The purpose of this research was to provide a FMAV with a hummingbird-like hovering function. The corresponding flapping mechanism should have three merits of large stroke angle, zero phase lag, and high flapping frequencies. Based on the Stephenson-III type 6-bar linkage mechanism, including the Watt's 4-bar linkage linear mechanism, the author novelly proposed using this mechanism for hovering motion with 10 bars and 13 pin-joints. It provided the large stroke angle design up to 150° and without phase lag. The aluminum-alloy mechanisms are fabricated by electrical discharge wire cutting (EDWC) technique. Regarding the higher flapping frequency, 5 different gear reduction ratios (6.67, 8.57, 21.3, 26.6, 27.4) were investigated to have the better performance. The gear ratio 21.3 case generates the largest frequency of 22Hz and the driving torque. Meanwhile the gear ratio 26.6 case generates the largest thrust force of 3.2 gram fore. Furthermore the author selected 3 kinds of wing foils with the aspect ratios of 9.08 (Nano Hummingbird), 6.6 (scaling law), 3.78(Golden snitch) to perform the flight test by this new flapping mechanism (26.6 gear ratio).The flight test showed that the Golden Snitch wing case generates the largest thrust force of 5.48 gram fore. and successfully free flew with 66° high attack angle for 57 seconds. Under such a condition of 3.7V driving, the flapping stroke is observed above 100° and the phase lag between two wings is no more than 5°. The flapping frequency could be near to 22 Hz. In summary, the improved performance of the novel flapping mechanism in this thesis is believed to have substantial contribution to the development of hummingbird-like FMAVs.