|Número de publicación||USRE29008 E|
|Tipo de publicación||Concesión|
|Número de solicitud||US 05/601,595|
|Fecha de publicación||19 Oct 1976|
|Fecha de presentación||4 Ago 1975|
|Fecha de prioridad||26 Ene 1973|
|Número de publicación||05601595, 601595, US RE29008 E, US RE29008E, US-E-RE29008, USRE29008 E, USRE29008E|
|Inventores||James H. Ott|
|Cesionario original||Novar Electronics Corporation|
|Exportar cita||BiBTeX, EndNote, RefMan|
|Citas de patentes (10), Citada por (44), Clasificaciones (10)|
|Enlaces externos: USPTO, Cesión de USPTO, Espacenet|
This invention relates to machine identification of persons and more particularly relates to a method and apparatus for computer measurement and analysis of the frequency characteristics of a portion of a person's body for automatically identifying that person.
The computer industry is presently engaged in developing systems for rapid, accurate and automatic computer identification of persons.
A typical use for such a system would be to automatically identify persons seeking admittance to a secure area in a plant or to sensitive data stored in a computer memory. For example, a person seeking sensitive data or admittance to a secure area would be interrogated by a computer to determine if he is a person authorized to have access to such area or data.
Similarly, machine identification would be used in credit transactions, such as is currently being planned for future use. In such a transaction, a person would not only present his credit card to a clerk, but in addition, would be subjected to machine identification for a determination that he is the person who owns the card being presented. Such a system can reduce the damage from credit card losses and theft.
Attempts to design a computer identification system have, to date, been directed toward voice print identification and toward finger print identification techniques. Signature identification has also been proposed. To date, however, none of these methods has become practically feasible.
I have discovered a method and apparatus for individual identification involving the application of sonic energy to a person's body and the subsequent detection of the frequency response of that part of the person's body. Persons can then be distinguished through the unique frequency response that an arm, for example, exhibits.
Others have applied sonic energy to a person's body. For example, sonic energy is applied to provide a "picture" of the internal condition of the body for medical purposes. Such systems apply sonic energy in a radar type system or in a holographic system. Although these systems apply sonic energy to the human body, this is their only similarity to the present invention. The prior art methods and apparatus for obtaining and for processing the received energy differs greatly from that used in the present invention. In the system of the present invention, a comparison is made of transfer characteristics. In these prior art systems, radar or sonar principles are used to obtain "pictures."
The automatic identification capabilities provided by frequency response identification will have unimaginable impact on many industries. For example, a computer will now be able to identify the person operating it so that only proper data will be accessible to this person. Compact locking devices may be programmed to admit only certain individuals. A computer can interrogate and identify a person over the telephone. For example, the identity of a salesman wanting computer data from a distant city in a motel through an acoustical coupler can be quickly and accurately verified. Credit cards and checks may contain a coding which would permit a quick identity verification at point of purchase with a simple machine. Automobiles can be programmed to operate for only specific individuals. Homes, apartments, or any secured property can be made accessible only to owners. Legal signatures can be obtained by telephone by permitting the frequency response identification to function as a legal signature.
Frequency response identification may also be adopted for use in the medical field. For example, a new means may be at hand which will provide a quick and simple check for bone aging, deterioration, disease, and the like. It is believed that various characteristics of the bones transfer function may be altered by bone condition, muscular tension, presence of fat, and other variable health conditions. It may even be possible to determine the emotional state or tension of the person whose identity has been established. This can be important where a person who is authorized to remove information from the computer might be nervous because he is intending to do this for illegitimate reasons or is under duress.
The invention is an apparatus and a method for identifying individual persons. The apparatus comprises a means for applying sinusoidal-wave energy to the body of a person. Received wave energy is electronically processed by suitable means for detecting the frequency response characteristics of the intermediate body portion. Data storing means are also connected to the detecting means for storing data representing an initial measurement of the frequency response for use in comparing a subsequently detected frequency response.
The method is performed by applying sinusoidal-wave energy to the body and using the applied energy to detect the frequency response characteristics of at least a portion of the body. Data representing said characteristics is stored and then subsequently sinusoidal-wave energy is applied to a person being identified. The frequency response characteristics of the subsequent person is detected and compared with the characteristics of the first person to determine if the identical person is represented.
Accordingly, it is an object of the invention to provide an identification method and apparatus suitable for automatic machine use.
Further objects and features of the invention will be apparent from the following specification and claims when considered in connection with the accompanying drawings illustrating several embodiments of the invention.
FIG. 1 is a block diagram illustrating the preferred embodiment of the invention.
FIG. 2 is a graph representing a hypothetical transfer function of an individual.
In describing the invention as illustrated in the drawings, specific terminology will be resorted to for the sake of clarity. However, it is not intended to be limited to the specific terms so selected and it is to be understood that each specific term includes all technical equivalents which operate in a similar manner to accomplish a similar purpose. For example, use of the word "connection" includes not only direct connection, but also connection through an intermediate circuit where such a connection is equivalent as known by those skilled in the art.
Referring to FIG. 1, a frequency generator 10 is used to generate the sonic frequency signal to be applied to the body of a person. Although various portions of the frequency spectrum may be useful, I believe that the sonic portion of the spectrum is most useful in the preferred embodiment of the invention. The preferred frequency generator 10 is a sweep frequency generator which periodically varys its output frequency from one end of a selected frequency range to the other end of the selected range. For example, Hz frequency generator might repeatedly sweep from 100 Hz, to 10 KHz over a suitable period. It might, for example, comprise an oscillator having a capacitance diode driven by a sawtooth signal in a conventional sweep frequency generator circuit.
Alternatively, of course, the generator 10 could be a generator providing discrete selectable frequencies spaced across a desired frequency range. The generator can then be sequentially switched from discrete frequency to discrete frequency in a periodic manner.
As another alternative, the frequency generator 10 can instead be a generator which has several output frequencies simultaneously generated at its output. Suitable filtering means can be provided in the detecting circuits to distinguish the transfer function at various frequencies.
In any case, the output of the frequency generator 10 is applied to a suitable transducer which preferably is in mechanical contact with the body of a person. For example, as illustrated, the output contact 14 of the transducer 12 contacts the ulna bone of a person 16 at his elbow 18. A transducer 12 of conventional design may be used and might be of the piezoelectric type, electromagnetic type, and so forth. For example, I have used a transducer of the radio-speaker type and positioned my elbow in contact with its paper cone.
Thus, the transducer 12 and the frequency generator 10 together provide a means for applying sinusoidal wave-energy to the body of a person. This wave energy is preferably sonic energy. Another electromechanical receiving transducer 20 is positioned with its contact portion 22 against another part of the person's body. As shown, in the preferred embodiment, the contact portion 22 of the transducer 20 is positioned in contact with the ulna bone at the opposite end of the forearm near the wrist 24. Thus, energy applied at the elbow 18 is transmitted through the forearm, primarily through the ulna bone and is received at the wrist 24 by the transducer 20.
The transducer 20, like the transducer 12 may be any of the well known electromechanical transducers which convert mechanical vibratory energy to an electronic signal. For example, I used a sensitive microphone positioned in contact with the ulna bone.
Amplitude and phase detectors 26 are connected to receive the output of the transducer 20. This detector 26 senses both the amplitude of the transmitted wave energy and also its phase relative to the input wave energy of the transducer 12.
The circuitry of the amplitude and phase detectors is not shown because they may be any of the well known variety of circuits used for detecting the amplitude and phase of wave energy. For example, amplitude is often detected by the conventional diode and capacitor circuit used in a diode detector of an amplitude modulated radio receiver. Similarly, phase detectors are likewise well known and may easily be adapted for use in the present invention by a person skilled in the art.
The detected amplitude and phase from the detector 26 is then applied to a correlator means 30. The correlator means 30 preferably functions to process the incoming signal to provide an output representing a transfer function of the portion of the body through which the wave energy was transmitted. The transfer function is the algebraic-trigono-metric statement of the output divided by the input. In the preferred embodiment, the function of the correlator means 30 is to compute the transfer function of the forearm 16.
For example, if the wave energy applied by the transducer 12 is maintained at a constant amplitude and phase, the correlator means might comprise a pair of x-y plotters. The x input of each would be a time varying voltage proportional to the frequency of the frequency generator 10. For example, the sawtooth driving the sweep frequency generator 10 could be applied to the x drivers of both x-y plotters. The y input for one plotter would be the detected amplitude output of the amplitude and phase detector 26. The y input of the other plotter would be the detected phase output of the amplitude and phase detector 26. In this manner, visual, graphical readouts of the transfer function would be automatically provided by the correlator means.
Alternatively, the correlator means can periodically sample the output amplitude and phase and record it digitally as a function of the frequency. It should also be noted that it may be desirable to have the correlator means determine only the phase or only the amplitude part of the transfer function. A typical output from the correlator means 30 is illustrated in FIG. 2 as a bode plot.
If the amplitude or phase of the input frequency is varied, or if improved accuracy is desired, the output signal may be applied from the sweep frequency generator 10 to the correlator means 30 for comparison by the correlator means 30 with the output from the amplitude and phase detector 26. The transfer function would be continuously computed by the correlator means by comparing the output signal to the input signal at all times.
In an alternative embodiment where the transfer function is not computed, the portion of a person's body can be considered as a terminating load rather than as a transmitting medium. In such a system, both transducers would be positioned at the identical point of in the alternative, a single transducer would be utilized and the amplitude and phase detector 26 would be solely an amplitude detector and would be connected to the input of the single transducer. The frequency response would then be detected in a manner analogous to the detection of the frequency response of a tuned circuit. As the sweeping generator sweeps through the frequency range, the forearm, for example, of the individual would exhibit peaks of relative resonance. These peaks can be used to detect the individual characteristics of a person.
Returning however, to the preferred embodiment of FIG. 1, the output of the correlator means 30 may be applied to an analog to digital converter 32 and then stored in a suitable storage means 34. The storage means 34 can be any of the multitude of storage systems currently available for data processing. For example, the data representing the transfer function of a person being initially detected would be stored in the storage means 34 and identified as being that of a person who is permitted access to sensitive computer data. At a subsequent time when the person seeks access to the data, the output of the analog/digital converter 32 would be applied to a comparator analysis circuit 36. The comparator analysis circuit 36 simultaneously receives from the storage means 34, the transfer function of the individual stored therein. The stored information can be withdrawn from the memory by a person's name or the computer can scan all stored transfer functions. The subsequently measured transfer function and the previously stored transfer function are compared by the comparator circuit to determine if they represent the same person.
Of course, the comparator analysis circuit 36 could include a pair of x-y plotters on which the subsequently measured transfer function is printed together with the previously stored transfer function for visual analysis and comparison by a person.
Preferably however, the circuit compares the two automatically and may be programmed to reject the person as not being of the proper identity if the transfer function is not within preselected tolerances. The comparator analysis circuit 36 electronically compares the magnitude of the amplitude deviations and the magnitude of the phase deviations of the subsequently measured transfer function from the transfer function stored in the storage means 34. Such comparisons may occur throughout the entire frequency range for which the transfer function was measured or can be accomplished at selected discrete frequencies. The comparator circuit may, for example, include a pair of differential amplifiers, one for detecting the difference in phase and the other for detecting the difference in amplitude between the stored transfer function and the subsequently detected transfer function.
In operating the circuitry illustrated in FIG. 1, a person's arm is positioned to extend from the transducer 12 to the transducer 20. The circuit is activated and energy generated by the sweep frequency generator 10 is applied to the arm by the transducer 12 and transferred along the forearm 16 to the transducer 20. The transducer 20 converts the mechanical signal to an electronic signal and the amplitude and phase of the received signal are detected by the amplitude and phase detector 26. Thus, the preferred output of the amplitude and phase detector 26 is a pair of electronic signals, the amplitude of which are representative of the amplitude and of the phase of the output signal at the transducer 20.
The detected amplitude and phase signals are applied to a correlator means 30 which in effect correlates the output amplitude and phase as a function of frequency. Thus, the output of the correlator means 30 is representative of the transfer function of the forearm 16. This may be converted to digital data if desired by analog/digital converter 32 and when appropriate, such as when making initial measurements, is then stored in a suitable storage means 34. The transfer function data may, however, always be stored in a storage means for later identifying persons who sought access to data even when such persons are subsequently rejected.
Data from the storage means 34 which is representative of previously measured transfer functions and subsequently measured data directly from the analog/digital converter 32 are applied to the comparator analysis circuit 36 where the two transfer functions are compared to determine whether the same person is present at the transducers 12 and 20. Further computing and decision making computation circuitry may be connected to the output 40 of the comparator analysis circuit 36. Such circuitry would be programmed with the criteria for accepting or rejecting a person and for suitable means for responding to or signalling an acceptance or rejection.
It may be found that a person's unique transfer function may have a unique shape but may also shift upwardly or downwardly in the frequency spectrum as a result of aging or other factors. Thus, computing circuitry may be added to shift one of the computed transfer functions being compared, up or down to seek a point of minimum deviation. Then comparison is made to accept or reject a person's identity.
It is to be understood that while the detailed drawings and specific examples given describe the preferred embodiments of the invention, they are for the purposes of illustration only, that the apparatus of the invention as well as the method is not limited to the precise details and conditions disclosed and that various changes may be made therein without departing from the spirit of the invention which is defined by the following claims.
|Patente citada||Fecha de presentación||Fecha de publicación||Solicitante||Título|
|US2184511 *||28 Oct 1937||26 Dic 1939||Abraham Barnett||Method and apparatus for measuring impedance|
|US3085566 *||18 Sep 1959||16 Abr 1963||Cutler Hammer Inc||Apparatus for measuring the electrical response of living tissue|
|US3177347 *||25 Feb 1959||6 Abr 1965||Shell Oil Co||Method and apparatus for determining the dynamic response of a system|
|US3334622 *||15 Dic 1964||8 Ago 1967||Branson Instr||Method and apparatus for electroacoustic exploration|
|US3340867 *||19 Ago 1964||12 Sep 1967||Univ Minnesota||Impedance plethysmograph|
|US3506813 *||13 Jun 1966||14 Abr 1970||Hewlett Packard Co||Signal-to-noise ratio enhancement methods and means|
|US3622784 *||29 Oct 1969||23 Nov 1971||Louis R M Del Guercio||Sensor-analyzer system with means for selecting output signals corresponding to accurately positioned sensors|
|US3639905 *||27 Nov 1970||1 Feb 1972||Omron Tateisi Electronics Co||Credit card system having means for sensing if object is living|
|US3653373 *||19 Ene 1970||4 Abr 1972||Steven C Batterman||Apparatus for acoustically determining periodontal health|
|US3677831 *||14 May 1970||18 Jul 1972||Lodding Engineering Corp||Stress relief in solid materials|
|Patente citante||Fecha de presentación||Fecha de publicación||Solicitante||Título|
|US4986281 *||12 Ene 1990||22 Ene 1991||Starkey Laboratories, Inc.||Method for obtaining a signal for analyzing human and animal joint functions|
|US4996161 *||16 Oct 1987||26 Feb 1991||Guardian Technologies, Inc.||Breath alcohol testing system|
|US5787187 *||1 Abr 1996||28 Jul 1998||Sandia Corporation||Systems and methods for biometric identification using the acoustic properties of the ear canal|
|US6560352||11 Abr 2001||6 May 2003||Lumidigm, Inc.||Apparatus and method of biometric identification or verification of individuals using optical spectroscopy|
|US6628809 *||8 Oct 1999||30 Sep 2003||Lumidigm, Inc.||Apparatus and method for identification of individuals by near-infrared spectrum|
|US6816605||3 Abr 2003||9 Nov 2004||Lumidigm, Inc.||Methods and systems for biometric identification of individuals using linear optical spectroscopy|
|US7147153||5 Abr 2004||12 Dic 2006||Lumidigm, Inc.||Multispectral biometric sensor|
|US7203345||12 Sep 2003||10 Abr 2007||Lumidigm, Inc.||Apparatus and method for identification of individuals by near-infrared spectrum|
|US7347365||17 Dic 2004||25 Mar 2008||Lumidigm, Inc.||Combined total-internal-reflectance and tissue imaging systems and methods|
|US7386152||8 Jul 2005||10 Jun 2008||Lumidigm, Inc.||Noninvasive alcohol sensor|
|US7394919||25 Abr 2005||1 Jul 2008||Lumidigm, Inc.||Multispectral biometric imaging|
|US7440597||8 Jul 2005||21 Oct 2008||Rowe Robert K||Liveness sensor|
|US7460696||25 Abr 2005||2 Dic 2008||Lumidigm, Inc.||Multispectral imaging biometrics|
|US7508965||28 Nov 2006||24 Mar 2009||Lumidigm, Inc.||System and method for robust fingerprint acquisition|
|US7539330||25 Abr 2005||26 May 2009||Lumidigm, Inc.||Multispectral liveness determination|
|US7545963||19 Jul 2006||9 Jun 2009||Lumidigm, Inc.||Texture-biometrics sensor|
|US7613504||30 Sep 2002||3 Nov 2009||Lumidigm, Inc.||Spectroscopic cross-channel method and apparatus for improved optical measurements of tissue|
|US7620212||12 Ago 2003||17 Nov 2009||Lumidigm, Inc.||Electro-optical sensor|
|US7627151||23 Nov 2005||1 Dic 2009||Lumidigm, Inc.||Systems and methods for improved biometric feature definition|
|US7668350||1 Sep 2005||23 Feb 2010||Lumidigm, Inc.||Comparative texture analysis of tissue for biometric spoof detection|
|US7735729||17 May 2006||15 Jun 2010||Lumidigm, Inc.||Biometric sensor|
|US7751594||19 Jul 2006||6 Jul 2010||Lumidigm, Inc.||White-light spectral biometric sensors|
|US7801338||24 Abr 2006||21 Sep 2010||Lumidigm, Inc.||Multispectral biometric sensors|
|US7801339||31 Jul 2006||21 Sep 2010||Lumidigm, Inc.||Biometrics with spatiospectral spoof detection|
|US7804984||31 Jul 2006||28 Sep 2010||Lumidigm, Inc.||Spatial-spectral fingerprint spoof detection|
|US7819311||18 May 2006||26 Oct 2010||Lumidigm, Inc.||Multispectral biometric sensor|
|US7831072||3 Oct 2008||9 Nov 2010||Lumidigm, Inc.||Multispectral imaging biometrics|
|US7835554||29 Oct 2008||16 Nov 2010||Lumidigm, Inc.||Multispectral imaging biometrics|
|US7890158||5 Jun 2001||15 Feb 2011||Lumidigm, Inc.||Apparatus and method of biometric determination using specialized optical spectroscopy systems|
|US7899217||19 Jul 2007||1 Mar 2011||Lumidign, Inc.||Multibiometric multispectral imager|
|US7995808||10 Jun 2008||9 Ago 2011||Lumidigm, Inc.||Contactless multispectral biometric capture|
|US8165357||10 Sep 2009||24 Abr 2012||Lumidigm, Inc.||Two camera biometric imaging|
|US8175346||10 Jun 2008||8 May 2012||Lumidigm, Inc.||Whole-hand multispectral biometric imaging|
|US8184873||14 Jun 2010||22 May 2012||Lumidigm, Inc.||White-light spectral biometric sensors|
|US8229185||9 Abr 2008||24 Jul 2012||Lumidigm, Inc.||Hygienic biometric sensors|
|US8285010||19 Mar 2008||9 Oct 2012||Lumidigm, Inc.||Biometrics based on locally consistent features|
|US8355545||10 Abr 2008||15 Ene 2013||Lumidigm, Inc.||Biometric detection using spatial, temporal, and/or spectral techniques|
|US8570149||14 Mar 2011||29 Oct 2013||Lumidigm, Inc.||Biometric imaging using an optical adaptive interface|
|US8731250||26 Ago 2010||20 May 2014||Lumidigm, Inc.||Multiplexed biometric imaging|
|US8781181||24 Feb 2011||15 Jul 2014||Lumidigm, Inc.||Contactless multispectral biometric capture|
|US8787630||5 Ene 2011||22 Jul 2014||Lumidigm, Inc.||Multispectral barcode imaging|
|US8831297||17 May 2011||9 Sep 2014||Lumidigm, Inc.||Contactless multispectral biometric capture|
|US8872908||26 Ago 2010||28 Oct 2014||Lumidigm, Inc||Dual-imager biometric sensor|
|US8913800||29 May 2012||16 Dic 2014||Lumidigm, Inc.||Optical biometrics imaging with films|
|Clasificación de EE.UU.||600/587, 73/579, 367/191, 181/.5|
|Clasificación internacional||A61B5/117, A61B5/103|
|Clasificación cooperativa||A61B5/4504, A61B5/117|
|Clasificación europea||A61B5/45B, A61B5/117|