Lecture 11 - Estimating Abundance in Animal Populations PDF

Summary

This document is a lecture on estimating abundance in animal populations. It discusses different methods, including absolute and relative density estimations as well as mark-and-recapture techniques (Petersen and Schnabel methods).

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BDB 211 POPULATION AND COMMUNITY ECOLOGY

Lecture 11

Estimating abundance in Animal Populations

23 September 2024

Prof S W Makhabu
Learning Objective

 To learn and master the methods used in estimating abundance in
animal populations
INTRODUCTION
 The central question of many ecologists when they see a population is “How many individuals are
there?
 If there is a wish to harvest some of them, one necessary bit of information is the size of the
population
 If you are deciding to spray a pesticide of aphids on a crop, you need to know their population
 If you wish to measure the impact of lion predation on a zebra population, you need to know the size
of both the lion and zebra populations
 The cornerstone of many ecological studies is an estimate of the abundance of a particular population
 This is true for both population ecology, in which interest centres on one species, and community
ecology, in which interest centres on many species and, thus, the estimation problem is more
complex
 You need to decide whether estimation of population is necessary
Deciding whether estimation of population is necessary
INTRODUCTION
 Abundance can be measured in two ways:
a. Absolute density
b. Relative density
 Absolute density is the number of organisms per unit area or volume e.g. A red deer density of four
deer per square kilometre is an absolute density
 Relative density is the density of one population to that of another population e.g. blue grouse may
be more common in a block of recently burned woodland than in a block of mature woodland
 Relative density may be adequate for many ecological problems, and it should always be used when
adequate because it is much easier and cheaper to determine than absolute density
 Absolute density must be obtained for any detailed population study in which one attempts to relate
population density to reproductive rate or any other vital statistic.
 The analysis of harvesting strategies also demands information on absolute numbers. All community
studies which estimate energy flow or nutrient cycles also require reliable estimates of absolute
density
Estimating Abundance Techniques
Mark-and- recapture Techniques
 One way to estimate the size of a population is to capture and mark individuals from the population,
release them, and then resample to see what fraction of individuals carry marks
 John Graunt first used this simple principle to estimate the human population of London in 1662
 The first ecological use of mark-and-recapture was carried out by Danish fisheries biologist C. G. J.
Petersen in 1896 (Ricker, 1975)
 Tagging of fish was first used to study movements and migration of individuals, but Petersen realized
that tagging could also be used to estimate population size and to measure mortality rates
 Fisheries biologists were well advanced over others in applying these methods
 Lincoln (1930) used mark-recapture to estimate the abundance of ducks from band returns, and
Jackson (1933) was the first entomologist to apply mark-recapture methods to insect populations
 The strength of mark-and-recapture techniques is that they can be used to provide information on
birth, death, and movement rates in addition to information on absolute abundance
 The weakness of these techniques is that they require considerable time and effort to get the
required data and to be accurate, they require a set of very restrictive assumptions about the
properties of the population being studied
Estimating Abundance Techniques
Mark-and- recapture Techniques
 Mark-and-recapture techniques may be used for open or closed populations

 A closed population is one that does not change in size during the study period, that is, one in
which the effects of births, deaths, and movements are negligible
 An open population is the more usual case, a population that changes in size and composition
from births, deaths, and movements
 Different methods must be applied to open and closed populations:
i. Closed populations, single, marking – Petersen method
ii. Closed populations, multiple markings – Schnabel method
iii. Open populations, multiple census – Jolly-Seber method
Petersen Method
 The Petersen method is the simplest mark-and-recapture method because it is
based on a single episode of marking animals, and a second single episode of
recapturing individuals. The basic procedure is to mark a number of individuals over
a short time, release them, and then to recapture individuals to check for marks. All
individuals can be marked in the same way. The second sample must be a random
sample for this method to be valid; that is, all individuals must have an equal chance
of being captured in the second sample, regardless of whether they are marked or
not. The data obtained are
 M = Number of individuals marked in the first sample
 C = Total number of individuals captured in the second sample
 R = Number of individuals in second sample that are marked.
 From these three variables, we need to obtain an estimate of
 Ň = Size of population at time of marking
 By a proportionality argument, we obtain:
Petersen Method Nˆ = C M
R
Petersen Method
 Confidence Intervals for the Petersen Method

 How reliable are these estimates of population size?
 To answer this critical question, a statistician constructs confidence intervals around the
estimates.
 A confidence interval is a range of values which is expected to include the true
population size a given percentage of the time.
 Typically the given percentage is 95% but you can construct 90% or 99% confidence
intervals, or any range you wish.
 The high and low values of a confidence interval are called the confidence limits.
 Clearly, one wants confidence intervals to be as small as possible, and the statistician's job
is to recommend confidence intervals of minimal size consistent with the assumptions of
the data at hand.
 Confidence Intervals for the Petersen Method
 Confidence intervals are akin to gambling.
 You can state that the chances of flipping a coin and getting "heads" is 50%, but after the coin is flipped, it is either
"heads" or "tails".
 Similarly, after you have estimated population size by the Petersen method and calculated the confidence interval,
the true population size (unfortunately not known to you!) will either be inside your confidence interval or outside it.
 You cannot know which, and all the statistician can do is tell you that on the average 95% of confidence intervals
will cover the true population size.
 Alas, you only have one estimate, and on the average does not tell you whether your one confidence interval is lucky
or unlucky.
 Confidence intervals are an important guide to the precision of your estimates.
 If a Petersen population estimate has a very wide confidence interval, you should not place too much faith in it. If
you wish you can take a larger sample next time and narrow the confidence limits.
 But remember that even when the confidence interval is narrow, the true population size may sometimes be outside
the interval.
 Several techniques of obtaining confidence intervals for Petersen estimates of
population size are available, and the particular one to use for any specific set of data
depends upon the size of the population in relation to the samples we have taken. Seber
(1982) gives the following general guide:
1. If the fraction of marked animals (R/C) is less than 0.10, and
a. The number of recaptures (R) is less than 50, use Poisson confidence intervals.
b. The number of recaptures (R) is above 50, use the normal approximation to obtain
confidence intervals.
2. If the fraction of marked animals (R/C) is more than 0.10, use binomial
confidence intervals.
Confidence Intervals for the Petersen Method
 Assumptions of Petersen Method


For Nˆ in formula (2.2) or (2.3) to be an accurate estimate of population size the following five
assumptions must hold:
1. The population is closed, so that N is constant.

2. All animals have the same chance of getting caught in the first sample.
3. Marking individuals does not affect their catchability.
4. Animals do not lose marks between the two sampling periods.
5. All marks are reported upon discovery in the second sample.
 If the first assumption is to hold in a biological population, it is essential that the Petersen
method be applied over a short period of time.
 One of the crucial assumptions of mark-recapture work is that marked and unmarked animals are equally
catchable.
 Random sampling is critical if we are to obtain accurate Petersen estimates, but it is difficult to achieve in field
programs.
SCHNABEL METHOD

 Schnabel (1938) extended the Petersen method to a series of samples in which there is a
2nd, 3rd, 4th...nth sample. Individuals caught at each sample are first examined for marks, then
marked and released. Marking occurs in each of the sampling times. Only a single type of
mark need be used, since throughout a Schnabel experiment we need to distinguish only two
types of individuals: marked = caught in one or more prior samples; and unmarked = never
caught before. We determine for each sample t:

 Ct = total number of individuals caught in sample t
 Rt = number of individuals already marked when caught in sample t
 Ut = number of individuals marked for first time and released in sample t
 Normally Ct = Rt + Ut
 but if there are accidental deaths involving either marked or unmarked animals, these are subtracted
from the Ut value*.
SCHNABEL METHOD
SCHNABEL METHOD
 The number of marked individuals in the population continues to accumulate as we add further samples, and we
define:
 M = number of marked individuals in the population
 t  just before the t − th sample is taken 
  
 t −1
 Mt = Ut
 i =1

so that, for example,

M6 = U1 + U2 + U3 + U4 + U5

Table 2.2 gives an example of some Schnabel-type data obtained on a sunfish population.


 Given these counts of marked and unmarked individuals, we need to derive an estimate of population size N
for a closed population. Ricker (1975) gives several methods, and Seber (1982, Chap. 4) discusses this estimation
problem in detail. We will describe here two methods of estimation, the original Schnabel method and the
Schumacher and Eschmeyer method, which is the most robust and useful ecological model according to Seber
(1982).
 Assumptions of the Schnabel Method
 The Schnabel method makes all the same assumptions that the Petersen method makes
 - that the population size is constant without recruitment or losses, that sampling is
random, and all individuals have an equal chance of capture in any given sample.
 Our previous discussion of the limitations these assumptions impose are thus all relevant
here.
 The major advantage of the multiple sampling in a Schnabel experiment is that it is easier to pick
up violations of these assumptions.
 What methods are available for counting wildlife?
 There are three main methods for counting wildlife.
 These are ! total counts, ! sample counts ! index counts. The choice of how to
do the count, whether on foot, from a vehicle or from an aircraft, will
depend on the species to be counted, the size and relief of the area, the
resources available and the objective of the count.