Practical Field Ecology. C. Philip Wheater

Practical Field Ecology - C. Philip Wheater


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if these small squares represented the only damp area within the site (covering around 8% of the total area), then this particular habitat variation would have been missed altogether. An alternative strategy would be to use systematic sampling (Figure 1.4b). This is an objective method of spreading the sampling points across the entire area, thus dealing with any spatial heterogeneity. So, to systematically sample the insects on trees, we might collect from every tenth tree in a plantation.

      Usually, systematic sampling would provide us with random individuals – unless for some reason every tenth individual is more likely to share certain characteristics. Suppose we used systematic sampling to examine the distribution of ants' nests in a grassland. We could place 2 m × 2 m quadrats evenly 10 m apart across the site and then count the number of nests within each quadrat. However, if ants' nests are in competition with each other, they are likely to be spaced out. If this spacing happens to be at about 10 m distances, we would either overestimate the number of nests if our sequence of samples included the nests, or underestimate if we just missed including nests in each quadrat. It would be better in this situation to use a mixture of random and systematic sampling (called stratified random sampling – Figure 1.4c) where the area was divided into blocks (say of 10 m × 10 m) and then the 2 m × 2 m quadrats were placed randomly within each of these. This type of sampling design can also be applied to temporal situations by, for example, dividing the day into blocks of 4 hours and allocating the order of the sites to be sampled within each block using different random numbers.

Experimental layouts for five different treatments. (a) Clustered design; (b) stratified design; (c) Latin square design. Each treatment is represented by a different symbol.

      Planning statistical analysis

      Describing data

      We need a variety of techniques to describe the data that we collect. This might be as a data exploratory technique (to check the data to see how variable a data set is, or what sort of distribution we get, etc.), to understand some aspects of the data (e.g. how diverse communities are), and for communication purposes (to be able to discuss the results, orally and in writing, with other people).

Example question Null hypothesis Type of test Data required
Is there a difference between the number of birds found in deciduous woodlands and coniferous woodlands? There is no significant difference between the number of birds in deciduous and coniferous woodlands. Difference tests, e.g. a t test or a Mann–Whitney U test (p. 305). Two variables: one nominal describing the woodland type and one based on either measurements (i.e. actual numbers) or on a ranked scale that describes the number of birds.
Is there a relationship between the number of birds and the size of the woodland? There is no significant relationship between the number of birds and the size of the woodland. Relationship tests, e.g. correlation analysis (p. 307). Two variables: one (either measured or ranked) that describes the number of birds and one (either measured or ranked) that describes the size of the woodland.
Is there an association between whether birds are resident or not and whether the woodlands are deciduous or coniferous? There is no significant association between the frequency of residency and the frequency of woodland type. Frequency analysis, e.g. a Chi‐square test (p. 312). Two variables: one nominal describing the residency status of the birds and one nominal describing the woodland type.

      Asking questions about data


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