KR100416556B1 - Apparatus and method for compensating image quality - Google Patents

Abstract

The present invention relates to a scanning system and an operation method, and more particularly, to an image quality compensation device and method for correcting characteristics and light quantity deviations of a color-contact image sensor (CIS) to realize an optimum image quality. will be. In a color-adherent image sensor scanning system using red, green, and blue light emitting elements as a light source, the average value of the pixels is calculated from a turn-on time of the light emitting element preset for pixel deviation correction of a read original, Image processing means for determining the light emitting device turn-on time by comparing the average value of the pixels calculated while changing the turn-on time of the light emitting device in a predetermined step; And control means for providing the interval and the reference value of the step, and controlling the pixel deviation correction of the read document with the determined light emitting element turn-on time. According to the present invention, by setting the LED turn-on time that is most suitable for the R, G, B light intensity characteristics of the CIS, there is an effect of enabling a uniform image quality that can cover the optimum image quality and each CIS deviation. .

Description

Apparatus and method for compensating image quality}

The present invention relates to a scanning system and an operation method, and more particularly, to an image quality compensation device and method for correcting characteristics and light quantity deviations of a color-contact image sensor (CIS) to realize an optimum image quality. will be.

Image scanning devices, such as scanners, are the most common means for scanning prints, photographs, human-written notes or pictures in color or black and white. Is an essential component.

In such an image scanning apparatus, an image sensor such as a CCD (Charge Coupled Device) or a CIS performs photoelectric conversion in proportion to light reflected from an original to be scanned, thereby converting the pixel pattern into an original image. Scanners using CCDs generally use halogen lamps or fluorescent lamps as light sources, while scanners using CIS typically use small light emitting diodes (LEDs) as light sources. The black and white CIS is a single white light, and the color CIS irradiates red, blue, and green LEDs alternately to read the amount of light for each LED and recognize the original color by the combination of these three values.

It is very important that these LEDs are mechanically prevented from being exposed to external light as the amount of light is significantly smaller than that of lamps as well as external light. On the other hand, if the light reflected from the original is not incident on the image sensor correctly, or if the deviation occurs due to the optical system assembly tolerance, the amount of light reflected from the original cannot be accurately measured by the image sensor, resulting in image distortion. This phenomenon is called shading. Therefore, the image scanning apparatus performs shading correction before scanning the actual document so that data can be read at a stable level when scanning the actual document. There are two shading corrections, white shading correction and black shading correction. White shading correction is a method to correct the bright characteristics of the CIS. The white shading correction method is used to read the white original, store the entire pixel value, and then correct the actual data.Black shading correction is a method to correct the dark characteristics of the CIS. As a result, it is ideal but practically difficult to read a black manuscript, so that the entire pixel value is read and stored in the LED off state and then corrected in association with the white shading value.

CIS features ROD lens (not shown) that plays a role in integrating and delivering each sample variation, each LED variation, pixel variation, sensor chip (not shown), and reflected light amount to the sensor chip. The amount of light deviation due to such as there exists. Here, the LED turn-on time is MIN. It can be used up to the SCAN LINE TIME (minimum time to read one line), but because the R, G, B light characteristics are different, there is a problem to turn on constantly, and if the LED turn-on time is short, the level This becomes unstable, and if it is too long, the saturation (close to the saturation) state is a problem that it is difficult to achieve the optimum image quality and consistent image quality.

The technical problem to be achieved by the present invention is to provide an image quality compensation device that implements the optimal image quality by setting the LED turn-on time to optimize the R, G, B light amount in the CIS.

Another technical problem to be achieved by the present invention is to provide an image quality compensation method for implementing an optimum image quality by setting the LED turn-on time to optimize the amount of R, G, B in the CIS.

1 is a block diagram showing the configuration of an image quality compensation device according to the present invention.

2 is a flowchart showing the operation of the image quality compensation method according to the present invention.

The image quality compensation apparatus for solving the technical problem to be achieved by the present invention is a color-adherent image sensor scanning system using a red, green, blue light emitting element as a light source, the above-mentioned preset for the pixel deviation correction of the read document The image of calculating the average value of the pixel from the turn-on time of the light emitting device, and comparing the average value of the pixel calculated by changing the turn-on time of the light emitting device in a predetermined step to determine the light-emitting device turn-on time Processing means; And control means for providing an interval and a reference value of the step for determining a light emitting device turn-on time in the imaging means, and controlling pixel deviation correction of the read document with the determined light emitting device turn-on time. It is preferable.

The image processing means may include: a shading processor configured to correct pixel deviation of the read document according to the determined turn-on time of the light emitting device; An average value calculator configured to calculate an average value of the pixel at a preset turn-on time of the light emitting device and to calculate an average value of the pixel at the turn-on time of the light emitting device according to the step change; And comparing the average value of the pixel calculated by changing the turn-on time of the light emitting device with the step and the reference value provided by the control means, by comparing the average value calculated in the previous step. And a comparison unit outputting the shading processing unit after determining the time.

In the present invention, the processing for determining the turn-on time of the red, green, and blue light emitting devices is sequentially performed in the image processing means, and the light emitting device whose turn-on time is determined first stops the process of the step. Waiting until the turn-on time of the remaining light emitting device is determined.

According to another aspect of the present invention, there is provided a method of compensating for image quality, the method of operating a color tight image sensor scanning system using red, green, and blue light emitting elements as a light source. Calculating an average value of the pixels from a preset turn-on time of the light emitting device to correct the deviation; (b) determining the light emitting device turn-on time from the average value of the pixels calculated while changing the turn-on time of the light emitting device in a predetermined step; And (c) correcting pixel deviation of the read original according to the determined turn-on time.

In the present invention, step (b) comprises: (b-1) calculating an average value of the pixels while changing a preset turn-on time of the light emitting device to a predetermined step; (b-2) comparing the calculated average value with the average value calculated in the previous step; And (b-3) determining a turn-on time of the light emitting device by comparing the comparison value with a reference value.

In the present invention, in the step (b), the processing for determining the turn-on time of the red, green, and blue light emitting devices is sequentially performed at the same time, and the light emitting device whose turn-on time is determined first stops the process of the step. And wait until the turn-on time of the remaining light emitting devices is determined.

Hereinafter, with reference to the accompanying drawings will be described in detail the present invention.

1 is a block diagram showing a configuration of an image quality compensation device according to the present invention, which includes an image quality control unit 100, an image processing unit 101, a shading processing unit 102, a CIS 103, an ADC 104, a RAM 105, It consists of ROM 106. In the present invention, the image quality control section 100 includes a control section 100-1, an average value calculating section 100-2, and a comparing section 100-3. In the following claims, the shading processor 102, the average value calculator 100-2, and the comparator 100-3 are described as image processing means.

Next, the image quality compensation device according to the present invention will be described in detail with reference to FIG. 1.

The CIS 103 performs an original reading function for reading an original loaded into the scanning system. The CIS 103 reads the amount of light reflected from the original while sequentially turning on an internal optical device, that is, a red LED, a green LED, and a blue LED. At this time, the LED turn-on time is stored in the ROM 106. When the read operation by the three LEDs is completed, go to the next line and repeat the same operation.

The analog signal read out from the CIS 103 is converted into digital in the ADC 104 and stored in the RAM 105. The data stored in the RAM 105 is converted and used in a desired format by a color matching table (not shown) preset for a desired output (eg, PC SCAN, PRINT, COLOR FAX, etc.).

The image processor 101 processes digitally converted image image data, and the shading processor 102 performs shading processing of the processed image image data.

The shading processor 101-2 corrects the actual data so that the data can be read at a stable level when scanning the actual document. In the present invention, the shading processor 102 performs a white shading correction operation. White shading correction is a method for correcting light characteristics of the CIS 103. The white shading correction is a method of reading white originals, storing all pixel values, and then correcting actual data.

For shading correction, the controller 100-1 sets each LED turn-on time to MIN. SCAN LINE TIME (minimum time for reading one line) is set, and the average value calculation unit 100-2 sets MIN. The average value of all pixels is calculated starting from the SCAN LINE TIME. The average value calculator 100-2 then calculates the average value of all the pixels while lowering the LED turn-on time in a predetermined step. The step of changing the LED turn-on time is controlled by the controller 100-1, and the step of changing the LED turn-on time may proceed to TOP-DOWN or DOWN-TOP according to the characteristics of the CIS 103.

The comparator 100-3 compares the average value calculated in the current step with the average value calculated in the previous step. The comparison unit 100-3 compares the average value compared according to the step with the reference value provided by the control unit 100-1, and if there is a difference more than a predetermined time, the comparison unit 100-3 compares the average value and the reference value again, and then compares the average value with the predetermined value. If no difference is found, determine the optimal LED turn-on time in that state. The optimally determined LED turn-on time is applied to the shading correction task. The reference value provided by the controller 100-1 is set as pre-experimental data.

Processing for determining the LED turn-on time proceeds sequentially at the same time, and the LED whose turn-on time is determined first stops the step progress and waits until the remaining LED turn-on time is determined.

2 is a flowchart illustrating the operation of the image quality compensation method according to the present invention, performing a white shading operation (200), MIN. Setting the SCAN LINE TIM to each LED turn-on time and calculating an average value of all the pixels (201), calculating the average value of all the pixels while decreasing each LED turn-on time to a predetermined step (202), present Comparing the average value calculated in the step with the average value calculated in the previous step (203), determining whether the comparison result value is smaller than the reference value (204), and determining the LED turn-on time of the state as an optimal value. 205, applying 206 the determined optimal LED turn-on time to the white shading operation.

Next, the image quality compensation method according to the present invention will be described in detail with reference to FIG. 2.

When scanning the actual document, white shading correction is performed during the shading correction operation to correct the actual data so that the data can be read at a stable level (step 200). White shading correction is a method to correct the bright characteristics of the CIS. The white shading correction method reads a white original, stores the entire pixel value, and then corrects the actual data.

The control unit 100-1 is MIN. SCAN LINE TIM (minimum time for reading one line) is set to each LED turn-on time, and the average value calculation unit 100-2 sets MIN. The average value of all pixels in the SCAN LINE TIM is calculated (step 201).

The control unit 100-1 sets each LED turn-on time to MIN. In step 202, the average value calculator 100-2 calculates the average value of all pixels according to the down step. The step of changing the LED turn-on time is controlled by the controller 100-1, and the step of changing the LED turn-on time may proceed to TOP-DOWN or DOWN-TOP according to the characteristics of the CIS 103.

The comparator 100-3 compares the average value calculated in the current step with the average value calculated in the previous step (203).

It is determined whether the comparison result value of the comparator 100-3 is smaller than the reference value provided by the controller 100-1 (204), and the reference value provided by the controller 100-1 is set as pre-experimental data.

If the comparison result of the comparison unit 100-3 is smaller than the reference value provided by the control unit 100-1, the LED turn-on time of the state is determined as an optimal value (step 205). However, when the comparison result of the comparison unit 100-3 is larger than the reference value provided by the control unit 100-1, the control unit 100-1 jumps to step 202 and compares the average value and the reference value calculated in the next step again.

The determined optimal LED turn-on time is applied to the white shading correction operation (step 206).

Processing for determining the LED turn-on time proceeds sequentially at the same time, and the LED whose turn-on time is determined first stops the step progress and waits until the remaining LED turn-on time is determined.

The present invention is not limited to the above-described embodiments and can be modified by those skilled in the art within the spirit of the invention.

As described above, according to the present invention, by setting the LED turn-on time that is most suitable for the R, G, B light quantity characteristics of the CIS, it is possible to realize a uniform image quality that can cover the optimum image quality and each CIS deviation. It is effective.

Claims (6)

In the color-contact image sensor scanning system using a red, green, blue light emitting element as a light source, The average value of the pixel is calculated from the preset turn-on time of the light emitting device for correcting pixel deviation of the read document, and the average value of the pixels calculated while changing the turn-on time of the light emitting device is compared in a predetermined step. Image processing means for determining the turn-on time of the light emitting device; And An image quality control means for providing an interval and a reference value of the step for determining a light emitting device turn-on time in the imaging means, and controlling the pixel deviation correction of the read document with the determined light emitting device turn-on time. Compensation device. The method of claim 1, wherein the image processing means A shading processor configured to correct pixel deviation of the read document according to the determined light emitting device turn-on time; An average value calculator configured to calculate an average value of the pixel at a preset turn-on time of the light emitting device and to calculate an average value of the pixel at the turn-on time of the light emitting device according to the step change; And The step of comparing the average value of the pixel calculated while changing the turn-on time of the light emitting device by the step and the reference value provided by the control means by comparing the average value calculated in the previous step with the light emitting device turn-on time And a comparator configured to determine and output the shader to the shading processor. 2. The apparatus according to claim 1, wherein said image processing means Processing for determining the turn-on time of the red, green, and blue light emitting devices is sequentially performed simultaneously, and the light emitting device having the turn-on time determined first stops the step and the turn-on time of the remaining light emitting devices is determined. Picture quality compensation device, characterized in that waiting until. In the operation method of the color-contact image sensor scanning system using a red, green, blue light emitting element as a light source, (a) calculating an average value of the pixels from a preset turn-on time of the light emitting device to correct pixel deviation of a read original; (b) determining the light emitting device turn-on time from the average value of the pixels calculated while changing the turn-on time of the light emitting device in a predetermined step; And (c) correcting pixel deviation of the read original according to the determined turn-on time. The method of claim 4, wherein step (b) (b-1) calculating an average value of the pixels while changing a preset turn-on time of the light emitting device in a predetermined step; (b-2) comparing the calculated average value with the average value calculated in the previous step; And (b-3) determining a turn-on time of the light emitting device by comparing the comparison value with a reference value. The method of claim 4, wherein in step (b) Processing for determining the turn-on time of the red, green, and blue light emitting devices is sequentially performed simultaneously, and the light emitting device having the turn-on time determined first stops the step and the turn-on time of the remaining light emitting devices is determined. Image quality compensation method, characterized by waiting until.