#flapping — Public Fediverse posts

Aflutter in the Breeze

Fabrics flutter in seemingly impossible ways in artist Thomas Jackson‘s images. But despite first appearances, each photograph is true to life; the fabrics are suspended on taut lines. Their dance is driven by wind energy, drag, tension, and flow–not manipulated pixels. I love the (turbulent) energy of them! (Image credit: T. Jackson; via Colossal)

Aflutter in the Breeze

Fabrics flutter in seemingly impossible ways in artist Thomas Jackson‘s images. But despite first appearances, each photograph is true to life; the fabrics are suspended on taut lines. Their dance is driven by wind energy, drag, tension, and flow–not manipulated pixels. I love the (turbulent) energy of them! (Image credit: T. Jackson; via Colossal)

Aflutter in the Breeze

Fabrics flutter in seemingly impossible ways in artist Thomas Jackson‘s images. But despite first appearances, each photograph is true to life; the fabrics are suspended on taut lines. Their dance is driven by wind energy, drag, tension, and flow–not manipulated pixels. I love the (turbulent) energy of them! (Image credit: T. Jackson; via Colossal)

Aflutter in the Breeze

Fabrics flutter in seemingly impossible ways in artist Thomas Jackson‘s images. But despite first appearances, each photograph is true to life; the fabrics are suspended on taut lines. Their dance is driven by wind energy, drag, tension, and flow–not manipulated pixels. I love the (turbulent) energy of them! (Image credit: T. Jackson; via Colossal)

Aflutter in the Breeze

Fabrics flutter in seemingly impossible ways in artist Thomas Jackson‘s images. But despite first appearances, each photograph is true to life; the fabrics are suspended on taut lines. Their dance is driven by wind energy, drag, tension, and flow–not manipulated pixels. I love the (turbulent) energy of them! (Image credit: T. Jackson; via Colossal)

When the #SolarWind interacts with charged particles in the upper Martian #atmosphere, a long magnetic tail forms and extends behind #Mars.

NASA’s #MAVEN probe has shown that this #magnetotail is particularly dynamic: it twists, shifts, ... #Flapping phenomena have also been observed by the Chinese Tianwen-1 orbiter.

Researchers suggest that the flapping of Mars magnetotail should result from magnetic #reconnexion : https://eos.org/research-spotlights/what-makes-marss-magnetotail-flap

When the #SolarWind interacts with charged particles in the upper Martian #atmosphere, a long magnetic tail forms and extends behind #Mars.

NASA’s #MAVEN probe has shown that this #magnetotail is particularly dynamic: it twists, shifts, ... #Flapping phenomena have also been observed by the Chinese Tianwen-1 orbiter.

Researchers suggest that the flapping of Mars magnetotail should result from magnetic #reconnexion : https://eos.org/research-spotlights/what-makes-marss-magnetotail-flap

When the #SolarWind interacts with charged particles in the upper Martian #atmosphere, a long magnetic tail forms and extends behind #Mars.

NASA’s #MAVEN probe has shown that this #magnetotail is particularly dynamic: it twists, shifts, ... #Flapping phenomena have also been observed by the Chinese Tianwen-1 orbiter.

Researchers suggest that the flapping of Mars magnetotail should result from magnetic #reconnexion : https://eos.org/research-spotlights/what-makes-marss-magnetotail-flap

When the #SolarWind interacts with charged particles in the upper Martian #atmosphere, a long magnetic tail forms and extends behind #Mars.

NASA’s #MAVEN probe has shown that this #magnetotail is particularly dynamic: it twists, shifts, ... #Flapping phenomena have also been observed by the Chinese Tianwen-1 orbiter.

Researchers suggest that the flapping of Mars magnetotail should result from magnetic #reconnexion : https://eos.org/research-spotlights/what-makes-marss-magnetotail-flap

When the #SolarWind interacts with charged particles in the upper Martian #atmosphere, a long magnetic tail forms and extends behind #Mars.

NASA’s #MAVEN probe has shown that this #magnetotail is particularly dynamic: it twists, shifts, ... #Flapping phenomena have also been observed by the Chinese Tianwen-1 orbiter.

Researchers suggest that the flapping of Mars magnetotail should result from magnetic #reconnexion : https://eos.org/research-spotlights/what-makes-marss-magnetotail-flap

📢 New post! Aerodynamic consequences of wing damage in dragonfly flapping flight https://blog.espci.fr/ramiro/aerodynamic-consequences-of-wing-damage-in-dragonfly-flapping-flight/ #Publications #Research #Aerodynamics #Flapping #Fluidstructureinteraction #Insectflight

📢 New post! Aerodynamic consequences of wing damage in dragonfly flapping flight https://blog.espci.fr/ramiro/aerodynamic-consequences-of-wing-damage-in-dragonfly-flapping-flight/ #Publications #Research #Aerodynamics #Flapping #Fluidstructureinteraction #Insectflight

📢 New post! Aerodynamic consequences of wing damage in dragonfly flapping flight https://blog.espci.fr/ramiro/aerodynamic-consequences-of-wing-damage-in-dragonfly-flapping-flight/ #Publications #Research #Aerodynamics #Flapping #Fluidstructureinteraction #Insectflight

📢 New post! Aerodynamic consequences of wing damage in dragonfly flapping flight https://blog.espci.fr/ramiro/aerodynamic-consequences-of-wing-damage-in-dragonfly-flapping-flight/ #Publications #Research #Aerodynamics #Flapping #Fluidstructureinteraction #Insectflight

📢 New post! Aerodynamic consequences of wing damage in dragonfly flapping flight https://blog.espci.fr/ramiro/aerodynamic-consequences-of-wing-damage-in-dragonfly-flapping-flight/ #Publications #Research #Aerodynamics #Flapping #Fluidstructureinteraction #Insectflight

#StarTrek #Flapping

#StarTrek #Flapping

#StarTrek #Flapping

#StarTrek #Flapping

#StarTrek #Flapping

Swimming Like a Ray

Manta rays are amazing and efficient swimmers — a necessity for any large animal that survives on tiny plankton. Researchers have built a new soft robot inspired by swimming mantas. Like its biological inspiration, the robot flaps its pectoral fins much as bird flaps its wings; this motion creates vortices that push water behind the robot, propelling it forward. For a downstroke, air inflates the robot’s body cavity, pushing the fins downward. When that air is released, its fins snap back up. With this simple and energy efficient stroke, researchers are able to control the robot’s swimming speed and depth, allowing it to maneuver around obstacles. Flapping faster helps the robot surface, and slower flapping allows it to sink. (Living manta rays also sink if they slow down.) Check out the robot in action below. (Image credit: J. Lanoy; video and research credit: H. Qing et al.; via Ars Technica)

https://www.youtube.com/watch?v=pXB9Ip7qa0o

#biology #biophysics #biorobotics #flapping #fluidDynamics #mantaRay #physics #science #swimming

Swimming Like a Ray

Manta rays are amazing and efficient swimmers — a necessity for any large animal that survives on tiny plankton. Researchers have built a new soft robot inspired by swimming mantas. Like its biological inspiration, the robot flaps its pectoral fins much as bird flaps its wings; this motion creates vortices that push water behind the robot, propelling it forward. For a downstroke, air inflates the robot’s body cavity, pushing the fins downward. When that air is released, its fins snap back up. With this simple and energy efficient stroke, researchers are able to control the robot’s swimming speed and depth, allowing it to maneuver around obstacles. Flapping faster helps the robot surface, and slower flapping allows it to sink. (Living manta rays also sink if they slow down.) Check out the robot in action below. (Image credit: J. Lanoy; video and research credit: H. Qing et al.; via Ars Technica)

https://www.youtube.com/watch?v=pXB9Ip7qa0o

#biology #biophysics #biorobotics #flapping #fluidDynamics #mantaRay #physics #science #swimming

Swimming Like a Ray

Manta rays are amazing and efficient swimmers — a necessity for any large animal that survives on tiny plankton. Researchers have built a new soft robot inspired by swimming mantas. Like its biological inspiration, the robot flaps its pectoral fins much as bird flaps its wings; this motion creates vortices that push water behind the robot, propelling it forward. For a downstroke, air inflates the robot’s body cavity, pushing the fins downward. When that air is released, its fins snap back up. With this simple and energy efficient stroke, researchers are able to control the robot’s swimming speed and depth, allowing it to maneuver around obstacles. Flapping faster helps the robot surface, and slower flapping allows it to sink. (Living manta rays also sink if they slow down.) Check out the robot in action below. (Image credit: J. Lanoy; video and research credit: H. Qing et al.; via Ars Technica)

https://www.youtube.com/watch?v=pXB9Ip7qa0o

#biology #biophysics #biorobotics #flapping #fluidDynamics #mantaRay #physics #science #swimming

Swimming Like a Ray

Manta rays are amazing and efficient swimmers — a necessity for any large animal that survives on tiny plankton. Researchers have built a new soft robot inspired by swimming mantas. Like its biological inspiration, the robot flaps its pectoral fins much as bird flaps its wings; this motion creates vortices that push water behind the robot, propelling it forward. For a downstroke, air inflates the robot’s body cavity, pushing the fins downward. When that air is released, its fins snap back up. With this simple and energy efficient stroke, researchers are able to control the robot’s swimming speed and depth, allowing it to maneuver around obstacles. Flapping faster helps the robot surface, and slower flapping allows it to sink. (Living manta rays also sink if they slow down.) Check out the robot in action below. (Image credit: J. Lanoy; video and research credit: H. Qing et al.; via Ars Technica)

https://www.youtube.com/watch?v=pXB9Ip7qa0o

#biology #biophysics #biorobotics #flapping #fluidDynamics #mantaRay #physics #science #swimming

Swimming Like a Ray

Manta rays are amazing and efficient swimmers — a necessity for any large animal that survives on tiny plankton. Researchers have built a new soft robot inspired by swimming mantas. Like its biological inspiration, the robot flaps its pectoral fins much as bird flaps its wings; this motion creates vortices that push water behind the robot, propelling it forward. For a downstroke, air inflates the robot’s body cavity, pushing the fins downward. When that air is released, its fins snap back up. With this simple and energy efficient stroke, researchers are able to control the robot’s swimming speed and depth, allowing it to maneuver around obstacles. Flapping faster helps the robot surface, and slower flapping allows it to sink. (Living manta rays also sink if they slow down.) Check out the robot in action below. (Image credit: J. Lanoy; video and research credit: H. Qing et al.; via Ars Technica)

https://www.youtube.com/watch?v=pXB9Ip7qa0o

#biology #biophysics #biorobotics #flapping #fluidDynamics #mantaRay #physics #science #swimming

rays flapping...

#rays #flapping #sealife #animatedgif

rays flapping...

#rays #flapping #sealife #animatedgif

rays flapping...

#rays #flapping #sealife #animatedgif

Rolf Mueller is Lynn Professor of Mechanical Engineering at Virginia Tech and directs the @ubdvtlab. He has studied bat biosonar from the perspectives of biophysics and bioinspired engineering for over 20 years. His research aims to meet the sensory information needs of autonomy in complex natural environments.

Listen to our chat here: https://robottalk.org/2024/01/12/episode-68-rolf-mueller/

#Robots #Robotics #Bat #Flight #Flapping #Sensor #Sonar #AI

Rolf Mueller is Lynn Professor of Mechanical Engineering at Virginia Tech and directs the @ubdvtlab. He has studied bat biosonar from the perspectives of biophysics and bioinspired engineering for over 20 years. His research aims to meet the sensory information needs of autonomy in complex natural environments.

Listen to our chat here: https://robottalk.org/2024/01/12/episode-68-rolf-mueller/

#Robots #Robotics #Bat #Flight #Flapping #Sensor #Sonar #AI

Rolf Mueller is Lynn Professor of Mechanical Engineering at Virginia Tech and directs the @ubdvtlab. He has studied bat biosonar from the perspectives of biophysics and bioinspired engineering for over 20 years. His research aims to meet the sensory information needs of autonomy in complex natural environments.

Listen to our chat here: https://robottalk.org/2024/01/12/episode-68-rolf-mueller/

#Robots #Robotics #Bat #Flight #Flapping #Sensor #Sonar #AI

Rolf Mueller is Lynn Professor of Mechanical Engineering at Virginia Tech and directs the @ubdvtlab. He has studied bat biosonar from the perspectives of biophysics and bioinspired engineering for over 20 years. His research aims to meet the sensory information needs of autonomy in complex natural environments.

Listen to our chat here: https://robottalk.org/2024/01/12/episode-68-rolf-mueller/

#Robots #Robotics #Bat #Flight #Flapping #Sensor #Sonar #AI

Rolf Mueller is Lynn Professor of Mechanical Engineering at Virginia Tech and directs the @ubdvtlab. He has studied bat biosonar from the perspectives of biophysics and bioinspired engineering for over 20 years. His research aims to meet the sensory information needs of autonomy in complex natural environments.

Listen to our chat here: https://robottalk.org/2024/01/12/episode-68-rolf-mueller/

#Robots #Robotics #Bat #Flight #Flapping #Sensor #Sonar #AI

📢 New Episode Alert!

This week, @claireasher chats to Dr. Rolf Mueller from Virginia Tech and @ubdvtlab about biomimicry, flapping-wing flight, sensing and artificial intelligence.

Listen now: http://robottalk.org/2024/01/12/episode-68-rolf-mueller/

#Robots #Robotics #Bat #Flight #Flapping #Sensor #Sonar #AI

📢 New Episode Alert!

This week, @claireasher chats to Dr. Rolf Mueller from Virginia Tech and @ubdvtlab about biomimicry, flapping-wing flight, sensing and artificial intelligence.

Listen now: http://robottalk.org/2024/01/12/episode-68-rolf-mueller/

#Robots #Robotics #Bat #Flight #Flapping #Sensor #Sonar #AI

📢 New Episode Alert!

This week, @claireasher chats to Dr. Rolf Mueller from Virginia Tech and @ubdvtlab about biomimicry, flapping-wing flight, sensing and artificial intelligence.

Listen now: http://robottalk.org/2024/01/12/episode-68-rolf-mueller/

#Robots #Robotics #Bat #Flight #Flapping #Sensor #Sonar #AI

📢 New Episode Alert!

This week, @claireasher chats to Dr. Rolf Mueller from Virginia Tech and @ubdvtlab about biomimicry, flapping-wing flight, sensing and artificial intelligence.

Listen now: http://robottalk.org/2024/01/12/episode-68-rolf-mueller/

#Robots #Robotics #Bat #Flight #Flapping #Sensor #Sonar #AI

📢 New Episode Alert!

This week, @claireasher chats to Dr. Rolf Mueller from Virginia Tech and @ubdvtlab about biomimicry, flapping-wing flight, sensing and artificial intelligence.

Listen now: http://robottalk.org/2024/01/12/episode-68-rolf-mueller/

#Robots #Robotics #Bat #Flight #Flapping #Sensor #Sonar #AI

New Episode of Robot Talk @RobotTalkPod: This week,
@claireasher chats to Dr. Rolf Mueller from
@virginia.tech and @ubdvtcenter about biomimicry, flapping-wing flight, sensing and artificial intelligence.
Listen now: https://www.robottalk.org/2024/01/12/episode-68-rolf-mueller/
#Robots #Robotics #Bat #Flight #Flapping #Sensor #Sonar #AI

New Episode of Robot Talk @RobotTalkPod: This week,
@claireasher chats to Dr. Rolf Mueller from
@virginia.tech and @ubdvtcenter about biomimicry, flapping-wing flight, sensing and artificial intelligence.
Listen now: https://www.robottalk.org/2024/01/12/episode-68-rolf-mueller/
#Robots #Robotics #Bat #Flight #Flapping #Sensor #Sonar #AI

New Episode of Robot Talk @RobotTalkPod: This week,
@claireasher chats to Dr. Rolf Mueller from
@virginia.tech and @ubdvtcenter about biomimicry, flapping-wing flight, sensing and artificial intelligence.
Listen now: https://www.robottalk.org/2024/01/12/episode-68-rolf-mueller/
#Robots #Robotics #Bat #Flight #Flapping #Sensor #Sonar #AI

New Episode of Robot Talk @RobotTalkPod: This week,
@claireasher chats to Dr. Rolf Mueller from
@virginia.tech and @ubdvtcenter about biomimicry, flapping-wing flight, sensing and artificial intelligence.
Listen now: https://www.robottalk.org/2024/01/12/episode-68-rolf-mueller/
#Robots #Robotics #Bat #Flight #Flapping #Sensor #Sonar #AI

New Episode of Robot Talk @RobotTalkPod: This week,
@claireasher chats to Dr. Rolf Mueller from
@virginia.tech and @ubdvtcenter about biomimicry, flapping-wing flight, sensing and artificial intelligence.
Listen now: https://www.robottalk.org/2024/01/12/episode-68-rolf-mueller/
#Robots #Robotics #Bat #Flight #Flapping #Sensor #Sonar #AI

I know it's only Wednesday, but it has been a long week already.

I offer that as an excuse, of sorts.

#sillyScribbles #animation #video #loop #birds #flapping

I know it's only Wednesday, but it has been a long week already.

I offer that as an excuse, of sorts.

#sillyScribbles #animation #video #loop #birds #flapping

I know it's only Wednesday, but it has been a long week already.

I offer that as an excuse, of sorts.

#sillyScribbles #animation #video #loop #birds #flapping

I know it's only Wednesday, but it has been a long week already.

I offer that as an excuse, of sorts.

#sillyScribbles #animation #video #loop #birds #flapping

I know it's only Wednesday, but it has been a long week already.

I offer that as an excuse, of sorts.

#sillyScribbles #animation #video #loop #birds #flapping

"We show that Anna's #hummingbirds (Calypte anna) can negotiate apertures less than one wingspan in diameter using a novel sideways maneuver that incorporates continuous, bilaterally asymmetric wing motions. Crucially, this maneuver allows hummingbirds to continue #flapping as they negotiate the constriction."

https://journals.biologists.com/jeb/article-abstract/226/21/jeb245643/334536/Sideways-maneuvers-enable-narrow-aperture?redirectedFrom=fulltext

"We show that Anna's #hummingbirds (Calypte anna) can negotiate apertures less than one wingspan in diameter using a novel sideways maneuver that incorporates continuous, bilaterally asymmetric wing motions. Crucially, this maneuver allows hummingbirds to continue #flapping as they negotiate the constriction."

https://journals.biologists.com/jeb/article-abstract/226/21/jeb245643/334536/Sideways-maneuvers-enable-narrow-aperture?redirectedFrom=fulltext