1.6: The Measurement Principle

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This linear superposition \(|\psi\rangle=\sum_{j=0}^{k-1} \alpha_{j}|j\rangle\) is part of the private world of the electron. Access to the information describing this state is severely limited in particular, we cannot actually measure the complex amplitudes \(\alpha_{j}\). This is not just a practical limitation; it is enshrined in the measurement postulate of quantum physics.

A measurement on this \(k\) state system yields one of at most \(k\) possible outcomes: i.e. an integer between 0 and \(k-1\). Measuring \(|\psi\rangle\) in the standard basis yields \(j\) with probability \(\left|\alpha_{j}\right|^{2}\).

One important aspect of the measurement process is that it alters the state of the quantum system: the effect of the measurement is that the new state is exactly the outcome of the measurement. I.e., if the outcome of the measurement is \(j\), then following the measurement, the qubit is in state \(|j\rangle\). This implies that you cannot collect any additional information about the amplitudes \(\alpha_{j}\) by repeating the measurement.

Intuitively, a measurement provides the only way of reaching into the Hilbert space to probe the quantum state vector. In general this is done by selecting an orthonormal basis \(\left|e_{0}\right\rangle, \ldots,\left|e_{k-1}\right\rangle\). The outcome of the measurement is \(\left|e_{j}\right\rangle\) with probability equal to the square of the length of the projection of the state vector \(\psi\) on \(\left|e_{j}\right\rangle\). A consequence of performing the measurement is that the new state vector is \(\left|e_{j}\right\rangle\). Thus measurement may be regarded as a probabilistic rule for projecting the state vector onto one of the vectors of the orthonormal measurement basis.

Some of you might be puzzled about how a measurement is carried out physically? We will get to that soon when we give more explicit examples of quantum systems.

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