Optimal Particle-Conserved Linear Encoding for Practical Fermionic Simulation
- URL: http://arxiv.org/abs/2309.09370v3
- Date: Mon, 22 Sep 2025 12:14:51 GMT
- Title: Optimal Particle-Conserved Linear Encoding for Practical Fermionic Simulation
- Authors: M. H. Cheng, Yu-Cheng Chen, Qian Wang, V. Bartsch, M. S. Kim, Alice Hu, Min-Hsiu Hsieh,
- Abstract summary: Number-conserved subspace encoding reduces resources needed for quantum simulations.<n>We study qubit-gate-measurement trade-offs through the lens of classical/quantum error correction complexity.<n>We propose the Fermionic Expectation Decoder for scalable probability decoding in $mathcalO(M4)$ bases.
- Score: 8.725181592083521
- License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
- Abstract: Number-conserved subspace encoding reduces resources needed for quantum simulations, but scalable complexity trade-off bounds for $M$ modes and $N$ particles with $\mathcal{O}(N\log M)$ qubits have remained unknown. We study qubit-gate-measurement trade-offs through the lens of classical/quantum error correction complexity, and develop a framework of fermionic gate and measurement complexity based on encoder and decoder complexities appeared in error correction framework. We demonstrate optimal encoding with random classical parity check code and propose the Fermionic Expectation Decoder for scalable probability decoding in $\mathcal{O}(M^4)$ bases. The protocol is tested with variational quantum eigensolver on LiH in the STO-3G and 6-31G basis, and $\text{H}_2$ potential energy curve in the 6-311G* basis.
Related papers
- Game-Theoretic Discovery of Quantum Error-Correcting Codes Through Nash Equilibria [0.0]
We recast code optimization as strategic interactions between competing objectives, where equilibria generates codes with desired properties.<n>We validate the framework by demonstrating it rediscovers the optimal $[![15,7,3]!]$Cal quantum Hamming code.<n>This work opens research avenues at the intersection of game theory and quantum information, providing systematic, interpretable frameworks for quantum system design.
arXiv Detail & Related papers (2025-10-17T01:11:32Z) - FFT-Accelerated Auxiliary Variable MCMC for Fermionic Lattice Models: A Determinant-Free Approach with $O(N\log N)$ Complexity [52.3171766248012]
We introduce a Markov Chain Monte Carlo (MCMC) algorithm that dramatically accelerates the simulation of quantum many-body systems.<n>We validate our algorithm on benchmark quantum physics problems, accurately reproducing known theoretical results.<n>Our work provides a powerful tool for large-scale probabilistic inference and opens avenues for physics-inspired generative models.
arXiv Detail & Related papers (2025-10-13T07:57:21Z) - Optimal Quantum $(r,δ)$-Locally Repairable Codes From Matrix-Product Codes [52.3857155901121]
We study optimal quantum $(r,delta)$-LRCs from matrix-product (MP) codes.<n>We present five infinite families of optimal quantum $(r,delta)$-LRCs with flexible parameters.
arXiv Detail & Related papers (2025-08-05T16:05:14Z) - Reinforcement Learning Enhanced Greedy Decoding for Quantum Stabilizer Codes over $\mathbb{F}_q$ [0.0]
We construct new classical Goppa codes and corresponding quantum stabilizer codes from plane curves defined by separateds.<n>Our work thus broadens the class of Goppa- and quantum-stabilizer codes from separated-polynomial curves and delivers a learned decoder with near-optimal performance.
arXiv Detail & Related papers (2025-06-03T21:08:36Z) - Matrix encoding method in variational quantum singular value decomposition [49.494595696663524]
We propose the variational quantum singular value decomposition based on encoding the elements of the considered $Ntimes N$ matrix into the state of a quantum system of appropriate dimension.<n> Controlled measurement is involved to avoid small success in ancilla measurement.
arXiv Detail & Related papers (2025-03-19T07:01:38Z) - Tensor decomposition technique for qubit encoding of maximal-fidelity Lorentzian orbitals in real-space quantum chemistry [0.0]
We propose an efficient scheme for encoding an MO as a many-qubit state from a Gaussian-type solution.
We demonstrate via numerical simulations that the proposed scheme is a powerful tool for encoding MOs of various quantum chemical systems.
arXiv Detail & Related papers (2025-01-13T11:08:20Z) - Demonstrating dynamic surface codes [118.67046728951689]
We experimentally demonstrate three time-dynamic implementations of the surface code.<n>First, we embed the surface code on a hexagonal lattice, reducing the necessary couplings per qubit from four to three.<n>Second, we walk a surface code, swapping the role of data and measure qubits each round, achieving error correction with built-in removal of accumulated non-computational errors.<n>Third, we realize the surface code using iSWAP gates instead of the traditional CNOT, extending the set of viable gates for error correction without additional overhead.
arXiv Detail & Related papers (2024-12-18T21:56:50Z) - Learning with Norm Constrained, Over-parameterized, Two-layer Neural Networks [54.177130905659155]
Recent studies show that a reproducing kernel Hilbert space (RKHS) is not a suitable space to model functions by neural networks.
In this paper, we study a suitable function space for over- parameterized two-layer neural networks with bounded norms.
arXiv Detail & Related papers (2024-04-29T15:04:07Z) - 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) - Quantum Resources Required to Block-Encode a Matrix of Classical Data [56.508135743727934]
We provide circuit-level implementations and resource estimates for several methods of block-encoding a dense $Ntimes N$ matrix of classical data to precision $epsilon$.
We examine resource tradeoffs between the different approaches and explore implementations of two separate models of quantum random access memory (QRAM)
Our results go beyond simple query complexity and provide a clear picture into the resource costs when large amounts of classical data are assumed to be accessible to quantum algorithms.
arXiv Detail & Related papers (2022-06-07T18:00:01Z) - Minimax Optimal Quantization of Linear Models: Information-Theoretic
Limits and Efficient Algorithms [59.724977092582535]
We consider the problem of quantizing a linear model learned from measurements.
We derive an information-theoretic lower bound for the minimax risk under this setting.
We show that our method and upper-bounds can be extended for two-layer ReLU neural networks.
arXiv Detail & Related papers (2022-02-23T02:39:04Z) - How to simulate quantum measurement without computing marginals [3.222802562733787]
We describe and analyze algorithms for classically computation measurement of an $n$-qubit quantum state $psi$ in the standard basis.
Our algorithms reduce the sampling task to computing poly(n)$ amplitudes of $n$-qubit states.
arXiv Detail & Related papers (2021-12-15T21:44:05Z) - Qubit-efficient encoding scheme for quantum simulations of electronic
structure [5.16230883032882]
Simulating electronic structure on a quantum computer requires encoding of fermionic systems onto qubits.
We propose a qubit-efficient encoding scheme that requires the qubit number to be only logarithmic in the number of configurations that satisfy the required conditions and symmetries.
Our proposed scheme and results show the feasibility of quantum simulations for larger molecular systems in the noisy intermediate-scale quantum (NISQ) era.
arXiv Detail & Related papers (2021-10-08T13:20:18Z) - Realization of arbitrary doubly-controlled quantum phase gates [62.997667081978825]
We introduce a high-fidelity gate set inspired by a proposal for near-term quantum advantage in optimization problems.
By orchestrating coherent, multi-level control over three transmon qutrits, we synthesize a family of deterministic, continuous-angle quantum phase gates acting in the natural three-qubit computational basis.
arXiv Detail & Related papers (2021-08-03T17:49:09Z) - 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) - Fermionic partial tomography via classical shadows [0.0]
We propose a tomographic protocol for estimating any $ k $-body reduced density matrix ($ k $-RDM) of an $ n $-mode fermionic state.
Our approach extends the framework of classical shadows, a randomized approach to learning a collection of quantum-state properties, to the fermionic setting.
arXiv Detail & Related papers (2020-10-30T06:28:26Z) - Simulating nonnative cubic interactions on noisy quantum machines [65.38483184536494]
We show that quantum processors can be programmed to efficiently simulate dynamics that are not native to the hardware.
On noisy devices without error correction, we show that simulation results are significantly improved when the quantum program is compiled using modular gates.
arXiv Detail & Related papers (2020-04-15T05:16:24Z) - Quantum Gram-Schmidt Processes and Their Application to Efficient State
Read-out for Quantum Algorithms [87.04438831673063]
We present an efficient read-out protocol that yields the classical vector form of the generated state.
Our protocol suits the case that the output state lies in the row space of the input matrix.
One of our technical tools is an efficient quantum algorithm for performing the Gram-Schmidt orthonormal procedure.
arXiv Detail & Related papers (2020-04-14T11:05:26Z) - Quantum Algorithms for Simulating the Lattice Schwinger Model [63.18141027763459]
We give scalable, explicit digital quantum algorithms to simulate the lattice Schwinger model in both NISQ and fault-tolerant settings.
In lattice units, we find a Schwinger model on $N/2$ physical sites with coupling constant $x-1/2$ and electric field cutoff $x-1/2Lambda$.
We estimate observables which we cost in both the NISQ and fault-tolerant settings by assuming a simple target observable---the mean pair density.
arXiv Detail & Related papers (2020-02-25T19:18:36Z)
This list is automatically generated from the titles and abstracts of the papers in this site.
This site does not guarantee the quality of this site (including all information) and is not responsible for any consequences.