השוואת שיטות
סקרו את השיטות שבחרתם זו לצד זו; שורות שבהן יש הבדל מודגשות.
| מודלים של אינטראקציה מרחבית (כבידה)× | רגרסיית פואסון ובינומית שלילית× | |
|---|---|---|
| תחום≠ | ניתוח מרחבי | אקונומטריקה |
| משפחה | Regression model | Regression model |
| שנת המקור≠ | 1971 | 1998 |
| הוגה השיטה≠ | Alan Wilson (entropy-maximizing family) | Cameron & Trivedi (textbook treatment); Hilbe (negative binomial) |
| סוג≠ | Model of flows between spatial origins and destinations | Generalized linear model for count data |
| מקור מכונן≠ | Wilson, A. G. (1971). A family of spatial interaction models, and associated developments. Environment and Planning A, 3(1), 1–32. DOI ↗ | Cameron, A. C. & Trivedi, P. K. (1998). Regression Analysis of Count Data. Cambridge University Press. DOI ↗ |
| כינויים | gravity model, spatial interaction model, competing destinations model, mekânsal etkileşim modeli | count regression, log-linear count model, negative binomial regression, Poisson / Negatif Binom Regresyon |
| קשורות | 4 | 4 |
| תקציר≠ | Spatial interaction models predict the volume of flows — migrants, commuters, shoppers, trade, trips — between origins and destinations as a function of the size of each place and the distance or cost separating them. By analogy to Newton's gravity, interaction rises with the 'mass' of origin and destination and falls with separation, and Wilson's 1971 entropy-maximizing family put these models on a rigorous footing for transport, migration, and retail analysis. | Poisson regression is a generalized linear model for count outcomes — events tallied as non-negative integers such as hospital admissions, accidents, or article counts. It models the log of the expected count as a linear function of the predictors, and is developed in the standard count-data treatment of Cameron and Trivedi (1998); when the counts are over-dispersed, the closely related negative binomial model (Hilbe, 2011) is preferred. |
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