This paper employs both experimental and numerical methods to investigate the behavior of steel reinforced concrete (SRC) columns subjected to fire. The experimental work was divided into two phases. Phase one was to test four column specimens under standard fire condition and to study the temperature distribution on the cross section. Test parameters included shape of the cross section (square and circular) and concrete strength. Phase two was to conduct axial compression test of eight column specimens and to study the residual properties after expose to fire. An analytical method was developed to predict the residual strength of SRC columns subject to fire by adopting the temperature distribution data from test results. Test results show that the concrete cover of circular SRC columns severely spalled, however the spalling occurred only at corners for square columns. The concrete strength had insignificant effect on temperature distribution and rate of the temperature rise. Temperatures on the steel were higher than nearby concrete that was attributed to the heat transfer of the steel. The axial compression test results indicate that specimens with high strength concrete had greater reduction on residual strength than specimens with normal strength concrete. Specimens exposed to fire demonstrated increase of the ductility. The analytical predictions for axial residual strength agreed closely with the experimental result. Concrete encased steel SRC columns demonstrated excellent fire resistance performance due to the encase of the concrete.