Predictive model based on artificial neural network for assessing beef cattle thermal stress using weather and physiological variables

Abstract The performance of feedlot cattle is adversely affected by thermal stress but the approach to assess the status of animal stress can be laborious, invasive, and/or stressful. To overcome these constraints, the present study proposes a model based on an artificial neural network (neural model), for individual assessment of the level of thermal stress in feedlot finishing cattle considering both weather and animal factors. An experiment was performed using two different groups of Nellore cattle. Physiological and weather data were collected during both experiments including surface temperatures for four selected spots, using infrared thermography (IRT). The data were analyzed (in terms of Pearson’s correlation) to determine the best correlation between the weather and physiological measurements and the IRT measurements for defining the best body location and physiological variable to support the neural model. The neural model had a feed-forward and multi-layered architecture, was trained by supervised learning, and accepted IRT, dry bulb temperature, and wet bulb temperature as inputs to estimate the rectal temperature (RT). A regression model was built for comparison, and the predicted and measured RTs were classified on levels of thermal stress for comparing with the classification based on the traditional temperature–humidity index (THI). The results suggested that the neural model has a good predictive ability, with an R2 of 0.72, while the regression model yielded R2 of 0.57. The thermal stress predicted by the neural model was strongly correlated with the measured RT (94.35%), and this performance was much better than that of the THI method. In addition, the neural model demonstrated good performance on previously unseen data (ability to generalize), and allowed the individual assessment of the animal thermal stress conditions during the same period of day.

[1]  Hongwei Xin,et al.  A real-time computer vision assessment and control of thermal comfort for group-housed pigs , 2008 .

[2]  Line Kessel,et al.  The relationship between body and ambient temperature and corneal temperature. , 2010, Investigative ophthalmology & visual science.

[3]  P. Hansen,et al.  Is the temperature-humidity index the best indicator of heat stress in lactating dairy cows in a subtropical environment? , 2009, Journal of dairy science.

[4]  J. Colyn,et al.  The non-invasive and automated detection of bovine respiratory disease onset in receiver calves using infrared thermography , 2011, Research in Veterinary Science.

[5]  Rafael Vieira de Sousa,et al.  Development and evaluation of a fuzzy logic classifier for assessing beef cattle thermal stress using weather and physiological variables , 2016, Comput. Electron. Agric..

[6]  Yubin Lan,et al.  Review: Development of soft computing and applications in agricultural and biological engineering , 2010 .

[7]  W. Heuwieser,et al.  Effect of heat stress on body temperature in healthy early postpartum dairy cows. , 2012, Theriogenology.

[8]  T. Brown-Brandl,et al.  Dynamic Response Indicators of Heat Stress in Shaded and Non-shaded Feedlot Cattle, Part 2: Predictive Relationships , 2005 .

[9]  Carola Sauter-Louis,et al.  Infrared thermography of the udder surface of dairy cattle: characteristics, methods, and correlation with rectal temperature. , 2014, Veterinary journal.

[10]  C. R. Taylor,et al.  Thermal panting: a comparison of wildebeest and zebu cattle. , 1969, The American journal of physiology.

[11]  E. C. Thom The Discomfort Index , 1959 .

[12]  X. Maldague,et al.  Use of infrared ocular thermography to assess physiological conditions of pigs prior to slaughter and predict pork quality variation. , 2013, Meat science.

[13]  Jean-Marie Aerts,et al.  Is precision livestock farming an engineer's daydream or nightmare, an animal's friend or foe, and a farmer's panacea or pitfall? , 2008 .

[14]  D. McCafferty The value of infrared thermography for research on mammals: previous applications and future directions , 2007 .

[15]  T. Mader,et al.  Management of Cattle Exposed to Adverse Environmental Conditions. , 2015, The Veterinary clinics of North America. Food animal practice.

[16]  Stephen P. Miller,et al.  Application of infrared thermography as an indicator of heat and methane production and its use in the study of skin temperature in response to physiological events in dairy cattle (Bos taurus) , 2008 .

[17]  T. Mader,et al.  Environmental factors influencing heat stress in feedlot cattle. , 2006, Journal of animal science.

[18]  R. Collier,et al.  Major advances associated with environmental effects on dairy cattle. , 2006, Journal of dairy science.

[19]  Wayne Woldt,et al.  Evaluating Modelling Techniques for Cattle Heat Stress Prediction , 2005 .

[20]  Stephen P. Miller,et al.  On the determination of residual feed intake and associations of infrared thermography with efficiency and ultrasound traits in beef bulls , 2009 .

[21]  D. Spiers,et al.  Determinants of bovine thermal response to heat and solar radiation exposures in a field environment , 2011, International journal of biometeorology.

[22]  T. Mader,et al.  Body temperature and respiratory dynamics in un-shaded beef cattle , 2014, International Journal of Biometeorology.

[23]  P. R. Leme,et al.  Infrared thermography as a tool to evaluate body surface temperature and its relationship with feed efficiency in Bos indicus cattle in tropical conditions , 2015, International Journal of Biometeorology.

[24]  Marcos Aurélio Lopes,et al.  Models for Prediction of Physiological Responses of Holstein Dairy Cows , 2014, Appl. Artif. Intell..

[25]  R. Silva,et al.  Evaluation of thermal stress indexes for dairy cows in tropical regions , 2007 .