The variations in morphometric parameter of mammalian brains may be influenced by process of functional complexity, evolution and adaptation. Comparative analysis of linear measurements of cerebrum in the human and baboon has shown morphometric differences. In the present study linear measurements from human and baboon cerebrum (n=10 each) were used to predict various values for human and baboon brain and body parameters through multiple regression models. The average brain weights were found to be 2.08% and 0.84% of the body weights for humans and baboons respectively. The elasticity of regression models revealed that unit percentage increase in Occipital-Frontal (OF) distance would increase the human brain weight by 66.19%, while the baboon brain weight would increase by 7.63%. The unit percentage increase in the Height of Temporal Lobe (HTL) would increase the human brain weight by 16.28%, while the baboon brain weight would increase by only 0.28%. Unit percentage increase in Frontal-Temporal (FT) distance would decrease the human and baboon brain weights by 14.04% and 0.46% respectively. Inter-species values were also predicted through simulation techniques by using the ratios of model parameters with application of programming language Python. The OF, FT and HTL values for human were found to be 2.01 times, 1.55 times and 1.91 times respectively to that of baboon. Las variaciones en los par芍metros morfom谷tricos del cerebro de los mam赤feros pueden estar influenciadas por el proceso de complejidad funcional de la evoluci車n y adaptaci車n. An芍lisis comparativo de las mediciones lineales del cerebro en el humano y babuino han puesto de manifiesto las diferencias morfom谷tricas. En este estudio las mediciones lineales del cerebro humano y babuinos (n = 10 cada uno) fueron utilizados para predecir los valores distintivos para el cerebro de humanos y monos babuinos y los par芍metros del cuerpo a trav谷s de modelos de regresi車n m迆ltiple. El peso medio del cerebro result車 ser 2,08% y 0,84% del peso corporal de los seres humanos y los babuinos, respectivamente. La elasticidad de los modelos de regresi車n revel車 que el aumento de una unidad porcentual en la distancia occipital-frontal (DE) aumentar赤a el peso del cerebro humano en 66,19%, mientras que el peso del cerebro babuino se incrementar赤a en 7,63%. El porcentaje de aumento en la altura de l車bulo temporal (HTL) aumentar赤a el peso del cerebro humano en 16,28%, mientras que el peso del cerebro babuino aumentar赤a en s車lo el 0,28%. Si aumenta la distancia frontal-temporal (FT) se reducir赤a el peso del cerebro huma