Showing posts with label dna fingerprints. Show all posts
Showing posts with label dna fingerprints. Show all posts

27 October 2008

More on Labour's Data Delusion

And so it goes on:


Every police force in the UK is to be equipped with mobile fingerprint scanners - handheld devices that allow police to carry out identity checks on people in the street.

The new technology, which ultimately may be able to receive pictures of suspects, is likely to be in widespread use within 18 months. Tens of thousands of sets - as compact as BlackBerry smartphones - are expected to be distributed.

The police claim the scheme, called Project Midas, will transform the speed of criminal investigations. A similar, heavier machine has been tested during limited trials with motorway patrols.

To address fears about mass surveillance and random searches, the police insist fingerprints taken by the scanners will not be stored or added to databases.

Yeah, pull the other one. The point is, given the current government's mentality that more is better, it is inevitable that these prints will be added. The irony is, this will actually make the system *less* useful.

To see why, consider what happens if there is a 1 in 100,000,000 chance of false positives using these new units. Suppose there are 1,000,000 fingerprints on the database: that means after 100 checks, there is likely to be a false match - bad enough. But now consider what happens when all these other fingerprints, obtained at random, are added, and the database increases to 10,000,000: a false positive will be obtained after every *10* checks on average. In other words, the more prints there are on the database, the worse the false positive rate becomes because of the unavoidable errors in biometrics.

This back of the envelope calculation also shows the way forward for biometric checks - of all kinds, since they are all subject to the same scaling problem. The government should aim to *reduce* the number of files it holds, but ensure that they are the ones that they are most interested in/concerned about. In other words, try to cut the database down to 100,000, say, but make sure they are *right* 100,000, not just random members of the public.

It's clear that the reason for Labour's data delusion is that it doesn't understood the technology that it is seeking to apply. In particular, it doesn't understand that the error rate sets a limit on the useful size of such databases. Super-duper databases are simply super stupid.

27 May 2007

Googling the Genome, Part III

Good to see some others concerned by the imminent arrival of personal genomics:

In addition, many scientists fear cheap genome sequencing could have other, worrying consequences. Professor Steve Jones of University College London, said: 'If you make your genome public, you are not just revealing information about yourself and what diseases you might be susceptible to, you are also giving away crucial data about the kind of illnesses your children might be prone to. Each of your children gets half your genes, after all. They might not want the world to know about the risks they face and become very unhappy in later life that you went public. Your other relatives might equally be displeased.'

And by its implications for civil liberties:

However, there are other concerns, as Professor Ashburner points out. 'Anyone who commits relatively minor offences can have their DNA taken and analysed. At present, the main use of this process is to create a DNA fingerprint that can be used to identify that individual. But soon we will be able to create an entire genome sequence of that individual from a swab or blood sample. We will end up knowing everything about their genes. In the end, we could have millions of people on a database and know every single genetic secret of each person. That has to be a very worrying prospect.'

02 February 2007

Genetic Information Nondiscrimination Act of 2007

Because of this:

(1) Deciphering the sequence of the human genome and other advances in genetics open major new opportunities for medical progress. New knowledge about the genetic basis of illness will allow for earlier detection of illnesses, often before symptoms have begun. Genetic testing can allow individuals to take steps to reduce the likelihood that they will contract a particular disorder. New knowledge about genetics may allow for the development of better therapies that are more effective against disease or have fewer side effects than current treatments. These advances give rise to the potential misuse of genetic information to discriminate in health insurance and employment.

(2) The early science of genetics became the basis of State laws that provided for the sterilization of persons having presumed genetic `defects' such as mental retardation, mental disease, epilepsy, blindness, and hearing loss, among other conditions. The first sterilization law was enacted in the State of Indiana in 1907. By 1981, a majority of States adopted sterilization laws to `correct' apparent genetic traits or tendencies. Many of these State laws have since been repealed, and many have been modified to include essential constitutional requirements of due process and equal protection. However, the current explosion in the science of genetics, and the history of sterilization laws by the States based on early genetic science, compels Congressional action in this area.

Everybody needs something like this:

legislation establishing a national and uniform basic standard is necessary to fully protect the public from discrimination and allay their concerns about the potential for discrimination, thereby allowing individuals to take advantage of genetic testing, technologies, research, and new therapies.

And beyond "simple" discrimination, there's going to be stuff like this:

Consider a not-too-distant future in which personal genomes are readily available. For those with relations affected by a serious medical condition, this will conveniently provide them with any genetic test they need. But it will also offer the rest of us information about our status for these and other, far less serious, autosomal recessive disorders that might similarly manifest themselves in children if we married a fellow carrier.

A bioinformatics program running on a PC could easily check our genomes for all genes associated with the autosomal recessive disorders that had been identified so far. Regular software updates downloaded from the internet - like those for anti-virus programs - would keep our search software abreast of the latest medical research. The question is, how potentially serious does a variant gene's effects have to be for us to care about its presence in our DNA? Down to what level should we be morally obliged to tell our prospective partners - or have the right to ask about?

And just when is the appropriate moment to swap all these delicate DNA details? Before getting married? Before going to bed together? Before even exchanging words? Will there one day be a new class of small, wireless devices that hold our personal genomic profile in order to carry out discreet mutual compatibility checks on nearby potential partners: a green light for genomic joy, a red one for excessive recessive risks?

Given the daunting complexity of the ethical issues raised by knowing the digital code of life in detail, many may opt for the simplest option: not to google it. But even if you refuse to delve within your genome, there are plenty of others who will be keen to do so. Employers and insurance companies would doubtless love to scan your data before giving you a job or issuing a policy. And if your children and grandchildren have any inconvenient or expensive medical condition that they have inherited from one side of the family, they might like to know which - not least, to ensure that they sue the right person.

Another group that is likely to be deeply interested in googling your genome are the law enforcement agencies. Currently, DNA is used to match often microscopic samples found at the scene of a crime, for example, with those taken from suspects, by comparing special, short regions of it - DNA "fingerprints". The better the match, the more likely it is that they came from the same individual. Low-cost sequencing technologies would allow DNA samples to be analysed completely - not just to give patterns for matching, but even rough indications of physical and mental characteristics - convenient for rounding up suspects. This is a rather hit-and-miss approach, though, where success depends on pulling in the right people. How much more convenient it would be if everyone's DNA were already to hand, allowing a simple text matching process to find the guilty party.

Nobody ever said digital DNA was going to be easy.

23 July 2006

The Great ID FUD

When will they ever learn?

Unlike traditional forms of identification, the VeriChip can’t be lost, stolen, misplaced, or counterfeited.

That's what the human-implantable RFID VeriChip site says. And this is what happened at the Hackers on Planet Earth (HOPE) 6 conference:

two presenters demonstrated the electronic equivalent of making a copy of an implanted RFID or radio frequency ID chip.

The point was to show just how easy it is to fool a detection device that purports to uniquely identify any individual.

So let's just do a quick recap: which technologies are available for establishing identity unambiguously these days?

Irises: nope
Faces: nope
Fingerprints: nope
DNA: nope
Implanted RFID: nope

So, tell me Mr Blair, how exactly you were going to implement this ID card system in a way that it can't be spoofed to hell?