There is a firm that has employed the help of geographers which requires the evaluation of the geography and distribution of tornadoes throughout Kansas and Oklahoma. The states would like to mandate a building of tornado shelters in areas where there have been a large number of tornadoes. However, there is an argument from some that they are unnecessary because of cost and likely lack of use in some areas. The goal is to locate areas that would be of high tornado probability and access whether shelters would be necessary. In addition, there will need to be a basis in which it is more appropriate to require the building of tornado shelters. This would include calculating statistics using the given files including tornado locations and their width and paying special attention to the patterns over time.
Methods:
There are four main tools used in analyzing the spatial data of tornadoes in Oklahoma and Kansas. The first is the mean center. This is the average of the x and y coordinates, which then creates a hypothetical point that displays the average place in which a tornado would occur. The second is a weighted mean center which takes into consideration the frequencies of the grouped data, in this case the width of tornadoes. Having this point allows one to see if there is a difference in mean centers and weighted mean centers. In some cases, the weighted mean could be more important than the mean center, but it is important to know both to have a better understanding of the spatial data presented.
Another tool is the use of standard distance. This is basically a spatial version of standard deviation. In ArcMap, one can choose how many standard deviations they want to display. In the case of this lab, only one standard deviation circled is shown. The closer a point is to the middle of this circle, the closer it is to the mean. An important note is that unlike regular standard deviation, standard distance cannot be negative.There is also a weighted standard distance that acts in a similar way to that of a weighted mean center. A map cannot have a weighted standard distance if it does not have a weighted mean center.
Results:
Map 1.a displays the mean and weighted center of tornadoes in Kansas and Oklahoma from 1995 to 2006. A mean center is displayed in pink, which shows where the average x and y coordinates are for the given data. There is also a weighted mean center that is based on the width of the tornado. This map shows that the larger tornadoes are located slightly farther south and west on the map. It is visible to the naked eye to see that there appear to be larger tornadoes in the southern region (depicted by the yellow graduated circles- the bigger circles being the larger tornadoes).
Map 1a. Depicts the mean and weighted center of Tornadoes in Kansas and Oklahoma from 1995 and 2006 |
Map
2 shows the mean and weighted center for tornadoes in Kansas and Oklahoma from
2007 to 2012. This map reaffirms that the larger tornadoes seem to be south of
the mean center because the weighted width mean center is below the mean
center. Further, there are more tornadoes occurring in Kansas than Oklahoma,
but at a smaller scale and likely severity of damages and lives lost.
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Map 3. Mean and Weighted Center of Tornadoes in Kansas and Oklahoma from 1995 to 2012 |
Map 4 displays the standard and weighted distance for tornadoes in Kansas and Oklahoma from 1995 to 2006. Much like the above maps, the weighted width standard distance is separating the two distance circles from one another. This contributes to earlier findings of the weighted standard distance pulling farther south than the standard distance.
Map 4. Standard and Weighted Distance for Tornadoes in Kansas and Oklahoma from 1995 to 2006. |
Map 5. Standard and Weighted Distance for Tornadoes in Kansas and Oklahoma from 2007 to 2012. |
Map 6. Weighted Standard Distance and Mean for Tornadoes in Kansas and Oklahoma from 1995 to 2012. |
Map 7. Standard Deviation of Tornadoes (by count) in Kansas and Oklahoma from 2007 to 2012. |
The task was given to find what the sample number would have to be to exceed the number of tornadoes 70% of the time. To do this, 70% was found on the z-score chart which turned out to be .52. Because this is exceeded more often than not (which would show up on the negative side of a standard deviation graph), the .52 was changed to -.52 to account for that. After calculations, 1.76 tornadoes would have to occur in a county to exceed tornadoes 70% of the time. Another task was given to find what the sample number would have to be to exceed the number of tornadoes 20% of the time. The chances of a county having 80% of the most tornadoes is quite slim, so the z-score deviation would need to be very high. In this case, 80% was found on the z-score table at .84 and after calculations, it was determined that one would need 7.6 tornadoes to occur in a county for this to be true.
Conclusion:
Overall, all of the methods used above are related to one another in some way. Generally, the weighted mean centers are being pulled south, whereas the weighted standard distances and weighted mean centers are moving toward the northeast over time.
This study has large implications on not only the budget of the states, but survival rates of their citizens. It makes sense that the general population would find these shelters to be obsolete, but if the statistics say otherwise, then the likelihood of the shelter being used and saving lives is greatly increased. The tough position as a statistical researcher is determining where the cut off point is for a community to either have a tornado shelter or not. At the state level you obviously do not want to make the mistake of looking over important details and putting certain people at risk because of it.
The strength of each tornado and its damage play a big role in determining where a tornado shelter would be most suitable. Most would assume that the wider tornadoes would cause more destruction and loss of lives, but it would be interesting to see how that data would fit into the distribution of tornadoes above. Other information that would be useful to see the tornado trends over time would be weather related, which would include temperature, heat index, and dew point. This would be able to determine if there is more of correlation with the shift of tornado widths.
If I could redo one part of this lab, it would be changing the tornado width data for 1995-2006 so that there would be no tornadoes with the width of 0. Although it did not appear to effect my maps too much, I would have still liked to make it as accurate as possible. Unlike the last lab, for this we did not look at any raw data in Excel beforehand, so I wrongly assumed that it would be just fine to use the data. That shows that I need to take more time to analyze the raw data I have before I analyze their spatial meaning.
As a recommendation, I would encourage Oklahoma and Kansas to place tornado shelters in the regions with dark blue (see map 7), or the counties with standard deviations 1.5 above the mean. In the aspect of time, I would likely put more tornado shelters to the north and east of the weighted standard distance because there seems to be stronger tornadoes in that region. When looking at the data, there is no place in which I would say that a tornado shelter is not necessary. That being said, there are areas in which there seems to be higher numbers of tornadoes occurring, and those, given that there is room in the budget, should have shelters as well.