infection: Susceptibility and Infection
In USCCANA/netdiffuseR: Analysis of Diffusion and Contagion Processes on Networks
View source: R/infect_suscept.r
infection R Documentation
Susceptibility and Infection
Description
Calculates infectiousness and susceptibility for each node in the graph
Usage
infection(
graph,
toa,
t0 = NULL,
normalize = TRUE,
K = 1L,
r = 0.5,
expdiscount = FALSE,
valued = getOption("diffnet.valued", FALSE),
outgoing = getOption("diffnet.outgoing", TRUE)
)
susceptibility(
graph,
toa,
t0 = NULL,
normalize = TRUE,
K = 1L,
r = 0.5,
expdiscount = FALSE,
valued = getOption("diffnet.valued", FALSE),
outgoing = getOption("diffnet.outgoing", TRUE)
)
Arguments
graph
A dynamic graph (see netdiffuseR-graphs).
toa
Integer vector of length n with the times of adoption.
t0
Integer scalar. See toa_mat.
normalize
Logical. Whether or not to normalize the outcome
K
Integer scalar. Number of time periods to consider
r
Numeric scalar. Discount rate used when expdiscount=TRUE
expdiscount
Logical scalar. When TRUE, exponential discount rate is used (see details).
valued
Logical scalar. When TRUE weights will be considered. Otherwise non-zero values will be replaced by ones.
outgoing
Logical scalar. When TRUE, computed using outgoing ties.
Details
Normalization, normalize=TRUE, is applied by dividing the
resulting number from the infectiousness/susceptibility stat
by the number of individuals who adopted the innovation at
time t.
Given that node i adopted the innovation in time t, its
Susceptibility is calculated as follows
S_i = \frac{%
\sum_{k=1}^K\sum_{j=1}^n x_{ij(t-k+1)}z_{j(t-k)}\times \frac{1}{w_k}}{%
\sum_{k=1}^K\sum_{j=1}^n x_{ij(t-k+1)}z_{j(1\leq t \leq t-k)} \times \frac{1}{w_k} }\qquad \mbox{for }i,j=1,\dots,n\quad i\neq j
where x_{ij(t-k+1)} is 1 whenever there's a link from i
to j at time t-k+1, z_{j(t-k)}
is 1 whenever individual j adopted the innovation at time t-k,
z_{j(1\leq t \leq t-k)} is 1 whenever
j had adopted the innovation up to t-k, and w_k is
the discount rate used (see below).
Similarly, infectiousness is calculated as follows
I_i = \frac{%
\sum_{k=1}^K \sum_{j=1}^n x_{ji(t+k-1)}z_{j(t+k)}\times \frac{1}{w_k}}{%
\sum_{k=1}^K \sum_{j=1}^n x_{ji(t+k-1)}z_{j(t+k\leq t \leq T)}\times \frac{1}{w_k} }\qquad \mbox{for }i,j=1,\dots,n\quad i\neq j
It is worth noticing that, as we can see in the formulas, while susceptibility
is from alter to ego, infection is from ego to alter.
When outgoing=FALSE the algorithms are based on incoming edges, this is
the adjacency matrices are transposed swapping the indexes (i,j) by
(j,i). This can be useful for some users.
Finally, by default both are normalized by the number of individuals who
adopted the innovation in time t-k. Thus, the resulting formulas,
when normalize=TRUE, can be rewritten as
%
S_i' = \frac{S_i}{\sum_{k=1}^K\sum_{j=1}^nz_{j(t-k)}\times \frac{1}{w_k}} %
\qquad I_i' = \frac{I_i}{\sum_{k=1}^K\sum_{j=1}^nz_{j(t-k)} \times\frac{1}{w_k}}
For more details on these measurements, please refer to the vignette titled
Time Discounted Infection and Susceptibility.
Value
A numeric column vector (matrix) of size n with either infection/susceptibility rates.
Discount rate
Discount rate, w_k in the formulas above, can be either exponential
or linear. When expdiscount=TRUE, w_k = (1 + r)^{k-1}, otherwise
it will be w_k = k.
Note that when K=1, the above formulas are equal to the ones presented
in Valente et al. (2015).
Author(s)
George G. Vega Yon
References
Thomas W. Valente, Stephanie R. Dyal, Kar-Hai Chu, Heather Wipfli, Kayo
Fujimoto Diffusion of innovations theory applied to global tobacco control
treaty ratification, Social Science & Medicine, Volume 145, November 2015,
Pages 89-97, ISSN 0277-9536
\Sexpr[results=rd]{tools:::Rd_expr_doi("10.1016/j.socscimed.2015.10.001")}
Myers, D. J. (2000). The Diffusion of Collective Violence: Infectiousness,
Susceptibility, and Mass Media Networks. American Journal of Sociology, 106(1),
173–208. \Sexpr[results=rd]{tools:::Rd_expr_doi("10.1086/303110")}
See Also
The user can visualize the distribution of both statistics
by using the function plot_infectsuscep
Other statistics:
bass,
classify_adopters(),
cumulative_adopt_count(),
dgr(),
ego_variance(),
exposure(),
hazard_rate(),
moran(),
struct_equiv(),
threshold(),
vertex_covariate_dist()
Examples
# Creating a random dynamic graph
set.seed(943)
graph <- rgraph_er(n=100, t=10)
toa <- sample.int(10, 100, TRUE)
# Computing infection and susceptibility (K=1)
infection(graph, toa)
susceptibility(graph, toa)
# Now with K=4
infection(graph, toa, K=4)
susceptibility(graph, toa, K=4)
USCCANA/netdiffuseR documentation built on Sept. 5, 2023, 12:31 a.m.
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View source: R/infect_suscept.r
| infection | R Documentation |
Susceptibility and Infection
Description
Calculates infectiousness and susceptibility for each node in the graph
Usage
infection(
graph,
toa,
t0 = NULL,
normalize = TRUE,
K = 1L,
r = 0.5,
expdiscount = FALSE,
valued = getOption("diffnet.valued", FALSE),
outgoing = getOption("diffnet.outgoing", TRUE)
)
susceptibility(
graph,
toa,
t0 = NULL,
normalize = TRUE,
K = 1L,
r = 0.5,
expdiscount = FALSE,
valued = getOption("diffnet.valued", FALSE),
outgoing = getOption("diffnet.outgoing", TRUE)
)
Arguments
graph |
A dynamic graph (see |
toa |
Integer vector of length |
t0 |
Integer scalar. See |
normalize |
Logical. Whether or not to normalize the outcome |
K |
Integer scalar. Number of time periods to consider |
r |
Numeric scalar. Discount rate used when |
expdiscount |
Logical scalar. When TRUE, exponential discount rate is used (see details). |
valued |
Logical scalar. When |
outgoing |
Logical scalar. When |
Details
Normalization, normalize=TRUE, is applied by dividing the
resulting number from the infectiousness/susceptibility stat
by the number of individuals who adopted the innovation at
time t.
Given that node i adopted the innovation in time t, its
Susceptibility is calculated as follows
S_i = \frac{%
\sum_{k=1}^K\sum_{j=1}^n x_{ij(t-k+1)}z_{j(t-k)}\times \frac{1}{w_k}}{%
\sum_{k=1}^K\sum_{j=1}^n x_{ij(t-k+1)}z_{j(1\leq t \leq t-k)} \times \frac{1}{w_k} }\qquad \mbox{for }i,j=1,\dots,n\quad i\neq j
where x_{ij(t-k+1)} is 1 whenever there's a link from i
to j at time t-k+1, z_{j(t-k)}
is 1 whenever individual j adopted the innovation at time t-k,
z_{j(1\leq t \leq t-k)} is 1 whenever
j had adopted the innovation up to t-k, and w_k is
the discount rate used (see below).
Similarly, infectiousness is calculated as follows
I_i = \frac{%
\sum_{k=1}^K \sum_{j=1}^n x_{ji(t+k-1)}z_{j(t+k)}\times \frac{1}{w_k}}{%
\sum_{k=1}^K \sum_{j=1}^n x_{ji(t+k-1)}z_{j(t+k\leq t \leq T)}\times \frac{1}{w_k} }\qquad \mbox{for }i,j=1,\dots,n\quad i\neq j
It is worth noticing that, as we can see in the formulas, while susceptibility is from alter to ego, infection is from ego to alter.
When outgoing=FALSE the algorithms are based on incoming edges, this is
the adjacency matrices are transposed swapping the indexes (i,j) by
(j,i). This can be useful for some users.
Finally, by default both are normalized by the number of individuals who
adopted the innovation in time t-k. Thus, the resulting formulas,
when normalize=TRUE, can be rewritten as
%
S_i' = \frac{S_i}{\sum_{k=1}^K\sum_{j=1}^nz_{j(t-k)}\times \frac{1}{w_k}} %
\qquad I_i' = \frac{I_i}{\sum_{k=1}^K\sum_{j=1}^nz_{j(t-k)} \times\frac{1}{w_k}}
For more details on these measurements, please refer to the vignette titled Time Discounted Infection and Susceptibility.
Value
A numeric column vector (matrix) of size n with either infection/susceptibility rates.
Discount rate
Discount rate, w_k in the formulas above, can be either exponential
or linear. When expdiscount=TRUE, w_k = (1 + r)^{k-1}, otherwise
it will be w_k = k.
Note that when K=1, the above formulas are equal to the ones presented
in Valente et al. (2015).
Author(s)
George G. Vega Yon
References
Thomas W. Valente, Stephanie R. Dyal, Kar-Hai Chu, Heather Wipfli, Kayo Fujimoto Diffusion of innovations theory applied to global tobacco control treaty ratification, Social Science & Medicine, Volume 145, November 2015, Pages 89-97, ISSN 0277-9536 \Sexpr[results=rd]{tools:::Rd_expr_doi("10.1016/j.socscimed.2015.10.001")}
Myers, D. J. (2000). The Diffusion of Collective Violence: Infectiousness, Susceptibility, and Mass Media Networks. American Journal of Sociology, 106(1), 173–208. \Sexpr[results=rd]{tools:::Rd_expr_doi("10.1086/303110")}
See Also
The user can visualize the distribution of both statistics
by using the function plot_infectsuscep
Other statistics:
bass,
classify_adopters(),
cumulative_adopt_count(),
dgr(),
ego_variance(),
exposure(),
hazard_rate(),
moran(),
struct_equiv(),
threshold(),
vertex_covariate_dist()
Examples
# Creating a random dynamic graph
set.seed(943)
graph <- rgraph_er(n=100, t=10)
toa <- sample.int(10, 100, TRUE)
# Computing infection and susceptibility (K=1)
infection(graph, toa)
susceptibility(graph, toa)
# Now with K=4
infection(graph, toa, K=4)
susceptibility(graph, toa, K=4)
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