From 1970s, the calcium isotopes of meteorites have been studied. Compare with the terrestrial abundance, there exists some anomalies, including 48Ca, within these isotopes. With a neutron-rich Type Ia supernovae model, the 48Ca and others neutron rich isotopic anomalies had be solved. On the other hand, the pre-solar grains studies also indicated both calcium(42Ca, 43Ca, 44Ca) and titanium anomalies. Amari et al.2000 and Nittler et al.2008 succeed to explain these anomalies through an asymptotic giant branch(AGB) star model to some degree. The 43Ca anomalies, which has been found in presolar grains and solved by an AGB star model, was found in the calcium-aluminium inclusions(CAIs) recently. The excess of 43Ca/44Ca, 46Ca/44Ca & 48Ca/44Ca in the CAIs were found to be 0.29±0.16, 1.11±5.51, 4.48±0.29 respectively. For that reason, an AGB model is suggested to explain the CAIs measurement results. In such a model, different parameter, especially the main factor, neutron density was tuned in the simulation. All of the simulation generated a consistent result - less neutron-rich isotopes(42Ca, 43Ca) can be created through the s-process. Even through this model create less 46Ca anomalies, a significant excess of 46Ca can be seen after the strategy of normalize to solar abundance which is often used to analyse isotopic abundance. Nevertheless, a short time neutron exposure will leave 46Ca no effect. In another case, if the mixing model is considered, the 13C neutron source AGB stars will be a good candidate for this 46Ca anomalies.