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| Dünamiline programmeerimine× | Kitsendustega programmeerimine× | Süva tugevdamisõpe× | |
|---|---|---|---|
| Valdkond≠ | Optimeerimine | Optimeerimine | Süvaõpe |
| Perekond≠ | Process / pipeline | Process / pipeline | Machine learning |
| Tekkeaasta≠ | 1957 | 2006 | 2015 |
| Looja≠ | Richard Bellman | Rossi, van Beek & Walsh | Mnih, V. et al. (DQN) |
| Tüüp≠ | Exact combinatorial optimization via recursive decomposition | Declarative combinatorial optimization | Sequential decision-making (agent–environment interaction) |
| Algallikas≠ | Bellman, R. (1957). Dynamic Programming. Princeton University Press. ISBN: 978-0-691-07951-6 | Rossi, F., van Beek, P., & Walsh, T. (Eds.). (2006). Handbook of Constraint Programming. Elsevier. ISBN: 978-0-444-52726-4 | Mnih, V. et al. (2015). Human-Level Control through Deep Reinforcement Learning. Nature, 518, 529–533. DOI ↗ |
| Rööpnimetused≠ | DP, Bellman's Principle of Optimality, Recursive Optimization, Dinamik Programlama | Constraint Satisfaction Programming, Constraint-Based Optimization, Kısıt Programlama, CSP Optimization | Derin Pekiştirmeli Öğrenme (DQN / PPO / A3C), derin pekiştirmeli öğrenme, deep RL, DRL |
| Seotud≠ | 3 | 3 | 4 |
| Kokkuvõte≠ | Dynamic Programming (DP) is an exact optimization technique introduced by Richard Bellman in 1957 for solving multi-stage decision problems. It decomposes a complex problem into simpler, overlapping subproblems, solves each subproblem once, and stores the results to avoid redundant computation. Grounded in the Principle of Optimality, DP guarantees globally optimal solutions whenever the problem exhibits overlapping subproblems and optimal substructure. | Constraint Programming (CP) is a declarative optimization paradigm in which a problem is formulated as a set of variables, finite domains, and constraints, and a solver systematically searches for assignments that satisfy all constraints. Formalized comprehensively by Rossi, van Beek, and Walsh in their 2006 Handbook of Constraint Programming, CP unifies propagation-based pruning with intelligent backtracking search to tackle combinatorial problems across scheduling, planning, and configuration domains. | Deep Reinforcement Learning combines neural networks with reinforcement learning so an agent learns by interacting with an environment, popularised by Mnih and colleagues' 2015 Nature work on human-level Atari control. Instead of learning from a fixed labelled dataset, the agent takes actions, observes rewards, and gradually shapes a policy that maximises long-run return. |
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