Due to the finite lifespan of particles and constraints imposed by physical space, tempered fractional calculus has attracted increasing attention. This paper focuses on discrete-time tempered fractional neural networks (DTFNNs) with time delays and investigates their quasi-projective synchronization. By employing discrete convolution techniques and the discrete Laplace transform of tempered fractional operators, a fractional difference inequality is derived. Combining inequality methods with the Lyapunov function approach, easily verifiable sufficient conditions are established to guarantee synchronization of the proposed neural networks under a designed adaptive controller. Finally, numerical simulations are presented to validate the effectiveness and applicability of the theoretical results.
Zhang et al. (Wed,) studied this question.
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