Does infinite solutions imply the row vectors are linearly dependent?

In summary, having a 4x3 matrix means there are more equations than unknowns, leading to an overdetermined system with no solutions. The rows of the matrix must be linearly dependent in this case. However, this does not necessarily mean there are no solutions to the system. In some cases, it can be reduced to a consistent system with infinite solutions. For underdetermined systems, there may be infinite solutions even if the row vectors are linearly independent, making it inconsistent. Therefore, the number of solutions does not always imply the linear dependence of the row vectors.
  • #1
mitch_1211
99
1
if i have a 4x3 matrix, this means there are more equations than unknowns and so there are no solutions to the system.

does this mean that the row vectors are linearly dependent?
 
Physics news on Phys.org
  • #2
The rows must be linearly dependent because they are four vectors living in a three-dimensional vector space. It doesn't necessarily mean there are no solutions to Ax=b (A the matrix, b a known 4x1 vector and x an unknown 3x1 vector) though: for example, the last two rows of A may be equal and the last two entries of b also equal, in which case it is reduced to 3 equations with 3 unknowns, which may or may not have a solution.
 
  • #3
henry_m said:
The rows must be linearly dependent because they are four vectors living in a three-dimensional vector space.

Of course! I don't know why I didn't realize this straight away.

Thank you very much!
 
  • #4
Your question is about overdetermined system(4x3 in your example). It is mostly inconsistent but it can be consistent(as stated in post 2). If consistent, it may even have infinite solution.

For underdetermined system, it is mostly consistent but it can be inconsistent. If consistent, it must have infinite solution.So, "Does infinite solutions imply the row vectors are linearly dependent?"
Ans: Yes for overdetermined system(4x3 in your example). No for underdetermined system,
e.g
x+y+z=2
x+y+2z=3

have infinite solutions but the row vectors are linearly independent.
 
Last edited:
  • #5


No, the number of solutions to a system of equations is not directly related to the linear dependence of the row vectors in a matrix. Linear dependence refers to the relationship between the vectors in a matrix, not the number of solutions to the system of equations. In the case of a 4x3 matrix, it is possible for the row vectors to be linearly dependent, meaning that one or more vectors can be expressed as a linear combination of the others, even though there are no solutions to the system of equations. Similarly, the row vectors may also be linearly independent, even though there are no solutions to the system. The number of solutions to a system of equations is determined by the rank of the matrix, not by the linear dependence of the row vectors.
 

1. What does it mean for a set of solutions to be infinite?

When a set of solutions is infinite, it means that there are an infinite number of possible solutions to a given problem or equation. This can happen when there are multiple variables involved or when there are no constraints on the solutions.

2. Can a set of solutions be infinite and still have linearly dependent row vectors?

Yes, a set of solutions can be infinite and still have linearly dependent row vectors. Linear dependence refers to a relationship between vectors where one vector can be expressed as a linear combination of the other vectors. This relationship can still exist even if there are an infinite number of possible solutions.

3. How can I determine if the row vectors are linearly dependent?

To determine if the row vectors are linearly dependent, you can use a few different methods. One way is to perform row operations on the matrix and see if you can reduce it to a matrix with linearly dependent rows. Another way is to calculate the determinant of the matrix - if the determinant is equal to zero, then the row vectors are linearly dependent.

4. What implications does linear dependence of row vectors have on the solutions of a system of equations?

If the row vectors are linearly dependent, it means that there are not enough independent equations to uniquely determine the solutions of the system. This can result in an infinite number of solutions or no solutions at all.

5. Can linearly dependent row vectors ever lead to a unique solution?

No, linearly dependent row vectors can never lead to a unique solution. As mentioned earlier, linear dependence indicates that there are not enough independent equations to determine a unique solution. In order to have a unique solution, the row vectors must be linearly independent.

Similar threads

I Row space, Column space, Null space & Left null space
    • Linear and Abstract Algebra
Replies
8
Views
880
I Vector subspace and basis vectors in the context of data science
    • Linear and Abstract Algebra
Replies
6
Views
876
I Dimension and solution to matrix-vector product
    • Linear and Abstract Algebra
Replies
4
Views
879
B Is it invalid to redefine the sgn function in this way in a proof?
    • Linear and Abstract Algebra
Replies
15
Views
4K
I Consistent matrix index notation when dealing with change of basis
    • Linear and Abstract Algebra
Replies
12
Views
1K
MHB System no/infinitely many solution(s)
    • Linear and Abstract Algebra
Replies
15
Views
1K
MHB Solving Systems of Six Equations with Nine Variables
    • Linear and Abstract Algebra
Replies
1
Views
816
MHB Check the statements about a 4x5 matrix with rank 2.
    • Linear and Abstract Algebra
Replies
9
Views
4K
I Can a shear operation introduce a new linear dependency?
    • Linear and Abstract Algebra
Replies
12
Views
2K
I Is tensor product the same as dyadic product of two vectors?
    • Linear and Abstract Algebra
Replies
4
Views
2K

Hot Threads

Recent Insights

Back
Top