Linear embedding of nonlinear dynamical systems and prospects for efficient quantum algorithms

Engel, Alexander; Smith, Graeme; Parker, Scott

doi:10.1063/5.0040313

Cited by 28 publications

(18 citation statements)

References 26 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…Other works that address aspects of differential equations but with an application to plasma physics are [19], where a quantum algorithm to solve a linearized Vlasov equation is given. In [20,21], a formulation of several interesting problems in plasma physics that could be amenable to quantum algorithms through linearization is given and in [22], a quantum algorithm to solve classical dynamics using the Koopman operator approach is given. In [23], a quantum algorithm to solve cold plasma waves is given.…”

Section: Introductionmentioning

confidence: 99%

Improved quantum algorithms for linear and nonlinear differential equations

Krovi¹

2022

Preprint

View full text Add to dashboard Cite

We present substantially generalized and improved quantum algorithms over prior work for inhomogeneous linear and nonlinear ordinary differential equations (ODE). In [1], a quantum algorithm for a certain class of linear ODEs is given, where the matrix involved needs to be diagonalizable. The quantum algorithm for linear ODEs presented here extends to many classes of non-diagonalizable matrices. The algorithm here can also be exponentially faster for certain classes of diagonalizable matrices.Our linear ODE algorithm is then applied to nonlinear differential equations using Carleman linearization (an approach taken recently by us in [2]). The improvement over that result is two-fold. First, we obtain an exponentially better dependence on error. This kind of logarithmic dependence on error has also been achieved by [3], but only for homogeneous nonlinear equations. Second, the present algorithm can handle any sparse, invertible matrix (that models dissipation) if it has a negative log-norm (including non-diagonalizable matrices), whereas [2] and [3] additionally require normality.

show abstract

Section: Introductionmentioning

confidence: 99%

Improved quantum algorithms for linear and nonlinear differential equations

Krovi¹

2022

Preprint

View full text Add to dashboard Cite

show abstract

“…First, it yields a quadratic speedup in the accuracy of Monte Carlo estimates [BHMT00, Mon15,HM18]. Achieving 'Heisenberg limited' accuracy scaling has numerous applications in physics, chemistry, machine learning, and finance [Wright&20,ESP20,Rall20,An&20]. Second, it allows quantum computers to diagonalize unitaries in a certain restricted sense: if U = j e 2πiλ j |ψ j ψ j | then phase estimation performs the transformation…”

mentioning

confidence: 99%

Faster Coherent Quantum Algorithms for Phase, Energy, and Amplitude Estimation

Rall

2021

Quantum

View full text Add to dashboard Cite

We consider performing phase estimation under the following conditions: we are given only one copy of the input state, the input state does not have to be an eigenstate of the unitary, and the state must not be measured. Most quantum estimation algorithms make assumptions that make them unsuitable for this 'coherent' setting, leaving only the textbook approach. We present novel algorithms for phase, energy, and amplitude estimation that are both conceptually and computationally simpler than the textbook method, featuring both a smaller query complexity and ancilla footprint. They do not require a quantum Fourier transform, and they do not require a quantum sorting network to compute the median of several estimates. Instead, they use block-encoding techniques to compute the estimate one bit at a time, performing all amplification via singular value transformation. These improved subroutines accelerate the performance of quantum Metropolis sampling and quantum Bayesian inference.

show abstract

“…In [43], a linearization technique of nonlinear classical dynamics based on Koopman-von Neumann method is proposed. [44] summarizes three classical linear embedding techniques, including Carleman embedding(Carleman linearization is also called Carleman embedding) [26,27], coherent states embedding [27,45] and position-space embedding [46], and then puts forward the prospects of these linear embedding techniques to construct effective quantum algorithms. An open question is whether there are other ways to induce nonlinearity in quantum computing.…”

Section: Conclusion and Discussionmentioning

confidence: 99%

Quantum homotopy perturbation method for nonlinear dissipative ordinary differential equations

Xue

Guo

2021

New J. Phys.

View full text Add to dashboard Cite

While quantum computing provides an exponential advantage in solving linear differential equations, there are relatively few quantum algorithms for solving nonlinear differential equations. In our work, based on the homotopy perturbation method, we propose a quantum algorithm for solving n-dimensional nonlinear dissipative ordinary differential equations (ODEs). Our algorithm first converts the original nonlinear ODEs into other nonlinear ODEs which can be embedded into finite-dimensional linear ODEs. Then we solve the embedded linear ODEs with quantum linear ODEs algorithm and obtain a state ε-close to the normalized exact solution of the original nonlinear ODEs with success probability Ω(1). The complexity of our algorithm is O(gηTpoly(log(nT/ε))), where η, g measure the decay of the solution. Our algorithm provides exponential improvement over the best classical algorithms or previous quantum algorithms in n or ε.

show abstract

Linear embedding of nonlinear dynamical systems and prospects for efficient quantum algorithms

Cited by 28 publications

References 26 publications

Improved quantum algorithms for linear and nonlinear differential equations

Improved quantum algorithms for linear and nonlinear differential equations

Faster Coherent Quantum Algorithms for Phase, Energy, and Amplitude Estimation

Quantum homotopy perturbation method for nonlinear dissipative ordinary differential equations

Contact Info

Product

Resources

About