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{{More footnotes|date=January 2012}}
{{Artificial intelligence|Major goals}}
'''Automated
In known environments with available models, planning can be done offline. Solutions can be found and evaluated prior to execution. In dynamically unknown environments, the [[strategy]] often needs to be revised online. Models and policies must be adapted. Solutions usually resort to iterative [[trial and error]] processes commonly seen in [[artificial intelligence]]. These include [[dynamic programming]], [[reinforcement learning]] and [[combinatorial optimization]]. Languages used to describe planning and scheduling are often called [[action language]]s.
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* and a single agent.
When full observability is replaced by partial observability, planning corresponds to a [[partially observable Markov decision process]] (POMDP).
If there are more than one agent, we have [[multi-agent planning]], which is closely related to [[game theory]].
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The most commonly used languages for representing planning domains and specific planning problems, such as [[Stanford Research Institute Problem Solver|STRIPS]] and [[Planning Domain Definition Language|PDDL]] for Classical Planning, are based on state variables. Each possible state of the world is an assignment of values to the state variables, and actions determine how the values of the state variables change when that action is taken. Since a set of state variables induce a state space that has a size that is exponential in the set, planning, similarly to many other computational problems, suffers from the [[curse of dimensionality]] and the [[combinatorial explosion]].
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{{See also|Sussman anomaly}}
===Action model learning===
Creating ___domain models is difficult, takes a lot of time, and can easily lead to mistakes. To help with this, several methods have been developed to automatically learn full or partial ___domain models from given observations.
<ref>{{cite conference |author=Callanan, Ethan and De Venezia, Rebecca and Armstrong, Victoria and Paredes, Alison and Chakraborti, Tathagata and Muise, Christian |title=MACQ: A Holistic View of Model Acquisition Techniques |conference=ICAPS Workshop on Knowledge Engineering for Planning and Scheduling (KEPS) |year=2022 |url=https://icaps22.icaps-conference.org/workshops/KEPS/KEPS-22_paper_4962.pdf}}</ref>
<ref>{{cite journal |author=Aineto, Diego and Jiménez Celorrio, Sergio and Onaindia, Eva |title=Learning action models with minimal observability |journal=Artificial Intelligence |volume=275 |pages=104–137 |year=2019 |doi=10.1016/j.artint.2019.05.003 |url=https://doi.org/10.1016/j.artint.2019.05.003|doi-access=free |hdl=10251/144560 |hdl-access=free }}</ref>
<ref>{{cite journal |author=Jiménez, Sergio and de la Rosa, Tomás and Fernández, Susana and Fernández, Fernando and Borrajo, Daniel |title=A review of machine learning for automated planning |journal=The Knowledge Engineering Review |volume=27 |issue=4 |pages=433–467 |year=2012 |doi=10.1017/S026988891200001X |url=https://doi.org/10.1017/S026988891200001X|url-access=subscription }}</ref>
*Read more: [[Action model learning]]
=== Reduction to other problems ===
* reduction to the [[propositional satisfiability]] problem ([[satplan]]).
* reduction to [[
===Temporal planning===
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Deterministic planning was introduced with the [[Stanford Research Institute Problem Solver|STRIPS]] planning system, which is a hierarchical planner. Action names are ordered in a sequence and this is a plan for the robot. Hierarchical planning can be compared with an automatic generated [[Behavior tree (artificial intelligence, robotics and control)|behavior tree]].<ref>{{cite journal |title=Building a Planner: A Survey of Planning Systems Used in Commercial Video Games |author=Neufeld, Xenija and Mostaghim, Sanaz and Sancho-Pradel, Dario and Brand, Sandy |journal=IEEE Transactions on Games |year=2017 |publisher=IEEE}}</ref> The disadvantage is, that a normal behavior tree is not so expressive like a computer program. That means, the notation of a behavior graph contains action commands, but no [[Loop (computing)|loops]] or if-then-statements. Conditional planning overcomes the bottleneck and introduces an elaborated notation which is similar to a [[control flow]], known from other programming languages like [[Pascal (programming language)|Pascal]]. It is very similar to [[program synthesis]], which means a planner generates sourcecode which can be executed by an interpreter.<ref>{{cite conference |title=Short-term human robot interaction through conditional planning and execution |author=Sanelli, Valerio and Cashmore, Michael and Magazzeni, Daniele and Iocchi, Luca |conference=Proc. of International Conference on Automated Planning and Scheduling (ICAPS) |year=2017 |url=https://www.aaai.org/ocs/index.php/ICAPS/ICAPS17/paper/download/15750/15146 |access-date=2019-08-16 |archive-date=2019-08-16 |archive-url=https://web.archive.org/web/20190816172319/https://www.aaai.org/ocs/index.php/ICAPS/ICAPS17/paper/download/15750/15146 |url-status=live }}</ref>
An early example of a conditional planner is “Warplan-C” which was introduced in the mid 1970s.<ref>{{cite conference |title=Conditional nonlinear planning |author=Peot, Mark A and Smith, David E |conference=Artificial Intelligence Planning Systems |pages=189–197 |year=1992 |publisher=Elsevier|url=https://sites.google.com/site/markpeot2/peot92conditional.pdf}}</ref> What is the difference between a normal sequence and a complicated plan, which contains if-then-statements? It has to do with uncertainty at [[Run time (program lifecycle phase)|runtime]] of a plan. The idea is that a plan can react to [[Soft sensor|sensor signals]] which are unknown for the planner. The planner generates two choices in advance. For example, if an object was detected, then action A is executed, if an object is missing, then action B is executed.<ref>{{cite conference |title=Conditional progressive planning under uncertainty |author=Karlsson, Lars |conference=IJCAI |pages=431–438 |year=2001|url=https://www.researchgate.net/publication/2927504}}</ref> A major advantage of conditional planning is the ability to handle [[Partial-order planning|partial plans]].<ref>{{cite
====
We speak of "contingent planning" when the environment is observable through sensors, which can be faulty. It is thus a situation where the planning agent acts under incomplete information. For a contingent planning problem, a plan is no longer a sequence of actions but a [[decision tree]] because each step of the plan is represented by a set of states rather than a single perfectly observable state, as in the case of classical planning.<ref>{{Cite conference|conference=International Joint Conference of Artificial Intelligence (IJCAI)|year=2009|author1=Alexandre Albore|author2=Hector Palacios|author3=Hector Geffner|title=A Translation-Based Approach to Contingent Planning|publisher=AAAI|___location=Pasadena, CA|url=http://www.aaai.org/ocs/index.php/IJCAI/IJCAI-09/paper/download/587/852|access-date=2019-07-03|archive-date=2019-07-03|archive-url=https://web.archive.org/web/20190703164319/http://www.aaai.org/ocs/index.php/IJCAI/IJCAI-09/paper/download/587/852|url-status=dead}}</ref> The selected actions depend on the state of the system. For example, if it rains, the agent chooses to take the umbrella, and if it doesn't, they may choose not to take it.
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==== Conformant planning ====
Conformant planning is when the agent is uncertain about the state of the system, and it cannot make any observations. The agent then has beliefs about the real world, but cannot verify them with sensing actions, for instance. These problems are solved by techniques similar to those of classical planning,<ref>{{Cite journal|title=Compiling uncertainty away in conformant planning problems with bounded width|journal=Journal of Artificial Intelligence Research|last1=Palacios|first1=Hector|volume=35|pages=623–675|last2=Geffner|first2=Hector|year=2009|url=https://www.jair.org/index.php/jair/article/download/10618/25394|doi=10.1613/jair.2708|doi-access=free|access-date=2019-08-16|archive-date=2020-04-27|archive-url=https://web.archive.org/web/20200427045035/https://www.jair.org/index.php/jair/article/download/10618/25394|url-status=live|arxiv=1401.3468}}</ref><ref>{{Cite conference|title=Effective heuristics and belief tracking for planning with incomplete information|conference=Twenty-First International Conference on Automated Planning and Scheduling (ICAPS)|last1=Albore|first1=Alexandre|last2=Ramírez|first2=Miquel|year=2011|last3=Geffner|first3=Hector|url=https://www.aaai.org/ocs/index.php/ICAPS/ICAPS11/paper/viewFile/2709/3129|access-date=2019-08-16|archive-date=2017-07-06|archive-url=https://web.archive.org/web/20170706012917/https://aaai.org/ocs/index.php/ICAPS/ICAPS11/paper/viewFile/2709/3129/|url-status=live}}</ref> but where the state space is exponential in the size of the problem, because of the uncertainty about the current state. A solution for a conformant planning problem is a sequence of actions. Haslum and Jonsson have demonstrated that the problem of conformant planning is [[EXPSPACE]]-complete,<ref>{{cite
== Deployment of planning systems ==
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* [[Action description language]]
* [[Action model learning]]
* [[Actor model]]
* [[Applications of artificial intelligence]]
* [[Constraint satisfaction problem]]
* [[International Conference on Automated Planning and Scheduling]]
* [[Reactive planning]]
* [[Scheduling (computing)]]
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; Lists
* [[List of SMT solvers]]▼
* [[List of constraint programming languages]]
* [[List of emerging technologies]]
▲* [[List of SMT solvers]]
* [[Outline of artificial intelligence]]
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