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Rossmo's formula

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Rossmo's formula is a geographic profiling formula to predict where a serial criminal lives. It relies upon the tendency of criminals to not commit crimes near places where they might be recognized, but also to not travel excessively long distances. The formula was developed and patented in 1996[1] by criminologist Kim Rossmo and integrated into a specialized crime analysis software product called Rigel.[2] The Rigel product is developed by the software company Environmental Criminology Research Inc. (ECRI), which Rossmo co-founded.[3]

Formula

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Imagine a map with an overlaying grid of little squares named sectors. If this map is a raster image file on a computer, these sectors are pixels. A sector is the square on row i and column j, located at coordinates . The following function gives the probability of the position of the serial criminal residing within a specific sector (or point) :[4]

where:

Here the summation is over past crimes located at coordinates , , where is the number of past crimes. Furthermore, is an indicator function that returns 0 when a point is an element of the buffer zone B (the neighborhood of a criminal residence that is swept out by a radius of B from its center). The indicator allows the computation to switch between the two terms. If a crime occurs within the buffer zone, then and, thus, the first term does not contribute to the overall result. This is a prerogative for defining the first term in the case when the distance between a point (or pixel) becomes equal to zero. When , the 1st term is used to calculate .

is the Manhattan distance between a point and the n-th crime site , .

Finally, is an appopriately selected normalization constant to ensure that .

Alternative Implementation

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is not well suited for image processing because of the asymptotic behavior near the coordinates of a crime site.

Alternatively, Rossmo's function may use other distance decay functions instead of .

One method would be to use a probability distribution similar to the Gaussian Distribution as a distance decay function:

If implementing on a computer, the maximum value of p() matches the maximum value of a set of colors being used to create the n by m Jeopardy Surface matrix J. The elements of the matrix J may represent the pixel values of an image.

Where:


Explanation

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The summation in the formula consists of two terms. The first term describes the idea of decreasing probability with increasing distance. The second term deals with the concept of a buffer zone. The variable is used to put more weight on one of the two ideas. The variable describes the radius of the buffer zone. The constant is empirically determined.

The main idea of the formula is that the probability of crimes first increases as one moves through the buffer zone away from the hotzone, but decreases afterwards. The variable can be chosen so that it works best on data of past crimes. The same idea goes for the variable .

The distance is calculated with the Manhattan distance formula.

Applications

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The formula has been applied to fields other than forensics.[5] Because of the buffer zone idea, the formula works well for studies concerning predatory animals such as white sharks.[6]

This formula and math behind it were used in crime detecting in the Pilot episode of the TV series Numb3rs and in the 100th episode of the same show, called "Disturbed".

References

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  1. ^ US patent 5781704, Rossmo, D. K., "Expert system method of performing crime site analysis", issued 2002-07-16 
  2. ^ "Rigel Analyst". Geographic Profiling - Crime Analysis. Environmental Criminology Research Inc. Retrieved 2019-02-12.
  3. ^ Rich, T.; Shively, M (December 2004). "A Methodology for Evaluating Geographic Profiling Software" (PDF). U.S. Department of Justice. p. 14.
  4. ^ Rossmo, Kim D. (1995). "Geographic profiling: target patterns of serial murderers" (PDF). Simon Fraser University: 225. {{cite journal}}: Cite journal requires |journal= (help)
  5. ^ Le Comber, S. C.; Stevenson (2012). "From Jack the Ripper to epidemiology and ecology". Trends in Ecology & Evolution. 27 (6): 307–308. Bibcode:2012TEcoE..27..307L. doi:10.1016/j.tree.2012.03.004. PMID 22494610.
  6. ^ Martin, R. A.; Rossmo, D. K.; Hammerschlag, N. (2009). "Hunting patterns and geographic profiling of white shark predation" (PDF). Journal of Zoology. 279 (2): 111–118. doi:10.1111/j.1469-7998.2009.00586.x. Archived from the original (PDF) on 2010-06-12.

Further reading

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