The cost of complexity in forecasts of population abundances is reduced but not eliminated by borrowing information across space using a hierarchical approach

Chevalier, Mathieu; Knape, Jonas

doi:10.1111/oik.06401

Forskningsartikel2020Vetenskapligt granskad

The cost of complexity in forecasts of population abundances is reduced but not eliminated by borrowing information across space using a hierarchical approach

Chevalier, Mathieu; Knape, Jonas

Sammanfattning

Anticipating ecological changes is paramount if we are to manage biodiversity and the services they provide to humanity. When forecasting population abundances, studies have shown that simple statistical models often have better forecast performance than complex models. These studies have evaluated forecasts of models fitted separately to data from single sites (single-site approach). Here, we aim to contrast the forecast performance and forecast horizon between a single-site approach and a hierarchical multi-site approach where a single model is fitted to data from multiple-sites, and to investigate how they vary with model complexity. We used 5273 population time series on 84 species from the Swedish breeding bird survey program, and found that simple models on average had better forecast performance and forecast horizon than complex models for both the single- and the multi-site approach. However, the cost of complexity was considerably reduced under the multi-site approach, while the proportion of species for which complex models had better forecast performance than simple models was also much larger than under the single-site approach. This suggests that the multi-site approach is useful for inclusion of more detailed processes which may benefit forecasts for some species and which are of importance for managers. Still, our results are in line with some previous studies suggesting that it is surprisingly difficult to construct complex models that, on average, beat trivial baseline forecasts.

Nyckelord

baseline models; bird abundances; forecast performance; hierarchical models; population dynamics; scoring rules

Publicerad i

Oikos
2020, Volym: 129, nummer: 2, sidor: 249-260
Utgivare: WILEY

SLU författare

Chevalier, Mathieu
- Institutionen för ekologi, Sveriges lantbruksuniversitet
- Université de Lausanne

Knape, Jonas
- Institutionen för ekologi, Sveriges lantbruksuniversitet

Globala målen

SDG15 Skydda, återställa och främja ett hållbart nyttjande av landbaserade ekosystem, hållbart bruka skogar, bekämpa ökenspridning, hejda och vrida tillbaka markförstöringen samt hejda förlusten av biologisk mångfald

UKÄ forskningsämne

Ekologi

Publikationens identifierare

DOI: https://doi.org/10.1111/oik.06401

Permanent länk till denna sida (URI)

https://res.slu.se/id/publ/103469