Math 3A
Onto (Surjective)
#Pivots = #Rows
Parametric Vector Equation
(.3) x2(1) (0)
Echelon Form
1. All Zero Rows are at the Bottom 2. Every Entry below the Pivot Point is zero 3. All Pivot Points are to the right of the Previous Column.
Reduced Echelon Form
1. Be in Echelon Form First 2. Every entry above and below the pivot point is zero. 3. Every pivot point is zero
A system of linear equations has
1. No Solution 2. Exactly One Solution 3. Infinitely Many Solutions
Linearly Independent Rows
1. Pivot in each row 2. Onto (surjective) 3 .Ax = b has a solution for all b.
Linearly Independent Columns
1.Pivot in each column(After row reducing) 2.One to One 3. Ax=0 has ONLY x=0 as the solution
Homogenous
A system of linear equations that can be written as Ax = 0
The homogeneous equation Ax = 0 has the trivial solution if and only if the equation has at least one free variable.
FALSE - The trivial solution is always a solution to the equation Ax = 0.
I The codomain of the transformation x 7→ Ax is the set of all linear combinations of the columns of A.
FALSE The If A is m × n codomain is R m. The original statement in describing the range
If x is a nontrivial solution of Ax = 0, then every entry in x is nonzero
FALSE. At least one entry in x is nonzero
TOF: Every linear transformation is a matrix transformation
False Every matrix transfromation is a linear transformation. There exists linear transformations that are not matrix transformations
TOF: If A is an mxn matrix, then the range of the transformation x to Ax in R^m
False The range of T is the set of linear combinations of the columns of A
TOF: If T: R^n to R^m is a linear transformation and if c is in R^m, then a uniqueness question is "Is c in the range of T?"
False The uniqueness question is "Is c the image of a unique x in R^n"
TOF: If A is a 3x5 matrix and T is a Transformation defined by T (x) = Ax, then the domain of T is R^3
False. The domain of T is R^n when A has n columns.
Matrices Basic Operation
Interchange (Switch two rows) Scaling (Multiply a row by a constant) Replacement (Replace one row by the sum of itself and a multiple of another row)
Inconsistent
No Solution
Nontrivial Solution
Nonzero Vector that satisfies Ax=0
Consistent
One or Infinitely many solutions
Unique Solution
Only one solution
Linear Transformations
T: Linear Transformation U & V: vectors C: Scalar then the following holds: 1. T(U + V) = T(U) + T(V) 2. T(CV) = CT(V)
The equation Ax = b is homogeneous if the zero vector is a solution.
TRUE. If the zero vector is a solution then b = Ax = A0 = 0. So the equation is Ax = 0, thus homogenous.
TOF: A linear transformation preserves the operations of vector addition and scalar multiplication
True
TOF: A transformation T is linear if and only if T(c1v1 + c2v2) = c1T(v1) + c2T(v2) for all v1 and v2 in the domain of T and for all scalars c1 and c2.
True A transformation, T, is linear if T(u+v) = Tu + Tv for all u, v in domain T.
TOF: Every matrix transfromation is a linear transformation
True Every matrix transformation is a linear transformation
TOF: A linear transformation T: R^n to R^m always maps the origin of R^n to the origin of R^m
True If T is a linear transformation, T(0) = 0
TOF: The range of the transformation x to Ax is the set of all linear combinations of the columns of A.
True The range of T is the set of linear combinations of the columns of A because each imahe Tx is of the form AX
TOF: A linear transformation is a special type of function
True. The correspondance from x to Ax is a function from one set of vectors to another.
Trivial Solution
Zero Solution (x=0)
Linearly Independent
{v1....vp} in R^n is LI if the vector equation x1v1 + x2v2 +...+ xpvp = 0 has only a trivial solution
Linearly Dependent
{v1....vp} is LD if c1v1 +c2v2 + ...+ cpvp = 0 where not all the C's are not zero.