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Modelos SEIR
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ID:(349, 0)


Modified SEIR models
Definition

ID:(873, 0)


SEIR model curve
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In the case of SEIR models there are four curves, that of susceptible, latent, infected and recovered:

ID:(9703, 0)


Curvas del modelo SEIR
Note

The model can solve numerically the equations for susceptible S, infected I, latent E and recovered R:

$\displaystyle\frac{dS}{dt}=-\displaystyle\frac{\beta C}{N}I(t)S(t)+\mu_bN-\mu_dS(t)$



$\displaystyle\frac{dE}{dt}=\displaystyle\frac{\beta C}{N}I(t)S(t)-(\sigma+\mu_d)E(t)$



$\displaystyle\frac{dI}{dt}=\sigma E(t)-(\gamma+\mu_d)I(t)$



$\displaystyle\frac{dR}{dt}=\gamma I(t)-\mu_dR(t)$

where t is the time \beta the cup of contagion, \sigma the cup of emergence of the symptoms in the infected, \gamma the recovery rate, C the number of contacts, N the population, \mu_b per capita birth rate and \mu_d per capita mortality.

ID:(6834, 0)


Modelos SEIR
Description

Variables
Symbol
Text
Variable
Value
Units
Calculate
MKS Value
MKS Units
$I_{crit}$
I_crit
Asymptotic Infected
-
$E_{crit}$
E_crit
Asymptotic Latent
-
$S_{crit}$
S_crit
Asymptotic Susceptible
-
$\mu_b$
mu_b
Birth Time Factor
$\mu_d$
mu_d
Death Time Factor
$I_t$
I_t
Infected
-
$dI$
dI
Infected Variation
-
$dt$
dt
Infinitesimal Variation of Time
s
$E$
E
Latent
-
$\sigma$
sigma
Latent Factor pass to Infected by Time
$C$
C
Number of People with that Contact
-
$N$
N
Population
-
$\beta$
beta
Probability of Infection in Time
1/s
$R_0$
R_0
Propagation Factor
$R_t$
R_t
Recovered
-
$dR$
dR
Recovered Variation
-
$\gamma$
gamma
Recovery Time Factor
1/s
$S_t$
S_t
Susceptible
-
$dS$
dS
Susceptible Variation
-
$dE$
dE
Variation of Latent
-

Calculations

First, select the equation:   to ,  then, select the variable:   to 
Symbol
Equation
Solved
Translated

Calculations

Symbol
Equation
Solved
Translated

 Variable   Given   Calculate   Target :   Equation   To be used


Equations

Examples

In the case of those susceptible, the process of generating latent people in the SEIR model is equivalent to that of creating infected in the SIR model. Therefore in this case the equation that describes the susceptible is the same in both models:

$\displaystyle\frac{dS}{dt}=-\displaystyle\frac{\beta C}{N}I(t)S(t)+\mu_bN-\mu_dS(t)$

(ID 4086)

In the case of the equation of latent cases, one must first consider those that have been infected and that the SIR model led to those infected\\n\\n

$-\displaystyle\frac{\beta C}{N} I(t) S(t $

\\n\\nwhere \beta is the probability of infected, C the number of contacts, S the number of those susceptible, I the number of those infected and N the number of the population.\\n\\nThe number of latents will decrease depending on the fraction \sigma that will show the symptoms and be part of those infected with symptoms I\\n\\n

$-\sigma E(t)$

\\n\\nSimilarly those who die from another cause should be considered\\n\\n

$-\mu_d E(t)$



so the equation to describe the latent will be

$\displaystyle\frac{dE}{dt}=\displaystyle\frac{\beta C}{N}I(t)S(t)-(\sigma+\mu_d)E(t)$

(ID 4087)

In the case of the equation of infected cases, first consider those that are latent E and that in the proportion \sigma become infected

\sigma E(t)

The number of infected will decrease depending on the \gamma fraction of the infected I that is recovered

-\gamma I(t)

Similarly those who die from another cause should be considered

-\mu_d I(t)

so the equation to describe the infected will be

$\displaystyle\frac{dI}{dt}=\sigma E(t)-(\gamma+\mu_d)I(t)$

(ID 4088)

In the case of the equation of recovered cases, it is necessary to first consider those that are infected I and that in the proportion \gamma become recovered\\n\\n

$\gamma I(t)$

\\n\\nSimilarly those who die from another cause should be considered\\n\\n

$-\mu_d R(t)$



so the equation to describe the infected will be

$\displaystyle\frac{dR}{dt}=\gamma I(t)-\mu_dR(t)$

(ID 4089)

If the probability of becoming infected is \beta, the number of contacts C, the reproduction factor \gamma, the step factor from latent to infected and \mu_d the death factor from other causes, the reproduction factor is

$R_0=\displaystyle\frac{\beta C\sigma}{(\sigma+\mu_d)(\gamma+\mu_d)}$

(ID 4093)

In the critical case where the system becomes stable the number of latex E will not vary

$\displaystyle\frac{dE}{dt}=\displaystyle\frac{\beta C}{N}I(t)S(t)-(\sigma+\mu_d)E(t)$



and the infected I

$\displaystyle\frac{dI}{dt}=\sigma E(t)-(\gamma+\mu_d)I(t)$



where S is the number of susceptible, \beta is the probability of infecting, C number of contacts, N population number, \gamma is the recovery factor, \mu_b the birth factor and \mu_d the death factor.

The number of critical latents can be cleared from the second equation

$\displaystyle\frac{E_{crit}}{N}=\displaystyle\frac{(\gamma+\mu_d)}{\sigma}\displaystyle\frac{I_{crit}}{N}$



If this value is replaced in the first equation, the critical value for the susceptible ones is obtained

$\displaystyle\frac{S_{crit}}{N}=\displaystyle\frac{(\sigma+\mu_d)(\gamma+\mu_d)}{\beta C\sigma}$

which corresponds to the situation in which the infected curve reaches its maximum. In other words, the number of critically susceptible is the number of susceptible that remain at the moment that the number of infected reaches its maximum.

(ID 4090)

From the equation of the infected I

$\displaystyle\frac{dI}{dt}=\sigma E(t)-(\gamma+\mu_d)I(t)$



where \gamma is the recovery factor, \sigma the latent to infected step factor, E the latent ones and \mu_d the factor of the dead.

As the number of susceptible in the critical case is

$\displaystyle\frac{I_{crit}}{N}=\displaystyle\frac{\mu_bN-\mu_dS_{crit}}{{\beta C S_{crit}}}$



you can calculate the critical number of those infected

$\displaystyle\frac{E_{crit}}{N}=\displaystyle\frac{(\gamma+\mu_d)}{\sigma}\displaystyle\frac{I_{crit}}{N}$

which corresponds to the situation in which the infected curve reaches its maximum. In other words, the number of critical latents is the number of latents that remain at the moment that the number of infected reaches its maximum.

(ID 4092)

From the equation of the susceptible S

$\displaystyle\frac{dS}{dt}=-\displaystyle\frac{\beta C}{N}I(t)S(t)+\mu_bN-\mu_dS(t)$



where \beta is the probability of infection, C the number of contacts, N the number of the population, I those infected, \mu_b the factor of births and \mu_d the factor of the dead.

As the number of susceptible in the asymptotic case is

$\displaystyle\frac{S_{crit}}{N}=\displaystyle\frac{(\sigma+\mu_d)(\gamma+\mu_d)}{\beta C\sigma}$



the asymptotic number of those infected can be calculated

$\displaystyle\frac{I_{crit}}{N}=\displaystyle\frac{\mu_bN-\mu_dS_{crit}}{{\beta C S_{crit}}}$

(ID 4091)

In the case of SEIR models there are four curves, that of susceptible, latent, infected and recovered:

(ID 9703)

The model can solve numerically the equations for susceptible S, infected I, latent E and recovered R:

$\displaystyle\frac{dS}{dt}=-\displaystyle\frac{\beta C}{N}I(t)S(t)+\mu_bN-\mu_dS(t)$



$\displaystyle\frac{dE}{dt}=\displaystyle\frac{\beta C}{N}I(t)S(t)-(\sigma+\mu_d)E(t)$



$\displaystyle\frac{dI}{dt}=\sigma E(t)-(\gamma+\mu_d)I(t)$



$\displaystyle\frac{dR}{dt}=\gamma I(t)-\mu_dR(t)$

where t is the time \beta the cup of contagion, \sigma the cup of emergence of the symptoms in the infected, \gamma the recovery rate, C the number of contacts, N the population, \mu_b per capita birth rate and \mu_d per capita mortality.

(ID 6834)

ID:(349, 0)