Motion Camouflage in Dragonflies Dragonflies, whose ancestors were once the size

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Motion Camouflage in Dragonflies Dragonflies, whose ancestors were once the size of hawks, have prowled the skies in search of small flying insects for over 250 million years. Faster and more maneuverable than any other insect, they even fold their front two legs in flight and tuck them behind their head to be as streamlined as possible. They also employ an intriguing stalking strategy known as "motion camouflage" to approach their prey almost undetected. The basic idea of motion camouflage is for the dragonfly to move in such a way that the line of sight from the prey to the dragonfly is always in the same direction. Moving in this way, the dragonfly appears almost motionless to its prey, as if it were an object at infinity. Eventually the prey notices the dragonfly has grown in size and is therefore closer, but by that time it's too late for the prey to evade capture. A typical capture scenario is shown in the figure below, where the prey moves in the positive y direction with the constant speed vp=0.750m/s, and the dragonfly moves at an angle =48.5 to the x axis with the constant speed vd. If the dragonfly chooses its speed correctly, the line of sight from the prey to the dragonfly will always be in the same direction—parallel to the x axis in this case. The figure shows a prey and a dragonfly moving in the x y plane. The prey moves in the positive y direction at speed v subscript p at an x position. The dragonfly moves straight from the origin at an angle theta above the x axis at speed v subscript d. The dragonfly moves in such a way that the line of sight between it and the prey is always parallel to the x axis. The trajectories of the insects intersect at the capture point. Part A In a similar situation, the dragonfly is observed to fly at a constant speed, but its angle to the x axis gradually increases from 20 to 40. Which of the following is the best explanation for this behavior? In a similar situation, the dragonfly is observed to fly at a constant speed, but its angle to the axis gradually increases from 20 to 40. Which of the following is the best explanation for this behavior? The prey is moving in the positive y direction and increasing its speed. The prey is moving in the positive y direction and decreasing its speed. The prey is moving in the positive x direction and maintaining a constant speed. The prey is moving in the positive y direction and maintaining a constant speed.
Motion Camouflage in Dragonflies Dragonflies, whose ancestors were once the size of hawks, have prowled the skies in search of small flying insects for over 250 million years. Faster and more maneuverable than any other insect, they even fold their front two legs in flight and tuck them behind their head to be as streamlined as possible. They also employ an intriguing stalking strategy known as "motion camouflage" to approach their prey almost undetected. The basic idea of motion camouflage is for the dragonfly to move in such a way that the line of sight from the prey to the dragonfly is always in the same direction. Moving in this way, the dragonfly appears almost motionless to its prey, as if it were an object at infinity. Eventually the prey notices the dragonfly has grown in size and is therefore closer, but by that time it's too late for the prey to evade capture. A typical capture scenario is shown in the figure below, where the prey moves in the positive y direction with the constant speed vp=0.750m/s, and the dragonfly moves at an angle =48.5 to the x axis with the constant speed vd. If the dragonfly chooses its speed correctly, the line of sight from the prey to the dragonfly will always be in the same direction—parallel to the x axis in this case. The figure shows a prey and a dragonfly moving in the x y plane. The prey moves in the positive y direction at speed v subscript p at an x position. The dragonfly moves straight from the origin at an angle theta above the x axis at speed v subscript d. The dragonfly moves in such a way that the line of sight between it and the prey is always parallel to the x axis. The trajectories of the insects intersect at the capture point. Part A In a similar situation, the dragonfly is observed to fly at a constant speed, but its angle to the x axis gradually increases from 20 to 40. Which of the following is the best explanation for this behavior? In a similar situation, the dragonfly is observed to fly at a constant speed, but its angle to the axis gradually increases from 20 to 40. Which of the following is the best explanation for this behavior? The prey is moving in the positive y direction and increasing its speed. The prey is moving in the positive y direction and decreasing its speed. The prey is moving in the positive x direction and maintaining a constant speed. The prey is moving in the positive y direction and maintaining a constant speed.
Motion Camouflage in Dragonflies Dragonflies, whose ancestors were once the size of hawks, have prowled the skies in search of small flying insects for over 250 million years. Faster and more maneuverable than any other insect, they even fold their front two legs in flight and tuck them behind their head to be as streamlined as possible. They also employ an intriguing stalking strategy known as "motion camouflage" to approach their prey almost undetected. The basic idea of motion camouflage is for the dragonfly to move in such a way that the line of sight from the prey to the dragonfly is always in the same direction. Moving in this way, the dragonfly appears almost motionless to its prey, as if it were an object at infinity. Eventually the prey notices the dragonfly has grown in size and is therefore closer, but by that time it's too late for the prey to evade capture. A typical capture scenario is shown in the figure below, where the prey moves in the positive y direction with the constant speed vp=0.750m/s, and the dragonfly moves at an angle =48.5 to the x axis with the constant speed vd. If the dragonfly chooses its speed correctly, the line of sight from the prey to the dragonfly will always be in the same direction—parallel to the x axis in this case. The figure shows a prey and a dragonfly moving in the x y plane. The prey moves in the positive y direction at speed v subscript p at an x position. The dragonfly moves straight from the origin at an angle theta above the x axis at speed v subscript d. The dragonfly moves in such a way that the line of sight between it and the prey is always parallel to the x axis. The trajectories of the insects intersect at the capture point. Part A In a similar situation, the dragonfly is observed to fly at a constant speed, but its angle to the x axis gradually increases from 20 to 40. Which of the following is the best explanation for this behavior? In a similar situation, the dragonfly is observed to fly at a constant speed, but its angle to the axis gradually increases from 20 to 40. Which of the following is the best explanation for this behavior? The prey is moving in the positive y direction and increasing its speed. The prey is moving in the positive y direction and decreasing its speed. The prey is moving in the positive x direction and maintaining a constant speed. The prey is moving in the positive y direction and maintaining a constant speed.

Explanation / Answer

Option is d. The pray is moving along y axis at constant speed. But the speed of dragonfly changes for which it is finally able to catch the prey.

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