(Solved): please help answer 2,3,4 An object of mass 1kg, falls vertically down through the air near the sur ...

An object of mass $1\mathrm{kg}$, falls vertically down through the air near the surface of the earth. The object is subject to the regular force of gravity $\left(\mathrm{g}=9.80655\mathrm{m}/{\mathrm{s}}^2\right)$ and a force of air resistance given by $F_{\text{drag }}=-b{v}^2$ where $v$ is the object's speed and $b$ is a constant coefficient. Using the Python script developed in the lecture, determine the distance covered by the object in a time interval of $10\mathrm{s}$, if it is released from rest and $b=0.0042$ ${\mathrm{Ns}}^2/{\mathrm{m}}^2$. Use a time step of delta $\mathrm{t}=0.01\mathrm{s}$. Question 2 $0/0.25\mathrm{pts}$ Still assuming release from rest, $b=0.0042{\mathrm{Ns}}^2/{\mathrm{m}}^2$ and time step of delta_t $=0.01$ Still assuming release from rest, $b=0.0042{\mathrm{Ns}}^2/{\mathrm{m}}^2$ and time step of delta_t=0.01 $\mathrm{s}$, what additional distance in meters would the object have covered in $10\mathrm{s}$, if there were no air resistance? (i.e., the distance that would be covered in free fall minus the distance covered with air resistance). Question 3 $0/0.25\mathrm{pts}$ Assuming now that $b=0.0025{\mathrm{Ns}}^2/{\mathrm{m}}^2$ and the object is thrown down ward with an initial speed of $15\mathrm{m}/\mathrm{s}$, determine the speed of the object $7.5\mathrm{s}$ after it is thrown down. Use the Python script developed in the lecture with a time step of delta_t= $0.01\mathrm{s}$ Assuming now that $b=0.0025{\mathrm{Ns}}^2/{\mathrm{m}}^2$ and the object is thrown downward with an initial speed of $15\mathrm{m}/\mathrm{s}$, determine the speed of the object $7.5\mathrm{s}$ after it is thrown down. Use the Python script developed in the lecture with a time step of delta_t = $0.01\mathrm{s}$. Question 4 $0/0.25\mathrm{pts}$ Still assuming that $b=0.0025{\mathrm{Ns}}^2/{\mathrm{m}}^2$ and the object is thrown downward with an initial speed of $15\mathrm{m}/\mathrm{s}$, by how much faster would the object be moving at $7.5\mathrm{s}$ if there were no air resistance? (i.e., what is the difference between the -free fall speed" and the actual speed predicted with air resistance?). Find your answer using the Pytthon script developed in the lecture with a time step of delta_t $=0.01\mathrm{s}$. down. Use the Python script developed in the lecture with a time step of delta_t = $0.01\mathrm{s}$. Question 4 $0/0.25\mathrm{pts}$ Still assuming that $b=0.0025{\mathrm{Ns}}^2/{\mathrm{m}}^2$ and the object is thrown downward with an initial speed of $15\mathrm{m}/\mathrm{s}$, by how much faster would the object be moving at $7.5\mathrm{s}$ if there were no air resistance? (i.e., what is the difference between the "free fall speed and the actual speed predicted with air resistance?). Find your answer using the Python script developed in the lecture with a time step of delta $t=0.015$.