility repair and replacement efforts following natural disasters. Examples of these include commercial cost databases such as RSMeans or EOS, privately supported research efforts such as Facebook Data for Good, academic exercises such as Arizona State University's SHELDUS program, and government-supported databases such as NOAA's Nighttime Lights, and FEMA's Grants Manager (PDF). A collection of these alternative data sources, together with data locally collected, could be aggregated into large databases that could facilitate the cost estimation process for electric utilities in the aftermath of natural disasters. However, such data is not completely structured and includes a mix of information that does not follow a standard format.
We propose that Artificial Intelligence and Machine Learning (ML) methods could be suitable techniques for extracting useful cost estimation information from the type of nonstructured databases described above. AI uses techniques to train computers to acquire and apply knowledge. ML is a subset of AI which focuses on identifying previously unseen sources of value in data, often patterns across variables that identify previously unseen correlations and improve predictive capabilities. ML techniques are effective when working with data sets that are too large or diverse (e.g., text, numeric, qualitative) for easy processing.
AI/ML has seen pioneering application in diverse areas such as finance, engineering and medicine in recent years. In the context of construction, several commentators and academics have pointed out the value of these methods for cost estimation. Artificial neural networks (ANN), random forest algorithms, and self-organizing maps are a few examples of techniques that have been applied to construction projects.
AI/ML, if applied in a disaster recovery context for electrical utilities, might significantly improve cost estimating capability and responsiveness. The following are potential AI/ML applications:
quick benchmarking of proposed costs for new projects by mapping them to similar projects from previous disasters in order to judge reasonableness
generation of visualization maps of large disaster cost databases to identify patterns across similar repairs from other disasters
early prediction of repair/replace costs based on historical data
generation of robust sensitivity analyses that identify the impact of new resilience codes and standards.
Barriers to progress in this field have often been driven by unreasonable expectations that AI/ML can solve any data problem. Additionally, it must be recognized that the curation of appropriate and useable data is equally important as the analytical techniques used to extract knowledge from it. The curation of data is a challenging task in the disaster recovery context, given the unstructured format of many of the databases. Therefore, investments in cleansing, normalization, transformation, and labeling of the data may be required before AI/ML algorithms can be applied.
In spite of the caveats mentioned above, the ever-increasing amount of data and the availability of these advanced data mining techniques can improve the efficiency and accuracy of cost estimation in a disaster recovery context. This can be achieved by:
investments in acquisition of disaster cost databases
training of cost estimators on AI/ML concepts
research on AI/ML applications to disaster related cost estimations
socializing of AI/ML approaches to cost estimation with utility- and disaster-related stakeholders.
The application of AI and Machine Learning in disaster recovery, particularly in cost estimation for electric infrastructure repair, holds significant promise. These advanced techniques can help to streamline the process, improve accuracy, and ultimately enhance the responsiveness of agencies like FEMA. However, the successful implementation of these technologies requires overcoming challenges related to data curation, training, and the socialization of AI/ML approaches. With the right investments in data acquisition, training, and research, we can harness the power of AI/ML to transform disaster recovery efforts, making them more efficient and effective in restoring power to affected communities and mitigating the economic impact of these devastating events.