JP2004355263A - Image detector for paper currency - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an image detector for paper currency which enables cost reduction. <P>SOLUTION: This image detector for a paper currency has a light emitting means 31 (31X), a light emitting means 27 (27X), a light emitting means 31 (31Y), and a light emitting means 27 (27Y). The light emitting means 31 (31X) is arranged oppositely to an image detecting sensor 24 (24X), and emits one wavelength band of light beam toward a paper currency S to detect transmission light in the paper currency S by the image detecting sensor 24 (24X). The light emitting means 27 (27X) is arranged at the same side as the image detecting sensor 24 (24X), and emits a plurality of light beams different in wavelength bands toward the paper currency S to detect reflection light thereof by the image detecting sensor 24 (24X). The light emitting means 31 (31Y) is arranged oppositely to an image detecting sensor 24 (24Y) at the opposite side of the image detecting sensor 24 (24X), and emits another wavelength band of light beam toward the paper currency S to detect transmission light in the paper currency S by the image detecting sensor 24 (24Y). The light emitting means 27 (27Y) is arranged at the same side as the image detecting sensor 24 (24Y), and emits a plurality of light beams different in wavelength bands toward the paper currency S to detect reflection light thereof by the image detecting sensor 24 (24Y). <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to a bill image detecting device used for distinguishing bills.
[0002]
[Prior art]
For example, as a technology related to a bill image detecting device used when discriminating whether a bill is true or false, a denomination, a stain, and the like, irradiating light toward a bill from a light emitting unit disposed on one side of a bill conveyance path, The transmitted light is detected by a light receiving unit arranged on the opposite side to the bill transport path, and light is emitted toward the bill from the light emitting unit arranged on one side of the bill transport path of the light emitting and receiving unit In some cases, the reflected light is detected by a light receiving unit of the simultaneous light receiving unit (for example, see Patent Document 1). Further, a technique relating to an image sensor module used in such a bill image detecting device is also disclosed (for example, see Patent Document 2).
[0003]
[Patent Document 1]
JP 2001-357429 A
[Patent Document 2]
Japanese Patent No. 3099077
[0004]
[Problems to be solved by the invention]
In the discrimination of banknote authenticity, denomination, contamination, etc., in order to enhance the discrimination accuracy, discrimination is performed for each of the image on one side of the banknote, the image on the opposite side of the banknote and the transparent image on the front and back of the banknote. In some cases, the banknote image detecting device disclosed in Patent Document 1 is used to detect an image on one side of the front and back sides of the banknote. 1st light emitting and receiving unit which has a 1st image detection sensor and a 1st light emitting body for the 2nd image detection sensor and a 2nd light emitting body for the detection of the image of the front and back direction reverse side of a banknote , A light emitting unit having a third light emitter for detecting transmitted images on the front and back of the bill, and a light receiving unit having a third image detection sensor are required. Three for Cost for the image detection sensor is provided there is a problem that increases.
[0005]
Therefore, an object of the present invention is to provide a bill image detecting device capable of reducing costs.
[0006]
[Means for Solving the Problems]
In order to achieve the above object, the invention according to claim 1 is arranged such that the first image detection sensor and the first image detection sensor are opposed to each other across the bill conveyance path and are conveyed along the bill conveyance path. A first light emitting means for irradiating light in one wavelength region toward a bill to be transmitted and detecting the transmitted light of the light with the bill by the first image detection sensor; and The first image detection sensor is provided on the same side as the first image detection sensor and emits light in a plurality of different wavelength regions toward a bill conveyed in the bill conveyance path, and detects light reflected from the bill on the first image. A second light emitting unit that is detected by a sensor, a second image detection sensor provided on a side opposite to the first image detection sensor with respect to the bill conveyance path, and a second image detection sensor that sandwiches the bill conveyance path. And the bill is disposed opposite to the second image detection sensor. A third method in which light of another wavelength region different from that of the first light emitting unit is irradiated toward a bill conveyed in a feed path, and light transmitted through the bill is detected by the second image detection sensor. Irradiating a plurality of different wavelength regions of light toward bills provided on the same side of the bill transport path as the second image detection sensor and transported on the bill transport path. And a fourth light emitting means for detecting the reflected light from the bill by the second image detection sensor.
[0007]
Thus, when the first light emitting unit irradiates light in one wavelength region toward the banknote in the banknote transport path, the first image detection sensor opposed to the banknote transport path across the banknote transport path transmits light transmitted through the banknote. That is, the transmitted images on the front and back are detected. When the second light emitting means disposed on the same side of the bill transport path as the first image detection sensor irradiates the bills in the bill transport path with light in a plurality of different wavelength regions, the reflected light That is, the first image detection sensor detects the reflection image on one side in the front and back directions. Further, the third light emitting means facing the second image detection sensor provided on the side opposite to the first image detection sensor with respect to the bill transport path, the first light emitting means facing the bill in the bill transport path. When light of another wavelength region different from the above is irradiated, the second image detection sensor detects light transmitted through the bill, that is, transmitted images on the front and back. In addition, when the second image detection sensor and the third light emitting means disposed on the same side of the bill transport path irradiate the bills in the bill transport path with light in a plurality of different wavelength regions, the reflected light That is, the second image detection sensor detects the reflection image on the opposite side of the front and back directions. This makes it possible to detect an image on one side of the banknote in the front and back direction, an image on the opposite side of the banknote in the front and back direction, and a transmission image on the front and back of the banknote, respectively, when light in a plurality of wavelength regions is irradiated. As a result, the discrimination accuracy can be improved. Then, as described above, only two image detection sensors, the first image detection sensor and the second image detection sensor, are required.
[0008]
According to a second aspect of the present invention, in the first aspect of the present invention, light of the one wavelength region is emitted at a predetermined timing from the first light emitting means, and a plurality of different wavelength regions are emitted from the second light emitting means. Are emitted at different timings and at different timings from the first light emitting means, and the first image detection sensor is synchronized with each light emission of the first light emitting means and the second light emitting means. A first capture control unit that captures a plurality of image data detected in step 1 into a first image memory area; and a light source that emits the light of the other wavelength region at a predetermined timing from the third light emitting unit. The light emitting means emits light in a plurality of different wavelength regions at different timings and at different timings from the third light emitting means. And second capture control means for capturing a plurality of image data detected by the second image detection sensor into a second image memory area in synchronization with each light emission of the fourth light emitting means. It is characterized by.
[0009]
Thus, the first capture control unit causes the first light emitting unit to emit light in one wavelength region, and the second light emitting unit emits light in a plurality of different wavelength regions at different timings and at the first timing. The first light emitting means and the second light emitting means emit light at a different timing from the light emitting means, and the first image detecting sensor detects image data in synchronization with each light emission of the first light emitting means and the second light emitting means. While capturing the plurality of detected image data into the first image memory area, the second capture control unit causes the third light emitting unit to emit light in another wavelength region different from the first light emitting unit, The fourth light-emitting means emits light in a plurality of different wavelength regions at different timings and at different timings from the third light-emitting means, and the third light-emitting means and the fourth light-emitting means To detect the image data by the second image detection sensor in synchronization to each light emission capturing a plurality of image data detected by the second image detection sensor of the second image memory area. As described above, the first capture control means is provided for the first image detection sensor, and the second capture control means is provided for the second image detection sensor. The detection timing of the image of the second image detection sensor can be superimposed on the detection timing of the image data of the sensor.
[0010]
According to a third aspect of the present invention, in the second aspect of the invention, the first capture control means and the second capture control means provide the second image capture sensor with the second image capture timing at the image detection timing of the first image detection sensor. This is characterized in that the detection timings of the images by the image detection sensors are overlapped.
[0011]
As described above, since the detection timing of the image of the second image detection sensor can be superimposed on the detection timing of the image of the first image detection sensor, more data can be transferred to the bill moving at the same transport speed. Detection can be performed, and the accuracy of determination can be further increased.
[0012]
According to a fourth aspect of the present invention, in the first aspect of the present invention, light of the one wavelength region is emitted from the first light emitting unit at a predetermined timing, and a plurality of different wavelength regions are emitted from the second light emitting unit. Are emitted at different timings and at different timings from the first light-emitting means, and light in the other wavelength region is further transmitted from the third light-emitting means to the first light-emitting means and the second light-emitting means. Light is emitted at a different timing from the light emitting means, and light in a plurality of different wavelength regions is emitted from the fourth light emitting means at different timings respectively, and the first light emitting means, the second light emitting means, and the third light emitting The first light emitting means and the second light emitting means emit light at a timing different from that of the first light emitting means, and are detected by the first image detecting sensor in synchronization with each light emission of the first light emitting means and the second light emitting means. A single image data area and a plurality of image data detected by the second image detection sensor in synchronism with each light emission of the third light emitting means and the fourth light emitting means are taken into a single image memory area. It is characterized by having capture control means.
[0013]
Accordingly, the single capture control unit causes the first light emitting unit to emit light in one wavelength region, and the second light emitting unit emits light in a plurality of different wavelength regions at different timings and at the first timing. The light emitting means emits light at a different timing, and the third light emitting means emits light in another wavelength region different from the first light emitting means at a different timing from the first light emitting means and the second light emitting means. Further, the fourth light-emitting means emits light in a plurality of different wavelength ranges at different timings and at different timings from the first light-emitting means, the second light-emitting means, and the third light-emitting means. The plurality of image data detected by the first image detection sensor and the respective light emission of the third light emitting means and the fourth light emitting means in synchronization with each light emission of the means and the second light emitting means, respectively. Capturing a plurality of image data detected by the second image detection sensor of the image memory area. Thus, only one capture control means is required for the first image detection sensor and the second image detection sensor.
[0014]
The invention according to claim 5 is the invention according to claim 4, wherein the first light-emitting group including the first light-emitting means and the second light-emitting means, the third light-emitting means, and the fourth light-emitting means. It is characterized in that light is emitted alternately for each group with the second group comprising the means.
[0015]
As described above, the first light emitting group including the first light emitting unit and the second light emitting unit according to the first image detecting sensor, and the third light emitting unit and the fourth light emitting according to the second image detecting sensor. The first light emitting means, the second light emitting means, and the third light emitting means are provided so as to alternately emit light for each group between the first light emitting means, the second light emitting means, and the second light emitting means. The light emission time of each of the means and the fourth light emitting means can be lengthened.
[0016]
The invention according to claim 6 is the invention according to any one of claims 1 to 5, wherein each of the second light emitting means and the fourth light emitting means emits light in two different wavelength regions. It is characterized by:
[0017]
As described above, since each of the first light emitting unit and the third light emitting unit, the second light emitting unit, and the fourth light emitting unit emit light in two different wavelength regions, the discrimination accuracy is improved. Can be done.
[0018]
The invention according to claim 7 is the invention according to claim 6, wherein each of the second light emitting means and the fourth light emitting means emits any one of visible light, infrared light, and ultraviolet light. And the first light emitting means and the third light emitting means emit any one of visible light, infrared light and ultraviolet light.
[0019]
As described above, each of the first light emitting unit and the third light emitting unit, the second light emitting unit, and the fourth light emitting unit is provided with any one of visible light, infrared light, and ultraviolet light. Since the light is irradiated, the difference between the image data can be emphasized.
[0020]
The invention according to claim 8 is the invention according to any one of claims 1 to 5, wherein each of the second light emitting unit and the fourth light emitting unit emits light in three different wavelength regions. In addition, the third light emitting means emits light in two other wavelength ranges different from the first light emitting means.
[0021]
As described above, since each of the first light emitting means and the third light emitting means, the second light emitting means, and the fourth light emitting means emit light in three different wavelength regions, the discrimination accuracy is further improved. Can be improved.
[0022]
The invention according to claim 9 is the invention according to claim 8, wherein each of the second light emitting means and the fourth light emitting means emits visible light, infrared light, and ultraviolet light, and The light emitting means emits any one of visible light, infrared light and ultraviolet light, and the third light emitting means emits any two of visible light, infrared light and ultraviolet light. It is characterized by irradiating light.
[0023]
As described above, each of the first light emitting unit and the third light emitting unit, the second light emitting unit, and the fourth light emitting unit emits three lights of visible light, infrared light, and ultraviolet light. Therefore, the difference between the image data can be emphasized, and the number of comparisons can be increased.
[0024]
BEST MODE FOR CARRYING OUT THE INVENTION
A bill image detecting device according to a first embodiment of the present invention will be described below with reference to FIGS.
As shown in FIG. 1, the banknote image detection device 11 of the first embodiment includes a pair of identically configured detection units 13 that are disposed on both sides of a banknote conveyance path 12 that conveys a banknote S linearly. are doing.
[0025]
The detection unit 13 has a dimension in the length direction (the direction perpendicular to the paper surface in FIG. 1) that is considerably larger than the dimension in the thickness direction (the vertical direction in FIG. 1) and the dimension in the width direction (the horizontal direction in FIG. 1). It has an elongated shape. The detection unit 13 includes an elongated box-shaped storage body 16 provided with an opening 15 on one side in the thickness direction of the detection unit 13, and an elongated plate attached to the storage body 16 so as to close the opening 15. And a unit main body 18 composed of a light-transmitting cover 17 having a rectangular shape. Since the unit main body 18 constitutes an outer portion of the detection unit 13, the length direction, the thickness direction, and the width direction match the detection unit 13.
[0026]
The translucent cover 17 is formed of a transparent material such as glass, and has projections 20 formed on both sides in the width direction on the side where the housing 16 is attached, and on the surface 19 side opposite to the housing 16. The mirror has a mirror-symmetrical shape in which chamfers 21 are formed at both ends in the width direction so as to be inclined such that the thickness becomes thinner toward the tip. Note that by fitting the housing 16 inside the portion of the light-transmitting cover 17 surrounded by the projections 20, the light-transmitting cover 17 and the housing 16 are joined in a positioned state.
[0027]
In the unit body 18, a CCD sensor (image detection sensor) 24 is arranged on one side in the width direction and on the opposite side to the light transmitting cover 17. Like the unit main body 18, the CCD sensor 24 has an elongated shape, and is attached to the housing 16 of the unit main body 18 with its length direction coinciding with the length direction of the unit main body 18. The CCD sensor 24 has its image detection direction directed toward the light transmitting cover 17 along the thickness direction of the unit body 18. Note that the length of the CCD sensor 24 is longer than the length of the maximum length bill S to be handled.
[0028]
In the unit main body 18, an elongated fiber lens array (lens body) 25 is arranged in parallel with the CCD sensor 24 on the side of the light-transmitting cover 17 which is on the front side in the detection direction of the CCD sensor 24. The fiber lens array 25 is attached to the housing 16 of the unit main body 18 in a state where the positions in the width direction and the length direction of the unit main body 18 are entirely overlapped with the CCD sensor 24. In addition, the length of the fiber lens array 25 is also longer than the length of the maximum length bill S to be handled.
[0029]
Here, the CCD sensor 24 moves the first detection area (first detection area), which is the detection area of the image captured via the fiber lens array 25, outward by a predetermined amount from the light-transmitting cover 17 on the front side in the detection direction. 1 (in FIG. 1, the first detection area for the lower detection unit 13 in the figure is denoted by Z1, and the first detection area for the upper detection unit 13 in the figure is denoted by Z1 '). The line connecting the sensor and the CCD sensor 24 is orthogonal to the surface 19. Note that the first detection area also has an elongated shape in the length direction of the unit body 18 as a matter of course. As described above, the CCD sensor 24 detects the image of the first detection area set outside the light-transmitting cover 17 which is one side of the unit main body 18, and the first detection area and the CCD sensor 24 The fiber lens array 25 is arranged in the unit main body 18 between them.
[0030]
Inside the unit main body 18, an elongated light emitter 27 irradiating light obliquely toward the first detection area is provided inside the fiber lens array 25 in the width direction thereof in parallel with the CCD sensor 24 and the fiber lens array 25. (In FIG. 1, the direction of light is indicated by a broken line). The light emitter 27 is attached to the housing 16 of the unit main body 18 in a state where the position in the length direction of the unit main body 18 is entirely overlapped with the CCD sensor 24 and the fiber lens array 25.
[0031]
The luminous body 27 has a length substantially equal to or greater than that of the CCD sensor 24 and a light guide body 28 made of a transparent material such as glass having an elongated shape and arranged in parallel with the CCD sensor 24, as shown in FIG. A pair of rectangular mounting plate portions 30 formed at both ends in the length direction of the light guide body 28 so as to extend perpendicularly to the length direction are provided on the respective outer end surfaces, and light is emitted from both end sides. A light-emitting element 29 made of a semiconductor element for irradiating the inside of the guide body 28 is provided. In addition, the length of the luminous body 27 is also longer than the length of the maximum length bill S to be handled.
[0032]
In the unit main body 18, the light-emitting body 27 in the width direction is opposite to the fiber lens array 25, and is parallel to and transparent to the first detection area set at a position different from the first detection area. An elongated light emitter 31 is provided in parallel with the light emitter 27, the CCD sensor 24, and the fiber lens array 25 to irradiate light straight toward a second detection area (second detection area) having the same distance from the cover 17. (In FIG. 1, the second detection area for the lower detection unit 13 in the figure is indicated by Z2, and the second detection area for the upper detection unit 13 in the figure is indicated by Z2 '). The light emitter 31 is attached to the housing 16 of the unit main body 18 in a state where the position in the length direction of the unit main body 18 is entirely overlapped with the light emitter 27, the CCD sensor 24, and the fiber lens array 25. The light-emitting body 31 has a second detection area set outside the light-transmitting cover 17 by a predetermined amount along the thickness direction of the unit body 18, and irradiates light in this direction.
[0033]
The light-emitting body 31 is also approximately the same length or longer than the CCD sensor 24 and has a light guide body 32 made of a transparent material such as elongated glass that is disposed in parallel with the CCD sensor 24, and as shown in FIG. A pair of rectangular mounting plate portions 34 formed at both ends in the length direction of the light guide body 32 so as to extend orthogonally to the length direction are provided on the respective outer end surfaces, and light is emitted from both ends. And a light emitting element 33 made of a semiconductor element for irradiating the inside of the guide body 32. In addition, the length of the light emitting body 31 is also longer than the length of the bill S of the maximum length to be handled.
[0034]
Here, the distance from the one end of the unit main body 18 in the width direction on the first detection area side to the first detection area, and the second detection from the other end of the unit main body 18 on the second detection area side in the width direction. The distance to the area is set equal.
[0035]
The luminous body 27 and the luminous body 31 will be further described.
In the light-emitting body 27, the light-emitting elements 29 provided on each end face in the length direction are capable of irradiating the light guide body 28 with light having a plurality of, specifically, three different wavelength regions, each having a desired wavelength. A plurality of, specifically, three LED elements (light emitting element sections) 29A, 29B, 29C capable of independently irradiating the light of the area are connected to the terminal sections 29a, 29b, 29c and the common electrode terminal 29d by wire bonding or the like. . By selecting the terminal portions 29a to 29c for applying a voltage to the common electrode terminal 29d, the LED elements 29A to 29C can be switched to emit light. Then, by selecting the emission wavelengths of the LED elements 29A to 29C, it is possible to irradiate light in any three wavelength regions of visible light, ultraviolet light, and infrared light of a plurality of colors such as RGB.
[0036]
Here, the light-emitting elements 29 on both sides will be described as those in which each of the LED elements 29A to 29C that overlaps in a plane direction orthogonal to the length direction of the light guide body 28 emits light in the same wavelength region. However, it is not essential that the LED elements 29A to 29C in the opposing regions emit light in the same wavelength region.
Further, the wavelength region of light emitted by the three LED elements 29A to 29C on one end face and the wavelength region of light emitted by the three LED elements 29A to 29C on the other end face are a combination of light in three wavelength regions. Is not essential, and it is possible to emit light in up to six wavelength ranges.
[0037]
Also in the light emitting body 31, the light emitting elements 33 provided on each end face can irradiate a plurality of, specifically, three different wavelength regions of light into the light guide body 32, each of which has a desired wavelength region. , And specifically, three LED elements (light emitting element sections) 33A, 33B, 33C are connected to the terminal sections 33a, 33b, 33c and the common electrode terminal 33d by wire bonding or the like. By selecting the terminal sections 33a to 33c for applying a voltage between the common electrode terminal 33d and the common electrode terminal 33d, the LED elements 33A to 33C can be switched to emit light. Then, by selecting the emission wavelengths of the LED elements 33A to 33C, it is possible to irradiate light in any three wavelength regions of visible light, ultraviolet light, and infrared light of a plurality of colors such as RGB.
[0038]
In the first embodiment, as described later, each of the light emitters 27 and 31 emits only a plurality of light beams, specifically, light in two different wavelength regions. If only two of the LED elements 29C emit light, or if the light in a certain wavelength region is weak, it is possible to emit a plurality of light in the wavelength region of the LED elements 29A to 29C and emit the remaining one. Similarly, in the luminous body 31, when only two of the three LED elements 33A to 33C emit light, or when the light in a certain wavelength region is weak, a plurality of the LED elements 33A to 33C emit light in that wavelength region and the remaining one is emitted. Light emission.
[0039]
The housing 16 has a bottom wall 35 formed therein to prevent light from the light emitters 27 and 31 from leaking to the CCD sensor 24. An opening 36 is formed only on the front side in the detection direction of the sensor 24, and the fiber lens array 25 is attached so as to cover the opening 36. Further, the housing 16 has a side wall portion 37 for preventing light leakage of the light emitters 27 and 31 to the fiber lens array 25 and a light leakage between the light emitters 27 and 31 is prevented. And a side wall portion 38 to be formed.
[0040]
On the other hand, the above-described banknote transport path 12 transports the banknote S straight and linearly in a posture in which the length direction is orthogonal to the transport direction and the width direction thereof is along the transport direction. The length direction of the bill S is arranged in a direction orthogonal to the bill, and the bill S is conveyed in the left-right direction of the paper, for example, from left to right on the paper along the width direction of the bill S in the left-right direction of the paper.
[0041]
The bill image detecting device 11 includes a CCD sensor 24 that detects an image of the first detection area set on one side of the unit main body 18 as described above, and a light emitting body that irradiates light to the first detection area. 27, and a light-emitting body 31 for irradiating light to a second detection area set at a position different from the first detection area on the one side of the unit main body 18 is arranged in the unit main body 18. A pair of the detection units 13 are arranged so as to be opposed to each other across the banknote transport path 12 so that the CCD sensor 24 of the one detection unit 13 can detect an image of the second detection area of the other detection unit 13. At this time, the pair of detection units 13 make the surface portions 19 of the translucent cover 17 face each other in a state parallel to the bill transport path 12.
[0042]
In other words, the one detection unit 13 is arranged on one side of the banknote transport path 12 with the translucent cover 17 facing the banknote transport path 12 side, and the detection unit 13 is placed around an axis along the length direction. The other detection unit 13 is disposed on the opposite side with respect to the banknote transport path 12 in a posture corresponding to the state of being inverted by 180 degrees, and the detection direction of the CCD sensor 24 of the one detection unit 13 and the detection of the other The light irradiation direction of the light emitting body 31 of the unit 13 is matched. In other words, for example, the CCD sensor 24 of the lower detection unit 13 in FIG. 1 can detect the image of the second detection area Z2 ′ of the upper detection unit 13 in FIG. The detection area Z2 'overlaps), and the CCD sensor 24 of the upper detection unit 13 in FIG. 1 can detect the image of the second detection area Z2 of the lower detection unit 13 in FIG. 1 (FIG. 1). The pair of detection units 13 is arranged so that the second detection area Z2 overlaps the first detection area Z1 ′).
[0043]
At this time, the pair of detection units 13 match the positions in the length direction with each other, and match the width direction with the bill conveyance direction of the bill conveyance path 12. Note that the pair of detection units 13 are positioned with respect to the banknote transport path 12 so that the entire image in the length direction of the banknote S transported along the transport direction in the banknote transport path 12 can be detected. Is set. That is, the pair of detection units 13 overlaps the entire length of the bill S conveyed in the bill conveyance path 12 with the CCD sensor 24, the fiber lens array 25, the luminous body 27, and the inside area in the longitudinal direction of the luminous body 31. The position with respect to the bill transport path 12 is set so as to match.
[0044]
Here, as described above, the distance from one end on the first detection area side in the width direction of the unit main body 18 to the first detection area, and the other end on the second detection area side in the width direction of the unit main body 18 Since the distance from to the second detection area is set to be equal, the pair of detection units 13 match the positions in the width direction.
[0045]
As a result, the pair of detection units 13 dispose the CCD sensors 24 on opposite sides in the bill transport direction of the bill transport path 12, and on the bill transport path 12 side of the translucent cover 17 of the unit main body 18, A chamfered portion 21 as a symmetrical guide portion for guiding the introduction of the bill S conveyed through the bill conveyance path 12 is formed at both ends of the bill conveyance path 12 in the bill conveyance direction.
[0046]
In such a bill image detecting device 11, the CCD sensor 24 of the one detecting unit 13 of the pair of detecting units 13 opposed to each other with the bill transport path 12 interposed therebetween emits light of the other detecting unit 13. The image of the second detection area irradiated with light at 31, that is, the transmission image of the front and back is detected by scanning in the length direction, and the transmission image of such front and back is obtained at a plurality of timings during the conveyance of the banknote S. To detect.
[0047]
The CCD sensor 24 of the other detection unit 13 of the pair of detection units 13 that are opposed to each other with the bill transport path 12 interposed therebetween is also irradiated with light by the light-emitting body 31 of the one detection unit 13. The image of the two detection areas, that is, the front and back transmission images are scanned and detected in the length direction, and such front and back transmission images are detected at a plurality of timings during the conveyance of the banknote S.
[0048]
In addition, the banknote image detecting device 11 includes an image of the first detection area where the CCD sensor 24 of one of the pair of detection units 13 is irradiated with light by the luminous body 27 of the detection unit 13. That is, the reflection image on one side in the front and back direction is detected by scanning in the length direction, and such a reflection image on one side in the front and back direction is detected at a plurality of timings during the conveyance of the banknote S.
[0049]
Further, the banknote image detection device 11 is configured such that the CCD sensor 24 of the opposite detection unit 13 lengthens the image of the first detection area where light is emitted by the light emitting body 27 of the detection unit 13, that is, the reflection image on the opposite side of the front and back directions. The reflected image on the opposite side in the front and back direction is detected at a plurality of timings during the conveyance of the bill S.
[0050]
Then, the banknote image detection device 11 compares the front and back transmission image data, the front and back direction one side reflection image data and the front and back direction reverse side reflection image data with, for example, master data, respectively, and compares the authenticity, denomination and contamination. It has an identification means 46 shown in FIG.
[0051]
Next, the control system of the banknote image detecting device 11 will be described. The CCD sensor 24 of the upper detection unit 13 as a first image detecting sensor is a first CCD sensor 24 (24X) for distinction, and the banknote transport path is used. The first CCD sensor 24 (24X) is disposed opposite to the first CCD sensor 24 (24X), and is irradiated with light in one wavelength region toward the bill S conveyed through the bill conveyance path 12, and the transmitted light of the light is transmitted to the bill S. The luminous body 31 of the lower detection unit 13 as the first luminous means detected by one CCD sensor 24 (24X) is referred to as a first luminous body 31 (31X) for distinction.
[0052]
In addition, a plurality of light beams, specifically two different wavelength regions, are radiated toward the bill S provided on the same side of the bill transport path 12 as the first CCD sensor 24 (24X) and transported in the bill transport path 12. The second light-emitting body 27 (27X) for distinguishing the light-emitting body 27 of the upper detection unit 13 as a second light-emitting means for detecting the reflected light from the bill S with the first CCD sensor 24 (24X). And
[0053]
Further, the second CCD sensor for distinguishing the CCD sensor 24 of the lower detection unit 13 as a second image detection sensor provided on the opposite side of the bill transport path 12 from the first CCD sensor 24 (24X). 24 (24Y), which is disposed opposite to the second CCD sensor 24 (24Y) with the bill transport path 12 interposed therebetween, and is different from the first light emitter 31 (31X) toward the bill S transported in the bill transport path 12. The light emitting body 31 of the upper detection unit 13 as the third light emitting means for irradiating light of another wavelength region and detecting the light transmitted through the bill S by the second CCD sensor 24 (24Y) is used for distinction. The third light emitter 31 (31Y) is used.
[0054]
In addition, a plurality of light beams, specifically two different wavelength regions, are provided toward the bill S that is provided on the same side of the bill transport path 12 as the second CCD sensor 24 (24Y) and is transported in the bill transport path 12. The fourth illuminant 27 for distinguishing the illuminant 27 of the lower detection unit 13 as fourth illuminating means for irradiating the reflected light from the bill S with the second CCD sensor 24 (24Y). 27Y).
[0055]
Then, in the first embodiment, as shown in FIG. 3, only light of one wavelength region is emitted from the first light emitter 31 (31X) by, for example, driving the LED element 33A, and the second light emitter 27 (27X) is driven. Accordingly, a plurality of light beams, specifically two different wavelength regions, are emitted at different timings and at different timings from the first light emitting body 31 (31X), for example, by driving the LED elements 29A and 29B. 31 (31X) and a plurality of image data, specifically three image data detected by the first CCD sensor 24 (24X) and AD-converted by the AD converter 41 at detection timings synchronized with the respective light emission of the second light-emitting bodies 27 (27X). Capture control means (first capture control means) 43 for capturing the image data into the first image memory area of the memory 42.
[0056]
In the first embodiment, only light in another wavelength region different from the third light emitting body 31 (31Y) to the first light emitting body 31 (31X) is emitted by, for example, driving the LED element 33B. A plurality of light beams, specifically two different wavelength regions, are emitted from the four light emitters 27 (27Y) at different timings, for example, by driving the LED elements 29A and 29B. The plurality of image data, specifically three image data detected by the second CCD sensor 24 (24Y) and AD-converted by the AD converter 44 at the detection timing synchronized with each light emission of the light-emitting body 27 (27Y) is stored in the second memory 42. It has a second capture control means (second capture control means) 45 for capturing in the image memory area.
[0057]
In addition, the light of two different wavelength ranges emitted by the first light emitter 31 (31X) and the third light emitter 31 (31Y) and the light of two different wavelength regions emitted by the second light emitter 27 (27X) are used. The light in the two different wavelength ranges emitted by the fourth light emitting body 27 (27Y) is any two of one of visible light such as RGB, ultraviolet light, and infrared light, and all of the same combination. Has become.
[0058]
Here, the first capture control means 43 and the second capture control means 45 superimpose the detection timing of all the images of the second CCD sensor 24 (24Y) on the detection timing of the image data of the first CCD sensor 24 (24X). Control the timing to match. That is, since a plurality of image data cannot be detected simultaneously by the same CCD sensor, the detection timing is different for image data detected by the same CCD sensor, and the detection timing is adjusted for image data detected by different CCD sensors. It is.
[0059]
Specifically, as shown in FIG. 4 (FIG. 4 shows each light emission timing, and the hatched portion indicates the image detection timing), the first capture control unit 43 controls the first light emitter 31 (31X). ), Any one of RGB visible light is emitted at a predetermined light emission timing, and the image data is detected by the first CCD sensor 24 (24X) at the detection timing synchronized with the light emission of the first light emitter 31 (31X). (See visible transmission in FIG. 4).
[0060]
In addition, the first capture control unit 43 uses the second light-emitting body 27 (27X) to emit any one of the visible light and the infrared light of RGB at different light-emission timings and emit light of the first light-emitting body 31 (31X). Light is emitted at different light emission timings, and image data is detected by the first CCD sensor 24 (24X) at a detection timing synchronized with each light emission of the second light emitter 27 (27X) (visible reflection table and infrared reflection table in FIG. 4). reference). As described above, the visible light front and back banknote transmission image data, the visible light banknote front and back direction one side reflection image data, and the infrared light banknote front and back side one side reflection image data are obtained.
[0061]
On the other hand, the second capture control unit 45 causes the third light emitting body 31 (31Y) to emit infrared light, which is light in a wavelength range different from that of the first light emitting body 31 (31X), at a predetermined light emission timing. The image data is detected by the second CCD sensor 24 (24Y) at the detection timing synchronized with the light emission of the third light emitter 31 (31Y) (see infrared transmission in FIG. 4).
[0062]
The second capture control unit 45 causes the fourth light emitter 27 (27Y) to emit any one of RGB visible light and infrared light at different light emission timings, and also causes the fourth light emitter 27 (27Y). The image data is detected by the second CCD sensor 24 (24Y) at the detection timings synchronized with the respective light emission (see the visible reflection back and the infrared reflection back in FIG. 4). As described above, transmission image data of the front and back of the banknote of infrared light, reflection image data of the visible light on the opposite side of the banknote front and back, and reflection image data of the infrared light on the opposite side of the banknote front and back are obtained.
[0063]
The transmission image data of the front and back of the banknote of infrared light, the reflection image data of the front and back of the banknote of visible light, and the reflection image data of the front and back of the banknote of infrared light are the emission timing and the detection timing. One-to-one match with any of visible light banknote front and back transmission image data, visible light banknote front and back direction one side reflection image data, and infrared light banknote front and back direction one side reflection image data (The point where the visible transmission and the infrared transmission in FIG. 4 match the detection timing, the point where the visible reflection table and the visible reflection back match the detection timing, and the point where the infrared reflection table and the infrared reflection back are the same. And the point where the detection timing is matched).
[0064]
As described above, according to the banknote image detection device 11 of the first embodiment, when the first light emitter 31 (31X) irradiates the banknote S on the banknote transport path 12 with light in one wavelength region, The first CCD sensor 24 (24X) disposed opposite to the bill transport path 12 detects the transmitted light of the bill S, that is, the front and back transmitted images. In addition, the second light emitter 27 (27X) disposed on the same side of the bill transport path 12 as the first CCD sensor 24 (24X) directs light in a plurality of different wavelength regions to the bills S on the bill transport path 12. Then, the first CCD sensor 24 (24X) detects each reflected light, that is, a reflected image on one side in the front and back directions. Further, a third light emitting body 31 (31Y) disposed opposite to the second CCD sensor 24 (24Y) disposed on the opposite side of the first CCD sensor 24 (24X) with respect to the bill transport path 12 with the bill transport path 12 interposed therebetween. ) Irradiates the banknote S on the banknote transport path with light in another wavelength region different from the first light-emitting body 31, the second CCD sensor 24 (24Y) detects the transmitted light, that is, the transmitted image on the front and back. In addition, the second CCD sensor 24 (24Y) and the fourth illuminator 27 (27Y) arranged on the same side with respect to the banknote transport path 12 emit light of a plurality of different wavelength regions toward the banknote S in the banknote transport path. Upon irradiation, the second CCD sensor 24 (24Y) detects each reflected light, that is, the reflected image on the opposite side in the front and back directions. Accordingly, an image on one side of the banknote S in the front and back direction, an image on the opposite side of the banknote S in the front and back direction, and a transmission image on the front and back of the banknote S can be detected when light in a plurality of wavelength regions is irradiated. As a result, the discrimination accuracy can be improved. Since only two image detection sensors, the first CCD sensor 24 (24X) and the first CCD sensor 24 (24Y), can be used, the cost can be reduced.
[0065]
In addition, the first capture control unit 43 causes the first light emitter 31 (31X) to emit light in one wavelength region, and the second light emitter 27 (27X) emits light in a plurality of, specifically, two different wavelength regions. Light is emitted at different light emission timings and at different light emission timings from the first light emitter 31 (31X), and the detection is synchronized with each light emission of the first light emitter 31 (31X) and the second light emitter 27 (27X). Image data is detected by the first CCD sensor 24 (24X) at the timing, and a plurality of, specifically, three image data detected by the first CCD sensor 24 (24X) are loaded into the first image memory area of the memory 42, The second capture control unit 45 causes the third light emitting body 31 (31Y) to emit light in another wavelength region different from the first light emitting body 31 (31X), 7 (27Y), and more specifically, light in two different wavelength ranges is emitted at different emission timings, and is synchronized with each emission of the third light emitter 31 (31Y) and the fourth light emitter 27 (27Y). The image data is detected by the second CCD sensor 24 (24Y) at the detected timing, and a plurality of, specifically, three, image data detected by the second CCD sensor 24 (24Y) are taken into the second image memory area of the memory 42. . As described above, the first capture control means 43 dedicated to the first CCD sensor 24 (24X) is provided, and the second capture control means 45 dedicated to the second CCD sensor 24 (24Y) is provided. The detection timing of the image of the second CCD sensor 24 (24Y) can be superimposed on the detection timing of the image data of the first CCD sensor 24 (24X). Therefore, more data can be detected for bills moving at the same transport speed, and the discrimination accuracy can be further increased.
[0066]
Further, each of the first luminous body 31 (31X), the third luminous body 31 (31Y), the second luminous body 27 (27X), and the fourth luminous body 27 (27Y) has two different wavelength ranges. Since the light is irradiated, the discrimination accuracy can be improved.
[0067]
In addition, the first light emitter 31 (31X), the third light emitter 31 (31Y), the second light emitter 27 (27X), and the fourth light emitter 27 (27Y) are respectively visible light and infrared light. Since only any two of the light and the ultraviolet light are applied, the difference between the image data can be emphasized. Therefore, the discrimination accuracy can be further improved.
[0068]
In the above, when there is a difference in sensitivity on the CCD sensor 24 side when light of each wavelength region is emitted, for example, the irradiation time or the driving current for irradiation is controlled for each wavelength region degree, and the sensitivity is controlled. Differences can be absorbed.
[0069]
Next, a bill image detecting device according to a second embodiment of the present invention will be described below with reference to FIGS. 5 to 7, focusing on differences from the first embodiment. The same parts as those in the first embodiment are denoted by the same reference numerals, and description thereof is omitted.
[0070]
In the first embodiment, the first capture control unit 43 and the second capture control unit 45 are used. However, in the second embodiment, as shown in FIG. Used. That is, the capture control unit 47 of the second embodiment causes the first light emitting body 31 (31X) to emit only light in one wavelength region by, for example, driving the LED element 33A, and causes the second light emitting body 27 (27X) to emit light. More specifically, only the light in two different wavelength regions is emitted at different emission timings and at emission timings different from that of the first light emitter 31 (31X), for example, by driving the LED elements 29A and 29B to perform third emission. Only light in another wavelength region different from the body 31 (31Y) to the first light emitter 31 (31X) is emitted at a different light emission timing from the first light emitter 31 (31X) and the second light emitter 27 (27X). For example, the LED element 33B is driven to emit light, and the fourth light-emitting body 27 (27Y) emits a plurality of light, specifically, only light of two different wavelength ranges, respectively, with different light emission timings In addition the first light emitter 31 (31X), the second light emitter 27 (27X) and the third light emitter 31 (31Y) and also a different emission timing example LED elements 29A, emit light by the driving of 29B.
[0071]
At the same time, the capture control means 47 of the second embodiment uses the first CCD sensor 24 (24X) at a detection timing synchronized with each light emission of the first light emitter 31 (31X) and the second light emitter 27 (27X). A plurality of, specifically three, image data detected and A / D-converted by the A / D converter 41 via the multiplexer 48 are loaded into the first image memory area of the memory 42, and the third light emitter 31 (31Y) and the fourth light are emitted. A plurality of image data, specifically three image data detected by the second CCD sensor 24 (24Y) at the detection timing synchronized with each light emission of the body 27 (27Y) and AD-converted by the AD converter 44 via the multiplexer 48 are stored in the memory 42. In the second image memory area.
[0072]
As described above, since the capture control unit 47 is single, the detection timing of the image data of the first CCD sensor 24 (24X) and the detection timing of the image data of the second CCD sensor 24 (24Y) are all shifted. Control the timing.
[0073]
Specifically, as shown in FIG. 6 (FIG. 6 shows each light emission timing, hatched portions indicate image detection timings), the capture control unit 47 uses the first light emitter 31 (31X). Any one of RGB visible light is emitted at a predetermined light emission timing, and the image data is detected by the first CCD sensor 24 (24X) at the detection timing synchronized with the light emission of the first light emitter 31 (31X) (FIG. 6 see visible transmission).
[0074]
In addition, the capture control unit 47 uses the second light emitter 27 (27X) to emit any one of the visible light and the infrared light of RGB at different light emission timings, and also emits light different from the light emission of the first light emitter 31 (31X). The first CCD sensor 24 (24X) detects the image data at the detection timing synchronized with each light emission of the second luminous body 27 (27X) at the same time as the light emission (see the visible reflection table and the infrared reflection table in FIG. 6). . As described above, the visible light front and back banknote transmission image data, the visible light banknote front and back direction one side reflection image data, and the infrared light banknote front and back side one side reflection image data are obtained.
[0075]
Further, the capture control unit 47 uses the third light emitter 31 (31Y) to emit infrared light at a predetermined light emission timing, and also emits all the light emitted from the first light emitter 31 (31X) and the second light emitter 27 (27X). The light is emitted at a different light emission timing, and the image data is detected by the second CCD sensor 24 (24Y) at the detection timing synchronized with the light emission of the third light emitter 31 (31Y) (see infrared transmission in FIG. 6).
[0076]
In addition, the take-in control means 47 uses the fourth luminous body 27 (27Y) to emit any one of RGB visible light and infrared light at different luminescence timings, and furthermore, the first luminous body 31 (31X) and the second luminescence. The light emission is performed at a different light emission timing from all the light emission of the body 27 (27X) and the third light emitter 31 (31Y), and the second CCD sensor 24 (24Y) is detected at a detection timing synchronized with each light emission of the fourth light emitter 27 (27Y). ) To detect image data (see the visible reflection back and the infrared reflection back in FIG. 6). As described above, transmission image data of the front and back of the banknote of infrared light, reflection image data of the visible light on the opposite side of the banknote front and back, and reflection image data of the infrared light on the opposite side of the banknote front and back are obtained.
[0077]
As described above, according to the banknote image detection device 11 of the second embodiment, the single capture control unit 47 causes the first luminous body 31 (31X) to emit light in one wavelength region, A plurality of light beams, specifically two different wavelength regions, are emitted from the second light emitter 27 (27X) at different light emission timings and at different light emission timings from the first light emitter 31 (31X). Light of a different wavelength range from the body 31 (31Y) different from the first light emitting body 31 (31X) is emitted at a light emission timing different from that of the first light emitting body 31 (31X) and the second light emitting body 27 (27X); A plurality of lights, specifically two different wavelength regions, from the fourth light emitter 27 (27Y) are emitted at different light emission timings, and the first light emitter 31 (31X), the second light emitter 27 (27X), and the third light emitter are used. 31 ( 1Y) and emit light at different emission timings, and a plurality of specific examples detected by the first CCD sensor 24 (24X) at detection timings synchronized with each emission of the first light emitter 31 (31X) and the second light emitter 27 (27X). More specifically, a plurality of image data detected by the second CCD sensor 24 (24Y) at detection timings synchronized with the light emission of the third light emitter 31 (31Y) and the light emission of the fourth light emitter 27 (27Y), respectively. The three image data are taken into the image memory area. As described above, since only one capture control means 47 is required for the first CCD sensor 24 (24X) and the second CCD sensor 24 (24Y), the cost can be further reduced.
[0078]
The control timing of the second embodiment described above can be changed as follows.
The first luminous body 31 (31X) and the second luminous body 27 (27X) of the first CCD sensor 24 (24X) form a first luminous group, and the third luminous body 31 (31Y) of the second CCD sensor 24 (24Y). ) And the fourth light-emitting body 27 (27Y) as a second light-emitting group, and control is performed such that the first light-emitting group and the second light-emitting group emit light alternately for each group.
[0079]
Specifically, as shown in FIG. 7 (FIG. 7 shows each light emission timing, the hatched portion indicates the image detection timing), the capture control unit 47 uses the first light emitter 31 (31X). Emission of any one of the visible lights of RGB at a predetermined light emission timing, detection of image data by the first CCD sensor 24 (24X) at a detection timing synchronized with the light emission (see visible transmission in FIG. 7), and second light emission Emission of any one of the RGB visible lights by the body 27 (27X) at a predetermined emission timing and detection of image data by the first CCD sensor 24 (24X) at a detection timing synchronized with the emission (visible reflection table in FIG. 7). ), And the second CC 27 (27X) emits infrared light at a predetermined emission timing and the first CC at a detection timing synchronized with the emission. The detection of image data by the sensor 24 (24X) (see the infrared reflection table in FIG. 7) and the three first groups, and the third light emitting body 31 (31Y) at a predetermined light emission timing of infrared light Detection of image data by the second CCD sensor 24 (24Y) at the light emission and detection timing synchronized therewith (see infrared transmission in FIG. 7), and any one of RGB visible light by the fourth light emitter 27 (27Y) At the predetermined light emission timing and detection of image data by the second CCD sensor 24 (24Y) at the detection timing synchronous with the light emission (see the visible reflection back in FIG. 7), and red light emission by the fourth light emitter 27 (27Y). Light emission at a predetermined light emission timing of external light and detection of image data by the second CCD sensor 24 (24Y) at a detection timing synchronized with the light emission ( 7), one of the first group, one of the second group, the remaining one of the first group, the remaining one of the second group, Light emission and image detection are performed in the order of the remaining one of the one group and the remaining one of the second group.
[0080]
In this way, as shown in FIG. 7, the first luminous body 31 (31X), the second luminous body 27 (27X), and the third luminous body 27 (27X) can be used without increasing the time required for all light emission and image detection. The light emission time of each of the body 31 (31Y) and the fourth light emitting body 27 (27Y) can be prolonged. Therefore, the discrimination accuracy can be further improved.
[0081]
Next, a bill image detecting device according to a third embodiment of the present invention will be described below with reference to FIGS. 8 and 9 focusing on differences from the first embodiment. The same parts as those in the first embodiment are denoted by the same reference numerals, and description thereof is omitted.
[0082]
In the first embodiment, each of the first luminous body 31 (31X), the third luminous body 31 (31Y), the second luminous body 27 (27X), and the fourth luminous body 27 (27Y) is two. Although only light in different wavelength regions is emitted, in the third embodiment, only light in three different wavelength regions is emitted.
[0083]
That is, in the third embodiment, as shown in FIG. 8, the first capture control unit 43 causes the first light emitting body 31 (31X) to emit only light in one wavelength region, for example, by driving the LED element 33A. Only the light in the three different wavelength ranges is emitted from the second light emitter 27 (27X) at different light emission timings, for example, by driving the LED elements 29A, 29B, and 29C, and the first light emitter 31 (31X) and the second light are emitted. Four image data detected by the first CCD sensor 24 (24X) and AD-converted by the AD converter 41 at the detection timing synchronized with each light emission of the light-emitting body 27 (27X) is taken into the first image memory area of the memory 42. .
[0084]
Further, in the third embodiment, the second capture control unit 45 emits only light in the other two wavelength ranges different from the third light emitting body 31 (31Y) to the first light emitting body 31 (31X). For example, the LED elements 33B and 33C are driven to emit light at the same timing, and only the light in the three different wavelength regions is emitted from the fourth light emitter 27 (27Y) at different emission timings and different from the third light emitter 31 (31Y). For example, the LED elements 29A, 29B, and 29C are driven to emit light at the same timing, and the second CCD sensor 24 (24Y) is detected at a detection timing synchronized with each emission of the third light emitter 31 (31Y) and the fourth light emitter 27 (27Y). 5) and the five image data subjected to AD conversion by the AD converter 44 are taken into the second image memory area of the memory 42. . In addition, the light of three different wavelength ranges emitted by the first light emitting body 31 (31X) and the third light emitting body 31 (31Y) and the light of three different wavelength areas emitted by the second light emitting body 27 (27X) are used. The light in the three different wavelength regions emitted by the fourth light emitting body 27 (27Y) is one of visible light such as RGB, ultraviolet light, and infrared light, and all have the same combination.
[0085]
Here, the first capture control means 43 and the second capture control means 45 determine the detection timing of the image data of the first CCD sensor 24 (24X), which is a small number, by using the image data of the second CCD sensor 24 (24Y). The timing is controlled so as to overlap the detection timing. That is, in this case as well, the detection timing of image data detected by different CCD sensors is adjusted as much as possible.
[0086]
Specifically, as shown in FIG. 9 (FIG. 9 shows each light emission timing, the hatched portion indicates the image detection timing), the first capture control unit 43 controls the first light emitter 31 (31X). ), Any one of RGB visible light is emitted at a predetermined light emission timing, and the image data is detected by the first CCD sensor 24 (24X) at the detection timing synchronized with the light emission of the first light emitter 31 (31X). (See visible transmission in FIG. 9).
[0087]
Further, the first capture control unit 43 uses the second light emitter 27 (27X) to emit any one of the visible light, RGB, infrared light, and ultraviolet light of RGB at different light emission timings, and furthermore, the first light emitter 31 (31X). And the first CCD sensor 24 (24X) detects image data at a detection timing synchronized with each light emission of the second light-emitting body 27 (27X) (visible reflection table, red in FIG. 9). External reflection table and UV reflection table). As described above, the transmitted image data of the front and back of the visible light banknote, the reflected image data of one side of the front and back of the visible light banknote, the reflected image data of the one side of the front and back of the infrared light banknote, and the one of the front and back directions of the ultraviolet light. Side reflection image data.
[0088]
On the other hand, the second capture control unit 45 causes the third light emitting body 31 (31Y) to emit infrared light and ultraviolet light at different light emission timings and synchronizes with each light emission of the third light emitting body 31 (31Y). At the detection timing, the image data is detected by the second CCD sensor 24 (24Y) (see infrared transmission and ultraviolet transmission in FIG. 9).
[0089]
The second capture control unit 45 causes the fourth light emitting body 27 (27Y) to emit any one of RGB visible light, infrared light, and ultraviolet light at different light emission timings. The image data is detected by the second CCD sensor 24 (24Y) at the detection timing synchronized with each light emission of (27Y) (see visible reflection back, infrared reflection back and ultraviolet reflection back in FIG. 9). As described above, the transmission image data of the front and back of the banknote of infrared light, the transmission image data of the front and back of the banknote of ultraviolet light, the reflection image data of the front and back of the banknote of visible light, and the opposite side of the front and back of the banknote of infrared light The reflected image data and the reflected image data of the ultraviolet light on the opposite side of the banknote front and back direction are obtained.
[0090]
Then, the transmitted image data of the front and back sides of the bill of visible light, the reflected image data of one side of the front and back sides of the visible light, the reflected image data of one side of the front and back sides of the infrared light, and the reflected image of one side of the front and back sides of the ultraviolet light banknote Regarding the data, the transmission image data of the front and back of the banknote of infrared light, the transmission image data of the front and back of the banknote of ultraviolet light, the reflection image data of the front and back of the banknote of visible light, and the reflection of the infrared light on the front and back of the banknote Match the image data with one of the reflected image data on the reverse side of the banknote front and back of the ultraviolet light (the point that the detection timing is matched between the visible transmission and the infrared transmission in FIG. 9, the visible reflection table and the ultraviolet transmission , The point at which the detection timing matches, the point at which the infrared reflection table and the visible reflection back match the detection timing, and the point at which the ultraviolet reflection table and the infrared reflection back match the detection timing. Irradiation).
[0091]
As described above, according to the banknote image detection device 11 of the third embodiment, the first luminous body 31 (31X) and the third luminous body 31 (31Y), the second luminous body 27 (27X), Since each of the fourth light emitters 27 (27Y) emits light in three different wavelength ranges, the discrimination accuracy can be further improved.
[0092]
In addition, the first luminous body 31 (31X), the third luminous body 31 (31Y), the second luminous body 27 (27X), and the fourth luminous body 27 (27Y) respectively emit visible light and infrared light. In addition, since the image data is irradiated with ultraviolet light, the difference between image data can be emphasized, and the number of comparisons can be increased. Therefore, the discrimination accuracy can be further improved.
[0093]
Next, a bill image detecting device according to a fourth embodiment of the present invention will be described below with reference to FIGS. 10 to 12, focusing on differences from the third embodiment. The same parts as those in the third embodiment are denoted by the same reference numerals, and description thereof will be omitted.
[0094]
In the third embodiment, the first capture control means 43 and the second capture control means 45 are used. However, in the fourth embodiment, as shown in FIG. Used. In other words, the capture control unit 47 of the fourth embodiment emits only light in one wavelength region from the first light emitter 31 (31X) at a predetermined light emission timing, for example, by driving the LED element 33A, and the second light emitter Only light of three different wavelength regions from 27 (27X) is emitted at different emission timings and at emission timings different from that of the first light emitter 31 (31X), for example, by driving the LED elements 29A, 29B, and 29C. Only the light in the other two wavelength ranges different from the first luminous body 31 (31X) to the first luminous body 31 (31X) and the second luminous body 27 (27X) ) At different light emission timings, for example, by driving the LED elements 33B and 33C, and from the fourth light emitter 27 (27Y), three different light emission timings. Only the light in the wavelength region is emitted at different light emission timings and at different light emission timings from the first light emitter 31 (31X), the second light emitter 27 (27X), and the third light emitter 31 (31Y). Light emission is performed by driving 29C.
[0095]
At the same time, the capture control unit 47 of the fourth embodiment uses the first CCD sensor 24 (24X) at the detection timing synchronized with each light emission of the first light emitter 31 (31X) and the second light emitter 27 (27X). The four image data detected and AD-converted by the AD converter 41 via the multiplexer 48 are taken into the first image memory area of the memory 42, and the third light emitter 31 (31Y) and the fourth light emitter 27 (27Y) The five image data detected by the second CCD sensor 24 (24Y) at the detection timings synchronized with the respective light emission and AD-converted by the AD converter 41 via the multiplexer 48 are taken into the second image memory area of the memory 42.
[0096]
As described above, since the capture control unit 47 is single, the detection timing of the image data of the first CCD sensor 24 (24X) and the detection timing of the image data of the second CCD sensor 24 (24Y) are all shifted. Control the timing.
[0097]
Specifically, as shown in FIG. 11 (FIG. 11 shows each light emission timing, hatched portions indicate image detection timings), the capture control unit 47 uses the first light emitter 31 (31X). Any one of RGB visible light is emitted at a predetermined light emission timing, and the image data is detected by the first CCD sensor 24 (24X) at the detection timing synchronized with the light emission of the first light emitter 31 (31X) (FIG. 11 see visible transmission).
[0098]
Further, the capture control unit 47 uses the second light emitting body 27 (27X) to emit any one of RGB visible light, infrared light, and ultraviolet light at different light emission timings, and furthermore, to emit light of the first light emitting body 31 (31X). And the first CCD sensor 24 (24X) detects image data at a detection timing synchronized with each light emission of the second light emitter 27 (27X) (visible reflection table, infrared reflection in FIG. 11). Table and UV reflection table). As described above, the transmitted image data of the front and back of the visible light banknote, the reflected image data of one side of the front and back of the visible light banknote, the reflected image data of the one side of the front and back of the infrared light banknote, and the one of the front and back directions of the ultraviolet light. Side reflection image data.
[0099]
Furthermore, the capture control unit 47 uses the third light emitting body 31 (31Y) to emit infrared light and ultraviolet light at different light emission timings, and furthermore, to emit light from the first light emitting body 31 (31X) and the second light emitting body 27 (27X). The second CCD sensor 24 (24Y) detects image data at a detection timing synchronized with the light emission of the third light emitter 31 (31Y) (see infrared transmission and ultraviolet transmission in FIG. 11).
[0100]
In addition, the capture control unit 47 uses the fourth light emitter 27 (27Y) to emit any one of RGB visible light, infrared light, and ultraviolet light at different light emission timings, and furthermore, the first light emitter 31 (31X), The second light emitting element 27 (27X) and the third light emitting element 31 (31Y) emit light at different light emission timings, and the second CCD sensor 24 emits light at a detection timing synchronized with each light emission of the fourth light emitting element 27 (27Y). The image data is detected by (24Y) (see visible reflection back, infrared reflection back and ultraviolet reflection back in FIG. 11). As described above, the transmission image data of the front and back of the banknote of infrared light, the transmission image data of the front and back of the banknote of ultraviolet light, the reflection image data of the front and back of the banknote of visible light, and the opposite side of the front and back of the banknote of infrared light The reflected image data and the reflected image data of the ultraviolet light on the opposite side of the banknote front and back direction are obtained.
[0101]
As described above, according to the banknote image detection device 11 of the fourth embodiment, the single capture control unit 47 performs three operations from the first luminous body 31 (31X) and the third luminous body 31 (31Y). Lights of two different wavelength regions are emitted at different light emission timings, and light of three different wavelength regions is emitted from the second light emitter 27 (27X) at different light emission timings, and the first light emitter 31 (31X) and the third light emission. The body 31 (31Y) emits light at a different light emission timing, and the fourth light emitter 27 (27Y) further emits light in three different wavelength ranges at different light emission timings, and furthermore, the first light emitter 31 (31X) and the second light emitter. 27 (27X) and the third light emitting body 31 (31Y) emit light at different light emission timings, and the first light emitting body 31 (31X) and the second light emitting body 27 (27 ), The four image data detected by the first CCD sensor 24 (24X) at the detection timings synchronized with the respective light emission, and the respective light emission of the third light emitter 31 (31Y) and the fourth light emitter 27 (27Y). The five image data detected by the second CCD sensor 24 (24Y) at the synchronized detection timing are taken into the image memory area. As described above, since only one capture control means 47 is required for the first CCD sensor 24 (24X) and the second CCD sensor 24 (24Y), the cost can be further reduced.
[0102]
The control timing of the fourth embodiment described above can be changed as follows.
[0103]
That is, the first light-emitting body 31 (31X) and the second light-emitting body 27 (27X) related to the first CCD sensor 24 (24X) are set as the first light-emitting group, and the third light-emitting body 31 related to the second CCD sensor 24 (24Y). (31Y) and the fourth luminous body 27 (27Y) are set as the second luminous group, and control is performed so that the first luminous group and the second luminous group emit light alternately for each group.
[0104]
Specifically, as shown in FIG. 12 (FIG. 12 shows each light emission timing, hatched portions indicate image detection timings), the capture control unit 47 uses the first light emitter 31 (31X). Emission of any one of the visible lights of RGB at a predetermined light emission timing, detection of image data by the first CCD sensor 24 (24X) at a detection timing synchronized with the light emission (see visible transmission in FIG. 7), and second light emission Emission of any one of the visible lights of RGB by the body 27 (27X) at a predetermined emission timing and detection of image data by the first CCD sensor 24 (24X) at a detection timing synchronized with the emission (visible reflection table in FIG. 12). ), And the second light-emitting body 27 (27X) emits infrared light at a predetermined light-emission timing and the second light-emission at a detection timing synchronized with the light emission. The detection of image data by the CCD sensor 24 (24X) (see the infrared reflection table in FIG. 7), the emission of ultraviolet light by the second light emitter 27 (27X) at a predetermined emission timing, and the detection timing synchronized therewith. Of the image data by the first CCD sensor 24 (24X) (see the ultraviolet reflection table in FIG. 12), and the predetermined light emission timing of the infrared light by the third light emitter 31 (31Y) , And detection of image data by the second CCD sensor 24 (24Y) at a detection timing synchronized with the light emission (see infrared transmission in FIG. 12), and predetermined emission of ultraviolet light by the third light emitter 31 (31Y). Light emission at the timing and detection of image data by the second CCD sensor 24 (24Y) at the detection timing synchronized with the light emission (see FIG. (See UV transmission), and emission of any one of the RGB visible lights by the fourth light emitter 27 (27Y) at a predetermined emission timing and image data by the second CCD sensor 24 (24Y) at a detection timing synchronized with the emission timing. (See the visible reflection back in FIG. 12), the emission of infrared light by the fourth light emitter 27 (27Y) at a predetermined emission timing, and the detection by the second CCD sensor 24 (24Y) at the detection timing synchronized with the emission. The detection of image data (see the infrared reflection back in FIG. 12), the emission of ultraviolet light by the fourth light emitter 27 (27Y) at a predetermined emission timing, and the second CCD sensor 24 (24Y) at a detection timing synchronized with this. ) (See the ultraviolet reflection back in FIG. 12), one of the second groups and the first group. One of the loops, the remaining one of the second group, the remaining one of the first group, the remaining one of the second group, the remaining one of the first group, the remaining one of the second group Light emission and image detection are performed in the order of one, the remaining one of the first group, and the remaining one of the second group.
[0105]
In this way, as shown in FIG. 12, the first light-emitting body 31 (31X), the second light-emitting body 27 (27X), and the third light-emitting body 27 (27X) can be used without increasing the time required for all light emission and image detection. The light emission time of each of the body 31 (31Y) and the fourth light emitting body 27 (27Y) can be prolonged. Therefore, the discrimination accuracy can be further improved.
[0106]
【The invention's effect】
As described above in detail, according to the first aspect of the invention, when the first light emitting unit irradiates light in one wavelength region toward the banknotes in the banknote transport path, the first light emitting unit is opposed to the banknote transport path. The first image detection sensor detects the transmitted light on the bill, that is, the front and back transmitted images. When the second light emitting means disposed on the same side of the bill transport path as the first image detection sensor irradiates the bills in the bill transport path with light in a plurality of different wavelength regions, the reflected light That is, the first image detection sensor detects the reflection image on one side in the front and back directions. Further, the third light emitting means facing the second image detection sensor provided on the side opposite to the first image detection sensor with respect to the bill transport path, the first light emitting means facing the bill in the bill transport path. When light of another wavelength region different from the above is irradiated, the second image detection sensor detects light transmitted through the bill, that is, transmitted images on the front and back. In addition, when the second image detection sensor and the third light emitting means disposed on the same side of the bill transport path irradiate the bills in the bill transport path with light in a plurality of different wavelength regions, the reflected light That is, the second image detection sensor detects the reflection image on the opposite side of the front and back directions. This makes it possible to detect an image on one side of the banknote in the front and back direction, an image on the opposite side of the banknote in the front and back direction, and a transmission image on the front and back of the banknote, respectively, when light in a plurality of wavelength regions is irradiated. As a result, the discrimination accuracy can be improved. Further, since only two image detection sensors, the first image detection sensor and the second image detection sensor, are required as described above, the cost can be reduced.
[0107]
According to the second aspect of the present invention, the first capture control unit causes the first light emitting unit to emit light in one wavelength region, and the second light emitting unit emits light in a plurality of different wavelength regions. The light is emitted at a different timing and at a different timing from the first light emitting means, and image data is detected by the first image detection sensor in synchronization with each light emission of the first light emitting means and the second light emitting means. While a plurality of image data detected by the first image detection sensor are taken into the first image memory area, the second taking control means sets the third light emitting means to another wavelength different from the first light emitting means. The fourth light emitting means emits light in a plurality of different wavelength regions at different timings and at different timings from the third light emitting means. Capturing a plurality of image data detected by detecting the image data in the second image detection sensor of the respective synchronization with the second image detection sensor to each of the light of the fourth light emitting means in the second picture memory areas. As described above, the first capture control means is provided for the first image detection sensor, and the second capture control means is provided for the second image detection sensor. The detection timing of the image of the second image detection sensor can be superimposed on the detection timing of the image data of the sensor. Therefore, more data can be detected for bills moving at the same transport speed, and the discrimination accuracy can be further increased.
[0108]
According to the invention according to claim 3, since the detection timing of the image of the second image detection sensor can be superimposed on the detection timing of the image of the first image detection sensor, the banknote moving at the same transport speed can be used. Thus, more data can be detected, and the discrimination accuracy can be further improved.
[0109]
According to the invention according to claim 4, the single capture control unit causes the first light emitting unit to emit light in one wavelength region and the second light emitting unit to emit light in a plurality of different wavelength regions. Light is emitted at a different timing and at a different timing from the first light emitting means, and light of another wavelength range different from the first light emitting means is transmitted from the third light emitting means to the first light emitting means and the second light emitting means. Emits light at different timings, and further emits light in a plurality of different wavelength ranges from the fourth light emitting means at different timings and at different timings from the first light emitting means, the second light emitting means, and the third light emitting means. Then, a plurality of image data detected by the first image detection sensor in synchronization with each light emission of the first light emitting means and the second light emitting means, and each light emission of the third light emitting means and the fourth light emitting means. To Capturing a plurality of image data in the image memory region detected by the second image detection sensor with respective Re synchronization. As described above, since only one acquisition control unit is required for the first image detection sensor and the second image detection sensor, the cost can be further reduced.
[0110]
According to the fifth aspect of the present invention, the first light emitting group including the first light emitting means and the second light emitting means according to the first image detecting sensor, and the third light emitting according to the second image detecting sensor. The second light emitting means and the second light emitting means emit light alternately for each group. Therefore, the first light emitting means and the second light emitting means can be used without increasing the time required for all light emission and image detection. The light emission time of each of the means, the third light emitting means and the fourth light emitting means can be lengthened. Therefore, the discrimination accuracy can be further improved.
[0111]
According to the invention according to claim 6, each of the first light emitting means and the third light emitting means, the second light emitting means, and the fourth light emitting means emit light in two different wavelength regions. Therefore, the discrimination accuracy can be improved.
[0112]
According to the invention according to claim 7, each of the first light-emitting means, the third light-emitting means, the second light-emitting means, and the fourth light-emitting means emits visible light, infrared light, and ultraviolet light. Since any one of the two lights is irradiated, the difference between the image data can be emphasized. Therefore, the discrimination accuracy can be further improved.
[0113]
According to the invention according to claim 8, each of the first light-emitting means, the third light-emitting means, the second light-emitting means, and the fourth light-emitting means emits light in three different wavelength regions. Therefore, the discrimination accuracy can be further improved.
[0114]
According to the ninth aspect of the present invention, each of the first light-emitting means, the third light-emitting means, the second light-emitting means, and the fourth light-emitting means emits visible light, infrared light, and ultraviolet light. Since the three light beams are irradiated, the difference between the image data can be emphasized, and the number of comparisons can be increased. Therefore, the discrimination accuracy can be further improved.
[Brief description of the drawings]
FIG. 1 is an enlarged sectional side view of a bill image detecting device according to a first embodiment of the present invention as viewed from one side in a length direction.
FIG. 2 is a front view in which a light-transmitting cover illustrating a detection unit in the banknote image detection device according to the first embodiment of the present invention is omitted.
FIG. 3 is a block diagram of a control system showing the bill image detecting device according to the first embodiment of the present invention.
FIG. 4 is a timing chart of light emission and image detection in the banknote image detection device according to the first embodiment of the present invention.
FIG. 5 is a block diagram of a control system showing a bill image detecting device according to a second embodiment of the present invention.
FIG. 6 is a timing chart of light emission and image detection in the banknote image detection device according to the second embodiment of the present invention.
FIG. 7 is a timing chart of another example of light emission and image detection showing the bill image detecting device according to the second embodiment of the present invention.
FIG. 8 is a block diagram of a control system showing a bill image detecting device according to a third embodiment of the present invention.
FIG. 9 is a timing chart of light emission and image detection in the banknote image detection device according to the third embodiment of the present invention.
FIG. 10 is a block diagram of a control system showing a bill image detecting device according to a fourth embodiment of the present invention.
FIG. 11 is a timing chart of light emission and image detection in a banknote image detection device according to a fourth embodiment of the present invention.
FIG. 12 is a timing chart of another example of light emission and image detection showing the bill image detecting device according to the fourth embodiment of the present invention.
[Explanation of symbols]
11 Banknote image detection device
12 Banknote transport path
24 (24X) 1st CCD sensor (1st image detection sensor)
24 (24Y) second CCD sensor (second image detection sensor)
27 (27X) 2nd light-emitting body (2nd light-emitting means)
27 (27Y) 4th luminous body (4th luminous means)
31 (31X) first luminous body (first luminous means)
31 (31Y) Third illuminant (third illuminant)
43 1st capture control means (1st capture control means)
45 Second capture control means (first capture control means)
47 Single capture control means
S banknote

Claims (9)

A first image detection sensor;
It is disposed opposite the first image detection sensor across the bill transport path, and irradiates light in one wavelength region toward the bill transported in the bill transport path, and transmits light transmitted through the bill in the light. A first light-emitting unit that is detected by the first image detection sensor;
The banknote transport path is provided on the same side as the first image detection sensor, and is irradiated with light in a plurality of different wavelength regions toward the banknote transported in the banknote transport path, and the light is emitted from the banknote. Second light emitting means for detecting reflected light with the first image detection sensor;
A second image detection sensor provided on a side opposite to the first image detection sensor with respect to the bill conveyance path;
The first light-emitting unit is irradiated with light of another wavelength region different from the first light-emitting means toward a bill conveyed in the bill conveyance path while being disposed opposite to the second image detection sensor with the bill conveyance path interposed therebetween. Third light emitting means for detecting the transmitted light of the light by the bill by the second image detection sensor,
The bill conveyance path is provided on the same side as the second image detection sensor and is irradiated with light in a plurality of different wavelength regions toward a bill conveyed in the bill conveyance path. Fourth light emitting means for detecting reflected light with the second image detection sensor;
A bill image detecting device comprising: The first light emitting means emits light in the one wavelength region at a predetermined timing, and the second light emitting means emits light in a plurality of different wavelength regions at different timings and is different from the first light emitting means. At the same time as emitting light at the same time, a plurality of image data detected by the first image detection sensor are taken into the first image memory area in synchronization with each emission of the first light emitting means and the second light emitting means. First capture control means;
The third light emitting means emits light in the other wavelength region at a predetermined timing, and the fourth light emitting means emits light in a plurality of different wavelength regions at different timings and is different from the third light emitting means. A plurality of image data detected by the second image detection sensor are taken into a second image memory area in synchronization with the light emission of the third light emitting unit and the light emission of the fourth light emitting unit. Second capture control means;
The bill image detecting device according to claim 1, comprising: The first capture control means and the second capture control means overlap the detection timing of the image of the first image detection sensor with the detection timing of the image of the second image detection sensor. The bill image detecting device according to claim 2, wherein The first light emitting means emits light in the one wavelength region at a predetermined timing, and the second light emitting means emits light in a plurality of different wavelength regions at different timings and is different from the first light emitting means. The fourth light emission is performed by emitting light in the other wavelength region from the third light emitting unit at a different timing from the first light emitting unit and the second light emitting unit. Means for emitting light in a plurality of different wavelength ranges at different timings and at different timings from the first light-emitting means, the second light-emitting means, and the third light-emitting means; The plurality of image data detected by the first image detection sensor in synchronization with each light emission of the second light emitting means, the third light emitting means, and the third light emitting means. 2. A single capture control means for capturing a plurality of image data detected by said second image detection sensor into an image memory area in synchronization with each light emission of said light emitting means. Banknote image detection device. A first light-emitting group consisting of the first light-emitting means and the second light-emitting means and a second group consisting of the third light-emitting means and the fourth light-emitting means emit light alternately for each group. The bill image detecting device according to claim 4, characterized in that: The bill image detecting device according to claim 1, wherein each of the second light emitting unit and the fourth light emitting unit emits light in two different wavelength ranges. Each of the second light-emitting means and the fourth light-emitting means irradiates any two of visible light, infrared light and ultraviolet light, and the first light-emitting means and the third light-emitting means. 7. The bill image detecting device according to claim 6, wherein the light emitting means emits one of visible light, infrared light, and ultraviolet light. Each of the second light-emitting means and the fourth light-emitting means emits light in three different wavelength ranges, and the third light-emitting means has two other wavelengths different from the first light-emitting means. The banknote image detecting device according to any one of claims 1 to 5, wherein the region is irradiated with light. Each of the second light emitting means and the fourth light emitting means emits visible light, infrared light and ultraviolet light, and the first light emitting means emits visible light, infrared light and ultraviolet light. The banknote image according to claim 8, wherein the third light emitting unit irradiates any one of visible light, infrared light, and ultraviolet light. Detection device.

Images