Unified framework of four Caputo fractional differences for initial and final value problems in discrete fractional calculus with variable bounds

Xiaomin  Li; Huaigu Tian; Peijun  Zhang; Jun  Ma

doi:10.59400/adecp3725

Unified framework of four Caputo fractional differences for initial and final value problems in discrete fractional calculus with variable bounds

Xiaomin Li
Xi’an Key Laboratory of Human-Machine Integration and Control Technology for Intelligent Rehabilitation, Xijing University, Xi’an 710123, China; College of Air Traffic Navigation, Air Force Engineering University, Xi’an 710051, China
Huaigu Tian
Xi’an Key Laboratory of Human-Machine Integration and Control Technology for Intelligent Rehabilitation, Xijing University, Xi’an 710123, China; Shaanxi International Joint Research Center for Applied Technology of Controllable Neutron Source, Xijing University, Xi’an 710123, China
Peijun Zhang
Xi’an Key Laboratory of Human-Machine Integration and Control Technology for Intelligent Rehabilitation, Xijing University, Xi’an 710123, China; Shaanxi International Joint Research Center for Applied Technology of Controllable Neutron Source, Xijing University, Xi’an 710123, China
Jun Ma
Xi’an Key Laboratory of Human-Machine Integration and Control Technology for Intelligent Rehabilitation, Xijing University, Xi’an 710123, China

Article ID: 3725

Keywords: Caputo fractional difference equation; forward and backward differences; variable upper and variable lower-limit sums; initial and final value problems

Abstract

Fractional calculus has emerged as a powerful tool for characterizing non-classical dynamic phenomena, yet its discretization remains fragmented, with existing studies primarily focusing on single combinations of variable bounds and difference directions. To address this gap, this paper proposes a unified theoretical framework for discrete fractional calculus by systematically introducing four novel Caputo fractional difference definitions, which integrate variable upper/lower-limit sums with forward/backward difference operations. First, we rigorously derive the fundamental properties of these four definitions, including the commutativity of fractional sums and differences, and their consistency with integer-order difference operations. Second, we construct fractional difference equations for each definition, establish their equivalence to Volterra sum equations, and provide explicit solutions and strict proofs for their corresponding initial and final value problems. To validate the theoretical results, we design four targeted computational cases and numerical simulations, confirm the consistency between theoretical solutions and numerical results, and intuitively demonstrate the long-memory effect of fractional-order discrete systems. Furthermore, we present a concise comparison of the four definitions, clarifying their suitability for discrete systems with distinct boundary conditions and dynamic characteristics. This work not only completes the theoretical system of discrete fractional calculus with variable bounds but also provides standardized and targeted mathematical tools for modeling complex discrete dynamic processes, laying a solid foundation for the practical application of discrete fractional calculus in fields such as engineering control, infectious disease modeling, and economic dynamics.

Published

2026-02-03

How to Cite

Li, X., Tian, H., Zhang, P., & Ma, J. (2026). Unified framework of four Caputo fractional differences for initial and final value problems in discrete fractional calculus with variable bounds. Advances in Differential Equations and Control Processes, 33(1). https://doi.org/10.59400/adecp3725

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Vol. 33 No. 1 (2026)

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Articles

This work is licensed under a Creative Commons Attribution 4.0 International License.

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