Answer to Question #336649 in Linear Algebra for dev

In order to prove that "W" is a subspace of "\\mathbb{R}^3" we will use a subspace criteria. Namely, it is enough to prove that "u+w\\in W" for any two vectors "u,w\\in W" and "\\alpha u\\in W" for any "\\alpha\\in{\\mathbb{R}}". Suppose that "u,w\\in W". It means that "u=(x,4x,3x)" and "w=(y,4y,3y)" where "x,y\\in{\\mathbb{R}}." We obtain: "u+w=(x+y,4(x+y),3(x+y))". Denote "z:=x+y". We receive: "(z,4z,3z)\\in W". Multiply a vector "u" by "\\alpha": "\\alpha u=(\\alpha x,4\\alpha x,3\\alpha x)". Denote "\\alpha x=a". We receive: "\\alpha u=(a,4a,3a)\\in W". Thus, the criteria holds. Remind that "W\\oplus U=\\{W+U|W\\cap U=\\empty\\}". I.e., the direct sum consists of sums of vectors from "W" and "U". Consider a vector "(1,4,3)". it belongs to "W". The matrix "\\left(\\begin{array}{lll}1&4&3\\\\0&1&0\\\\0&0&1\\end{array}\\right)" is non-degenerate. The determinant is "1". It means that "(1,4,3)", "(0,1,0)","(0,0,1)" is a basis in "\\mathbb{R}^3". Set "U=\\{(0,x,y)|x,y\\in{\\mathbb{R}} \\}". "W\\cap U=\\empty", since "(1,4,3),(0,1,0),(0,0,1)" are linearly independent. "W\\oplus U=\\mathbb{R}^3", since "(1,4,3),(0,1,0)(0,0,1)" is a basis.

Answer: "U=\\{(0,x,y)|x,y\\in{\\mathbb{R}} \\}". The basis of "U" is: "(0,1,0),(0,0,1)."