TW201347527A - Method for producing high dynamic range image - Google Patents

Abstract

A method for producing high dynamic range image is provided. The present invention includes capturing a present image with a present exposure value (EV). Count the quantity of pixels of the present image under different luminance, and set the quantity of the pixels with particular luminance as the quantity of dark pixels and the quantity of light pixels. Determine and obtain a lowest EV according to the quantity of the light pixels and a first threshold. Determine and obtain a highest EV according to the quantity of the dark pixels and a second threshold. Add a compensation EV to the present EV and repeat the steps mentioned above until obtained the highest EV and the lowest EV. Generate the HDR image based on a first image with the highest EV and the second image with the lowest EV.

Description

High dynamic range image processing method

The invention relates to a method for processing an image, and in particular to a method for processing a high dynamic range image.

Thanks to the rapid advancement of technology, the camera's functions have been greatly improved, whether it is shutter speed, aperture size, focus speed or image processing speed has made great progress. However, since the range of colors and brightness in the real world is very large, most cameras still only capture a fixed dynamic range (the range from the brightest to the darkest in the picture), so that the camera shoots The photos will be different from the actual ones in some scenes.

The emergence of High Dynamic Range (HDR) display technology allows the image captured by the camera to be closer to the actual scene. In the general HDR display technology, the camera captures three different Exposure Value (EV), such as -1EV, 0EV, and +1EV, and then corrects the image captured based on the above three exposure values using linear or nonlinear calculations. The method enables the dynamic range of the image to be further extended to obtain a High Dynamic Range Image (HDRI).

However, in some scenes with high contrast, such as sunlight and shadows in the shooting scene, the high dynamic range image capture using only the -1EV, 0EV and +1EV exposure values can not cover the scene. All image information in the middle, in other words, in this case, the processing method using the above high dynamic range image still causes the image captured by the camera to be distorted.

The invention provides a processing method for a high dynamic range image, which can determine an exposure value range required for generating a high dynamic range image according to an ambient brightness and contrast of an actual scene to be captured, and obtain an image according to the exposure value range. Produces high dynamic range images.

The invention provides a processing method for high dynamic range images, which is suitable for an image capturing device with a processing unit. The processing method includes the following steps: capturing the current image according to the current Exposure Value (EV); counting the number of pixels (pixels) of the current image under different brightness, and the sum of the number of pixels whose brightness is less than the first value is the number of pixels in the dark portion And the sum of the number of pixels whose brightness is greater than the second value is the number of bright pixels; according to the number of bright pixels and the first threshold, the lowest exposure value is determined and obtained; according to the number of dark pixels and the second threshold, the highest exposure is determined and obtained. a value; adding the current exposure value to the exposure compensation value, repeating the above steps until the highest exposure value and the lowest exposure value are obtained; and generating a high dynamic according to the first image having the highest exposure value and the second image having the lowest exposure value Range Dynamic Image (HDRI).

In an embodiment of the invention, the step of determining and obtaining the lowest exposure value further comprises: when the number of bright pixels is greater than the first threshold, causing the lowest exposure value to be an exposure value of the previous captured image.

In an embodiment of the invention, the step of determining and obtaining the highest exposure value further comprises causing the highest exposure value to be the current exposure value when the number of dark portions of the pixels is less than the second threshold.

In an embodiment of the invention, the processing method of the high dynamic range image further comprises: making the initial current exposure value a lowest level exposure value.

The invention provides a processing method for high dynamic range images, which is suitable for an image capturing device with a processing unit. The processing method includes the following steps: a. capturing the current image according to the current Exposure Value (EV); b. counting the number of pixels (pixels) of the current image at different brightnesses, and summing the number of pixels whose brightness is less than the first value. The number of pixels in the dark portion, and the sum of the pixels whose brightness is greater than the second value is the number of bright pixels; according to the number of bright pixels and the first threshold, the lowest exposure value is determined and obtained, and the current exposure value is added to the exposure compensation value. Repeat steps a and b above until the lowest exposure value is obtained; determine and obtain the highest exposure value according to the number of dark portions and the second threshold, and subtract the previous exposure value from an exposure compensation value, repeat steps a and b above; Obtaining a highest exposure value; and generating the high dynamic range image based on the first image having the highest exposure value and the second image having the lowest exposure value.

In an embodiment of the invention, the step of determining and obtaining the lowest exposure value further comprises causing the lowest exposure value to be the current exposure value when the number of bright portion pixels is less than the first threshold.

In an embodiment of the invention, the processing method of the high dynamic range image further comprises: determining the initial current exposure value as a standard exposure value, wherein the standard exposure value is determined according to the actual brightness and contrast of the current image captured initially.

Based on the above, the processing method proposed in the embodiment of the present invention uses the method of setting the high brightness threshold and the low brightness threshold to enable the processing unit of the image capturing device to be based on the set threshold value and the number of bright and dark pixels. Dynamically determines the range of exposure values required for high dynamic range images.

The above described features and advantages of the present invention will be more apparent from the following description.

The processing method of the high dynamic range image proposed in the embodiment of the present invention provides an image capturing device (such as a camera, a camera, etc.) to dynamically adjust and generate a high dynamic range image according to the brightness and contrast of the actual shooting scene. The processing method of the required exposure value range. In order to make the content of the present invention easier to understand, the following specific embodiments are illustrative of the embodiments of the present invention. In addition, wherever possible, the elements and/

FIG. 1 is a flow chart showing the steps of a method for processing a high dynamic range image according to an embodiment of the invention. Please refer to FIG. 1 , the embodiment is applicable to any image capturing device (such as a camera, a camera, etc.) having a processing unit, but is not limited thereto. In step S100, the image capturing device (not shown) First, a current image is taken based on a current exposure value. In this embodiment, the processing unit (not shown) causes the initial current exposure value to be the lowest level exposure value (step S10), that is, the lowest exposure value within the adjustable range of the exposure value in the image capturing device. . In the general image capturing device application, taking a digital camera as an example, the exposure values are relative exposure values, and the adjustable range is between -2 EV and +2 EV, and the exposure value can be adjusted according to different designs. The adjustable range is divided into 5 exposure levels (such as -2EV, -1EV, 0EV, +1EV, and +2EV) or 9 exposure levels (such as -2EV, -1.5EV, -1EV, -0.5EV, 0EV, Types such as +0.5 EV, +1 EV, +1.5 EV, and +2 EV), wherein different exposure compensation values are respectively used depending on the adjustable range type of the exposure value, however, the present invention is not limited thereto.

After the step S100, the processing unit of the image capturing device counts the number of pixels of the current image captured at different brightnesses, and defines the sum of the number of pixels whose brightness is less than the first value as the number of pixels in the dark portion, and the brightness is greater than the first The sum of the number of pixels of the two values is defined as the number of bright pixels (step S102), wherein the first value and the second value can be designed by one of ordinary skill in the art.

Then, the processing unit determines and obtains the lowest exposure value according to the number of bright pixels and the first threshold (step S120), and determines and obtains the highest exposure value according to the number of dark portions and the second threshold (step S130). However, in order to enable the processing unit to know whether the currently performed processing procedure is performed for the lowest exposure value or for the highest exposure value, the processing unit determines whether the image capturing device determines before step S120. The required minimum exposure value has been obtained, and if the lowest exposure value has not been obtained, step S120 is performed; otherwise, if the lowest exposure value has been obtained, the flow jumps to step S130, and the step of continuing the determination and obtaining the highest exposure value is performed. .

In step S120, in order to obtain the lowest exposure value, the processing unit further determines whether the number of bright pixels of the current image is greater than the first critical value (step S104), wherein the first critical value can be adjusted according to the designer's needs. If the number of bright pixels of the current image is not greater than the first threshold, the processing unit adds an exposure compensation value to the current exposure value (step S106), that is, the image capturing device is raised by an exposure level, so that the image capturing device is enabled. The current image is captured according to the new current exposure value (step S100), and the steps S100 to S106 are repeated until the processing unit determines that the number of bright pixels of the current image is greater than the first threshold, and the processing unit makes the lowest exposure value the previous one. The exposure value of the image is taken (step S107). In other words, before the image capturing device obtains the lowest exposure value, the processing unit adds the current exposure value to the exposure compensation value, and repeats the above steps (step S100 to step S106) until the lowest exposure value is obtained.

Next, in step S130, in order to obtain the highest exposure value, the processing unit determines whether the number of dark portions of the pixels is smaller than the second critical value according to the current image (step S108), wherein the second critical value is similar to the first critical value, according to the designer. Need to adjust itself. If the number of pixels in the dark portion is not less than the second threshold, the processing unit adds an exposure compensation value to the current exposure value (step S106), and repeats steps S100, S102, S103, S106, and S108 until the processing unit determines the dark portion of the current image. When the number of pixels is less than the second threshold, the processing unit causes the highest exposure value to be the current exposure value (step S109). In other words, before the image capturing device obtains the highest exposure value, the processing unit adds the current exposure value to the exposure compensation value, and repeats the above steps (steps S100, S102, S103, S106, and S108) until the highest exposure value is obtained.

Finally, in step S110, the image capturing device generates a high dynamic range image according to the first image having the lowest exposure value and the second image having the highest exposure value. In this embodiment, the image capturing device may store the first/second image having the lowest/highest exposure value in the image capturing device when the processing unit determines that the current exposure value is the lowest/highest exposure value, and After the first image and the second image are read in the above step S110, the high dynamic range image is generated according to the first image and the second image; or in the above step S110, the minimum exposure value and the highest exposure value are re-based. The first image and the second image are taken, and the high dynamic range image is generated according to the first image and the second image. This part can be designed by the designer according to the general knowledge in the art, and the invention is not limited thereto.

The general image capturing device can use the processing unit to count the number of pixels in various brightnesses in the image in the image captured by the image capturing device, and in the general image capturing device application, the number of pixels in different brightness can be distributed. More clearly, the distribution of the number of pixels of the image at different brightnesses can be expressed as a histogram. The abscissa of the luminance profile represents from left to right the darkest to the brightest, while the ordinate represents the statistical number of pixels.

In addition, the general image capturing device records the captured image by at least 8 bits, so the brightness range that can be covered by the general image capturing device can be divided into 256 levels and brightness in the range from the darkest to the brightest. The horizontal coordinate of the distribution map is represented by 0 to 255, wherein the leftmost side of the abscissa axis is 0, which represents the state of total absorption of the optical signal, that is, the state of all black; and the rightmost side of the abscissa axis is 255, which represents the total reflection of the optical signal. The condition is the state of all white.

The above steps will be explained by way of another example. 2A-2E are schematic diagrams showing a processing method of a high dynamic range image according to the embodiment of FIG. 1. In FIG. 2A to FIG. 2E , an image capturing device with an exposure value adjustable range of -2 EV to +2 EV and an exposure compensation value of +1 EV is taken as an example, and FIGS. 2A to 2E respectively show an exposure value of -2 EV, - Image and brightness distribution of 1EV, 0EV, 1EV, and 2EV.

Referring to FIG. 1 and FIG. 2A to FIG. 2E, in FIG. 2A, the image capturing device first captures a current image according to an initial current exposure value, and the initial current exposure value is the lowest level exposure value, that is - 2EV, and the current image is image 260. After the number of pixels of the current image under different brightness is counted by the processing unit, the brightness distribution map 310 is displayed, wherein the first value C1 and the second value C2 defining the dark portion pixel and the bright portion pixel are respectively shown in the brightness distribution map 310. The following is a convenient description. Therefore, in FIG. 2A to FIG. 2E, the number of bright pixels and the number of dark pixels are relatively quantized according to the luminance profile, and the first threshold and the second threshold are 20, as shown in the following table:

However, the numerical values may be changed by those skilled in the art or may be changed according to actual conditions, and the present invention is not limited thereto. In the luminance distribution map 310, the processing unit counts that the number of bright pixels is 15 and the number of dark pixels is 60, so the processing unit determines that the number of bright pixels is less than the first critical value, so that the image capturing device exposes according to the above processing method. The value -2 EV plus +1 EV gives a new current exposure value of -1 EV, and the current image is retrieved based on the new current exposure value, at which time the current image is image 270.

The processing unit counts that the number of bright pixels of the current image is 25 and the number of pixels of the dark portion is 50. At this time, since the number of bright pixels exceeds the first critical value, the processing unit determines the previous exposure level of the current exposure value, that is, -2 EV, The minimum exposure value required for high dynamic range image synthesis. It can also be seen from FIG. 2A to FIG. 2E that when the exposure value is greater than -2 EV, the brightness of the window portion in the upper right corner of the image is saturated, and the image near the window is distorted.

Then, since the number of dark portions of the current image is still greater than the second threshold, the processing unit adds the exposure value -1 EV to the +1 EV to obtain the current exposure value of 0 EV according to the processing method described above, and re-takes the current exposure value according to the current exposure value. Image, at this time the current image is image 280, the number of bright pixels is 35 and the number of dark pixels is 40.

Since the number of pixels in the dark portion of the image 280 is still greater than the second threshold value, the current image having the higher current exposure value is repeatedly captured according to the above processing method. This process is the same as the above process, and therefore will not be described again. Until the image capturing device is based on the current exposure value of the +2EV and capturing the current image (in this case, the image 300), the processing unit counts the number of dark pixels in the current image as 5. Since the number of dark portions of the current image is less than the second threshold, the processing unit determines that the current exposure value is equal to +2 EV, and the current exposure value is the highest exposure value required for high dynamic range image synthesis. Finally, the processing unit generates a high dynamic range image based on the image 260 having the lowest exposure value and the image 300 having the highest exposure value.

In the above embodiment, the image capturing device captures the current image from the lowest level exposure value, and sequentially raises the exposure level, and the processing method obtains the minimum exposure value required to generate the high dynamic range image and The highest exposure value. However, in more cases, the image capture device first meters the image to be captured, and provides a standard exposure value (0 EV) as the starting current exposure value, and based on the current exposure value for the current The image is taken.

Therefore, the present invention proposes a processing method for another high dynamic range image, which is different from the foregoing embodiment in that, in the above embodiment, the image capturing device uses the lowest grade exposure value (such as -2 EV) as the initial current. The exposure value is gradually added to the exposure compensation value, and is determined by the processing unit to obtain the range of exposure values required to generate the high dynamic range image. In the embodiment, the processing unit determines the current image according to the actual brightness and contrast of the current image. The most suitable exposure value, and the most appropriate exposure value is set as the standard exposure value (such as 0EV), so that the image capture device determines the current exposure value and the lowest exposure value of the current image, the standard exposure value is used as the initial exposure. The value is set and the exposure level is increased or the exposure level is lowered according to the standard exposure value to obtain the range of exposure values required to produce a high dynamic range image.

3 is a flow chart showing the steps of a method for processing a high dynamic range image according to another embodiment of the present invention. Referring to FIG. 3, in step S200, the image capturing device first captures a current image according to a current exposure value, and the processing unit causes the initial current exposure value to be a standard exposure value (step S20), wherein the standard exposure value is based on the initial The actual brightness and contrast of the current image captured is determined.

After the step S200 is completed, the processing unit counts the number of pixels of the current image under different brightness (step S202). This step is the same as step S102 of the previous embodiment, and therefore will not be described again.

Next, the processing unit determines and obtains the lowest exposure value according to the number of bright pixels and the first threshold (step S220), and determines and obtains the highest exposure value according to the number of dark portions and the second threshold (step S230).

In step S220, in order to obtain the lowest exposure value, the processing unit further determines whether the number of bright pixels of the current image is less than the first critical value (step S204), wherein the first critical value can be adjusted according to the designer's needs. If the number of bright pixels of the current image is not less than the first threshold, the processing unit subtracts an exposure compensation value from the current exposure value (step S205), that is, the image capturing device is lowered by one exposure level, so that the image capturing device is enabled. Extracting the current image according to the new current exposure value (step S200), and repeating steps S200 to S205 until the processing unit determines that the number of bright pixels of the current image is greater than the first threshold, the processing unit causes the lowest exposure value to be the current exposure value. (Step S207). In other words, before the image capturing device obtains the lowest exposure value, the processing unit subtracts the exposure compensation value from the current exposure value, and repeats the above steps (step S200 to step S205) until the lowest exposure value is obtained.

In this embodiment, after obtaining the lowest exposure value, the image capturing device resets the setting of the exposure value, and re-sets the current exposure value to the standard exposure value (step S20), and captures the current image again according to the standard exposure value. (Step S200).

Then, the subsequent steps S200, S202, S206, S208, S209, and S210 are respectively the same as steps S100, S102, S106, S108, S109, and S110 of the foregoing embodiment, that is, the present embodiment determines and obtains the highest exposure value. The step (S230) and the step of generating a high dynamic range image (step S210) are the same as those of the foregoing embodiment, and thus are not described herein again.

In addition, the processing method of this embodiment does not limit the priority order of processing the lowest exposure value or the highest exposure value, that is, the processing method of the embodiment may also perform the steps of determining and obtaining the highest exposure value, and then performing the judgment and obtaining the minimum. The steps of the exposure value may be changed before and after the designer's needs, and the present invention is not limited to the manner illustrated in the drawings.

The process steps of this embodiment can also be further illustrated in FIG. 2A to FIG. 2E. Referring to FIG. 3 and FIG. 2A to FIG. 2E , first in step S200 , the image capturing device captures the current image according to the current exposure value. Therefore, the current image initially captured by the image capturing device is the image 280 of FIG. 2C.

Then, the processing unit counts the number of pixels in different brightnesses, and determines whether the number of bright pixels is smaller than the first critical value. Since the number of bright pixels of the current image is 35 is still not less than the first critical value, the processing unit will The current exposure value plus a negative exposure compensation value, that is, an exposure level is lowered, the current exposure value is reduced from 0 EV to -1 EV, and the current image is retrieved based on the new current exposure value.

Repeating the above steps S200, S202, S204 and S206 until the current exposure value is -2EV, the number of bright pixels is smaller than the first critical value, so the processing unit determines that the current exposure value is equal to -2EV, so that the lowest exposure value is the current exposure value.

After obtaining the lowest exposure value, the image capturing device retrieves the current image according to the standard exposure value 0EV, and obtains the highest exposure value and the high dynamic range image corresponding to the lowest exposure value and the highest exposure value according to the foregoing steps. The processing method of the high dynamic range image in this embodiment has a faster processing speed in the case where the contrast of some scenes is low.

In summary, the processing method proposed by the embodiment of the present invention uses the method of setting a high brightness threshold and a low brightness threshold to enable the processing unit of the image capturing device to be based on the set threshold and the bright and dark portions. The number of pixels dynamically determines the range of exposure values required for the high dynamic range image, so that the image capturing device of the present invention can still maintain a certain degree of realism when shooting some high contrast scenes, thereby improving The quality of the image.

Although the present invention has been disclosed in the above embodiments, it is not intended to limit the invention, and any one of ordinary skill in the art can make some modifications and refinements without departing from the spirit and scope of the invention. The scope of the invention is defined by the scope of the appended claims.

S10, S100, S102, S103, S104, S106, S107, S108, S109, S110, S120, S130. . . Step process for obtaining high dynamic range images

S20, S200, S202, S204, S205, S206, S208, S209, S210, S220, S230. . . Step process for obtaining high dynamic range images

260, 270, 280, 290, 300. . . image

310, 320, 330, 340, 350. . . Brightness map

C1. . . First value

C2. . . Second value

FIG. 1 is a flow chart showing the steps of a method for processing a high dynamic range image according to an embodiment of the invention.

2A-2E are schematic diagrams showing a processing method of a high dynamic range image according to the embodiment of FIG. 1.

3 is a flow chart showing the steps of a method for processing a high dynamic range image according to another embodiment of the present invention.

S100, S102, S104, S106, S108, S110. . . Step process for obtaining high dynamic range images

Claims (8)

A method for processing a high dynamic range image, which is suitable for an image capturing device having a processing unit, the processing method comprising: capturing a current image according to a current exposure value; and counting pixels of the current image at different brightness The quantity, the sum of the number of pixels whose brightness is less than a first value is a number of dark pixels, and the sum of the number of pixels whose brightness is greater than a second value is a number of bright pixels; according to the number of pixels of the bright part and a first critical value, judging And obtaining a minimum exposure value; determining and obtaining a highest exposure value according to the number of dark portion pixels and a second threshold value; adding the current exposure value to an exposure compensation value, repeating the above steps until the highest exposure value is obtained and The lowest exposure value; and generating the high dynamic range image based on a first image having the highest exposure value and a second image having the lowest exposure value. The method for processing a high dynamic range image according to claim 1, wherein the step of determining and obtaining the lowest exposure value further comprises: when the number of bright pixels is greater than the first threshold, making the lowest exposure value The exposure value of the image captured for the previous one. The method for processing a high dynamic range image according to claim 1, wherein the step of determining and obtaining the highest exposure value further comprises: when the number of pixels in the dark portion is less than the second threshold, the highest exposure value is obtained. The current exposure value. The method for processing a high dynamic range image as described in claim 1 further comprises: causing the initial current exposure value to be a lowest level exposure value. A method for processing a high dynamic range image, which is suitable for an image capturing device having a processing unit, the processing method comprising: a. capturing a current image according to a current exposure value; b. counting the current image is different The number of pixels in the brightness, the sum of the number of pixels whose brightness is less than a first value is a number of dark pixels, and the sum of the number of pixels whose brightness is greater than a second value is a number of bright pixels; according to the number of pixels of the bright part and a first a threshold value, determining and obtaining a minimum exposure value, and subtracting the current exposure value by an exposure compensation value, repeating steps a and b until the minimum exposure value is obtained; determining according to the number of dark portions of pixels and a second threshold value And obtaining a highest exposure value, and adding the current exposure value to an exposure compensation value, repeating steps a and b until the highest exposure value is obtained; and according to a first image having the highest exposure value and having the lowest exposure A second image of the value produces the high dynamic range image. The method for processing a high dynamic range image according to claim 5, wherein the step of determining and obtaining the lowest exposure value further comprises: when the number of bright pixels is less than the first threshold, making the lowest exposure value For the current exposure value. The method for processing a high dynamic range image according to claim 5, wherein the step of determining and obtaining the highest exposure value further comprises: when the number of pixels in the dark portion is less than the second threshold, the highest exposure value is obtained. The current exposure value. The method for processing a high dynamic range image as described in claim 5, further comprising: causing the initial current exposure value to be a standard exposure value, wherein the standard exposure value is based on an actual captured current image. Brightness and contrast are determined.