Dataset Paper
Spatial and Temporal Abundance of Interacting Populations of
White Clover and Grass Species as Assessed by Image Analyses

Anne Kjersti Bakken,1 Helge Bonesmo,2 and Bård Pedersen3

1Norwegian Institute for Agricultural and Environmental Research (Bioforsk), 7512 Stjørdal, Norway
2Norwegian Agricultural Economic Research Institute, Statens Hus, P.O. Box 4718, Sluppen, 7468 Trondheim, Norway
3Norwegian Institute for Nature Research, P.O. Box 5685, Sluppen, 7485 Trondheim, Norway

Correspondence should be addressed to Anne Kjersti Bakken; anne.kjersti.bakken@bioforsk.no

Received 2 April 2014; Accepted 26 September 2014

Academic Editor: Nicola Pizzolato

Copyright © 2015 Anne Kjersti Bakken et al. This is an open access article distributed under the Creative Commons Attribution
License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly
cited.

The dataset comprises detailed mappings of two communities of interacting populations of white clover (Trifolium repens L.) and
grass species under differing experimental treatments over 4-5 years. Information from digital photographs acquired two times per
season has been processed into gridded data and documents the temporal and spatial dynamics of the species that followed from
a wide range of spatial configurations that arose during the study period. The data contribute a unique basis for validation and
further development of previously published models for the dynamics and population oscillations in grass-white clover swards.
They will be well suited for estimating parameters in spatially explicit versions of these models, like neighborhood based models
that incorporate both the dispersal and the local nature of plant-plant interactions.

1. Introduction

White clover (Trifolium repens L.) is a clonal legume that
is commonly grown in grasslands managed for grazing and
forage production. The facilitation of long term, stable coex-
istence of clover and grass in such a system is a challenge [1–
4] and the community dynamics are still poorly understood.
The community has therefore turned out to be an important
model system for studying and understanding ecological
interactions between plants and the consequences of these
interactions for coexistence of populations of different plant
species.

Various mechanisms have been proposed to cause popu-
lation oscillations and formation of clover patches in pastures
and swards. Amongst them are facilitation and exploitation
[5], balancing local extinction and invasion of clover [6],
and synchronous fragmentation of ramets into small and
vulnerable individuals [7]. Grass and clover populations
are suggested to remain stable at a nitrogen level that
balances their competitive advantages; otherwise oscillations
are expected [5, 8]. An increase in nitrogen availability in
the sward increases the abundance of grass, and clover is

excluded by grass. Time delayed responses to changes in
the availability of nitrogen may increase the probability of
oscillations [5]. In order to stabilize field scale oscillations of
white clover population size, it is suggested that it must have
a patchy distribution, be able to invade space where it can
achieve high growth rate, and avoid space where it will be out-
competed [9]. In addition, environmental and demographic
stochasticity [10] affect dynamics of real ecological systems
of interacting species. Such stochastic noise may also induce
dynamic phenomena like oscillations, local extinctions, and
spatial pattern formation, features that characterize dynamics
of grass-clover systems [11, 12].

Thus, both the temporal and spatial variation in clover
abundance may be relevant to deduce mechanisms that cause
the dynamics. The above theories suggest it is especially
relevant to study the spatiotemporal dynamics of clover-grass
systems under contrasting environmental conditions that
differ with respect to nitrogen availability and disturbance
regimes. Simulation models have been developed to explore
the spatiotemporal dynamics of white clover populations
[5, 6, 8, 9, 13]. There are, however, few reports from field
studies contributing data on spatial dynamics [6, 14–17] and

Hindawi Publishing Corporation
Dataset Papers in Science
Volume 2015, Article ID 620164, 9 pages
http://dx.doi.org/10.1155/2015/620164



2 Dataset Papers in Science

to the best of our knowledge none that cover temporal and
spatial abundance of both grass and clover in contrasting
environments.

We have constructed an experiment with swards domi-
nated by white clover and smooth meadow-grass (Poa praten-
sis ssp. pratensis L.), with different management regimes
with respect to cutting frequency and nitrogen supply. The
management and treatments were chosen to develop environ-
ments that gave differing competitive advantages of grass and
clover.

Both the spatial distribution and abundance of white
clover and grass were recorded during four or five years by
digital photography and image analyses. The results were fur-
ther processed to gridded data appropriate as inputs to spatial
statistical analyses as suggested by Pedersen et al. [18] or sim-
ulation models for population dynamics in space and time.

2. Methodology

Site description and experimental layout are as follows. The
experiment was initiated in 2001 and undertaken at two
sites in pastures/leys dominated by white clover and smooth
meadow-grass. The first one was located at Mære Agricultural
School (63∘56󸀠N, 11∘25󸀠E, 40 m a.s.l.) in central Norway in a
pasture previously grazed by dairy cattle. The species sown
in 1993 besides smooth meadow-grass and white clover were
timothy (Phleum pratense L.) and meadow fescue (Festuca
pratensis Hudson). In 2001 the timothy and meadow fescue
had nearly disappeared and there was a low appearance of
weeds. The soil at the site is a sandy loam, and the content
of organic matter in the topsoil is 5%.

The second experimental site was located at Kvithamar
Research Centre (63∘29󸀠N 10∘52󸀠E, 40 m a.s.l.) in a ley sown in
spring 2000 with white clover (variety Norstar, Graminor AS,
Stange, Norway) and smooth meadow-grass (variety Entop-
per, Innoseeds b.b., Vlijmen, The Netherlands). Altogether
18 main plots (4 m × 8 m each) were split into small plots
(0.5 m × 0.5 m) and sown either with white clover at a rate
of 0.8 g m−2 or smooth meadow-grass at a rate of 1.7 g m−2 or
a mixture of both species (0.5 g m−2 + 1.5 g m−2). The three
types of small plots were randomly distributed within main
plots and the respective numbers of them in each main plot
were 20 with clover, 20 with grass, and 88 with a mixture of
the two species. The leys were cut once in late summer 2000
and were not fertilized until spring 2001. The soil at the site is
a silt loam (20–25% clay and 55–65% silt) and the content of
organic matter in the topsoil is 8%.

From spring 2001 until autumn 2004 (Mære)/spring 2005
(Kvithamar), a factorial experiment with two harvesting
regimes combined with three nitrogen-fertilizer levels was
conducted at both sites. At Mære the treatments were repli-
cated four times on 4 m × 4 m plots within a total area of
480 m2 and at Kvithamar there were three replicates laid out
on 4 m × 8 m plots within an area of 684 m2. Plots were
bordered with 20 cm wide strips kept free from vegetation
by regular spraying with glyphosate. The plots were cut at a
stubble height of 5 cm either two (late June and late August)
or four times (late May, late June, late July, and late August)

each growing season. The first/second and second/fourth cuts
were always synchronised.

Nitrogen was supplied from a compound mineral fer-
tiliser (N-P-K, 18 : 3 : 15) at rates of 0, 10, or 30 g m−2yr−1. In
the first treatment, 1.5 g P and 5.1 g K m−2 were supplied from
a P-K fertilizer.

In the two-cut regime, 60% of the fertiliser was dis-
tributed in early spring and 40% after the first cut, whereas
in the four-cut regime 40% was supplied in spring and 20%
after each of the cuts in late May, late June, and late July.

Dry yields were recorded at each of the cuts at Kvithamar.
For the years 2002–2005, the content of clover in plotwise
subsamples of the yield was determined by Near Infrared
Reflectance Spectroscopy [19]. At Mære, there were no yield
recordings. On both sites and just before the cuts in late
August in 2003 and in late June and August in 2004, the
height of the plant canopy was determined by a rising-
plate meter [20]. There were 128 and 64 recording points
within each plot at Kvithamar (Figure 1) and Mære (Figure 2),
respectively. Precipitation, temperature, and global radiation
for the experimental period are available at Agrometeorology
Norway, lmt.bioforsk.no, stations Kvithamar and Mære.

Plots harvested two times per season and supplied with
high levels of N were, by time, invaded by tussock forming
and more erect and high yielding grass species than smooth
meadow-grass. They were Elytrigia repens L., P. pratense L.,
Agrostis capillaris L., and Lolium perenne L. After harvest,
the initial regrowth rate expressed as plant coverage of soil
surface, was slower in such plots. In line with this, bare soil
at the time of image acquisition (cf. next section) does not
indicate low grass abundance or production.

Determination of plant coverage image acquisition and
processing was as follows. To determine the coverage of
clover, grass, and dicotyledonous weeds in the experimental
fields, they were mapped by means of digital photography
about ten days after the cuts in late June and August every
year from 2001 and onwards (Figure 3). To ensure that the
images were taken at the same positions in the fields at each
acquisition, 1.5 m steel tubes with a diameter of 1.9 cm were
inserted into the ground at the corners of the 4.0 m× 4.0 m
and 4.0 m×8.0 m plots. Portable rails were anchored on these
tubes on each side of the plot and on the rails, across the plot,
a moveable bar was placed, and a sliding 0.5 m×0.5 m metal
frame that delimited the squares to be analysed sequentially
was placed upon the bar (Figure 3).

The area to be photographed was shielded from sunlight
by an opaque parasol and the internal blitz of the camera was
used to eliminate shadows and ensure even illumination. The
camera was mounted to a rack on the metal frame such that
the distance from the camera to the ground was kept constant
at 80 cm. A digital Olympus Camedia C-3040Zoom camera
was used, and the images were stored in a compressed format
that gave a spatial resolution of approximately 1600 × 1600
pixels m−2.

The information from the digital colour photographs was
processed by software (“Trifolium.exe”) specially designed
for the purpose. The software classifies each pixel in the
image as clover, grass, weeds, and bare ground. A thorough
description of the image analysis techniques is given by



Dataset Papers in Science 3

1 2 3 4 5 6

7 8 9 10 11 12

13 14 15 16 17 18

(a)

1 2 3 4 5 6 7 8

9 10 11 12 13 14 15 16

17 18 19 20 21 22 23 24

25 26 27 28 29 30 31 32

33 34 35 36 37 38 39 40

41 42 43 44 45 46 47 48

49 50 51 52 53 54 55 56

57 58 59 60 61 62 63 64

65 66 67 68 69 70 71 72

73 74 75 76 77 78 79 80

81 82 83 84 85 86 87 88

89 90 91 92 93 94 95 96

97 98 99 100 101 102 103 104

105 106 107 108 109 110 111 112

113 114 115 116 117 118 119 120

121 122 123 124 125 126 127 128

(b)

Figure 1: Orientation of the maps at Kvithamar: (a) 18 plots (4 m×
8 m plots each) and (b) 128 subplots (small plots: 0.5 m×0.5 m plots
each).

Bonesmo et al. [21]. The 0.5 m × 0.5 m single images were
after processing by the software (Figure 4) combined into
one picture (TIF-format) (Figure 5) or data file for each plot
after identifying overlap zones and removing them from
one of the overlapping images. The procedure for removing
overlap zones as well as the software Trifolium.exe is available
from the authors. The copyright for the source code of
Trifolium.exe is not owned by the authors and cannot be
published here.

3. Dataset Description

The dataset associated with this Dataset Paper consists of 21
items which are described as follows.

Dataset Item 1 (Images). Photos for each plot and image
acquisition at Kvithamar. All photos together covered the
whole plot. The photos are named according to the number

8 7 6 5 4 3 2 1

16 15 14 13 12 11 10 9

24 23 22 21 20 19 18 17

(a)

1 2 3 4 5 6 7 8

9 10 11 12 13 14 15 16

17 18 19 20 21 22 23 24

25 26 27 28 29 30 31 32

33 34 35 36 37 38 39 40

41 42 43 44 45 46 47 48

49 50 51 52 53 54 55 56

57 58 59 60 61 62 63 64

(b)

Figure 2: Orientation of the maps at Mære: (a) 24 plots (4 m ×
4 m plots each) and (b) 64 subplots (small plots: 0.5 m×0.5 m plots
each).

Figure 3: Positioned image acquisition to map the grass-clover
sward.

of image acquisition (9 image acquisitions), plot number
(18 main plots), and subplot number (128 subplots). These
photos were the basis for the image analyses conducted by the
software Trifolium.exe. There are altogether 20736 photos (9
image acquisitions× 18 plots/acquisition× 128 photos/plot).
A few photographs are missing.

Dataset Item 2 (Images). Photos for each plot and image
acquisition at Mære. All photos together covered the whole
plot. The photos are named according to the number of image
acquisition (8 image acquisitions), plot number (24 main
plots), and subplot number (64 subplots). These photos were
the basis for the image analyses conducted by the software
Trifolium.exe. There are altogether 12288 photos (8 image
acquisitions× 24 plots/acquisition× 64 photos/plot). A few
photographs are missing.



4 Dataset Papers in Science

200

200

400

400

600

600
800

800

(a) Image

200

200

400

400

600

600
800

800

(b) Grey level image

200

200

400

400

600

600
800

800

(c) Edge image

200

200

400

400

600

600
800

800

(d) Classification

Figure 4: Outputs at sequential steps in the analysis of (a) a digital colour image by the software Trifolium.exe, (b) grey level image, (c) edge
image, and (d) classified image, where red indicates clover, blue indicates grass, and black indicates soil (published with permission from
Taylor & Francis Group, and previously printed in [21]).

Figure 5: An example of a 4 m× 4 m plot with patterns occurring
from identification of pixels either as clover (red), grass (blue), bare
ground (black), or dicotyledonous weeds (white).

Dataset Item 3 (Table). Treatments allocated to the different
plots are listed together with harvest dates, data for harvested

yield, and clover proportion in dried yield samples, as deter-
mined by NIRS. Yields were recorded at the site Kvithamar
only. The column Site identifies whether the site is Kvithamar
or Mære. The column Plot Number presents the plot number
within site (1–18 at Kvithamar and 1–24 at Mære). In the col-
umn Harvesting Regime, 1 indicates two cuts per season and 2
indicates four cuts per season. In the column Nitrogen Supply
Rate, 1 indicates 0 g, 2 indicates 10 g, and 3 indicates 30 g.
The column Yield One presents the dry matter yield (g m−2)
at harvest in spring (May/June); Yield Two, the dry matter
yield (g m−2) at harvest in early summer (June/July); Yield
Three, the dry matter yield (g m−2) at harvest in late summer
(July/August); Yield Four, the dry matter yield (g m−2) at har-
vest in autumn (August/September). The column Clover One
presents the proportion (%, weight/weight) of clover in yields
in spring; Clover Two, the proportion (%, weight/weight) of
clover in yields in early summer; Clover Three, the proportion
(%, weight/weight) of clover in yields in late summer; Clover
Four, the proportion (%, weight/weight) of clover in yields in
autumn. The column Date One presents the date of harvest in
spring; Date Two, the date of harvest in early summer; Date
Three, the date of harvest in late summer; Date Four, the date
of harvest in autumn. The harvest dates at Mære were 2-3
days later than respective dates at Kvithamar. A dot (⋅) in a



Dataset Papers in Science 5

cell indicates that no value was recorded for this combination
of harvesting regime, N-supply rate, year, and time of season.

Column 1: Site
Column 2: Plot Number
Column 3: Harvesting Regime
Column 4: Nitrogen Supply Rate (g m−2y−1)
Column 5: Year
Column 6: Yield One (g m−2)
Column 7: Yield Two (g m−2)
Column 8: Yield Three (g m−2)
Column 9: Yield Four (g m−2)
Column 10: Clover One (%)
Column 11: Clover Two (%)
Column 12: Clover Three (%)
Column 13: Clover Four (%)
Column 14: Date One
Column 15: Date Two
Column 16: Date Three
Column 17: Date Four

Dataset Item 4 (Matrices). Registration of the first image
acquisition at Kvithamar containing 18 matrices that contain
2400× 1200 cells describing the 8 m×4 m plots. Each cell in
the matrices contains one digit (1, 2, 3, or 4), which identifies
the character of single cells as being covered by clover (1),
grass (2), bare ground (3), or dicotyledonous weeds (4). For a
few plots, there are smaller areas that are not identified. Such
cells are annotated with the digit 0.

Dataset Item 5 (Matrices). Registration of the second image
acquisition at Kvithamar containing 18 matrices that contain
2400× 1200 cells describing the 8 m×4 m plots. Each cell in
the matrices contains one digit (1, 2, 3, or 4), which identifies
the character of single cells as being covered by clover (1),
grass (2), bare ground (3), or dicotyledonous weeds (4). For a
few plots, there are smaller areas that are not identified. Such
cells are annotated with the digit 0.

Dataset Item 6 (Matrices). Registration of the third image
acquisition at Kvithamar containing 18 matrices that contain
2400× 1200 cells describing the 8 m×4 m plots. Each cell in
the matrices contains one digit (1, 2, 3, or 4), which identifies
the character of single cells as being covered by clover (1),
grass (2), bare ground (3), or dicotyledonous weeds (4). For a
few plots, there are smaller areas that are not identified. Such
cells are annotated with the digit 0.

Dataset Item 7 (Matrices). Registration of the fourth image
acquisition at Kvithamar containing 18 matrices plots that
contain 2400 × 1200 cells describing the 8 m × 4 m. Each
cell in the matrices contains one digit (1, 2, 3, or 4), which
identifies the character of single cells as being covered by

clover (1), grass (2), bare ground (3), or dicotyledonous weeds
(4). For a few plots, there are smaller areas that are not
identified. Such cells are annotated with the digit 0.

Dataset Item 8 (Matrices). Registration of the fifth image
acquisition at Kvithamar containing 18 matrices that contain
2400× 1200 cells describing the 8 m×4 m plots. Each cell in
the matrices contains one digit (1, 2, 3, or 4), which identifies
the character of single cells as being covered by clover (1),
grass (2), bare ground (3), or dicotyledonous weeds (4). For a
few plots, there are smaller areas that are not identified. Such
cells are annotated with the digit 0.

Dataset Item 9 (Matrices). Registration of the sixth image
acquisition at Kvithamar containing 18 matrices that contain
2400× 1200 cells describing the 8 m×4 m plots. Each cell in
the matrices contains one digit (1, 2, 3, or 4), which identifies
the character of single cells as being covered by clover (1),
grass (2), bare ground (3), or dicotyledonous weeds (4). For a
few plots, there are smaller areas that are not identified. Such
cells are annotated with the digit 0.

Dataset Item 10 (Matrices). Registration of the seventh image
acquisition at Kvithamar containing 18 matrices that contain
2400 × 1200 cells describing the 8 m × 4 m plots (plot 9
is missing). Each cell in the matrices contains one digit (1,
2, 3, or 4), which identifies the character of single cells as
being covered by clover (1), grass (2), bare ground (3), or
dicotyledonous weeds (4). For a few plots, there are smaller
areas that are not identified. Such cells are annotated with the
digit 0.

Dataset Item 11 (Matrices). Registration of the eighth image
acquisition at Kvithamar containing 18 matrices that contain
2400 × 1200 cells describing the 8 m × 4 m plots (plot 8
is missing). Each cell in the matrices contains one digit (1,
2, 3, or 4), which identifies the character of single cells as
being covered by clover (1), grass (2), bare ground (3), or
dicotyledonous weeds (4). For a few plots, there are smaller
areas that are not identified. Such cells are annotated with the
digit 0.

Dataset Item 12 (Matrices). Registration of the ninth image
acquisition at Kvithamar containing 18 matrices that contain
2400× 1200 cells describing the 8 m×4 m plots. Each cell in
the matrices contains one digit (1, 2, 3, or 4), which identifies
the character of single cells as being covered by clover (1),
grass (2), bare ground (3), or dicotyledonous weeds (4). For a
few plots, there are smaller areas that are not identified. Such
cells are annotated with the digit 0.

Dataset Item 13 (Matrices). Registration of the first image
acquisition at Mære containing 24 matrices that contain
1200×1200 cells describing the 4 m×4 m plots. Each cell in
the matrices contains one digit (1, 2, 3, or 4), which identifies
the character of single cells as being covered by clover (1),
grass (2), bare ground (3), or dicotyledonous weeds (4). For a



6 Dataset Papers in Science

few plots, there are smaller areas that are not identified. Such
cells are annotated with the digit 0.

Dataset Item 14 (Matrices). Registration of the second image
acquisition at Mære containing 24 matrices that contain
1200×1200 cells describing the 4 m×4 m plots (plots 11, 19,
and 20 are missing). Each cell in the matrices contains one
digit (1, 2, 3, or 4), which identifies the character of single cells
as being covered by clover (1), grass (2), bare ground (3), or
dicotyledonous weeds (4). For a few plots, there are smaller
areas that are not identified. Such cells are annotated with the
digit 0.

Dataset Item 15 (Matrices). Registration of the third image
acquisition at Mære containing 24 matrices that contain
1200×1200 cells describing the 4 m×4 m plots. Each cell in
the matrices contains one digit (1, 2, 3, or 4), which identifies
the character of single cells as being covered by clover (1),
grass (2), bare ground (3), or dicotyledonous weeds (4). For a
few plots, there are smaller areas that are not identified. Such
cells are annotated with the digit 0.

Dataset Item 16 (Matrices). Registration of the fourth image
acquisition at Mære containing 24 matrices that contain
1200×1200 cells describing the 4 m×4 m plots. Each cell in
the matrices contains one digit (1, 2, 3, or 4), which identifies
the character of single cells as being covered by clover (1),
grass (2), bare ground (3), or dicotyledonous weeds (4). For a
few plots, there are smaller areas that are not identified. Such
cells are annotated with the digit 0.

Dataset Item 17 (Matrices). Registration of the fifth image
acquisition at Mære containing 24 matrices that contain
1200×1200 cells describing the 4 m×4 m plots. Each cell in
the matrices contains one digit (1, 2, 3, or 4), which identifies
the character of single cells as being covered by clover (1),
grass (2), bare ground (3), or dicotyledonous weeds (4). For a
few plots, there are smaller areas that are not identified. Such
cells are annotated with the digit 0.

Dataset Item 18 (Matrices). Registration of the sixth image
acquisition at Mære containing 24 matrices that contain
1200×1200 cells describing the 4 m×4 m plots. Each cell in
the matrices contains one digit (1, 2, 3, or 4), which identifies
the character of single cells as being covered by clover (1),
grass (2), bare ground (3), or dicotyledonous weeds (4). For a
few plots, there are smaller areas that are not identified. Such
cells are annotated with the digit 0.

Dataset Item 19 (Matrices). Registration of the seventh image
acquisition at Mære containing 24 matrices that contain
1200×1200 cells describing the 4 m×4 m plots. Each cell in
the matrices contains one digit (1, 2, 3, or 4), which identifies
the character of single cells as being covered by clover (1),
grass (2), bare ground (3), or dicotyledonous weeds (4). For a
few plots, there are smaller areas that are not identified. Such
cells are annotated with the digit 0.

Dataset Item 20 (Matrices). Registration of the eighth image
acquisition at Mære containing 24 matrices that contain
1200×1200 cells describing the 4 m×4 m plots. Each cell in
the matrices contains one digit (1, 2, 3, or 4), which identifies
the character of single cells as being covered by clover (1),
grass (2), bare ground (3), or dicotyledonous weeds (4). For a
few plots, there are smaller areas that are not identified. Such
cells are annotated with the digit 0.

Dataset Item 21 (Table). Recordings of plant canopy height at
Kvithamar and Mære in late August in 2003, late June in 2004,
and late August in 2004. There were 128 and 64 recording
points within each plot at Kvithamar and Mære, respectively.

Column 1: Cut Date
Column 2: Site
Column 3: Plot Number
Column 4: Subplot Number
Column 5: Height (cm)

4. Concluding Remarks

The dataset presented here will contribute a unique basis for
validation and further development of previously published
models for the dynamics and population oscillations in grass-
white clover swards. The set documents the spatial dynamics
of the two species that followed from a wide range of spatial
configurations that arose during the experiment. It should
therefore be well suited for estimating parameters in spatially
explicit versions of these models, like neighborhood based
models that incorporate both the dispersal and the local
nature of plant-plant interactions (e.g., [22–25]). For example,
the hypothesis that a patchy distribution of clover and its
ability to invade space where it is not outcompeted will damp
oscillations may be tested.

Dataset Availability

The dataset associated with this Dataset Paper is dedicated to
the public domain using the CC0 waiver and is available at
http://dx.doi.org/10.1155/2015/620164/dataset.

Conflict of Interests

There is no conflict of interests in the access or publication of
this dataset.

Acknowledgments

Anne Stine Ekker and Anne Langerud have contributed
substantially to this work. The Norwegian Research Council
and Bioforsk are acknowledged for financial support.

References

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Dataset Papers in Science 7

Balances in New Zealand Ecosystems, P. Gandar, Ed., pp. 85–89,
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[2] M. G. Lambert, D. A. Clark, D. A. Grant, and D. A. Costall,
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[8] J. H. M. Thornley, J. Bergelson, and A. J. Parsons, “Complex
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[9] S. Schwinning and A. J. Parsons, “A spatially explicit population
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[10] R. Lande, S. Engen, and B.-E. Sæther, Stochastic Population
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[11] B. Spagnolo, A. Fiasconaro, and D. Valenti, “Noise induced
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