Linear Ind

A.a = 3

B.a = -3

C.a = 9

D.a = -9

A.{u + v, v + w, w + z, z + u} spans V.

B.{u + v, v + w, w + z, z + u} is independent.

C.Span {u + v,v + w, w + z,z + u} is contained in span {u, v, w z}.

D.{u + v, v + w, w + z, z + u} is a basis of V.

A. There exists ij such that v_i = kv_j for some scalar k.

B. {v₁} is dependent.

C. Span {v₁, v₂, …, v_n} has dimension smaller than n.

A. u is a linear combination of v and w.

B. { u , v , u + v } is independent.

C. au + bv + cw = 0 for some nonzero scalars a, b and c.

D. { u , u + v , u + v + w } is independent.

A. Whenever X is in V and c is a scalar, then cx is in W.

B. Whenever X is in W and c is a scalar, then cx is in V.

C. Whenever X is in W and c is a scalar, then cx is in W

D.Whenever X is in V and c is a scalar, then cx is in V.

A. Must be linearly independent, but cannot span V.

B. Can span V , but only if it is linearly independent, and vice versa.

C.Must be a basis of V.

Must be linearly dependent, and must span V.

A. Cannot span V , but can be linearly independent or dependent.

B. Must be linearly dependent, but may or may not span V .

C. Must be linearly independent, but cannot span V .

D. Must be linearly dependent, and must span V .

A.Every vector V in has exactly one representation

as a linear combination of vectors in S .

B.Every vector V in can be expressed as a linear

combination of vectors in S.

C.The elements of are all distinct from each other

None of the above

A.Every element in V is a linear combination of

elements in S .

B.The only way to write 0 as a linear combination of elements of S is the zero combination .

C.The number of elements of S is less than or equal to the

dimension of V .

None of the above

A.Every element of S is a linear combination of

other elements of S.

B.There is a way to write 0 as a linear combination of elements of S other than the zero combination.

C.The span of S has smaller dimension than the

dimension of V .

None of the above.