Search (4 results, page 1 of 1)

0.001539155 = product of:
  0.010774084 = sum of:
    0.010774084 = weight(_text_:a in 120) [ClassicSimilarity], result of:
      0.010774084 = score(doc=120,freq=4.0), product of:
        0.04271548 = queryWeight, product of:
          1.153047 = idf(docFreq=37942, maxDocs=44218)
          0.03704574 = queryNorm
        0.25222903 = fieldWeight in 120, product of:
          2.0 = tf(freq=4.0), with freq of:
            4.0 = termFreq=4.0
          1.153047 = idf(docFreq=37942, maxDocs=44218)
          0.109375 = fieldNorm(doc=120)
  0.14285715 = coord(1/7)

Type

a

0.0012438248 = product of:
  0.008706774 = sum of:
    0.008706774 = weight(_text_:a in 119) [ClassicSimilarity], result of:
      0.008706774 = score(doc=119,freq=2.0), product of:
        0.04271548 = queryWeight, product of:
          1.153047 = idf(docFreq=37942, maxDocs=44218)
          0.03704574 = queryNorm
        0.20383182 = fieldWeight in 119, product of:
          1.4142135 = tf(freq=2.0), with freq of:
            2.0 = termFreq=2.0
          1.153047 = idf(docFreq=37942, maxDocs=44218)
          0.125 = fieldNorm(doc=119)
  0.14285715 = coord(1/7)

Type

a

0.0012168088 = product of:
  0.008517661 = sum of:
    0.008517661 = weight(_text_:a in 2883) [ClassicSimilarity], result of:
      0.008517661 = score(doc=2883,freq=10.0), product of:
        0.04271548 = queryWeight, product of:
          1.153047 = idf(docFreq=37942, maxDocs=44218)
          0.03704574 = queryNorm
        0.19940455 = fieldWeight in 2883, product of:
          3.1622777 = tf(freq=10.0), with freq of:
            10.0 = termFreq=10.0
          1.153047 = idf(docFreq=37942, maxDocs=44218)
          0.0546875 = fieldNorm(doc=2883)
  0.14285715 = coord(1/7)

Abstract

Optimal retrieval in on-line searching can be achieved through combined use of both natural language and controlled vocabularies. However, there is a large variety of types of controlled vocabulary in data bases and often more than one in a single data base. Optimal use of these vocabularies requires understanding what types of languages are involved, and taking advantage of the particular mix of vocabularies in a given data base. Examples 4 major types of indexing and classification used in data bases and puts these 4 in the context of 3 other approaches to subject access. Discusses how to evaluate a new data base for various forms of subject access.

Type

a

0.0012168088 = product of:
  0.008517661 = sum of:
    0.008517661 = weight(_text_:a in 207) [ClassicSimilarity], result of:
      0.008517661 = score(doc=207,freq=10.0), product of:
        0.04271548 = queryWeight, product of:
          1.153047 = idf(docFreq=37942, maxDocs=44218)
          0.03704574 = queryNorm
        0.19940455 = fieldWeight in 207, product of:
          3.1622777 = tf(freq=10.0), with freq of:
            10.0 = termFreq=10.0
          1.153047 = idf(docFreq=37942, maxDocs=44218)
          0.0546875 = fieldNorm(doc=207)
  0.14285715 = coord(1/7)

Abstract

Optimal retrieval in on-line searching can be achieved through combined use of both natural language and controlled vocabularies. However, there is a large variety of types of controlled vocabulary in data bases and often more than one in a single data base. Optimal use of these vocabularies requires understanding what types of languages are involved, and taking advantage of the particular mix of vocabularies in a given data base. Examples 4 major types of indexing and classification used in data bases and puts these 4 in the context of 3 other approaches to subject access. Discusses how to evaluate a new data base for various forms of subject access.

Type

a