4,825 research outputs found
Tradeoffs for reliable quantum information storage in surface codes and color codes
The family of hyperbolic surface codes is one of the rare families of quantum
LDPC codes with non-zero rate and unbounded minimum distance. First, we
introduce a family of hyperbolic color codes. This produces a new family of
quantum LDPC codes with non-zero rate and with minimum distance logarithmic in
the blocklength. Second, we study the tradeoff between the length n, the number
of encoded qubits k and the distance d of surface codes and color codes. We
prove that kd^2 is upper bounded by C(log k)^2n, where C is a constant that
depends only on the row weight of the parity-check matrix. Our results prove
that the best asymptotic minimum distance of LDPC surface codes and color codes
with non-zero rate is logarithmic in the length.Comment: 10 page
Non-Clifford and parallelizable fault-tolerant logical gates on constant and almost-constant rate homological quantum LDPC codes via higher symmetries
We study parallel fault-tolerant quantum computing for families of
homological quantum low-density parity-check (LDPC) codes defined on
3-manifolds with constant or almost-constant encoding rate. We derive generic
formula for a transversal gate of color codes on general 3-manifolds, which
acts as collective non-Clifford logical CCZ gates on any triplet of logical
qubits with their logical- membranes having a triple
intersection at a single point. The triple intersection number is a topological
invariant, which also arises in the path integral of the emergent higher
symmetry operator in a topological quantum field theory: the
gauge theory. Moreover, the transversal gate of the color code corresponds
to a higher-form symmetry supported on a codimension-1 submanifold, giving rise
to exponentially many addressable and parallelizable logical CZ gates. We have
developed a generic formalism to compute the triple intersection invariants for
3-manifolds and also study the scaling of the Betti number and systoles with
volume for various 3-manifolds, which translates to the encoding rate and
distance. We further develop three types of LDPC codes supporting such logical
gates: (1) A quasi-hyperbolic code from the product of 2D hyperbolic surface
and a circle, with almost-constant rate and
distance; (2) A homological fibre bundle code with
rate and distance; (3) A specific family of 3D
hyperbolic codes: the Torelli mapping torus code, constructed from mapping tori
of a pseudo-Anosov element in the Torelli subgroup, which has constant rate
while the distance scaling is currently unknown. We then show a generic
constant-overhead scheme for applying a parallelizable universal gate set with
the aid of logical- measurements.Comment: 40 pages, 31 figure
Constructions et performances de codes LDPC quantiques
L'objet de cette thèse est l'étude des codes LDPC quantiques. Dans un premier temps, nous travaillons sur des constructions topologiques de codes LDPC quantiques. Nous proposons de construire une famille de codes couleur basée sur des pavages hyperboliques. Nous étudions ensuite les paramètres d'une famille de codes basée sur des graphes de Cayley.Dans une seconde partie, nous examinons les performances de ces codes. Nous obtenons une borne supérieure sur les performances des codes LDPC quantiques réguliers sur le canal à effacement quantique. Ceci prouve que ces codes n'atteignent pas la capacité du canal à effacement quantique. Dans le cas du canal de dépolarisation, nous proposons un nouvel algorithme de décodage des codes couleur basé sur trois décodages de codes de surface. Nos simulations numériques montrent de bonnes performances dans le cas des codes couleur toriques.Pour finir, nous nous intéressons au phénomène de percolation. La question centrale de la théorie de la percolation est la détermination du seuil critique. Le calcul exacte de ce seuil est généralement difficile. Nous relions la probabilité de percolation dans certains pavages réguliers du plan hyperbolique à la probabilité d'erreur de décodage pour une famille de codes hyperboliques. Nous en déduisons une borne sur le seuil critique de ces pavages hyperboliques basée sur des résultats de théorie de l'information quantique. Il s'agit d'une application de la théorie de l'information quantique à un problème purement combinatoire.This thesis is devoted to the study of quantum LDPC codes. The first part presents some topological constructions of quantum LDPC codes. We introduce a family of color codes based on tilings of the hyperbolic plane. We study the parameters of a family of codes based on Cayley graphs.In a second part, we analyze the performance of these codes. We obtain an upper bound on the performance of regular quantum LDPC codes over the quantum erasure channel. This implies that these codes don't achieve the capacity of the quantum erasure channel. In the case of the depolarizing channel, we propose a new decoding algorithm of color codes based on three surface codes decoding. Our numerical results show good performance for toric color codes.Finally, we focus on percolation theory. The central question in percolation theory is the determination of the critical probability. Computing the critical probability exactly is usually quite difficult. We relate the probability of percolation in some regular tilings of the hyperbolic plane to the probability of a decoding error for hyperbolic codes on the quantum erasure channel. This leads to an upper bound on the critical probability of these hyperbolic tilings based on quantum information. It is an application of quantum information to a purely combinatorial problem.BORDEAUX1-Bib.electronique (335229901) / SudocSudocFranceF
Magic State Distillation with Low Space Overhead and Optimal Asymptotic Input Count
We present an infinite family of protocols to distill magic states for
-gates that has a low space overhead and uses an asymptotic number of input
magic states to achieve a given target error that is conjectured to be optimal.
The space overhead, defined as the ratio between the physical qubits to the
number of output magic states, is asymptotically constant, while both the
number of input magic states used per output state and the -gate depth of
the circuit scale linearly in the logarithm of the target error (up to
). Unlike other distillation protocols, this protocol
achieves this performance without concatenation and the input magic states are
injected at various steps in the circuit rather than all at the start of the
circuit. The protocol can be modified to distill magic states for other gates
at the third level of the Clifford hierarchy, with the same asymptotic
performance. The protocol relies on the construction of weakly self-dual CSS
codes with many logical qubits and large distance, allowing us to implement
control-SWAPs on multiple qubits. We call this code the "inner code". The
control-SWAPs are then used to measure properties of the magic state and detect
errors, using another code that we call the "outer code". Alternatively, we use
weakly-self dual CSS codes which implement controlled Hadamards for the inner
code, reducing circuit depth. We present several specific small examples of
this protocol.Comment: 39 pages, (v2) renamed "odd" and "even" weakly self-dual CSS codes of
(v1) to "normal" and "hyperbolic" codes, respectively. (v3) published in
Quantu
Constructions and Noise Threshold of Hyperbolic Surface Codes
We show how to obtain concrete constructions of homological quantum codes
based on tilings of 2D surfaces with constant negative curvature (hyperbolic
surfaces). This construction results in two-dimensional quantum codes whose
tradeoff of encoding rate versus protection is more favorable than for the
surface code. These surface codes would require variable length connections
between qubits, as determined by the hyperbolic geometry. We provide numerical
estimates of the value of the noise threshold and logical error probability of
these codes against independent X or Z noise, assuming noise-free error
correction
Upper Bounds on the Rate of Low Density Stabilizer Codes for the Quantum Erasure Channel
Using combinatorial arguments, we determine an upper bound on achievable
rates of stabilizer codes used over the quantum erasure channel. This allows us
to recover the no-cloning bound on the capacity of the quantum erasure channel,
R is below 1-2p, for stabilizer codes: we also derive an improved upper bound
of the form : R is below 1-2p-D(p) with a function D(p) that stays positive for
0 < p < 1/2 and for any family of stabilizer codes whose generators have
weights bounded from above by a constant - low density stabilizer codes.
We obtain an application to percolation theory for a family of self-dual
tilings of the hyperbolic plane. We associate a family of low density
stabilizer codes with appropriate finite quotients of these tilings. We then
relate the probability of percolation to the probability of a decoding error
for these codes on the quantum erasure channel. The application of our upper
bound on achievable rates of low density stabilizer codes gives rise to an
upper bound on the critical probability for these tilings.Comment: 32 page
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