We are currently developing the smart mosquito counter device (height 1080mm × width 560mm × diameter 320mm, 220V 60Hz 30W), which can attract the blood sucking female mosquitoes by emitting CO2 gas (300ml/min), can count the number of the captured mosquitoes by an infra-red beam area sensor, and can send the captured mosquitoes’ number through the CDMA module at real time. We operated the 8 – 16 devices with mosquito sensor networks and a server at the Youngdeungpo-gu areas in Seoul city of south Korea for three years (2011-2013) and we could efficiently control mosquitoes at the high mosquito density area based on the mosquito sensor’s data. We found that the accuracy of the device was about over 93% compared the real mosquito data and transmitted data by CDMA. We also found the water reservoir areas to control floods in Seoul metro city had relatively higher mosquito density than other normal areas, because those flat water areas were preferred by mosquitoes. Because our pest control office knew the mosquito occurrence peak times and areas from mosquito data transmitted by the mosquito sensor devices, we efficiently controlled mosquito larva and adults at the right time. We could accomplish very systematic mosquito control policy and we had the high credibility with the results. Based on the mosquito occurrence data, we selectively and scientifically controlled mosquitoes. Therefore, we reduced pesticide usage and saved annually pesticide expenses up to 2/3. Conclusively, if there is no mosquito, we don’t have to control mosquitoes.

• Hoonbok Yi(Department of Bio & Environmental Technology, Seoul Women’s University)
• Jae seung Yu(E-TND, Environmental Technology % Development, Kwangju)
• Kyeongoh Park(Yeongdeungpo-gu, Health Center, Seoul)
• Sangae Kim(Yeongdeungpo-gu, Health Center, Seoul)
• E-hyun Shin(Korea Centers for Diseases Control & Prevention)
• Wookgyo Lee(Korea Centers for Diseases Control & Prevention)
• Mihyun Park(Yeongdeungpo-gu, Health Center, Seoul)