KR200183189Y1 - Card ruggedness sensing device - Google Patents

Abstract

The present invention relates to an uneven character recognition device, which irradiates light on the uneven character face and reflects the irradiated light to change the reflection characteristics or wear of the uneven character face in advance in recognizing the character by contrast. And it is to reduce the error of recognition due to the distortion of contrast due to unstable lighting.

The uneven character recognition device of the present invention is made of a material consisting of a material causing a change in transmittance by an electric field and two conductive films 12 (12A) surrounding both sides to form an electric field in the material. It is made to surround the outside, one side of the conductive film is characterized in that it is in contact with the irregular characters or symbols to induce a change in the thickness of the material causing a change in transmittance by the contact pressure. Accordingly, while using the optical means to recognize the uneven character can reduce the recognition error of the uneven character and increase the recognition rate.

Description

Uneven character recognition device {Card ruggedness sensing device}

The present invention relates to an uneven character recognition device, and more particularly, to reflect the irradiated characters on the surface of the uneven characters and reflect the irradiated light to change the reflection characteristics or unevenness according to the material that occurs in advance in the recognition of characters by contrast. This is to reduce the recognition error due to the wear of the character surface and the distortion of the contrast due to unstable lighting.

Credit cards, blind braille, etc., treat the flat surface with uneven characters or magnetic parts of the back side to enable identification of numbers. Recognition means by the uneven characters are dependent on the optical means, and the recognition means by the magnetic means are recognized as magnetic means. Such card recognition uses magnetic, but some recognizes irregular characters.

In general, the uneven character recognition method uses an optical means to irradiate light on the uneven character surface and reflect the irradiated light to recognize it using a contact image sensor (CIS). An example can be found in a character recognition device and method such as a credit card 1 having an uneven character 3, and FIGS. 1 and 2 show a contact image sensor (not shown) used for recognition of uneven characters 3 of a credit card. 2) and the recognition method accordingly.

The contact image sensor 2 includes a light emitting diode 4 fixed at a position where the surface of the uneven character 3 formed on the surface of the card 1 is viewed, and a plurality of light receiving elements 5 at the periphery of the light emitting diode 4. It consists of an array sensor (6) installed to have a constant arrangement by fixing the, the typical use example of the contact image sensor (2) has been applied for the purpose of reading documents from the fax (FAX) device.

Such a contact image sensor 2 first irradiates light on the surface of the uneven character 3 through the light emitting diode 4, and then the light receiving elements 5 read the light reflected from the uneven character 3. It recognizes letters that are uneven by the contrast. Therefore, the contact image sensor 2 applied by the optical means shows the optical recognition result differently according to the state of the uneven character 3 on the card 1 surface. That is, even under the same conditions, if the state of the uneven character 3 is normal, it can be correctly recognized without an error of recognition, but if the uneven character 3 is in an abnormal state, the recognition rate drops.

In addition, the factors influencing the optical recognition result by the contact image sensor 2 are variations in reflection characteristics according to materials, illumination and contrast distortion caused by the optical means themselves, and these factors act as error factors of recognition at any time. do.

Therefore, the conventional method of using optical means to recognize uneven characters such as credit cards is irrelevant to the uneven change of the card used, the irradiated light is reflected, so that the CIS recognizes the character by the contrast, reflection according to the material There was a problem that an error occurs in recognition due to a change in characteristics, the influence of lighting, and the like.

Therefore, an object of the present invention is to increase the recognition rate of uneven characters when optical means are used to recognize uneven characters.

The present invention for achieving the above object is made of a light emitting diode fixed to a position to see the surface of the irregularities formed on the surface of the card, and an array sensor installed to have a constant arrangement by fixing a plurality of light receiving elements to the periphery of the light emitting diode In the uneven character recognition device for applying the contact image sensor to recognize the uneven character optically,

The uneven character recognition device,

It is composed of a material that causes a change in transmittance by an electric field and two conductive films surrounding both sides to form an electric field in the material.

One side of the conductive film is in contact with the uneven characters or symbols to induce a change in the thickness of the material causing a change in transmittance by the contact pressure.

Optionally, the polymer dispersed liquid crystal is used as a material causing a change in transmittance by the electric field.

Optionally, the polymer dispersed liquid crystal is constituted by a cylindrical roller.

Optionally, one side of the conductive film is a transparent ITO coated film, and the other side of the conductive film is treated with a transparent ITO film or a film coated with an opaque conductive metal.

1 is a view showing a general uneven character recognition method

2 is a block diagram of a contact image sensor applied to a conventional uneven character recognition method

3 shows the configuration of the uneven character recognition device according to the present invention

(A) side view

(B) is a front view

4 is a layered cross-sectional view of a polymer dispersed liquid crystal according to an embodiment of the present invention.

5 and 6 are diagrams illustrating changes in transmittance of polymer dispersed liquid crystals according to voltage and thickness changes, respectively.

7 is a view showing another configuration of the polymer dispersed liquid crystal according to the present invention

8 is a cross-sectional view showing the configuration of a cylindrical coalescing polymer dispersed liquid crystal according to the present invention

*** Explanation of symbols for main parts of drawings ***

1: card 2: contact image sensor

3: uneven character (symbol) 4: light emitting diode

5: Receiving element 6: Array sensor

10: polymer dispersed liquid crystal 11.11A: transparent film

12.12A: Conductive Layer 13: Polymer

14: liquid crystal 15: conductive metal

If the outside of the contact image sensor is treated with Polymer Dispersed Liquid Crystal and closely adheres to the irregular characters, the recognition rate of the irregular characters is improved by using the principle that the transmittance of the irregular characters portion and the polymer dispersed liquid crystal sheet is changed. Will be.

Hereinafter, the present invention will be described with reference to the drawings.

Figure 3 shows the configuration of the uneven character recognition device according to the present invention (A) is a side view (B) is a front view, Figure 4 is a layered cross-sectional structure of the polymer dispersed liquid crystal according to an embodiment of the present invention, 5 and 6 are diagrams illustrating transmittance changes of polymer dispersed liquid crystals according to voltage and thickness changes, respectively, and FIG. 7 shows another configuration of the polymer dispersed liquid crystal according to the present invention, and FIG. 8 is a polymer dispersed type according to the present invention. It is sectional drawing which shows the structure of the cylindrical coalescence of a liquid crystal.

The present invention is made of a material consisting of a material causing a change in transmittance by an electric field and two conductive films surrounding both sides to form an electric field in the material, as shown in FIGS. 3 to 8. One side of the conductive film is configured to contact the uneven characters or symbols to induce a change in thickness of a material causing a change in transmittance by the contact pressure to recognize the uneven characters. And the polymer dispersed liquid crystal 10 is used as a substance which changes transmittance | permeability by an electric field, and the polymer dispersed liquid crystal 10 is produced in the cylindrical roller type.

The present invention treats the outside of the contact image sensor 2 with the polymer dispersed liquid crystal 10 as shown in FIG. 3 to bring the polymer dispersed liquid crystal 10 into contact with the uneven characters 3, and the contact image sensor 2 Instead of recognizing the contrast of the uneven character 3 directly, it is configured to recognize an image of the uneven character 3 appearing on the polymer dispersed liquid crystal 10 surface. The polymer dispersed liquid crystal 10 is made of a cylindrical roller to place the contact image sensor 2 inside the cylindrical roller.

The polymer dispersed liquid crystal 10 has a form in which the liquid crystal 14 is dispersed between the polymers 13 as shown in FIG. 4. In general, the two transparent films 11 and 11A have conductive layers 12 and 12A coated with a conductive material so as to be electrically conductive, with a layer of colorless polymer 13 interposed therebetween, and the polymer 13 The liquid crystal 14 is distributed between them. The conductive layers 12 and 12A are mainly coated with ITO (Indium Tri-Oxide) thinly by about 0.1 micron to become a transparent electrode.

The liquid crystal 14 and the polymer 13 adopt a kind similar in optical refractive index, so that the polymer dispersed liquid crystal 10 becomes transparent in a state where the liquid crystal 14 is excited, and is in a translucent to opaque state. That is, since the liquid crystals 14 are irregularly arranged in a state in which no voltage V is applied, light is scattered and becomes opaque. However, when voltage V is applied to both sides of the transparent ITO film, the liquid crystal 10 has directivity. Since the refractive index of the polymer 13 and the liquid crystal 14 becomes the same, a transmittance | permeability becomes high and becomes transparent.

5 and 6 show the characteristics of the transmittance change of the general polymer dispersed liquid crystal. In FIG. 5, the transmittance of the polymer dispersed liquid crystal 10 is proportional to the voltage V when the distance between the conductive layers 12 and 12A is constant, and becomes saturated at a constant voltage V. In FIG. 6, when the voltage across the polymer dispersed liquid crystal 10 is constant, the transmittance is inversely proportional to the thickness of the polymer dispersed liquid crystal 10.

In general, the thickness of the polymer dispersed liquid crystal 10 is several microns to several tens of microns, and even though the contact pressure with the uneven surface is not large, it causes a difference in transmittance in which a minute thickness difference caused by the unevenness is prominent.

Therefore, when the polymer dispersed liquid crystal 10 film having a transparent conductive layer is attached to the uneven characters or the sign plate and a constant voltage is applied, the distance between the ITO electrodes on both sides of the polymer dispersed liquid crystal 10 film of the uneven characters changes. It appears as a change in transmittance. The portion of the polymer dispersed liquid crystal 10 in contact with the protruding portion of the uneven character becomes more transparent and the portion not translucent to opaque.

If both polymer films of the polymer dispersed liquid crystal 10 are transparent, when a voltage is applied, the reflected image is likely to depend on the material or the reflectivity of the uneven face. Therefore, as shown in FIG. 7, the lower electrode film of the polymer dispersed liquid crystal may use a film coated with a conductive metal 15 having high reflectivity. In this case, irrespective of the material of the uneven face, the part having high transmittance, that is, the protrusion of the uneven letter has a high reflectivity by exposing the surface of the conductive metal 15 on the lower surface as it is, and the other part has a low reflectivity, It brings a high contrast.

Since the uneven characters are actually recorded on the flat plate, it is necessary for the uneven characters to continuously contact the polymer dispersed liquid crystal 10 in order for the contact image sensor 2 to scan them. To this end, if the polymer dispersed liquid crystal 10 is made of a cylindrical roller as shown in FIG. 8 so that the polymer dispersed liquid crystal 10 rolls over the uneven character array, the polymer dispersed liquid crystal 10 having a cylindrical roller shape is placed in the center of the polymer dispersed liquid crystal 10. The positioned contact image sensor 2 recognizes an image of irregularities on the polymer dispersed liquid crystal 10.

As described above, according to the present invention, a contact image sensor is formed by forming an outer layer of a contact image sensor by a material consisting of a material causing a change in transmittance by an electric field and two conductive films surrounding both sides to form an electric field therein. Instead of directly recognizing the intensity of the uneven characters, it induces to recognize the image appearing on the material surface causing the change in transmittance, thereby significantly increasing the uneven character or symbol recognition rate.

Claims (4)

The uneven characters are optically applied by applying a contact image sensor comprising a light emitting diode fixed at a position where the uneven character formed on the surface of the card is viewed, and an array sensor installed to fix a plurality of light receiving elements around the light emitting diode to have a constant arrangement. In the uneven character recognition device recognized by The uneven character recognition device, It is composed of a material that causes a change in transmittance by an electric field and two conductive films surrounding both sides to form an electric field in the material. The uneven character recognition device, characterized in that one side of the conductive film is in contact with the uneven characters or symbols to induce a change in the thickness of the material causing a change in transmittance by the contact pressure. The method of claim 1, An uneven character recognition device using a polymer dispersed liquid crystal as a material causing a change in transmittance by the electric field. The method of claim 2, Uneven character recognition device characterized in that the polymer dispersed liquid crystal is composed of a cylindrical roller. The method of claim 1, One side of the conductive film is a transparent ITO coating film, the other side of the conductive film is uneven character recognition device, characterized in that treated with a transparent ITO film or a film coated with an opaque conductive metal.