JP2001255708A - Image forming device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an image forming device by which accurate correction to eliminate density deterioration due to the void of a boundary part is always performed without causing the increase of the size and the cost of the device as the image forming device in which the image data of a specified correction area extended from an edge to the area of a low dot area ratio is corrected by detecting an edge position in the case that an electrostatic dot latent image relatively changing from the area of a high dot area ratio to the area of the low dot area ratio by taking a specified edge as a boundary in accordance with the timewise order of development by a developing unit is formed on an image carrier. SOLUTION: This device possesses data correcting means 1433 and 1434 by which the image data of the specified correction area extended from the edge to the area of the low dot area ratio is corrected to the side of the high dot area ratio based on an edge position detected by an edge detecting means 1432, respective dot area ratios of the area of the high dot area ratio and the area of the low dot area ratio across the edge and the potential of a toner image for measuring potential measured by a toner image potential measuring means 13.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION The present invention relates to an image bearing member having a relatively high halftone area ratio and a low halftone area ratio with a predetermined edge as a boundary according to the time sequence of development by a developing device. An image forming apparatus that detects an edge position when an electrostatic halftone dot latent image that changes to an area is formed, and corrects image data of a predetermined correction area extending from the edge to an area having a low halftone dot area ratio. .

[0002]

2. Description of the Related Art Conventionally, image forming apparatuses such as copying machines and printers by electrophotography have been known.

In order to form an image, an image forming apparatus such as a copying machine or a printer based on the electrophotographic technique first irradiates exposure light modulated in accordance with image data.
An electrostatic dot latent image is formed on the image carrier. Next, the toner contained in the developing device is transferred to the image carrier using the potential difference from the image carrier to develop an electrostatic halftone latent image, thereby forming a toner image on the image carrier. I do. Further, the toner image formed on the image carrier is finally transferred and fixed on a predetermined image recording medium to form an image composed of the fixed toner image on the image recording medium.

In such an image forming apparatus in which toner is transferred onto an image carrier by utilizing a potential difference between the image carrier and the image carrier, relative movement is performed with a predetermined edge as a boundary in accordance with a time sequence of development by a developing device. When developing an electrostatic halftone dot latent image that changes from a high halftone dot area to a low halftone dot area, a problem described below with reference to FIG. 6 occurs.

FIG. 6 is a view showing a toner image formed on an image carrier.

The toner image 60 shown in FIG. 6 is formed by a two-component developer composed of a toner and a magnetic carrier, and has a high halftone dot area with an edge 61 interposed therebetween. 62 and a region 63 having a low halftone dot area ratio. The arrow in the drawing indicates the direction in the order of development time, that is, the development direction, and the toner image 60 first has the area 6 having a high halftone dot area ratio.
After the development of No. 2, the region 63 having the low halftone dot area ratio is continuously developed.

The area 62 having a relatively high halftone dot area and the area 6 having a relatively low halftone dot area with the edge 61 as a boundary.
In the toner image 60 that changes to 3, a phenomenon occurs in which the density of the region 63 ′ decreases (so-called white spots) in the region 63 ′ extending from the edge 61 to the region 63 having the low halftone dot area ratio. Hereinafter, this phenomenon is referred to as a boundary white spot.

[0008] When the two-component developer is used, the white spot on the boundary is caused by the carrier around which toner adheres.
This is considered to be a phenomenon caused by the generation of residual charges having a polarity opposite to the charge potential of the toner. In brief, the toner adhering to the periphery of the carrier is in a charged state, and the transfer of the toner to the electrostatic dot latent image is performed by a potential difference between the charged potential of the toner and the potential of the electrostatic dot latent image. (Hereinafter, this potential difference is referred to as a development potential.) The density of the developed toner image is determined by the level of the development potential.
In other words, the development potential is higher in the region with the high halftone area ratio of the electrostatic halftone dot latent image than in the region with the low halftone dot area ratio.

When the toner is transferred to the electrostatic halftone dot latent image, a residual charge having a polarity opposite to the charge polarity of the toner is generated on the carrier according to the amount of the transferred toner.

Therefore, when the area 62 having a high halftone dot area ratio in FIG. 6 is developed, a large amount of toner is consumed.
After the transfer of the toner, the carrier is in a state where many residual charges are generated. The toner remaining on the carrier in such a state is strongly adhered by many residual charges generated on the carrier, and even if an attempt is made to develop an area having a low halftone dot area ratio of the electrostatic halftone latent image, the developing potential is low. In the middle, the transfer of the electrostatic halftone latent image to the region having a low halftone dot area ratio is not promoted, and as a result, the density is reduced.

Further, due to a large number of residual charges generated in the carrier having a polarity opposite to the charge polarity of the toner, the area between the low dot area ratio of the electrostatic dot latent image and the carrier is opposite to the developing potential. , The toner which has been transferred to the area of the electrostatic halftone dot latent image having a low halftone dot area ratio is returned to the carrier, and the density further decreases.

[0012]

Here, it is known to prevent the occurrence of white spots at the boundary by improving the laser beam used as exposure light for forming an electrostatic halftone latent image on the image carrier. From this perspective, the applicant has
A technique has been developed in which time modulation and intensity modulation of a laser beam are performed to improve the accuracy of laser beam scanning (see JP-A-6-87234). However, it is not preferable to increase the accuracy of such laser beam scanning, because the size and cost of the apparatus are increased.

On the other hand, the present applicant has determined in advance a correction coefficient for correcting image data of an area 63 ′ (see FIG. 6) which spreads toward the area 63 having a low halftone dot area ratio, and determines an edge 61 from the image data. (See FIG. 6)
A correction coefficient is selected from the predetermined correction coefficients based only on the input image data, and the selected correction coefficient is simply used to extend the area 6 extending to the low halftone dot area 63 side.
A technique for correcting 3 ′ (see FIG. 6) image data has also been developed (see Japanese Patent Application Laid-Open No. H10-65919). In this technology, although it is possible to avoid an increase in the size and cost of the apparatus, since the correction coefficient selected based on only the input image data is simply used, the type of toner that is not reflected in the input image data is not reflected. Changes, changes in temperature and humidity, changes over time in the toner in the developing device, and changes in the toner concentration (the ratio of toner to carrier) in the developing device when a two-component developer consisting of toner and carrier is used. It is not possible to perform correction in consideration of the above. For this reason, an image formed by using this technique is an image in which the amount of correction is insufficient and a blank portion in the boundary remains apparent, or an image in which the correction area is too large and the correction area is emphasized. Cheap.

The present invention has been made in view of the above circumstances, and has as its object to provide an image forming apparatus capable of always performing accurate correction for eliminating a density reduction due to a blank portion at a boundary without increasing the size and cost of the apparatus. It is assumed that.

[0015]

An image forming apparatus according to the present invention, which achieves the above object, receives an exposure light modulated in accordance with image data while moving in a predetermined direction, and forms an electrostatic halftone dot on the surface. A developing device for storing an image carrier on which a latent image is formed and toner, and developing the electrostatic dot latent image formed on the image carrier with the toner to form a toner image on the image carrier; The toner image formed on the image carrier is finally transferred and fixed on a predetermined image recording medium, thereby forming an image composed of the fixed toner image on the image recording medium. In the image forming apparatus for forming, a region having a relatively high dot area ratio and a region having a relatively low dot area ratio with a predetermined edge as a boundary on the image carrier in accordance with a time sequence of development by the developing device. When an electrostatic halftone latent image is formed Edge detecting means for detecting the position based on image data for forming the electrostatic halftone dot latent image, and forming a potential measurement toner image on the image carrier and measuring the potential of the potential measurement toner image. The toner image potential measuring means to be measured, the edge position detected by the edge detecting means, and the halftone dot area ratios of the high halftone dot area and the low halftone dot area sandwiching the edge, Based on the potential of the toner image for potential measurement measured by the toner image potential measuring means, the image data of a predetermined correction area extending from the edge to the area of the low halftone dot area is corrected to the high halftone dot area side. Data correction means.

As described above, it is considered that the boundary white spot is a phenomenon that occurs when a two-component developer is used and residual charges having a polarity opposite to the charged potential of the toner are generated on the carrier. Therefore, in the image forming apparatus of the present invention, when using a two-component developer, pay attention to how much residual charge actually generated remains in the carrier,
By obtaining the potential of the toner image for potential measurement and reflecting the measurement result in the correction of the image data, it is possible to accurately reduce the density reduction due to white spots at the boundary without incurring an increase in the size and cost of the apparatus. Correction can always be made.

In the image forming apparatus of the present invention, the toner image potential measuring means forms a toner image having a dot area ratio of 100% on the image carrier and measures the potential of the toner image. And the data correction means corrects the image data of the correction area to a higher halftone dot area ratio as the potential of the toner image measured by the toner image potential measurement means is lower. In addition, the edge detecting means may change the halftone dot area ratio from a region having a halftone dot area ratio of 35% or more to a halftone dot area ratio of 5% or more in accordance with the time sequence of development by the developing device. It is preferable to detect an edge formed by a drop of the halftone dot area ratio of 30% or more when shifting to a region of 70% or more and 70% or less.

[0018]

Embodiments of the present invention will be described below.

FIG. 1 is a schematic configuration diagram of a characteristic portion of an image forming apparatus according to an embodiment of the present invention, excluding an image processing section.

The image forming apparatus according to the present embodiment is a color image forming apparatus, and uses a plurality of image carriers and developing devices corresponding to the number of toner colors to synchronize with each other in synchronization with the transfer of a transfer member. A tandem system is used in which toner images of respective colors are formed on an image carrier, and the toner images are superimposed on a transfer member to obtain a color image.

FIG. 1 shows an image forming apparatus 10 according to this embodiment.
1 shows one image carrier 11 of the plurality of image carriers, a developing device 12 provided corresponding to the image carrier 11, and a potential measuring means 13.

The image carrier 11 is driven to rotate in the direction of arrow A in the figure. The surface of the image carrier 11 receives image data processed by an image processing unit described later, which is irradiated from an exposure device (not shown). An electrostatic halftone latent image is formed by the laser light modulated in accordance with the rotation of the image carrier 11.

The developing device 12 contains a developer. The developer of the present embodiment is a two-component developer composed of a toner having a diameter of 7 μm and a so-called low-resistance magnetic carrier having a diameter of 50 μm and a volume resistivity of 10 ⁸ Ω · cm or less. Further, in the developing area B, the developing device 12
It is arranged so as to be close to or in contact with the image carrier 11,
A developer carrier 121 and a pair of screw augers 122
And The developer carrier 121 is a cylindrical sleeve that rotates in the direction of arrow C and carries the developer on the surface and transports the developer to the development area B. The sleeve has a cylindrical shape having a plurality of magnetic poles. Fixed magnets (not shown) are provided. The developer in the developing device is agitated by the pair of screw augers 122.

The developer agitated by the pair of screw augers 122 is conveyed while being attracted to the surface of the developer carrier 121 by the magnetic poles of the fixed magnets in the developer carrier 121 to form a developer layer (not shown). The member forms a developer layer having a predetermined thickness. In this developer layer, a carrier carrying a large number of toners around the developer carrier 121
It is composed of so-called "spikes", which are continuous in the radial direction. The developer layer formed on the developer carrier 121 is rotated by the rotation of the developer carrier 121.
The developer is conveyed to the developing area B facing the image carrier 11. The developer layer conveyed to the developing area B approaches or comes into contact with the image carrier 11, and the toner contained in the developer layer is transferred to an electrostatic halftone latent image on the image carrier 11 by the development potential. In this way, the electrostatic dot latent image formed on the image carrier 11 is developed to form a toner image.

The toner image formed on the image carrier 11 together with the toner image formed on another image carrier is
The image is transferred onto an intermediate transfer belt (not shown) by the transfer unit (not shown) in a state where the belts are superimposed on each other. Further, the toner images transferred to each other in a superimposed state are transferred to a sheet conveyed from a sheet supply unit (not shown), and fixed by a fixing unit (not shown), thereby forming an image on the sheet. .

The potential measurement means 13 measures the potential of the toner image for potential measurement formed on the image carrier 11 and has an electrometer 131 and a probe 132. The probe 132 is located downstream of the development area B in the development direction.
It is arranged close to the surface of the image carrier 11. The frequency of the potential measurement of the potential measurement toner image by the potential measurement unit 13 is set at the initial setting of the image forming apparatus 10 so as to be performed every time the power of the image forming apparatus 10 is turned on, every elapse of a predetermined time, or every predetermined number of times of image formation. Set in stages. The potential measurement toner image is stored in advance in the image forming apparatus 10 based on a toner image patch pattern having a dot area ratio of 100% from which the potential of the electrostatic dot latent image can be accurately grasped. It is a toner image formed thereon. Therefore, the combination of the potential measuring means 13 and the developing device 12 corresponds to the toner image potential measuring means according to the present invention.

FIG. 1 shows a dot area ratio of 1 on the image carrier 11.
One potential measurement toner image 20 formed based on a patch pattern of a 00% toner image is shown.

Next, an image processing section of the image forming apparatus 10 of the present embodiment will be described with reference to FIGS.

FIG. 2 is a diagram showing a schematic configuration of an image processing unit of the image forming apparatus 10 of the present embodiment, together with an image input unit and a screen generation unit. FIG. 3 is a diagram showing a data correction unit of the image processing unit of FIG. FIG.

The image processing unit 14 includes a color correction unit 141,
It has a tone correction unit 142 and a data correction unit 143.

First, when an RGB signal is input to the image input unit 15, the RGB signal is converted into a signal of three colors of YMC by the color correction means 141 of the image processing unit 14, and the signal of three colors of YMC is converted into a gradation signal. The gradation is corrected by the correction unit 142 and converted into a signal of four colors of YMCK.

The signals of the four colors of YMCK are supplied to the data correction unit 143 as image data.
In 3, the following correction processing is performed.

The data correction section 143 is provided with the data storage means 1
431, an edge detection unit 1432, a correction target determination unit 1433, and a pixel value correction unit 1434.

The data storage means 1431 receives image data of a predetermined number of pixels from the gradation correction means 142, and temporarily stores the received image data. Further, the data storage unit 1431 reads pixel data from the stored image data one pixel at a time in a direction according to the time sequence of development by the developing device 12, that is, in the same direction as the development direction (see the arrow C in FIG. 1). The read pixel data is supplied to an edge detection unit 1432 and a pixel value correction unit 1434. Here, each pixel data supplied to the edge detection unit 1432 and the pixel value correction unit 1434 represents a pixel position X representing a pixel position according to the same direction as the developing direction of the developing device 12 and a dot area ratio. Pixel values.

The edge detecting means 1432 determines the position of the edge sandwiched between the high halftone dot area and the low halftone dot area based on the supplied pixel position X and the pixel value representing the halftone dot area ratio. To detect. Here, the determination of the region with the high halftone dot area ratio and the region with the low halftone dot area ratio is performed based on the conditions obtained based on the experimental results shown in Table 1.

Table 1 shows image data of various combinations of dot area ratios in an image which changes in the developing direction of the developing device from a region having a high dot area ratio CH to a region having a low dot area ratio CL. 9 is a table summarizing the results of observation of the degree of white spots in a boundary portion in an image formed of a fixed toner image formed on a sheet and input to the image forming apparatus 10 of the embodiment.

[0037]

[Table 1]

Table 1 shows the results when the value of the high halftone dot area ratio CH is changed with respect to the low halftone dot area ratio CL of the same value in one horizontal line. In the table, ◎ means that no white spots on the boundary are observed, ○ means that the occurrence of white spots on the boundary can be partially confirmed, but means that it is acceptable, Partial white spots are noticeably generated, which means that they are unacceptable. For example, in the second row of Table 1, when the low halftone dot area ratio CL is set to 5%, when the high halftone dot area ratio CH is 10% and 20%, no white spots are generated at the boundary portion. When the halftone dot area ratio CH is 30%, occurrence of an acceptable boundary white spot is partially confirmed, and when the high halftone dot area rate CH is 35% or more, an unacceptable boundary white spot is remarkable. Means to occur.

The reason why the observation in which the low dot area ratio CL is set to a dot area ratio of less than 5% was refrained is that in an electrophotographic image forming apparatus, the dot area ratio is generally less than 5%. This is because it is difficult to reproduce the pixel in the image output unit, and when the halftone dot area ratio is less than 5%, it is not necessary to consider the problem of the density reduction due to the blank area at the boundary.

The edge detecting means 1432 determines the relationship between the high halftone dot area ratio and the low halftone dot area ratio based on the experimental results shown in Table 1 as follows: high halftone dot area ratio ≧ low halftone dot area ratio + 30% Is determined as a region having a dot area ratio of 35% or more and 100% or less as a region having a high dot area ratio and 5% or more and 7% or more.
A region having a dot area ratio of 0% or less is determined as a region having a low dot area ratio.

When the edge position is detected by the edge detecting means 1432, in the present embodiment, the pixel position X ₀ of the pixel adjacent to the detected edge on the side of the region having the low halftone dot area ratio is used. , Sent to the correction target determination unit 1433, in this case, the region of the high halftone dot area ratio and the region of the low halftone dot area ratio determined at the time of detection of the edge position,
The pixel values representing the halftone dot area ratios (the pixel values C _H representing the halftone dot area ratios of the high halftone dot area regions and the pixel values C _L representing the halftone dot area ratios of the low halftone dot region regions) are corrected. The image data is sent to the pixel value correction unit 1434 via the target determination unit 1433. Further, in the present embodiment, the edge detecting means 1433 also detects the number of pixels included in the high halftone dot area and the low halftone dot area, and when the number of pixels is detected, ,
The number W _{H of} pixels included in the area of the high halftone area ratio and the number D _{L of} pixels included in the area of the low halftone area ratio are also sent to the pixel value correction unit 1434 via the correction target determination unit 1433. Sent.

On the other hand, the measured value of the potential of the toner image 20 for potential measurement having the dot area ratio of 100% measured by the potential measuring means 13 is also sent to the correction object determining means 1433.

Here, the potential of the toner image for potential measurement having a dot area ratio of 100% formed on the image carrier 11 and the degree of the blank portion at the boundary portion have a predetermined linear relationship as shown in FIG. Therefore, a description will be given below.

FIG. 4 shows the potential of the toner image and the degree of white spots in the boundary portion of the image composed of the fixed toner image formed on the paper when the developing potential is set to 200 V in the image forming apparatus of this embodiment. 5 is a graph showing the relationship of FIG.

The horizontal axis of the graph in FIG. 4 indicates the potential of the toner image for potential measurement having a dot area ratio of 100% formed on the image carrier 11. On the other hand, the vertical axis indicates the degree of the boundary white spot by the sensory test. The smaller the value, the smaller the degree of the boundary white spot, and the value 0 means that no boundary white spot is observed. Each of the values plotted in the graph of FIG. 4 is a value obtained by making each of the toner density, the type of toner, and the type of carrier in the developing device 12 different from when other values are obtained.

As shown in FIG. 4, even if the toner concentration, the type of toner, and the type of carrier in the developing device 12 are different, the image carrier 1
The potential of the toner image for potential measurement having a dot area ratio of 100% formed on the dot 1 and the degree of the blank portion at the boundary are determined by the dot area ratio 1
It can be seen that the lower the potential of the 00% potential measurement toner image is, the greater the degree of white spots at the boundary is in a linear relationship.

This means that the relationship between the amount of residual charge generated in the carrier and the degree of white spots in the boundary portion is such that the greater the amount of residual charge in the carrier, the greater the degree of white spots in the boundary portion. Probably because there is. Here, since the low-resistance carrier is used in the image forming apparatus of the present embodiment, the potential of the toner image formed on the image carrier can be regarded as the development potential. Therefore,
If the potential of the potential measurement toner image 20 having a dot area ratio of 100% is the same as the development potential, no residual charge remains on the toner carrier (carrier), and the potential of the potential measurement toner image 20 The lower the value, the more residual charge remains on the toner carrier (carrier).

The correlation between the potential of the potential measurement toner image 20 having a dot area ratio of 100% formed on the image carrier 11 shown in FIG. Stored in a table.

When the pixel position X ₀ of the pixel adjacent to the edge on the side of the low halftone dot area ratio is sent from the edge detecting means 1432 to the correction object determining means 1433,
Halftone dot area ratio 100 measured by the potential measuring means 13
From the measured value of the potential of the toner image 20 for potential measurement of FIG.
With reference to the lookup table in which the correlation shown in (1) is stored, the degree of the blank portion in the boundary portion is obtained. The obtained degree of the blank portion in the boundary portion is sent to the pixel value correction unit 1434.

The data correction unit 143 includes a pixel value C _H representing the halftone dot area ratio of the region having the high halftone dot area ratio, a pixel value C _L representing the halftone dot area ratio of the region having the low halftone dot area ratio, Four values C _H , C _L , the number W _{H of} pixels included in the area of the halftone dot area and the number D _{L of} pixels included in the area of the low halftone area ratio,
Adjacent to the correction area a and the edge on the area side of the low halftone dot area ratio for correcting the density decrease due to the boundary white spot for each of various combinations of values when W _H and D _L are variables. There is provided a look-up table (not shown) in which the correction amount b of the pixel value represented by the dot area ratio of the pixel to be represented is represented. Further, the data correction unit 143 corrects each of the correction area a and the correction amount b for each degree of the degree of the blank portion corresponding to the potential of the potential measurement toner image 20 having the dot area ratio of 100%. A look-up table (not shown) in which a correction function is represented is also provided. These correction functions are functions that increase the correction area a and increase the correction amount b as the potential of the potential measurement toner image having a dot area ratio of 100% is lower.

The pixel value correcting means 1434 calculates the pixel position X ₀ of the pixel adjacent to the edge on the side of the low halftone dot area, the pixel value C _H representing the halftone dot area ratio of the high halftone dot area, pixel value representing a halftone dot area ratio of a region of the halftone dot area ratio C _L, the number W _H of pixels included in the high halftone dot area ratio in the region, the number of pixels D in the low dot percentage in the region _{When L} and the degree of the blank area are sent, the pixel value C _H representing the halftone dot area ratio of the high halftone dot area and the halftone dot area ratio of the low halftone dot area are calculated. Based on the represented pixel value C _L , the number W _{H of} pixels included in the area with a high halftone dot area ratio, and the number D _L of pixels included in the area with a low halftone dot area rate, the density drop due to a white spot in the boundary portion The correction area a and the correction amount b are obtained with reference to a look-up table in which the correction area a and the correction amount b for correcting the correction are expressed. Further, the pixel value correction unit 1434 also has a look-up table in which a correction function for correcting each of the correction area a and the correction amount b is represented based on the degree of the boundary white spot transmitted from the correction target determination unit 1433. The correction area a and the correction amount b are corrected by the correction function with reference to the corrected correction area a ′ and the halftone dot area ratio of the pixel adjacent to the edge on the side of the area having the low halftone dot area ratio. A correction amount b ′ of the corrected pixel value is obtained.

Of the pixels in the corrected area a ', pixels closer to the edge detected by the edge detecting means 1432 have a greater degree of white spots at the boundary, and the distance from the edge and the degree of white spots at the boundary are higher. Is a linear relationship, in the present embodiment, the pixel value correction unit 1434 indicates the positions of the pixels included in the corrected correction area a ′ according to the same direction as the developing direction of the developing device 12. Correction is performed according to the pixel position X. That is, the correction amount y of the pixel value representing the dot area ratio is obtained for each pixel included in the corrected correction area a ′ by the following linear expression. y = (b ′ / a ′) X + b ′ − (b ′ / a ′) X _{0 The} pixel value correction unit 1434 further obtains the value for each pixel included in the corrected correction area a ′ obtained by the above equation. The corrected amount of correction y is added to the pixel value representing the dot area ratio of each pixel included in the corrected correction area a ′ based on the image data sent from the data storage unit 1431.

Hereinafter, the correction of the image data will be described with reference to FIG.
This will be further described with reference to FIG.

FIG. 5 is a graph for explaining the correction of the pixel value by the pixel value correcting means 1434.

The horizontal axis of the graph shown in FIG.
2 shows a pixel position X representing a pixel position in the same direction as the developing direction, and a vertical axis shows a pixel value representing a dot area ratio. The thick solid line in FIG. 5 represents the image data supplied from the data storage unit 1431 to the pixel value correction unit 1434. On the other hand, a dashed line represents image data after correction by the pixel value correction unit 1434, and a pixel value representing a dot area ratio of each pixel included in the corrected correction area a ′ is a pixel close to the edge. Indicates that the pixel value is corrected to the pixel value side representing the high halftone dot area ratio.

Therefore, the combination of the correction object determination means 1433 and the pixel value correction means 1434 corresponds to the data correction means according to the present invention.

The correction area a 'thus corrected.
The corrected pixel values of the pixels included in are stored in the data storage unit 1431 and supplied to the screen generation unit 16 from the data storage unit 1431 as output image data.

The screen generator 16 generates a screen signal whose pulse width is modulated according to the pixel value of the output image data. Based on the generated screen signal, an exposure device (not shown) irradiates exposure light onto the image carrier 11 to form an electrostatic halftone latent image.

The present invention is not limited to the embodiment described above. For example, in the above-described embodiment, 1 using the corrected correction area a ′ and the corrected correction amount b ′
The correction method according to the following equation is adopted. However, the present invention is based on the fact that the potential of the actually developed toner is used to correct the image data according to the state of the image forming apparatus at that time. The correction coefficient and the method of correcting the pixel value using the correction coefficient may be any method. Further, the type of the developer is not limited to the two-component type.

[0060]

As described above, according to the present invention, it is possible to always perform an accurate correction for eliminating a decrease in the wettability due to a blank portion at a boundary without incurring an increase in the size and cost of the apparatus. An apparatus can be provided.

[Brief description of the drawings]

FIG. 1 is a schematic configuration diagram of a characteristic part of an image forming apparatus according to an embodiment of the present invention, excluding an image processing unit.

FIG. 2 is a diagram illustrating a schematic configuration of an image processing unit of the image forming apparatus according to the embodiment, together with an image input unit and a screen generation unit.

FIG. 3 is a diagram illustrating a data correction unit of the image processing unit in FIG. 2;

FIG. 4 is a graph showing the relationship between the potential of a toner image and the degree of white spots in a boundary portion of an image formed of a fixed toner image formed on an image recording sheet when the developing potential is set to 200 V in the image forming apparatus of the present embodiment. It is a graph showing the relationship.

FIG. 5 is a graph for explaining pixel value correction by a pixel value correction unit.

FIG. 6 is a diagram illustrating a toner image formed on an image carrier.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 10 Image forming apparatus 11 Image carrier 12 Developing device 121 Developer carrier 122 A pair of screw augers 13 Potential measurement means 131 Electrometer 132 Probe 20 Potential measurement toner image 14 Image processing part 141 Color correction means 142 Tone correction means 143 Data correction unit 1431 Data storage unit 1432 Edge detection unit 1433 Correction target determination unit 1434 Pixel value correction unit 15 Image input unit 16 Screen generation unit

Continued on the front page (72) Inventor: Yutaka Kanai 430, Nakaicho, Ashigamikami-gun, Kanagawa Prefecture Green Tech Inside Fuji Xerox Co., Ltd. (Reference) 2C262 AA05 AA24 AA26 AB13 BB29 DA03 EA06 GA03 GA43 2H027 DA10 DA50 DB01 EC03 EC06 EC20 EE07 EF06 EF09 FD00 FD03 ZA07 5C074 AA08 BB02 BB26 CC26 DD04 EE12 FF07 FF11 GG12 9A001H34

Claims (4)

[Claims] An image carrier having an electrostatic halftone latent image formed on its surface by receiving exposure light modulated in accordance with image data while moving in a predetermined direction, and containing toner. A developing unit that develops an electrostatic halftone dot latent image formed on the image carrier with a toner to form a toner image on the image carrier, wherein the toner image formed on the image carrier is An image forming apparatus that finally forms an image composed of a fixed toner image on the image recording medium by transferring and fixing the image on a predetermined image recording medium; Position where an electrostatic halftone dot latent image relatively changes from a high halftone dot area to a low halftone dot area with a predetermined edge as a boundary in accordance with the time sequence of development by Based on image data for forming the electrostatic halftone latent image Edge detecting means for detecting the potential, toner image potential measuring means for forming a potential measuring toner image on the image carrier and measuring the potential of the potential measuring toner image, and an edge detected by the edge detecting means The position, the halftone dot area ratio of the high dot area ratio region and the low dot area ratio region sandwiching the edge, and the potential of the potential measuring toner image measured by the toner image potential measuring means. An image forming apparatus for correcting image data of a predetermined correction area extending from the edge to a low halftone dot area based on the edge to a high halftone dot area side. 2. A method according to claim 1, wherein said toner image potential measuring means forms a toner image having a dot area ratio of 100% on said image carrier and measures the potential of said toner image. 2. The image forming apparatus according to 1. 3. The data correction means corrects the image data in the correction area to a higher halftone dot area ratio as the potential of the toner image measured by the toner image potential measurement means is lower. The image forming apparatus according to claim 1, wherein: 4. An image forming apparatus according to claim 1, wherein said edge detecting means has a dot area ratio of 30% or more from a region having a dot area rate of 35% or more in accordance with a time sequence of development by said developing device. 2. The image forming apparatus according to claim 1, wherein an edge formed by a drop of the halftone dot area ratio of 30% or more is detected when shifting to an area of 5% or more and 70% or less.