Write down the Lagrangian for a projectile (subject to no air resistance) in terms of its...

A particle of mass m is projected with an initial velocity v0 in a direction making...

A particle of mass m is projected with an initial velocity v0 in a direction making an angle α with the horizontal level ground as shown in the figure. The motion of the particle occurs under a uniform gravitational field g pointing downward. (a) Write down the Lagrangian of the system by using the Cartesian coordinates (x, y). (b) Is there any cyclic coordinate(s). If so, interpret it (them) physically. (c) Find the Euler-Lagrange equations. Find at least one constant...

a) A small block of mass m is confined to move on the inside surface of...

a) A small block of mass m is confined to move on the inside surface of a cone defined by z = aρ, where (ρ, φ, z) give its position in cylindrical coordinates. The block slides without friction along the surface and feels the gravitational force, which is directed in the negative z direction. a. Write down the Lagrangian for the system in terms of the coordinates ρ and φ b) Obtain the Lagrange equations of motion for the coordinate...

Find x(t), y(t), z(t), vx(t), vy(t), vz(t) for a projectile in 3-D with air resistance and...

Find x(t), y(t), z(t), vx(t), vy(t), vz(t) for a projectile in 3-D with air resistance and wind resistance. Given: vector for vo=(vx,vy,vz), vector for wind vw=wŷ Equation of motion of projectile: Ftot=ma=-my(z-hat)- β(vector for vo)+ β(vector for vw)y

What do we need? ▪ Assumptions: Negligible air resistance, no wind effects, ▪ Governing equations: projectile...

What do we need? ▪ Assumptions: Negligible air resistance, no wind effects, ▪ Governing equations: projectile equations (equations of motion) Equations: x= Vo Cosxt (1) Vx=Vocosx (2) Y= 1/2gt^2 +Vosinxt +Yo (3) Vy= Vosinx+gt (4) ▪ find the optimal firing parameters (firing angle, muzzle velocity) to hit a target that is a distance away and you are shooting from a hill. Start calculating and optimizing. Vo = 10 ft/sec Yo = 100 ft g = 32 ft/sec^2 t = time,...

An airplane in flight is subject to an air resistance force proportional to the square of...

An airplane in flight is subject to an air resistance force proportional to the square of its speed v. But there is an additional resistive force because the airplane has wings. Air flowing over the wings is pushed down and slightly forward, so from Newton's third law the air exerts a force on the wings and airplane that is up and slightly backwardThe upward force is the lift force that keeps the airplane aloft, and the backward force is called induced drag. At...

- write N-S equations for incompressible flows in cartesian coordinates in long form (in x,y,z coordinates)...

- write N-S equations for incompressible flows in cartesian coordinates in long form (in x,y,z coordinates) (1 point) - also write continuity equation and N-S equations for incompressible flows in polar coordinates in long form (in r,θ,z) (since one of your friends ask you can find it easily in online resources or in books) (1 point) - Write down N-S equations in x direction for Planar Couette- Pouseille flow and derive an equation for velocity variation using boundary layer conditions...

We want to evaluate a ferrous material in terms of its resistance. The factors that we...

We want to evaluate a ferrous material in terms of its resistance. The factors that we want to evaluate are the effect of temperature and the Cooling Method in the resistance of the material. The temperatures evaluated were 850 and 1000 Celsius degrees, while the cooling method consisted of cooling: exposed to air, exposed to water, and water with ice. Four plates of appoximately 1 squared inch were cutted of the ferrous material. Each one of these plates were subdivided...

A ball of mass m is projected vertically upwards at a velocity v◦. The ball experiences...

A ball of mass m is projected vertically upwards at a velocity v◦. The ball experiences an air resistance force (in addition to gravity) of the form FR = −αv^2 where α > 0 is constant and v is the velocity, and reaches a maximum height h before it returns back to the point of projection. (a) Write down the equations of motion of the ball during its upward and and downward journeys and show that the maximum height reached...

Consider the bead on a rotating circular hoop system that we saw in lecture. Recall that...

Consider the bead on a rotating circular hoop system that we saw in lecture. Recall that R is the radius of the hoop, ω is the angular velocity of rotation, and m is the mass of the bead that is constrained to be on the hoop as it rotates about the z-axis. We found that we could solve the constraints in terms of a single coordinate θ and that the Cartesian coordinates were given by x = −R sin(ωt)sinθ, y...

For his engineering project, Fran¸cois built a model rocket of mass m = 0.55 kg simply...

For his engineering project, Fran¸cois built a model rocket of mass m = 0.55 kg simply by using materials he found lying around the lab and blueprints he found on the internet. The rocket’s propulsion is provided by a special battery-powered fan that is able to provide a constant force |Ffan| = 7.0 N – that is, once it is launched in a specific direction, the direction of the fan’s force does not change. The downside is that the rocket...