Department News
Air-Vehicles for Flying in Near-Earth Environments
Seminar Date
2004-09-24
Author
임아주
Date
2004-09-24
Views
1848
1. 제 목 : Air-Vehicles for Flying in Near-Earth Environments
2. 연 사 : Assistant Prof. Paul Oh
Mechanical Engineering Department, Drexel University, Philadelphia,
USA
3. 일 시 : 2004년 10월 5일 화요일 오후 4시~5시
4. 장 소 : 서울대학교 301동 1512호 세미나실
5. 내 용 :
Micro air vehicles are a new class of bird-sized aerial platforms. Called MAVs, the envisioned purpose is to have them act as robotic front observers that provide situational awareness in near-Earth environments like forests, buildings, caves and tunnels. Unlike contemporary miniature fixed-wing vehicles that fly in open air spaces, MAVs will be agile vehicles that can fly slowly and safely in cluttered environments. Making such airframes robotic demands sensor suites that can autonomously
navigate the vehicle. MAVs have severe payload constraints, demanding the sensor suite be small, light and power-conscious. Additionally GPS, lighting and communications are often degraded in near-earth environments. As such, the sensor suite should operate in varied lighting and avoid distributed wireless computing.
Flying insects, like honeybees, do not possess sophisticated visual or inertial measurement systems. Instead they avoid obstacles, regulate speed, compensate for wind gust, hover and follow terrain using optic flow. This sensing modality is simply the apparent visual motion experienced by an insect as it travels through the environment. Objects that are close will tend to appear to move faster than objects that are far away, and objects with which the insect are on a collision course will tend to appear as if they are rapidly increasing in size. Optic flow sensors, like those found in a computer mouse, are readily available. They often weigh less than 10-grams, are coin-sized, draw milliAmps and can interface with embedded microprocessors.
This talk details proof-of-concept results applying optic flow sensors on MAV test beds. These 20-inch wingspan, 30-gram fixed-wing vehicles fly indoors at speeds as slow as 2 m/s in areas as small as 10x10 square meters. Demonstrations of autonomous collision avoidance, altitude regulation, take off and landing are presented. The results are promising and suggest broad impacts to all classes of unmanned aerial vehicles including lighter-than-air blimps, rotary- and flapping-wing vehicles.
6. 문 의 : 기계항공공학부 박종우 교수 (☏880-7133)
2. 연 사 : Assistant Prof. Paul Oh
Mechanical Engineering Department, Drexel University, Philadelphia,
USA
3. 일 시 : 2004년 10월 5일 화요일 오후 4시~5시
4. 장 소 : 서울대학교 301동 1512호 세미나실
5. 내 용 :
Micro air vehicles are a new class of bird-sized aerial platforms. Called MAVs, the envisioned purpose is to have them act as robotic front observers that provide situational awareness in near-Earth environments like forests, buildings, caves and tunnels. Unlike contemporary miniature fixed-wing vehicles that fly in open air spaces, MAVs will be agile vehicles that can fly slowly and safely in cluttered environments. Making such airframes robotic demands sensor suites that can autonomously
navigate the vehicle. MAVs have severe payload constraints, demanding the sensor suite be small, light and power-conscious. Additionally GPS, lighting and communications are often degraded in near-earth environments. As such, the sensor suite should operate in varied lighting and avoid distributed wireless computing.
Flying insects, like honeybees, do not possess sophisticated visual or inertial measurement systems. Instead they avoid obstacles, regulate speed, compensate for wind gust, hover and follow terrain using optic flow. This sensing modality is simply the apparent visual motion experienced by an insect as it travels through the environment. Objects that are close will tend to appear to move faster than objects that are far away, and objects with which the insect are on a collision course will tend to appear as if they are rapidly increasing in size. Optic flow sensors, like those found in a computer mouse, are readily available. They often weigh less than 10-grams, are coin-sized, draw milliAmps and can interface with embedded microprocessors.
This talk details proof-of-concept results applying optic flow sensors on MAV test beds. These 20-inch wingspan, 30-gram fixed-wing vehicles fly indoors at speeds as slow as 2 m/s in areas as small as 10x10 square meters. Demonstrations of autonomous collision avoidance, altitude regulation, take off and landing are presented. The results are promising and suggest broad impacts to all classes of unmanned aerial vehicles including lighter-than-air blimps, rotary- and flapping-wing vehicles.
6. 문 의 : 기계항공공학부 박종우 교수 (☏880-7133)