JP2017135438A - Scanner and image production method - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a technique for improving the picture quality of a scanned picture.SOLUTION: A scanner including a transfer mechanism for transferring multiple scripts continuously, a sensor for reading the transferred script, and a control unit for correcting the picture read by the sensor by using a correction value, is further provided with: a calculation unit for calculating the correction value based on the N-th (N is a natural number) correction level, i.e., the result of a reference region read by the sensor after the N-th script has passed through the sensor until the (N+1)th script arrives at the sensor; and a storage unit for storing the correction values sequentially in any one of multiple storage regions. Upon completion of storage of the calculated correction values, the control unit switches the storage region for reading the correction values used for correction to the storage region storing the calculated correction values.SELECTED DRAWING: Figure 3

Description

  The present invention relates to a scanner and an image production method.

  A technique for obtaining correction data for performing shading correction prior to reading a document is known (see Patent Document 1). Specifically, correction data is obtained based on white reference image data obtained by reading a white reference plate.

JP 2009-200599 A

However, in order to obtain correction data for shading correction, it is necessary to read a reference subject like a white reference plate, and the correction value for shading correction cannot be updated while the original is being read continuously. There was a problem. Accordingly, when the characteristics of the sensor or the like change while continuously reading the document, the image quality of the scanned image is deteriorated.
The present invention was created to solve such problems, and an object of the present invention is to provide a technique for improving the quality of a scanned image.

  In order to solve the above problems, a scanner according to the present invention corrects a transport mechanism that transports a plurality of documents continuously, a sensor that reads the transported documents, and a correction value for a read image read by the sensor. And a control unit that performs a scanning operation, and the sensor reads the reference area after the Nth (N is a natural number) document passes through the sensor and before the (N + 1) th document reaches the sensor. A calculation unit that calculates a correction value based on the Nth correction level that is a result of the correction, and a storage unit that sequentially stores the correction value in any of a plurality of storage areas when the correction value is calculated, When the storage of the calculated correction value is completed, the control unit switches the storage area from which the correction value used for correction is read to the storage area in which the calculated correction value is stored.

  In the above configuration, the correction value is calculated based on the correction level at which the sensor reads the black reference after the Nth document passes through the sensor and until the (N + 1) th document reaches the sensor. Since the correction value is stored in one of the plurality of storage areas, the correction value can be stored in a storage area different from the storage area from which the control unit reads the correction value. Accordingly, it is possible to update the correction value even during a period in which the document is continuously read, and the read image can be corrected based on the updated correction value.

  Note that the function of each unit recited in the claims is realized by hardware resources whose function is specified by the configuration itself, hardware resources whose function is specified by a program, or a combination thereof. The functions of these means are not limited to those realized by hardware resources that are physically independent of each other. Furthermore, the present invention is also established as a scan system, a scan method, a scan program, and a scan program recording medium. Of course, the recording medium may be a magnetic recording medium, a magneto-optical recording medium, or any recording medium developed in the future.

1A is a block diagram of the scanner, and FIGS. 1B and 1C are schematic sectional views of the scanner. It is a flowchart of a continuous scanning process. 3A and 3B are timing charts of the continuous scanning process. 4A and 4B are timing charts of the continuous scan processing according to the second embodiment. It is a flowchart of the continuous scanning process of 3rd Embodiment. 6A and 6B are timing charts of the continuous scan processing according to the third embodiment.

Here, embodiments of the present invention will be described in the following order.
(1) Scanner configuration and processing:
(2) Scanner operation timing:
(3) Second embodiment:
(4) Third embodiment:
(5) Other embodiments:

(1) Scanner configuration and processing:
FIG. 1A is a block diagram of a scanner 1 according to an embodiment of the present invention. The scanner 1 includes a controller 10, an image sensor 20, an illumination unit 30, and a transport mechanism 40. The controller 10 includes a recording medium (not shown), a general-purpose processor that reads and executes a program from the recording medium, and a dedicated circuit such as an ASIC that is a semiconductor circuit configured to execute specific processing.

  The image sensor 20 is a linear linear image sensor in the main scanning direction, and is a sensor that reads a conveyed document. The image sensor 20 includes a large number of light receiving elements that generate a current having a magnitude corresponding to the received light intensity, and the light receiving elements are arranged in the main scanning direction. In the present embodiment, the position of the image sensor 20 is assumed to be constant. The illumination unit 30 includes a light source that generates illumination light for a document and an optical system that guides the illumination light to the document. The illumination light reflected from the document is received by each light receiving element of the image sensor 20, and each light receiving element outputs a current having a magnitude corresponding to the received light intensity of the illumination light. The image sensor 20 includes an AEF (analog front end) 20a including a circuit that amplifies a current output according to the received light intensity of illumination light and a circuit that performs A / D conversion. The image sensor 20 outputs a read image indicating the gradation value of the received light intensity of the illumination light to the controller 10 for each pixel corresponding to the light receiving element.

  The transport mechanism 40 is an auto sheet feeder that transports a document in the sub-scanning direction, which is a direction orthogonal to the main scanning direction, and continuously transports a plurality of documents. The transport mechanism 40 picks up documents one by one from a document table on which a plurality of documents are placed, and starts conveying the next document while the document is being conveyed. Then, the document is conveyed so that a plurality of documents pass through the image sensor 20 continuously one by one. Although not shown, the transport mechanism 40 includes an optical document edge sensor. The controller 10 detects the leading and trailing transport positions of the document based on the detection signal of the document edge sensor and the driving amount of the transport mechanism 40.

  1B and 1C are schematic cross-sectional views of the scanner 1, and are views of the cross-section of the scanner 1 viewed from the main scanning direction. As shown in FIGS. 1B and 1C, the document is conveyed in the sub-scanning direction (left to right) that is a direction orthogonal to the main scanning direction (direction perpendicular to the paper surface). The light receiving surface of the image sensor 20 is set to the upward direction on the paper. Between the original and the light receiving surface of the image sensor 20, there is a platen glass 60 through which illumination light is transmitted. The controller 10 obtains a read image for each position in the sub-scanning direction by causing the image sensor 20 to repeatedly perform image capturing at a predetermined image capturing period while conveying a document on the image sensor 20. The controller 10 obtains a two-dimensional read image by arranging the read images for each position in the sub-scanning direction. The controller 10 performs black correction and white correction on the gradation value of each pixel of the read image. As a result, the read image is corrected so that a gradation value of the minimum gradation (0) means black and a gradation value of the maximum gradation means white. The Rukoto. The scanner 1 may perform a color scan for acquiring gradation values for each RGB channel, but a case where a grayscale scan is performed will be described as an example for simplification of description.

  As shown in FIG. 1B, any time on the image sensor 20 after the end of the Nth document passes over the image sensor 20 until the top of the (N + 1) th document reaches the image sensor 20. There is a period in which no original exists (hereinafter referred to as the Nth no original period). N is a natural number representing the transport order of documents. For example, as shown in FIG. 1C, after the end of the (N + 1) th document passes over the image sensor 20 and before the top of the (N + 2) th document reaches the image sensor 20, The (N + 1) th no-document period occurs. During these no-document periods, the document cover 50 faces the light receiving surface of the image sensor 20. A reference area which is an area facing the image sensor 20 in the document cover 50 is formed of a uniform white member having a reflectance of almost 100%. Imaging the reference area with the image sensor 20 in the state where the illumination light is irradiated means imaging the white reference, and imaging the reference area with the image sensor 20 in the state where the illumination light is not irradiated is black reference. Is taken.

  FIG. 2 is a flowchart of a continuous scan process that starts when an instruction to start continuous scan is given. Hereinafter, processing of each functional configuration 11 to 13 of the controller 10 will be described according to a flowchart. First, the controller 10 performs calibration (step S100). Calibration is a process of adjusting the lighting time of the illumination unit 30, the amplification gain in the AEF 20a, and the like.

  Next, the controller 10 prepares an initial black correction value (step S110). In step S110, the image sensor 20 images the reference area of the document cover 50 a specified number of times without irradiating illumination light. The calculation unit 12 calculates an initial black correction value by averaging the black level (correction level) that is the gradation value indicated by each pixel of the plurality of read images for each pixel. The storage unit 13 stores the black correction value of each pixel in the storage area R1. The black correction value is a gradation value corresponding to the current value output by the light receiving element in a state where no illumination light is received, and ideally, all pixels have the minimum gradation. However, a value other than the minimum gradation is obtained as the black correction value due to temperature characteristics of the light receiving element, manufacturing variations, and the like. In particular, in a pixel corresponding to a light receiving element near the AEF 20a that easily generates heat, the black correction value is likely to change.

  Next, the controller 10 prepares a white correction value (step S120). In step S120, the image sensor 20 captures the reference area of the document cover 50 a predetermined number of times while irradiating illumination light. The calculation unit 12 calculates a white correction value by averaging the white level, which is the gradation value indicated by each pixel of the plurality of read images, for each pixel. The storage unit 13 stores the white correction value of each pixel in a storage area (not shown). The white correction value is a gradation value corresponding to the current value output by the light receiving element in a state where the white plate is imaged, and ideally, all the pixels have the maximum gradation. However, a value other than the maximum gradation is obtained as the white correction value due to manufacturing variation of the light receiving element. Further, the controller 10 detects an abnormal light receiving element based on the black level in step S110 and the white level in step S120, and stores information for specifying the abnormal light receiving element. You may make it memorize | store a specific value as a black correction value and white correction value of the pixel corresponding to the said imaging pixel. For example, the controller 10 determines that the imaging pixel is abnormal when the black level and the white level have the same value. The controller 10 stores the specific value as the black correction value for the pixel corresponding to the abnormal light receiving element. The specific value may be a gradation value that can be distinguished from a normal black correction value. For example, the maximum gradation that originally means white may be stored as the specific value.

  Next, the scanner 1 scans the document (step S130). Hereinafter, a case where the Nth document is scanned will be described as an example. The transport mechanism 40 transports the document so that the top to the end of the Nth document passes over the image sensor 20. At this time, the illumination unit 30 irradiates illumination light, and the image sensor 20 repeatedly captures an image of a document at a predetermined imaging cycle. In this embodiment, the imaging cycle is constant, and the controller 10 increases the scan resolution in the sub-scanning direction by decreasing the document conveyance speed.

  When the read image of the Nth original is obtained, the control unit 11 performs black correction with the black correction value (step S200). For example, if the gradation value of a certain pixel is 20 and the black correction value is 20, the control unit 11 corrects the gradation value of the pixel to 0. Thereby, it can correct | amend so that the said pixel may show black. The control unit 11 uses, for black correction, the black correction value stored in the storage areas R1 and R2 that are switched to be read out of the two storage areas R1 and R2. The storage unit R1, R2 to be read is switched by the control unit 11 in the process described later. In addition, for a pixel in which a specific value is stored as a black correction value, the gradation value obtained from the image sensor 20 is discarded and, for example, a gradation value derived by pixel interpolation using peripheral pixels is associated.

  Although not shown, in addition to black correction, the control unit 11 performs various image processing (white correction, γ correction, pixel interpolation, etc.) on the read image in step S200 to generate a final read image. Then, final read images for all the originals are output. The process of step S200 is performed in parallel with steps S140 and S320 to S360 described later.

  When the end of the Nth document passes over the image sensor 20, the controller 10 captures the black reference to acquire the black level, and stores the storage area R0 (not shown in the storage areas R1 and R2 that are not to be read). May be stored) (step S140). Specifically, after resetting to 0 before starting accumulation, every time the black level is acquired, the output value of each pixel of the image sensor 20 is added to the position corresponding to each pixel in the storage area R0. As shown in FIG. 1B, the Nth no-document period, which is the period from the end of the Nth document passing over the image sensor 20 until the beginning of the (N + 1) th document reaches the image sensor 20. The black level is acquired by capturing the black reference. In the present embodiment, it is assumed that the black reference is imaged X times (X = 32) in one non-document period. Therefore, the controller 10 obtains 32 black reference captured images in which each pixel indicates a black level. If the distance between the originals in the transport direction is divided by the transport speed to obtain a non-original period, and X is set so that the period obtained by multiplying the imaging cycle by X is smaller than the non-original period. Good.

  When the black level is acquired, the controller 10 determines whether there is a next original (step S150). When it is determined that there is a next document (step S150: Y), the controller 10 returns to step S130 and scans the next document. On the other hand, when it is not determined that there is a next original (step S150: N), the controller 10 ends the continuous scanning process. If the determination in step S150 is performed before step S140 and it is determined that there is a next original, the black level is acquired in step S140 and the process returns to step S130. If it is not determined that there is a next original, step S140 is performed. You may complete | finish without performing S140.

  When the black level is acquired in step S140, the next original is scanned, and the processing for the black level (steps S320 to S360) is executed in parallel with the next original scan. First, the calculation unit 12 determines whether or not black level accumulation has been completed (step S320). Specifically, the calculation unit 12 determines whether or not a specified number Y (= X × s) of black-based captured images has been accumulated. That is, it is determined whether or not Y black levels are accumulated for each pixel. s is a natural number that means the number of non-document periods required for black level accumulation, and in this embodiment, s = 2 (Y = 64). In the present embodiment, the black level accumulation is completed every time the no-document period comes twice. Assuming that the no-document period at which black level accumulation starts is the Nth no-document period, the Nth black level read by the image sensor 20 in the Nth no-document period and the Mth (M = N + 1) absence The accumulation of the black level is completed when the Mth black level read by the image sensor 20 is accumulated in the document period. Of course, s may be a natural number other than 2.

  When it is not determined that the black level accumulation is completed (step S320: N), the calculation unit 12 returns to step S320. On the other hand, when it is determined that the accumulation of the black level is completed (step S320: Y), the calculation unit 12 calculates a black correction value (step S330). That is, the calculation unit 12 waits until the (N + 1) th original reaches the image sensor 20 after the Nth (N is a natural number) original passes through the image sensor 20 (Nth no original period). A black correction value is calculated based on the Nth black level that is the result of the sensor reading the reference area. However, if the accumulation of Y black levels is not completed in only one non-document period, the calculation unit 12 causes the Nth black level and the Mth (M = N + 1) document to pass through the sensor. After that, the black correction value is calculated by combining with the Mth black level, which is the result of the sensor reading the black reference, until the (M + 1) th original reaches the sensor.

  Specifically, the calculation unit 12 calculates the average value as the black correction value by dividing the total value of the Y black levels accumulated for each pixel by Y. The black correction value is not necessarily an average value of the black level, and may be a mode value or a median value as long as the black level is stored so as to be distinguishable every time the black level is acquired. It may be.

  Next, the storage unit 13 stores the calculated black correction value in the storage areas R1 and R2 that are not to be read (step S340). That is, when the black correction value is calculated, the storage unit 13 sequentially stores the black correction value in one of the plurality of storage areas R1 and R2. Specifically, the black correction value calculated is stored in the storage areas R1 and R2 that are not currently switched as the reading target out of the two storage areas R1 and R2. Further, when storing the black correction value in the storage areas R1 and R2 that are not to be read, the storage unit 13 specifies a pixel in which the specific value is currently stored in the storage areas R1 and R2 to be read, and the pixel Is stored as a black correction value. That is, for the pixels corresponding to the abnormal light receiving elements, the specific value continues to be copied between the storage areas R1 and R2 as the black correction value. Therefore, it is possible to prevent black correction from being performed based on the black correction value obtained from the abnormal light receiving element even when the storage areas R1 and R2 to be read are switched.

Next, the storage unit 13 determines whether or not the calculated black correction value is normal (step S350). The storage unit 13 derives the statistical values of the calculated black correction values of i pixels (the maximum value H _R among all the pixels, the minimum value L _R among all the pixels, and the total value S _{R of} all the pixels). To do. Similarly, the storage unit 13 stores the statistical value of the black correction value of each pixel used for black correction (the maximum value H _U among all pixels, the minimum value L _U among all pixels, and the total value of all pixels). S _U ) is derived. Note that the statistical value may be stored in advance, or the stored statistical value may be read out. Here, if the calculated black correction value is stored in the storage area R1, the black correction value used for the black correction is stored in the other storage area R2. On the contrary, if the calculated black correction value is stored in the storage area R2, the black correction value used for the black correction is stored in the other storage area R1. Note that specific values are excluded in the calculation of statistical values. The storage unit 13 determines that the calculated black correction value is normal when all of the following equations (1) to (3) are satisfied.
H _R ≦ H _U + E (1)
L _R ≧ L _U −E (2)
S _U −E × i / 2 ≦ S _R ≦ S _U + E × i / 2 (3)

Here, E is a predetermined value. Here, the same value is used as E for all equations, but a different value may be used for each equation. According to the equation (1), the calculated maximum black correction value H _R is not more than a value obtained by adding an allowable error (= E) to the maximum black correction value H _U used for black correction. Can guarantee. According to Equation (2), the calculated minimum black correction value L _R is not less than a value obtained by subtracting an allowable error (= E) from the minimum black correction value L _U used for black correction. Can guarantee. According to equation (3), the calculated total value S _R of black correction values is a value obtained by adding an allowable error (= E × i / 2) to the total value S _U of black correction values used for black correction. The calculated black correction value total value S _R is not less than a value obtained by subtracting an allowable error (= E × i / 2) from the total black correction value S _U used for black correction. You can be assured.

  When it is determined that the calculated black correction value is normal by satisfying all the above expressions (1) to (3), the control unit 11 switches the storage areas R1 and R2 to be read (step S1). S360). That is, the control unit 11 switches the storage areas R1 and R2 in which the calculated black correction values are stored to the storage areas R1 and R2 to be read, so that the calculated black correction values are used for black correction. Like that. In addition, when any of the above formulas (1) to (3) is not satisfied, it is determined that the black correction value calculated in step S350 is abnormal. In this case, the use of the black correction value of each pixel currently used for black correction is continued, the next black level is accumulated (step S320), and the black correction value is calculated based on the accumulation of the next black level. Is performed (step S330).

  In the present embodiment described above, when the storage of the calculated black correction value is completed, the control unit 11 stores the calculated black correction value in the storage areas R1 and R2 for reading the black correction value used for the black correction. The storage areas are switched to the storage areas R1 and R2. In this configuration, since the black correction value can be stored in any of the plurality of storage areas R1, R2, the black color is stored in the storage areas R1, R2 different from the storage areas R1, R2 from which the control unit 11 reads the black correction value. The correction value can be stored. Therefore, it is possible to update the black correction value even in a short non-document period as in the case of performing black correction by continuously reading the original, and the black correction of the read image is performed based on the updated black correction value. It can be carried out.

  As described above, the storage unit 13 determines whether or not the calculated black correction value is normal, and reads the black correction value used for black correction when the calculated black correction value is normal. The storage areas R1 and R2 are switched to a storage area that stores the calculated black correction value. Thereby, it is possible to suppress the possibility that black correction is performed using an abnormal black correction value.

When the black correction value is calculated, the storage unit 13 stores the calculated black correction value (H _R , L _R , S _R ) and the black correction value used for black correction in the storage areas R 1 and R 2. Based on the comparison with the stored black correction values (H _U , L _U , S _U ), it is determined whether or not the calculated black correction value is normal. As a result, when the calculated black correction value changes more than the reference with respect to the past black correction value, it can be determined that the calculated black correction value is abnormal.

Further, the storage unit 13, a plurality of kinds of statistics from the black correction value _{(H R, L R, S} R) to derive, the plurality of types of statistical values _{(H R, L R, S} R) each is given The calculated black correction value is normal by determining whether or not a deviation (E, E, E × i / 2) or more from the values (H _U , L _U , S _U ) is not deviated. It is determined whether or not. Thereby, it is possible to determine whether or not the black correction value is normal with an allowable error suitable for the type of statistical value.

  The calculation unit 12 calculates a black correction value by combining the Nth black level and the Mth (M = N + 1) black level. As a result, even when a sufficient amount of black level cannot be obtained by only one non-document period, the black correction value can be calculated by combining the Nth black level and the Mth black level.

(2) Scanner operation timing:
3A and 3B are timing charts showing the operation timing of the scanner 1 in the continuous scanning process. The horizontal axis of FIG. 3A and FIG. 3B means time. As shown in FIG. 3A, the Nth no-document period between reading the Nth original and the (N + 1) th original, and the M between reading the M (= N + 1) th original and the (M + 1) th original. The black correction value (N, N + 1) is calculated at the stage where the black level read by the image sensor 20 is accumulated in the second document-free period. When the calculation of the black correction value (N, N + 1) is completed, the calculated black correction value (N, N + 1) is stored in the storage area R2. When the calculation of the black correction value (N, N + 1) is completed, the storage area R1 is to be read, and the black correction value (N-1, N-2) stored in the storage area R1 is used. The control unit 11 performs black correction. Therefore, the calculated black correction value (N, N + 1) is stored in the storage area R2 that is not a read target.

  Then, when it is determined that the calculated black correction value (N, N + 1) is normal, the storage area R2 is switched as a reading target, and thereafter the calculated black correction value (N, N + 1) is the black correction. Will be used. In the case of FIG. 3A, the timing at which the storage area R2 is switched as a reading target is before the completion of the reading of the (N + 2) th original, and thus the black correction value for the read image of the (N + 2) th original. Black correction by (N, N + 1) is performed.

  FIG. 3B is a timing chart when the calculated black correction value (N, N + 1) is not determined to be normal. If it is not determined that the calculated black correction value (N, N + 1) is normal, the storage area R1 is maintained as a read target without switching the storage area R2 as a read target. Therefore, the state in which the control unit 11 performs black correction using the black correction values (N−1, N−2) stored in the storage area R1 continues. As described above, since the black correction value is calculated based on the black level read by the image sensor 20 in the non-document period, the black correction value can be updated at a high frequency, and the temperature of the image sensor 20 can be changed. Respond quickly. In this embodiment, if it is determined that the black correction value is normal, the black correction value can be updated each time two originals are read.

(3) Second embodiment:
4A and 4B are timing charts showing operation timings of the scanner 1 in the continuous scan processing according to the second embodiment. As shown in FIGS. 3A and 3B, the second embodiment is different from the first embodiment in that accumulation of the black level is completed in one non-document period. For example, the value of Y may be smaller than in the first embodiment, the document conveyance speed may be smaller, or the imaging cycle of the image sensor 20 may be shorter. As shown in FIGS. 4A and 4B, the accumulation of the black level is completed every time one non-document period ends, and the calculation unit 12 calculates the black correction value every time one non-document period ends. I do. If the calculated black correction value continues to be normal, the storage areas R1 and R2 to be read are switched at the same length as the period in which the non-document period arrives.

  In the case of FIG. 4A, the determination as to whether or not the Nth black correction value is normal ends, and the timing at which the storage area R2 is switched as a reading target is before the completion of the reading of the (N + 1) th original. It is. Therefore, black correction is performed on the read image of the (N + 1) th original by the Nth black correction value. That is, assuming that the black correction value calculated based on the Nth black level is the Nth black correction value, the control unit 11 performs the Nth black correction on the read image obtained by reading the (N + 1) th original. Black correction is performed using the value. In other words, the black correction value based on the black level can be applied to the read image of the original read in the period subsequent to the non-original period in which the black level is obtained. It can correspond to.

  In the case of FIG. 4B, the determination as to whether or not the Nth black correction value is normal ends, and the timing at which the storage area R2 is switched as a reading target is after the completion of the reading of the (N + 1) th original. And before the reading of the (N + 2) th original is completed. Therefore, the black correction by the Nth black correction value is performed for the read image of the (N + 2) th original for the first time. That is, the control unit 11 performs black correction for the first time on the read image obtained by reading the (N + 2) th and subsequent documents using the Nth black correction value. That is, it is not always necessary to apply the Nth black correction value to the read image obtained by reading the (N + 1) th original.

  When a large number of black levels can be acquired at high speed, a black correction value can be calculated for each non-document period as shown in FIGS. 4A and 4B. In order to realize such an operation timing, a functional configuration for acquiring a black level in a non-document period may be realized by an ASIC instead of a general-purpose processor. Further, when the period for calculating the black correction value and the period for determining whether the black correction value is normal are short, the original read in the period following the non-original period in which the black level is obtained as shown in FIG. 4A. A black correction value based on the black level can be applied to the read image. In order to realize such operation timing, the functional configuration for calculating the black correction value and the functional configuration for determining whether the black correction value is normal may be realized by an ASIC instead of a general-purpose processor.

  Further, the number X of times the black reference is imaged in one non-document period may be a fixed value or a variable value. For example, the controller 10 may set X according to the scan mode, or may set X to a larger value as the non-document period becomes longer. Since the non-document period becomes longer as the document conveyance speed is lower, X may be set to a larger value as the scan mode has a higher resolution. Further, since the processing period of the image sensor 20 is longer in the color mode than in the monochrome mode, X may be set to a larger value in the color mode than in the gray scale mode. Further, X may not be a preset value. For example, the controller 10 may stop black-based imaging when the beginning of the next document approaches the image sensor 20 within a specified distance. In this case, X is the number of times the image is taken from the start of the non-document period to the stop of the imaging. According to this configuration, even when the distance between the originals varies, the number of black levels corresponding to the distance between the originals can be obtained.

(4) Third embodiment:
FIG. 5 is a flowchart of the continuous scanning process in the third embodiment. In the present embodiment, the calculation unit 12 determines whether or not the black level is normal every time the black level is acquired in the non-document period or while the black level is being accumulated (step S300). ). Various determination methods can be employed. For example, the calculation unit 12 may determine that the acquired black level is normal when the acquired black level does not deviate from a past black level by a predetermined reference or more.

  If it is not determined that the acquired black level is normal (step S300: N), the calculation unit 12 acquires the black level in the next non-document period without accumulating the acquired black level. Wait. That is, when the acquired black level is not normal, the calculation unit 12 discards the acquired black level.

  On the other hand, when it determines with the acquired black level being normal (step S300: Y), the calculation part 12 accumulate | stores the acquired black level (step S310). When the acquired black level is accumulated, the calculation unit 12 determines whether or not the accumulation of the black level is completed (step S320). When it is not determined that the accumulation of the black level is completed (step S320: N), the calculation unit 12 waits for the black level to be acquired in the next non-document period. For example, the black level accumulation may be completed when Y black levels are accumulated as in the first embodiment. On the other hand, when it is determined that the acquired black level is normal (step S320: Y), the calculation unit 12 calculates a black correction value (step S330). That is, the calculation unit 12 calculates a black correction value based on a black level that has been determined to be normal in advance. Therefore, it can be guaranteed that the calculated black correction value is also a normal value.

  Next, the storage unit 13 stores the calculated black correction value in the storage areas R1 and R2 that are not to be read (step S340). Then, the control unit 11 switches the storage areas R1 and R2 in which the calculated black correction value is stored to the storage areas R1 and R2 to be read (step S350).

  6A and 6B are timing charts showing operation timings of the scanner 1 in the continuous scan processing according to the third embodiment. As shown in FIGS. 6A and 6B, when the black level is acquired in the Nth no-document period between reading the Nth original and the (N + 1) th original, the acquired black level is normal. It is determined whether or not there is.

  In FIG. 6A, the black level acquired in the Nth no document period and the black level acquired in the (N + 1) th no document period are both normal. Therefore, when it is determined that the black level acquired in the (N + 1) th no-document period is normal, normal black level accumulation is completed, and the black correction value ( N, N + 1) is calculated. Next, the calculated black correction value (N, N + 1) is stored in the storage area R2. Since the calculated black correction value (N, N + 1) is normal, the control unit 11 switches the storage area R2 as it is to be read as it is.

  On the other hand, in FIG. 6B, the black level acquired in the Nth no document period is normal, and the black level acquired in the (N + 1) th no document period is not normal. For this reason, if it is not determined that the black level acquired in the (N + 1) th no-document period is normal, the (N + 2) -th black in the next (N + 2) th (N + 2 = L) no-document period. Wait until the level is acquired. In this case, the (N + 1) th black level is discarded. When the (N + 2) th black level is normal, the accumulation of the black level is completed when the (N + 2) th black level is accumulated. Then, the black correction value is calculated by combining the Nth black level and the (N + 2) th black level.

  That is, in the third embodiment, when the Nth black level is normal and the Mth (M = N + 1) black level is abnormal, the calculation unit 12 is Lth (L = N + 2 = M + 1). Whether the Lth black level, which is the result of the image sensor 20 reading the black reference from when the original passes through the image sensor 20 until the (L + 1) th original reaches the image sensor 20, is normal? If the Lth black level is normal, a black correction value is calculated by combining the Nth black level and the Lth black level. As described above, it is not determined whether all the Y black levels necessary for calculating the black correction value are normal, but is normal for every X black levels smaller than Y. Therefore, the black level can be discarded in units of X, and the number of black levels acquired in vain can be suppressed.

(5) Other embodiments:
Further, the storage unit 13 may determine whether or not the calculated black correction value is normal for each divided region obtained by dividing the image sensor 20. For example, the image sensor 20 may be divided into a first divided region in which the distance from the AFE 20a is equal to or smaller than a threshold value and a second divided region in which the distance from the AFE 20a is larger than the threshold value. Then, the storage unit 13 derives statistical values (H _R , L _R , S _R , H _U , L _U , S _U ) of the black correction values for the pixels corresponding to the light receiving elements in the first divided region, Based on the statistical values (H _R , L _R , S _R , H _U , L _U , S _U ), it may be determined whether or not the black correction value of the first divided region is normal. Similarly, the storage unit 13 derives the statistical values (H _R , L _R , S _R , H _U , L _U , S _U ) of the black correction values for the pixels corresponding to the light receiving elements in the second divided region, Based on the statistical values (H _R , L _R , S _R , H _U , L _U , S _U ), it may be determined whether or not the black correction value of the second divided region is normal. Further, the storage unit 13 may set the allowable error size (the size of E in the first embodiment) to a different value between the first divided region and the second divided region. For example, the storage unit 13 may set E defining the allowable error of the first divided region whose temperature is more likely to fluctuate than the second divided region to be larger than E defining the allowable error of the second divided region. . By doing in this way, even when the characteristics of the black correction value are different for each part of the image sensor 20, it is possible to determine whether or not the black correction value is normal under the determination condition suitable for the characteristics.

  It should be noted that the technical scope of the present invention is not limited to the above-described embodiment, and it is needless to say that various modifications can be made without departing from the scope of the present invention. For example, the scanner 1 may not perform the process of determining whether the black correction value and the black level are normal. Further, the present invention may be applied when calculating the white correction value instead of or in addition to the black correction value. In this case, the illumination unit 30 may irradiate illumination light during the non-document period. In addition, when applying color scanning, the correction values described above may be acquired and applied for each color component, or when image sensors are arranged on both sides of a document and both sides of the document are scanned simultaneously, The above-described correction value acquisition and application may be performed for each image sensor. Further, the scanner 1 may be incorporated into a composite apparatus having other functions (printing function, facsimile function, etc.). Furthermore, some of the components of the present invention may be realized on a computer that is communicably connected to the scanner 1.

DESCRIPTION OF SYMBOLS 1 ... Scanner, 10 ... Controller, 11 ... Control part, 12 ... Calculation part, 13 ... Memory | storage part, 20 ... Image sensor, 30 ... Illumination part, 40 ... Conveyance mechanism, 50 ... Document cover, 60 ... Platen glass, E ... Values that define tolerances, R1, R2, ... storage area

Claims (9)

A transport mechanism for continuously transporting a plurality of documents;
A sensor that reads the conveyed document,
A control unit that performs correction using a correction value on a read image read by the sensor, and a scanner,
After the Nth (N is a natural number) document passes through the sensor and before the (N + 1) th document reaches the sensor, the sensor reads the reference area to the Nth correction level. A calculation unit for calculating the correction value based on the
When the correction value is calculated, the storage unit sequentially stores the correction value in any of a plurality of storage areas,
When the storage of the calculated correction value is completed, the control unit switches the storage area from which the correction value used for the correction is read to the storage area in which the calculated correction value is stored.
scanner. The storage unit determines whether or not the calculated correction value or the correction level is normal. When the storage unit determines that the correction value or the correction level is normal, the storage unit reads the correction value used for the correction, When the storage area storing the correction value calculated based on the calculated correction value or the correction level is switched to the storage area and determined to be abnormal, based on the calculated correction value or the correction level. The storage area storing the correction value calculated in the above is not used as the storage area for reading the correction value used for the correction.
The scanner according to claim 1. When the correction value is calculated, the storage unit is based on a comparison between the calculated correction value and the correction value stored in the storage area that reads the correction value used for the correction. Determining whether the calculated correction value is normal;
The scanner according to claim 2. The storage unit determines whether the correction value or the correction level is normal for each divided region obtained by dividing the sensor.
The scanner according to claim 2 or claim 3. The storage unit derives a plurality of types of statistical values from the correction value or the correction level, and determines whether each of the plurality of types of statistical values has deviated from a predetermined value by an allowable error or more, Determining whether the calculated correction value or the correction level is normal;
The size of the tolerance varies depending on the plurality of types of statistics.
The scanner according to any one of claims 2 to 4. When the correction value calculated based on the Nth correction level is the Nth correction value,
The control unit performs correction for the first time using the Nth correction value for the read image obtained by reading the (N + 2) th and subsequent documents.
The scanner according to any one of claims 1 to 5. When the correction value calculated based on the Nth correction level is the Nth correction value,
The control unit corrects the read image obtained by reading the (N + 1) th document using the Nth correction value.
The scanner according to any one of claims 1 to 5. The calculation unit includes the N-th correction level and the M-th (M is a natural number other than N) document passing through the sensor until the (M + 1) -th document reaches the sensor. The correction value is calculated in combination with the Mth correction level, which is the result of the sensor reading the black reference.
The scanner according to any one of claims 1 to 7. A conveyance process for conveying a plurality of documents continuously;
A correction process for correcting a read image obtained by reading a conveyed document using a sensor using a correction value;
An output step of outputting an image based on the read image after correction;
An image production method comprising:
After the Nth (N is a natural number) document passes through the sensor and before the (N + 1) th document reaches the sensor, the sensor reads the reference area to the Nth correction level. A calculating step of calculating the correction value based on
When the correction value is calculated, a storage step of sequentially storing the correction value in any of a plurality of storage areas,
In the correction step, when storage of the calculated correction value is completed, the storage area from which the correction value used for the correction is read is switched to the storage area in which the calculated correction value is stored.
Image production method.

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