Born Rule

If a Quantum System is in state $\left\lvert \psi \right\rangle$ and you measure observable $\hat{A}$ — the probability of getting eigenvalue $\lambda_\alpha$ (which corresponds to eigenstate $\left\lvert \alpha \right\rangle$ ) is

\begin{gather*} P_\alpha=|\left\langle \alpha|\psi \right\rangle|^2 \end{gather*}

This only holds true if eigenstate $\left\lvert \phi_n \right\rangle$ is non-degenerate and normalized. Usually, the convention is that we pick the representative state $\left\langle \phi_n|\phi_n \right\rangle=1$ (i.e., it is normalized).

Born’s rule is a postulate, meaning that it is based on experimental observations and cannot be derived from first principles.

Note that $|\braket{\alpha|\psi}|^2$ is a probability amplitude