Consider the set of all polynomials of degree ≤3 in t defined over the interval [0,1].
(a) Find an orthonormal basis for this space.
(b) Find the projection of the polynomial t^4 onto this space.
Consider the set of all polynomials of degree ≤3 in t defined over the interval [0,1]....
Q3. Consider the vector space P, consisting of all polynomials of degree at most two together with the zero polynomial. Let S = {p.(t), p2(t)} be a set of polynomials in P, where: pi(t) = -4 +5, po(t) = -3° - 34+5 (a) Determine whether the set S = {P1(t).pz(t)} is linearly independent in Py? Provide a clear justification for your solution. (8 pts) (b) Determine whether the set S = {p(t),p2(t)} spans the vector space P ? Provide a...
3. Determine if each set is a subspace of the space of degree < 2 polynomials. If so, provide a basis for the set. (a) Degree s 2 polynomial functions whose degree 1 coefficient is zero: $(x) = ax2 + c where a,CER. (b) Degree s 2 polynomial functions whose degree 1 coefficient is 1: f(x) = ax2 + x + c where a,CER.
(4) Let C[0,1] be the inner produce space of all real-valued, continuous functions on the interval (0,1) with inner product.g) = Sopr)(x) dr. Determine the projection of the vector {m} onto the space spanned by the orthonormal system of vectors given below. {1, 73(2x - 1)}
6. (15 pts) Consider an inner product on the vector space P2[-1, 1] of polynomials of degree 2 or less in the closed interval [-1, 1], defined as follows: (f, 9) = | f(t)g(t) dt, for all f, ge P2[-1, 1]. Apply the Gram-Schmidt process to the basis {3, t – 2,t2 + 1} to obtain an {x1, X2, X3} = %3D orthonormal basis.
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Let P2 be the vector space of all polynomials with degree at most 2, and B be the basis {1,T,T*). T(p(x))-p(kr); thus, Consider the linear operator T : P) → given by where k 0 is a parameter (a) Find the matrix Tg,b representing T in the basis B (b) Verify whether T is one-to-one and whether or not it is onto. (c) Find the eigenvalues and the corresponding eigenspaces of the...
t Ps be the vector space of all polynomials of degree s 3. is a subspace of Ps (verify!). Find a basis for and the dimension of W.
3. P. is the vector space of all polynomials of degree n or less and the zero polynomial Define a derivative transformation T as follow: T. +P, T(+241 +0,2%) = 41 + 2121 (a) (10 Puan) Find the corresponding matrix for T. (b) (10 Puan) Choose your polynomial in P, and find the derivative of your polynomial by using the matrix in (a).
let P3 denote the vector space of polynomials of degree 3 or
less, with an inner product defined by
14. Let Ps denote the vector space of polynomials of degree 3 or less, with an inner product defined by (p, q) Ji p(x)q(x) dr. Find an orthogo- nal basis for Ps that contains the vector 1+r. Find the norm (length) of each of your basis elements
14. Let Ps denote the vector space of polynomials of degree 3 or less,...
Consider the function f(1) = el defined on the interval (0,1). Compute the 2nd order Taylor series approximation to f. Next, compute the approximation to f using the orthogonal projection onto the span of (1,1,2²}, with the inner product of two functions on [0,1] being defined by (5.9) = ['s(a)g(z) ds.
Consider the function f(1) = el defined on the interval (0,1). Compute the 2nd order Taylor series approximation to f. Next, compute the approximation to f using the orthogonal projection onto the span of (1,1,2²}, with the inner product of two functions on [0,1] being defined by (5.9) = ['s(a)g(z) ds.