DySIS

The DySIS (Dynamic SIS) Model extends the classical SIS model to time-varying networks. Instead of a fixed graph \(G=(V,E)\), diffusion evolves on a sequence of graph snapshots \(\{G^{(k)}=(V,E^{(k)})\}_{k=1}^{T}\), where the edge set \(E^{(k)}\) may change at each discrete time step \(k\). Each node is in one of two states: \(S\) (susceptible) or \(I\) (infected).

A susceptible node \(i\) can be infected by infected neighbors \(j \in N^{(k)}(i)\) with infection rate \(\beta\); meanwhile an infected node recovers and becomes susceptible again with rate \(\lambda\):

\[\begin{split}\begin{aligned} \frac{dS_i}{dt}\bigg|_{t=k} &= -\beta \sum_{j\in N^{(k)}(i)} S_i I_j + \lambda I_i, \\ \frac{dI_i}{dt}\bigg|_{t=k} &= \beta \sum_{j\in N^{(k)}(i)} S_i I_j - \lambda I_i . \end{aligned}\end{split}\]

Compared with the static SIS model on a single graph, the DySIS model captures the impact of evolving topology on transmission and recovery dynamics. The number of simulation steps is bounded by the length of the snapshot sequence \(T\).

Implementation

Node transitions follow two rules:

if a \(S\) state node has \(I\) state neighbors in the current snapshot, each \(I\) state neighbor transmits the infection to the \(S\) state node with probability \(\beta\);
the \(I\) state node recovers and becomes susceptible with probability \(\lambda\).

Node states are represented by a Boolean indicator vector \(h \in \{0,1\}^N\), where \(h_i=1\) denotes infected and \(h_i=0\) denotes susceptible. The update of the system at step \(k\) is decomposed into three stages:

1) Each infected neighbor \(j\) of node \(i\) in the current snapshot \(G^{(k)}\) transmits a log-probability contribution

\[m_{ji}^{(k)} = h_j^{(k-1)} \cdot \log\!\bigl(1-\beta\,w_{ji}^{(k)}\bigr)\]

where \(w_{ji}^{(k)}=1\) if edge weights are not provided.

Node \(i\) collects contributions from neighbors \(N^{(k)}(i)\) to compute its infection probability

\[m_i^{(k)} = 1 - \exp\!\left( \sum_{j \in N^{(k)}(i)} m_{ji}^{(k)} \right)\]

3) The indicator variable is updated with independent uniform random variables \(U_i^{\mathrm{inf}}, U_i^{\mathrm{rec}} \sim \mathrm{Uniform}(0,1)\):

\[\begin{split}\begin{aligned} h_i^{(k)} &= \begin{cases} 1, & \text{if } h_i^{(k-1)}=0 \land (U_i^{\mathrm{inf}} < m_i^{(k)}), \\[4pt] 0, & \text{if } h_i^{(k-1)}=1 \land (U_i^{\mathrm{rec}} < \lambda), \\[4pt] h_i^{(k-1)}, & \text{otherwise}. \end{cases} \end{aligned}\end{split}\]

As in other dynamic models, \(N^{(k)}(i)\) and optional edge weights \(w_{ji}^{(k)}\) are time-dependent and taken from the \(k\)-th snapshot. The total number of iterations is bounded by \(T =\) len(edge_index_list).

Status

During the simulation, a node can be in one of the following states:

Status	Code
Susceptible	0
Infected	1

DySISModel

class fs_gplib.Dynamic.DySISModel(x, edge_index_list, seeds, infection_beta: float, recovery_lambda: float, device='cpu', rand_seed=None, edge_attr_list=None)[source]

Bases: DiffusionModel

Dynamic SIS (DySIS) epidemic model on time-varying networks (dynamic network models).

This model extends the classical static SIS dynamics (see the epidemic SISModel) to a sequence of graph snapshots \(\{G^{(k)}=(V,E^{(k)})\}_{k=1}^{T}\). At step \(k\), a susceptible node may be infected by infected neighbors in \(N^{(k)}(i)\) with probability \(\beta\) per contact (optionally scaled by snapshot edge weights in edge_attr_list), and an infected node may recover to susceptible with probability \(\lambda\).

The number of simulation steps cannot exceed len(edge_index_list). As with other dynamic models, pass an explicit node tensor x (shape (N, 1)) and edge_index_list (and optional edge_attr_list) rather than a single PyG Data object.

Parameters:

x (torch.Tensor) -- Node feature tensor of shape (N, 1) (node count \(N\) from the leading dimension).
edge_index_list (list[torch.Tensor]) -- One edge_index tensor per snapshot, length \(T\), defining \(E^{(k)}\) at each step.
seeds (list[int] | float) -- Initially infected nodes: a list of integer node IDs, or a float in (0, 1) to infect that fraction of nodes uniformly at random.
infection_beta (float) -- Per-contact infection probability \(\beta \in [0, 1]\).
recovery_lambda (float) -- Per-step recovery probability \(\lambda \in [0, 1]\) for infected nodes.
device (str | int) -- (optional) 'cpu' or a CUDA device index. Defaults to 'cpu'.
rand_seed (int | None) -- (optional) Random seed used when seeds is a float. Defaults to None.
edge_attr_list (list[torch.Tensor] | None) -- (optional) One edge-weight tensor per snapshot, aligned with edge_index_list. If None, weights are 1.

run_iteration()[source]

Advance the epidemic by one snapshot step.

The internal node_status is updated so that subsequent calls continue from the latest state. Requires at least one remaining snapshot.

Returns:: State tensor after that step, shape (1, 1, N).
Return type:: torch.Tensor

run_iterations(times)[source]

Run times consecutive snapshot steps on the evolving graph sequence.

The internal node_status is updated to the state after the last step. Requires len(edge_index_list) - t >= times where \(t\) is the number of steps already consumed on this process.

Parameters:: times (int) -- Number of snapshots to advance (must not exceed remaining snapshots).
Returns:: States after each of the times steps, stacked with shape (times, 1, N).
Return type:: torch.Tensor

run_epoch()[source]

Run one Monte-Carlo realisation over the full snapshot sequence.

The process internal step counter is reset; node states are re-initialised before the epoch starts.

Returns:: State trajectory over all snapshots, shape (T, 1, N) with \(T =\) len(edge_index_list).
Return type:: torch.Tensor

run_epochs(epochs, batch_size=200)[source]

Run multiple independent Monte-Carlo realisations in batches.

For each realisation the snapshot index is reset to the beginning and the epidemic is evolved through all snapshots. Node states are re-initialised before the run.

Parameters:

epochs (int) -- Total number of independent realisations.
batch_size (int) -- (optional) Parallel epochs per batch. Defaults to 200.

Returns:

Trajectories for all realisations, shape (T, E, N) where \(T =\) len(edge_index_list) and \(E\) is epochs.

Return type:

torch.Tensor

Note

Unlike the static SIS model which accepts a single data object containing edge_index and edge_attr, the DySIS model requires an explicit node tensor x and a list of edge index tensors edge_index_list representing the dynamic network snapshots. Edge weights are similarly provided as a list edge_attr_list.