Distributions of epidemic sizes computed in the complete, partial, baseline, and surrogate cases for the LSCH dataset. Each panel corresponds to , one value of the fraction of nodes with partial information [panels (a),(d) = 0.1; (b),(e) = 0.2; (c),(f) = 0.4] and one couple of spreading parameters: (a)–(c) and ; (d)–(f) and . For the partial, baseline, and surrogate cases, the symbols and lines show the median distribution of the epidemic size computed from the results relative to the 10 different sets of nodes with partial information, while the shaded area is delimited by the 25th and 75th percentiles.

Distributions of epidemic sizes computed in the complete, partial, baseline, and surrogate cases for the HT09 dataset. Each panel corresponds to , one value of the fraction of nodes with partial information [panels (a),(d) = 0.1; (b),(e) = 0.2; (c),(f) = 0.4] and one couple of spreading parameters: (a)–(c) β = 0.60 and μ = 0.10; (d)–(f) β = 0.25 and μ = 0.05. The symbols and lines show the median distribution of the epidemic size computed from the results relative to the 10 different sets of nodes with partial information, while the shaded area is delimited by the 25th and 75th percentiles.

Distributions of epidemic sizes computed in the complete, partial, baseline, and surrogate cases for the SFHH dataset. Each panel corresponds to , one value of the fraction of nodes with partial information [panels (a),(d) = 0.1; (b),(e) = 0.2; (c),(f) = 0.4] and one couple of spreading parameters: (a)–(c) β = 0.3 and μ = 0.10; (d)–(f) β = 0.25 and μ = 0.08. For the partial, baseline and surrogate cases, the symbols and lines show the median distribution of the epidemic size computed from the results relative to the 10 different sets of nodes with partial information, while the shaded area is delimited by the 25th and 75th percentiles.

Distributions of epidemic sizes computed in the complete, partial, baseline, and surrogate cases both using the NTF with only the partial network and also using the JNTF with auxiliary data for the LSCH data set. Each panel corresponds to a fixed fraction of nodes with increasing loss of information for nodes . The JNTF is computed on the two tensors representing the temporal social network of the LSCH data set and the related temporal location network. Here we report the epidemic size distributions of the complete, partial, and surrogate networks for SIR processes with two different couples of infection and recovery probabilities: (a)–(c) and and (d)–(f) and . In (c) and (f), as , no information can be gained on the nodes with missing data using simply NTF, so the results of the NTF-based method coincide with the ones obtained by simulating the SIR process over the network with partial information.

Results achieved by the surrogate construction method using the JNTF. Each panel corresponds to the case in which and . The JNTF is computed on the two tensors representing the temporal human proximity network of the LSCH data set and the related temporal location network. Here we report the results for two different couples of infection and recovery probabilities: (a) and and (b) and . The symbols and lines show the median distributions of epidemic sizes computed over the ten random generations of the missing times, while the shaded area is delimited by the 25th and 75th percentiles.

Outcome of an SIR process: over the complete network, the partial network and the network approximated through the NTF for the LSCH dataset. Each panel corresponds to one fraction of nodes with partial information (, , and ) and one couple of spreading parameters: (a)–(c) and ; (d)–(f) and . The lines show the median distribution of the epidemic size computed from the results relative to 10 different sets of nodes with missing information, while the shaded area is delimited by the 25-th and 75-th percentiles.

Weight distributions in the (a) LSCH, (b) HT09, and (c) SFHH data sets for the complete network and the partial network with increasing percentage of nodes with missing information: and .

Distributions of epidemic sizes computed in the complete, partial, baseline and surrogate cases for the LSCH dataset, for a scenario in which data loss occurs at random times. Each panel corresponds to one value of the fraction of nodes with partial information (, , and ) and one couple of spreading parameters: (a)–(c) and ; (d)–(f) and . For the partial, baseline and surrogate cases, the symbols and lines show the median distribution of the epidemic size computed from the results relative to the 10 different sets of nodes with partial information, while the shaded area is delimited by the 25-th and 75-th percentiles.

Distributions of epidemic sizes computed in the complete, partial, baseline and surrogate cases for the HT09 dataset, for a scenario in which data loss occurs at random times. Each panel corresponds to one value of the fraction of nodes with partial information (, , and ) and one couple of spreading parameters: (a)–(c) and ; (d)–(f) and . The symbols and lines show the median distribution of the epidemic size computed from the results relative to the 10 different sets of nodes with partial information, while the shaded area is delimited by the 25-th and 75-th percentiles.

Distributions of epidemic sizes computed in the complete, partial, baseline and surrogate cases for the SFHH dataset, for a scenario in which data loss occurs at random times. Each panel corresponds to one value of the fraction of nodes with partial information (, , and ) and one couple of spreading parameters: (a)–(c) and ; (d)–(f) and . For the partial baseline, and surrogate cases, the symbols and lines show the median distribution of the epidemic size computed from the results relative to the 10 different sets of nodes with partial information, while the shaded area is delimited by the 25-th and 75-th percentiles.