Associative Memory for Online Learning in Noisy Environments Using Self-Organizing Incremental Neural Network
Associative memory operating in a real environment must perform well in online incremental learning and be robust to noisy data because noisy associative patterns are presented sequentially in a real environment. We propose a novel associative memory that satisfies these requirements. Using the prop...
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| Veröffentlicht in: | IEEE transaction on neural networks and learning systems 2009-06, Vol.20 (6), p.964-972 |
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| creator | Sudo, A. Sato, A. Hasegawa, O. |
| description | Associative memory operating in a real environment must perform well in online incremental learning and be robust to noisy data because noisy associative patterns are presented sequentially in a real environment. We propose a novel associative memory that satisfies these requirements. Using the proposed method, new associative pairs that are presented sequentially can be learned accurately without forgetting previously learned patterns. The memory size of the proposed method increases adaptively with learning patterns. Therefore, it suffers neither redundancy nor insufficiency of memory size, even in an environment in which the maximum number of associative pairs to be presented is unknown before learning. Noisy inputs in real environments are classifiable into two types: noise-added original patterns and faultily presented random patterns. The proposed method deals with two types of noise. To our knowledge, no conventional associative memory addresses noise of both types. The proposed associative memory performs as a bidirectional one-to-many or many-to-one associative memory and deals not only with bipolar data, but also with real-valued data. Results demonstrate that the proposed method's features are important for application to an intelligent robot operating in a real environment. The originality of our work consists of two points: employing a growing self-organizing network for an associative memory, and discussing what features are necessary for an associative memory for an intelligent robot and proposing an associative memory that satisfies those requirements. |
| doi_str_mv | 10.1109/TNN.2009.2014374 |
| format | Article |
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We propose a novel associative memory that satisfies these requirements. Using the proposed method, new associative pairs that are presented sequentially can be learned accurately without forgetting previously learned patterns. The memory size of the proposed method increases adaptively with learning patterns. Therefore, it suffers neither redundancy nor insufficiency of memory size, even in an environment in which the maximum number of associative pairs to be presented is unknown before learning. Noisy inputs in real environments are classifiable into two types: noise-added original patterns and faultily presented random patterns. The proposed method deals with two types of noise. To our knowledge, no conventional associative memory addresses noise of both types. The proposed associative memory performs as a bidirectional one-to-many or many-to-one associative memory and deals not only with bipolar data, but also with real-valued data. Results demonstrate that the proposed method's features are important for application to an intelligent robot operating in a real environment. 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| subjects | Algorithms Applied sciences Artificial intelligence Associate members Association Associative memory Biomimetics - methods Computer science control theory systems Computer Simulation Connectionism. Neural networks Exact sciences and technology Humans Intelligent agent Intelligent robots Learning Models, Theoretical neural network Neural networks Neural Networks (Computer) Noise robustness online learning Online Systems Pattern Recognition, Automated - methods Redundancy Robotics - methods robustness to noise Self-organizing networks Studies Working environment noise |
| title | Associative Memory for Online Learning in Noisy Environments Using Self-Organizing Incremental Neural Network |
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