Local Stability Analysis of Discrete-Time, Continuous-State, Complex-Valued Recurrent Neural Networks With Inner State Feedback

Mohamad, Mostafa; Teich, Werner G.; Lindner, J.

doi:10.1109/tnnls.2013.2281217

Cited by 19 publications

(13 citation statements)

References 24 publications

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“…11. If we consider only the equalization loop in Figure 19, we notice that it describes exactly the dynamical behavior of discrete-time recurrent neural networks [19,25,33,[54][55][56] u½l þ 1¼½ I−…”

Section: Joint Equalization and Decodingmentioning

confidence: 99%

A Continuous-Time Recurrent Neural Network for Joint Equalization and Decoding – Analog Hardware Implementation Aspects

Mohamad¹,

Oliveri²,

Teich³

et al. 2016

Artificial Neural Networks - Models and Applications

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Equalization and channel decoding are "traditionally" two cascade processes at the receiver side of a digital transmission. They aim to achieve a reliable and efficient transmission. For high data rates, the energy consumption of their corresponding algorithms is expected to become a limiting factor. For mobile devices with limited battery's size, the energy consumption, mirrored in the lifetime of the battery, becomes even more crucial. Therefore, an energy-efficient implementation of equalization and decoding algorithms is desirable. The prevailing way is by increasing the energy efficiency of the underlying digital circuits. However, we address here promising alternatives offered by mixed (analog/digital) circuits. We are concerned with modeling joint equalization and decoding as a whole in a continuous-time framework. In doing so, continuous-time recurrent neural networks play an essential role because of their nonlinear characteristic and special suitability for analog very-large-scale integration (VLSI). Based on the proposed model, we show that the superiority of joint equalization and decoding (a wellknown fact from the discrete-time case) preserves in analog. Additionally, analog circuit design related aspects such as adaptivity, connectivity and accuracy are discussed and linked to theoretical aspects of recurrent neural networks such as Lyapunov stability and simulated annealing.

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Section: Joint Equalization and Decodingmentioning

confidence: 99%

A Continuous-Time Recurrent Neural Network for Joint Equalization and Decoding – Analog Hardware Implementation Aspects

Mohamad¹,

Oliveri²,

Teich³

et al. 2016

Artificial Neural Networks - Models and Applications

Self Cite

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“…3 shows a continuous-time RNN. The dynamical behavior is given by the following pair of state space equations time cases [9].…”

Section: Vector-valued Transmission Modelmentioning

confidence: 99%

“…Reviewing the conditions, which an activation function in an RNN must fulfill to guarantee the Lyapunov stability [8], [9] and comparing them with the above listed properties, we notice that the optimum activation function for vector equalization based on RNNs fulfills these conditions. The importance of this approximation for analog implementation lies in the fact that the tanh can be easily realized in analog by differential amplifiers.…”

Section: A Properties Of the Optimum Activation Functionmentioning

confidence: 99%

Approximation of activation functions for vector equalization based on recurrent neural networks

Mohamad

Teich

Lindner

2014

2014 8th International Symposium on Turbo Codes and Iterative Information Processing (ISTC)

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Activation functions represent an essential element in all neural networks structures. They influence the overall behavior of neural networks decisively because of their nonlinear characteristic. Discrete-and continuous-time recurrent neural networks are a special class of neural networks. They have been shown to be able to perform vector equalization without the need for a training phase because they are Lyapunov stable under specific conditions. The activation function in this case depends on the symbol alphabet and is computationally complex to be evaluated. In addition, numerical instability can occur during the evaluation. Thus, there is a need for a computationally less complex and numerically stable evaluation. Especially for the continuous-time recurrent neural network, the evaluation must be suitable for an analog implementation. In this paper, we introduce an approximation of the activation function for vector equalization with recurrent neural networks. The activation function is approximated as a sum of shifted hyperbolic tangent functions, which can easily be realized in analog by a differential amplifier. Based on our ongoing research in this field, the analog implementation of vector equalization with recurrent neural networks is expected to improve the power/speed ratio by several order of magnitude compared with the digital one.

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“…Recently, neural networks have been electronically implemented and they have been used in real-time applications. However in electronic implementation of neural networks, some essential parameters of neural networks such as release rate of neurons, connection weights between the neurons and transmission delays might be subject to some deviations due to the tolerances of electronic components employed in the design of neural networks (Aizenberg, Paliy, Zurada, & Astola, 2008;Hu & Wang, 2012;Mostafa, Teich, & Lindner, 2013;Wang, Xue, Fei, & Li, 2013;Wu, Shi, Su, & Chu, 2011). As we know, time delays commonly exist in the neural networks because of the network traffic congestions and the finite speed of information transmission in networks.…”

Section: Introductionmentioning

confidence: 99%

“…Over the past decades, some work has been done to analyze the dynamic behavior of the equilibrium points of the various CVNNs. In Mostafa et al (2013), local stability analysis of discrete-time, continuous-state, complex-valued recurrent neural networks with inner state feedback was presented. In Zhou and Song (2013), the authors studied boundedness and complete stability of complex-valued neural networks with time delay by using free weighting matrices.…”

Section: Introductionmentioning

confidence: 99%

Dissipativity and passivity analysis for discrete-time complex-valued neural networks with time-varying delay

Nagamani

Ramasamy

2015

Cogent Mathematics

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In this paper, we consider the problem of dissipativity and passivity analysis for complex-valued discrete-time neural networks with time-varying delays. The neural network under consideration is subject to time-varying. Based on an appropriate Lyapunov-Krasovskii functional and by using the latest free-weighting matrix method, a sufficient condition is established to ensure that the neural networks under consideration is strictly (, , )-dissipative. The derived conditions are presented in terms of linear matrix inequalities. A numerical example is presented to illustrate the effectiveness of the proposed results.

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Local Stability Analysis of Discrete-Time, Continuous-State, Complex-Valued Recurrent Neural Networks With Inner State Feedback

Cited by 19 publications

References 24 publications

A Continuous-Time Recurrent Neural Network for Joint Equalization and Decoding – Analog Hardware Implementation Aspects

A Continuous-Time Recurrent Neural Network for Joint Equalization and Decoding – Analog Hardware Implementation Aspects

Approximation of activation functions for vector equalization based on recurrent neural networks

Dissipativity and passivity analysis for discrete-time complex-valued neural networks with time-varying delay

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