The effect of target width and target distance in aimed movement has been described clearly in Index of difficulty (ID: log_2^(2A/w) ) equation ( Fitts, 1954 ). The positive correlation of movement time and ID is robust and widely used in human-computer interface design. Purpose: How distance and target width affects movement time independently is seldom discussed. Method: In this article, we used 9 target widths and 9 distances to compose 81 levels of aiming task to observe the effect of target width and distance to movement time by introducing an effective assumption approach. Results: The results showed that both target width and distance did not affect movement time linearly like ID described. Small distances and target widths tended to increase movement time, and large distances and target widths decreased movement time. Movement time tended toward a nonlinear relation with both parameters in extreme values. Accuracy demand decreased when target width exceeded critical point. Long distance provided room for acceleration to high velocity and made the movement more efficient. The linear Fitts' Law relation happened in middle range of target width and distance. Conclusion: In summary, these two parameters behaved differently when increased gradually. Effective assumption approach offers more information about the source of change in movement time than traditional statistical analyses, and provides another point of view describing movement time variability.