4. For a beam with Free-Free boundary, assume the solution as, (a) Determine the equation to...
2. Consider a cantilevered beam with length L = 3 m, uniform E = 180 GPa, Iz- 5.375 × 10-8 m. and ρ 3.0 kg/m. (a) (20 points) Compute, by hand, the first 5 (lowest) natural frequencies for this beam. Note, unlike for the simply-supported beam problem, you will not be able to solve, analytically, the transcendental equation obtained from the application of the boundary conditions to the general free vibration solution. So, use Matlab roots of this equation numerically
der 5. (15 pts) Consider a homogeneous horizontal beam of length L. Recall that the deflection y (x)of such a beam satisfies the fourth order differential equation ELY wo where Wo is a constant load uniformly distributed along the length of the beam. The general solution of this equation is y () = C1 +223 + c3x2 + 423 + 2457 (a) Determine the appropriate boundary conditions if the beam is free on the left and embedded on the right...
dat 5. (15 pts) Consider a homogeneous horizontal beam of length L. Recall that the deflection y(x)of such a beam satisfies the fourth order differential equation Erd'y w where wois a constant load uniformly distributed along the length of the beam. The general solution of this equation is y(x) = c + C2# + 03 72 +423 + (a) Determine the appropriate boundary conditions if the beam is free on the left and embedded on the right (b) Solve the...
GPA and p in kg/m3 The beam supported in two different ways: (i) Free-Free (ii) Fixed-Free (ii) Fixed-Fixed (iv) Pinned-Pinned (a) Free-hand sketch the beams and list boundary conditions for each. (b) Compute the three lowest temporal frequencies for each beam. (c) Free-hand sketch the first three mode shapes for each beam. Use the following Table for specifications: Lenth, L (m)b(m)h (m)E(GPa) Density, ρ (kg/m3) 7825 1.75 0.145 0.055 27 Use the appended Table for other parameters.
5. (15 pts) Consider a homogeneous horizontal beam of length L. Recall that the deflection y (x) of such a beam satisfies the fourth order differential equation EI d'y - wo where wois a constant load uniformly d.24 distributed along the length of the beam. The general solution of this equation is y(x) = (1 + c2x + c3 x2 + 4x3 + 2001x4 (a) Determine the appropriate boundary conditions if the beam is free on the left and embedded...
Solve equation (4) in Section 5.2 FIdywx) dxA (4) subject to the appropriate boundary conditions. The beam is of length L, and wo is a constant. (a) The beam is embedded at its left end and simply supported at its right end, and w(x) wo, 0 < x < L. усх) (b) Use a graphing utility to graph the deflection curve when wo 48EI and L = 1. = y y 0.2 0.4 0.6 0.8 1,0 0.2 0.4 0.6 0.8...
Problem 1. The natural frequencies wn of free vibration of a cantilever beam are determined from the roots of the equation: ET Cantilever beam Wn = (k~L)2 VPALA in which E = 2.0 x 1011 N/m is the elastic modulus, L = 0.45 m is the beam length, 1 = 4.5 x 10-11 m is the moment of inertia, A = 6.0 x 10-5 mº is the cross-sectional area, and p = 6850 kg/m' is the density per unit length....
Find the solution by Fourier series of the heat equation with nonhomogeneous boundary conditions. Assume that the initial condition is given byf(x) uo u(0,t) = uo, u(L,t) = u1, t > 0 u(x,0) = f(x), 0 < x < L
We want to find a fundamental solution of the stationary equation for a simply supported beam, i.e., a function g(x, ) satisfying dtg da (z ), with boundary conditions 9(0.5) = g"(0,E) = g( 1, ξ)「g',(1,E) = 0. i) Find a causal fundamental solution, i.e., a function E satisfying and E(z) = 0 for z < ξ. (3 Marks) Add a solution of the homogeneous equationO to E to obtain a function that satisfies the boundary conditions. (2 Marks) i)...
help with all except numbers 21-26
16. Solve the differential equation by using the Cauchy-Euler Equation 17. Find the solution to the given Initial Value Problem using Green's Theorem 0,y'(0)s 0 y(0) y" + 6y' + 9y x, 18. Find the solution to the given Boundary Value Problem y" ty-1, y(O)0, y(1) 19. Solve the system of differential equations by systematic elimination. dy dt dt 20. Use any procedure in Chapter 4 to solve the differential equation subjected to the...