Answer to Question #278547 in Linear Algebra for Tharun

Let us verify Rank-nullity theorem for the linear transformation "T:\\R^3\\to \\R^3" defined by "T(x,y,z)=(x-y, 2y+z, x+y+z)."

For this let us find the kernal and the range of "T."

"Ker(T)=\\{(x,y,z)\\in\\R:T(x,y,z)=(0,0,0)\\}\n\\\\=\\{(x,y,z)\\in\\R:(x-y, 2y+z, x+y+z)=(0,0,0)\\}\n\\\\=\\{(x,y,z)\\in\\R:x-y=0, 2y+z=0, x+y+z=0\\}\n\\\\=\\{(x,y,z)\\in\\R:x=y, z=-2y, x+y+z=0\\}\n\\\\=\\{(y,y,-2y)\\in\\R:y\\in\\R\\}\n\\\\=\\{y(1,1,-2)\\in\\R:y\\in\\R\\}."

It follows that "\\dim(Ker(T))=1."

Let "(a,b,c)\\in Range(T)." Then "T(x,y,z)=(a,b,c)" for some "(x,y,z)\\in\\R."

Therefore, "x-y=a, 2y+z=b, x+y+z=c."

It follows that "x-y=(x+y+z)-(2y+z)=c-b," and hence "a=c-b."

Then

"Range(T)=\\{(a,b,c)\\in\\R: T(x,y,z)=(a,b,c)\\}\n\\\\=\\{(c-b,b,c):b,c\\in\\R\\}\n\\\\=\\{c(1,0,1)+b(-1,1,0):b,c\\in\\R\\}."

Consequently, "\\dim(range(T))=2."

Since "\\dim(Ker(T))+\\dim(range(T))=1+2=3=\\dim(\\R^3)," we conclude that the Rank-nullity theorem is indeed true.