Abstract
In firearm identification, a firearm examiner looks at a pair of fired bullets or cartridge cases using a comparison microscope and determines from this visual analysis if they were both fired from the same firearm. In the particular case of fired bullets, the individual firearm signature takes the form of a striated pattern. Over the time, the firearm examiner’s community developed two distinct approaches for bullet identification: pattern matching and line counting. More recently, the emergence of technology enabling the capture of surface topographies down to a submicron depth resolution has been a catalyst for the field of computerized objective ballistic identification. Objectiveness is achieved through the statistical analysis of various scores of known matches and known nonmatches exhibit pair comparison, which in turn implies the capture of large quantities of bullets and cartridge cases topographies. The main goal of this study was to develop an objective identification method for bullets fired from conventionally rifled barrels, and to test this method on public and proprietary bullet 3D image datasets captured at different lateral resolutions. Two newly developed bullet identification scores, the Line Counting Score (LCS) and the Pattern Matching Score, computed on 3D topographies yielded perfect match versus nonmatch separation for three different sets used in the standard Hamby–Brundage Test. A similar analysis performed using a larger, more-realistic set, enabled us to define a discriminative line at a false match rate of 1/10[Formula: see text]000 on a 2D plot that shows both identification scores for matches and nonmatches. The LCS is shown to produce a better sensitivity than the standard consecutive matching striae criteria for the more-realistic dataset. A likelihood function was also computed from a linear combination of both scores, and a conservative approach based on extreme value theory is proposed to extrapolate this function in the score domain where nonmatch data are not available. This study also provides a better understanding of the limitations of studies that involve very few firearms.
Highlights
Firearm identication is a discipline of forensic science that involves determining ifred bullets or cartridge cases had a particularrearm as a common source, by analyzing the unique marks left on their surfaces duringring
The primary objective of this paper is to present an objective identication method suitable for bulletsred from conventionally ri°ed barrelsb based on a dataset that is larger than those used in other studies; we use standard consecutively manufactured barrel sets to train the feature extraction used in our model
A larger number of images raises the possibility of errors caused by bullet manipulation and/or image stitching when the acquisition process is manual
Summary
Firearm identication is a discipline of forensic science that involves determining ifred bullets or cartridge cases had a particularrearm as a common source, by analyzing the unique marks left on their surfaces duringring. This discipline is often referred to asrearmngerprinting because it is analogous to the identication of individualngerprints. Some random °aws or incidents during manufacturing, such as an accidental dent on a tool edge, can impart unintended marks on several consecutively manufactured parts of therearm Some manufacturing processes, such as broaching or metal injection molding, are prone to producing marks that transfer over to several tooled surfaces It is impossible for a layperson to distinguish random marks from subclass characteristics.a The ability to segregate specic marks from subclass characteristics constitutes one of the many successfully resolved challenges of forensicrearm identication
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