Phase Kickback

Learn about phase kickbacks and the CNOT-gate in detail.

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Depicting the two basis states ∣0⟩ and ∣1⟩

Quantum entanglement is one of the astonishing characteristics of quantum mechanics. Two entangled particles share a state of superposition no matter how far apart they are.

From a practical perspective, we can use entanglement to let one qubit control the state of another. For instance, the controlled NOT-gate (CNOT- or CX-gate) switches the amplitudes of a target qubit only if the control qubit is in state $|1\rangle$ . Nothing happens if the control qubit is in state $|0\rangle$ .

Such controlled quantum gates let us precisely manipulate a multi-qubit system. In the lesson Composing Quantum Computing Controls, we let certain states of the quantum system exhibit the measurement probabilities we want them to have. We use entanglement to create a fine-grained probabilistic system.

Another practical characteristic of controlled quantum gates is that they leave the control qubit untouched.

The following figure depicts the truth table of the CNOT-gate.

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Getting Started

Binary Classification

Qubit and Quantum States

Probabilistic Binary Classifier

Working with Qubits

Working with Multiple Qubits

Quantum Naïve Bayes

Quantum Computing Is Different

Quantum Bayesian Networks

Bayesian Inference

The World Is Not a Disk

Working with the Qubit Phase

Search for Relatives

Sampling

Conclusion

APPENDIX

Quantum Machine Learning in Python

Phase Kickback