[1] Alsaaod, M., & Büscher, W. (2012). Detection of hoof lesions using digital infrared thermography
in dairy cows. Journal of dairy science, 95(2), 735-742.
[2] Bartolomé, E., Sánchez, M. J., Molina, A., Schaefer, A. L., Cervantes, I., & Valera, M. (2013). Using eye temperature and heart rate for stress assessment in young horses competing in jumping competitions and its possible influence on sport performance. Animal: an International Journal of Animal Bioscience, 7(12), 2044.
[3] Berry, R. J., Kennedy, A. D., Scott, S. L., Kyle, B. L., & Schaefer, A. L. (2003). Daily variation in the udder surface temperature of dairy cows measured by infrared thermography: Potential for mastitis detection. Canadian journal of animal science, 83(4), 687-693.
[4] Bland, J. M., & Altman, D. G. (1999). Measuring agreement in method comparison studies. Statistical methods in medical research, 8(2), 135-160.
[5] Burfeind, O., Von Keyserlingk, M. A. G., Weary, D. M., Veira, D. M., & Heuwieser, W. (2010). Repeatability of measures of rectal temperature in dairy cows. Journal of dairy science, 93(2), 624-627.
[6] Case, L. A., Wood, B. J., & Miller, S. P. (2012). Investigation of body surface temperature measured with infrared imaging and its correlation with feed efficiency in the turkey (Meleagris gallopavo). Journal of Thermal Biology, 37(5), 397-401.
[7] Chen, P. H., & White, C. E. (2006). Comparison of rectal, microchip transponder, and infrared thermometry techniques for obtaining body temperature in the laboratory rabbit (Oryctolagus cuniculus). Journal of the American Association for Laboratory Animal Science, 45(1), 57-63.
[8] Chiang, M. F., Lin, P. W., Lin, L. F., Chiou, H. Y., Chien, C. W., Chu, S. F., & Chiu, W. T. (2008). Mass screening of suspected febrile patients with remote-sensing infrared thermography: alarm temperature and optimal distance. Journal of the Formosan Medical association, 107(12), 937-944.
[9] George, W. D., Godfrey, R. W., Ketring, R. C., Vinson, M. C., & Willard, S. T. (2014). Relationship among eye and muzzle temperatures measured using digital infrared thermal imaging and vaginal and rectal temperatures in hair sheep and cattle. Journal of animal science, 92(11), 4949-4955.
[10] Gloster, J., Ebert, K., Gubbins, S., Bashiruddin, J., & Paton, D. J. (2011). Normal variation in thermal radiated temperature in cattle: implications for foot-and-mouth disease detection. BMC veterinary research, 7(1), 73.
[11] Hoffmann, G., Schmidt, M., Ammon, C., Rose-Meierhöfer, S., Burfeind, O., Heuwieser, W., & Berg, W. (2013). Monitoring the body temperature of cows and calves using video recordings from an infrared thermography camera. Veterinary research communications, 37(2), 91-99.
[12] Bobić, T., Mijić, P., Gregić, M., Bagarić, A., & Gantner, V. (2017). Early detection of the hoof diseases in Holstein cows using thermovision camera. Agriculturae Conspectus Scientificus, 82(2), 197-200.
[13] Hoffmann, G., Schmidt, M., & Ammon, C. (2016). First investigations to refine video-based IR thermography as a non-invasive tool to monitor the body temperature of calves. animal, 10(9), 1542-1546.
[14] Švejdová, K., Šoch, M., Šimková, A., Švarcová, A., Frejlac, T., Zábranský, L., & Čermák, B. (2016). Current Options for Measuring the Surface Temperature of Dairy Cattle in a Stable Technology. Scientific Papers Animal Science and Biotechnologies, 49(1), 194-198.
[15] AlZahal, O., AlZahal, H., Steele, M. A., Van Schaik, M., Kyriazakis, I., Duffield, T. F., & McBride, B. W. (2011). The use of a radiotelemetric ruminal bolus to detect body temperature changes in lactating dairy cattle. Journal of dairy science, 94(7), 3568-3574.
[16] Brown–Brandl, T. M., Yanagi, T., Xin, H., Gates, R. S., Bucklin, R. A., & Ross, G. S. (2003). A new telemetry system for measuring core body temperature in livestock and poultry. Applied engineering in agriculture, 19(5), 583.
[17] Small, J. A., Kennedy, A. D., & Kahane, S. H. (2008). Core body temperature monitoring with passive transponder boluses in beef heifers. Canadian journal of animal science, 88(2), 225-235.
[18] Voss, B., Laue, H. J., Hoedemaker, M., & Wiedemann, S. (2016). Field-trial evaluation of an automatic temperature measurement device placed in the reticulo-rumen of pre-weaned male calves. Livestock Science, 189, 78-81.
[19] Yadav, B., Singh, G., & Wankar, A. (2017). The use of infrared skin temperature measurements for monitoring heat stress and welfare of crossbred cattle. Indian J Dairy Sci, 70(1), 127-131.
[20] Giro, A., de Campos Bernardi, A. C., Junior, W. B., Lemes, A. P., Botta, D., Romanello, N., ... & Garcia, A. R. (2019). Application of microchip and infrared thermography for monitoring body temperature of beef cattle kept on pasture. Journal of thermal biology, 84, 121-128.
[21] Adams, A. E., Olea-Popelka, F. J., & Roman-Muniz, I. N. (2013). Using temperature-sensing reticular boluses to aid in the detection of production diseases in dairy cows. Journal of dairy science, 96(3), 1549-1555.
[22] Jara, A. L., Hanson, J. M., Gabbard, J. D., Johnson, S. K., Register, E. T., He, B., & Tompkins, S. M. (2016). Comparison of microchip transponder and noncontact infrared thermometry with rectal thermometry in domestic swine (Sus scrofa domestica). Journal of the American Association for Laboratory Animal Science, 55(5), 588-593.
[23] Maxwell, B. M., Brunell, M. K., Olsen, C. H., & Bentzel, D. E. (2016). Comparison of digital rectal and microchip transponder thermometry in ferrets (Mustela putorius furo). Journal of the American Association for Laboratory Animal Science, 55(3), 331-335.
[24] Gianesella, M., Arfuso, F., Fiore, E., Giambelluca, S., Giudice, E., Armato, L., & Piccione, G. (2018). Infrared thermography as a rapid and non-invasive diagnostic tool to detect inflammatory foot diseases in dairy cows. Polish journal of veterinary sciences, 299-305.
[25] Barros, D. V., Silva, L. K. X., Kahwage, P. R., Lourenço Júnior, J. B., Sousa, J. S., Silva, A. G. M., ... & Garcia, A. R. (2016). Assessment of surface temperatures of buffalo bulls (Bubalus bubalis) raised under tropical conditions using infrared thermography. Arquivo Brasileiro de Medicina Veterinária e Zootecnia, 68(2), 422-430.
[26] Kearton, T. R., Doughty, A. K., Morton, C. L., Hinch, G. N., Godwin, I. R., & Cowley, F. C. (2020). Core and peripheral site measurement of body temperature in short wool sheep. Journal of Thermal Biology, 102606.
[27] Sevegnani, K. B., Fernandes, D. P., & Silva, S. H. (2016). Evaluation of thermorregulatory capacity of dairy buffaloes using infrared thermography. Engenharia Agrícola, 36(1), 1-12.
[28] Higaki, S., Koyama, K., Sasaki, Y., Abe, K., Honkawa, K., Horii, Y., ... & Darhan, H. (2020). Calving prediction in dairy cattle based on continuous measurements of ventral tail base skin temperature using supervised machine learning. Journal of Dairy Science, 103(9), 8535-8540.
[29] Johnson, S. R., Rao, S., Hussey, S. B., Morley, P. S., & Traub-Dargatz, J. L. (2011). Thermographic eye temperature as an index to body temperature in ponies. Journal of Equine Veterinary Science, 31(2), 63-66.
[30]Murugeswari, S., & Murugan, K. (2020). Bio‐inspired Mimosa pudica algorithm for energy‐efficient wireless video sensor networks. International Journal of Communication Systems, 33(16), e4577.
[31] Kammersgaard, T. S., Malmkvist, J., & Pedersen, L. J. (2013). Infrared thermography–a non-invasive tool to evaluate thermal status of neonatal pigs based on surface temperature. Animal, 7(12), 2026-2034.
[32] Knížková, I., Kunc, P., Gürdil, G. A. K., Pinar, Y., & Selvi, K. C. (2007). Applications of infrared thermography in animal production. Journal of the Faculty of Agriculture, 22(3), 329-336