Could sampling make hares eat lynxes

Cycles in population dynamics are widely found in nature. These cycles are understood as emerging from the interaction between two or more coupled species. Here, we argue that data regarding population dynamics are prone to misinterpretation when sampling is conducted at a slow rate compared to the population cycle period. This effect, known as aliasing, is well described in other areas, such as signal processing and computer graphics. However, to the best of our knowledge, aliasing has never been addressed in the population dynamics context or in coupled oscillatory systems. To illustrate aliasing, the Lotka-Volterra model oscillatory regime is numerically sampled, creating prey-predator cycles. Inadequate sampling periods produce inversions in the cause-effect relationship and an increase in cycle period, as reported in the well-known hare-lynx paradox. More generally, slow acquisition rates may distort data, producing deceptive patterns and eventually leading to data misinterpretation.

[1]  Marten Scheffer,et al.  Chaos in a long-term experiment with a plankton community , 2008, Nature.

[2]  Alexandre Souto Martinez,et al.  Effective carrying capacity and analytical solution of a particular case of the Richards-like two-sp , 2011, 1111.2796.

[3]  C. Krebs,et al.  What Drives the 10-year Cycle of Snowshoe Hares? , 2001 .

[4]  J. C. Holmes,et al.  EFFICACY OF IVERMECTIN AGAINST NEMATODES INFECTING FIELD POPULATIONS OF SNOWSHOE HARES (LEPUS AMERICANUS) IN YUKON, CANADA , 1996, Journal of wildlife diseases.

[5]  A. Mougi,et al.  Evolutionary ecology of inducible morphological plasticity in predator–prey interaction: toward the practical links with population ecology , 2009, Population Ecology.

[6]  C. Krebs,et al.  Impact of Food and Predation on the Snowshoe Hare Cycle , 1995, Science.

[7]  D. A. MacLulich,et al.  Fluctuations in the numbers of the varying hare (Lepus americanus) , 1937 .

[8]  Florian D. Schneider,et al.  Body masses, functional responses and predator-prey stability. , 2013, Ecology letters.

[9]  Michael E. Gilpin,et al.  Do Hares Eat Lynx? , 1973, The American Naturalist.

[10]  P. Barbosa,et al.  Ecology of Predator-Prey Interactions , 2005 .

[11]  N. Stenseth,et al.  Linking climate change to population cycles of hares and lynx , 2013, Global change biology.

[12]  Alexandre Souto Martinez,et al.  Generalized Allee effect model , 2014, Theory in Biosciences.

[13]  S. Levin,et al.  Size and scaling of predator-prey dynamics. , 2006, Ecology letters.

[14]  James D. Murray Mathematical Biology: I. An Introduction , 2007 .

[15]  R. Macarthur,et al.  Graphical Representation and Stability Conditions of Predator-Prey Interactions , 1963, The American Naturalist.

[16]  Florian D. Schneider,et al.  Body mass constraints on feeding rates determine the consequences of predator loss. , 2012, Ecology letters.

[17]  Kung-Sik Chan,et al.  Functional responses and scaling in predator-prey interactions of marine fishes: contemporary issues and emerging concepts. , 2011, Ecology letters.

[18]  C. Krebs,et al.  A natural feeding experiment on a declining snowshoe hare population , 1986, Oecologia.

[19]  G. Feingold,et al.  Aerosol–cloud–precipitation system as a predator-prey problem , 2011, Proceedings of the National Academy of Sciences.

[20]  John Vandermeer,et al.  Coupled Oscillations in Food Webs: Balancing Competition and Mutualism in Simple Ecological Models , 2004, The American Naturalist.

[21]  J. Andrew Royle,et al.  Trend estimation in populations with imperfect detection , 2009 .

[22]  E. Odum Fundamentals of Ecology. , 1955 .

[23]  Michael H. Cortez Comparing the qualitatively different effects rapidly evolving and rapidly induced defences have on predator-prey interactions. , 2011, Ecology letters.

[24]  N. Rashevsky,et al.  Mathematical biology , 1961, Connecticut medicine.

[25]  C. Elton,et al.  The Ten-Year Cycle in Numbers of the Lynx in Canada , 1942 .

[26]  Jef Huisman,et al.  Coupled predator-prey oscillations in a chaotic food web. , 2009, Ecology letters.

[27]  N. Chr. Canadian hare-lynx dynamics and climate variation: need for further interdisciplinary work on the interface between ecology and climate , 2007 .

[28]  O. Gimenez,et al.  Accounting for Sampling Error When Inferring Population Synchrony from Time-Series Data: A Bayesian State-Space Modelling Approach with Applications , 2014, PloS one.

[29]  Charles Hyde Smith Spatial trends in Canadian Snowshoe Hare, Lepus americanus, population cycles , 1983, The Canadian field-naturalist.

[30]  B. Cabella,et al.  Data collapse, scaling functions, and analytical solutions of generalized growth models. , 2011, Physical review. E, Statistical, nonlinear, and soft matter physics.