If a an animal jumps straight up to a maximum height of 0.5 meters. Using the four generic kinematics equations listed below, provide your simplified equations using a coordinate system whose y axis is positive up and the x axis positive right such that the origin is located at the maximum height
If a an animal jumps straight up to a maximum height of 0.5 meters. Using the...
A hot-air balloon rises at a velocity of 10 m/s. When the
balloon is 60 meters above the ground, it releases a sandbag. After
release, the sandbag is in free fall. Using the four kinematics
equations listed below, provide your simplified equations using a
coordinate system whose y axis is positive up and the x axis
positive right such that the origin is located at the ground
level
tion: x=xo + vt 2 22a(-
A rock is dropped into a river from the top of a mountain. It
starts from rest and falls freely and vertically. Using the four
generic kinematics equations listed below, provide your simplified
equations using a coordinate system whose y axis is positive down
and the x axis positive right such that the origin is located at
the top of the mountain.
tion: x=xo + vt 2 22a(-
A rock is thrown vertically downward from the edge of the
mountain. It leaves your hand at a point even with the edge and a
speed of 15 m/s. Using the four generic kinematics equations listed
below, provide your simplified equations using a coordinate system
whose y axis is positive down and the x axis positive right such
that the origin is located at the edge of the mountain.
tion: x=xo + vt 2 22a(-
A rock is thrown vertically upward from the edge of a cliff. It
leaves your hand at a point even with the edge at a speed of 25
m/s. The rock is then in free fall. On its way back down, it misses
the edge of the cliff and continues its fall towards the river.
Using the four generic kinematics equations listed below, provide
your simplified equations using a coordinate system whose y axis is
positive down and the x...
A flea jumps straight up to a maximum height of 0.500 m . How long is the flea in the air from the time it jumps to the time it hits the ground? (I figured out initial velocity was 3.13 m/s)
You toss a ball from your window 14 meters above the ground. When the ball leaves your hand, it is moving at a speed of 20 m/s at an angle of 10 degree below the horizontal. Choosing a coordinate system such that its origin is located on your hand, the positive x axis is down and the positive y axis is right. Provide all the simplified equations of motion in both directions for this projectile motion problem.
A dolphin in an aquatic show jumps straight up out of the water at a velocity of 14.3 m/s. The magnitude of the gravitational acceleration g = 9.8 m/s2 Take the water surface to be y0 = 0. Choose UPWARD as positive y direction. Keep 2 decimal places in all answers. (a) How high (what maximum height) in meters does his body rise above the water? To solve this part, first note that the body's final velocity at the maximum...
1 2 A projectile PA is launched from point A towards the east with an initial launch velocity ves and an initial launch angle of 8aA. The impact point of the projectile Pa is a point B in a valley with an ordinate, you, located below the elevation of point A. The launch from point A is instantaneously detected at point B, and a counter projectile Pa ts launched simultaneously towards the west to intercept the incoming projectile PA. Projectile...
Please help me correct my MATLAB script code for this
problem, thank you!!
A projectile PA is launched from point A towards the east with an initial launch velocity voa and an initial lauw angle of 0x. The impact point of the projectile Pa is a point B in a valley with an ordinate, yon, located below the clevation of point A. The launch from point A is instantaneously detected at point B, and a counter projectile P launched simultaneously...
Consider a cylindrical capacitor like that shown in Fig. 24.6. Let d = rb − ra be the spacing between the inner and outer conductors. (a) Let the radii of the two conductors be only slightly different, so that d << ra. Show that the result derived in Example 24.4 (Section 24.1) for the capacitance of a cylindrical capacitor then reduces to Eq. (24.2), the equation for the capacitance of a parallel-plate capacitor, with A being the surface area of...