Reed–Frost model

The Reed–Frost model is a mathematical model of epidemics put forth in the 1920s by Lowell Reed and Wade Hampton Frost, of Johns Hopkins University.[1][2] While originally presented in a talk by Frost in 1928 and used in courses at Hopkins for two decades, the mathematical formulation was not published until the 1950s, when it was also made into a TV episode.

Description

This is an example of a "chain binomial" model, a simplified, iterative model of how an epidemic will behave over time.

The Reed–Frost model is one of the simplest stochastic epidemic models. It was formulated by Lowell Reed and Wade Frost in 1928 (in unpublished work) and describes the evolution of an infection in generations. Each infected individual in generation t (t = 1,2,...) independently infects each susceptible individual in the population with some probability p. The individuals that become infected by the individuals in generation t then constitute generation t + 1 and the individuals in generation t are removed from the epidemic process.[3]

The Reed–Frost model is based on the following assumptions:[4]

  1. The infection is spread directly from infected individuals to others by a certain type of contact (termed "adequate contact") and in no other way.
  2. Any non-immune individual in the group, after such contact with an infectious individual in a given period, will develop the infection and will be infectious to others only within the following time period; in subsequent time periods, he is wholly and permanently immune.
  3. Each individual has a fixed probability of coming into adequate contact with any other specified individual in the group within one time interval, and this probability is the same for every member of the group.
  4. The individuals are wholly segregated from others outside the group. (It is a closed population.)
  5. These conditions remain constant during the epidemic.

The following parameters are set initially:

  • Size of the population
  • Number of individuals already immune
  • Number of cases (usually set at 1)
  • Probability of adequate contact

With this information, a simple formula allows the calculation of how many individuals will be infected, and how many immune, in the next time interval. This is repeated until the entire population is immune, or no infective individuals remain. The model can then be run repeatedly, adjusting the initial conditions, to see how these affect the progression of the epidemic.

The probability of adequate contact corresponds roughly with R0, the basic reproduction number – in a large population when the initial number of infecteds is small, an infected individual is expected to cause new cases.

Mathematics

Let represent the number of cases of infection at time . Assume all cases recover or are removed in exactly one time-step. Let represent the number of susceptible individuals at time . Let be a Bernoulli random variable that returns with probability and with probability . Making use of the random-variable multiplication convention, we can write the Reed–Frost model as

with initial number of susceptible and infected individuals given. Here, is the probability that a person comes in contact with another person in one time-step and that that contact results in disease transmission.

The deterministic limit is (found by replacing the random variables with their expectations),

gollark: Well there you go.
gollark: (is completely useless since *you cannot do that*)
gollark: No, it has a limit imposed by mekanism itself.
gollark: I believe you'll hit the limit of "how many induction whatevers can I cram in" before "how is this storing energy".
gollark: The limit is likely to be their maximum size.

See also

References

  1. Schwabe CW, Riemann HP, Franti CE. (1977). Epidemiology in Veterinary Practice. Lea & Febiger. pp. 258–260
  2. Abbey, Helen (1952). "An examination of the Reed-Frost theory of epidemics". Hum. Biol. 3:201
  3. Deijfen, Maria. "Epidemics and vaccination on weighted graphs". arXiv:1101.4154.
  4. "Reed–Frost Epidemic Model". Ohio Supercomputer Center.
  • Johns Hopkins science review. Epidemic theory : what is it?
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