JPH03288974A - Image information reader - Google Patents

Abstract

PURPOSE:To suitably select the read of an uneven picture or a background pattern by judging the presence/absence of uneveness by two difference detecting methods such as optical detection and mechanical detection. CONSTITUTION:In addition to an uneveness reader circuit 8 to read the uneveness of a card C by turning on two light sources 3 and 4, an uneveness detection part 2 is provided to detect the presence/absence of uneveness by getting a detection end 12 contact to the uneveness of the card C and detecting the displacement of this detection end 12. Therefore, the presence/absence of uneveness can be judged by the two different detecting methods such as the optical detection and the mechanical detection. Thus, the read of the uneven picture or the background pattern can be suitably selected.

Description

DETAILED DESCRIPTION OF THE INVENTION [Industrial Application Field] The present invention relates to an image information reading device for reading an image of an object to be read, such as a plastic card, which has an uneven image or a gray-scale image.

[Conventional technology]

Conventionally, when a transaction is carried out using an automatic transaction device such as a financial institution using a plastic card such as a magnetic card, the card is engraved in order to leave evidence that can identify the card used at the time of the transaction. Processing is also carried out to read and store the embossed image (also referred to as ``embossed j'') of names, etc.

As a device that performs such reading,
Some of them are disclosed in Japanese Patent Nos. 528-6530. These devices bring the claw into contact with the unevenness of the card being transported.
The unevenness is read by detecting the displacement of the claw, but it has not been possible to identify cards without unevenness.

For this reason, it is possible to read the unevenness, and if there is no unevenness, a grayscale image (also called a "ground pattern") of the card pattern etc.
A device that can read the information is required, and such a device is disclosed, for example, in Japanese Patent Application Laid-Open No. 1-155488. Here, FIGS. 2(a) to 2(c) are explanatory diagrams showing an apparatus capable of reading unevenness and background patterns.

In this device, as shown in FIG. The reflected light L3 reflected from the card C is read by the light receiving element 24 through the lens 23.The part where the intensity of the reflected light L3 is the same is the flat part F of the card C, and the different part (when the light source 21 is irradiated, the same figure (b) The uneven image is read by determining that the shaded area shown in ) is a sloped area S of the unevenness, whereas the shaded area shown in FIG.

On the other hand, the tint block is read based on the output of the light receiving element 24 when one light source 21 (or 22) is turned on.

[Problem to be solved by the invention]

However, in the device shown in FIG. 2, when a transactable card without a concave-convex image is inserted into the device, is it actually reading a card without a concave-convex image?
Even though a card with a concave-convex image is being read, it is not possible to distinguish whether the card is mistakenly recognized as having no concave-convex image due to a device malfunction, and as a result, an inaccurate image may be stored. there were.

Therefore, the present invention has been made to solve the problems of the prior art as described above, and its purpose is to:
To provide an image information reading device capable of accurately detecting the presence or absence of a concavo-convex image, reading the concavities and convexities when there is a concave-convex image, and reading the shading of a pattern or the like on the surface of a card when there is no concave-convex image.

[Means to solve the problem]

The image information reading device according to the present invention includes two light sources disposed at different positions that generate light that is irradiated from two different directions onto an object to be read that has image information consisting of unevenness or shading on a flat surface. , a light receiving element disposed between the two light sources and receiving reflected light reflected from the object to be read, a light source control circuit driving the two light sources at different timings, and a light source control circuit that drives the two light sources alternately. An unevenness reading circuit calculates the exclusive OR of the outputs of the light receiving elements when turned on, and reads the unevenness based on the result of this calculation, and a gray level reading circuit calculates the density based on the output of the light receiving circuit when one of the light sources is turned on. An image information reading device comprising a gradation reading circuit for reading the image of the object to be read, and a selection circuit for switching image information output by selecting either the unevenness reading circuit or the shading reading circuit. It is equipped with an unevenness detection mechanism that detects the presence or absence of unevenness by contacting the unevenness, and when it is determined that there is an unevenness based on the calculation result of the unevenness reading circuit, and when the presence of unevenness is detected by the unevenness detection mechanism, the above-mentioned A selection circuit selects the unevenness reading circuit, outputs unevenness data obtained by the selected unevenness reading circuit as image information, and determines that there is no unevenness from the calculation result of the unevenness reading circuit, and detects the unevenness. The present invention is constructed by comprising a control circuit that causes the select circuit to select the shading reading circuit when the mechanism detects the absence of unevenness, and outputs shading data obtained by the selected shading reading device as image information. Ru.

[For production]

In addition to the unevenness reading circuit that reads the unevenness of the object to be read by lighting two light sources, the present invention includes an unevenness detection mechanism that contacts the unevenness of the object to be read to detect the presence or absence of the unevenness. As a result, the presence or absence of unevenness can be determined using two different detection methods, optical detection and mechanical detection.

Then, when it is determined that there is an unevenness based on the calculation result of the unevenness reading circuit, and when the presence of unevenness is detected by the unevenness detection mechanism, it is determined that the object to be read has an uneven image, and the unevenness is selected by the unevenness selection circuit. The unevenness reading circuit reads the unevenness image and outputs the unevenness data as image information.

On the other hand, when it is determined that there is no unevenness from the calculation result of the unevenness reading circuit, and when the unevenness detection mechanism detects that there is no unevenness, the selection circuit selects the grayscale reading circuit, and the unevenness image is displayed on the object to be read. It is determined that there is no pattern, and the gradation image is read by the gradation reading circuit selected by the unevenness selection circuit, and the gradation data is output as image information.

In addition, when either the calculation result of the unevenness reading circuit or the unevenness detection mechanism determines that there is an uneven image, and the other determines that there is no unevenness, processing such as re-reading can be selected,
Prevents output of inaccurate images.

〔Example〕

The present invention will be explained below based on illustrated embodiments.

FIG. 1 is a block diagram showing the configuration of an embodiment of an image information reading device according to the present invention.

As shown in the figure, the image information reading device of this embodiment has an image reading unit that optically reads image information consisting of unevenness or shading formed on the flat surface of a plus square card C as an object to be read. 1, and an unevenness detection section 2 that mechanically detects the unevenness of the card C.

The image reading unit 1 has two light sources 3 and 4 placed at different positions that emit light from two different directions onto the surface of the card C, and these two light sources are emitted at different times. A light source control circuit 5 for driving the light source is provided.

The image reading unit 1 also includes a light receiving element 6 that is placed between the two light sources 3.4 and receives the reflected light from the card C, and a light receiving element 6 that converts the analog output of the light receiving element 6 into a digital signal. An A/D converter 7 is also provided.

Furthermore, the image reading unit 1 includes an unevenness reading circuit 8 that calculates an exclusive OR of the outputs of the light receiving element 6 when the two light sources 3.4 are turned on alternately, and reads the unevenness based on the calculation result. , a shading reading circuit 9 that reads the shading (forgery-inhibited pattern) on the card surface based on the output of the light receiving element 6 when one of the light sources is turned on, and an output by selecting either the unevenness reading circuit 8 or the shading reading circuit 9. It is provided with a select circuit 10 for switching the image information to be displayed, and a memory 11 for storing the output image information.

On the other hand, the unevenness detection section 2 includes a detection end 12 that rotates in contact with a card C that is conveyed in the insertion direction (direction A) along a guide mechanism (not shown), and a detection end 12 that rotates in contact with a card C that is conveyed in the insertion direction (direction A) along a guide mechanism (not shown), and a protrusion that is above a certain height (or a certain a displacement detector 13 that detects the amount of displacement when the detection end 12 is displaced by a recess (with a depth greater than or equal to the depth of the recess); an amplifier 14 that amplifies the output of the displacement detector 13; A comparator 15 is provided to compare the value. Note that the detection end 12 that contacts the card C is arranged near the insertion opening on the conveyance path for conveying the card C.

Further, 16 is a CPU as a control circuit that controls the operation of this embodiment, and controls the operation of the selection circuit 10 based on the output of the unevenness detection section 2 and the output of the unevenness reading circuit 8.

FIG. 3 is a flowchart showing the operation of this embodiment.

The operation of this embodiment will be explained based on this figure and FIG. 1.

First, in step 1, the presence or absence of unevenness on the inserted card C is detected by the unevenness detection section 2, and in step 2, the unevenness is read by the unevenness reading circuit 8 using an alternate lighting method. The reading method in this case is the same as the conventional case shown in FIG. Detects the unevenness of the surface and reads the unevenness.

In step 3, the unevenness detection unit 2 detects the presence of unevenness, and
When it is determined that there is an unevenness based on the calculation result of the unevenness reading circuit 8, the process proceeds to step 4, where the selection circuit 10 selects the unevenness reading circuit 8, and the unevenness data obtained by the selected unevenness reading circuit 8 is used as image information. Output to memory 11.

On the other hand, in the case of No in step 3, the process proceeds to step 5, where it is determined whether the unevenness detection unit 2 detects the absence of unevenness and the calculation result of the unevenness reading circuit 8 determines that there is no unevenness. In some cases, proceed to step 6. In step 6, single-lighting reading is performed, the select circuit 10 selects the gradation reading circuit 9, and the gradation data obtained by the gradation reading circuit 9 selected in step 7 is output to the memory 11 as image information.

Furthermore, if the determination in step 5 is NO, that is,
If either the calculation result of the unevenness reading circuit 8 or the unevenness detection unit 2 determines that there is an uneven image and the other determines that there is no unevenness, the process proceeds to step 8.

In step 8, return the card to near the insertion slot,
The card is transported again in the insertion direction, and the unevenness of the card is mechanically detected by the unevenness detection section 2, and then optically detected by the image reading section 1, and the same judgment as in step 3 and step 5 is made. . As a result, if the results of the presence or absence of unevenness match (if there is no contradiction in both detection results), it is recognized as normal operation, the step is YES, and the process proceeds to step 3.

On the other hand, in the case of No in step 9, it is determined that there is a failure in the image reading section 1 or the unevenness detection section 2, and for example, in the case of a card with a magnetic stripe, transactions are performed using only the magnetic stripe data of the card being handled. Perform degraded operation to continue.

As described above, in this embodiment, two light sources 3
．． In addition to the unevenness reading circuit 8 that reads the unevenness of the card C by lighting up the unevenness reading circuit 8, the unevenness reading circuit 8 detects the presence or absence of unevenness by bringing the detection end 12 into contact with the unevenness of the card C and detecting the displacement of this detection@12. By providing the detection unit 2, the structure is such that the presence or absence of unevenness can be determined by two different detection methods, optical detection and mechanical detection. Then, when it is determined that there is an unevenness based on the calculation result of the unevenness reading circuit 8, and when the presence of unevenness is detected by the unevenness detection section 2, the unevenness reading circuit 8 reads the unevenness image and outputs the unevenness data as image information. On the other hand, when it is determined that there is no unevenness from the calculation result of the unevenness reading circuit 8, and when the unevenness detection section 2 detects that there is no unevenness, the grayscale reading circuit 9 reads the grayscale image and outputs the grayscale data as image information. do.

In addition, the calculation result of the unevenness reading circuit 8 or the unevenness detection section 2
When it is determined that one of the detection results indicates that an uneven image exists and the other indicates that there is no uneven image, for example, processing such as re-reading can be selected. Therefore, since the unevenness of the card is detected using two different detection methods, it is possible to appropriately select the reading of the uneven image or the tint block, and it is possible to prevent inaccurate image reading due to device failure or the like.

〔Effect of the invention〕

As described above, according to the present invention, in addition to the unevenness reading circuit that reads the unevenness of the object to be read by lighting two light sources, the unevenness detection mechanism that mechanically detects the unevenness of the object to be read is provided. Accordingly, the structure is such that the presence or absence of irregularities can be determined using two different detection methods, optical detection and mechanical detection. Therefore, when both the unevenness reading circuit and the unevenness detection mechanism detect the presence of unevenness, the unevenness image is read, and on the other hand, when the unevenness reading circuit and the unevenness detection mechanism detect no unevenness, the gradation reading circuit reads the unevenness image. Can read images.

Furthermore, when either the unevenness reading circuit or the detection result of the unevenness detection section determines that an uneven image exists and the other determines that there is no uneven image, processing such as re-reading can be selected, for example. In this way, since the unevenness of the card is detected using two different detection methods, it is possible to appropriately select the reading of the uneven image or the tint block, and it is also possible to prevent inaccurate image reading due to device failure or the like.

[Brief explanation of the drawing]

FIG. 1 is a block diagram showing the configuration of an embodiment of an image information reading device according to the present invention, FIGS. 2(a) to (c) are explanatory diagrams showing a conventional reading device, and FIG. 3 is an embodiment of the present invention. 3 is a flowchart showing the operation of FIG. 1... Image reading unit 2... Unevenness detection unit 3.4... Light source 5... Light source control circuit 6... Light receiving element 7... A/D converter 8... Unevenness reading circuit 9... Concentration reading circuit 10... Select circuit 11... Memory 12... Detecting end 13... Displacement detector 14... Amplifier 15... Comparator 16... CPU

Claims (1)

[Scope of Claims] Two light sources disposed at different positions that generate light irradiated from two different directions onto an object to be read that has image information consisting of unevenness or shading on a flat surface; a light receiving element disposed between the light sources and receiving the reflected light reflected from the object to be read; a light source control circuit driving the two light sources at different timings; and when the two light sources are turned on alternately. an unevenness reading circuit that calculates an exclusive OR of the outputs of the light receiving elements and reads the unevenness based on the calculation result; and a grayscale reading circuit that reads the shading based on the output of the light receiving element when one of the light sources is turned on. and a selection circuit that switches image information to be output by selecting one of the unevenness reading circuit or the grayscale reading circuit, wherein the image information reading device includes: an unevenness detection mechanism for detecting the presence or absence of unevenness, and when the presence of unevenness is determined from the calculation result of the unevenness reading circuit and the presence of unevenness is detected by the unevenness detection mechanism, the selection circuit An unevenness reading circuit is selected, unevenness data obtained by the selected unevenness reading circuit is outputted as image information, and it is determined that there is no unevenness based on the calculation result of the unevenness reading circuit, and the unevenness detection mechanism determines that there is no unevenness. An image information reading device comprising: a control circuit that causes the selection circuit to select the grayscale reading circuit when the grayscale reading device is detected, and outputs grayscale data obtained by the selected grayscale reading device as image information. Device.