@article {3410, title = {Clifford operations and homological codes for rotors and oscillators}, year = {2023}, month = {11/13/2023}, abstract = {

We develop quantum information processing primitives for the planar rotor, the state space of a particle on a circle. By interpreting rotor wavefunctions as periodically identified wavefunctions of a harmonic oscillator, we determine the group of bosonic Gaussian operations inherited by the rotor. This n-rotor Clifford group, U(1)n(n+1)/2⋊GLn(Z), is represented by continuous U(1) gates generated by polynomials quadratic in angular momenta, as well as discrete GLn(Z) momentum sign-flip and sum gates. We classify homological rotor error-correcting codes [arXiv:2303.13723] and various rotor states based on equivalence under Clifford operations.
Reversing direction, we map homological rotor codes and rotor Clifford operations back into oscillators by interpreting occupation-number states as rotor states of non-negative angular momentum. This yields new multimode homological bosonic codes protecting against dephasing and changes in occupation number, along with their corresponding encoding and decoding circuits. In particular, we show how to non-destructively measure the oscillator phase using conditional occupation-number addition and post selection. We also outline several rotor and oscillator varieties of the GKP-stabilizer codes [arXiv:1903.12615].

}, url = {https://arxiv.org/abs/2311.07679}, author = {Yijia Xu and Yixu Wang and Victor V. Albert} } @article {2771, title = {Hyper-Invariant MERA: Approximate Holographic Error Correction Codes with Power-Law Correlations}, year = {2021}, month = {3/15/2021}, abstract = {

We consider a class of holographic tensor networks that are efficiently contractible variational ansatze, manifestly (approximate) quantum error correction codes, and can support power-law correlation functions. In the case when the network consists of a single type of tensor that also acts as an erasure correction code, we show that it cannot be both locally contractible and sustain power-law correlation functions. Motivated by this no-go theorem, and the desirability of local contractibility for an efficient variational ansatz, we provide guidelines for constructing networks consisting of multiple types of tensors that can support power-law correlation. We also provide an explicit construction of one such network, which approximates the holographic HaPPY pentagon code in the limit where variational parameters are taken to be small.

}, url = {https://arxiv.org/abs/2103.08631}, author = {ChunJun Cao and Jason Pollack and Yixu Wang} } @article {2601, title = {Approximate recovery and relative entropy I. general von Neumann subalgebras}, year = {2020}, month = {6/14/2020}, abstract = {

We prove the existence of a universal recovery channel that approximately recovers states on a v. Neumann subalgebra when the change in relative entropy, with respect to a fixed reference state, is small. Our result is a generalization of previous results that applied to type-I v. Neumann algebras by Junge at al. [arXiv:1509.07127]. We broadly follow their proof strategy but consider here arbitrary v. Neumann algebras, where qualitatively new issues arise. Our results hinge on the construction of certain analytic vectors and computations/estimations of their Araki-Masuda Lp norms. We comment on applications to the quantum null energy condition.

}, url = {https://arxiv.org/abs/2006.08002}, author = {Thomas Faulkner and Stefan Hollands and Brian Swingle and Yixu Wang} } @article {2641, title = {Approximate recovery and relative entropy I. general von Neumann subalgebras}, year = {2020}, month = {6/14/2020}, abstract = {

We prove the existence of a universal recovery channel that approximately recovers states on a v. Neumann subalgebra when the change in relative entropy, with respect to a fixed reference state, is small. Our result is a generalization of previous results that applied to type-I v. Neumann algebras by Junge at al. [arXiv:1509.07127]. We broadly follow their proof strategy but consider here arbitrary v. Neumann algebras, where qualitatively new issues arise. Our results hinge on the construction of certain analytic vectors and computations/estimations of their Araki-Masuda Lp norms. We comment on applications to the quantum null energy condition.

}, url = {https://arxiv.org/abs/2006.08002}, author = {Thomas Faulkner and Stefan Hollands and Brian Swingle and Yixu Wang} } @article {2300, title = {Holographic Complexity of Einstein-Maxwell-Dilaton Gravity}, journal = {J. High Energ. Phys. }, volume = {106}, year = {2018}, month = {2018}, abstract = {

We study the holographic complexity of Einstein-Maxwell-Dilaton gravity using the recently proposed \"complexity = volume\" and \"complexity = action\" dualities. The model we consider has a ground state that is represented in the bulk via a so-called hyperscaling violating geometry. We calculate the action growth of the Wheeler-DeWitt patch of the corresponding black hole solution at non-zero temperature and find that, in the presence of violations of hyperscaling, there is a parametric enhancement of the action growth rate. We partially match this behavior to simple tensor network models which can capture aspects of hyperscaling violation. We also exhibit the switchback effect in complexity growth using shockwave geometries and comment on a subtlety of our action calculations when the metric is discontinuous at a null surface.

}, doi = {https://doi.org/10.1007/JHEP09(2018)106}, url = {https://arxiv.org/abs/1712.09826}, author = {Brian Swingle and Yixu Wang} } @article {2297, title = {Recovery Map for Fermionic Gaussian Channels}, year = {2018}, abstract = {

A recovery map effectively cancels the action of a quantum operation to a partial or full extent. We study the Petz recovery map in the case where the quantum channel and input states are fermionic and Gaussian. Gaussian states are convenient because they are totally determined by their covariance matrix and because they form a closed set under so-called Gaussian channels. Using a Grassmann representation of fermionic Gaussian maps, we show that the Petz recovery map is also Gaussian and determine it explicitly in terms of the covariance matrix of the reference state and the data of the channel. As a by-product, we obtain a formula for the fidelity between two fermionic Gaussian states. We also discuss subtleties arising from the singularities of the involved matrices.

}, url = {https://arxiv.org/abs/1811.04956}, author = {Brian Swingle and Yixu Wang} }