Figure 1: Paper surveys consisting of the above photograph and the
instructions: (1) “Please draw an “x” at the center of the subject of
this image” and (2) “ write down a few words to describe it
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Figure 2: Scatter plot of locations marked by human subjects normalized to photograph dimensions.
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 Figure 3: Histogram of the horizontal components of the positions chosen by human subjects plot of locations (normalized by photograph width). 
Figure 4: Histogram of the vertical components of the positions chosen by human subjects plot of locations (normalized by photograph height).
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Location "center" choices were not segmented into taxons. The mean location choice was (.56 +-.09,.58+-.11). 
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Figure 8: As explained above, k-means cluster analysis separated the data into spatial taxons. To help the reader visualize how our operational definition of spatial taxon applies to the data, the visual taxons are shown as layers. Scatter plots of the location data for each spatial taxon are overlaid on top of the spatial taxon regions. The bottom layer shows the original image overlaid with a scatter plot of all the data.
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 Figure 9: As explained above, k-means cluster analysis separated the data into spatial taxons based on location. For each survey included in the cluster, the words collected by the second survey question were counted and ranked according to the procedure first introduced by George Zipf (Zipf, George Kingsley (1932): Selected Studies of the Principle of Relative Frequency in Language. Cambridge (Mass). The trend line equations and R-squared statistic are shown in the upper right corners. Though power-law functions provide a good fit for some of the clusters, they do not provide a good fit for others. Check back here for a follow-up analysis. | |
