Life science: flights of homing pigeons. It is known that homing pigeons tend to avoid flying over water in the daytime, perhaps because downdrafts of air over water make flying difficult. Suppose a homing pigeon is released on an island at point C , which is 3 mi directly out in the water from a point B on shore. Point B is 8 mi downshore from the pigeon’s home loft at point A . Assume that a pigeon flying over water uses energy at a rate 1.28 times the rate over land. Toward what point S downshore from A should the pigeon fly in order to minimize the total energy required to get to the home loft at A ? Assume that S is 4.245 mi downshore from A . Total energy = ( Energy rate over water ) × ( Distance over water ) + ( Energy rate over land ) × ( Distance over land ) .
Life science: flights of homing pigeons. It is known that homing pigeons tend to avoid flying over water in the daytime, perhaps because downdrafts of air over water make flying difficult. Suppose a homing pigeon is released on an island at point C , which is 3 mi directly out in the water from a point B on shore. Point B is 8 mi downshore from the pigeon’s home loft at point A . Assume that a pigeon flying over water uses energy at a rate 1.28 times the rate over land. Toward what point S downshore from A should the pigeon fly in order to minimize the total energy required to get to the home loft at A ? Assume that S is 4.245 mi downshore from A . Total energy = ( Energy rate over water ) × ( Distance over water ) + ( Energy rate over land ) × ( Distance over land ) .
Life science: flights of homing pigeons. It is known that homing pigeons tend to avoid flying over water in the daytime, perhaps because downdrafts of air over water make flying difficult. Suppose a homing pigeon is released on an island at point C, which is 3 mi directly out in the water from a point B on shore. Point B is 8 mi downshore from the pigeon’s home loft at point A. Assume that a pigeon flying over water uses energy at a rate 1.28 times the rate over land. Toward what point S downshore from A should the pigeon fly in order to minimize the total energy required to get to the home loft at A? Assume that
S is 4.245 mi downshore from A.
Total energy
=
(
Energy rate over water
)
×
(
Distance over water
)
+
(
Energy rate over land
)
×
(
Distance over land
)
.
Exercise 1
Given are the following planes:
plane 1:
3x4y+z = 1
0
plane 2:
(s, t) =
( 2 ) + (
-2
5 s+
0
(
3 t
2
-2
a) Find for both planes the Hessian normal form and for plane 1 in addition the parameter form.
b) Use the cross product of the two normal vectors to show that the planes intersect in a line.
c) Calculate the intersection line.
d) Calculate the intersection angle of the planes. Make a sketch to indicate which angle you are
calculating.
Only 100% sure experts solve it correct complete solutions ok
rmine the immediate settlement for points A and B shown in
figure below knowing that Aq,-200kN/m², E-20000kN/m², u=0.5, Depth
of foundation (DF-0), thickness of layer below footing (H)=20m.
4m
B
2m
2m
A
2m
+
2m
4m
University Calculus: Early Transcendentals (4th Edition)
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