Data from the herd

The PigIT project is a strategic research alliance founded to improve welfare and productivity in growing pigs using advanced information and communication technologies methods (Kristensen and Jensen, Reference Kristensen and Jensen2015). The BW data used in this study was collected on a commercial herd of finishing pigs within the PigIT project. The herd included a finisher unit with four large common pens, each with a maximum capacity of 400 pigs. Each large common pen measured 14.0 m by 9.0 m and included a main area for resting, two feeding areas with 18 feeding points each, and a slaughter collection area.

In this herd, the main area of each pen was separated from the feeding area and the slaughter collection area by a weight sorting system (Agrisys-Nedap, Groenlo, The Netherlands, graphically illustrated on Figure 1). Each time a pig wanted to enter the feeding area it had to pass through the weighing system. When a pig entered the weighing system, the scale doors closed, the pig was identified using an individual electronic ear tag, weight was recorded and then the system directed the pig to whichever feeding area it was assigned (based on weight). After feeding, pigs could exit the feeding area and enter the main area via a one-way door. Alternatively, once the pig reached slaughter weight it was automatically directed into the slaughter collection area. Any sick pigs, when identified by the herd caretaker, were moved to a section for sick animals.

Figure 1 Overview of the large common pen finisher unit that data was collected from for a study on daily changes in pig BW where (A) main area, (B) feeding area, (C) relief area, (D) sorting area, (E) weighing scale with 24-h lamp, (F) doors and (G) windows (from Krogsdahl Reference Krogsdahl2015).

In the studied farm all of the pigs originated from a cross-bred dam (Landrace×Yorkshire) and a pure bred sire (Duroc), which is a common combination in Denmark. Pigs entered the large common pen finisher unit in mixed-sex groups when they reached ~30 kg. The sex of weighed pigs was identified using electronic ear tags (gilts were marked with even numbers while barrows were marked with odd numbers). The pigs were allowed a 5-week adaptation period to learn the weight sorting system. During that time, all doors between the main area and feeding area were open. Following the adaption period, weight was recorded each time each pig entered the feeding area until slaughter. In the case that two pigs entered the scale simultaneously, BW was not registered. For each batch, BW data were registered from the time of turning on scales until the last pigs were sent to slaughter (example of all BW recordings for Batch 1 is presented in Figure 2). All pigs were fed ad libitum. For a detailed description of the feeding strategy, see Krogsdahl (Reference Krogsdahl2015).

Figure 2 Body weight of all pigs from Batch 1. Each line represents the BW of an individual pig.

In this study, BW measurements of pigs from Pen 1 (Batch 1, Batch 3, Batch 4, Batch 5) and Pen 2 (Batch 2) were obtained and analysed. Batches were observed during different seasons. Batch 1 and 2 were observed during winter, Batch 3 during spring, Batch 4 during summer and Batch 5 in autumn. A summary of all BW data used in this study is presented in Table 1. Altogether, 243,160 BW measurements were collected from 1710 pigs. All collected records were used in the analyses.

Table 1 Summary of data from five batches used in a study of daily pig growth

¹ Number of days from turning on the scales until the last recorded delivery of pigs from given pen to the slaughterhouse.

² Based on the first recorded observation.

³ The smaller number of observations was due to an error in saving data in the database.

Pigs were exposed to both natural light (placing of doors and windows marked in Figure 1) and artificial light (24-h lamp over weighing scale). The farm had a combi-diffuse ventilation system. Temperature in the production unit was regulated by the sprinklers that were installed above the main, feeding and collecting area and by the climate computer. Further descriptions of animals, labor and management can be found in Krogsdahl (Reference Krogsdahl2015).

Time corrections

In order to properly account for the diurnal pattern in all batches, the time of BW measurements was corrected for daylight saving time (DST). The DST indicator was obtained using the approach of Grolemund and Wickham (Reference Grolemund and Wickham2011), implemented in R. Time of each BW observation was checked for DST changes. If BW was observed during central European summer time, the time of observation was reduced by 1 h.

Due to the training period (when pigs were passing through scales without having their BW registered) the first initial BW information was obtained at 29 days after insertion in the pen. Therefore, for this analysis, the initial observation time ( $t_{0} {\equals}0$ ) was set at 696 h (29 days) after insertion.

Statistical analysis

Methods similar to Stygar and Kristensen (Reference Stygar and Kristensen2016) were used to describe the BW of pigs in the herd. The fixed part of the model presented by Stygar and Kristensen (Reference Stygar and Kristensen2016) was supplemented with fixed effects for the amplitude and frequency of a cosine wave (used to account for the diurnal pattern in daily BW). Due to the small number of observed batches (five consecutive batches were followed), it was not possible to estimate the random slope and intercept for the batch effect in the final model. Instead, the fit using generalized least squares method was applied to obtain a representation of the BW of a particular pig at a given hour. However, in order to account for the variation between batches, the final model was supplemented with interactions between batches and the fixed elements of the model. In summary, the full model used in the analyses of BW for pig i in batch j over time t was described as:

(1) $$\eqalignno{ y_{{ijt}} \, {\equals}\, & (\beta _{0} {\plus}q_{{0j}} ){\plus}(\beta _{1} {\plus}q_{{1j}} )t{\plus}q_{{2j}} t^{2} {\plus}(\beta _{2} {\plus}q_{{3j}} )\cos (wt)\cr & {\plus}(\beta _{3} {\plus}q_{{4j}} )\sin (wt){\plus}A_{{ijt}} {\plus}{\epsilon}_{{ijt}} \cr & \,A_{{ijt }} \: \sim\: N\left( {0, \sigma _{{At}}^{2} } \right),\,{\epsilon}_{{ijt}} \: \sim\: N\left( {0, \sigma _{t}^{2} } \right) $$

in which $$\beta _{0} ,\beta _{1} $$ are the fixed herd effects of intercept and time while $\beta _{2} $ and $\beta _{3} {\rm }$ are fixed effects for the cosine wave, $q_{{0j}} ,q_{{1j}} ,q_{{2j}} ,q_{{3j}} ,q_{{4j}} $ are the fixed effects of intercept, time, square value of time and cosine wave assumed independent for different batches, $A_{{ijt }} $ is a random effect of pig and ${\epsilon}_{{ijt}} $ is a random residual. Parameters $$\beta _{{2,}} \beta _{{3,}} q_{{3j}} $$ and $$q_{{4j}} $$ determine the amplitude and $w$ is the length of the cosine wave used to account for the diurnal pattern in daily BW. Here, $w$ is constant, does not vary with pig or batch, and was calculated as $$w\, {\equals}\, 2\pi \,/\,24$$ (representing exactly 1 day).

In addition, a gender coefficient was tested. The P-value for the gender coefficient suggested no significant differences between growth of gilts and barrows (P=0.52), and was therefore removed from the final model.

The model assumed that the within-batch errors are allowed to be heteroscedastic. The following models specifying within-group variance were tested: fixed variance, different variances per stratum, power of covariate, exponential of covariate and constant plus power of covariate. The model which successfully described the within-group variance was constant plus power of covariate. This variance model was given by the equation:

(2) $$\sigma _{{At}}^{2} {\plus}\sigma _{t}^{2} \, {\equals}\, \sigma _{A}^{2} \left( {\delta _{1} {\plus}\left| t \right|^{{\delta _{2} }} } \right)^{2} {\plus}\sigma ^{2} \left( {\delta _{1} {\plus}\left| t \right|^{{\delta _{2} }} } \right)^{2} $$

in which $\sigma _{A}^{2} $ is the variance in animal effect, $\sigma ^{2} $ is the variance in measurement error, $\delta _{1} $ and $\delta _{2} $ are constants for the variance model estimated from data.

Since the BW data consisted of repeated measurements on the same pigs, the pig effect was assumed to be a first order autoregressive process with mean 0 and autocorrelation $\rho $ so that

(3) $$A_{{ijt}} \, {\equals}\, \rho \left( {\sigma _{{At}} \,/\,\sigma _{{A,t{\minus}1}} } \right)A_{{ij,t{\minus}1}} {\plus}\omega _{{ijt}} $$

in which $\omega _{{ijt}} \: \sim\: N(0,(1{\minus}\rho ^{2} )\sigma _{{At}} ^{2} ).$

The observations of BW for pigs were not equally spaced in time. Therefore, similar to Pinheiro and Bates (Reference Pinheiro and Bates2000) we used continuous-time within-group correlation models, which naturally accommodate the imbalance in the data. Tested correlation models included: linear, rational quadratic, spherical, Gaussian and exponential. Similar to Stygar and Kristensen (Reference Stygar and Kristensen2016), the most adequate within-group correlation model for pig BW data was found when assuming that the correlation between BW measurements of a single pig decreases exponentially with time.

Following the approach of Pinheiro and Bates (Reference Pinheiro and Bates2000) the significance of terms used in the fixed effect model were tested by the conditional F-tests in the single-argument form of the ANOVA for fitted models. The ANOVA method was also used to test the significance of the heteroscedastic model. Spatial correlation models were compared based on information criteria statistics (Akaike information criterion and Bayesian information criterion).

For data analyses and plotting, the R statistical software (R Core Team, 2014) and nlme package (Pinheiro et al., Reference Pinheiro, Bates, DebRoy and Sarkar2017) was used.