JP2024042798A - Image reading device - Google Patents

Abstract

[Problem] For a document set containing multiple types of documents, it is necessary to change the image reading processing settings for each type of document. [Solution] The device includes a reading unit 70 that reads documents conveyed from a document table 1, a storage unit 82 that stores the size of the document S in association with the image reading settings, and an image processing unit 81 that performs image processing on the image read by the reading unit 70, and the image processing unit 81 performs image processing using the image reading settings stored in the storage unit 82 and associated with the size of the image read by the reading unit 70. [Selected Figure] Figure 1

Description

The present invention relates to an image reading device that reads a document.

In recent years, image reading devices such as scanners have been used at counters of banks and the like to digitize documents such as forms. Generally, manuscripts handled at counters include multiple types of manuscripts each having different sizes and thicknesses. At such a counter, a set of multiple types of originals is read together by an image reading device for each customer, and the original image obtained by capturing each original is sometimes managed as an image set that is one piece of electronic data. Therefore, the operator places the set of documents organized for each customer on the paper feed tray of the image reading device and starts the image reading process. At this time, image reading settings may be changed for each type of document.

However, with current image reading devices, only one image reading setting can be registered for a series of image reading processes that transport the original and save the scanned image data. It was necessary to set image reading settings for each type and perform image reading processing. Such a method not only requires time and effort for the operator, but also may cause errors in the management of document sets that should be saved for each customer.

Japanese Patent Application Publication No. 2020-141275 Patent No. 6161484 JP 2015-8370 A

For image reading devices used in operations that handle such document sets including multiple types of documents, Patent Document 1 discloses that an operator registers a combination of the number and size of documents to be transported in the image reading device. In this way, the present invention provides an image reading device and a control program that can determine whether or not the conveyed original is in the correct original set. However, when using the method described in Patent Document 1, although it is possible to appropriately store each customer's original set as image data, it is necessary to register the combination of the number and size of originals.

Further, Patent Document 2 provides an image reading device that can determine the type of document and change the image reading process by calculating character string density or character string variance from an image obtained by reading the document. However, when using the method described in Patent Document 2, it is necessary to extract a lot of image information from the image data of the transported document and calculate the character string density or character string dispersion, which increases the processing performed by the image reading device. Therefore, there are concerns that the user's work will be delayed and that it will be necessary to prepare a CPU with higher processing power, which will increase costs.

Furthermore, in Patent Document 3, the effort of changing settings is reduced by reading a cover sheet for each type of document and changing the settings. However, inserting a cover sheet for each type of document is cumbersome, and it is necessary to judge each scanned image whether it is a cover sheet or a desired document, which leads to a decline in reading performance. ing.

In view of the above, in the image reading system according to the present invention,
a reading section that reads the document conveyed from the document table;
a storage unit that associates and stores document size and image reading settings;
an image processing unit that performs image processing on the image read by the reading unit,
The image processing section is characterized in that it performs image processing using the image reading settings stored in the storage section and associated with the size of the document read by the reading section.

According to the present invention, it is possible to save the effort of individually specifying image reading settings for image reading processing of multiple types of originals.

Schematic diagram of an image reading device according to the first embodiment of the present invention Block diagram of a control unit of an image reading device according to a first embodiment of the present invention Block diagram of an external information processing device according to the first embodiment of the present invention An example of a scan screen according to the first embodiment of the present invention An example of an editing screen for image reading settings according to the first embodiment of the present invention An example of an editing screen for image reading settings according to the first embodiment of the present invention An example of an image reading setting table according to the first embodiment of the present invention Flowchart showing the operation of image reading device A according to the first embodiment of the present invention An example of a graph showing the document size detection operation in the medium detection sensor 60 according to the first embodiment of the present invention An example of a graph showing the document size detection operation in the image reading unit 70 according to the first embodiment of the present invention Flowchart showing the operation of the image processing application AP according to the first embodiment of the present invention An example of an image information table according to the first embodiment of the present invention Flowchart showing operations related to image processing in FIG. 11 according to the first embodiment of the present invention An example of a notification screen related to image processing in FIG. 12 according to the first embodiment of the present invention An example of an image information table according to the first embodiment of the present invention An example of an editing screen for image reading settings according to the second embodiment of the present invention An example of an editing screen for image reading settings according to the second embodiment of the present invention An example of an image reading setting table according to the second embodiment of the present invention Flowchart showing operations related to image processing in FIG. 11 according to the second embodiment of the present invention An example of a notification screen related to image processing in FIG. 12 according to the second embodiment of the present invention

Specific embodiments of the present invention will be described in detail below with reference to the drawings.

(First embodiment)
The image reading system according to the first embodiment of the present invention includes an image reading device A and an information processing device 90 connected thereto, and FIG. 1 is a schematic diagram of the image reading device A according to the present embodiment of the present invention. It is a diagram.

<Apparatus Configuration>
The image reading device A is a device that conveys one or more conveying media S loaded on a paper feed tray 1 (original table) one by one through a route RT into the device, reads the images, and discharges the media to a discharge tray 2. The conveying media S to be read are, for example, sheets such as office paper, checks, paper bills, cards, etc., and may be thick or thin sheets. Examples of cards include insurance cards, driver's licenses, and credit cards. The conveying media S also include booklets such as passports. When a booklet is the target, a holder 100 described later can be used. By storing a booklet in an open state in the holder 100 and placing it on the paper feed tray 1, the booklet is conveyed together with the holder 100, and the image can be read. An original detection sensor 13 determines whether an original is placed on the paper feed tray 1. Various types of document detection sensors can be used, but in this embodiment, an optical sensor called a PI is used, which has an emitter and a receiver on one side and detects the presence or absence of a document based on the principle that when a document is placed on it, the light emitted from the emitter does not reach the receiver.

A first transport unit 10 is provided as a feeding mechanism that feeds the transport medium S along the route RT. In the case of the present embodiment, the first conveyance unit 10 includes a feed roller 11 and a separation roller 12 arranged opposite to the feed roller 11, and separates the conveyance medium S on the paper feed tray 1 one by one in the conveyance direction D1. Convey sequentially. A driving force is transmitted to the feed roller 11 from a drive unit 3 such as a motor via a transmission unit 5, and the feed roller 11 is rotationally driven in the direction of the arrow in the figure. The transmission unit 5 is, for example, an electromagnetic clutch, and connects and disconnects the driving force from the drive unit 3 to the feed roller 11.

For example, in this embodiment, the transmission section 5 that connects the drive section 3 and the feed roller 11 is in a state where driving force is transmitted during normal times, and when the conveyance medium S is reversely fed, the driving force is cut off. When the transmission of the driving force is cut off by the transmission section 5, the feed roller 11 becomes in a state where it can freely rotate. Note that such a transmission section 5 may not be provided when the feed roller 11 is driven in only one direction.

A separation roller 12 arranged opposite to the feed roller 11 is a roller for separating the conveyed medium S one by one, and is pressed against the feed roller 11 with a constant pressure. In order to ensure this press-contact state, the separation roller 12 is provided so as to be swingable and is configured to be biased toward the feed roller 11. The separation roller 12 receives driving force from the drive unit 3 via the torque limiter 12a, and is rotationally driven in the direction of the solid arrow.

Since the transmission of driving force is restricted by the torque limiter 12a, the separation roller 12 rotates in a direction (in the direction of the dashed arrow) that rotates with the feed roller 11 when it is in contact with the feed roller 11. As a result, when multiple conveying media S are conveyed to the pressure contact area between the feed roller 11 and the separation roller 12, two or more conveying media S are blocked so that they cannot be conveyed downstream except for one.

In this embodiment, the separation mechanism is configured by the separation roller 12 and the feed roller 11, but such a separation mechanism does not necessarily have to be provided. Any feeding mechanism may be used. In addition, when a separation mechanism is provided, instead of the separation roller 12, a separation pad that applies frictional force to the conveyed medium S may be brought into pressure contact with the feed roller 11 to perform the same separation operation. You can.

The second conveyance section 20 as a conveyance mechanism located on the downstream side of the first conveyance section 10 in the conveyance direction includes a drive roller 21 and a driven roller 22 that follows the drive roller 21. The conveyed medium S is conveyed to the downstream side thereof. A driving force is transmitted to the driving roller 21 from a driving unit 4 such as a motor, and the driving roller 21 is driven to rotate in the direction of the arrow in the figure. The driven roller 22 is pressed against the drive roller 21 with a constant pressure and rotates with the drive roller 21. The driven roller 22 may be biased against the drive roller 21 by a biasing unit (not shown) such as a spring.

The third conveyance section 30 located downstream of the second conveyance section 30 in the conveyance direction includes a drive roller 31 and a driven roller 32 that engages the drive roller 31. The conveyed medium S is conveyed to the discharge tray 2. In other words, this third transport section 30 functions as a discharge mechanism. A driving force is transmitted to the driving roller 31 from the driving unit 4 such as a motor, and the driving roller 31 is driven to rotate in the direction of the arrow in the figure. The driven roller 32 is pressed against the drive roller 31 with a constant pressure and rotates with the drive roller 31. The driven roller 32 may be biased against the drive roller 31 by a biasing unit (not shown) such as a spring.

An image reading unit 70 (reading section) arranged between the second transport section 20 and the third transport section 30 reads the image.

A double feed detection sensor 40 disposed between the first conveyance section 10 and the second conveyance section 20 detects when conveyance media S such as paper come into close contact with each other due to static electricity or the like and pass through the first conveyance section 10 ( In other words, this is an example of a detection sensor (a sensor that detects the behavior and state of sheets) for detecting this (in the case of a double feeding state in which sheets are conveyed in an overlapping manner). Various types of double feed detection sensor 40 can be used, but in the case of this embodiment, it is an ultrasonic sensor, which is equipped with an ultrasonic transmitting section 41 and an ultrasonic receiving section 42, and is capable of detecting a conveyance medium such as paper. Double feeding is detected based on the principle that the amount of attenuation of the ultrasonic waves passing through the conveyance medium S is different depending on whether S is conveyed in duplicate or conveyed one by one.

The medium detection sensor 50 is an example of an upstream detection sensor (a sensor that detects the behavior or state of a sheet) that is arranged upstream of the second transport unit 20 and downstream of the first transport unit 10, and detects the position of the transport medium S transported by the first transport unit 10, more specifically, whether the end of the transport medium S has reached or passed the detection position of the medium detection sensor 50. Various types of medium detection sensor 50 can be used, but in this embodiment, it is an optical sensor that has a light emitting unit 51 and a light receiving unit 52 and detects the transport medium S based on the principle that the received light intensity (amount of received light) changes when the transport medium S arrives or passes through.

In the case of this embodiment, when the leading edge of the conveyed medium S is detected by the medium detection sensor 50, the conveyed medium S reaches a position where double feeding can be detected by the double feeding detection sensor 40. The detection sensor 50 is provided near the double feed detection sensor 40 on the downstream side thereof. Note that the medium detection sensor 50 is not limited to the above-mentioned optical sensor, and for example, a sensor (such as an image sensor) capable of detecting the end of the conveyed medium S may be used, or a lever-shaped sensor that protrudes into the path RT may be used. It can also be a sensor.

A medium detection sensor 60 different from the medium detection sensor 50 is an example of a downstream detection sensor disposed upstream of the image reading unit 70 and downstream of the second conveyance section 20, and is an example of a downstream detection sensor disposed upstream of the image reading unit 70 and downstream of the second conveyance section 20. The position of the conveyance medium S conveyed by the unit 20 is detected. Various types of medium detection sensor 60 can be used, but in the case of the present embodiment, it is an optical sensor like the medium detection sensor 50, and includes a light emitting section 61 and a light receiving section 62, and detects the conveyance medium S. The conveyed medium S is detected based on the principle that the received light intensity (the amount of received light) changes depending on the arrival or passage of the medium. In the present embodiment, the medium detection sensors 50 and 60 are disposed on the upstream and downstream sides of the second conveyance section 20 in the conveyance direction, but only one of them may be used.

The image reading unit 70 is, for example, one that optically scans, converts it into an electrical signal, and reads it as image data, and is equipped with a light source such as an LED, an image sensor, a lens array, etc. inside, and a black A background board is provided. If the transport medium S is not present, the image reading unit 70 reads the background board. In the case of this embodiment, the image reading units 70 are arranged one on each side of the route RT, and read the front and back sides of the conveyance medium S. However, a configuration may also be adopted in which one is disposed only on one side of the route RT and only one side of the conveyance medium S is read. Further, in this embodiment, the image reading units 70 are arranged facing each other on both sides of the route RT, but they may be arranged at intervals in the direction of the route RT, for example.

The control section 8 will be explained with reference to FIG. FIG. 2 is a block diagram of the control section 8 of the image reading apparatus A.

The control section 8 includes a CPU 81 , a storage section 82 , an operation section 83 , a communication section 84 , an interface section 85 , an actuator 86 , and a sensor 87 .

The CPU 81 controls the entire image reading apparatus A by executing a program stored in the storage unit 82 . The storage unit 82 is composed of, for example, a RAM, a ROM, and the like. The operation unit 83 is composed of, for example, a switch, a touch panel, etc., and receives operations from an operator.

The communication unit 84 is an interface that performs information communication with an information processing device 90 such as a PC or a mobile phone. Examples of the communication unit 84 include a USB interface and a SCSI interface. In addition to such a wired communication interface, the communication unit 84 may also be a wireless communication interface, and may include both wired and wireless communication interfaces.

The interface section 85 is an I/O interface that inputs and outputs data to and from the actuator 86 and the sensor 87. The actuator 86 includes a drive section 3, a drive section 4, a transmission section 5, and the like. The sensor 87 includes the double feed detection sensor 40, the medium detection sensors 50 and 60, the image reading unit 70, and the like.

The information processing device 90 of FIG. 2 will be described with reference to FIG. 3. FIG. 3 is a block diagram of the information processing device 90 connected to the image reading device A.

The CPU 91 controls the entire external information processing device by executing programs stored in the storage unit 92 . The storage unit 92 is composed of, for example, a RAM, and stores computer programs, data received from a communication unit described below, and the like. The operation unit 93 includes, for example, a keyboard, a mouse, etc., and by operating the operation unit 93, the user can input various instructions to the CPU 91.

The communication unit 94 is an interface that performs information communication with the image reading device A. Examples of the communication unit 94 include a USB interface and a SCSI interface. In addition to such a wired communication interface, the communication unit 94 may also be a wireless communication interface, and may include both wired and wireless communication interfaces. The display section 95 is composed of a CRT, a liquid crystal screen, or the like, and can display the results of processing by the CPU 91 in the form of images, characters, and the like.

In the present embodiment, a process will be described in which the image reading apparatus A performs image reading processing of a mixed original set including a plurality of originals of different sizes.

To operate the present embodiment, the user installs an application AP for performing image processing on the information processing device 90 in advance. It is assumed that the installed application AP is stored in the storage unit 92 and operated by the processing of the CPU 91. At this time, the CPU 91 or the application AP functions as an image processing section.

To start the image reading process in this embodiment, the user first connects the image reading device A and the information processing device 90 with a USB cable or the like, and starts the application AP in the information processing device 90. As shown in FIG. 4, the application AP displays a screen with functions such as a scan button 110 for starting the image reading process, a settings button 111 for editing settings for the image reading process, and a file format selection list 112. Waits for some kind of instruction from the user.

When the user presses the settings button 111, the application AP displays a settings editing screen as shown in FIG. The application AP displays the items displayed on this settings editing screen based on the image reading settings table shown in FIG. In the settings editing screen in this embodiment, as shown in FIG. 5, the document type 113, document width and height 114 for determining the document type, characters written on the leading edge side of the document 115, and settings for reading the document. The color mode 116, resolution 117, and reading surface 118 can be set as follows.

Note that when the user registers image reading settings for a new document type on the settings editing screen shown in FIG. 5, a drop-down menu for the document type 113 is displayed and the user selects new registration as shown in FIG.

The user sets the image reading settings for each type of document and presses the registration button 120. When the registration button 120 is pressed, the application AP saves the image reading setting information in the memory unit 92 as the image reading setting table shown in FIG. 7. As shown in FIG. 7 as an example, the image reading setting table stores the document type, size information consisting of the document width and height, document content information consisting of a character string written at the leading edge of the document, and reading settings consisting of color mode, resolution, and reading surface in association with each other. Note that these are examples of the document type, size information, content information which is the written information written on the document, and reading settings, and are not limited to these.

In this embodiment, it is assumed that the application AP is registered with image reading settings corresponding to four types of documents.

When the user presses the back button 119, the application AP returns to Figure 4.

Note that in this embodiment, the width and height of the document and the characters written on the leading edge of the document are used to determine the type of document from the image of the leading edge of the document, but this is not the case. In addition, although the reading settings are color mode, resolution, and reading surface, the present invention is not limited thereto.

When the user presses the scan button 110 shown in FIG. 4, the application AP instructs the image reading device A to start image reading processing. At this time, the application AP creates a setting that provides the highest image quality among the image reading settings registered in the image reading setting table shown in FIG. 7, and notifies the image reading apparatus A of the setting. In this embodiment, the application AP sets the color mode to color and the resolution to 600 dpi according to the image reading setting table in the state shown in FIG. Further, the subsequent processing of the application AP will be described later.

Next, the processing of the image reading device A when the image reading process is started will be described. FIG. 8 is a flowchart showing the operation of image reading device A.

When the user starts the image reading process, the document detection sensor 13 of the image reading device A determines whether or not a document exists in the paper feed tray 1 (S1001). When the document detection sensor 13 detects a document (Yes in S1001), the control section 8 of the image reading apparatus A starts driving the first conveyance section 10 (S1002). At this time, the plurality of originals stacked on the paper feed tray 1 are conveyed one by one starting from the lowest original. Further, if the document detection sensor 13 does not detect a document (No in S1001), the image reading device A notifies the information processing device 90 to end the image reading process (S1008), and ends the image reading process. shall be.

During the conveyance, the image reading apparatus A starts a process of detecting the size of the document using the medium detection sensor 60 (S1003). The detailed operation of the process of detecting the size of the document will be described later. At this time, the medium detection sensor 60 or the CPU 81 functions as a size detection section.

Subsequently, the image reading unit 70 starts reading the document transported by the second transport section 20 at a timing based on the detection result of the medium detection sensor 60 (S1004). At this time, the control unit 8 also stores information on the front and back sides of the document.

When the control unit 8 of the image reading device A determines that the image reading unit 70 has finished reading the original (the trailing edge of the original has been read) (Yes in S1005), it performs a size detection process on the original (S1006). ).

Here, the document size detection process will be explained. When the control unit 8 starts sampling in the medium detection sensor 60 in S1003, as shown in FIG. , the time when the threshold value changes from below to above the predetermined threshold value is stored as the time (t2) when the trailing edge of the document was detected. Further, the control unit 8 calculates the time from the time when the leading edge of the document is detected (t1) to the time when the trailing edge of the document is detected (t2) in S1006 as the time during which the paper is conveyed (Δt). Then, the control unit 8 calculates the height (size) of the document from the conveyance speed and Δt determined by the combination of resolution and color mode among the image reading settings.

In the image reading unit 70, since the color of the background plate is black in this embodiment, the amount of light received by the image sensor is small when the document is not being transported, and increases when the document is transported. The amount of light received by the image sensor while the document is being transported, acquired by the control unit 8, is shown in FIG. 10. At this time, the control unit 8 detects the pixel that switches from below a predetermined threshold to above it as the left edge pixel (p1) of the document, and the pixel that switches from above the predetermined threshold to below it as the right edge pixel (p2) of the document, and calculates the document width from the number of pixels (Δp) from p1 to p2 and the resolution of the image reading settings.

Note that in the document size detection processing in S1006 and S1007, an error may occur from the actual size due to the inclination of the document during conveyance or changes in conveyance speed due to the thickness of the document. method to determine whether they are the same.

The control unit 8 transmits image information linking the image data acquired in S1004, the image height and width size information acquired in S1006, and the front and back information of the document to the application AP in the information processing device 90 (S1007). Finally, the control unit 8 ejects the document that has been read onto the ejection tray 2 by the third conveying unit 30. The control unit 8 repeats the operations from S1001 to S1007 until there are no documents left on the paper feed tray, and when there are no documents left, notifies the application AP of the end of processing (S1008) and ends the image reading process.

Next, the operation of the application AP within the information processing device 90 will be explained. FIG. 11 is a flowchart showing the operation of the application AP when the image reading process is started.

When the user presses the scan button 110 in FIG. 4, the application AP instructs the image reading device A to start image reading processing (S2001). At this time, as described above, the application AP sets the color mode to color and the resolution to 600 dpi to obtain the highest image quality, based on the image reading setting table shown in FIG. 7 registered in advance in the storage unit 92. Notify image reading device A of the settings.

The application AP periodically checks whether the scan is completed after instructing the image reading device A to start the image reading process until being notified of the end of the process (S2002).

If image reading device A is scanning (No in S2002), application AP checks whether it has received image information sent from image reading device A (S2003).

When the application AP receives image information from the image reading device A, it sequentially adds the image information to the image information table shown in FIG. 12 in the storage unit 92 (S2004).

In this embodiment, for example, when a slip and an application form are transported, image information is transmitted from the image reading device A in the order of the slip (front), the slip (back), the application form (front), and the application form (back). be done. At this time, the image reading device A transmits the image conveyance order, size information, and conveyance surface. These information and the image storage address are stored in an image information table as shown in FIG. Note that there may be some errors in the size detection process of the document performed by image reading device A, so the sizes may differ between the front and back sides, but it can be determined whether they are the same by comparing the areas described later. .

Next, the application AP searches the image reading setting table of FIG. 7 registered in the storage unit 92 for the image reading setting corresponding to the image size in the image information table, and obtains the image reading setting (S2005). Details of this processing operation will be described later.

The application AP starts image processing according to the settings acquired in S2005 (S2006). Therefore, in S2005, the application AP detects the image data of the conveying orders 1 and 2 as slips, and detects the image data of the conveying orders 3 and 4 as application forms. At this time, the application AP performs image processing on the image data of the conveying order 1 as black and white, 300 dpi data, according to the image reading setting table in FIG. 7, and deletes the image data of the conveying order 2 because it is the back side. Note that the image data of the conveying order 3 has a width of 212, which is slightly different from the setting value stored in the image reading setting table, but the application AP is configured to determine that the image data of the conveying order 3 is an application form because the setting allows for a preset margin as described below. At this time, the image may be enlarged, reduced, trimmed, or other processing to match the setting value stored in the image reading setting table.

The image data for which image processing has been completed is added to the processed image table shown in FIG. 15 in the storage section 92. This processed image table can store the transport order, original size, and image storage address. The application AP performs the processes from S2002 to S2006 until it is notified from the image reading device A that the image reading process is finished.

When the image reading device A notifies the end of the image reading process (S2002: Yes), the application AP creates an image file based on the processed image table of FIG. 15 (S2007). After creating the image file, the application AP ends the image reading process.

Here, the process of acquiring image reading settings will be described with reference to the flowchart in Fig. 13. The application AP acquires image reading settings from the area S and aspect ratio R based on the document width and height shown in Fig. 7 and Fig. 12. The calculation formulas for the area S and aspect ratio R are shown below. The aspect ratio R is calculated to always be a value of 1 or more, taking into consideration the case where, for example, an A4 document is transported landscape.
Area S = width W x height H
Aspect ratio R = width W ÷ height H (when W > H)
Aspect ratio R = height H ÷ width W (if H > W)

First, the application AP obtains size information of the image being processed from the image information table of FIG. 12 stored in the memory unit 92, and obtains the area S1 of the image being processed (S3001).

Next, the application AP searches the image reading setting table of FIG. 7 for each size. At this time, if the image reading setting table is not the last row (No in S3002), the application AP obtains the area S0 and the aspect ratio R0 from the size information registered in the image reading setting table (S3003).

Next, the application AP checks whether the ratio of the respective image areas S1 and S0 is within a predetermined value x, taking into account errors in size detection that occur when the document is transported (S3004).

If the area ratio S1/S0 is within a predetermined value, the application AP determines whether the ratio of the respective aspect ratios R1 and R0 is within a predetermined value y in order to distinguish between documents that have the same image area but different lengths and widths. It is confirmed whether it is possible (S3005).

If the aspect ratio R1/R0 is within a predetermined value, the application AP recognizes the characters written at the leading edge of the document from the image information using OCR, which is a well-known technology (S3006). At this time, the application AP functions as a written content detection unit.

Next, the application AP searches the image reading setting table of FIG. 7 for each character that matches the recognized character (S3007). If the characters match, the application AP acquires the image reading settings (S3008). Also, if the area ratio S1/S0 is not within the predetermined value x (No in S3004), or if the aspect ratio R1/R0 is not within the predetermined value y (No in S3005), or if the characters match. If not (No in S3007), the application AP returns to S3002 and searches for image reading settings for other sizes.

If the image reading setting table is at the last row in S3002 (Yes in S3002), the application AP displays a screen like that in FIG. 14 on the display unit 95 to allow the user to select the image reading setting corresponding to the image being processed (S3009), and obtains the image reading setting.

Note that if there are no registered image reading settings, if you select new registration, the application AP will display the settings editing screen as shown in Figure 5. Select and set new registration as shown in step 6.

In this embodiment, the process of performing image reading processing corresponding to each document size based on the size information of each document detected within image reading device A and the character information written on the leading edge of the document has been shown, but in addition to document size, other methods for determining the type of document during transport include the thickness of the document and the presence or absence of double feeding. In addition, the type of document can also be determined by detecting the document color, character color, character size, character position, character orientation, etc. Therefore, this embodiment is merely an example, and the type of document may be determined based on other setting items and image reading processing may be performed.

The file format selection list 112 in FIG. 4 allows you to select the format in which image data is saved, but by adding a file format item to the image reading setting table, you can also specify the format in which image data is saved for each size. Furthermore, in the flowchart in FIG. 11, the application AP sorts the processed image table in the order of transport as shown in FIG. 15, so that the image files are saved in the order of transport, but the order in which the image files are saved can also be changed by sorting this processed image table by size.

Furthermore, in this embodiment, registration of image reading settings, image processing, image file generation processing, etc. are all performed using the application AP installed in the information processing device 90, but these processes are performed within the image reading device A. The CPU 81 may complete the process. At this time, in this embodiment, it is assumed that all the information related to the image reading settings as shown in FIG. 7 stored by the application AP is registered in the storage unit 82.

(Second embodiment)
In this embodiment, the type of document is determined using a method different from that in the first embodiment. In the first embodiment, the type of document was determined based on the size information of each document and the character information written at the leading edge of the document, but in this embodiment, the size information of each document and which corners of the document are missing are determined. The type of document is determined based on the information. Since the basic configuration is the same as that of the first embodiment, the explanation will be omitted, and only the differences will be explained below.

Figure 16 shows the edit setting screen of this embodiment. When the user presses the setting button 111 in Figure 4, the application AP displays a setting edit screen as shown in Figure 16. The application AP displays based on the image reading setting table shown in Figure 18. On the setting edit screen, it is possible to set the document type 113, the document width and height 114 for determining the document type, the position 122 of the diagonal corners of the document, and the color mode 116, resolution 117, and reading surface 118 for the document reading settings. When registering new image reading settings in Figure 16, the drop-down menu for document type 113 is displayed and new registration is selected as shown in Figure 17.

The user makes image reading settings for each type of document and presses the registration button 120. The application AP that has pressed the registration button 120 stores the setting information in the storage unit 92 as an image reading setting table shown in FIG.

In this embodiment, it is assumed that the application AP is registered with image reading settings corresponding to four types of documents.

When the user presses the back button 119, the application AP returns to Figure 4.

Note that in this embodiment, the width and height of the document and the position of the slanted corner among the four corners of the document are used to determine the type of document from the image at the leading edge of the document, but this is not the case. . In addition, although the reading settings are color mode, resolution, and reading surface, the present invention is not limited thereto.

When the user presses the scan button 110, the application AP instructs the image reading device A to start image reading processing. At this time, the application AP creates settings for the highest image quality based on the image reading setting table shown in FIG. 18, and notifies the image reading apparatus A of the settings. In this case, the application AP sets the color mode to color and the resolution to 600 dpi based on FIG. Further, the subsequent processing of the application AP is the same as in the first embodiment except for the procedure for acquiring the image reading settings from the image reading settings table of FIG. 18 registered in the storage unit 92.

Next, the process for acquiring image reading settings in this embodiment will be explained using the flowchart in FIG.

The application AP acquires image reading settings from the area S and aspect ratio R, as described in the first embodiment, based on the document width and height shown in FIGS. 18 and 12.

First, the application AP obtains the size information of the image being processed from the image information table of FIG. 12 stored in the storage unit 92, and obtains the area S1 of the image being processed (S4001).

Next, the application AP searches the image reading setting table of FIG. 18 for each size. At this time, if the image reading setting table is not the last row (No in S4002), the application AP obtains the area S0 and aspect ratio R0 from the size information registered in the image reading setting table (S4003).

Next, the application AP checks whether the ratio of the respective image areas S1 and S0 is within a predetermined value x, taking into account errors in size detection that occur when the document is transported (S4004).

If the area ratio S1/S0 is within a predetermined value, the application AP determines whether the ratio of the respective aspect ratios R1 and R0 is within a predetermined value y in order to distinguish between documents that have the same image area but different lengths and widths. It is checked whether it is possible (S4005).

If the aspect ratio R1/R0 is within a predetermined value, the application AP detects the position of a diagonal corner among the four corners of the document from the image information (S4006).

Next, the application AP searches the image reading setting table of FIG. 18 for a corner that matches the position of the detected corner (S4007). If the corner positions match, the application AP acquires the image reading settings (S4008). Also, if the area ratio S1/S0 is not within the predetermined value x (No in S4004), or if the aspect ratio R1/R0 is not within the predetermined value y (No in S4005), or if the corner position is If they do not match (No in S4007), the application AP returns to S4002 and searches for image reading settings for other sizes.

If the image reading setting table is at the last row in S4002 (S4002, Yes), the application AP displays a screen like that shown in FIG. 20 on the display unit 95 to allow the user to select the image reading setting corresponding to the image being processed (S4009), and obtains the image reading setting.

Note that if there are no registered image reading settings, if you select New Registration, the application AP will display the settings editing screen as shown in Figure 16. Select and set new registration as shown in step 17.

This embodiment shows a process of performing image reading processing corresponding to each document size based on the size information of each document detected in the image reading device A and information on which corner of the document is missing. However, in addition to the document size, other means for determining the type of document during transportation include the thickness of the document and the presence or absence of double feeding. Furthermore, the oblique corner among the four corners of the document may be folded diagonally by the user before processing, as well as depending on the shape of the document. Furthermore, the type of document can be determined not only by detecting the oblique corners among the four corners of the document, but also by detecting the position of punch holes, the number of punch holes, and the like. Therefore, this embodiment is just an example, and the type of document may be determined based on other setting items that appear in the shape of the document, and the image reading settings may be acquired. In addition, even if the shape of the document is not the same, parameters that can be detected by an optical sensor such as the medium detection sensor 60 or a document shape detection section such as the double feed detection sensor 40 (document transparency, overlapping situation, thickness) are set as items. The document type may be determined as follows, and the image reading settings may be obtained.

Note that in each of the embodiments described above, an embodiment in which the image reading process is started via the screen shown in FIG. It may be configured so that That is, when the image reading device A or the application AP is instructed to execute a specific mode such as automatic form discrimination mode, the process described in the above embodiment is executed, and other modes are not executed. If execution is input to image reading device A or application AP, image reading is executed using the image reading settings selected in advance from the image reading settings registered in the image reading settings table shown in FIG. It may be configured so that For example, when reading multiple documents of a specific type in succession, it is better to select the image reading settings from the image reading settings table in advance and perform image reading to reduce the image processing load after scanning. , or reading can be performed at high speed.

Further, in each of the embodiments described above, the image processing is performed by acquiring the corresponding image reading settings from the image reading setting table according to the size of the read original and the contents of the original. is not limited to this.

For example, if there is only one image reading setting registered in the image reading setting table that corresponds to a certain document size, the corresponding image reading setting may be obtained without referencing the contents of the document.

Alternatively, the configuration may be such that one image reading setting can be stored in association with only the size of the document, and the image reading setting is read from the image reading setting table according to the size of the read document.

Further, in these cases, the orientation of the character string, which is an example of the contents of the document, may be detected, and the image reading settings may be obtained from the image reading setting table using the orientations of the document.

Further, the detection result of the double feed detection sensor 40 may be used as an example of the content of the document. For example, for a document transported with A3 paper in a half-folded state and an A4 document, the size of the document (A4 The configuration may be such that the image reading settings are acquired from the image reading setting table using the size) and the detection result of the double feeding detection sensor 40 (double feeding is detected in the case of half-folding of A3 paper).

Furthermore, in each of the embodiments described above, image reading is performed with the settings that provide the highest image quality among the image reading settings registered in the image reading setting table, and then the corresponding image reading settings are performed based on the document size, etc. We have explained how to perform image processing according to the following. The present invention detects the size of the document using the medium detection sensor 60 and other detection sensors disposed upstream of the image reading unit 70, and changes the image reading settings of the image reading unit 70 based on the result to detect the image. It may be configured to perform reading. Even in this case, it is possible to output an image that has been subjected to image processing using image reading settings associated with the size of the document, and it is possible to improve convenience for the operator.

The present invention can be utilized by changing a part of each aspect explained above, and various changes can be made without departing from the spirit of the present invention, such as using them in appropriate combinations. be.

A Image reading device I (image processing) application S Transport medium 1 Paper feed trays 3, 4 Drive section 8 Control section 9 Medium detection sensor 10 First transport section 13 Document detection sensor 20 Second transport section 30 Third transport section 40 Heavy Feed detection sensor 50 Medium detection sensor 60 Medium detection sensor 70 Image reading unit 81 CPU
82 Storage unit 83 Operation unit 84 Communication unit 90 Information processing device 91 CPU of information processing device
92 Storage unit 93 of the information processing device Operation unit 94 of the information processing device Communication unit 95 of the information processing device Display unit of the information processing device

Claims (8)

a reading section that reads the document conveyed from the document table;
a storage unit that associates and stores document size and image reading settings;
an image processing unit that performs image processing on the image read by the reading unit,
The image reading system is characterized in that the image processing unit performs image processing using the image reading settings stored in the storage unit and associated with the size of the document read by the reading unit. 2. The image processing section performs image processing using the image reading settings stored in the storage section and associated with the size and content of the document read by the reading section. Image reading system described in . The image reading system according to claim 1, further comprising a size detection section that detects the sizes of the documents that are sequentially conveyed. 4. The image reading system according to claim 3, wherein the size detection section is arranged upstream of the reading section in the transport direction. It has a description content detection unit that detects content information of the manuscript,
4. The image reading system according to claim 3, wherein the content of the document includes content information of the document detected by the written content detection section. The image processing section stores image reading settings for the document size and document content information registered in advance by the user, and stores the document size detected by the size detection section and the image reading settings detected by the written content detection section. 6. The image reading system according to claim 5, wherein image processing of each document is performed based on the image reading settings stored in the storage unit in accordance with the content information. It has a document shape detection section that detects the shape of the document,
4. The image reading system according to claim 3, wherein the content of the document includes a shape of the document detected by the document shape detection section. The image processing section stores image reading settings for the document size and document shape registered in advance by the user, and stores the document size detected by the size detection section and the image reading settings detected by the document shape detection section. 8. The image reading system according to claim 7, wherein image processing of each original is performed based on the image reading settings stored in the storage unit according to the shape of the original.

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