JP2012043361A - Paper sheet inspection device and paper sheet processing device mounted with the same - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a paper sheet inspection device and a paper sheet processing device mounted with the same capable of inspecting a paper sheet with higher accuracy and performing a stable determination.SOLUTION: A paper sheet inspection device comprises: a magnetic detection section to detect magnetic intensity from a paper sheet; a light source section to irradiate the paper sheet with light; an optical detection section to detect an optical image by receiving the light from the paper sheet: a calculation section to calculate regularized magnetic intensity based on the magnetic intensity detected by the magnetic detection section and the optical image detected by the optical detection section; and a determination section to determine authenticity of the paper sheet based on the regularized magnetic intensity calculated by the calculation section and predetermined standard data.

Description

  Embodiments described herein relate generally to a paper sheet inspection apparatus that inspects paper sheets and a paper sheet processing apparatus that includes the paper sheet inspection apparatus.

  Conventionally, a paper sheet processing apparatus for inspecting various paper sheets such as banknotes has been put into practical use. The paper sheet processing apparatus has a paper sheet inspection apparatus. The paper sheet processing apparatus takes in the paper sheets input into the input unit one by one and conveys them to the paper sheet inspection apparatus.

  The paper sheet inspection apparatus performs various processes on the paper sheet to determine the state of the paper sheet. For example, the paper sheet inspection apparatus performs paper sheet type determination, authenticity determination, and determination as to whether or not the paper sheet can be recirculated (damage determination). The paper sheet processing apparatus sorts and accumulates paper sheets based on the determination result.

  Various security printing is performed on the paper sheets processed by the paper sheet processing apparatus. For example, paper sheets have a pattern printed with magnetic ink containing an object (magnetic material) that is magnetized when a magnetic field is applied. A paper sheet inspection apparatus having a magnetic head for detecting magnetic strength from a magnetic material applied to a paper sheet has been put into practical use.

JP 2002-347220 A

  A paper sheet may be subjected to security printing with a plurality of types of magnetic inks having different magnetization characteristics. When the magnetic strength is detected from a paper sheet on which security printing has been performed with a plurality of types of magnetic ink, the value of the magnetic strength detected by the magnetic head varies depending on the magnetization characteristics of the magnetic ink applied to the detection area.

  In addition, the magnetic head included in the paper sheet inspection apparatus has a detection width in a direction orthogonal to the paper sheet conveyance direction. For this reason, the value of the magnetic strength detected by the magnetic head differs depending on the amount of magnetic ink (magnetic material) applied to the area to be detected.

  For this reason, when the magnetic strength is detected from a paper sheet that has been security-printed with a plurality of types of magnetic ink, there is a problem that the magnetic head may detect the same magnetic strength depending on the amount of the magnetic ink.

  Accordingly, an object of the present invention is to provide a paper sheet inspection apparatus capable of performing a paper sheet inspection with higher accuracy and capable of performing a stable determination, and a paper sheet processing apparatus including the paper sheet inspection apparatus. And

  A paper sheet inspection apparatus according to an embodiment includes a magnetic detection unit that detects magnetic strength from a paper sheet, a light source unit that projects light onto the paper sheet, and light received from the paper sheet. An optical detection unit that detects an optical image, a calculation unit that calculates a normalized magnetic strength based on a magnetic intensity detected by the magnetic detection unit, and an optical image detected by the optical detection unit, and the calculation unit And a discriminating unit that discriminates the authenticity of the paper sheet based on the normalized magnetic strength calculated by the above and reference data set in advance.

FIG. 1 is an explanatory diagram for explaining an appearance of a paper sheet processing apparatus according to an embodiment. FIG. 2 is an explanatory diagram for explaining a configuration example of the paper sheet processing apparatus shown in FIG. 1. FIG. 3 is an explanatory diagram for explaining a configuration example of a control system of the sheet processing apparatus shown in FIGS. 1 and 2. FIG. 4 is an explanatory diagram for explaining a configuration example of the paper sheet inspection apparatus shown in FIGS. 2 and 3. FIG. 5 is an explanatory diagram for explaining an example of magnetic ink. FIG. 6 is an explanatory diagram for explaining an example of a print pattern of paper sheets. FIG. 7 is an explanatory diagram for explaining an example of a print pattern of paper sheets. FIG. 8 is an explanatory diagram for explaining an example of a detection result detected by the paper sheet inspection apparatus shown in FIG. FIG. 9 is an explanatory diagram for explaining an example of a detection result detected by the paper sheet inspection apparatus shown in FIG. FIG. 10 is an explanatory diagram for explaining a process for normalizing the detection results shown in FIGS. 8 and 9. FIG. 11 is an explanatory diagram for explaining processing for determining the type of magnetic ink. FIG. 12 is an explanatory diagram for explaining another configuration example of the paper sheet inspection apparatus.

  Hereinafter, a paper sheet inspection apparatus according to an embodiment and a paper sheet processing apparatus including the paper sheet inspection apparatus will be described in detail with reference to the drawings.

FIG. 1 is an explanatory diagram for explaining an appearance of a paper sheet processing apparatus 100 according to an embodiment.
As shown in FIG. 1, the sheet processing apparatus 100 includes a loading unit 112, an operation unit 136, an operation display unit 137, a door 138, an outlet 139, and a keyboard 140 outside the apparatus.

  The input unit 112 is configured to input a paper sheet 7 such as a banknote. The input unit 112 receives the stacked paper sheets 7 together. The operation unit 136 receives various operation inputs by the operator. The operation display unit 137 displays various operation guidance and processing results for the operator. The operation display unit 137 may be configured as a touch panel. In this case, the sheet processing apparatus 100 detects various operation inputs based on the buttons displayed on the operation display unit 137 and the operations performed on the operation display unit 137 by the operator.

  The door 138 is a door for opening and closing the input port of the input unit 112. The take-out port 139 has a configuration for taking out the paper sheet 7 from the stacking unit in which the paper sheets 7 determined not to be recirculated by the paper sheet processing apparatus 100 are stacked. The keyboard 140 functions as an input unit that receives various operation inputs by an operator.

FIG. 2 is an explanatory diagram for describing a configuration example of the paper sheet processing apparatus 100 illustrated in FIG. 1.
The sheet processing apparatus 100 includes an input unit 112, a take-out unit 113, a suction roller 114, a conveyance path 115, an inspection unit 116, gates 120 to 125, an exclusion conveyance path 126, an exclusion accumulation unit 127, an accumulation / bundling unit. 128 to 131, a cutting unit 133, and a stacker 134. Further, the paper sheet processing apparatus 100 includes a main control unit 151. The main control unit 151 controls the operation of each unit of the paper sheet processing apparatus 100 in an integrated manner.

  The take-out part 113 is provided in the upper part of the input part. The take-out unit 113 includes a suction roller 114. The suction roller 114 is provided so that the paper sheet 7 set in the input unit 112 is in contact with the upper end in the stacking direction. That is, the suction roller 114 rotates to take the sheets 7 set in the input unit 112 one by one from the upper end in the stacking direction. For example, the suction roller 114 functions to take out one sheet 7 every rotation. Thereby, the suction roller 114 takes out the paper sheets 7 at a constant pitch. The paper sheet 7 taken in by the suction roller 114 is introduced into the conveyance path 115.

  The conveyance path 115 is a conveyance unit that conveys the paper sheet 7 to each unit in the paper sheet processing apparatus 100. The conveyance path 115 includes a conveyance belt and a drive pulley (not shown). The conveyance path 115 operates the conveyance belt by a drive motor and a drive pulley (not shown). The conveyance path 115 conveys the paper sheet 7 taken in by the suction roller 114 at a constant speed by the conveyance belt. In the following description, the side near the take-out portion 113 in the transport path 115 is the upstream side, and the side near the stacker 134 is the downstream side.

  An inspection unit 116 is provided on the conveyance path 115 extending from the extraction unit 113. The inspection unit 116 includes an image reading device 117, an image reading device 118, a thickness inspection unit 119, and a paper sheet inspection device 135. The inspection unit 116 detects optical feature information, mechanical feature, and magnetic feature information of the paper sheet 7. Thereby, the paper sheet processing apparatus 100 inspects the type of the paper sheet 7, the fouling loss, the front and back, the authenticity, and the like.

  The image reading devices 117 and 118 are provided so as to face each other with the conveyance path 115 interposed therebetween. The image reading devices 117 and 118 read images on both sides of the paper sheet 7 conveyed through the conveyance path 115. Each of the image reading devices 117 and 118 includes a Charge Coupled Device (CCD) camera. The paper sheet processing apparatus 100 acquires the pattern images of the front and back surfaces of the paper sheet 7 based on the images captured by the image reading apparatuses 117 and 118.

  The image reading devices 117 and 118 temporarily store the read images in a memory (not shown) in the inspection unit 116. The sheet processing apparatus 100 displays the image stored in the memory on the operation display unit 137 in response to the operation input.

  The thickness inspection unit 119 inspects the thickness of the paper sheet 7 conveyed through the conveyance path 115. For example, if the detected thickness is equal to or greater than a specified value, the paper sheet processing apparatus 100 detects two sheets of the paper sheet 7 being picked.

  The paper sheet inspection apparatus 135 acquires an image from the conveyed paper sheet 7. Further, the paper sheet inspection apparatus 135 detects magnetic characteristic information (magnetic strength) of the conveyed paper sheet. The paper sheet inspection apparatus 135 determines the authenticity and type of the paper sheet 7 based on the detected image and magnetic strength.

  Based on the detection results of the image reading devices 117 and 118, the thickness inspection unit 119, the paper sheet inspection device 135, and the like, the main control unit 151 determines the type of the paper sheet 7, true / false determination, damage determination, and Judgment as to whether it is a rejection ticket or the like.

  The main control unit 151 determines the authenticity of the paper sheet 7 based on the detection result of each unit. The main control unit 151 determines that the paper sheet 7 conforming to the preset parameters is a genuine sheet, and the non-conforming paper sheet 7 is a false sheet.

  Further, the main control unit 151 determines the ticket type of the paper sheet 7 based on the detection result of each unit and preset parameters.

  Furthermore, the main control unit 151 determines whether or not the paper sheet 7 is a paper sheet 7 suitable for recirculation based on the detection result of each unit and a preset parameter (determination of damage). I do. That is, the main control unit 151 determines that the paper sheet 7 conforming to the preset parameter is a correct sheet, and the non-conforming paper sheet 7 is an unfit sheet.

  The paper sheet processing apparatus 100 conveys the paper sheet 7 determined to be a genuine note to the stacking / binding unit 128 to 131. Further, the paper sheet processing apparatus 100 conveys the paper sheet 7 determined to be a non-performing ticket to the cutting unit 133. The cutting part 133 cuts the conveyed slip. In addition, the paper sheet processing apparatus 100 may convey and stack the non-use ticket to the stacker 134. The stacker 134 performs sealing every time when the accumulated slips reach 100 sheets, for example.

  Further, the main control unit 151 rejects a paper sheet 7 such as a two-sheet ticket, a paper sheet 7 that is broken or torn, a paper sheet 7 whose ticket type is unknown, a counterfeit ticket, and the like. sheet). The main control unit 151 controls each unit so as to convey the paper sheet 7 determined to be an exclusion ticket to the exclusion stacking unit 127.

  Gates 120 to 125 are sequentially arranged on the conveyance path 115 on the downstream side of the inspection unit 116. Each of the gates 120 to 125 is controlled by the main control unit 151. The main control unit 151 controls the operations of the gates 120 to 125 based on the result of the inspection by the inspection unit 116. As a result, the main control unit 151 performs control so that the paper sheet 7 being conveyed on the conveyance path 115 is conveyed to a predetermined processing unit.

  A gate 120 disposed immediately after the inspection unit 116 branches the conveyance path 115 to an exclusion conveyance path 126. That is, the main control unit 151 controls the gate 120 so as to transport the paper sheet 7 determined to be the rejection ticket to the rejection transport path 126.

  An exclusion stacking unit (exclusion unit) 127 is provided at the end of the exclusion transport path 126. The exclusion stacking unit 127 stacks the exclusion tickets in the posture taken out by the taking-out unit 113. The paper sheets 7 accumulated in the exclusion accumulation unit 127 can be taken out from the take-out port 139.

  Further, stacking / binding portions 128 to 131 (generally referred to as a stacking and binding portion 132) are provided at the branches of the gates 121 to 124, respectively. In the stacking / binding unit 132, the paper sheets 7 determined to be redistributable are stacked separately for each type and front and back. The stacking / binding unit 132 binds and stores the stacked paper sheets 7 every predetermined number of sheets. Further, the paper sheet processing apparatus 100 collects and binds a plurality of paper sheets 7 that are bundled by a predetermined number of sheets by a large bundle bundling unit (not shown).

  A cutting portion 133 and a stacker 134 are disposed at a point branched by the gate 125. The cutting unit 133 cuts and stores the paper sheet 7. The stacker 134 accumulates the paper sheets 7 to be conveyed. The main control unit 151 controls the gates 121 to 124 so as to transport the paper sheet 7 determined to be a non-performing paper to the gate 125.

  When the non-paying sheet cutting mode is selected by an operation input from the outside, the main control unit 151 controls the gate 125 so as to transport the paper sheet 7 to the cutting unit 133. Further, the main control unit 151 controls the gate 125 so as to transport the paper sheet 7 to the stacker 134 when the non-paying sheet cutting mode is not selected.

  Note that the main control unit 151 sequentially stores the number of sheets 7 stacked in the stacking / binding unit 132, the number of sheets 7 cut by the cutting unit 133, and identification information.

  FIG. 3 is an explanatory diagram for explaining a configuration example of a control system of the paper sheet processing apparatus 100 shown in FIGS. 1 and 2.

  The sheet processing apparatus 100 includes a main control unit 151, an inspection unit 116, a conveyance control unit 152, a stacking / binding control unit 153, a cutting control unit 156, an operation display unit 137, a keyboard 140, and the like.

  The main control unit 151 governs overall control of the sheet processing apparatus 100. The main control unit 151 controls the conveyance control unit 152 and the stacking / binding control unit 153 based on the operation input by the operation display unit 137 and the inspection result by the inspection unit 116.

  For example, the operator inputs the ticket type, the number of sheets, the damage judgment level, the name of the supplier, the processing method, and the like of the paper sheet 7 to be processed by using the operation display unit 137 or the keyboard 140.

  The inspection unit 116 includes image reading devices 117 and 118, a thickness inspection unit 119, a paper sheet inspection device 135, other sensors 154, and a CPU 155.

  The image reading devices 117 and 118 read images on both sides of the paper sheet 7 conveyed through the conveyance path 115. The image reading devices 117 and 118 include a light receiving element such as a CCD and an optical system, for example. The image reading devices 117 and 118 project light onto the transported paper sheet 7 and receive reflected light or transmitted light using an optical system. The image reading devices 117 and 118 form an image of the light received by the optical system on the CCD and acquire an electrical signal (image).

  The main control unit 151 stores an image (reference image) serving as a reference of the paper sheet 7 in the storage unit 151a in advance. The main control unit 151 performs various determinations by comparing the image acquired from the paper sheet 7 with the reference image stored in the storage unit 151a.

  The thickness inspection unit 119 inspects the thickness of the paper sheet 7 conveyed through the conveyance path 115. The other sensors 154 are, for example, an ultraviolet image acquisition unit. The ultraviolet image acquisition unit irradiates the paper sheet 7 conveyed through the conveyance path 115 with ultraviolet light, and detects excitation light emitted from the phosphor applied to the paper sheet 7.

  As described above, the paper sheet inspection apparatus 135 detects an image and magnetic strength from the conveyed paper sheet 7.

  The CPU 155 integrates the inspection results obtained by the image reading devices 117 and 118, the thickness inspection unit 119, the paper sheet inspection device 135, and other sensors 154. The CPU 155 determines the type, correctness, front / back, authenticity, and the like of the paper sheet 7 conveyed on the conveyance path 115 based on the inspection result of each part.

  The transport control unit 152 controls the take-out unit 113, the transport path 115, the exclusion transport path 126, and the gates 120 to 125 based on the control of the main control unit 151. Thereby, the conveyance control unit 152 controls the taking-in and conveyance of the paper sheet 7. Further, the conveyance control unit 152 performs a sorting process for sorting for each type of the determined paper sheet 7. That is, the transport control unit 152 functions as a sorting processing unit.

  The stacking / binding controller 153 controls the exclusion stacking unit 127 and the stacking / binding units 128 to 131 based on the control of the main control unit 151. Thereby, the stacking / binding controller 153 controls the stacking and binding of the paper sheets 7.

  The cutting control unit 156 controls the operation of the cutting unit 133 based on the control of the main control unit 151. Accordingly, the cutting unit 133 performs cutting of the conveyed paper sheet 7.

FIG. 4 is an explanatory diagram for describing a configuration example of the paper sheet inspection apparatus 135 illustrated in FIGS. 2 and 3. The paper sheet inspection apparatus 135 is installed in the vicinity of the conveyance path 115 of the paper sheet processing apparatus 100, for example.
The paper sheet inspection apparatus 135 includes a control unit 10, a sensor unit 11, a signal processing unit 15, and a determination unit 16.

  The control unit 10 controls the operation of each unit of the paper sheet inspection apparatus 135. The control unit 10 is connected to the CPU 155 shown in FIG. The control unit 10 controls the paper sheet inspection apparatus 135 based on the control of the main control unit 151 of the paper sheet processing apparatus 100.

The sensor unit 11 includes a light source 12, an optical sensor 13, and a magnetic sensor 14.
The light source 12 projects light onto the conveyed paper sheet 7 at a timing based on the control of the control unit 10. For example, the light source 12 irradiates the paper sheet 7 with infrared wavelength light.

  The optical sensor 13 detects optical feature information (optical image) of the paper sheet 7. The optical sensor 13 receives the reflected light of the light irradiated to the paper sheet 7 from the light source 12 and acquires an image.

  The optical sensor 13 includes a light receiving element such as a charge coupled device (CCD), for example. The light receiving element converts the received light into an electrical signal. That is, the optical sensor 13 acquires an image by the light receiving element. The optical sensor 13 includes a plurality of light receiving elements arranged in a direction orthogonal to the transport direction a of the paper sheet 7. That is, the optical sensor 13 includes a line image sensor.

  The optical sensor 13 reads an image for one line of the paper sheet 7 conveyed by the conveyance path 115 at one timing. The optical sensor 13 acquires an entire image of the paper sheet 7 by continuously acquiring images from the conveyed paper sheet 7.

  The optical sensor 13 may be configured to acquire a one-dimensional signal pattern in the transport direction a using a single optical sensor such as a photodiode.

  Generally, the magnetic substance contained in the magnetic ink applied to the paper sheet 7 has a characteristic of absorbing light in the near-infrared wavelength band. For this reason, when irradiating infrared rays with respect to the paper sheet 7 from the light source 12, the optical sensor 13 can acquire the image of the printing pattern formed with magnetic ink.

  The magnetic sensor 14 detects the magnetic strength from the magnetic material contained in the magnetic ink applied to the conveyed paper sheet 7. The magnetic sensor 14 has a coil. The magnetic sensor 14 generates a magnetic field in the vicinity of the coil by applying a current to the coil.

  When a magnetic field is applied to the magnetic body, the magnetic body is magnetized. When the magnetic material is magnetized, it generates a magnetic flux with a magnetic flux density B corresponding to the strength H of the magnetic field.

  When the paper sheet 7 is conveyed in the magnetic field generated by the coil, the magnetic field is applied to the magnetic body on the paper sheet 7. In this case, the magnetic flux near the coil changes. As a result, the value of the current flowing through the coil changes. The magnetic sensor 14 detects the magnetic strength based on the change in the current value.

  Note that the relationship between the magnetic field strength H and the magnetic flux density B is unique to the magnetization characteristics of the magnetic material. That is, even when a magnetic field having the same strength is applied, the magnetic flux density of the magnetic flux generated from the magnetic material is different if the magnetization characteristics of the magnetic material are different.

FIG. 5 is an explanatory diagram for explaining an example of magnetic ink.
A graph 51 shown in FIG. 5 shows the magnetization characteristics of the first magnetic material contained in the first magnetic ink. The graph 52 shows the magnetization characteristics of the second magnetic material contained in the second magnetic ink.

  For example, when applying a magnetic field of strength He to the first magnetic body, the first magnetic body generates a magnetic flux having a magnetic flux density Ba. In addition, when applying a magnetic field of strength He to the second magnetic body, the first magnetic body generates a magnetic flux having a magnetic flux density Bb. Thus, when the magnetization characteristics are different, the magnetic flux density of the generated magnetic flux is different even when a magnetic field having the same strength is applied.

  In addition, although the magnetic sensor 14 was demonstrated as a structure which detects a magnetic intensity with a coil, the structure which detects a magnetic intensity may be based on what kind of other methods, such as a magnetoresistive element system.

  The signal processing unit 15 performs processing of a signal detected by the optical sensor 13 and a signal detected by the magnetic sensor 14. For example, the signal processing unit 15 performs processing for normalizing a signal detected by the magnetic sensor 14 using a signal detected by the optical sensor 13. The normalization process will be described later.

  The determination unit 16 determines the authenticity of the paper sheet 7 by comparing the signal transmitted from the signal processing unit 15 with the reference data stored in the storage unit 16a in advance. Furthermore, when the reference data is stored for each ticket type in the storage unit 16a, the determination unit 16 compares the signal transmitted from the signal processing unit 15 with the reference data stored in advance in the storage unit 16a. Thus, the ticket type of the paper sheet 7 can be determined.

6 and 7 are explanatory diagrams for explaining an example of the print pattern of the paper sheet 7.
FIG. 6 shows an infrared image of the paper sheet 7. As shown in FIG. 6, the paper sheet 7 includes a print pattern 71 and a print pattern 72 printed with magnetic ink. An arrow a indicates the conveyance direction of the paper sheet 7. An arrow H indicates the scanning direction of the optical sensor 13 and the magnetic sensor 14.

  The optical sensor 13 acquires an image using the range of the detection width D as a detection region, and detects the sum of densities of one scan (line) as a density signal.

  Further, the magnetic sensor 14 acquires the magnetic strength using the range of the detection width D as a detection region. In this case, the magnetic sensor 14 detects the sum of magnetic fluxes emitted from the detection region as a value of magnetic strength. That is, when the amount of magnetic ink applied to the detection area is large, the magnetic sensor 14 detects a high value.

  The print pattern 71 is printed with a constant optical density. The print pattern 72 is subjected to gradation printing so that the optical density gradually increases according to the position on the paper sheet 7.

  FIG. 7 shows the types of magnetic ink forming each print pattern. As shown in FIG. 7, the print pattern 71 is printed with the region 71 a printed with the first magnetic ink containing the first magnetic material and the second magnetic ink containing the second magnetic material. And a region 71b to which is applied. The areas 71a and 71b are printed with the same level of optical density.

  The print pattern 72 is printed with the same magnetic ink as the region 71a.

  Regions X1 to X8 shown in FIG. 7 are detection regions of the optical sensor 13 and the magnetic sensor 14, respectively. The area X1 does not include an area printed with magnetic ink. The region X2 and the region X3 include a part of the region 71a printed with the first magnetic ink. The region X4 and the region X5 include a part of the region 71b printed with the second magnetic ink. The area X6 does not include an area printed with magnetic ink. The region X7 includes a part of the print pattern 72 that is gradation-printed with the first magnetic ink. The area X8 does not include an area printed with magnetic ink.

  FIG. 8 is a diagram showing the detection result of the magnetic strength by the magnetic sensor 14. Here, the detection result in the paper sheets 7 shown in FIGS. 5 and 6 is shown.

  As described above, the magnetic sensor 14 detects a high value of magnetic strength in a region where a large amount of magnetic ink exists. Further, the magnetic sensor 14 detects an extremely low magnetic strength in an area where the amount of magnetic ink is small.

  In the region X1 where printing with magnetic ink is not performed, the magnetic sensor 14 detects a low value as the magnetic strength.

  In the region X2 printed with the first magnetic ink, the magnetic sensor 14 detects the magnetic strength. Since the amount of the magnetic material applied to the paper sheet 7 is distributed so as to increase with the transport distance of the paper sheet 7, the magnetic strength detected by the magnetic sensor 14 also depends on the amount of the magnetic material. Gradually increase.

  In the region X3 printed with the first magnetic ink, the magnetic sensor 14 detects a high magnetic intensity M1.

  In the region X4 printed with the second magnetic ink, the magnetic sensor 14 detects a magnetic strength M2 having a value lower than the magnetic strength M1.

  In the region X5 printed with the second magnetic ink, the magnetic sensor 14 detects the magnetic strength. Since the amount of the magnetic material applied to the paper sheet 7 is distributed so as to decrease according to the transport distance of the paper sheet 7, the magnetic strength detected by the magnetic sensor 14 also depends on the amount of the magnetic material. Gradually decreases.

  In the region X6 where printing with magnetic ink is not performed, the magnetic sensor 14 detects a very low value as the magnetic strength.

  In the region X7 printed with the first magnetic ink, the magnetic sensor 14 detects the magnetic strength. As described above, the region X7 includes a part of the print pattern 72 that is gradation-printed with the first magnetic ink. For this reason, the amount of the magnetic substance existing in the region X7 increases according to the transport distance of the paper sheet 7. As a result, the magnetic strength detected by the magnetic sensor 14 gradually increases according to the amount of the magnetic material.

  In the region X8 where printing with magnetic ink is not performed, the magnetic sensor 14 detects a very low value as the magnetic strength.

  In this case, the same magnetic strength M2 is detected at the point A in the region X4 and the point B in the region X7. However, the region X4 is a region printed with the second magnetic ink, and the region X7 is a region printed with the first magnetic ink.

  That is, when only the magnetic strength is detected, the sheet processing apparatus determines whether the plurality of regions where the same value of magnetic strength is detected are regions printed with the same density by the same magnetic ink. It is not possible to determine whether the area is printed at a different density with magnetic ink. As a result, the authenticity and type of the paper sheet may not be correctly determined.

  FIG. 9 is a diagram showing the detection result of the optical density. Here, the detection result in the paper sheets 7 shown in FIGS. 5 and 6 is shown.

  The optical sensor 13 acquires reflected light of the light irradiated on the paper sheet 7 from the light source 12 and detects an optical image. The signal processing unit 15 calculates an optical density based on an optical image for one line detected by the optical sensor 13, that is, an optical image per scan. For example, the signal processing unit 15 calculates the sum of the densities of the pixels of the optical image for one line detected by the optical sensor 13 as the optical density.

  The magnetic body absorbs light in the infrared band. For this reason, as described above, the optical sensor 13 and the signal processing unit 15 detect a location where the magnetic ink is present as a black spot, that is, a location having a high density.

  In the region X1 where printing with magnetic ink is not performed, the optical sensor 13 and the signal processing unit 15 detect a low value as the optical density.

  In the region X2 printed with the first magnetic ink, the optical sensor 13 and the signal processing unit 15 detect the optical density. Since the amount of the magnetic material applied to the paper sheet 7 is distributed so as to increase according to the transport distance of the paper sheet 7, the optical density detected by the optical sensor 13 and the signal processing unit 15 is also magnetic. Gradually increases with body volume.

  In the areas X3 and X4 printed with the first magnetic ink, the optical sensor 13 and the signal processing unit 15 detect a high optical density.

  In the region X5 printed with the second magnetic ink, the optical sensor 13 and the signal processing unit 15 detect the optical density. Since the amount of the magnetic material applied to the paper sheet 7 is distributed so as to decrease according to the transport distance of the paper sheet 7, the optical density detected by the optical sensor 13 and the signal processing unit 15 is also magnetic. It gradually decreases according to the amount of the body.

  In the region X6 where printing with magnetic ink is not performed, the optical sensor 13 and the signal processing unit 15 detect a low value as the optical density.

  In the region X7 printed with the first magnetic ink, the optical sensor 13 and the signal processing unit 15 detect the optical density. As described above, the region X7 includes a part of the print pattern 72 that is gradation-printed with the first magnetic ink. For this reason, the amount of the magnetic substance existing in the region X7 increases according to the transport distance of the paper sheet 7. As a result, the optical density detected by the optical sensor 13 and the signal processing unit 15 also gradually increases according to the amount of the magnetic material.

  In the region X8 where printing with magnetic ink is not performed, the optical sensor 13 and the signal processing unit 15 detect a low value as the optical density.

  The signal processing unit 15 of the paper sheet inspection apparatus 135 performs normalization processing based on the optical density and the magnetic intensity detected by the magnetic sensor 14. In other words, the paper sheet inspection apparatus 135 determines the type of magnetic ink by associating the magnetic strength signal output shown in FIG. 8 with the optical density signal output shown in FIG.

  Specifically, the signal processing unit 15 divides the magnetic intensity detected by the magnetic sensor 14 by the optical density. Thereby, the signal processing unit 15 calculates the magnetic strength per unit optical density (normalized magnetic strength). The signal processing unit 15 calculates the normalized magnetic strength graph shown in FIG. 10 based on the magnetic strength signal output shown in FIG. 8 and the optical density signal output shown in FIG.

FIG. 10 is a graph showing the normalized magnetic strength calculated by the signal processing unit 15.
Since the area X7 is gradation-printed with magnetic ink, as shown in FIGS. 8 and 9, the magnetic strength and optical density of the area X7 are gradually increased according to the transport distance of the paper sheet 7. It has increased. For this reason, when the magnetic strength is divided by the optical density, the signal processing unit 15 calculates a certain value of magnetic strength according to the type of magnetic ink, as shown in FIG.

The signal processing unit 15 transmits the calculated normalized magnetic strength to the sequential determination unit 16 sequentially.
The determination unit 16 determines the authenticity of the paper sheet 7 by comparing the normalized magnetic strength transmitted from the signal processing unit 15 with the reference data stored in advance in the storage unit 16a.

  For example, the determination unit 16 stores the reference magnetic strength as reference data in the storage unit 16a. The determination unit 16 calculates the similarity between the normalized magnetic strength and the reference magnetic strength transmitted from the signal processing unit 15. The determination unit 16 determines that the paper sheet 7 is a genuine note if the calculated similarity is equal to or greater than a preset reference value. Further, when the calculated similarity is less than a preset reference value, the determination unit 16 determines that the paper sheet 7 is a fake ticket.

  Moreover, when the memory | storage part 16a has memorize | stored the some reference | standard magnetic strength for every ticket type, the discrimination | determination part 16 calculates the similarity degree of each reference | standard magnetic intensity and normalized magnetic intensity. The determination unit 16 can determine the type of the paper sheet 7 by specifying the reference magnetic strength having the highest similarity.

  In addition, although the discrimination | determination part 16 demonstrated as a structure which calculates the similarity degree of reference | standard magnetic intensity | strength and normalized magnetic intensity | strength, it is not limited to this structure. The determination unit 16 may be configured to determine authenticity based on the normalized magnetic strength of a region set in advance on the paper sheet 7.

  The storage unit 16a stores a reference value as reference data for each region. The reference value is data having an allowable range, for example. The determination unit 16 determines the authenticity of the paper sheet 7 based on the value of each region of the normalized magnetic strength received from the signal processing unit 15 and the reference data stored in the storage unit 16a. That is, the determination unit 16 determines for each region whether or not the value of the normalized magnetic strength is within an allowable range indicated by the reference data. The determining unit 16 determines that the paper sheet 7 is a genuine note when the value of the normalized magnetic strength is within the allowable range indicated by the reference data.

  In the above-described embodiment, the paper sheet inspection apparatus 135 has been described as a configuration that acquires the normalized magnetic strength based on the magnetic strength and the optical density. However, the configuration is not limited to this configuration. The paper sheet inspection apparatus 135 may be configured to acquire the normalized magnetic strength based on the magnetic strength and the number of black pixels.

  For example, the signal processing unit 15 sets the number of pixels having a pixel value less than a preset value as the number of black pixels based on an optical image of one line detected by the optical sensor 13, that is, an optical image per scan. Count.

  The signal processing unit 15 divides the magnetic intensity detected by the magnetic sensor 14 by the number of black pixels acquired from the optical image detected by the optical sensor 13. Thereby, the signal processing unit 15 can calculate the magnetic strength per unit number of black pixels (normalized magnetic strength).

  Further, the signal processing unit 15 may be configured to simplify the normalized magnetic strength based on preset threshold values T1 and T2. In this case, the signal processing unit 15 includes a memory that holds the threshold values T1 and T2.

  The signal processing unit 15 compares the thresholds T1 and T2 stored in the memory with the normalized magnetic strength. The signal processing unit 15 quantizes the normalized magnetic strength based on the threshold values T1 and T2, and acquires the signal illustrated in FIG.

  For example, when the value of the normalized magnetic strength is equal to or greater than T1, the signal processing unit 15 sets the normalized magnetic strength to M1. Further, when the value of the normalized magnetic strength is less than T1 and equal to or greater than T2, the signal processing unit 15 sets the normalized magnetic strength to M2. Further, the signal processing unit 15 sets the normalized magnetic strength to 0 when the value of the normalized magnetic strength is less than T2.

  For example, the determination unit 16 stores the reference magnetic strength as reference data in the storage unit 16a. The determination unit 16 calculates the similarity between the normalized magnetic strength and the reference magnetic strength transmitted from the signal processing unit 15. The determination unit 16 determines that the paper sheet 7 is a genuine note if the calculated similarity is equal to or greater than a preset reference value. Further, when the calculated similarity is less than a preset reference value, the determination unit 16 determines that the paper sheet 7 is a fake ticket.

  Moreover, when the memory | storage part 16a has memorize | stored the some reference | standard magnetic strength for every ticket type, the discrimination | determination part 16 calculates the similarity degree of each reference | standard magnetic intensity and normalized magnetic intensity. The determination unit 16 can determine the type of the paper sheet 7 by specifying the reference magnetic strength having the highest similarity.

  In addition, although the discrimination | determination part 16 demonstrated as a structure which calculates the similarity degree of reference | standard magnetic intensity | strength and normalized magnetic intensity | strength, it is not limited to this structure. The determination unit 16 may be configured to determine authenticity based on the type of magnetic ink in a predetermined region on the paper sheet 7.

  The determination unit 16 is an area where the normalized magnetic strength value M1 is printed with the first magnetic ink, and an area where the normalized magnetic strength value M2 is printed with the second magnetic ink. It is possible to easily determine that a region where printing has been performed and a region having a normalized magnetic strength value of 0 is a region where printing with magnetic ink has not been performed.

  The determination unit 16 determines the type of magnetic ink for each region. The storage unit 16a stores information indicating the type of magnetic ink for each region as reference data. The determination unit 16 determines the authenticity of the paper sheet 7 based on the specified type of magnetic ink and the reference data stored in the storage unit 16a. That is, the determination unit 16 determines that the paper sheet 7 is a genuine note when the type of the magnetic ink identified by the determination unit 16 matches the reference data stored in the storage unit 16a.

  In this case, the region used for the comparison is not limited to the region shown in FIGS. 7 and 8, but may be any position where the authenticity or type of the paper sheet 7 can be determined based on the magnetic strength. It may be set at any position.

  As described above, the paper sheet inspection apparatus 135 normalizes the magnetic strength detected by the magnetic sensor 14 based on the detection result of the optical sensor 13 and acquires the normalized magnetic strength. Thereby, the paper sheet inspection apparatus 135 can calculate the magnetic strength per density of the magnetic ink regardless of the shape of the pattern printed with the magnetic ink, gradation, and the like. As a result, the paper sheet inspection apparatus 135 can inspect paper sheets with higher accuracy, can perform stable determinations, and can be used for paper sheets equipped with the paper sheet inspection apparatus. A similar processing apparatus can be provided.

  In the above-described embodiment, the paper sheet inspection apparatus 135 has been described as the configuration in which the reflected light of the infrared wavelength light projected from the light source 12 is detected by the optical sensor 13, but is not limited to this configuration. For example, the paper sheet inspection apparatus 135 may be configured to detect the transmitted light of the infrared wavelength light projected from the light source 12 by the optical sensor 13.

  FIG. 12 is an explanatory diagram for explaining another configuration example of the paper sheet inspection apparatus 135. The same components as those shown in FIG. 4 are denoted by the same reference numerals, and detailed description thereof is omitted.

  The light source 12 and the optical sensor 13 are disposed so as to face each other with the conveyance path 115 interposed therebetween. In this case, the optical sensor 13 receives the transmitted light emitted from the light source 12 and transmitted through the paper sheet 7, and acquires an image.

  The paper sheet inspection apparatus 135 shown in FIG. 12 acquires the normalized magnetic strength based on the detection result of the optical sensor 13 and the detection result of the magnetic sensor 14 as in the example shown in FIG. The paper sheet inspection apparatus 135 can determine the authenticity and / or type of the paper sheet 7 based on the normalized magnetic strength.

  Note that the present invention is not limited to the above-described embodiment as it is, and can be embodied by modifying the constituent elements without departing from the scope of the invention in the implementation stage. Further, various inventions can be formed by appropriately combining a plurality of constituent elements disclosed in the embodiment. For example, some components may be deleted from all the components shown in the embodiment. Furthermore, you may combine suitably the component covering different embodiment.

  DESCRIPTION OF SYMBOLS 7 ... Paper sheets, 10 ... Control part, 11 ... Sensor part, 12 ... Light source, 13 ... Optical sensor, 14 ... Magnetic sensor, 15 ... Signal processing part, 16 ... Discrimination part, 16a ... Memory | storage part, 100 ... Paper sheet Processing unit 112 ... Input unit 113 113 Extraction unit 114 Adsorption roller 115 Transport path 116 Inspection unit 117 Image reading device 118 Image reading device 119 Thickness inspection unit 135 Paper Leaf inspection apparatus 151... Main controller 151 a storage unit 152 transport control unit 153 stacking / binding control unit 155 CPU 156 cutting control unit

Claims (9)

A magnetic detection unit for detecting magnetic strength from the paper sheet;
A light source unit that projects light onto the paper sheet;
An optical detector that receives light from the paper and detects an optical image;
A calculation unit that calculates a normalized magnetic strength based on a magnetic intensity detected by the magnetic detection unit and an optical image detected by the optical detection unit;
A discriminating unit that discriminates the authenticity of the paper sheet based on the normalized magnetic strength calculated by the calculating unit and preset reference data;
A paper sheet inspection apparatus. The light source unit projects infrared light onto the paper sheet,
The optical detection unit receives at least infrared light to obtain an optical image;
The paper sheet inspection apparatus according to claim 1.   The calculation unit calculates an optical density based on an optical image detected by the optical detection unit, and calculates a normalized magnetic intensity by dividing a magnetic intensity detected by the magnetic detection unit by the calculated optical density. 2. The paper sheet inspection apparatus according to 2.   The calculation unit calculates the number of black pixels based on the optical image detected by the optical detection unit, and calculates the normalized magnetic strength by dividing the magnetic strength detected by the magnetic detection unit by the calculated number of black pixels. The paper sheet inspection apparatus according to claim 2.   The determination unit calculates a similarity between the normalized magnetic strength calculated by the calculation unit and preset reference data. If the similarity is equal to or greater than a preset threshold, the paper sheet is true. The paper sheet inspection apparatus according to claim 3 or 4, wherein the paper sheet inspection apparatus determines that the ticket is a ticket.   The discriminating unit is genuine when the value of the normalized magnetic strength calculated by the calculating unit in a preset area on the paper is within a preset allowable range. The paper sheet inspection device according to claim 3 or 4, wherein   The paper sheet inspection apparatus according to claim 1, wherein the optical detection unit detects an optical image by receiving reflected light of light projected from the light source unit onto the paper sheet.   The paper sheet inspection apparatus according to claim 1, wherein the optical detection unit detects an optical image by receiving transmitted light of light projected from the light source unit onto the paper sheet. A transport unit for transporting paper sheets;
A magnetic detection unit for detecting magnetic strength from the paper sheet conveyed by the conveyance unit;
A light source unit that projects light onto the paper sheet conveyed by the conveyance unit;
An optical detection unit for detecting an optical image by receiving light from a paper sheet conveyed by the conveyance unit;
A calculation unit that calculates a normalized magnetic strength based on a magnetic intensity detected by the magnetic detection unit and an optical image detected by the optical detection unit;
A discriminating unit that discriminates the authenticity of the paper sheet based on the normalized magnetic strength calculated by the calculating unit and preset reference data;
Based on a determination result by the determination unit, a classification processing unit that classifies the paper sheets,
A paper sheet processing apparatus comprising:

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