I am totally disoriented by orientation..
So in the text, it says
The closed unit vall $B^2$ in $\mathbb{R}^2$ inherits the standard orientation from $\mathbb{R}^2$. The induced orientation on $S^1$ is the one for which the counter-clockwise-pointing vectors are positive.
So according to my understanding, $S^1$ is oriented by $\{n_x, v_1\}$, where $n_x$ is the outward unit normal, and $v_1$ is a basis vector for $S^1$. Is this right? What is $v_1$? just $(1)$ as the standard basis?
Then, how can I get the conclusion that the orientation on $S^1$ is the one for which the counter-clockwise-pointing vectors are positive? We suppose to exam whether the determinant of linear transformation between standard basis $\{(1,0),(0,1)\}$ and $\{n_x, v_1\}$ is positive right? But how can I compute it, since I don't really understand the numerical representation of $\{n_x, v_1\}$ - therefore I can't carry out the computation.
Very much confused, sorry if the statement does not make much sense...
According to Guillemin and Pollack's Differential Topology
Definition: Orientation of $V$, a finite-dimensional real vector space: Let $\beta, \beta^\prime$ be ordered basis of $V$, then there is a unique linear isomorphism $A: V \to V$ such that $\beta = A \beta^\prime$. The sign given an ordered basis $\beta$ is called its orientation.
Definition: Orientation of $X$, a manifold with boundary: A smooth choice of orientations for all the tangent space $T_x(X).$