Extreme Value Analysis
Helping businesses estimate the likelihood and frequency of weather conditions that could have a critical impact on their infrastructure.
Senior Statistical Scientist Laura Dawkins turns forecasts into predictions of how a company’s operations might be impacted by various weather phenomena.
Predicting the future
Recently we’ve seen an increasing number of extreme weather events like the Beast from the East in 2018. The cold wave had a significant impact on national infrastructure and put people’s daily routines in chaos. We saw transport, energy and water networks affected – leading to wide-spread travel disruption and the closure of schools, offices and shops. Then followed by the hottest summer on record.
While it’s impossible to perfectly predict the impact and severity of every weather event, there are things we can do to assess the likelihood of them recurring, so that people and businesses are better prepared.
At the Met Office, we use a variety of techniques – from numerical systems that predict weather a few days ahead, to climate projection models that look decades into the future. The output can then be combined with that from other forecast centres, giving us a reliable picture of when to push out public weather warnings. Then after the event, we’ll look at the observation data (minimum temperatures, rainfalls, windspeeds, etc), and compare it with historic records to put the severity of the weather that occurred into context.
What is Extreme Value Analysis?
Extreme Value Analysis (EVA) is just one statistical technique that enables us to predict the likelihood of extreme values appearing in a data set – for example, an exceptionally cold spell in place of expected weather. In practical terms, it helps us to characterise the risk of any given natural hazard, and ultimately make sure that infrastructures are built to withstand their impact.
Quantifying the impact of natural hazards
Different infrastructure assets have different operational thresholds, depending on materials and usage. For example, some assets may not be able to function beyond a certain temperature variable: if it gets too hot or too cold, it will fail. The characterisation of an extreme event will vary depending on the asset.
The operational threshold of an asset is often referred to as a ‘return level’ of the weather variable, associated with a ‘return period’. For example, nuclear power infrastructure must be built to withstand an extreme temperature return level event, with a 1-in-10,000-year return period. Put simply, this refers to a high temperature that would be expected to occur on average once every 10,000 years. Which equates to a 0.01% probability of that temperature occurring in a given year. So this becomes the figure we use to ensure that the asset is built to withstand the temperature without failing.
At any given site we’ll have a limited amount of collected data – say, 50 years of observations. But if we’re interested in an extreme event (something that is likely to happen only once every 10,000 years, for example), we need to extrapolate the 50-year data beyond the limits of what we’ve seen historically.
Ideally, we’d draw on thousands of years of weather observations for our future predictions. But for most sites, we have less than 60 years of data. Running observational equipment can be expensive so, instead, we use supercomputers to run climate models. These models can then be used to generate simulations of weather over a prolonged period.
Of course, there’s inherent uncertainty in extrapolated data, and the observed data naturally varies year by year – so a larger initial data set will always yield more accurate predictions. But by extending the data set, we have much greater scope to estimate the probability of history repeating itself, or of a new extreme weather event occurring.
How historical data impacts predictions
Ultimately, observed data gives us a baseline to work from. We can see recent trends and these help identify what to look for in the overall data. Take global temperatures, for example. We’ll have a simple metric of overall temperature changing over time – sometimes that’s normal variability, and other times it’s more likely to be due to climate change. If we can isolate these from each other, we can make better predictions for the variable that we’re specifically interested in – for example, temperatures at a specific location.
Using this as an example, we know that a warmer atmosphere can hold more moisture, so there’s greater potential for more intense extreme rainfall events in future climates. But these events are likely to be less frequent because it takes longer for the moisture to build back up in the atmosphere. If we can predict global mean temperature, it will impact the predictions we make for mean future rainfall. It’s not just historical data of single weather phenomena that we use for our predictions – they’re often interlinked to take into account things like carbon emissions, and ultimately climate change.
Basis for infrastructure design
EVA is used to inform the design criteria of large infrastructure projects. Likewise, it helps to evaluate the health and safety case of existing assets, so they meet the current ISO standards and legal requirements. If a bridge is being built, it has to be sensitive to environmental elements such as strong winds. The more powerful the winds, the more robust the bridge needs to be. It’s not efficient to constantly fix and rebuild structures, so the design has to take into account extreme events that we would only expect to occur in an extended time period. For any new infrastructure that’s likely to be around for many decades, we need to account not only for predicted weather events but also for the state of the climate and how it might affect them. This, in turn, informs the design criteria of the asset.
Safety in uncertainty
We have recently been involved with a customer from the nuclear industry who is interested in estimating extreme temperatures for a new power station – specifically the outside air temperature, and how they can keep their buildings cool. Large air conditioning units are expensive, and their operating temperature further affects costs – in some cases by tens of millions of pounds. Design decisions need to take into account just how hot the outside temperature is likely to get, and how it’s likely to change in future. In accordance with the Office for Nuclear Regulation (ONR), the design is initially given a conservative prediction – based on our model data combined with observations. Then, by extrapolating the data set, we can better simulate future temperatures. This results in a much smaller metric of uncertainty for extreme temperature events, which improves trust in the data. The health and safety case is then supported, as well as the design basis for the asset.
Harnessing the value
Our ultimate goal is to provide the best possible weather information, regardless of the metric of uncertainty it contains. When we use model data, we always combine it with observational data in one way or another, so that the model recreates reality.
Our experience of working on critical infrastructure projects has given us vital insight into engineers’ requirements when creating a design basis for an asset. By working collaboratively with engineers in a project’s early stages, we can then maximise the delivery of our state-of-the-art science and research. This results in the potential to create significant cost savings across the lifecycle of the asset.
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