Liquid Cybernetic Systems: The Fourth‐Order Cybernetics

Chiolerio, Alessandro

doi:10.1002/aisy.202000120

Cited by 13 publications

(12 citation statements)

References 65 publications

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“…In view of the reported features, we can conclude that further investigations using multiple ports and holonomic concepts [8] and further engineering steps toward a complex computer are possible, based on the spatial arrangement of the ports (see Section S15, Supporting Information). While the generation of DC voltage (at high impedance) can be easily implemented using low-complexity circuit solutions, read-out custom electronic circuits can take advantage of the demonstrated cumulative ultrawide band impedance variation of the colloid, without necessarily requiring accurate frequency synthesis.…”

Section: Discussion Conclusion and Future Prospectsmentioning

confidence: 95%

“…Only recently, liquid and colloidal systems have been subject to attention for mimicking the ions moving in the human brain through embedding aqueous solutions in gel or solid-state scaffolds. [5] Being applicable to soft robotics, [6] energy harvesting, [7] and computation in general, [8] magnetic fluids are always of great research interest (Section S1, Supporting Information). Particularly, ferrofluids (FFs) are mixtures in which nanometricsize dispersed insoluble particles are suspended throughout a solvent, the particles being typically superparamagnetic, giving rise to interesting collective behavior.…”

Section: Introductionmentioning

confidence: 99%

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Experimental Demonstration of In‐Memory Computing in a Ferrofluid System

et al. 2023

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Magnetic fluids are excellent candidates for several important research fields including energy harvesting, biomedical applications, soft robotics, and exploration. However, notwithstanding relevant advancements such as shape reconfigurability, that have been demonstrated, there is no evidence for their computing capability, including the emulation of synaptic functions, which requires complex non‐linear dynamics. Here, it is experimentally demonstrated that a Fe3O4 water‐based ferrofluid (FF) can perform electrical analogue computing and be programmed using quasi direct current (DC) signals and read at radio frequency (RF) mode. Features have been observed in all respects attributable to a memristive behavior, featuring both short and long‐term information storage capacity and plasticity. The colloid is capable of classifying digits of a 8 × 8 pixel dataset using a custom in‐memory signal processing scheme, and through physical reservoir computing by training a readout layer. These findings demonstrate the feasibility of in‐memory computing using an amorphous FF system in a liquid aggregation state. This work poses the basis for the exploitation of a FF colloid as both an in‐memory computing device and as a full‐electric liquid computer thanks to its fluidity and the reported complex dynamics, via probing read‐out and programming ports.

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Section: Discussion Conclusion and Future Prospectsmentioning

confidence: 95%

Section: Introductionmentioning

confidence: 99%

Experimental Demonstration of In‐Memory Computing in a Ferrofluid System

et al. 2023

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“…Thus, initially, 80% of the output datasets were used for training with the targets and then the remaining 20% were used for testing the classification performance of the device. For training, only the output weights W m,i out were optimized using a Python-encoded ridge regression [51] model with a ridge regularization coefficient (λ) value with which the identity matrix I was multiplied, as expressed by Equation (7). Here, T represents the transpose of the voltage output matrix V (bold represents matrix format) constituting all the 11 time-series readouts.…”

Section: Methodsmentioning

confidence: 99%

“…Thus, unlike their von Neumann counterparts, the hardware implementations can instead pave the way for efficient machine intelligence computing. Many such hardware‐implemented NN models are being researched [ 6,7 ] ; however, the one that has recently been attracting attention is directed towards the emulation of reservoir computing (RC) [ 8–11 ] (Figure S1, Supporting Information) because of its bio‐inspired and straightforward framework for processing time‐series data. Execution of such temporal RC machine has been accomplished in atomic switch networks (ASNs), [ 12 ] conductive polymer network, [ 13 ] carbon nanotube (CNT)/polymer composites, [ 14,15 ] optoelectrical systems, [ 16,17 ] soft bodies, [ 18,19 ] spintronics, [ 20,21 ] and water tank systems.…”

Section: Introductionmentioning

confidence: 99%

Emergence of In‐Materio Intelligence from an Incidental Structure of a Single‐Walled Carbon Nanotube–Porphyrin Polyoxometalate Random Network

Banerjee

Kotooka

Azhari

et al. 2022

Advanced Intelligent Systems

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Hardware‐based machine intelligence with the network architecture of reservoir computing (RC) is gaining interest because of its biological computational resemblance along with an easy and efficient neural network training approach. Herein, such a physical RC (in‐materio RC) platform consisting of a recurrent network formed by the single‐walled carbon nanotube (SWNT)–porphyrin polyoxometalate (Por–POM) complex is demonstrated. The network architecture executes the fundamental reservoir properties of nonlinearity, higher harmonic generation, and 1/fγ power law information processing ability. Based on these functionalities, an RC benchmark task of waveform generation is performed where the device achieves maximum fitting accuracy of 99.4%. Furthermore, a supervised object classification task based on a one‐hot vector target is also executed using Toyota Human Support Robot tactile inputs. The successful classification of objects of different hardness is enhanced when the device output response follows the 1/fγ power law of maximized information processing.

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“…Nanofluids, or colloidal dispersion of nanoparticles in a liquid solvent, have received a lot of attention in recent years because of their prospective applications [17], encompassing intrinsic plasticity, self-adaptability and fault-tolerance [18,19]. Even after long periods of storage, a stable colloid is expected to remain sediment-free.…”

Section: Introductionmentioning

confidence: 99%

Learning in colloids: Synapse-like ZnO + DMSO colloid

Kheirabadi¹,

Chioleriob²,

Phillipsa³

et al. 2022

Preprint

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Colloids submitted to electrical stimuli exhibit a reconfiguration that could be used to store information and, potentially compute. We investigated learning, memorization, and time and stimulation's voltage dependence of conductive network formation in a colloidal suspension of ZnO nanoparticles in DMSO. Relations between critical resistance and stimulation time were reconstructed. The critical voltage, i.e. the stimulation voltage necessary for dropping the resistance, was shown to decrease in response to an increase in stimulation time. We characterized a dispersion of conductive ZnO nanoparticles in the DMSO polymeric matrix using FESEM and UV-visible absorption spectrum.

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Liquid Cybernetic Systems: The Fourth‐Order Cybernetics

Cited by 13 publications

References 65 publications

Experimental Demonstration of In‐Memory Computing in a Ferrofluid System

Experimental Demonstration of In‐Memory Computing in a Ferrofluid System

Emergence of In‐Materio Intelligence from an Incidental Structure of a Single‐Walled Carbon Nanotube–Porphyrin Polyoxometalate Random Network

Learning in colloids: Synapse-like ZnO + DMSO colloid

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