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Chi-square automatic interaction detection

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(Redirected from CHAID) Decision tree learning technique

Chi-square automatic interaction detection (CHAID) is a decision tree technique based on adjusted significance testing (Bonferroni correction, Holm-Bonferroni testing).

History

CHAID is based on a formal extension of AID (Automatic Interaction Detection) and THAID (THeta Automatic Interaction Detection) procedures of the 1960s and 1970s, which in turn were extensions of earlier research, including that performed by Belson in the UK in the 1950s.

In 1975, the CHAID technique itself was developed in South Africa. It was published in 1980 by Gordon V. Kass, who had completed a PhD thesis on the topic.

A history of earlier supervised tree methods can be found in Ritschard, including a detailed description of the original CHAID algorithm and the exhaustive CHAID extension by Biggs, De Ville, and Suen.

Properties

CHAID can be used for prediction (in a similar fashion to regression analysis, this version of CHAID being originally known as XAID) as well as classification, and for detection of interaction between variables.

In practice, CHAID is often used in the context of direct marketing to select groups of consumers to predict how their responses to some variables affect other variables, although other early applications were in the fields of medical and psychiatric research.

Like other decision trees, CHAID's advantages are that its output is highly visual and easy to interpret. Because it uses multiway splits by default, it needs rather large sample sizes to work effectively, since with small sample sizes the respondent groups can quickly become too small for reliable analysis.

One important advantage of CHAID over alternatives such as multiple regression is that it is non-parametric.

See also

References

  1. ^ Ritschard, Gilbert (2013). "CHAID and Earlier Supervised Tree Methods". Contemporary Issues in Exploratory Data Mining in the Behavioral Sciences, McArdle, J.J. And G. Ritschard (Eds). New York: Routledge: 48–74.
  2. ^ Kass, G. V. (1980). "An Exploratory Technique for Investigating Large Quantities of Categorical Data". Applied Statistics. 29 (2): 119–127. doi:10.2307/2986296. JSTOR 2986296.
  3. ^ Biggs, David; De Ville, Barry; Suen, Ed (1991). "A method of choosing multiway partitions for classification and decision trees". Journal of Applied Statistics. 18 (1): 49–62. doi:10.1080/02664769100000005. ISSN 0266-4763.
  4. ^ Morgan, James N.; Sonquist, John A. (1963). "Problems in the Analysis of Survey Data, and a Proposal". Journal of the American Statistical Association. 58 (302): 415–434. doi:10.1080/01621459.1963.10500855. ISSN 0162-1459.
  5. ^ Messenger, Robert; Mandell, Lewis (1972). "A Modal Search Technique for Predictive Nominal Scale Multivariate Analysis". Journal of the American Statistical Association. 67 (340): 768–772. doi:10.1080/01621459.1972.10481290. ISSN 0162-1459.
  6. ^ Morgan, James N. (1973). THAID, a sequential analysis program for the analysis of nominal scale dependent variables. Robert C. Messenger. Ann Arbor, Mich. ISBN 0-87944-137-2. OCLC 666930.{{cite book}}: CS1 maint: location missing publisher (link)
  7. Belson, William A. (1959). "Matching and Prediction on the Principle of Biological Classification". Applied Statistics. 8 (2): 65–75. doi:10.2307/2985543. JSTOR 2985543.

Bibliography

  • Press, Laurence I.; Rogers, Miles S.; & Shure, Gerald H.; An interactive technique for the analysis of multivariate data, Behavioral Science, Vol. 14 (1969), pp. 364–370
  • Hawkins, Douglas M.; and Kass, Gordon V.; Automatic Interaction Detection, in Hawkins, Douglas M. (ed), Topics in Applied Multivariate Analysis, Cambridge University Press, Cambridge, 1982, pp. 269–302
  • Hooton, Thomas M.; Haley, Robert W.; Culver, David H.; White, John W.; Morgan, W. Meade; & Carroll, Raymond J.; The Joint Associations of Multiple Risk Factors with the Occurrence of Nosocomial Infections, American Journal of Medicine, Vol. 70, (1981), pp. 960–970
  • Brink, Susanne; & Van Schalkwyk, Dirk J.; Serum ferritin and mean corpuscular volume as predictors of bone marrow iron stores, South African Medical Journal, Vol. 61, (1982), pp. 432–434
  • McKenzie, Dean P.; McGorry, Patrick D.; Wallace, Chris S.; Low, Lee H.; Copolov, David L.; & Singh, Bruce S.; Constructing a Minimal Diagnostic Decision Tree, Methods of Information in Medicine, Vol. 32 (1993), pp. 161–166
  • Magidson, Jay; The CHAID approach to segmentation modeling: chi-squared automatic interaction detection, in Bagozzi, Richard P. (ed); Advanced Methods of Marketing Research, Blackwell, Oxford, GB, 1994, pp. 118–159
  • Hawkins, Douglas M.; Young, S. S.; & Rosinko, A.; Analysis of a large structure-activity dataset using recursive partitioning, Quantitative Structure-Activity Relationships, Vol. 16, (1997), pp. 296–302

External lkinks

  • Luchman, J.N.; CHAID: Stata module to conduct chi-square automated interaction detection, Available for free download, or type within Stata: ssc install chaid.
  • Luchman, J.N.; CHAIDFOREST: Stata module to conduct random forest ensemble classification based on chi-square automated interaction detection (CHAID) as base learner, Available for free download, or type within Stata: ssc install chaidforest.
  • IBM SPSS Decision Trees grows exhaustive CHAID trees as well as a few other types of trees such as CART.
  • An R package CHAID is available on R-Forge.
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