Understanding factors affecting growth rates in swine is important in the productivity of pig farms. We herein propose machine learning-based schemes to predict the average daily gain (ADG) of pig weight using temperature, humidity, feed intake, and the current weight of the pig. In order to address the lack of available growth data for pigs, we generate a synthetic dataset describing the weight of swine in relation to environmental factors based on the theoretical growth model and experimentally measured data, in an attempt to facilitate the application of machine learning techniques. Using the generated growth data, linear regression, tree regression, adaptive boosting (AdaBoost), and a deep neural network (DNN) are applied to estimate ADG. By means of a performance evaluation, we confirm that the machine learning algorithms are capable of predicting the ADG of swine accurately even when the growth characteristics of pigs are heterogeneous, i.e., each pig follows a different growth curve. Moreover, we also find that DNN can provide a higher predictive accuracy than other machine learning-based schemes.
Y.S.Kim, S.W.Kim, M.A.Weaver and C.Y.Lee, Increasing the pig market weight: World trends, expected consequences and practical considerations, Asian-Australasian Journal of Animal Sciences18 (2005), 590–600.
2.
M.J.Park, B.C.Park, D.M.Ha, J.B.Kim, K.S.Jang, D.H.Lee, G.T.Kim, S.K.Jin and C.Y.Lee, Effects of increasing market weight of finishing pigs on backfat thickness, incidence of the 'caky-fatty' belly, carcass grade, and carcass quality traits, Journal of Animal Science and Technology55 (2013), 195–202.
3.
C.F.M.De Lange, B.J.Marty, S.Birkett, P.Morel and B.Szkotnicki, Application of pig growth models in commercial pork production, Canadian Journal of Animal Science81 (2001), 1–8.
4.
T.L.Ward, K.L.Watkins, L.L.Southern, P.G.Hoyt and D.D.French, Interactive effects of sodium zeolite-a and copper in growing swine: Growth, and bone and tissue mineral concentrations, Journal of animal science69 (1991), 726–733.
5.
C.M.Shull, Modeling Growth of Pigs Reared to Heavy Weights, Ph. D. Dissertation,University of Illinois at Urbana-Champaign, 2015.
6.
A.P.Schinckel, J.Ferrel, M.E.Einstein, S.M.Pearce and R.D.Boyd, Analysis of pig growth from birth to sixty days of age, The Professional Animal Scientist20 (2004), 79–86.
7.
J.Luo, H.Lei, L.Shen, R.Yang, Q.Pu, K.Zhu, M.Li, G.Tang, X.Li, S.Zhang and L.Zhu, Estimation of growth curves and suitable slaughter weight of the liangshan pig, Asian-Australasian Journal of Animal Sciences28 (2015), 1252–1258.
8.
G.Kusec, G.Kralik, R.Scitovski, D.Vincek and U.Baulain, Growth characteristics of hybrid pig predicted by means of asymmetric S-curve, Poljoprivreda14 (2008), 55–61.
9.
D.Vincek, K.Sabo, G.Kusec, G.Kralik, I.Durkin and R.Scitovski, Modeling of pig growth by S-function -least absolute deviation approach for parameter estimation, Archiv Tierzucht55 (2012), 364–374.
10.
J.A.A.Camargo, Evaluating the Ability of the NE system to Predict Growth Performance and Energy Utilization of Growing Pigs, M.S. Dissertation,Iowa State University, 2015.
11.
S.Nitikanchana, S.S.Dritz, M.D.Tokach, J.M.DeR-ouchey, R.D.Goodband and B.J.White, Regression analysis to predict growth performance from dietary net energy in growing finishing pigs, Journal of Animal Science93 (2015), 2826–2839.
12.
J.Noblet, H.Fortune, X.S.Shi and S.Dubois, Prediction of net energy value of feeds for growing pigs, Journal of Animal Science72 (1994), 344–354.
13.
D.Y.Kil, F.Ji, L.L.Stewart, R.B.Hinson, A.D.Beaulieu, G.L.Allee, J.F.Patience, J.E.Pettigrew and H.H.Stein, Effects of dietary soybean oil on pig growth performance, retention of protein, lipids, and energy, and the net energy of corn in diets fed to growing or finishing pigs, Journal of Animal Science91 (2013), 3283–3290.
14.
D.Z.Caraviello, K.A.Weigel, M.Craven, D.Gianola, N.B.Cook, K.V.Nordlund and M.C.Wiltbank, Analysis of reproductive performance of lactating cows on large dairy farms using machine learning algorithms, Journal of Dairy Science89 (2006), 4703–4722.
15.
S.Shahinfar, D.Page, J.Guenther, V.Cabrera, P.Fricke and K.Weigel, Prediction of insemination outcomes in holstein dairy cattle using alternative machine learning algorithms, Journal of Dairy Science97 (2014), 731–742.
16.
W.Lee, S.H.Kim, J.Ryu and T.-W.Ban, Fast detection of disease in livestock based on deep learning, Journal of Korea Institute of Information and Communication Engineering21 (2017), 1009–1015.
17.
M.S.Lee and Y.C.Choe, Forecasting sow's productivity using the machine learning models, Journal of Agricultural Extension and Community Development16 (2009), 939–965.
18.
K.Han, W.Lee and K.Sung, Development of a model to analyze the relationship between smart pig farm environmental data and daily weight increase based on decision tree, Journal ofKorea Institute ofInformation and Communication Engineering20 (2016), 2348–2354.
19.
K.Han, A Study on the Growth Prediction of Livestock based on Machine Learning, M.S. Dissertation,Gyeongsang National University, 2017.
20.
S.C.Pearce, N.K.Gabler, J.W.Ross, J.Escobar, J.F.Patience, R.P.Rhoads and L.H.Baumgard, The effects of heat stress and plane of nutrition on metabolism in growing pigs, Journal of Animal Science91 (2013), 2108–2118.
21.
T.J.O'Shea, J.Corgan and T.C.Clancy, Convolutional Radio Modulation Recognition Networks, Proc of EANN,Aberdeen, UK, 2016.
22.
B.Vautier, N.Quiniou, J.van Milgen and L.Brossard, Modelling The Dynamics of Feed Intake in Growing Pigs; Interest for Modelling Populations of Pigs, Proc of 62nd Annual Meeting of the European Federation of Animal Science, Stavanger, Norway,2011.
23.
I.H.Witten, E.Frank, M.A.Hall and C.J.Pal, Data Mining: Practical machine learning tools and techniques, Morgan Kaufmann, 2016.
24.
Y.Freund and R.E.Schapire, A decision-theoretic generalization of on-line learning and an application to boosting, Journal of Computer and System Sciences55 (1997), 119–139.
25.
Y.LeCun, Y.Bengio and G.Hinton, Deep learning, Nature521 (2015), 436–444.
26.
K.Simonyan and A.Zisserman, Very Deep Convolutional Networks for Large-scale Image Recognition, arXiv preprint arXiv:1409.1556,2014.
27.
V.Nair and G.E.Hinton, Rectified Linear Units Improve Restricted Boltzmann Machines, Proc of ICML, Haifa, Israel,2010.
