Hierarchical Model for Pattern Recognition
The computational complexity of neural network algorithms is an important factor in determining the effectiveness and efficiency of a pattern recognition scheme. The computational resource requirements, such as processing time and memory space, are heavily impacted by increases in the computational...
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| creator | Muhamad Amin, Anang Khan, Asad Nasution, Benny |
| description | The computational complexity of neural network algorithms is an important
factor in determining the effectiveness and efficiency of a pattern recognition
scheme. The computational resource requirements, such as processing time
and memory space, are heavily impacted by increases in the computational
complexity. Therefore, an increase in the size and/or the dimensionality of the
patterns disproportionately affects the computational resource requirement.
As mentioned in Chapter 1, size and dimensionality are two key aspects in
Internet-scale pattern recognition. Internet-scale pattern recognition can be
defined as the recognition process for large-scale data. It has been influenced
by the development of sophisticated data-harvesting techniques and growth
in data storage technologies.
In Chapter 2, the theoretical background of the distributed pattern recog-nition (DPR) scheme and some examples of DPR implementations were presented. A one-shot learning mechanism is considered important in the design
of effective and scalable DPR schemes. In Chapter 3, we presented the Graph
Neuron (GN) algorithm, a DPR scheme that uses one-shot learning. This fast
learning approach distributes learning using the adjacency comparison approach. A discussion of the limitations of the GN algorithm, including false
recalls generated by the crosstalk problem, was also presented.
In this chapter, the discussion of a GN-based DPR scheme will be extended.This chapter will elaborate on the details of the hierarchical concept and model
for a GN implementation. The hierarchical approach eliminates the crosstalk
problem of the single-layer GN scheme. The effects of a hierarchical structure
on the complexity and scalability of the DPR scheme will also be discussed. |
| doi_str_mv | 10.1201/b12989-10 |
| format | Book Chapter |
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factor in determining the effectiveness and efficiency of a pattern recognition
scheme. The computational resource requirements, such as processing time
and memory space, are heavily impacted by increases in the computational
complexity. Therefore, an increase in the size and/or the dimensionality of the
patterns disproportionately affects the computational resource requirement.
As mentioned in Chapter 1, size and dimensionality are two key aspects in
Internet-scale pattern recognition. Internet-scale pattern recognition can be
defined as the recognition process for large-scale data. It has been influenced
by the development of sophisticated data-harvesting techniques and growth
in data storage technologies.
In Chapter 2, the theoretical background of the distributed pattern recog-nition (DPR) scheme and some examples of DPR implementations were presented. A one-shot learning mechanism is considered important in the design
of effective and scalable DPR schemes. In Chapter 3, we presented the Graph
Neuron (GN) algorithm, a DPR scheme that uses one-shot learning. This fast
learning approach distributes learning using the adjacency comparison approach. A discussion of the limitations of the GN algorithm, including false
recalls generated by the crosstalk problem, was also presented.
In this chapter, the discussion of a GN-based DPR scheme will be extended.This chapter will elaborate on the details of the hierarchical concept and model
for a GN implementation. The hierarchical approach eliminates the crosstalk
problem of the single-layer GN scheme. The effects of a hierarchical structure
on the complexity and scalability of the DPR scheme will also be discussed.</description><identifier>ISBN: 146651096X</identifier><identifier>ISBN: 9781466510968</identifier><identifier>EISBN: 9780429096471</identifier><identifier>EISBN: 9781466510975</identifier><identifier>EISBN: 042909647X</identifier><identifier>EISBN: 1466510978</identifier><identifier>DOI: 10.1201/b12989-10</identifier><identifier>OCLC: 859886711</identifier><identifier>LCCallNum: QA76.9.D343 M84 2013</identifier><language>eng</language><publisher>United Kingdom: Chapman and Hall/CRC</publisher><subject>Automatic control engineering ; Internet guides & online services</subject><ispartof>Internet-Scale Pattern Recognition, 2013, p.67-90</ispartof><rights>2013 by Taylor & Francis Group, LLC</rights><woscitedreferencessubscribed>false</woscitedreferencessubscribed></display><links><openurl>$$Topenurl_article</openurl><openurlfulltext>$$Topenurlfull_article</openurlfulltext><thumbnail>$$Uhttps://ebookcentral.proquest.com/covers/1565556-l.jpg</thumbnail><link.rule.ids>779,780,784,793,24781,27925</link.rule.ids></links><search><creatorcontrib>Muhamad Amin, Anang</creatorcontrib><creatorcontrib>Khan, Asad</creatorcontrib><creatorcontrib>Nasution, Benny</creatorcontrib><title>Hierarchical Model for Pattern Recognition</title><title>Internet-Scale Pattern Recognition</title><description>The computational complexity of neural network algorithms is an important
factor in determining the effectiveness and efficiency of a pattern recognition
scheme. The computational resource requirements, such as processing time
and memory space, are heavily impacted by increases in the computational
complexity. Therefore, an increase in the size and/or the dimensionality of the
patterns disproportionately affects the computational resource requirement.
As mentioned in Chapter 1, size and dimensionality are two key aspects in
Internet-scale pattern recognition. Internet-scale pattern recognition can be
defined as the recognition process for large-scale data. It has been influenced
by the development of sophisticated data-harvesting techniques and growth
in data storage technologies.
In Chapter 2, the theoretical background of the distributed pattern recog-nition (DPR) scheme and some examples of DPR implementations were presented. A one-shot learning mechanism is considered important in the design
of effective and scalable DPR schemes. In Chapter 3, we presented the Graph
Neuron (GN) algorithm, a DPR scheme that uses one-shot learning. This fast
learning approach distributes learning using the adjacency comparison approach. A discussion of the limitations of the GN algorithm, including false
recalls generated by the crosstalk problem, was also presented.
In this chapter, the discussion of a GN-based DPR scheme will be extended.This chapter will elaborate on the details of the hierarchical concept and model
for a GN implementation. The hierarchical approach eliminates the crosstalk
problem of the single-layer GN scheme. The effects of a hierarchical structure
on the complexity and scalability of the DPR scheme will also be discussed.</description><subject>Automatic control engineering</subject><subject>Internet guides & online services</subject><isbn>146651096X</isbn><isbn>9781466510968</isbn><isbn>9780429096471</isbn><isbn>9781466510975</isbn><isbn>042909647X</isbn><isbn>1466510978</isbn><fulltext>true</fulltext><rsrctype>book_chapter</rsrctype><creationdate>2013</creationdate><recordtype>book_chapter</recordtype><recordid>eNotkE1Lw0AURUdEsdYu_AdZC9F5yXwuS1ErVBRRcBdeJi92MGbqZFT89ybU1eMuzuG-y9g58EsoOFzVUFhjc-AHbGG14aKw3Cqh4ZCdglBKwhhfj9nMSGuM0gAnbDEMvuZSCaGM0DN2sfYUMbqtd9hl96GhLmtDzB4xJYp99kQuvPU--dCfsaMWu4EW_3fOXm6un1frfPNwe7dabnIPRqWcjCXpROtsrQRaSUo50K2C2opGo0DS1pRGIJeN0jUiElFTliTbdoLKOSv23l0Mn180pIrqEN4d9Sli57a4G5sNFUglpVQVQKXMCC33kO_H-h_4E2LXVAl_uxDbiL3zwyQZMV5N41X78ab4PdrG94ryD4-EZCE</recordid><startdate>2013</startdate><enddate>2013</enddate><creator>Muhamad Amin, Anang</creator><creator>Khan, Asad</creator><creator>Nasution, Benny</creator><general>Chapman and Hall/CRC</general><general>CRC Press LLC</general><scope>FFUUA</scope></search><sort><creationdate>2013</creationdate><title>Hierarchical Model for Pattern Recognition</title><author>Muhamad Amin, Anang ; Khan, Asad ; Nasution, Benny</author></sort><facets><frbrtype>5</frbrtype><frbrgroupid>cdi_FETCH-LOGICAL-i186t-e89e5c4fc9b64a95e66c17f61b94d7a4ae798384a05d67baaaeeed33e5fffc9b3</frbrgroupid><rsrctype>book_chapters</rsrctype><prefilter>book_chapters</prefilter><language>eng</language><creationdate>2013</creationdate><topic>Automatic control engineering</topic><topic>Internet guides & online services</topic><toplevel>online_resources</toplevel><creatorcontrib>Muhamad Amin, Anang</creatorcontrib><creatorcontrib>Khan, Asad</creatorcontrib><creatorcontrib>Nasution, Benny</creatorcontrib><collection>ProQuest Ebook Central - Book Chapters - Demo use only</collection></facets><delivery><delcategory>Remote Search Resource</delcategory><fulltext>fulltext</fulltext></delivery><addata><au>Muhamad Amin, Anang</au><au>Khan, Asad</au><au>Nasution, Benny</au><format>book</format><genre>bookitem</genre><ristype>CHAP</ristype><atitle>Hierarchical Model for Pattern Recognition</atitle><btitle>Internet-Scale Pattern Recognition</btitle><date>2013</date><risdate>2013</risdate><spage>67</spage><epage>90</epage><pages>67-90</pages><isbn>146651096X</isbn><isbn>9781466510968</isbn><eisbn>9780429096471</eisbn><eisbn>9781466510975</eisbn><eisbn>042909647X</eisbn><eisbn>1466510978</eisbn><abstract>The computational complexity of neural network algorithms is an important
factor in determining the effectiveness and efficiency of a pattern recognition
scheme. The computational resource requirements, such as processing time
and memory space, are heavily impacted by increases in the computational
complexity. Therefore, an increase in the size and/or the dimensionality of the
patterns disproportionately affects the computational resource requirement.
As mentioned in Chapter 1, size and dimensionality are two key aspects in
Internet-scale pattern recognition. Internet-scale pattern recognition can be
defined as the recognition process for large-scale data. It has been influenced
by the development of sophisticated data-harvesting techniques and growth
in data storage technologies.
In Chapter 2, the theoretical background of the distributed pattern recog-nition (DPR) scheme and some examples of DPR implementations were presented. A one-shot learning mechanism is considered important in the design
of effective and scalable DPR schemes. In Chapter 3, we presented the Graph
Neuron (GN) algorithm, a DPR scheme that uses one-shot learning. This fast
learning approach distributes learning using the adjacency comparison approach. A discussion of the limitations of the GN algorithm, including false
recalls generated by the crosstalk problem, was also presented.
In this chapter, the discussion of a GN-based DPR scheme will be extended.This chapter will elaborate on the details of the hierarchical concept and model
for a GN implementation. The hierarchical approach eliminates the crosstalk
problem of the single-layer GN scheme. The effects of a hierarchical structure
on the complexity and scalability of the DPR scheme will also be discussed.</abstract><cop>United Kingdom</cop><pub>Chapman and Hall/CRC</pub><doi>10.1201/b12989-10</doi><oclcid>859886711</oclcid><tpages>24</tpages></addata></record> |
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| identifier | ISBN: 146651096X |
| ispartof | Internet-Scale Pattern Recognition, 2013, p.67-90 |
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| language | eng |
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| source | O'Reilly Online Learning: Academic/Public Library Edition |
| subjects | Automatic control engineering Internet guides & online services |
| title | Hierarchical Model for Pattern Recognition |
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