Hazardous air pollutants (HAPs) emitted from Hsinchu Science-based Industrial Park (HSIP) may significantly affect the health of surrounding residents. A systematic procedure was thus established for analyzing HAP distributions and assessing residential exposure risks. The procedure includes five major steps: selection of major pollutants, model simulation, scenario analysis, risk assessment and expected ambient concentration analysis. Major pollutants were selected based on their emission quantites and TWA-TLV values. The ISCST3 and AERMOD models were applied to simulate spatial an temporal HAP distributions. Simulated distributions were used to analyze spatial HAP impacts on surrounding areas and results obtained based on both models were also compared. Lifetime incremental cancer risk and Hazard Index (HI) were applied to estimate residential cancer and noncancer exposure risks from both single and multiple HAPs. Finally, required reductions of emissions for achieving several expected ambient qualities were estimated based on the uniform removal method for HAPs with high potential hazard. Several scenarios were analyzed based on emission data sets in 2008- 2010, and scenario S was established to simulate actual emission. While a low speed wind occurs, high HAP concentration is likely to occur at the downwind areas of the spot with dense HAP sources. The result for scenario S shows higher HAP concentration and wider impact because its total emission quantity is significantly larger than those of other scenarios. Since ISCST3 and AERMOD use different definitions for calm wind, significant difference exists between the results simulated by both models under low speed winds. According to the simulated result, maximal arsenic concentration mainly occurs at area about 0.1-0.6km to the western boundary of HSIP. However, the actual risk may be higher because the simulated result is lower than monitored values. The maximal HI of chlorine is 8.6 and is significantly higher than other major HAPs. For arsenic and chlorine and to achieve the cancer risk not exceeding 10-6 or HI less than 1, about 90% reduction of all pollution sources is required.