Hadamard test (quantum computation)

In quantum computation, the Hadamard test is a method used to create a random variable whose expected value is the expected real part of the $\mathrm {Re} \langle \psi |U|\psi \rangle$ , where $\psi \rangle$ is a quantum state and $U$ is a unitary gate acting on the space of $\psi \rangle$ . ^[1] The Hadamard test produces a random variable whose image is in $\{\pm 1\}$ and whose expected value is exactly $\mathrm {Re} \langle \psi |U|\psi \rangle$ . It is possible to modify the circuit to produce a random variable whose expected value is $\mathrm {Im} \langle \psi |U|\psi \rangle$ .^[1]

Description of the circuit[]

To perform the Hadamard test we first calculate the state ${\frac {1}{\sqrt {2}}}\left(\left|0\right\rangle +\left|1\right\rangle \right)\otimes \left|\psi \right\rangle$ . We then apply the unitary operator on $\left|\psi \right\rangle$ conditioned on the first qubit to obtain the state ${\frac {1}{\sqrt {2}}}\left(\left|0\right\rangle \otimes \left|\psi \right\rangle +\left|1\right\rangle \otimes U\left|\psi \right\rangle \right)$ . We then apply the Hadamard gate to the first qubit, yielding ${\frac {1}{2}}\left(\left|0\right\rangle \otimes (I+U)\left|\psi \right\rangle +\left|1\right\rangle \otimes (I-U)\left|\psi \right\rangle \right)$ .

Measuring the first qubit, the result is $\left|0\right\rangle$ with probability ${\frac {1}{4}}\langle \psi |(I+U^{\dagger })(I+U)|\psi \rangle$ , in which case we output $1$ . The result is $\left|1\right\rangle$ with probability ${\frac {1}{4}}\langle \psi |(I-U^{\dagger })(I-U)|\psi \rangle$ , in which case we output $-1$ . The expected value of the output will then be the difference between the two probabilities, which is ${\frac {1}{2}}\langle \psi |(U^{\dagger }+U)|\psi \rangle =\mathrm {Re} \langle \psi |U|\psi \rangle$

To obtain a random variable whose expectation is $\mathrm {Im} \langle \psi |U|\psi \rangle$ follow exactly the same procedure but start with ${\frac {1}{\sqrt {2}}}\left(\left|0\right\rangle -i\left|1\right\rangle \right)\otimes \left|\psi \right\rangle$ .^[2]

The Hadamard test has many applications in quantum algorithms such as the Aharonov-Jones-Landau algorithm. Via a very simple modification it can be used to compute inner product between two states $|\phi _{1}\rangle$ and $|\phi _{2}\rangle$ :^[3] instead of starting from a state $|\psi \rangle$ it suffice to start from the ground state $|0\rangle$ , and perform two controlled operations on the ancilla qubit. Controlled on the ancilla register being $|0\rangle$ , we apply the unitary that produces $|\phi _{1}\rangle$ in the second register, and controlled on the ancilla register being in the state $|1\rangle$ , we create $|\phi _{2}\rangle$ in the second register. The expected value of the measurements of the ancilla qubits leads to an estimate of $\langle \phi _{1}|\phi _{2}\rangle$ . The number of samples needed to estimate the expected value with absolute error $\epsilon$ is $O\left({\frac {1}{\epsilon ^{2}}}\right)$ , because of a chernoff bound. This value can be improved to $O\left({\frac {1}{\epsilon }}\right)$ using techniques.^[3]

References[]

^ ^a ^b Dorit Aharonov Vaughan Jones, Zeph Landau (2009). "A Polynomial Quantum Algorithm for Approximating the Jones Polynomial". Algorithmica. 55 (3): 395–421. arXiv:quant-ph/0511096. doi:10.1007/s00453-008-9168-0.
^ "quantumalgorithms.org - Hadamard test". Open Publishing. Retrieved 27 February 2022.
^ ^a ^b "quantumalgorithms.org - Modified hadamard test". Open Publishing. Retrieved 27 February 2022.

[DA2009-1] Dorit Aharonov Vaughan Jones, Zeph Landau (2009). "A Polynomial Quantum Algorithm for Approximating the Jones Polynomial". Algorithmica. 55 (3): 395–421. arXiv:quant-ph/0511096. doi:10.1007/s00453-008-9168-0.

[Hadamard_test-2] "quantumalgorithms.org - Hadamard test". Open Publishing. Retrieved 27 February 2022.

[Modified_Hadamard_test-3] "quantumalgorithms.org - Modified hadamard test". Open Publishing. Retrieved 27 February 2022.

[1]

[2]

[3]