EP3955222A1 - Mobile terminal and method for authenticating an illuminant-based security feature using a mobile terminal - Google Patents

Abstract

The invention relates to a method for authenticity verification of a luminescent-based security feature (102) using a mobile terminal (200), comprising the steps: - detecting a radiation intensity (I₀) of the ambient light, - specifying at least one parameter for an excitation of the luminescent-based security feature (102) depending on the detected radiation intensity (I₀) of the ambient light, - positioning the security feature (102) with respect to the image recording device (202) while setting or maintaining the at least one parameter for the Excitation, - stimulating the phosphor of the luminescent-based security feature (102) to emit by means of the lighting unit (204), - detecting the emission of the light emitted by the luminescent-based security feature (102) by means of the camera (206), - evaluating one of the cameras (206) captured series of images (304) or video recording by means of the evaluation device (208) un d Evaluation of the authenticity of the luminescent-based security feature (102) using reference data (306, 308). The invention also relates to a mobile terminal device (200) for carrying out the method.

Description

The present invention relates to a method for verifying the authenticity of a luminescent-based security feature using a mobile terminal device. The invention also relates to a mobile terminal device with an application (app) for carrying out the method.

Security features serve to protect value or security documents against counterfeiting. Valuable or security documents can be, for example, an ID document, a check card, a non-personalized authorization pass, such as a ticket or a means of payment, or a value or security element intended for product protection.

It has long been known from the prior art to provide value or security documents with security features in the form of luminescent substances in order to make them more forgery-proof. Arrangements and methods for the reliable verification of such luminescent-based security features with a mobile terminal are in the publications DE 10 2018 109 141 A1 , DE 10 2018 109 142 A1 and DE 10 2018 102 015 A1 described from the house of the applicant.

In the methods described therein, the authenticity checks are subject to the most varied of environmental conditions, in particular the most varied of lighting conditions, due to the use of the mobile end device. which can complicate the detection of phosphor-based security features.

It is the object of the present invention to specify a method for verifying the authenticity of a luminescent-based security feature using a mobile terminal device, which also delivers a reliable test result under different ambient light conditions. In addition, the object of the invention is to specify a mobile terminal device for carrying out the method

This object is achieved by a method having the features of claim 1 and by a mobile terminal having the features of claim 15. Advantageous configurations with expedient developments of the invention are specified in the dependent claims.

• Erfassen einer Strahlungsstärke des Umgebungslichts,
• Vorgeben wenigstens eines Parameters für eine Anregung des leuchtstoffbasierten Sicherheitsmerkmals in Abhängigkeit der erfassten Strahlungsstärke des Umgebungslichts,
• Positionieren des Sicherheitsmerkmals bezüglich der Bildaufnahmeeinrichtung unter Einstellen oder Einhalten des wenigstens einen Parameters für die Anregung,
• Anregen des Leuchtstoffs des leuchtstoffbasierten Sicherheitsmerkmals zur Emission mittels der Beleuchtungseinrichtung,
• Erfassen der Emission des vom leuchtstoffbasierten Sicherheitsmerkmal emittierten Lichts mittels der Kamera,
• Auswertung einer von der Kamera erfassten Bilderserie oder Videoaufnahme mittels der Auswertungseinrichtung und Bewertung der Echtheit des leuchtstoffbasierten Sicherheitsmerkmals anhand von Referenzdaten.

The method according to the invention for verifying the authenticity of a luminescent-based security feature using a mobile terminal device comprises the following steps in particular:

• detecting a radiation level of the ambient light,
• Specification of at least one parameter for an excitation of the luminescent-based security feature depending on the detected radiation intensity of the ambient light,
• Positioning the security feature with respect to the image recording device while setting or maintaining the at least one parameter for the excitation,
• Exciting the phosphor of the phosphor-based security feature to emit by means of the lighting device,
• capturing the emission of the light emitted by the luminescent-based security feature using the camera,
• Evaluation of a series of images or video recordings captured by the camera using the evaluation device and evaluation of the authenticity of the luminescent-based security feature using reference data.

This has the advantage that a simple mobile terminal device, in particular a commercially available smartphone, can be used to verify the authenticity of a luminescent-based security feature, which is also set up to take into account the lighting conditions prevailing during the verification.

The complexity of the component is reduced if the ambient light intensity is recorded by the camera itself. However, it is alternatively or additionally possible to use a brightness sensor which is also assigned to the mobile terminal device and is also set up to record the ambient light intensity.

It is advantageous if the at least one parameter for the excitation of the luminescent-based security feature is the distance between the image recording device and the luminescent-based security feature, and if the luminescent-based security feature can only be excited when the predetermined distance is present as a function of the radiation intensity of the ambient light . Authenticity can therefore only be checked if the mobile terminal device is at a predefined distance from the luminescent-based security feature or the document of value to which it is attached. This distance varies as a function of the detected ambient light, with real-time detection of the ambient light intensity and real-time adaptation of the predefined distance for the excitation of the security feature preferably taking place. In this way, shadowing caused by the mobile device can be taken into account in real-time verification.

Alternatively or additionally, there is also the advantageous possibility that the at least one parameter for the excitation of the luminescent-based security feature is the luminosity of the lighting unit, and that an excitation of the luminescent-based security feature is only made possible when the luminosity specified as a function of the radiation intensity of the ambient light to Excitation of the luminescent-based security feature is present. Thus, a reliable excitation of the luminescent-based security feature can also take place at greater distances, because of the The intensity emitted by the lighting unit is adjusted depending on the ambient light present.

Alternatively or additionally, the at least one parameter for exciting the luminescent-based security feature can be the exposure time. In this case, “exposure time” is basically to be understood as the duration of illumination during which the illumination unit radiates light in the direction of the security feature.

Even before the luminescent-based security feature is activated, real-time (image) capture can take place by means of the camera, with the image captured by the camera being output on the display of the mobile terminal device at the same time. The image output on the display is preferably overlaid with a partially transparent mask which has a positioning frame adapted to the feature to be detected or a positioning contour adapted to the feature to be detected. It is particularly preferred that the dimensions of the positioning frame or the positioning contour are specified as a function of the detected radiation intensity of the ambient light. In this way, the authenticity can be verified under conditions that are specified and set as a function of the incident ambient light.

It is preferred that the luminescent-based security feature can only be excited when the positioning frame or the positioning contour in the image has been brought into congruence with the dimensions of the luminescent-based security feature. An optimized distance between the camera and the security feature can thus be enforced, so that the authenticity can be checked more effectively.

There is the possibility that an excitation of the luminescent-based security feature is only made possible when the positioning frame or the positioning contour in the image with the dimensions of the luminescent-based security feature has been placed in a predetermined size ratio other than 1. Thus, a targeted deviation between the size of the mask and the size of the luminescent-based security feature detected in the be forced. This refinement makes it more difficult to falsify the measurement result.

The user-friendliness of the mobile terminal device for verifying the authenticity of the luminescent-based security feature is also increased in that the luminescent-based security feature is triggered automatically when the position frame or the position contour in the image has been brought into congruence with the dimensions of the luminescent-based security feature or with this in a different from 1 predetermined size ratio was set.

For an even more reliable detection and authenticity verification of the luminescent-based security feature, it is also advantageous if a white balance is carried out depending on the radiation intensity of the ambient light during or after the detection of the luminescent-based security feature.

There is the possibility that at least one environmental parameter is additionally recorded by the mobile terminal and evaluated by the evaluation device. For example, the geographical position recorded by means of a GPS sensor, the movement information recorded by means of inclination sensors and/or acceleration sensors, and data on mechanical vibrations of the mobile terminal device come into consideration as environmental parameters. The environmental parameters can thus be used to analyze the environment of the mobile terminal device and to draw conclusions that there is an anomaly with regard to at least one parameter relating to the environment (anomaly detection). For example, a luminescent-based security feature can also be evaluated as “forged” based on the detection of an anomaly in the surroundings.

The series of images or the video recording is preferably always captured for a predetermined minimum duration during a decay time of the emission of the luminescent-based security feature. After the end of the excitation, the decay behavior of the luminescent-based security feature can be examined and evaluated, with the decay curve or Emission curve is compared to a reference curve. If there is a discrepancy between the reference curve and the emission curve, a forged security feature containing a luminescent material or a value or security document with such a feature can likewise be inferred. The same applies to the cooldown time.

The corresponding reference values are stored, for example, in a digital memory that can be part of the mobile terminal device, or in an intelligent database on a remote server.

Emission detection and shape analysis are preferably carried out when assessing the authenticity of the luminescent-based security feature. In the emission detection, several images of an image series recorded by the camera are compared, with in particular an image difference between the recorded images and the reference image being determined, an RGB histogram being created, the hue value of different color channels being determined and the decay time of the phosphor being determined. In the shape analysis, the shape of the security feature is compared with a reference shape.

So that the security feature can only be detected using a smartphone, the phosphor is configured in such a way that it can be excited in the visible spectral range, in particular in the blue spectral range, so that the flash light source of the smartphone can deliver this excitation radiation. Furthermore, the phosphor is configured in such a way that it emits in the visible spectral range in order to ensure that it can be detected with the camera module of a commercially available smartphone. In addition, the phosphor is configured in such a way that its luminescence decays in the ms range after the flash excitation is completed, so that reliable verification is possible after the excitation has ended.

In a preferred embodiment, the phosphor of the phosphor-based security feature is a Ce ³⁺ or Mn ²⁺ co-doped silicate garnet phosphor. When excited with the light of white-emitting LEDs, preferably at a maximum wavelength of 450 nm, the stationary luminescence of the phosphor has a broadband emission spectrum with several emission maxima in the visible range spectral range. These maxima are around 505 nm (assignable to the emission of Ce ³⁺ ions on dodecahedral Ca ²⁺ sites), 570 nm (assignable to the sensitized emission of Mn ²⁺ ions on dodecahedral Ca ²⁺ sites), 700 nm (assignable to the sensitized emission of Mn ²⁺ ions on Sc ³⁺ octahedral sites).

The white light of a lighting unit of a smartphone is generated by an LED, which consists of an LED semiconductor chip emitting at approximately 450 nm, for example, and one or more LED conversion phosphors placed above the LED semiconductor chip. These conversion phosphors are capable of converting the emission of the blue LED proportionately into longer-wave visible luminescence radiation (broadband emissions in the green, yellow and red spectral range) with an emission maximum of around 560 nm, for example. The white light of the LED available as the lighting unit of commercially available smartphones results from the additive color mixture of the individual luminescence components described, with the blue spectral component having a significantly higher intensity. This means that the phosphor that can be used to provide the security feature according to the invention must preferably be configured in such a way that it has a high efficiency of spectral excitability, particularly in the range between 420 nm and 470 nm. The maximum of the spectral excitability of the phosphor is particularly preferably at about 450 nm.

The smartphone camera is available as an image acquisition unit for detecting the luminescence signals of the phosphor. The image acquisition unit is preferably equipped with a CMOS sensor and an IR filter. It therefore has a spectral sensitivity that covers the entire visible spectral range up to about 750 nm. Single images, image series or video recordings can be recorded by means of the image acquisition unit. For the phosphor used to create the security feature, this means that it must be configured in such a way that, after the excitation has taken place, it emits with the highest possible intensity, preferably in the spectral range between 480 nm and 750 nm.

The mobile terminal device used according to the invention for verifying the authenticity of the security feature is preferably a conventional, commercially available smartphone that is equipped with a suitable application program (app). It is understandable for the person skilled in the art that the same functionality can also be integrated into a tablet or a similar multifunctional data processing device, for which purpose it must be equipped with a camera with an image acquisition unit and/or lighting unit and a data processing unit. Devices of this type that have the same effect should also be included in the invention. The evaluation device is preferably a processor, in particular a microprocessor. The processor comprises a digital memory in which a computer program (app) with software code sections is loaded or can be loaded directly, which causes the steps of the above method to be performed and runs through when the program is executed by the processor.

Fig. 1

eine schematische Darstellung eines Wert- oder Sicherheitsdokuments in Form einer Banknote mit einem leuchtstoffbasierten Sicherheitsmerkmal,

Fig. 2

eine schematische Darstellung von Komponenten einer Anordnung zur Echtheitsverifikation des leuchtstoffbasierten Sicherheitsmerkmal,

Fig. 3

in Diagramm mit dem An- und Abklingverhalten eines Leuchtstoffes des Sicherheitsmerkmals bei Blitzlichtanregung,

Fig. 4

eine schematische Draufsicht auf das Display eines mobilen Endgeräts, bei welchem die Distanz zwischen dem Endgerät und dem Sicherheitsmerkmal zu groß ist, und

Fig. 5

eine schematische Draufsicht auf das Display eines mobilen Endgeräts, bei welchem die Distanz zwischen dem Endgerät und dem Sicherheitsmerkmal für dessen Echtheitsverifikation optimal ist.

The present invention is explained in more detail below with the aid of figures, the examples shown being merely exemplary in nature and not representing any limitation with regard to the scope of the invention described. They show in detail:

1

a schematic representation of a value or security document in the form of a banknote with a fluorescent-based security feature,

2

a schematic representation of components of an arrangement for authenticity verification of the luminescent-based security feature,

3

in a diagram with the rise and fall behavior of a phosphor of the security feature when excited by a flash light,

4

a schematic plan view of the display of a mobile terminal device, in which the distance between the terminal device and the security feature is too great, and

figure 5

a schematic top view of the display of a mobile terminal device, in which the distance between the terminal device and the security feature is optimal for its authenticity verification.

figure 1 FIG. 1 shows a value or security document 100 in the form of a bank note, which includes a fluorescent-based security feature 102. The security feature 102 can be used to verify the security document 100 . The luminescent-based security feature 102 has a star shape here. The star shape is purely illustrative, it can therefore have any other shape. The luminescent-based security feature 102 is arranged in the area of a visible feature 104, here in the form of the nominal value of the bank note. The security feature 102 consists of a phosphor that can be excited to luminescence by means of electromagnetic radiation with a predetermined wavelength, as mentioned above. The security feature 102 can be verified using a method in which the authenticity of the security feature 102 is checked, which will be discussed in more detail below.

figure 2 shows a schematic arrangement for verifying the luminescent-based security feature 102, the security feature 102 being excited to luminescence by means of a lighting unit 204 of an image recording device 202 of a mobile terminal device 200, in particular a smartphone, in that the lighting unit 204 generates excitation light, in particular a flashlight. The flashing light of the lighting unit 204 of the image recording device 202 is generated by means of an LED emitting white light. The flash light has an intensity I _A . After excitation, the phosphor of security feature 102 emits electromagnetic radiation, which occurs for a decay time in the ms range after excitation has ended. The emission I _E of the phosphor can be detected with a camera 204 or a detector of the image recording device 202 . Furthermore, the camera 204 is set up to capture an ambient radiation I ₀ of the daylight or room light that impinges on the security feature 102 and the bank note and is reflected on them. The smartphone can also be equipped with a brightness sensor (photo sensor) in order to detect the radiant intensity of the ambient light. The ambient radiation I ₀ is to keep as low as possible during the detection process of the luminescent-based security feature 102, wherein a distance d between the security feature 102 and the smartphone is kept small. Due to the small distance d, which is preferably below the focusing range (focus) of the camera 206, the smartphone shields the ambient radiation I ₀ for the most part, but this is not absolutely necessary in the method according to the invention.

In figure 3 a diagram with the rise and fall behavior of the phosphor used in the security feature 102 is shown. An emission curve 300 of the security feature 102 excited to luminescence is shown in the diagram along a time axis t. Furthermore, a flashlight excitation curve 302 is plotted along the time axis. When the flash is generated by the smartphone, the flash excitation curve 302 rises sharply, holds its level for a short time, and then falls to zero after the flash goes off. The phosphor of the security feature 102 is excited to luminescence by the electromagnetic radiation of the flash light, as a result of which its emission curve 300 rises almost simultaneously with the flash light emission curve 302, regularly with a reduced steepness. The emission curve 300 drops significantly more slowly than the flash light excitation curve 302 after the flash light has gone out. The decay behavior of the phosphor is in the ms range. Individual images 304 of the security feature 102 captured by the camera 206 of the mobile terminal device 200 are also shown below the time axis. The images 304 show the decaying emission of the security feature 102 as a pattern that becomes weaker over time. They can be used for verification of the security document 100 in a further method step. After the emission has essentially completely decayed, a reference image 306 can be recorded as the last image of the recorded image sequence. Depending on the evaluation method, an additional reference image 308 can also be recorded before the activation of the excitation radiation (triggering of the flash). An additional control of the security feature is possible, for example, by comparing the reference images 306 and 308 with one another.

• Erfassen der Strahlungsstärke I₀ des Umgebungslichts,
• Vorgeben wenigstens eines Parameters für eine Anregung des leuchtstoffbasierten Sicherheitsmerkmals 102 in Abhängigkeit der erfassten Strahlungsstärke I₀ des Umgebungslichts,
• Positionieren des Sicherheitsmerkmals 102 bezüglich der Bildaufnahmeeinrichtung 202 unter Einstellen oder Einhalten des wenigstens einen Parameters für die Anregung,
• Anregen des Leuchtstoffs des leuchtstoffbasierten Sicherheitsmerkmals 102 zur Emission mittels der Beleuchtungseinheit 204,
• Erfassen der Emission des vom leuchtstoffbasierten Sicherheitsmerkmal 102 emittierten Lichts mittels der Kamera 206,
• Auswertung einer von der Kamera 206 erfassten Bilderserie 304 oder Videoaufnahme mittels der Auswertungseinrichtung 208 und Bewertung der Echtheit des leuchtstoffbasierten Sicherheitsmerkmals 102 anhand von Referenzdaten 306, 308.

In order to authenticate the luminescent-based security feature 102 using the mobile terminal device 200, the following steps are carried out:

• Detection of the radiation intensity I ₀ of the ambient light,
• Specification of at least one parameter for an excitation of the luminescent-based security feature 102 depending on the detected radiation intensity I ₀ of the ambient light,
• Positioning the security feature 102 with respect to the image recording device 202 while setting or maintaining the at least one parameter for the excitation,
• Stimulating the phosphor of the phosphor-based security feature 102 to emit by means of the lighting unit 204,
• detecting the emission of the light emitted by the luminescent-based security feature 102 by means of the camera 206,
• Evaluation of an image series 304 or video recording captured by the camera 206 by means of the evaluation device 208 and evaluation of the authenticity of the luminescent-based security feature 102 on the basis of reference data 306, 308.

The at least one parameter for the excitation of the luminescent-based security feature 102 is presently the distance d between the image recording device 202 and the luminescent-based security feature 102. An excitation of the luminescent-based security feature 102 is only possible when the specified distance d as a function of the radiation intensity I ₀ des ambient light is present. Alternatively, there is also the possibility that the excitation luminosity I _A is increased on the basis of the detected ambient light in such a way that a desired luminescence effect occurs.

Evidence of Figures 4 and 5 before the luminescent-based security feature 102 is activated, real-time detection is performed by the camera 206 , the image captured by the camera 206 being output in real time on the display 210 of the mobile terminal device 200 . The image output on the display 210 is overlaid by a partially transparent mask 310 which has a positioning frame or a position frame adapted to the feature 102 to be detected positioning contour 312 adapted to the feature to be detected. The dimensions of the positioning frame or the positioning contour 312 are specified or set as a function of the detected radiation intensity I ₀ of the ambient light. The mask 310 or positioning contour 312 is therefore variable in terms of its representation size on the display 210 .

An excitation of the luminescent-based security feature 102 is only made possible when the positioning frame or the positioning contour 312 in the image has been brought into congruence with the dimensions of the luminescent-based security feature 102 . In an advantageous alternative, excitation of the luminescent-based security feature 102 is only made possible when the positioning frame or the positioning contour 312 in the image with the dimensions of the luminescent-based security feature 102 has been placed in a predetermined size ratio that differs from 1; that is, if there is a predetermined difference in size between the positioning contour 312 and the shape of the security feature 102 .

In figure 4 the ambient light level I ₀ was determined, with a high value for I ₀ . As a result, the mask 310 was chosen to be correspondingly small, which means that the smartphone has to be brought very close to the value or security document 100 in order to bring the contours of the security feature 102 and the positioning contour 312 either into alignment or into a suitably selected size difference . The closer the smartphone is brought to the security feature 102, the greater its shading from the ambient light, so that the size of the mask 310 can be readjusted. The excitation of the luminescent-based security feature 102 is carried out automatically when the position frame or the position contour 312 in the image has been brought into alignment with the dimensions of the luminescent-based security feature 102 or has been set to a predetermined size ratio that differs from 1, as shown in the illustration after figure 5 for the case of congruence is illustrated.

As a result, the ambient light can be reduced with the method according to the invention and with the mobile terminal device 200 according to the invention Reliably take account of authenticity verification of the luminescent-based security feature 102, with the result that an improved and more reliable testing option is created.

REFERENCE LIST

100

value or security document

102

fluorescent-based security feature

104

visible feature

200

mobile device / smartphone

202

image capture device

204

Lighting unit (image pickup device)

206

Camera (image recording device)

208

Evaluation device / microprocessor

210

screen

300

emission curve

302

flash excitation curve

304

image

306

reference image

308

additional reference image

310

mask (partially transparent)

312

positioning contour

Claims (15)

Method for verifying the authenticity of a luminescent-based security feature (102) using a mobile terminal device (200) which has at least one evaluation device (208), an image recording device (202) with a camera (206) and a lighting unit (204), and a display (210) has, comprising the steps: - detecting a radiation intensity (I ₀ ) of the ambient light, - Specification of at least one parameter for an excitation of the luminescent-based security feature (102) depending on the detected radiation intensity (I ₀ ) of the ambient light, - Positioning the security feature (102) with respect to the image recording device (202) while setting or maintaining the at least one parameter for the excitation, - Exciting the phosphor of the phosphor-based security feature (102) to emit by means of the lighting unit (204), - detecting the emission of the light emitted by the luminescent-based security feature (102) by means of the camera (206), - Evaluation of a series of images (304) or video recording captured by the camera (206) by means of the evaluation device (208) and evaluation of the authenticity of the luminescent-based security feature (102) using reference data (306, 308). Method according to Claim 1, characterized in that the ambient light intensity (I ₀ ) is detected by means of the camera (206). Method according to Claim 1 or 2, characterized in that the ambient light intensity (I ₀ ) is detected by means of a brightness sensor of the mobile terminal device (200). The method according to any one of claims 1 to 3, characterized in that the at least one parameter for the excitation of the phosphor-based Security feature (102) is the distance (d) between the image recording device (202) and the luminescent-based security feature (102), and that excitation of the luminescent-based security feature (102) is only made possible when the specified distance (d) depends on the radiation intensity (I ₀ ) of the ambient light is present. Method according to one of Claims 1 to 4, characterized in that the at least one parameter for the excitation of the luminescent-based security feature (102) is the luminosity (I _A ) of the lighting unit (204), and that an excitation of the luminescent-based security feature (102) only is made possible when the luminosity (I _A ) predetermined as a function of the radiation intensity (I ₀ ) of the ambient light for exciting the luminescent-based security feature (104) is present. Method according to one of Claims 1 to 5, characterized in that the at least one parameter for the excitation of the luminescent-based security feature (102) is the exposure time. Method according to one of Claims 1 to 6, characterized in that real-time detection by means of the camera (206) takes place before the luminescent-based security feature (102) is activated and the image captured by the camera (206) is output on the display (210), wherein the image output on the display (210) is overlaid with a partially transparent mask (310) which has a positioning frame adapted to the feature (102) to be detected or a positioning contour (312) adapted to the feature to be detected, and that the dimensions of the Position frame or the positioning contour (312) depending on the detected radiation intensity of the ambient light (I ₀ ) are specified. Method according to Claim 7, characterized in that an excitation of the luminescent-based security feature (102) is only made possible when the positioning frame or the positioning contour (312) in the image has been brought into alignment with the dimensions of the luminescent-based security feature (102). The method according to claim 7, characterized in that an excitation of the luminescent-based security feature (102) is only enabled when the positioning frame or the positioning contour (312) in the image with the dimensions of the luminescent-based security feature (102) in a different from 1, predetermined size ratio was set. The method according to claim 8 or 9, characterized in that the excitation of the luminescent-based security feature (102) is carried out automatically when the positioning frame or the positioning contour (312) in the image with the dimensions of the luminescent-based security feature (102) was brought into congruence or with this was placed in a predetermined size ratio different from 1. Method according to one of Claims 1 to 10, characterized in that a white balance is carried out as a function of the radiation intensity (I ₀ ) of the ambient light during or after the detection of the luminescent-based security feature (102). Method according to one of Claims 1 to 11, characterized in that at least one environmental parameter is additionally recorded by the mobile terminal (200) and evaluated by the evaluation device (208). Method according to one of Claims 1 to 12, characterized in that the series of images (304) or the video recording is recorded for a predetermined minimum duration during a decay time of the emission of the luminescent-based security feature (102). Method according to one of Claims 1 to 13, characterized in that emission detection and shape analysis are carried out when the authenticity of the luminescent-based security feature (102) is assessed. Mobile terminal (200) with a processor (208) forming an evaluation device, with an image recording device (202) which comprises a camera (206) and a lighting unit (204), with a display (210), and with a digital memory of the processor, in which a computer program with software code sections is loaded or can be loaded directly, which causes the execution of the steps of the method according to at least one of claims 1 to 14.

Images