The present disclosure claims the priority to Chinese patent application No. 202310003277.9, filed on Jan. 3, 2023, the entirety of which is incorporated herein by reference.
The present disclosure generally relates to the field of optical scanning technology and, more particularly, relates to an image-forming apparatus and a controller.
A laser printer typically includes an optical scanning unit for exposing a photosensitive member. The optical scanning unit emits laser based on image data. The laser is reflected by a rotating polygon mirror, and reflected laser light is then transmitted through a scanning lens. Transmitted light irradiates a photosensitive drum to expose the photosensitive drum. As the polygon mirror rotates, a laser spot formed on the surface of the photosensitive drum continuously moves to achieve scanning, thereby forming a latent image on the photosensitive member.
An existing scanning lens may have F-θ characteristics. The lens with F-θ characteristics may cause the laser spot to move on the surface of the photosensitive member at a uniform linear velocity when the polygon mirror rotates at a uniform angular velocity. The scanning lens with F-θ characteristics may be configured to perform proper exposure.
However, the scanning lens with F-θ characteristics may have relatively large size and high cost. Therefore, in order to reduce the size and cost of an image-forming apparatus, the scanning lens without F-θ characteristics may be configured.
In the existing technology, electrical correction may be performed to change an image clock frequency during a scanning operation, such that when the laser spot does not move at a uniform speed on the surface of the photosensitive member, no pixel deviation may be in the laser spot formed on the surface of the photosensitive member.
However, in above-mentioned existing technology, due to the change in the clock frequency, the exposure amounts of the pixels at an end region and a central region of the photosensitive member along a main scanning direction may also change, and such difference in exposure amounts may cause image degradation.
One aspect of the present disclosure provides an image-forming apparatus. The image-forming apparatus includes a photosensitive member; a scanning unit, configured to perform laser scanning on the photosensitive member at a non-constant linear speed along a main scanning direction to form an electrostatic latent image; and a controller, configured to make a first scanning period corresponding to a first pixel at a central region of the photosensitive member to be not equal to a second scanning period corresponding to a second pixel at a non-central region of the photosensitive member. The first pixel and the second pixel are each configured with a light-emitting time period and a non-light-emitting time period; the light-emitting time period satisfies that a light-emitting time length of the light-emitting time period of the first pixel is same as a light-emitting time length of the light-emitting time period of the second pixel; and for printing a fixed page, a light-emitting power of the scanning unit is a preset fixed value.
Another aspect of the present disclosure provides a controller, applied to an image-forming apparatus, where an image-forming lens of the image-forming apparatus is not capable of correcting a laser along a main scanning direction to be linear. A controller is configured to make a first scanning period corresponding to a first pixel at a central region of a photosensitive member to be not equal to a second scanning period corresponding to a second pixel at a non-central region of the photosensitive member, where the first pixel and the second pixel are each configured with a light-emitting time period and a non-light-emitting time period; the light-emitting time period satisfies that a light-emitting time length of the light-emitting time period of the first pixel is same as a light-emitting time length of the light-emitting time period of the second pixel; and for printing a fixed page, a light-emitting power of the scanning unit is a preset fixed value.
Other aspects of the present disclosure may be understood by those skilled in the art in light of the description, the claims, and the drawings of the present disclosure.
To clearly describe technical solutions of various embodiments of the present disclosure, the drawings which need to be configured for describing various embodiments are described below. Obviously, the drawings in the following description are merely some embodiments of the present disclosure. For those skilled in the art, other drawings may be obtained in accordance with the drawings without creative efforts.
In order to better understand the technical solutions of the present disclosure, embodiments of the present disclosure are described in detail below with reference to accompanying drawings.
It should be understood that described embodiments are only some of embodiments of the present disclosure, rather than all of embodiments. According to embodiments in present disclosure, all other embodiments obtained by those skilled in the art without making creative efforts should fall within the protection scope of present disclosure.
It may be seen that when the rotation angular speed of the rotating polygon mirror 405 is constant, the linear speed of the light spot moving along the main scanning direction may be not constant, that is, the linear speed at the end may be faster than the linear speed at the center. Such linear velocity inconsistency may lead to scanning deviation. Such deviation problem may be solved by designing an image-forming lens 406 as the lens with F-θ characteristics. The F-θ lens may achieve linear scanning with incident light of constant angular velocity. However, the lens with F-θ characteristics may be relatively large and expensive and require more space inside the printer; or in some image-forming apparatuses using the F-θ lens, the characteristics of the F-θ lens may be not sufficient to completely correct the laser along the main scanning direction to be linear. Therefore, a method of adjusting control period to reduce the scanning deviation is disclosed in the existing technology. For the principle of such method shown in
To solve above-mentioned problem, embodiments of the present disclosure provide an image-forming apparatus. The image-forming apparatus may include a photosensitive member; a scanning unit, configured to scan the photosensitive member at a non-constant linear speed along the main scanning direction to form an electrostatic latent image on the photosensitive member; and a controller, configured to make the first scanning period T1 corresponding to the first pixel at the central region of the photosensitive member to be not equal to the second scanning period T2 corresponding to the second pixel at a non-central region of the photosensitive member. Both the first pixel and the second pixel may be configured with a light-emitting time period and a non-light-emitting time period; the light-emitting time period may satisfy that the light-emitting time length of the light-emitting time period of the first pixel may be same as the light-emitting time length of the light-emitting time period of the second pixel. For printing a fixed page, the light-emitting power of the scanning unit may be a preset fixed value.
The non-central region in the present disclosure may further include an end region and at least one transition region, where the scanning period of the pixel in the end region may be shorter than the scanning period of the pixel in the transition region. As shown in
In one embodiment of the present disclosure, the scanning unit may have the following characteristics that the scanning speed of the end region on the scanning surface 407 may be higher than the scanning speed of the central region, which is because when the rotational angular velocity of the rotating polygon mirror (i.e., deflector) 405 is constant, the reflective surface may be further away from the end region of the photosensitive drum than from the central region of the photosensitive drum. Since the linear velocity is equal to the product of angular velocity and radius, it should be noted that the scanning linear velocity of the end region may be higher than the scanning linear velocity of the central region. That is, the scanning unit in one embodiment may perform laser scanning on the surface of the photosensitive member at a non-constant linear velocity. The image signal generation unit 100 may receive printing information from a computer and generate the VIDEO signal corresponding to image data; and the laser driving unit 300 may supply current to the light source 401 in response to the VIDEO signal to cause the light source 401 to emit light, such that the latent image corresponding to the VIDEO signal may be formed on the scanning surface. The image deviation problem caused by non-constant scanning speed may be solved by setting the period of the VIDEO signal. That is, the first scanning period T1 of the VIDEO signal corresponding to the pixel at the non-central region (such as the end region) may be shorter, and the second scanning period T2 of the VIDEO signal corresponding to the pixel at the central region may be longer. In one embodiment of the present disclosure, it may further configure the time of the VIDEO signal at an ON state (i.e., the laser emits light) in a period; and for remaining time of such period, the VIDEO signal may be at an OFF state (i.e., the laser does not emit light). That is, the VIDEO signal may be configured to control the scanning unit to emit light or not to emit light.
It may be understood that, in another embodiment of the present disclosure, the first scanning period T1 of the VIDEO signal corresponding to the pixel at the non-central region may be longer, and the second scanning period T2 of the VIDEO signal corresponding to the pixel at the central region may be shorter, which is due to “over-correction” of above-mentioned image-forming lens 406. At this point, the scanning speed of the end region on the scanning surface 407 may be lower than the scanning speed of the central region on the scanning surface 407. To solve such problem, the controller may be configured to make T1 to be less than T2.
The first VIDEO signal example is shown in
The second VIDEO signal example is shown in
The third VIDEO signal example is shown in
The fourth VIDEO signal example is shown in
It may be seen from
It may be seen from above-mentioned principle that the maximum value of the light-emitting time period should not exceed total time length of one scanning period at the end region, otherwise the light-emitting time periods at the end region and other regions may be not consistent with each other. If the proportion of the light-emitting time period to total time of the scanning period is no more than 3/4, the problem of inconsistent pixel widths may also be reduced. Pixel width refers to the product of exposure time of unit pixel and the scanning linear velocity. In the present disclosure, the light-emitting time periods in the scanning period of the pixels at the central region and the non-central region may be same, but the scanning linear velocities may be different, and theoretically the pixel widths may be different. If the proportion of the light-emitting time period to total time of the scanning period is reduced to less than 3/4, the problem of inconsistent pixel widths may be no longer obvious and the impact on image quality may be reduced.
In an optional implementation manner, the scanning unit may include a rotating polygon mirror for reflecting laser. The laser reflected by the rotating polygon mirror may be applied to the photosensitive member through the image-forming lens, and the image-forming lens cannot correct the laser along the main scanning direction to be linear. That is, the image-forming lens used in one embodiment may have certain optical correction characteristics but may not completely correct the scanning light beam to be linear. In such case, above-mentioned manner for configuring the light-emitting time period and the non-light-emitting time period may also be used to solve such problem.
The present disclosure further provides a controller, applied to the image-forming apparatus. The image-forming lens used in the image-forming apparatus cannot correct the laser along the main scanning direction to be linear. The controller may be configured to make the first scanning period T1 corresponding to the first pixel at the central region of the photosensitive member to be not equal to the second scanning period T2 corresponding to the second pixel at the non-central region of the photosensitive member. Both the first pixel and the second pixel may be configured with the light-emitting time period and the non-light-emitting time period; the light-emitting time period may satisfy that the light-emitting time length of the light-emitting time period of the first pixel may be same as the light-emitting time length of the light-emitting time period of the second pixel. For printing a fixed page, the light-emitting power of the scanning unit may be a preset fixed value.
The controller used in exemplary embodiment two, same as the controller in exemplary embodiment one, may be applied to the image-forming apparatus without the F-θ lens and may also be applied to the image-forming apparatus including an optical correction lens that the correction characteristics of the lens are not sufficient to completely correct the scanning light beam to be linear. In one embodiment, the controller may include the image signal generation unit 100 and the control unit 1 as shown in
Compared with the existing technology, the technical solutions provided by the present disclosure may achieve at least the following beneficial effects.
Compared with the existing technology, in embodiments of the present disclosure, the exposure amounts of the pixels at different regions along the main scanning direction may be same, which may reduce the problem of inconsistent image density at different regions which easily occurs in the existing technology, thereby improving image quality. Furthermore, the control logic of the present disclosure may be simple and easy to be configured and adjusted.
The above are only optional embodiments of the present disclosure and are not intended to limit the present disclosure. For those skilled in the art, the present disclosure may have various modifications and changes. Any modifications, equivalent replacements, improvements and the like made within the spirit and principle of the present disclosure shall be included in the protection scope of the present disclosure.
Number | Date | Country | Kind |
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202310003277.9 | Jan 2023 | CN | national |