Surgery – Diagnostic testing – Measuring anatomical characteristic or force applied to or...
Reexamination Certificate
2001-12-03
2004-01-13
Marmor, Charles (Department: 3736)
Surgery
Diagnostic testing
Measuring anatomical characteristic or force applied to or...
C600S306000
Reexamination Certificate
active
06676611
ABSTRACT:
BACKGROUND OF THE INVENTION
The present invention relates to an apparatus and to a method for noninvasively extracting physiological data from the skin of the body.
Noninvasive extraction of physiological data from the skin of the body is used either for medical purposes or for lie detection. By way of example, during a court hearing, a security check or a job interview, great importance is attached to the person to be examined; e.g., a witness or a defendant, telling the truth.
Methods for noninvasively extracting physiological data from the skin are known in which production of body perspiration is ascertained via measurement of the resistance of the skin, for example by electrodes attached to the upper body.
Lie detection is based, among other things, on the observation that deliberate lying results in a physical reaction of the skin.
It is an object of the present invention to provide a way of noninvasively extracting physiological data from the skin of the body which is easy to apply.
SUMMARY OF THE INVENTION
The apparatus of the present invention is designed such that it has at least one fingerprint sensor for ascertaining production of perspiration.
In this context, the fingerprint sensor is used to record a degree of blackening, and a change in the degree of blackening is used to measure a change in production of perspiration by the finger which has been placed on the fingerprint sensor. A change in the blackening image over time provides a blackening profile.
In this case, the degree of blackening corresponds essentially to the finger's contact area detected by the fingerprint sensor. In the event of increased perspiration production, the blackening image recorded by the fingerprint sensor also becomes darker, on average. The reason for this is, among other things, that the greater presence of body perspiration on the finger increases the pressure transferred from the finger to the fingerprint sensor, and that a larger area of the fingerprint sensor is occupied.
This method of noninvasively extracting physiological data has the advantage that it is possible to ascertain evidence relating to the production of body perspiration by simply applying a finger.
It is thus possible to dispense with any further attachment of apparatuses to the human body, for example, sleeves for measuring the pulse or adhesive strips for ascertaining the resistance of the skin. As such, it is also possible to provide a compact and portable apparatus for noninvasively extracting physiological data.
The apparatus may also have more than one fingerprint sensor; for example, two fingerprint sensors for two different fingers of a hand or on both hands. The apparatus also may be equipped with fingerprint sensors for each finger.
While the apparatus is operating, the pressure exerted on the fingerprint sensor by the finger may vary. However, any variation in the contact pressure results in a change in the blackening image due to the changing contact area. It is, therefore, desirable to separate the influence of the pressure from the influence of perspiration production on the blackening profile.
On the basis of this, it is advantageous for the lie detector to be equipped not only with the at least one fingerprint sensor but also with at least one pressure sensor which is able to measure the pressure exerted on the fingerprint sensor by the finger.
In this regard, the pressure sensor is expediently mounted on the side which is remote from the fingerprint sensor's surface provided for applying the finger. A finger, therefore, presses on the fingerprint sensor, which, in turn, presses on the pressure sensor.
This makes it possible to record the blackening profile from the fingerprint sensor and the pressure profile from the pressure sensor at the same time and to subject the degree of blackening to pressure-normalization; i.e., to ascertain it largely independently of the pressure by adjusting the blackening profile with the pressure profile.
It is also advantageous for the pressure-normalized or non-pressure-normalized blackening profile to be examined for cyclic components. The cyclic components can be used to ascertain the pulse or, when plotted against time, the pulse profile. To this end, there is advantageously an evaluation circuit for ascertaining cyclic components of the blackening profile.
This method of noninvasively extracting physiological data can be used advantageously for lie detection.
Taking into account the time of a statement, the blackening profile can be used to draw conclusions about a truth content of the statement. By way of example, one indication of a lie may be if, upon hearing a question or when responding to a question, there is significantly greater production of perspiration, in line with a local maximum in the advantageously pressure-normalized blackening profile.
Additionally using the pulse profile provides another way of ascertaining a physical reaction during lie detection. This is because hearing a question or responding to a question may also produce a higher pulse rate, for example.
The method of noninvasively extracting physiological data can also be used for detecting life. In this context, it is assumed that detection of a pulse profile refers to a finger applied to the apparatus being attached to a living person.
Detection of life can be used in identification machines based on fingerprint profiles; e.g., on cash machines or on security safeguards. Using detection of life makes it possible to establish whether the finger placed on the identification machine is still attached to a blood circulation or whether it has been removed from an authorized person in order to gain access by devious methods, for example.
This also can be used advantageously for detecting apparent death. To this end, the apparatus with pulse detection is strapped to a finger of a person regarded as dead, for example. If the apparatus detects a pulse, an alarm is triggered. For this purpose, the apparatus is preferably lightweight and portable and is equipped with a transmitter. Preferably, the radio waves emitted by the transmitter also should be able to penetrate a layer of earth, typically having a thickness of between half a meter and two meters.
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Physicochemical techniques in the development of latent fingerprints, Pounds et al.
Bell Boyd & Lloyd LLC
Marmor Charles
Siemens Aktiengesellschaft
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