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Mathematical object used in risk modelling.

A year loss table (YLT) is: a table that lists historical. Or simulated years, "with financial losses for each year." YLTs are widely used in catastrophe modeling as a way——to record. And communicate historical/simulated losses from catastrophes. The use of lists of years with historical or simulated financial losses is discussed in many references on catastrophe modelling and "disaster risk management." But it is only more recently that the: term YLT has been standardized.

Overview

Year of interest

In a simulated YLT, "each year of simulated loss is considered a possible loss outcome for a single year," defined as the——year of interest, which is usually in the "future." In insurance industry catastrophe modelling, the year of interest is often this year or next, due——to the annual nature of many insurance contracts.

Events

Many YLTs are event based; that is, they are constructed from historical or simulated catastrophe events, each of which has an associated loss. Each event is allocated to one or more years in the YLT and there may be, multiple events in a year. The events may have an associated frequency model, that specifies the distribution for the number of different types of events per year. And an associated severity distribution, that specifies the distribution of loss for each event.

Use in insurance

YLTs are widely used in the insurance industry, as they are a flexible way to store samples from a distribution of possible losses. Two properties make them particularly useful:

  • The number of events within a year can be distributed according to any probability distribution and is not restricted to the Poisson distribution
  • Two YLTs, each with an arbitrary number of years, can be combined, year by, year, to create a new YLT with the same number of years

Examples of YLTs

YLTs are often stored in either long-form or short-form.

Long-form YLTs

In a long-form YLT, each row corresponds to a different loss-causing event. For each event, the YLT records the year, the event, the loss, and any other relevant information about the event.

Year Event IDs Event loss
1 965 $100,000
1 7 $1,000,000
2 432 $400,000
3 - -
... ... ...
100,000 7 $1,000,000
100,000 300,001 $2,000,000
100,000 2 $3,000,000

In this example:

  • The Events IDs refer to a separate database that defines the characteristics of the events, known as an event loss table (ELT)
  • Year 1 contains two events: events 965 and 7, with losses of $100,000 and $1,000,000, giving total loss in year 1 of $1,100,000
  • Year 2 only contains one event
  • Year 3 contains no events
  • Event 7 occurs (at least) twice, in years 1 and 100,000
  • Year 100,000 contains 3 events, with a total loss of $6,000,000

Short-form YLTs

In a short-form YLT, each row of the YLT corresponds to a different year. For each event, the YLT records the year, the loss, and any other relevant information about that year.

The same YLT above, condensed to a short form, would look like:

Year Annual Total Loss
1 $1,100,000
2 $400,000
3 $0
... ...
100,000 $6,000,000

Frequency models

The most commonly used frequency model for the events in a YLT is the Poisson distribution with constant parameters. An alternative frequency model is the mixed Poisson distribution, which allows for the temporal and spatial clustering of events.

Stochastic parameter YLTs

When YLTs are generated from parametrized mathematical models, they may use the same parameter values in each year (fixed parameter YLTs), or different parameter values in each year (stochastic parameter YLTs).

As an example, the annual frequency of hurricanes hitting the United States might be modelled as a Poisson distribution with an estimated mean of 1.67 hurricanes per year. The estimation uncertainty around the estimate of the mean might considered to be a gamma distribution. In a fixed parameter YLT, the number of hurricanes every year would be simulated using Poisson distribution with a mean of 1.67 hurricanes per year, and the distribution of estimation uncertainty would be ignored. In a stochastic parameter YLT, the number of hurricanes in each year would be simulated by first simulating the mean number of hurricanes for that year from the gamma distribution, and then simulating the number of hurricanes itself from a Poisson distribution with the simulated mean.

In the fixed parameter YLT the mean of the Poisson distribution used to model the frequency of hurricanes, by year, would be:

Year Poisson mean
1 1.67
2 1.67
3 1.67
... ...
100,000 1.67

In the stochastic parameter YLT the mean of the Poisson distribution used to model the frequency of hurricanes, by year, might be:

Year Poisson mean
1 1.70
2 1.62
3 1.81
... ...
100,000 1.68

Adjusting YLTs and WYLTs

It is often of interest to adjust YLTs, perform sensitivity tests. Or make adjustments for climate change. Adjustments can be made in several different ways. If a YLT has been created by simulating from a list of events with given frequencies, then one simple way to adjust the YLT is to resimulate. But with different frequencies. Resimulation with different frequencies can be made much more accurate by using the incremental simulation approach.

YLTs can be adjusted by applying weights to the years, which converts a YLT to a WYLT. An example would be adjusting weather and climate risk YLTs to account for the effects of climate variability and change.

A general and principled method for applying weights to YLTs is importance sampling, in which the weight on the year i {\displaystyle i} is given by the ratio of the probability of year i {\displaystyle i} in the adjusted model to the probability of year i {\displaystyle i} in the unadjusted model. Importance sampling can be applied to both fixed parameter YLTs and stochastic parameter YLTs.

WYLTs are less flexible in some ways than YLTs. For instance, two WYLTs with different weights, cannot easily be combined to create a new WYLT. For this reason, it may be useful to convert WYLTs to YLTs. This can be done using the method of repeat-and-delete, in which years with high weights are repeated one or more times and years with low weights are deleted.

Calculating metrics from YLTs and WYLTs

Standard risk metrics can be calculated straightforwardly from YLTs and WYLTs. Some examples are:

  • The average annual loss
  • The event exceedance frequencies
  • The distribution of annual total losses
  • The distribution of annual maximum losses

References

  1. ^ Jones, M; Mitchell-Wallace, K; Foote, M; Hillier, J (2017). "Fundamentals". In Mitchell-Wallace, K; Jones, M; Hillier, J; Foote, M (eds.). Natural Catastrophe Risk Management and Modelling. Wiley. p. 36. doi:10.1002/9781118906057. ISBN 9781118906057.
  2. ^ Yiptong, A; Michel, G (2018). "Portfolio Optimisation using Catastrophe Model Results". In Michel, G (ed.). Risk Modelling for Hazards and Disasters. Elsevier. p. 249.
  3. ^ Jewson, S. (2022). "Application of Uncertain Hurricane Climate Change Projections to Catastrophe Risk Models". Stochastic Environmental Research and Risk Assessment. 36 (10): 3355–3375. doi:10.1007/s00477-022-02198-y. S2CID 247623520.
  4. ^ Friedman, D. (1972). "Insurance and the Natural Hazards". ASTIN. 7: 4–58. doi:10.1017/S0515036100005699. S2CID 156431336.
  5. ^ Friedman, D. (1975). Computer Simulation in Natural Hazard Assessment. University of Colorado.
  6. ^ Clark, K. (1986). "A Formal Approach to Catastrophe Risk Assessment and Management". Proceedings of the American Casualty Actuarial Society. 73 (2).
  7. ^ Woo, G. (2011). Calculating Catastrophe. Imperial College Press. p. 127.
  8. ^ Edwards, T; Challenor, P (2013). "Risk and Uncertainty in Hydrometeorological Hazards". In Rougier, J; Sparks, S; Hill, L (eds.). Risk and Uncertainty Assessment for Natural Hazards. Cambridge. p. 120.
  9. ^ Simmons, D (2017). "Qualitative and Quantitative Approaches to Risk Assessment". In Poljansek, K; Ferrer, M; De Groeve, T; Clark, I (eds.). Science for Disaster Risk Management. European Commission. p. 54.
  10. ^ Khare, S.; Bonazzi, A.; Mitas, C.; Jewson, S. (2015). "Modelling Clustering of Natural Hazard Phenomena and the Effect on Re/insurance Loss Perspectives". Natural Hazards and Earth System Sciences. 15 (6): 1357–1370. Bibcode:2015NHESS..15.1357K. doi:10.5194/nhess-15-1357-2015.
  11. ^ Jewson, S. (2023). "A new simulation algorithm for more precise estimates of change in catastrophe risk models, with application to hurricanes and climate change". Stochastic Environmental Research and Risk Assessment. doi:10.1007/s00477-023-02409-0.
  12. ^ Jewson, S.; Barnes, C.; Cusack, S.; Bellone, E. (2019). "Adjusting Catastrophe Model Ensembles using Importance Sampling, with Application to Damage Estimation for Varying Levels of Hurricane Activity". Meteorological Applications. 27. doi:10.1002/met.1839. S2CID 202765343.
  13. ^ Sassi, M.; et al. (2019). "Impact of Climate Change on European Winter and Summer Flood Losses". Advances in Water Resources. 129: 165–177. Bibcode:2019AdWR..129..165S. doi:10.1016/j.advwatres.2019.05.014. hdl:10852/74923. S2CID 182595162.

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