BIO Spiraling Up. Birds of prey typically rise upward on thermals. The paths these birds take may be spiral-like. You can model the spiral motion as uniform circular motion combined with a constant upward velocity. Assume that a bird completes a circle of radius 6.00 m every 5.00 s and rises vertically at a constant rate of 3.00 m/s. Determine (a) the bird’s speed relative to the ground: (b) the bird s acceleration (magnitude and direction); and (c) the angle between the bird’s velocity vector and the horizontal.
BIO Spiraling Up. Birds of prey typically rise upward on thermals. The paths these birds take may be spiral-like. You can model the spiral motion as uniform circular motion combined with a constant upward velocity. Assume that a bird completes a circle of radius 6.00 m every 5.00 s and rises vertically at a constant rate of 3.00 m/s. Determine (a) the bird’s speed relative to the ground: (b) the bird s acceleration (magnitude and direction); and (c) the angle between the bird’s velocity vector and the horizontal.
BIO Spiraling Up. Birds of prey typically rise upward on thermals. The paths these birds take may be spiral-like. You can model the spiral motion as uniform circular motion combined with a constant upward velocity. Assume that a bird completes a circle of radius 6.00 m every 5.00 s and rises vertically at a constant rate of 3.00 m/s. Determine (a) the bird’s speed relative to the ground: (b) the bird s acceleration (magnitude and direction); and (c) the angle between the bird’s velocity vector and the horizontal.
Birds of prey typically rise upward on thermals. The paths these birds take may be spiral-like. You can model the spiral motion as uniform circular motion combined with a constant upward velocity. Assume the a bird completes a circle of radius 6.00 m every 5.00 s and rises vertically at a constant rate of 3.00 m/s. Determine the bird's direction of acceleration in degrees above the horizontal.
It is common to see birds of prey rising upward on thermals. The paths they take may be spiral-like. You can model the spiral motion as uniform circular motion combined with a constant upward velocity. Assume a bird completes a circle of radius 6.00 m every 5.00 s and rises vertically at a constant rate of 3.00 m/s. Determine the speed of the bird relative to the ground.
A rocket accelerates at 25m/s2 from rest on a frictionless inclined surface. The inclined ramp has a height of 70m and makes a 32 degrees angle above the ground. The rocket stops accelerating at the instant it leaves the incline. If air resistance is negligible, what is the horizontal distance 'R' from the end of the ramp to the point of impact (where it hits the ground)?
a) Draw a diagram of this situation and be sure to include the distance 'R'
b) Calculate the distance 'R' from the end of the ramp to the point of impact.
1.Draw the clear diagram
2. Give the indicating distance 'R'
3. Show your work
4. Find vertical and horizontal components of velocity when rocket leaves ramp
5. Find distance 'R'
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