Consider the subspace W C R4 given by X1 X2 W = ER4 X1 + x2 + x4 = 0 and x2 + x3 + x4 = 0 X3 X4 = Find an orthonormal basis H {h1, h2, h3, h4} for R4 with the property that hy and h2 are elements of an orthonormal basis for W, where orthonormality is defined with respect to the dot product on R4 x R4.
Consider the subspace W C R4 given by X1 X2 W = ER4 X1 + x2 + x4 = 0 and x2 + x3 + x4 = 0 X3 X4 = Find an orthonormal basis H {h1, h2, h3, h4} for R4 with the property that hy and h2 are elements of an orthonormal basis for W, where orthonormality is defined with respect to the dot product on R4 x R4.
Consider the subspace W CR4 given by 22 W= - {O ER4 21 + x2 + 34 = 0 and 32 +33 +24 = 0 23 24, Find an orthonormal basis H = {h1, h2, h3, h4} for R$ with the property that h¡ and he are elements of an orthonormal basis for W, where orthonormality is defined with respect to the dot product on R4 x R4
(c) Consider the subspace W R4 given by W = ER4 21 +12 + 24 = 0 and x2 + x3 + 14 = 0 14 Find an orthonormal basis H = {h1, h2, h3, h4} for R4 with the property that hy and h2 are elements of an orthonormal basis for W, where orth onormality is defined with respect to the dot product on R4 x R4
ote: The norm of is denoted by |vand is calculated N a vector u Consider a subspace W of R4, W span(1, v2, v3, v4)). Where 0 из- 1. Find an orthonormal basis Qw of W and find the dimension of W 2. Find an orthonormal basis QWL of WL and find the dimension of WL 3. GIven a vector u- . find the Qw coordinate of Projw(v) . find the Qwa coordinate of Projwi (v) » find the coordinate...
Problem 2: Consider the following 2-dimensional linear subspace of R3: X = {(a,b,c) ER’: a+b+c=0}. Define a linear map F: X X by setting F(a,b,c) = (20 – 3b+c, -3a + 2b+c, a +b – 2c). (a) Find the matrix A representing F with respect to the basis 21 = (1,0, -1), 22 = (0,1, -1). (b) Find the matrix A representing F with respect to the basis î1 = (3,1,-4), f2 = (1, -2,1). (c) Find an invertible matrix...
2. Consider a mass m moving in R3 without friction. It is fasten tightly at one end of a string with length 1 and can swing in any direction. In fact, it moves on a sphere, a subspace of R3 1 0 φ g 2.1 Use the spherical coordinates (1,0,) to derive the Lagrangian L(0,0,0,0) = T-U, namely the difference of kinetic energy T and potential energy U. (Note r = 1 is fixed.) 2.2 Calculate the Euler-Lagrange equations, namely...
1. (30pt) LC Circuit and Simple Harmonic Oscillator (From $23.12 RLC Series AC Circuits) Let us first consider a point mass m > 0 with a spring k> 0 (see Figure 23.52). This system is sometimes called a simple harmonic oscillator. The equation of motion (EMI) is given by ma= -kr (1) where the acceleration a is given by the second derivative of the coordinate r with respect to time t, namely dr(t) (2) dt de(t) (6) at) (3) dt...
All of the following questions are in relation to the following journal article which is available on Moodle: Parr CL, Magnus MC, Karlstad O, Holvik K, Lund-Blix NA, Jaugen M, et al. Vitamin A and D intake in pregnancy, infant supplementation and asthma development: the Norwegian Mother and Child Cohort. Am J Clin Nutr 2018:107:789-798 QUESTIONS: 1. State one hypothesis the author's proposed in the manuscript. 2. There is previous research that shows that adequate Vitamin A intake is required...