Let 4 linearly dependent vectors such that any 3 of them is independence

Question

Kinda stuck at this question and confused.
Let 4 Linearly dependent vectors exist in the F field.            Such that any 3 of them are linearly independent.
Let the 4 vectors be {${u,v,w,x}$}.
Let L=Span{${u,u-2v,u+3v+w,w+x}$}.
Find the dimL.
In my opinion the dim is 3 but it’s a wild guess.
I found it with examples like (1,0,0),(0,1,0),(0,0,1),(1,1,1). And because (1,1,1) is linearly dependent the vector is also dependent in L.
How can I know what is the dim of L without similar inputs - only by the definition of the span.
Thank you very much in advance.

kccu · Accepted Answer

Notice that $u in L$. Then since $u in L$ and $u-2v in L$ we also have $v in L$ (we can write $v = frac{1}{2}u - frac{1}{2}(u-2v)$). Now since $u+3v+w in L$, we conclude that $w in L$ as well (since $w = (u+3v+w)-u-3v$). And so finally from the fact that $w+x in L$ we have $x in L$ (since $x = (w+x)-w$). Therefore $text{span}(u,v,w,x) subseteq L$.
Conversely, we also have $L subseteq text{span}(u,v,w,x)$ since the vectors used to define $L$ are all in $text{span}(u,v,w,x)$.
Hence $L=text{span}(u,v,w,x)$, so all that remains is to show that the dimension of $text{span}(u,v,w,x)$ is $3$.

Let 4 linearly dependent vectors such that any 3 of them is independence

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