Zeno's paradoxes are a famous set of philosophical problems generally understood to have been devised by Greek philosopher Zeno of Elea (c. 490–430 BC). The argument revolves around notions of motion, infinity, and the division of time and space.

In this paradox, the swift Achilles races a tortoise, who is given a head start. Zeno argues that Achilles will never overtake the tortoise, since whenever Achilles reaches where the tortoise was, the tortoise has already moved ahead, perpetually maintaining a lead.

This paradox argues that to reach a destination, one must first reach the halfway point, then the halfway point of the remaining distance, and so on, ad infinitum. Zeno asserts this requires completing an infinite number of tasks, which is impossible, thereby implying that any motion is an illusion.

Zeno declares that an arrow in flight is at each instant motionless, since it's either at the position where it is or it's not. Thus, if every instant involves no motion and time comprises these instants, motion doesn't exist.

Several solutions to these paradoxes have been proposed throughout history, such as the practical demonstration by Diogenes the Cynic who simply got up and walked to disprove Zeno's conclusion. Notably, Aristotle proposed that as distance decreases, the time needed to cover those distances also decreases. Additionally, he differentiated between "things infinite in respect of divisibility" and things that are infinite in extension. Thomas Aquinas furthered this point by explaining that instants are not parts of time.

Archimedes developed a method for deriving a finite sum from infinitely many terms that get progressively smaller, and Bertrand Russell introduced the "at-at theory of motion," suggesting motion is just change in position over time. Several modern thinkers such as Nick Huggett, Peter Lynds, and Hermann Weyl have proposed their theories to resolve Zeno's paradoxes.

In modern times, while the mathematical implications of Zeno's paradoxes have been largely resolved with the development of the epsilon-delta formulation of calculus, philosophers argue that not all issues raised by the paradoxes are resolved. Zeno's paradoxes continue to spur debate about the nature of infinity, time, space, and motion.

The paradoxes also have counterparts in other traditions, like ancient Chinese philosophers from the Mohist School of Names who developed paradoxes similar to Zeno’s. The Quantum Zeno effect in modern physics, first theorized in 1958, also parallels Zeno's arrow paradox, illustrating how observation can hinder or inhibit the motion of a quantum system.

In verification and design of timed and hybrid systems, Zeno behaviour refers to a system that includes an infinite number of discrete steps in a finite amount of time. In system models, these behaviours are often excluded since they cannot be implemented with a digital controller.