Physical Mapping Calculators  Random Fingerprinting
These calculators could help you to predict the progress of physical mapping projects based on fingerprinting a large number of library clones, chosen randomly (eg by restriction analysis or "shotgun" sequencing). You can calculate expected values of several measures of the experimental progress.
Two calculators are shown: one at the top is based on the (classic by now) paper by Lander and Waterman (1988), while that below  on a more recent publication of Roach (1995) and his personal communication. Their results are very similar for low library redundacy but start to differ at redundancies of three and higher, where the model of Jared Roach gives more consistent estimates (eg, for the contig length).
Another difference is in calculation of the expected number of gaps. Roach (1995) calculated the total number of all the gaps in the final map (which is the number of contigs plus one for a linear target), while Lander and Waterman (1988) provided results for "real" gaps (as opposed to undetected overlaps). You may need to enlarge your browser window or open a new window to see both calculators simulataneously.
Lander and Waterman

Roach

What are these measures?
A contig is a group of one or more clones overlapping by at least minimum overlap parameter above (given as a percentage of a clone length), so this fact is detected by sufficient similarity of their fingerprints. A contig formed by only clone is called a singleton. A gap is a segment of the genome with no contigs on it.
These predictions are based on the following assumptions:
 All library clones are selected randomly from the genome
 Minimum overlap between two clones is always detected
 All inserts are of the same size
Such experimental factors as chimerism, repeats and false positive/negative results are ignored, so expect your project to progress slower than the ideal model :(
References
The predictions are based on the mathematical results published in
Lander, E. and Waterman, M. S. (1988) Genomic mapping by fingerprinting random clones: a mathematical analysis. Genomics 2, 231239.
Roach, J. C. (1995) Random Subcloning. Genome Research. 5, 464473.
See also his web page on the subject.
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Copyright 1996 Andrei Grigoriev
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