Fit testing should be performed before the first use of tight-fitting respirators, and re-testing should be done annually. However, it may not always be conducted for various reasons, including time（>7 mins）and cost. As a result, reduced fit testing time would help increase the willingness of the employers, users, and respiratory protection programmer to implement fit testing, which in turn improves health protection This study aimed to evaluate if the fit testing time could be shorten by improving the instrumental settings, sampling system design, and data analysis procedure. In this study, investigation of the fit factors was divided into two levels: experimental testing with constant flow rates, simulation tests using a breathing machine（combination of tidal volume and breathing frequency). To simulate leakage, capillaries that were 10 mm in length with different diameters（1.0 mm-1.5mm）were used were inserted onto the respirators. The ratio of total and leak flow rate was considered the “true fit factor” in this study. Ambient particles were passed through the capillaries at constant flow rates of 5-50 L/min under the pressure drop of N95 and P100 respirators. The measured fit factors were determined by concurrent particle concentration measured by TSI Portacount and OPS 3330 with 1.7 m sampling tube in length. In addition, the effects of breathing pattern（tidal volume: 0.5-1 L, frequency: 5-20 times/min）and lung deposition（with/without HEPA filter behind the respirator）on in-mask particle concentration during fit testing were analyzed. The results were used to explore the minimal sampling time that approximated the “true fit factor, FFt”. Results showed that the particle measurement response time for Portacount and OPS were approximately 5 and 2 seconds, respectively. For P100 respirators, most measured fit factors were similar to the FFt, whereas there was an underestimation while using N95 respirator due to particle penetration. Therefore, N95-companion was necessary while using N95 respirator. For the breathing tests, the fit factor was overestimated because the sampling tube was connected onto the facepiece where filtered air was partly sampled. The higher the breathing flow rate, the more the fit factor was overestimated. On the other hand, the measured fit factor would be close to the “true fit factor” when using the highest concentration during a breath（FFmin), and it could be decided in only one breathing. Consequently, with improved design, a fit test would cost approximately only 12 seconds, where the whole fit testing process could be reduced from 7.5 to about 3 minutes.