Sir Francis Galton, the British man of science and mathematician who introduced the first fingerprint recognition methodology in 1892, may have never imagined that, more than a century in the future, police investigators would utilize his watershed invention to help them – along with sophisticated imaging and computer analysis – apprehend suspects. Galton, who had expertise in a wide array of things, was fascinated by the singularity of fingerprints, and calculated the chance of two people having the same fingerprint to be at least 1 in 64 million, based on his findings and calculations using a fairly small sampling. Galton studied the possibilities for the minutiae, that is, the simple patterns of a fingerprint’s tiny ridge lines where they split, end, commingle, etc. These minutiae are also called ridge characteristics, points of similarity, and now – suitably enough – “Galton details.”
Finding, identifying, and plotting the placement of the fingerprint minutiae enabled Galton and other early fingerprint experts to accurately orient and compare two similar fingerprints to ascertain if they, indeed, matched. Plotting and refining the analysis of the minutiae over decades would become central to the success of computerized automated fingerprint identification systems (AFIS) that would come forth by the late 1900s.
Technological inventions in computing have made it possible to shift fingerprint recognition from its post-arrest role in the courtrooms to the police department precincts as an effective crime-solving method. Policemen today can identify a suspect to target for investigation if he were fingerprinted in the course of the arrest processing or fingerprinted for certain types of security clearances for jobs, etc., known as civilian fingerprinting.
In the United States, the FBI maintains the largest biometric database in the world with fingerprint files and criminal history files that can be accessed and searched all day, any day, by law enforcement agencies. According to the FBI, by 2010 there were records of more than 55 million people on file. Electronic scanning advancements have shortened the time it takes for a subject’s rolled and flat print images to be uploaded into the database, from several weeks to two hours for criminal records and 24 hours for civilian records.
Fans of TV crime series know what it means to be “in the system,” because the effect of a match to a latent print found at a crime scene is the impending interrogation of the identified suspect. Ironically, the captivation with forensic science in books, movies, and television has produced a queer phenomenon in the real-world justice system, termed by some as “the CSI effect.” Jury members who watch fictional crime-solving may attribute more credibility and trustworthiness to the professionals who appear in a real criminal trial than may be warranted.
The general public watching these types of television series may see a fingerprint image on a computer screen in a show and may think that the computer does the analysis and that the resulting ID would be all that would need to be admitted as evidence. That might be feasible if suspects left full, perfect prints at the scene, because the software operates with a high grade of accuracy. The reality, however, is this: latent prints are created by oils and residues on the fingertips or contact surfaces, they may only be a partial image, and they may be of poor quality due to smudging. In fact, fingerprint identification relies on an examiner to make an eyeball comparison and confirm or dispute any preliminary match identified by the database search software.
Despite the sophisticated engineering that has helped invent and advance biometric ID systems, fingerprint recognition has developed some tarnish on its reputation. In 2004, shortly after a series of passenger train bombings in Spain, the FBI held Brandon Mayfield, a Portland, Oregon, lawyer, for two weeks after false fingerprint recognition linked him to these overseas acts of terrorism. It brightened the scrutiny on the factor of human fallibility in this field of forensic science. Academicians are distressed to identify that practicing fingerprint examiners may not conduct their analyses objectively, and seem to be influenced by the context in which the prints are evaluated to a certain extent.
In one experiment, the subjects had, in the past, analyzed some latent fingerprints, and were then presented with the same prints again. The second time, however, the prints were accompanied by photos of graphic violence. Surprisingly, two-thirds of the examiners drew a conclusion about the match that was different from their first findings. The investigator, a British neuroscientist named Itiel Dror, concluded that people are vulnerable to cognitive and psychological markers that clearly influenced the outcome.
Despite some evidence of human error in examining latent prints of irregular quality, the good news is that the automated fingerprint recognition technology that uses direct scanning for security ID functions is experiencing great success. Mainstream applications of it are used to secure the contents of valuable portable consumer electronics products such as laptops and wireless phones. If these devices are ripped off, the perpetrators will not be able to access their hard drives.
The pattern-matching programs that analyze the minutiae of fingertip ridges for criminal investigations have paved the way for automated biometric ID software and systems that are even more sophisticated and more capable of protecting us and our property, such as hand geometry, iris scanning, and facial recognition.
This story was provided by InventHelp. For updates on the newest inventions and technologies, visit news.inventhelp.com.