Ethical statement

To address potential concerns about ethical issues, we took sequential steps to protect our survey participants. First, all field interviewers and research staff signed a confidentiality agreement not to disclose any personal information from the sample list, which was destroyed after the interviews. Second, for participants aged <9 years, we asked a parent or guardian to answer the questions on the child's behalf. Third, written informed consent was required from the participants prior to the interviews; for those aged <18 years, a parent or guardian supplied the written consent. Fourth, we maintained the anonymity of all individual survey results and kept no identifiable personal information (including the names listed in the contact diaries). Finally, we destroyed all the completed paper questionnaires after data cleaning [Reference Fu, Wang and Chuang11]. The study and further data analysis were approved by the IRB at Academia Sinica, Taiwan (AS-IRB-HS 02-13020).

Survey design

We adopted practices associated with previous large-scale social surveys in Taiwan to collect a representative survey sample of 24-h contact diaries from the whole population [Reference Fu, Wang and Chuang11, Reference Smith14, Reference Chang and Fu15]. In April–July 2010, we launched an in-person household survey to investigate Taiwan residents' knowledge and experiences regarding H1N1 influenza. To understand how contact patterns are linked to the transmission of influenza, we added contact diaries that were slightly revised from those in similar studies in Europe and Asia [Reference Edmunds16–Reference Mossong21]. For each physical contact and each face-to-face contact with at least three words spoken within 2 m (up to 40 persons because of the survey's space and time limitations), respondents recorded information about the location, duration, and initiation, among other contact features, of the contact. By providing no age limit to our sample, we targeted Taiwan's residents of all ages.

This representative survey was facilitated by three-stage probability sampling: first by selecting 34 out of Taiwan's 358 towns and cities, then by identifying two villages or precincts from each sampled town or city, and finally by randomly choosing 28–86 residents from each village or precinct. In this final stage, we relied on a computer file that recorded all residents listed in the Household and Population Register [Reference Fu, Wang and Chuang11]. We allowed no substitute respondents during the field interviews and finished the survey with 1943 24-h contact diaries, yielding a response rate of about 51·3%.

To ensure the representativeness of our sample, we employed the following measures before and after the survey. First, we checked the demographics of our targeted sample against those of Taiwan's population with a test of goodness of fit and found no significant differences in any of the distributions for gender, age group, or the interaction between gender and age group. Second, another test showed that our ‘completed sample’ did not differ from the ‘non-respondents sample’ in gender and region of residence, although younger people were underrepresented in the completed sample and the elderly were slightly overrepresented, a common problem in social surveys. We used a weighted sample to partly alleviate such a potential bias. Third, we investigated the reasons for non-response according to the standard definition employed by the World Association of Public Opinion Research (http://wapor.org/standards-definitions/). The non-response was due to ‘no contact with selected person’, ‘personal refusal’, as well as other reasons, such as untraceable addresses or no contact at the selected address.

In addition, we cross-checked several major indicators from our findings with both official records and results from similar studies. The records of Taiwan's CDC showed that about 72% of the population aged 7–18 years received a H1N1 vaccination during the 2009–2010 season [Reference Huang22], compared to 74% in our completed sample. Furthermore, our 24-h diaries recorded 12·5 contact partners per survey participant, which was only slightly higher than the 12·1 partners (with non-fleeting, face-to-face contacts) averaged in 4776 diaries from a comprehensive, long-term contact diary study in Taiwan [Reference Fu23]. Finally, in our completed sample, about 4·0% of the diaries reached the upper cut-off point of 40 partners, while in the long-term contact diary study, which employed no upper limit, about 5·2% showed ⩾40 partners. Even though setting an upper cut-off point may cause concern about censoring, such a low percentage should not affect estimates markedly.

Weather data and study cases

We collected daily weather data, including precipitation, average temperature, temperature range (the gap between high and low temperature), and absolute humidity, from the Central Weather Bureau, Taiwan. A total of 13 local weather stations were identified to cover the 34 townships where 1942 study cases (i.e. all but one of our survey respondents) were located. We matched all these study cases to the corresponding counties' or cities' weather stations with the weather conditions on the day when they reported contact diaries (from April to July 2010). To compare contact changes under various weather conditions, we defined four types of weather conditions by classifying the weather variables of temperature, humidity, and precipitation into two conditions (either high or low) as follows. Temperature was classified as high when the daily temperature averaged >28°C. The cut-off point was chosen according to Taiwan's environmental policies and guidelines for using air conditioning when the temperature reaches 28°C. Temperature range was treated as high when the daily temperature range was >6·5°C, which was the median of daily temperature ranges. Absolute humidity H (g/m³) was calculated by the following formula [Reference Owen and Terrill24]: H = 1000 × k × e _v /(T + d), where k = 0·21 668, d = 273, e _v is vapour pressure (hPa) and T is temperature (°C). The median of 19·9 g/m³ was chosen as the threshold for distinguishing high and low absolute humidity. High precipitation refers to days when the rainfall was at least 50 mm, which is the Central Weather Bureau's definition for ‘heavy rain’ in Taiwan [Reference Chen25].

Model-free estimate of contact change

Our contact diaries yielded data similar to those analysed by Willem et al. [Reference Willem10]. To better compare our findings from the tropical weather conditions with those temperate zones, we applied the same formulae to calculate relative changes in the average number of contacts and reproduction number R ₀, and analysed how contact patterns varied by the weather conditions with these two measures. Willem et al. first divided the contacts of each respondent into several categories by the contacted person's age and then calculated both the mean contact number and the reproduction number. For each contact pattern, the mean number of contacts in age group j during one day reported by a respondent in age group i is estimated by $\hat m_{ij} $ in equation (4) of Willem et al. [Reference Willem10], which is expressed as:

$$\hat m_{ij} = \sum\nolimits_{t = 1}^{T_i} {w_t^d\, y_{ijt}} /\! \sum\nolimits_{t = 1}^{T_i} {w_t^d,} $$

where T _i is the number of participants in age group i, y _ijt is the reported number of contacts made in the specific category by participant t of age group i with someone of age group j, and w _t ^d is the diary weight of participant t. The diary weights were calculated based on the participants' age and household size and the day of the week when the survey was taken. The weights were further constrained to a maximum of three to limit any single participant's influence [Reference Willem10]. The relative change in the number of contacts was then estimated by the ratio $\sum _{ij} \hat m_{ij}^a /\sum _{ij} \hat m_{ij}^b $ , where indices a and b refer to the contacts that took place under two different conditions along the same weather dimension. The relative change in the reproduction number in equation (7) of Willem et al. [Reference Willem10] can be simplified and estimated, with the assumption of the proportionality factor being constant, by the ratio of the maximum eigenvalue of C^a to that of C^b , where the element of the C matrix is $c_{ij}= (\hat m_{ij} /N_j+ \hat m_{ji} /N_i )/2$ and N _j is the population size in age group j. We used a non-parametric bootstrap method to calculate 95% confidence intervals for the two measures of relative changes [Reference Goeyvaerts26]. We generated 10 000 bootstrap samples through resampling with replacements from the participants, stratified by age group. For each bootstrap sample, we re-calculated the diary weights and used the same procedures as those in Willem et al. to estimate the relative change. The 2·5th percentile and 97·5th percentile of the 10 000 bootstrapped relative changes are the lower and upper limits of the 95% bootstrap confidence interval, respectively.

Model-based estimate of contact change

To obtain better estimates of the relative change in the number of contacts, we proposed a model-based approach for controlling socio-demographic background and other individual characteristics collected in a questionnaire along with the contact diaries. In particular, we used the following variables for this purpose: household size, age, gender, region of the residence, a BIG-5 personality item (extraversion; we treated ‘being very extraverted and sociable’ as the base category, with three less extraverted and sociable groups as dummy variables), mental health (CMQ-12) [Reference Fu27], happiness, and school holiday (July). Because these background factors were also expected to influence social contact patterns [Reference Fu, Wang and Chuang11, Reference Fu28], controlling for them in a regression model allowed us to adjust potential confounders and achieve a better estimation of weather effects on the change in the average number of contacts.

In addition to the number of total contacts, all of the contacts were further divided by three criteria: membership (household, work/school, neither), contact duration (<15 min, 15–59 min, 1–4 h, >4 h), and the presence of physical contact (yes/no). Let Y _i denote the number of contacts with a specific pattern for respondent i. To take the overdispersion of the count data into account, we first fitted the data with negative binomial regression models, in which the mean can be expressed by the equation:

$$\eqalign{\log (\mu _i ) = & \alpha _0 + \alpha _1 \log (X_{i1} ) + \sum\nolimits_{\,j = 2}^8 {\sum\nolimits_{g = 2}^{G_j } {\alpha _{\,jg} I(X_{ij} = g)} } \cr & + \sum\nolimits_{l = 1}^5 {\beta _l B_{li} + \sum\nolimits_{l = 2}^5 {\gamma _l (B_{1i} \times B_{li} } } ).} $$

The first covariate, X _i1, is household size. The other covariates, X _ij , j = 2,…,8, are factors of G _j levels, including age group (ages 0–10, 11–18, 19–64, ⩾65 years), gender, region of residence, extraversion, mental health (CHQ-12 score ⩾3 vs. <3), happiness, and school holiday. In the mean equation, I(·) is an indicator function, and α _jg is the effect of level g compared to the baseline level 1of factor j. The second part of the mean equation is for modelling the weekday/weekend and four weather effects on contacts. We define dummy variables B _1i  = 1 when the subject was interviewed on a weekday, B _2i  = 1 if the daily average temperature was >28°C, B _3i  = 1 if the daily temperature range was >6·5°C, B _4i  = 1 if the daily absolute humidity was >19·9 g/m³, and B _5i  = 1 if it was a heavily rainy day. The parameters of interest β _l and β _l  + γ _l for l = 2, …, 5 correspond to effects of the four weather conditions on the number of contacts during weekends and weekdays, respectively.

Because there were high proportions of zero counts in some contact patterns, we also fitted the data with zero-inflated negative binomial regression models, in which the mean count was multiplied by 1 minus the proportion of zero, and written as E(Y _i ) = (1 − p _i )μ _i . We modelled the proportion of zero by logit(p _i ) = λ ₀ + λ ₁ W _i , where W _i is the total number of contacts of respondent i. Vuong's non-nested test was used to determine whether the zero-inflated negative binomial model was better than the negative binomial model for each data reference [Reference Vuong29]. The relative change of mean contact number between days with high weather conditions and days with low weather conditions during weekends and weekdays were estimated, respectively, by $\exp (\hat \beta _l )$ and $\exp (\hat \beta _l + \hat \gamma _l )$ , where $\hat \beta _l $ and $\hat \gamma _l $ for l = 2, …, 5 were the estimated coefficients. Since the estimate of relative change is an exponential of the coefficient of the model, we used a non-parametric bootstrap method to generate a 95% confidence interval of relative changes based on 10 000 bootstrap samples. The original sample of participants was stratified by age group, household size, and weekend/weekday into 4 × 11 × 2 = 88 categories. We drew a bootstrap sample from each category independently and then pooled the obtained bootstrap samples of the 88 categories to form a whole bootstrap sample to calculate model-based relative change estimates. The 2·5th percentile and the 97·5th percentile of the 10 000 bootstrapped relative changes are the lower and upper limits of the 95% bootstrap confidence interval, respectively.