<p>Parameters used for (a) and (b) are , , for (c) and (d) are , , finally for (e) and (f) are , . Figures (d) and (f) show a linear increase in livestock seroprevalence during post-epidemic which comes in cycles of 5 to 7 years approximately.</p
<p>A: cumulative incidence (total number of symptomatic cases) over a 28-year simulation as a functi...
<p>Small symbols represent the prevalence in the investigated villages. The large symbols represent ...
<p>(A) Frequency distribution of the basic reproductive ratio R<sub>0</sub>, (B) frequency distribut...
<p>Temporal distribution of seropositve samples: from wild ruminants analysed by serumneutralisation...
The simulation was for the month of March for 360 days when the temperature and midge populations we...
<p>The mean relative light units (RLU) ± SEM from triplicate measurements of immunoreactivity over a...
<p>(a)-(i), simulations of the cumulative numbers of infected livestock at year 4, 29, and 62 (by ro...
<p>(a)-(c) and (d)-(f) show the populations of infectious livestock and vectors in patches 1–3, resp...
<p>(a)-(c) show the populations of infectious livestock and (d)-(f) simulate the populations of infe...
<p>(a), (b) and (c) represent the populations of infectious livestock, (d), (e) and (f) represent si...
<p>Titles of each graph indicate infection group. X-axes depict the day of serum collection post inf...
<p>Time on the X-axes is in hours post-inoculation (A) or hours post-exposure (B and C). Lines repre...
<p>In a companion paper a logistic regression model of seroprevalence over time was developed ...
<p>Time on the X-axes is in hours post-inoculation (A) or hours post-exposure (B and C). Lines repre...
<p>(a), (b) and (c) represent the populations of infectious livestock (solid line) and vectors (dash...
<p>A: cumulative incidence (total number of symptomatic cases) over a 28-year simulation as a functi...
<p>Small symbols represent the prevalence in the investigated villages. The large symbols represent ...
<p>(A) Frequency distribution of the basic reproductive ratio R<sub>0</sub>, (B) frequency distribut...
<p>Temporal distribution of seropositve samples: from wild ruminants analysed by serumneutralisation...
The simulation was for the month of March for 360 days when the temperature and midge populations we...
<p>The mean relative light units (RLU) ± SEM from triplicate measurements of immunoreactivity over a...
<p>(a)-(i), simulations of the cumulative numbers of infected livestock at year 4, 29, and 62 (by ro...
<p>(a)-(c) and (d)-(f) show the populations of infectious livestock and vectors in patches 1–3, resp...
<p>(a)-(c) show the populations of infectious livestock and (d)-(f) simulate the populations of infe...
<p>(a), (b) and (c) represent the populations of infectious livestock, (d), (e) and (f) represent si...
<p>Titles of each graph indicate infection group. X-axes depict the day of serum collection post inf...
<p>Time on the X-axes is in hours post-inoculation (A) or hours post-exposure (B and C). Lines repre...
<p>In a companion paper a logistic regression model of seroprevalence over time was developed ...
<p>Time on the X-axes is in hours post-inoculation (A) or hours post-exposure (B and C). Lines repre...
<p>(a), (b) and (c) represent the populations of infectious livestock (solid line) and vectors (dash...
<p>A: cumulative incidence (total number of symptomatic cases) over a 28-year simulation as a functi...
<p>Small symbols represent the prevalence in the investigated villages. The large symbols represent ...
<p>(A) Frequency distribution of the basic reproductive ratio R<sub>0</sub>, (B) frequency distribut...
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