This application is based on and claims priority under 35 USC 119 from Japanese Patent Application No. 2011-246540 filed Nov. 10, 2011.
(i) Technical Field
The present invention relates to a detection apparatus and method, an image forming apparatus, and a non-transitory computer readable program.
(ii) Related Art
Techniques for detecting the state of an image forming apparatus or the state of media used for image formation in order to perform high-precision image formation are known.
According to an aspect of the invention, there is provided a detection apparatus including: a first measuring unit that measures, from a binary image, density levels of first regions having a first grayscale value and density levels of second regions having a second grayscale value, the first regions and the second regions being alternately arranged in a first direction in the binary image, the binary image being disposed on a second surface of a holding member, the holding member including a first surface and the second surface provided opposite the first surface; a storage unit that stores, in the storage unit, information indicating an association between a distance from the first measuring unit to the second surface and a contrast between the first region and the second region positioned adjacent to each other obtained as a result of the first measuring unit measuring the density levels; a calculator that calculates a contrast between the first region and the second region positioned adjacent to each other by using the density level of the first region and the density level of the second region measured by the first measuring unit; and a detector that specifies a distance corresponding to the contrast calculated by the calculator by using the information stored in the storage unit, and detects a deflection of the holding member in the first direction by using the specified distance as the distance from the second surface to the first region and the second region positioned adjacent to each other.
An exemplary embodiment of the present invention will be described in detail based on the following figures, wherein:
The intermediate transfer belt 22 (an example of a holding member) transports toner images which have been transferred on the intermediate transfer belt 22 by using the first transfer rollers to the second transfer roller 23. The intermediate transfer belt 22 is supported by plural rollers including a tension roller 25 and a driving roller 26. The driving roller 26 drives the intermediate transfer belt 22 in the X direction indicated by the arrow in
A first image sensor 31 (an example of a first measuring unit) and a second image sensor 32 (an example of a second measuring unit) are disposed such that they oppose each other with the intermediate transfer belt 22 therebetween.
The second image sensor 32 is a contact image sensor that reads images formed on the front surface of the intermediate transfer belt 22. The second image sensor 32 is also a line sensor and reads a detection width corresponding to the width of the intermediate transfer belt 22. The second image sensor 32 is positioned such that the distance between the second image sensor 32 and the front surface of the intermediate transfer belt 22 is equal to the focal length. The configuration of the second image sensor 32 is the same as that of the first image sensor 31. The second image sensor 32 measures the density of an image by using the amount of light received by the light receiving element and outputs a signal representing the measured density.
In the storage unit 13, a first function f1 is stored in advance. The first function f1 represents the association between the distance d from the first image sensor 31 to the back surface of the intermediate transfer belt 22 and the contrast of the ladder pattern chart obtained as a result of measurements performed by the first image sensor 31. The contrast is calculated in accordance with the density measured by the first image sensor 31 when the first image sensor 31 is separated from the back surface of the intermediate transfer belt 22 by the distance d.
In the storage unit 13, a reference distance is also stored. The reference distance is a distance between the first image sensor 31 and the back surface of the intermediate transfer belt 22 when there is no occurrence of deflection in the intermediate transfer belt 22. In this example, assume that the reference distance is the distance d5 shown in
In the image forming apparatus 1, density correction processing is performed by using a test chart. The test chart is an image used for correcting density levels of individual colors. The test chart has a predetermined density distribution. The test chart includes density patches of, for example, yellow, magenta, cyan, and black.
In step S11, the controller 11 drives the intermediate transfer belt 22 to rotate by using the driving roller 26. In step S12, the first image sensor 31 reads the ladder pattern chart formed on the back surface of the intermediate transfer belt 22. More specifically, the first image sensor 31 irradiates the back surface of the intermediate transfer belt 22 with laser light by using the light emitting elements 33 and receives light reflected by the ladder pattern chart by using the light receiving element 34. The first image sensor 31 measures the density for each of the lines contained in the ladder pattern chart by using the amount of light received by the light receiving element 34, and outputs a signal representing the measured density. As shown in
In step S13, the controller 11 calculates the contrast of the ladder pattern chart on the basis of the signal output from the first image sensor 31. More specifically, for each pair of black and white narrow lines contained in the ladder pattern chart, the controller 11 calculates the contrast between the white line and the black line adjacent to each other. The contrast is the density difference between the black region and the white region. Assume that, for example, the output of the first image sensor 31 is 10 bits (1024 steps). In this case, if the grayscale value of the black region and the grayscale value of the white region measured by the first image sensor 31 are 900 and 50, respectively, the contrast is (900-50)/1024×100=83%.
In step S14, the controller 11 measures the distance d corresponding to the contrast calculated in step S13 by using the first function f1 stored in the storage unit 13, and detects an amount of deflection in the widthwise direction of the intermediate transfer belt 22 from the measured distance d. For example, if the contrast is calculated to 83% in step S13, the distance d corresponding to the contrast 83% is the distance d2 or the distance d4 according to the first function f1 shown in
If, for example, all the distances d measured in step S14 are equal to the reference distance d5, it means that there is no occurrence of deflection along the intermediate transfer belt 22. In contrast, if a distance d different from the reference distance d5 is contained in the distances d measured in step S14, deflection is occurring in that portion of the intermediate transfer belt 22.
After step S11, the image forming engines 21Y, 21M, 21C, and 21K form a test chart on the front surface of the intermediate transfer belt 22. In step S15, the second image sensor 32 reads the test chart formed on the front surface of the intermediate transfer belt 22. More specifically, the second image sensor 32 irradiates the front surface of the intermediate transfer belt 22 with laser light by using the light emitting elements, and receives light reflected by the test chart formed on the front surface of the intermediate transfer belt 22 by using the light receiving element. The second image sensor 32 measures the density of the test chart by using the amount of light received by the light receiving element, and outputs a signal representing the measured density. Since the second image sensor 32 is a contact image sensor, the depth of focus is small. Accordingly, if deflection occurs in the intermediate transfer belt 22 so as to change the distance between the second image sensor 32 and the intermediate transfer belt 22, laser light is not in focus on the intermediate transfer belt 22, thereby generating errors in the density measurements.
In step S16, upon the occurrence of deflection in the intermediate transfer belt 22, the controller 11 controls the position or the angle of the tension roller 25 so that an amount of deflection is corrected. The meaning of “correction” or “corrected” includes, not only completely eliminating deflection, but also reducing the amount of deflection. For example, the controller 11 shifts the position of the tension roller 25 in a direction in which tension of the intermediate transfer belt 22 increases. Alternatively, the controller 11 tilts the tension roller 25 in a direction in which the deflection of the intermediate transfer belt 22 is corrected. As a result, the deflection of the intermediate transfer belt 22 is corrected, and the distance d between the first image sensor 31 and the back surface of the intermediate transfer belt 22 is returned to the reference distance d5.
If deflection occurs in the intermediate transfer belt 22, in step S17, the controller 11 corrects a signal output from the second image sensor 32 in accordance with the state of deflection of the intermediate transfer belt 22 detected in step S14. For example, if the distance d which changes as shown in
Then, when forming an image specified by a user, in step S18, the controller 11 performs density correction processing in accordance with a signal corrected in step S17. More specifically, the controller 11 generates a density distribution of the test chart by using the signal corrected in step S17. The controller 11 corrects the density of an image to be formed by each of the image forming engines 21Y, 21M, 21C, and 21K so that the density nonuniformity and streaks contained in the generated density distribution can be reduced. For example, the controller 11 corrects the grayscale value represented by an image signal to be supplied to each exposure device by using a lookup table.
In this exemplary embodiment, the distance d between the first image sensor 31 and the back surface of the intermediate transfer belt 22 is uniquely specified, thereby detecting deflection in the widthwise direction of the intermediate transfer belt 22. Additionally, density correction processing is performed on the basis of the signal which has been corrected for errors caused by a change in the distance between the second image sensor 32 and the front surface of the intermediate transfer belt 22, thereby improving the precision in density correction processing. The position or the angle of the tension roller 25 is also controlled, thereby reducing deflection in the intermediate transfer belt 22.
The above-described exemplary embodiment is only an example of the present invention. Alternatively, the present invention may be modified as follows, or the following modified examples may be combined.
The first image sensor 31 may be disposed at a position at which the distance d between the first image sensor 31 and the back surface of the intermediate transfer belt 22 is smaller than the focal length. In this case, the controller 11 utilizes a value in the range R1 of the first function f1 in which the distance decreases from the focal length d3. Accordingly, if the contrast is calculated to 83% in step S13, the controller 11 specifies the distance d2 contained in the range R1, out of the distance d2 and the distance d4 corresponding to the contrast 83% in the first function f1. That is, when the first image sensor 31 is disposed at a position at which the distance between the first image sensor 31 and the back surface of the intermediate transfer belt 22 is greater than the focal length, a value in the range of the first function f1 in which the distance d increases from a value equal to the focal length is utilized. In contrast, when the first image sensor 31 is disposed at a position at which the distance between the first image sensor 31 and the back surface of the intermediate transfer belt 22 is smaller than the focal length, a value in the range of the first function f1 in which the distance d decreases from the focal length is utilized.
In the above-described exemplary embodiment, in step S14, the controller 11 determines which range of values of the function f1 is to be utilized, on the basis of the reference distance, and thereby uniquely specifies the distance d between the first image sensor 31 and the back surface of the intermediate transfer belt 22. However, instead of using the reference distance, the distance d may be directly measured.
In this modified example, the first image sensor 31 may be disposed at a position at which the distance between the first image sensor 31 and the back surface of the intermediate transfer belt 22 is greater than the focal length, or at a position at which the above-described distance is smaller than the focal length. In the storage unit 13, a reference contrast and a reference amount of light are stored in advance. The reference contrast is a contrast calculated by using the density measured by the first image sensor 31 when there is no occurrence of deflection in the intermediate transfer belt 22. Assume that the reference contrast is 70%. The reference amount of light is the amount of light received by the first image sensor 31 when there is no occurrence of deflection in the intermediate transfer belt 22. The meaning of the state in which there is “no occurrence of deflection” is not necessarily a state in which no deflection occurs whatsoever, but may be a state in which the amount of deflection is equal to or less than a threshold.
In step S14, the controller 11 first specifies, by using the function f1, the distance d corresponding to the contrast calculated in step S13. For example, if the contrast is calculated to 83% in step S13, the controller 11 specifies the distance d2 and the distance d4 corresponding to the reference contrast 70% in the first function f1 shown in
Then, the controller 11 compares the amount of light received by the first image sensor 31 in step S12 with the reference amount of light stored in the storage unit 13, and determines whether the distance d has been increased. As shown in
In this manner, when the contrast calculated in step S13 is higher than the reference contrast, the controller 11 specifies the distance d as follows. When the amount of light received by the first image sensor 31 is larger than the reference amount of light, the controller 11 specifies the distance d between the first image sensor 31 and the back surface of the intermediate transfer belt 22 by using a value in the range R2 of the first function f1 in which the distance d increases from the focal length d3. In contrast, when the amount of light received by the first image sensor 31 is smaller than the reference amount of light, the controller 11 specifies the distance d between the first image sensor 31 and the back surface of the intermediate transfer belt 22 by using a value in the range R1 in which the distance d decreases than the focal length d3 in the first function f1.
If the contrast calculated in step S13 is lower than the reference contrast, the controller 11 specifies the distance d in a manner opposite to that when the contrast is higher than the reference contrast. More specifically, when the amount of light received by the first image sensor 31 is larger than the reference amount of light, the controller 11 utilizes a value in the range R1 of the first function f1 in which the distance d decreases from the focal length d3. When the amount of light received by the first image sensor 31 is smaller than the reference amount of light, the controller 11 utilizes a value in the range R2 of the first function f1 in which the distance d increases from the focal length d3.
The first image sensor 31 may measure plural density levels for each line contained in the ladder pattern chart. In this case, in step S13, the controller 11 calculates contrast corresponding to the density levels measured in step S12. The contrast corresponding to the density levels may be the average of the plural density levels, and may be the median or the mode of the density levels. If the average is to be utilized, the controller 11 may extract the peak value from the plural density levels, sequentially select a predetermined number of density levels in descending order from the peak value, and take the average of the selected number of peak values.
The first image sensor 31 is not restricted to a line sensor. The first image sensor 31 may be a spot laser sensor that reads images by utilizing spot light.
In the above-described exemplary embodiment, the distance d between the first image sensor 31 and the back surface of the intermediate transfer belt 22 is measured by the use of the contrast of a ladder pattern chart. However, the distance d may be measured without using the contrast of a ladder pattern chart.
In this modified example, instead of the above-described ladder pattern chart, a white board is formed on the back surface of the intermediate transfer belt 22. More specifically, the back surface of the intermediate transfer belt 22 may be formed in white, or a white medium may be attached to the back surface of the intermediate transfer belt 22. Additionally, the first image sensor 31 may be disposed at a position at which the distance between the first image sensor 31 and the intermediate transfer belt 22 is equal to the focal length, or at which the above-described distance is greater or smaller than the focal length.
In the storage unit 13, a second function f2 is stored in advance. The second function f2 indicates the association between the distance d from the first image sensor 31 to the back surface of the intermediate transfer belt 22 and a change in the reflectivity of the white board formed on the back surface of the intermediate transfer belt 22.
In step S23, on the basis of the signal output from the first image sensor 31, the first image sensor 31 calculates the reflectivity values of plural regions of the white board in the widthwise direction of the intermediate transfer belt 22. The reflectivity is calculated by using the amount of light emitted from the light emitting elements 33 and the amount of light received by the light receiving element 34. In step S24, the controller 11 measures the distance d corresponding to a change in the reflectivity calculated in step S23 by utilizing the second function f2 stored in the storage unit 13, and detects the deflection of the intermediate transfer belt 22 from the measured distance d. For example, if a change in the reflectivity calculated in step S23 is 0.6% in the second function f2 shown in
In the above-described exemplary embodiment, in the case of the occurrence of deflection in the intermediate transfer belt 22, processing for correcting the deflection of the intermediate transfer belt 22 in step S16 and processing for correcting a signal output from the first image sensor 31 in step S17 are both performed. However, it is not always necessary that both of steps S16 and S17 be performed, and only processing for correcting the deflection of the intermediate transfer belt 22 may be performed. In this case, it is preferable that, after the deflection is corrected, a test chart is formed and read. Alternatively, only processing for correcting a signal output from the first image sensor 31 may be performed. Additionally, as a normal operation, only steps S11 through S14 and step S16 may be performed, and only when an instruction to form a test chart is given, may steps S1 through S18 be performed.
In
In
In the above-described exemplary embodiment, the first function f1 is utilized as information indicating the association between the distance d from the first image sensor 31 to the back surface of the intermediate transfer belt 22 and the contrast of the ladder pattern chart read by the first image sensor 31. However, the information indicating the above-described association is not restricted to a function. For example, a table format indicating the association may be used.
The type of ladder pattern chart is not restricted to the ladder pattern chart discussed in the exemplary embodiment. For example, the colors of the lines of the ladder pattern chart may be different from white and black, or two gray colors having different grayscale values may be used. Additionally, the intervals between the lines or the thickness of the lines may be different from those discussed in the exemplary embodiment, and lines of two colors do not have to be parallel. The pattern of the ladder pattern chart is not restricted to lines, but may be a different pattern, for example, a lattice pattern including black and white. That is, any type of ladder pattern chart may be used as long as it is an image from which contrast can be measured, i.e., a binary image on which first regions having a first grayscale value and second regions having a second grayscale value are alternately disposed.
The function of the test chart is not restricted to the correction of the color density. For example, the test chart may include images used for correcting color misalignment.
The first image sensor 31 or the second image sensor 32 is not restricted to a contact image sensor, and it may be any type of sensor as long as it exhibits characteristics that cause the measured contrast or the amount of received light to vary in accordance with the distance between the sensor and a subject irradiated with light.
The above-described controller 11, the storage unit 13, and the first image sensor 31 may be formed into a unit, and may be provided as a detection apparatus that detects deflection of the intermediate transfer belt 22. Such a detection apparatus may be used in an apparatus other than the image forming apparatus 1, for example, it may be used in a scanner.
The program executed by the CPU of the controller 11 may be provided by being recorded in a recording medium, such as magnetic tape, a magnetic disk, a flexible disk, an optical disc, a magneto-optical disc, or a memory, and be installed into the image forming apparatus 1. Alternatively, the program may be downloaded into the image forming apparatus 1 via a communication line, such as the Internet.
The foregoing description of the exemplary embodiment and modified examples of the present invention has been provided for the purposes of illustration and description. It is not intended to be exhaustive or to limit the invention to the precise forms disclosed. Obviously, many modifications and variations will be apparent to practitioners skilled in the art. The embodiment and modified examples were chosen and described in order to best explain the principles of the invention and its practical applications, thereby enabling others skilled in the art to understand the invention for various embodiments and with the various modifications as are suited to the particular use contemplated. It is intended that the scope of the invention be defined by the following claims and their equivalents.
Number | Date | Country | Kind |
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2011-246540 | Nov 2011 | JP | national |