Thursday, November 26, 2020

Internal fingerprint sensor peers inside fingertips for more surefire ID

Must read

‘Forensic Breakthrough’ Leads to Potential Suspect in 40-Year-Old Irish Massacre

The Kingsmill massacre, the execution of 10 unarmed men, is one of the most infamous attacks from the violent era of the ‘Troubles’ in...

Forensic Comparison Software Workflow Touch Screen

This video showcases the workflow from capture of the fingerprint at a crime scene, enhancement, matching on case AFIS , and finally...

Hands Off! NIST Helps Bring Contactless Fingerprint Technology to Market

Quickly moving through security checkpoints by showing your hand to a scanner seems straight out of science fiction, but the National Institute of Standards...

Double rapist forced victim to scrub bloodstains off her body to remove forensic evidence

A rapist who forced a victim to scrub bloodstains from her body in a bid to get rid of forensic evidence has been jailed. Andrew Peters,...
Michael Whyte
Crime Scene Officer and Fingerprint Expert with over 12 years experience in Crime Scene Investigation and Latent Print Analysis. The opinions or assertions contained on this site are the private views of the author and are not to be construed as those of any professional organisation or policing body.
- Forensic Podcast -

In the 1971 film Diamonds are Forever, British secret agent James Bond uses fake fingerprints as part of a ploy to assume the identity of a diamond smuggler. At the time, sham prints were purely a futuristic bit of Bond gadgetry, but technology has since caught up.

In 2002, the Japanese cryptographer Tsutomu Matsumoto showed that imitation fingerprints made cheaply from gelatin, a main component of gummy sweets, could trick up to 80 percent of standard fingerprint sensors. The sensors also sometimes fail to recognize legitimate prints when the finger being scanned is dirty, worn, scarred, or too wet or dry.

Now scientists from The Langevin Institute, Paris, France, have constructed a new fingerprint imaging system that peers inside the finger to take a picture — a more reliable and secure way of identifying individuals. Importantly, the device is also simpler, faster, and cheaper than other technology used previously to image inside fingers. The researchers report their results in the journal Biomedical Optics Express, from The Optical Society (OSA).

“In the past years, the use of fingerprint sensors has expanded greatly beyond the field of forensics. Far from just being used for border security or passport registration, current uses of these sensors allows access to mobile phones, computers and even gym facilities,” said Egidijus Auksorius, postdoctoral researcher, The Langevin Institute.

Despite the widespread use of commercial fingerprint sensors, problems with the devices persist, Auksorius said, including up to 5 percent of the population having difficulties using the sensors because their fingerprints are flattened from old age or damaged by routine manual work or sports such as rock climbing. Additionally, people attempting to escape identification might deliberately thwart the sensors by rubbing out their fingerprints, and the systems can be tricked by fake prints, as was demonstrated by Matsumoto and others.

Fingerprint sensor is based on full field optical coherence tomography (FF-OCT) and inexpensive fast camera. Credit: Egidijus Auksorius/Institut Langevin

To combat these problems Auksorius worked with Claude Boccara, a professor who specializes in scientific instruments at The Langevin Institute, to develop a new “internal fingerprint” sensor.

Most optical fingerprint sensors today produce images by reflecting light from areas where the skin does not come in contact with a glass plate, a technique that captures details from only the very top layer of skin. In contrast, Auksorius and Boccara’s device images the “internal fingerprints,” which have the same pattern as external fingerprints, but are about half a millimeter below the skin’s surface.

“In fact, the internal fingerprints serve as a ‘master template’ from which the surface regrows when it is damaged,” Auksorius said.

The new sensor uses a special variant of an imaging technology called optical coherence tomography (OCT). OCT is already used for medical imaging and works by analyzing an interference pattern created when a beam of light that travels through a biological sample, like a finger, is recombined with a reference beam of light.

Standard OCT systems gather 3D data and often require sophisticated lasers systems and light detectors, which can get expensive. Auksorius and Boccara simplified their system by using a modified version of OCT called full-field OCT, or FF-OCT, which was invented by their laboratory and developed in the early 2000s.

The main advantage of the FF-OCT system is that it can take a 2D image of the fingerprint directly, saving time and making the data processing simpler and cheaper. Because not everyone’s internal fingerprints are located at the same depth, the researchers also developed a method to first take an image of the fingertip at an angle. The first image was used to determine the depth of the internal fingerprint, and then a second image of the fingerprint itself was taken. The system can also image sweat pores, which provide an additional means of identification.

These images were acquired with the fingerprint sensor based on full field optical coherence tomography (FF-OCT).

Currently the system is about shoebox size and Auksorius is working to further shrink it. The biggest and most expensive element in the system — a specialized infrared camera — cost about $40,000, but the team recently acquired comparable images using a camera less than one fifth the cost. Auksorius estimates that a complete device using the new camera could be constructed for less than $10,000. While the price is still significantly higher than standard fingerprint sensors, Auksorius predicts that the new device could find a market dedicated to imaging problematic fingerprints or in areas where security is a particular concern.

“We showed that the internal fingerprints could be imaged with a relatively simple and inexpensive system,” Auksorius said. “Furthermore, recent results with the new camera show that the system can potentially be a commercially viable solution.”

The team has plans to soon test the device in Turkey, where 100 people will have their fingerprints scanned. They are also working to further improve the imaging speed and depth capabilities of the system.

Paper: E. Auksorius and A. Boccara “Fingerprint imaging from the inside of a finger with full-field optical coherence tomography” Biomedical Optics Express 6, 4465-4471 (2015).

Source: The Optical Society

- Advertisement -

More articles

- Advertisement -

Latest article

Trees and shrubs might reveal the location of decomposing bodies

Plants could help investigators find dead bodies. Botanists believe the sudden flush of nutrients into the soil from decomposition may affect nearby foliage. If...

Are Detectives discounting the associative value of fingerprints that fall short of an identification in their investigations?

Every day, Fingerprint Experts in every latent office across the globe examine fingermarks that they determine to fall short of an identification....

Using the NCIC Bayesian Network to improve your AFIS searches

This National Crime Information Centre (NCIC) Bayesian network is based on the statistical data of general patterns of fingerprints on the hands...

DNA decontamination of fingerprint brushes

Using fingerprint brushes across multiple crime scenes yields a high risk of DNA cross-contamination. Thankfully an Australian study has discovered a quick and easy way to safely decontaminate fingerprint brushes to prevent this contamination risk and allows the brushes to be safely reused even after multiple cleaning cycles.

Detection of latent fingerprint hidden beneath adhesive tape by optical coherence tomography

Adhesive tape is a common item which can be encountered in criminal cases involving rape, murder, kidnapping and explosives. It is often the case...