NL8002604A - Palm image pattern recognition and identification system - has raster optically scanning surface of palm to sense varying levels of light using flashing UV source - Google Patents

Abstract

The system is for enhancing image details of an object to be recorded. The object, such as the palm of a hand, is bombarded by radiant energy from an ultraviolet light source in such a manner that the object absorbs the radiant energy and emits visible light in the form of fluorescence and phosphorescence. A camera optically scans the object and records image details that have become available due to the fluorescence and phosphorescence. The details of objects having rough or irregular surfaces may be further enhanced by disposing the ultraviolet light source at an angle with respect to the surface of the object so that some portions are shaded while other portions of the surface absorb the radiant energy and emit visible light. Appropriate filters may be provided to reduce the effects of extraneous light.

Description

- 1 - t Vi

Method and device for recording image details.

In identification systems, based on pattern recognition, it is important that eye-catching image details and features are reproducibly provided to the identification system. One method of highlighting such details is to electrically amplify the electrical analog signal output from a recording camera. pounds with light levels obtained from an image as scanned by the camera. The magnification provides greater accentuation of light and dark levels, and such magnification can be achieved by a conventional differential network consisting of a series capacitor and a shunt resistor.

It would be desirable to accentuate the image details before they are recorded by the camera so that the analog signal better represents the eye-catching details, including the number of light-dark and dark-light variations behind the camera placed accentuators must respond is reduced, which in turn increases reliability of subsequent image or pattern recognition. Contains the palm of a hand. , e.g. both friction wrinkles and folds, but the folds. details are much more noticeable than the friction wrinkle details. It would be desirable to present only 25 the pleat details to the camera.

When exposed to inconsistent light, the palm of the hand will reflect the light in such a way that a camera cannot detect subtle pattern changes caused by irregular surface details such as wrinkles and creases. For this reason, a pure illumination of the palm with visible light does not provide the desired accentuation and, in essence, may even obscure certain details.

It is known that most objects when they are exposed to light of a given wavelength will reflect or absorb the light. In many materials, the light emitted from the object will be of a different wavelength of 800 2 6 04 * - - - - 4 f * - 2 - which is known as luminescence »One type of luminescence includes fluorescence, this is a radiation form of energy that takes place according to quantum mechanics, wherein an atom excited by an external energy source relaxes from one state to another, delivering an energy quantum in the form of light. Another type of luminescence, which is caused by the absorption of radiation, and which persists for a considerable period of time after the radiation has ceased. -: - ¾% ¾ is phosphorescence. The term fluorescence is commonly used to indicate that the emitted radiation is maintained only as long as the excitation continues, while the term phosphorescence is used to indicate that the emitted radiation persists for some time after the excitation has ended. .

It is generally believed that the dividing line between these two types of luminescence is determined by -8 a lag time of 10 sec.

Both fluorescence and phosphorescence can result from excitation by means of an ultraviolet light source and depending on the length of time in which radiations thereof are applied to a material, the material can excite to an energy level which is luminescent. , will generate for a certain period of time until '- the energy level drops to a level at which a desired visible light level is no longer emitted. Fluorescence decay technology is used in laboratory research as an aid in determining the presence of certain molecules in complex organic samples. For example, phosphorescence is used in radar pointers, where latent target images slowly fade in order to track a flying object.

The invention generally relates to an identification system, and more particularly to a method and apparatus for accentuating (light amplifying) image details of an object before recording it with a camera of an identification system.

To provide a recognition of 40 information related to a particular object or person 800 2 6 04 - 3 - *. * an identification system includes a camera such as a vidicon or a crystal charge-coupled image detector, which scans an identification object, which may be formed by a palm, and then outputs an electrical analog signal proportional to the light levels, which occur when the wrinkles and folds of the palm are scanned.

Before scanning the camera, place the palm of the hand in the correct position and expose it to a flash of light or a series of intermittent interrupted light. •:: ·:: -Λ: - ·:; · '> · 10 ··. · Ί · Ί1χΐ3βη-: from: an ultraviolet 'light source> · -so that ·· dé. · Palm <·····> · ♦ ··· -f' · absorbs radiant energy. During ultraviolet excitation and after its termination, the palm emits visible light for a short period of time, during which period the above camera records image details which have become available due to fluorescence and phosphorescence. The variation of light levels emitted by the frictional ripples at such luminescence is very small although the variations are generally greater than those which can be obtained by exposure to a source of visible light, while the variation of the light levels emitted by the folds, when luminescence is significant. This is believed to be at least in part due to the differences in molecular density of the skin and differences in surface irregularities and tissues. Consequently, the palm piooid details are accentuated, facilitating positive identification.

It has been found that optimum accentuation is achieved by aligning the palm so that it occupies an oblique angle with respect to the ultraviolet light source and at the same time is perpendicular to the camera. During an ultraviolet flash, trough portions of the palm print details will be shaded and remain dark, while the top edges of the wrinkles and the high surface areas absorb radiant energy. These parts, which absorb radiant energy, form the parts, which fluoresce and phosphoresce.

Suitable filters may be provided for filtering out light from outside both during the ultraviolet flash and during camera recording.

800 2 6 04 * '- 4 -

The object of the invention is to provide a new method and device for recording image details for use in an identification system.

The invention further aims to provide an accentuation of the striking image details of an object to be recorded by making use of the object's fluorescence and phosphorescence properties.

A further object of the invention is an in- •. .-- 4 'r · ··. "" "direction te · vèirschaffenv which provides" feasible "we eye-catching image details of an object to an identification system.

The invention will be explained in more detail below with reference to the drawing, which shows by way of example a favorable embodiment of the device according to the invention. Herein: fig. 1 shows a block diagram of a favorable embodiment of the device according to the invention, and: fig. 2 shows a cross-section of an object receiving light energy at an oblique angle.

Fig. 1 shows a block diagram of an identification system, which includes a system for light amplifying or accentuating the image details, in particular details of a palm. The identification system is in. / · *. -.25 = .; .ha! ari indicated in full by the reference number. 10 and includes a camera 12 for recording image details. The camera may suitably be a television type vidicon or a crystal charge-coupled image detector such as a Fairchild CCD 202 camera. With this camera 30, an image is scanned in a raster, producing an analog voltage signal corresponding to the light levels obtained from the image with each horizontal scan. An enhancement circuit 14, which may consist of a conventional differential circuit such as a series 35 capacitor and a shunt resistor, may be provided to effect an electrical gain of the recorded image details if such electrical gain is necessary or desirable. The analog signal, which is either electrically enlarged or comes directly from the camera, is converted into digital form 800 2 6 04 -β - 5 -

* · - .7 VWA

in an analog / digital converter 16 to provide numerical digital information corresponding to the different voltage levels. For this purpose use can be made of one of the many different conventional analog / digital converters.

The digitized signal is then stored line by line in an image memory unit 20 when the image is scanned, so that a fully digital image is stored therein. A .·". * - · -. ·. 10 ·: · - such memory unit -can, 10,000 or more addressable ·· *. contain memory elements.

A recognition information analyzing unit 22 is provided for performing an analysis, element by element, of the pattern image stored in the image memory unit 20. The recognition information analyzing unit 22 includes a number of permanent memories, which include specific logic steps for analyzing each memory element without loss of information under program control to highlight and rank the eye-catching image details according to their degree of distinctiveness. The more noticeable image details are then stored in information blocks 24, which can be suitably formed by any memory medium intended for permanent storage such as magnetic disks, tapes, etc. .. cassettes or cards. The information can be later retrieved for identity verification upon request.

The identity verification is performed by an identification test unit 26, which compares old image 30 information stored in information blocks 24 with newly obtained image information * input into the image memory unit 20. The identification test unit 26 contains permanent memories, which contain specific logic steps for correlating information 35 under program control. In addition, the recognition information analyzing unit 22 can be queried to take out the eye-catching details as was done by the original information retrieval. Logical operation 40 is performed by the identification test unit 26 to check whether a reasonable adjustment 800 2 6 04 - 6 - has been achieved between the stored recognition information and the new recognition pattern and an output is applied to a user device 30, which indicates a verification whether the new recognition pattern rejects. The appliance 30 can suitably contain an electromechanical door opening member, signal lamps or an alarm member.

A process and control logic unit 34 is provided for controlling the operation and operation order of the camera and chains of the identification system 10.

... vJThis;.: process and control logic unit .34 can be set on .suitable ... ....

10 consist of a mini-computer or microprocessor construction. Both have been used successfully in development prototypes of the invention and a microprocessor has been used in the commercial embodiment. The identification system 10 may suitably be of the type described in the

U.S. Patent Application No. 817,623 to applicant.

A pre-camera accent is provided by using the fluorescence and phosphorescence properties of the object to be recorded, which in the example given above, as already mentioned, consists of a palm. The hand is placed in the correct position, optionally using a suitable jig (not shown) to ensure repeatable readings, exposing the palm to both the ultraviolet “.25” light source “40” and the camera 12. The palm of the hand is preferably oriented such that it is at an oblique angle. to the ultraviolet light source 40 and at the same time is perpendicular to the camera 12, for reasons which will become more apparent later. The identification system 30 can be operated by various methods. For example, the person to be identified can enter an identity code via a keyboard or he can enter a magnetized identification card into a card reader. After activation of the identification system, the process and control logic unit 34 starts its identification program. First, the ultraviolet light source 40 is turned on, releasing an ultraviolet flash or periodically interrupted amount of radiant energy absorbed by the palm. During the ultraviolet 800 2 6 04 ψ - 7 - excitation and after its determination, visible light is emitted from the palm of the hand for a short period of time, during which image details, primarily those of the fold lines, due to the fluorescence and 5 phosphorescence become available. The variation of the light levels radiated by the friction ripples at this luminescence is very small compared to the variation of the light levels radiated by folds and neighboring areas. It should be noted that the folds themselves appear - * -. -i .10 -.as · dark, .glads- against ·· the bright 'adjacent' areas. . · .. ·. ·

It is believed that because the skin of the palm is tense when the hand is opened, the molecular details of the skin in the fold lines become less than the density of other areas and according to quantum mechanics it can be concluded that the relatively smaller atoms absorb less radiant energy and emit less visible light. As a result, the crease details in front of the camera will appear as dark lines.

The flash supplied by the ultraviolet light source 40 has a duration of about 1 millisecond. The time required for scanning and recording operation of the camera 12 is typically about 10 milliseconds.

In addition, optical filters 42 and 44 are present, the filter 42 of which has light with a wavelength of 350 to. ; 400 nanometers, to ensure that only ultraviolet light * reaches the palm, while filter 44 transmits light of 450 to 550 nanometers wavelength to ensure that only visible light reaches the camera 12.

The provision of a mirror 46 ensures that the palm is fully and uniformly protected to reflect excessive ultraviolet light, which would otherwise enter the palm during the flash period. Even with such a reflected light operation, however, the trough parts and other low parts of the palm including the pleat details are shaded.

When the palm detail information is recorded by the camera 12, the identification system 40 operates on the stored information under the control of the process 800 2 6 04 Τ '- 8 -

- - ----. . * -> J

and control logic unit 34 as described above and the hand can be removed from the predetermined location.

With regard to Fig. 2, it is noted that when light hits an object 50 with crests 50 and troughs 54 at an oblique angle, the troughs 54 do not receive the incident light and are thus shaded. Therefore, mainly from the top parts 52 will be lightly reflected. For this reason, it is preferable to direct the palm of the hand so that ultraviolet light reflects from the flash source 40. palm at an oblique angle. This ensures that the pleat details will absorb less radiant energy and that the image details of the palm will be accentuated.

It will be clear that the invention is by no means limited to the above-described exemplary embodiment, but that many modified embodiments are possible without departing from the scope of the invention.

conclusions - 80 0 2 6 04

Claims (10)

A method of recording image details of an object to be identified, characterized in that this method consists of irradiating the object with radiant energy such that the object 5 absorbs the radiant energy and emits visible light from at least parts thereof, which be representative of accentuated image details, and from the optical .-! ··. · Scanning the object and. 'opneraen of the picture details. · · · .- ...- 2. A method according to claim 1, characterized in that the radiant energy is formed by ultraviolet light and the visible light is formed by fluorescence and phosphorescence. 3. Method according to claim 1, characterized in that the radiant energy is directed at an angle to the object. 4. Method according to claim 1, characterized in that the irradiation of the object with radiant energy takes place in a period of time of about 1 millisecond. 5. Device for recording image details 20 of an object to be identified, characterized in that this device consists of a means for irradiating the object with radiant energy such that the object absorbs the radiant energy and emits visible light from at least parts of these, which are representative of accentuated image details, and from means for optically scanning the object and recording the image details. 6. Device according to claim 5, characterized in that the irradiating member consists of an ultraviolet light source, that the radiant energy is formed by ultraviolet light, and that the visible light emitted is formed by fluorescence and phosphorescence. 800 2 6 04 - 10 - t ~~ 7. Device according to claim 6, characterized in that it further comprises a first optical filter placed between the ultraviolet light source and the object to be identified, and a second optical filter placed between the object to be identified and the optical scanning and recording means, the first optical filter transmitting light having a wavelength of about 350 to 400 nanometers, while the second optical filter transmitting light having a wavelength of about 450 to 10-550 ... nanometers. . . . . 8. Device as claimed in claim 6, characterized in that a mirror is placed in the vicinity of the object to be identified and is oriented such that it reflects the ultraviolet light directed at the object. 9. Device according to claim 6, characterized in that the ultraviolet light source is placed at an angle relative to the object to be identified, such that certain parts of the object are shadowed by the radiant energy. 10. Device as claimed in claim 6, characterized in that a control device for controlling the operation thereof is connected to the ultraviolet light source and the optical scanning and recording means. 800 2 6 04