Related papers: Non-Clifford diagonalization for measurement shot reduction in quantum expectation value estimation

Non-Clifford diagonalization for measurement shot reduction in quantum expectation value estimation

URL: http://arxiv.org/abs/2408.11898v3
Date: Mon, 30 Jun 2025 23:04:19 GMT
Title: Non-Clifford diagonalization for measurement shot reduction in quantum expectation value estimation
Authors: Nicolas P. D. Sawaya, Daan Camps, Ben DalFavero, Norm M. Tubman, Grant M. Rotskoff, Ryan LaRose,
Abstract summary: Estimating expectation values on near-term quantum computers often requires a prohibitively large number of measurements.<n>We introduce a method that relaxes this constraint of commutativity, instead allowing for entirely arbitrary terms to be grouped together.<n>We show that $k$-NoCliD reduces the number of circuit shots, often by a very large margin, and often even for $k$ as small as 2.
Score: 1.2754578699685275
License: http://creativecommons.org/licenses/by/4.0/
Abstract: Estimating expectation values on near-term quantum computers often requires a prohibitively large number of measurements. One widely-used strategy to mitigate this problem has been to partition an operator's Pauli terms into sets of mutually commuting operators. Here, we introduce a method that relaxes this constraint of commutativity, instead allowing for entirely arbitrary terms to be grouped together, save a locality constraint. The key idea is that we decompose the operator into arbitrary tensor products with bounded tensor size, ignoring Pauli commuting relations. This method -- named $k$-NoCliD ($k$-local non-Clifford diagonalization) -- allows one to measure in far fewer bases in most cases, often (though not always) at the cost of increasing the circuit depth. We introduce several partitioning algorithms tailored to different Hamiltonian classes. For electronic structure, we numerically demonstrate the existence of threshold values of $k$ for which $k$-NoCliD leads to the lowest shot counts, though we leave improved partitioning algorithms to future work. We focus primarily on three Hamiltonian classes -- molecular vibrational structure, Fermi-Hubbard, and Bose-Hubbard -- and show that $k$-NoCliD reduces the number of circuit shots, often by a very large margin, and often even for $k$ as small as 2.

Related papers

Near-Optimal Clustering in Mixture of Markov Chains [74.3828414695655]
We study the problem of clustering $T$ trajectories of length $H$, each generated by one of $K$ unknown ergodic Markov chains over a finite state space of size $S$.<n>We derive an instance-dependent, high-probability lower bound on the clustering error rate, governed by the weighted KL divergence between the transition kernels of the chains.<n>We then present a novel two-stage clustering algorithm.
arXiv Detail & Related papers (2025-06-02T05:10:40Z)
Enforced Gaplessness from States with Exponentially Decaying Correlations [0.0]
We show that even certain exponentially decaying correlations can imply gaplessness. Our findings have implications for identifying the subset of Hilbert space to which gapped ground states belong.
arXiv Detail & Related papers (2025-03-03T19:00:37Z)
Lieb-Robinson bounds with exponential-in-volume tails [0.0]
Lieb-Robinson bounds demonstrate the emergence of locality in many-body quantum systems.<n>Perturbation theory and cluster expansion methods suggest that at short times, volume-filling operators are suppressed.<n>We show that disorder operators have volume-law suppression near the "solvable (Ising) point" in quantum phases with spontaneous symmetry breaking.
arXiv Detail & Related papers (2025-02-04T19:00:12Z)
Operator space fragmentation in perturbed Floquet-Clifford circuits [0.0]
Floquet quantum circuits are able to realise a wide range of non-equilibrium quantum states. We investigate the stability of operator localisation and emergence of chaos in random Floquet-Clifford circuits.
arXiv Detail & Related papers (2024-08-02T19:18:30Z)
Towards large-scale quantum optimization solvers with few qubits [59.63282173947468]
We introduce a variational quantum solver for optimizations over $m=mathcalO(nk)$ binary variables using only $n$ qubits, with tunable $k>1$. We analytically prove that the specific qubit-efficient encoding brings in a super-polynomial mitigation of barren plateaus as a built-in feature.
arXiv Detail & Related papers (2024-01-17T18:59:38Z)
$k$-commutativity and measurement reduction for expectation values [0.0]
We introduce a notion of commutativity between operators on a tensor product space, nominally Pauli strings on qubits, that interpolates between qubit-wise commutativity and (full) commutativity. We apply this notion to measuring expectation values of observables in quantum circuits and show a reduction in the number measurements at the cost of increased circuit depth.
arXiv Detail & Related papers (2023-12-19T04:12:56Z)
Simulation of IBM's kicked Ising experiment with Projected Entangled Pair Operator [71.10376783074766]
We perform classical simulations of the 127-qubit kicked Ising model, which was recently emulated using a quantum circuit with error mitigation. Our approach is based on the projected entangled pair operator (PEPO) in the Heisenberg picture. We develop a Clifford expansion theory to compute exact expectation values and use them to evaluate algorithms.
arXiv Detail & Related papers (2023-08-06T10:24:23Z)
Quadratic Lower bounds on the Approximate Stabilizer Rank: A Probabilistic Approach [6.169364905804677]
The approximate stabilizer rank of a quantum state is the minimum number of terms in any approximate decomposition of that state into stabilizer states. We improve the lower bound on the approximate rank to $tilde Omega(sqrt n)$ for a wide range of the approximation parameters.
arXiv Detail & Related papers (2023-05-17T15:09:41Z)
Nonlocality under Computational Assumptions [51.020610614131186]
A set of correlations is said to be nonlocal if it cannot be reproduced by spacelike-separated parties sharing randomness and performing local operations. We show that there exist (efficient) local producing measurements that cannot be reproduced through randomness and quantum-time computation.
arXiv Detail & Related papers (2023-03-03T16:53:30Z)
A lower bound on the space overhead of fault-tolerant quantum computation [51.723084600243716]
The threshold theorem is a fundamental result in the theory of fault-tolerant quantum computation. We prove an exponential upper bound on the maximal length of fault-tolerant quantum computation with amplitude noise.
arXiv Detail & Related papers (2022-01-31T22:19:49Z)
Nystr\"om Kernel Mean Embeddings [92.10208929236826]
We propose an efficient approximation procedure based on the Nystr"om method. It yields sufficient conditions on the subsample size to obtain the standard $n-1/2$ rate. We discuss applications of this result for the approximation of the maximum mean discrepancy and quadrature rules.
arXiv Detail & Related papers (2022-01-31T08:26:06Z)
Random quantum circuits transform local noise into global white noise [118.18170052022323]
We study the distribution over measurement outcomes of noisy random quantum circuits in the low-fidelity regime. For local noise that is sufficiently weak and unital, correlations (measured by the linear cross-entropy benchmark) between the output distribution $p_textnoisy$ of a generic noisy circuit instance shrink exponentially. If the noise is incoherent, the output distribution approaches the uniform distribution $p_textunif$ at precisely the same rate.
arXiv Detail & Related papers (2021-11-29T19:26:28Z)
Halving the cost of quantum multiplexed rotations [0.0]
We improve the number of $T$ gates needed for a $b$-bit approximation of a multiplexed quantum gate with $c$ controls. Our results roughly halve the cost of state-of-art electronic structure simulations based on qubitization of double-factorized or tensor-hypercontracted representations.
arXiv Detail & Related papers (2021-10-26T06:49:44Z)
Annihilating Entanglement Between Cones [77.34726150561087]
We show that Lorentz cones are the only cones with a symmetric base for which a certain stronger version of the resilience property is satisfied. Our proof exploits the symmetries of the Lorentz cones and applies two constructions resembling protocols for entanglement distillation.
arXiv Detail & Related papers (2021-10-22T15:02:39Z)
Random quantum circuits anti-concentrate in log depth [118.18170052022323]
We study the number of gates needed for the distribution over measurement outcomes for typical circuit instances to be anti-concentrated. Our definition of anti-concentration is that the expected collision probability is only a constant factor larger than if the distribution were uniform. In both the case where the gates are nearest-neighbor on a 1D ring and the case where gates are long-range, we show $O(n log(n)) gates are also sufficient.
arXiv Detail & Related papers (2020-11-24T18:44:57Z)
Even more efficient quantum computations of chemistry through tensor hypercontraction [0.6234350105794442]
We describe quantum circuits with only $widetildecal O(N)$ Toffoli complexity that block encode the spectra of quantum chemistry Hamiltonians in a basis of $N$ arbitrary orbitals. This is the lowest complexity that has been shown for quantum computations of chemistry within an arbitrary basis.
arXiv Detail & Related papers (2020-11-06T18:03:29Z)
Approximate unitary $t$-designs by short random quantum circuits using nearest-neighbor and long-range gates [0.0]
We prove that $poly(t)cdot n1/D$-depth local random quantum circuits with two qudit nearest-neighbor gates are approximate $t$-designs in various measures. We also prove that anti-concentration is possible in depth O(log(n) loglog(n) using a different model.
arXiv Detail & Related papers (2018-09-18T22:28:15Z)

This list is automatically generated from the titles and abstracts of the papers in this site.