Find the center of mass of a toy top with a constan density that has a...

The diagram shows a toy. The shape of the toy is a cone, with radius 4...

The diagram shows a toy. The shape of the toy is a cone, with radius 4 cm and height 9 cm, on top of a hemisphere with radius 4 cm. Calculate the volume of the toy. Give your answer correct to the nearest cubic centimetre. [The volume, V, of a cone with radius r and height h is V = 3 1 πr 2h.] [The volume, V, of a sphere with radius r is V = 3 4 πr 3.]

We are going to examine a uniform copper cone. The cone has a height of 3...

We are going to examine a uniform copper cone. The cone has a height of 3 cm and a base diameter of 2 cm. Calculate the mass of the cone. You may use the equation for the volume of a cone if you wish. Starting from the definition equation for center of mass, calculate the center of mass of the cone. The point is to learn to calculate the center of mass, not to find the equation and plug in...

Use spherical coordinates. (a) Find the centroid of a solid homogeneous hemisphere of radius 1. (Assume...

Use spherical coordinates. (a) Find the centroid of a solid homogeneous hemisphere of radius 1. (Assume the upper hemisphere of a sphere centered at the origin. Use the density function ρ(x, y, z) = K. (x, y, z) = (b) Find the moment of inertia of the solid in part (a) about a diameter of its base. Id =

3. Consider a solid hemisphere of radius R, constant mass density ρ, and a total mass...

3. Consider a solid hemisphere of radius R, constant mass density ρ, and a total mass M. Calculate all elements of the inertia tensor (in terms of M and R) of the hemisphere for a reference frame with its origin at the center of the circular base of the hemisphere. Make sure to clearly sketch the hemisphere and axes positions.

Calculate the rotational inertia for one of the following objects, but not both. a) A cylinder...

Calculate the rotational inertia for one of the following objects, but not both. a) A cylinder of hight 3m, radius 4m about its central axis. The density varies with radius. Rho = 2 r2 kg/m5. b) A cone with its top removed about its central axis. It would have been a cone of height 6 meters and radius 2 meters, but the top two meters were chopped off (The part farthest from the base). The density is 2 kg/m3.

A, The Toy consists of wooden cylinder mounted on top of hemisphere. The mass of the...

A, The Toy consists of wooden cylinder mounted on top of hemisphere. The mass of the system is 0.2kg. The radius of sphere is R=0.3cm. The center of mass the system lies a distance L=R/5 below the hemisphere's center. a) find expression for the potential energy of toy when it is tipped an angle theta from the vertical. b) For the case of small oscillations, show that potential energy takes the form of Hooke's Law. Define new variable s=R*theta and...

A thin, rigid, uniform rod has a mass of 1.40 kg and a length of 2.50...

A thin, rigid, uniform rod has a mass of 1.40 kg and a length of 2.50 m. (a) Find the moment of inertia of the rod relative to an axis that is perpendicular to the rod at one end. (b) Suppose all the mass of the rod were located at a single point. Determine the perpendicular distance of this point from the axis in part (a), such that this point particle has the same moment of inertia as the rod...

2) Find the moment of inertia and the radius of gyration of: y=x2 , X=0 and...

2) Find the moment of inertia and the radius of gyration of: y=x2 , X=0 and y=9 about the y-axis. Assume ? = 5. (Hint: This is rotating a flat plate, like a flag. Not a volume as in #3 and #4) ANSWER- Iy=162 R=Sq.Root(162/18) 3) Find the moment of inertia and the radius of gyration of the solid formed by rotating y=3x, y=0 and x=2 about the y-axis. Assume ? = 15. Answer- Iy= 176pi R= Sq.root(276pi/240pi) Need the...

Calculate the center of mass of a nonuniform rod of length L, whose linear density is...

Calculate the center of mass of a nonuniform rod of length L, whose linear density is p(x) = p0√x ​and the moment of inertia for this rod when the axis of rotation is located at the lighter end.

The rotational inertia I of any given body of mass M about any given axis is...

The rotational inertia I of any given body of mass M about any given axis is equal to the rotational inertia of an equivalent hoop about that axis, if the hoop has the same mass M and a radius k given by The radius k of the equivalent hoop is called the radius of gyration of the given body. Using this formula, find the radius of gyration of (a) a cylinder of radius 3.72 m, (b) a thin spherical shell...