Add to ORKGMemcomputing is a novel computing paradigm that employs time non-locality (memory) to solve combinatorial optimization problems. It can be realized in practice by means of non-linear dynamical systems whose point attractors represent the solutions of the original problem. It has been previously shown that during the solution search digital memcomputing machines go through a transient phase of avalanches (instantons) that promote dynamical long-range order. By employing mean-field arguments we predict that the distribution of the avalanche sizes follows a Borel distribution typical of critical branching processes with exponent $\tau= 3/2$. We corroborate this analysis by solving various random 3-SAT instances of the Boolean satisfiability pr...
The power-law size distributions obtained experimentally for neuronal avalanches are an important ev...
Power laws in nature are considered to be signatures of complexity. The theory of self-organized cri...
Funder: Engineering and Physical Sciences Research Council; doi: http://dx.doi.org/10.13039/50110000...
Memcomputing is a novel computing paradigm that employs time non-locality (memory) to solve combinat...
This dissertation aims to address the dual goals of (1) proposing practical computing devices that m...
Recent work on quantum annealing has emphasized the role of collective behavior in solving optimizat...
Memcomputing is a novel computing paradigm that employs time non-local dynamical systems to compute ...
This dissertation will review and compile several advancements in the development of digital memcomp...
Scale-free dynamics in physical and biological systems can arise from a variety of causes. Here, we ...
We discuss mean-field theories for self-organized criticality and the connection with the general th...
Experimental and computational studies provide compelling evidence that neuronal systems are charact...
Like sentinels guarding a secret treasure, computationally difficult problems define the edge of wha...
Branching processes are widely used to model phenomena from networks to neuronal avalanching. In a l...
A multitype branching process is introduced to mimic the evolution of the avalanche activity and det...
Neural networks with long-range connectivity are known to display critical behavior including power-...
The power-law size distributions obtained experimentally for neuronal avalanches are an important ev...
Power laws in nature are considered to be signatures of complexity. The theory of self-organized cri...
Funder: Engineering and Physical Sciences Research Council; doi: http://dx.doi.org/10.13039/50110000...
Memcomputing is a novel computing paradigm that employs time non-locality (memory) to solve combinat...
This dissertation aims to address the dual goals of (1) proposing practical computing devices that m...
Recent work on quantum annealing has emphasized the role of collective behavior in solving optimizat...
Memcomputing is a novel computing paradigm that employs time non-local dynamical systems to compute ...
This dissertation will review and compile several advancements in the development of digital memcomp...
Scale-free dynamics in physical and biological systems can arise from a variety of causes. Here, we ...
We discuss mean-field theories for self-organized criticality and the connection with the general th...
Experimental and computational studies provide compelling evidence that neuronal systems are charact...
Like sentinels guarding a secret treasure, computationally difficult problems define the edge of wha...
Branching processes are widely used to model phenomena from networks to neuronal avalanching. In a l...
A multitype branching process is introduced to mimic the evolution of the avalanche activity and det...
Neural networks with long-range connectivity are known to display critical behavior including power-...
The power-law size distributions obtained experimentally for neuronal avalanches are an important ev...
Power laws in nature are considered to be signatures of complexity. The theory of self-organized cri...
Funder: Engineering and Physical Sciences Research Council; doi: http://dx.doi.org/10.13039/50110000...