Fully-Observable System
A Fully-Observable System is a observable system where an agent can sense at any point in time is completely sufficient to make the optimal decision.
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- Counter-Example(s):
- See: Fully Observable Markov Decision Process, Chess Game.
References
2015
- (Wikipedia, 2015) ⇒ http://en.wikipedia.org/wiki/partially_observable_system Retrieved:2015-2-1.
- A partially observable system is one in which the entire state of the system is not fully visible to an external sensor. In a partially observable system the observer may utilise a memory system in order to add information to the observer's understanding to the system. [1]
An example of a partially observable system would be a card game in which some of the cards are discarded into a pile face down. In this case the observer is only able to view their own cards and potentially those of the dealer. They are not able to view the face-down (used) cards, and nor are they able to view the cards which will be dealt at some stage in the future. A memory system can be used to remember the previously dealt cards that are now on the used pile. This adds to the total sum of knowledge that the observer can use to make decisions.
In contrast, a fully observable system would be that of chess. In chess (apart from the 'who is moving next' state) the full state of the system is observable at any point in time.
Partially observable is a term used in a variety of mathematical settings, including that of Artificial Intelligence and Partially observable Markov decision processes.
- A partially observable system is one in which the entire state of the system is not fully visible to an external sensor. In a partially observable system the observer may utilise a memory system in order to add information to the observer's understanding to the system. [1]
2014
- https://www.udacity.com/wiki/cs271/unit1-notes
- QUOTE: fully versus partially observable. An environment is called fully observable if what your agent can sense at any point in time is completely sufficient to make the optimal decision i.e. its sensors can see the entire state of the environment. That is in contrast to some other environments where agents need memory to make the best decision.