JP2012129719A - Image processing device and method of controlling the same - Google Patents

Abstract

PROBLEM TO BE SOLVED: To suppress rapid change in image quality in the case that the reproduction is resumed after the reproduction is suspended, in an image processing device performing the reproduction while developing a RAW motion picture.SOLUTION: An image processing device has: a developing parameter generator generating a developing parameter value for a current frame, based on an intermediate parameter value that is a developing parameter value generated from RAW data on the current frame of a RAW motion picture, and a developing parameter value for a frame prior to the current frame; a developing unit developing RAW data on each frame of the RAW motion picture by using the developing parameter value generated by the developing parameter generator; and a developing parameter storing unit storing the developing parameter value for a frame at the time when the reproduction of the RAW motion picture is stopped. The developing parameter generator generates the developing parameter value for a frame at the time when the reproduction of the RAW motion picture is resumed after the reproduction is stopped, based on the intermediate parameter value for the frame at the time when the reproduction is resumed, and the developing parameter value for the frame at the time when the reproduction is stopped which is stored in the developing parameter storing unit.

Description

  The present invention relates to an image processing apparatus that generates a development parameter and develops a RAW moving image when a RAW moving image is reproduced, and a control method thereof.

The still image RAW image is data in which the output of the image sensor is recorded as it is.
In order to reproduce a RAW image, it is necessary to develop the RAW image. Parameters used for developing a RAW image are called development parameters. The hue, brightness, white balance, and the like of image data obtained by developing a RAW image are determined by the value of the development parameter (development parameter value). The RAW moving image is a moving image in which the output of the image sensor is recorded as it is, as with a RAW image of a still image.

Conventionally, in order to reproduce a RAW moving image, development is performed in the following steps. A development parameter value used for developing a RAW moving image is generated (calculated) in advance. RAW moving images are developed according to the development parameter values to generate moving image data. The user reproduces and views the moving image data generated in this way. Thus, conventionally, in order to reproduce a RAW moving image, it has been necessary to complete development processing (generate moving image data) in advance.
On the other hand, a viewing mode in which playback is performed while developing a RAW moving image while automatically generating development parameter values is also conceivable.

In addition, when a user views a RAW moving image while developing it, it is considered that an operation performed when viewing moving image data in the conventional MPEG (Moving Picture Experts Group) format or the like is also performed when viewing a RAW moving image. It is done.
For example, when viewing moving image data, the user performs an operation of pausing playback halfway, an operation of restarting playback from the stop position, or the like.

In connection with such pause and resumption of reproduction during moving image reproduction, Patent Document 1 discloses a processing method in which the entire execution area of the reproduction control program is saved in order to resume reproduction from the stop position. .
Further, Patent Document 2 discloses a processing method of recording only changed playback condition information among a plurality of playback condition information of a DVD in order to reduce information to be stored in order to resume playback from the stop position. Yes.
In conventional moving image reproduction, if the position at which reproduction is started is known, reproduction can be resumed from there.

In the reproduction of the RAW moving image, it is conceivable to use the development parameter value used for the development of the RAW data of the past frame image in order to generate the development parameter value corresponding to the RAW data of the frame image at a certain time.
FIG. 7 schematically shows, in time series, processing until generation of a development parameter value, development, and screen display of a development result when a RAW moving image is reproduced while being developed. In general, there are a plurality of types of development parameters. Here, for the sake of simplicity, white balance will be described as an example of development parameters.
A period from time t1 to time t5 in FIG. 7 is a period in which the development parameter value is generated and the RAW moving image is reproduced while developing the RAW data.

The development of the frame A ′ of the RAW moving image at time t1 will be described. In order to develop RAW data, development parameter values (white balance value, color temperature value) are required. The development parameter value corresponding to the RAW data of frame A ′ is calculated from the RAW data of frame A ′. In the example of FIG. 7, the development parameter value (color temperature value) corresponding to the RAW data of frame A ′ is calculated as 4000K. This development parameter value is a development parameter value calculated from RAW data for one frame (frame A ′) of the RAW moving image. Hereinafter, the development parameter value calculated from the RAW data for one frame of the RAW moving image is referred to as “intermediate parameter value”.

For the frame A ′ of the RAW moving image at time t1, the intermediate parameter value is used as it is as the development parameter value used for developing the RAW data of that frame. Accordingly, the development parameter value used for developing the RAW data of the frame A ′ is set to 4000K.
Development of the frame B ′ of the RAW moving image at time t2 will be described. First, as in the case of the frame A ′ described above, an intermediate parameter value is generated from RAW data for one frame (frame B ′) of the RAW moving image. In the example of FIG. 7, the intermediate parameter value calculated for the frame B ′ of the RAW moving image is 6000K.

  Here, as in the case of the development of the frame A ′, if the intermediate parameter value 6000K is used as it is as the development parameter value used for the development of the RAW data of the frame B ′, the color temperature values of the frame A ′ and the frame B ′ are the same. It will be very different. Therefore, the color temperature changes abruptly at the transition from the image data A obtained by developing the RAW moving image frame A ′ to the image data B obtained by developing the RAW moving image frame B ′. May feel uncomfortable.

Therefore, the development parameter value used for developing the RAW data of the current frame using the development parameter value used for developing the RAW data of the past frame and the intermediate parameter value calculated for the RAW data of the current frame. Can be calculated. For example, the development parameter value WB2 of the current frame is calculated by the following equation, using the intermediate parameter value WB2 ′ of the current frame (current frame) and the development parameter value WB1 of the frame one frame past (previous frame) from the current frame. Can do.

WB2 = (WB2′−WB1) / 4 + WB1

  For example, the development parameter value of frame B ′ at time t2 is 4500K by substituting the development parameter value 4000K of frame A ′ at time t1 and the intermediate parameter value 6000K of frame B ′ at time t2 into the above equation. Calculated. According to this, the RAW data of the frame B 'of the RAW moving image at time t2 is developed with a white balance value (color temperature value) of 4500K. Accordingly, the color temperature is rapidly changed at the transition from the image data A obtained by developing the RAW data of the frame A ′ developed at the color temperature value of 4000 K to the image data B obtained by developing the RAW data of the frame B ′. Change is suppressed.

  As described above, the development parameter value of each frame of the RAW moving image is generated (calculated) using the development parameter value of the frame earlier than that frame, so that when the RAW moving image is reproduced while being developed, the image quality is rapidly increased. Changes (changes in color temperature in the above example) can be suppressed.

JP 2009-232123 A JP 2007-164860 A

  As described above, the intermediate parameter value of a RAW moving image frame at a certain time is calculated from the RAW data of that frame. On the other hand, in order to calculate the final development parameter value of a RAW moving image frame at a certain time, the development parameter value of a frame in the past from that time is required.

  In the example of FIG. 7, 4695K is calculated as the development parameter value of the frame E ′ of the RAW moving image at time t5, but the reproduction of the RAW moving image is temporarily stopped at time t5. The information of the development parameter value (4695K) of the frame E ′ is lost when the reproduction is resumed. For this reason, when the playback of the RAW moving image is resumed at time t10, the development parameter value of the frame earlier than the frame F ′ cannot be used when calculating the development parameter value of the frame F ′ of the RAW moving image at time t10. . Accordingly, the development parameter value of the frame F ′ is an intermediate parameter value calculated only from the RAW data of the frame F ′, as in the case of the frame A ′. In this case, since there is no correlation as defined by the above equation between the development parameters of consecutive frames E ′ and F ′ of the RAW moving image, the color between the image data E and the image data F obtained by the development processing The temperature could change suddenly.

  The present invention provides a technique capable of suppressing an abrupt change in image quality before and after resuming playback when the playback is resumed after the playback is paused in an image processing apparatus that plays back while developing a RAW moving image. For the purpose.

The present invention is an image processing apparatus that reproduces while developing a RAW moving image by performing development of RAW data of each frame of the RAW moving image and outputting image data of each frame obtained by the development in parallel.
Based on the intermediate parameter value, which is a development parameter value generated from the RAW data of the current frame of the RAW moving image, and the development parameter value used for developing the RAW data of the previous frame from the current frame of the RAW moving image. A development parameter generation unit for generating a development parameter value used for developing the RAW data of the current frame of the moving image;
A developing unit that develops RAW data of each frame of the RAW moving image using the development parameter value generated by the development parameter generation unit;
A development parameter storage unit that stores development parameter values used to develop the RAW data of the frame when playback of the RAW video is stopped;
Have
The development parameter generation unit generates a development parameter value used for developing the RAW data of the frame when the reproduction is resumed after the reproduction of the RAW moving image is stopped, and an intermediate parameter generated from the RAW data of the frame when the reproduction is resumed. The image processing apparatus is generated based on the value and the development parameter value used for developing the RAW data of the frame when the reproduction stored in the development parameter storage unit is stopped.

The present invention provides a control method for an image processing apparatus that reproduces a RAW moving image while developing it by developing the RAW data of each frame of the RAW moving image and outputting the image data of each frame obtained by the development in parallel. ,
Based on the intermediate parameter value, which is a development parameter value generated from the RAW data of the current frame of the RAW moving image, and the development parameter value used for developing the RAW data of the previous frame from the current frame of the RAW moving image. A development parameter generation step for generating a development parameter value used for developing the RAW data of the current frame of the moving image;
A development step of developing RAW data of each frame of the RAW moving image using the development parameter value generated in the development parameter generation step;
A development parameter storage step for storing a development parameter value used for developing the raw data of the frame when the reproduction of the raw video is stopped;
Have
In the development parameter generation step, the development parameter value used for developing the RAW data of the frame when the reproduction is resumed after the reproduction of the RAW moving image is stopped, and the intermediate parameter generated from the RAW data of the frame when the reproduction is resumed. And a development parameter value used for developing the RAW data of the frame when the reproduction stored in the development parameter storage unit is stopped.

  According to the present invention, in an image processing apparatus that reproduces while developing a RAW moving image, when resuming reproduction after pausing reproduction, a technique capable of suppressing a rapid change in image quality before and after resuming reproduction. Can be provided.

1 is a block diagram illustrating a schematic configuration of an image processing apparatus according to a first embodiment. The figure which described the process which concerns on reproduction | regeneration of the RAW moving image which concerns on Example 1 in time series. Flowchart of processing related to reproduction of RAW moving image according to Embodiment 1 FIG. 7 is a block diagram illustrating a schematic configuration of an image processing apparatus according to a second embodiment. The figure which described the process which concerns on reproduction | regeneration of the RAW moving image which concerns on Example 2 in time series. Flowchart of processing relating to reproduction of RAW moving image according to Embodiment 2 The figure which described the process which concerns on reproduction | regeneration of the RAW moving image concerning the background art of this invention in time series

Example 1
An example for carrying out the present invention will be described below.
FIG. 1 is a configuration diagram of an image processing apparatus 10 according to the present embodiment. The image processing apparatus 10 reproduces (displays) a RAW moving image while developing it by developing the RAW data of each frame of the RAW moving image and outputting the image data of each frame obtained by the development in parallel. It is.
Here, the role of each block constituting the image processing apparatus 10 according to the present embodiment will be described. The recording medium 100 is a medium for recording RAW moving image data, and is detachable from the image processing apparatus 10. The recording medium 100 is, for example, a memory card taken out from a digital camera or a digital video camera, a hard disk on which RAW moving image data is recorded, a DVD (Digital Versatile Disc), a BD (Blu-ray Disc), or the like. That is, the image processing apparatus 10 has a data reading function unit that can attach and detach such a recording medium 100 and can read RAW moving image data recorded on the recording medium 100 and send it to each function unit described later. (Not shown).

The development parameter generation unit 101 generates a development parameter value used for developing a RAW moving image.
The development unit 102 develops the RAW moving image using the development parameter value output from the development parameter generation unit 101.
The development parameter storage unit 103 stores the development parameter value when the reproduction of the RAW moving image is paused.
The display unit 104 displays image data as a result of development by the development unit 102. Note that the display unit 104 is not essential as an embodiment of the image processing apparatus of the present invention. The image data obtained by the developing unit 102 may be output to an image display device connected as an external device.
The operation unit 105 is a unit that performs an operation for the user to input an instruction to the image processing apparatus 10.

The control unit 106 outputs a control signal in accordance with a user operation received by the operation unit 105, and controls the operation of each block constituting the image processing apparatus 10.
The system bus 110 transmits a control signal output from the control unit 106 to each block constituting the image processing apparatus 10.

FIG. 2 is a diagram schematically showing, in time series, processing for reproducing a RAW moving image while developing it in the image processing apparatus 10 of the present embodiment. Here, white balance will be described as an example of the development parameter. That is, here, the development parameter value is a color temperature value.
In this embodiment, the development parameter value calculated from the RAW data for one frame of the RAW moving image is referred to as “intermediate parameter value”. In the image processing apparatus of the present embodiment, the development parameter value of the RAW data of the current frame (current frame) is set to the development parameter value of the frame one frame before the current frame and the intermediate parameter calculated for the RAW data of the current frame. And a value.

The development parameter value WB2 for the current frame is calculated by the following equation 1 based on the development parameter value WB1 for the previous frame and the intermediate parameter value WB2 ′ calculated from the RAW data for the current frame.

WB2 = (WB1-WB2 ′) / 4 + WB1 (Formula 1)

  The development parameter generation unit 101 calculates an intermediate parameter value (color temperature value) of the frame A ′ based on the RAW data of the frame A ′ of the RAW moving image at time t1. The color temperature value is calculated from an average value of color data in RAW data, for example. In the example of FIG. 2, the intermediate parameter value of the frame A ′ of the RAW moving image is 4000K. Since the frame A 'at the time t1 is the first frame of the RAW moving image and there is no past frame (previous frame), the intermediate parameter value (4000K) of the frame A' is directly used as the development parameter value of the frame A '.

  The developing unit 102 uses the development parameter value 4000K of the frame A ′ generated by the development parameter generation unit 101 to develop the RAW data of the frame A ′ with white balance corresponding to the color temperature 4000K. That is, the image data A as a result of development of the frame A ′ that is finally displayed on the display unit 104 is image data with a color temperature of 4000K as a white reference.

Next, the development parameter generation unit 101 calculates an intermediate parameter value of the frame B ′ from the RAW data of the frame B ′ of the RAW moving image at time t2. In the example of FIG. 2, the intermediate parameter value of the frame B ′ is 6000K.
The development parameter generation unit 101 uses the intermediate parameter value 6000K of the frame B ′ of the RAW video at time t2 and the development parameter value 4000K of the frame A ′ of the RAW video at time t1 to develop the frame B ′ of the RAW video. A development parameter value is calculated.
When calculated using Expression 1, the development parameter value of the frame B ′ of the RAW moving image is 4500K. The development unit 102 develops the RAW moving image frame B ′ using the development parameter value 4500K, and outputs the obtained image data B to the display unit 104. The frame image data B displayed on the display unit 104 is image data with a color temperature of 4500K as a white reference.

Assume that at time t5, the user performs an operation to input to the image processing apparatus 10 an instruction to pause playback of the RAW moving image. The development parameter generation unit 101 calculates the development parameter value of the frame E ′ at the time t5 to 4695K from the intermediate parameter value 5000K of the frame E ′ at the time t5 and the development parameter value 4594K of the frame D ′ at the time t4 according to Equation 1. And calculate. The developing unit 102 develops the RAW data of the frame E ′ with the calculated development parameter value 4594K, and the obtained frame image data E is displayed on the display unit 104. The frame image data E is continuously displayed on the display unit 104 until an instruction to resume playback is input due to the input of an instruction to pause playback of the RAW moving image. The display unit 104 reads frame image data E from a built-in frame memory (not shown) and performs continuous display.

  At this time, in the image processing apparatus 10 of the present embodiment, the development parameter generation unit 101 sends the calculated development parameter value of the frame E ′ to the development parameter storage unit 103. The development parameter storage unit 103 stores the received development parameter value of the frame E ′ until a reproduction restart instruction is input.

  Assume that at time t10, the user performs an operation to input an instruction to resume playback of the RAW moving image to the image processing apparatus 10. The development parameter generation unit 101 calculates (6000K) an intermediate parameter value of the frame F ′ of the RAW moving image at time t10. The development parameter generation unit 101 uses the equation 1 to develop the frame F ′ from the calculated intermediate parameter value of the frame F ′ and the development parameter value (4695K) of the frame E ′ read from the development parameter storage unit 103. The parameter value is calculated (5021K).

  Using the development parameter value of the frame F ′ thus calculated, the developing unit 102 develops the frame F ′ of the RAW moving image, and sends the frame image data F obtained by the development to the display unit 104. On the display unit 104, the display transitions from the frame image data E that has been continuously displayed during the suspension period to the frame image data F obtained by the development. At this time, since the development parameter value of the frame F ′ is a value calculated by the expression 1 using the development parameter value of the frame E ′, the image quality (color temperature) is changed in the transition from the frame image data E to the frame image data F. ) Is suppressed from changing rapidly.

FIG. 3 is a flowchart of processing relating to reproduction of a RAW moving image in the present embodiment.
In step S <b> 101, when an instruction to pause the playback of the RAW moving image is input to the control unit 106 by the operation of the operation unit 105 by the user, the control unit 106 transmits RAW to each block of the image processing apparatus 10 via the system bus 110. Give instructions to pause video playback. In the example of FIG. 2, the process of step S101 is executed at time t5.

  In step S102, the development parameter storage unit 103 acquires the development parameter of the RAW moving image frame at the time when the reproduction pause instruction is input from the development parameter generation unit 101 and stores the development parameter. In the example of FIG. 2, the development parameter storage unit 103 uses the development parameter value (4695K) calculated by the development parameter generation unit 101 to be used for developing the RAW data of the frame E ′ at time t5 when the pause instruction is input. Save. At the same time, the display unit 104 continues to display the frame image data (frame image data E in the example of FIG. 2) stored in the frame memory built in the display unit 104 during the period when the reproduction is stopped. The display unit 104 displays the frame image data in the frame memory for a period until the development of frame image data (frame image data F in the example of FIG. 2) of the RAW data of a new frame is input by the user's instruction to resume playback. Continue to be displayed.

In step S <b> 103, the control unit 106 determines whether or not an instruction to resume playback of the RAW moving image is input to the control unit 106 by the operation of the operation unit 105 by the user. When it is determined that an instruction to resume playback has been input (positive determination), the control unit 106 issues an instruction for restarting playback of the RAW moving image to each block of the image processing apparatus 10 via the system bus 110. In the example of FIG. 2, an affirmative determination is made in step S103 at time t10, and subsequent steps S10.
The processing from 4 to S107 is executed.
In step S104, the development parameter generation unit 101 reads the development parameter value stored in step S102 from the development parameter storage unit 103. In the example of FIG. 2, the development parameter generation unit 101 reads the development parameter value 4695K of the frame E ′ of the RAW moving image at time t5 from the development parameter storage unit 103.

In step S105, the development parameter generation unit 101 calculates an intermediate parameter value from the RAW data of the RAW moving image frame at the time of resuming the reproduction. Then, the development parameter generation unit 101 determines the development parameter of the frame at the time of resuming the reproduction from the intermediate parameter of the frame at the time of the resumption of reproduction and the development parameter of the RAW moving image frame at the time of the pause read from the development parameter storage unit 103. Generate. In the example of FIG. 2, the intermediate parameter value of the frame F ′ of the RAW moving image at the time of resuming reproduction (time t10) is 6000K, and the frame E of the RAW moving image at the time of pause (time t5) read from the development parameter storage unit 103. The development parameter value of 'is 4695K. Therefore, according to Equation 1, the development parameter value of the frame F ′ at the time of resuming reproduction is 5021K.
In step S106, the developing unit 102 uses the development parameter value generated by the development parameter generating unit 101 in step S105 to develop a RAW moving image frame when resuming reproduction. In the example of FIG. 2, the developing unit 102 develops the frame F ′ of the RAW moving image using the development parameter value 5021K generated by the development parameter generating unit 101.

In step S107, the display unit 104 displays the frame image data obtained by development in step S106. In the example of FIG. 2, the frame image data F displayed on the display unit 104 is image data with the color temperature 5021K as a white reference.
According to the image processing apparatus of this embodiment, even when a RAW moving image is played back while being developed and playback is paused, the development parameter value of the frame at the time of resuming playback uses the development parameter value of the frame at the time of pause. Therefore, it is possible to suppress the change in image quality when replaying is resumed.

(Example 2)
Next, a second embodiment of the present invention will be described. Components having functions equivalent to those of the first embodiment are denoted by the same reference numerals as those of the first embodiment, and detailed description thereof is omitted.
In the first embodiment, paying attention only to white balance as a development parameter, during a pause of RAW video playback, a white balance value (color temperature value) of a RAW video frame at the time of pause is stored in the development parameter storage unit. An example of saving was described.
In the present embodiment, an example will be described in which when there are a plurality of types of development parameters, the development parameters that need to be stored during the temporary suspension period are determined, and only the development parameter values are stored.

FIG. 4 is a configuration diagram of the image processing apparatus 20 of the present embodiment. Here, the role of each block constituting the image processing apparatus 20 of the present embodiment will be described.
The recording medium 100, the operation unit 105, the control unit 106, and the system bus 110 illustrated in FIG. 4 have the same functions as those in the first embodiment. Details of operations of the development parameter generation unit 201, the development unit 202, the development parameter storage unit 203, and the display unit 204 will be described later.
The storage parameter determination unit 200 determines the development parameter elements, and outputs a determination result as to whether or not to save to the development parameter storage unit 203.

FIG. 5 is a diagram schematically showing, in time series, processing for reproducing a RAW moving image while developing it in the image processing apparatus 20 of the present embodiment.
Hereinafter, a RAW moving image reproduction process performed by the image processing apparatus 20 according to the present exemplary embodiment will be described with reference to FIGS. 4 and 5. In this embodiment, white balance, contrast, and saturation will be described as examples of a plurality of development parameters. In the following description, white balance may be referred to as development (intermediate) parameter 0, contrast may be referred to as development (intermediate) parameter 1, and saturation may be referred to as development (intermediate) parameter 2. The types of development parameters are not limited to those exemplified.

<Development parameter: White balance>
The white balance value generation (calculation) method is as described in the first embodiment.
As for the frame A ′ of the RAW moving image at time t1 in FIG. 5, there is no past frame, so the development parameter generation unit 201 obtains the value of the intermediate parameter 0 from the data of the frame A ′ as in the first embodiment. The calculated value is used as the value of development parameter 0 as it is.
For the frame B ′ of the RAW moving image at time t2 in FIG. 5, the development parameter generation unit 201 calculates the value of the intermediate parameter 0 from the RAW data of the frame B ′. Further, the value of the development parameter 0 of the frame B ′ is calculated from the value of the development parameter 0 of the frame A ′ and the value of the intermediate parameter 0 of the frame B ′. Here, as in the first embodiment, the value of the development parameter 0 of the current frame is calculated from the value of the development parameter 0 of the previous frame and the value of the intermediate parameter 0 of the current frame by Equation 1. In the example of FIG. 5, the value of the development parameter 0 of the frame B ′ of the RAW moving image at time t2 is 4500K. Therefore, the frame image data B obtained by developing the frame B ′ of the RAW moving image is image data with the color temperature 4500K as a white reference.

<Development parameter: Contrast>
The intermediate parameter 1 and the development parameter 1 are development parameters that determine the contrast of the development result, and the value of the development parameter 1 corresponds to the contrast ratio of the image data of the development result. In this embodiment, it is assumed that the development parameter 1 takes a value of 0 to 1000.
For the frame A ′ of the RAW moving image at time t 1 in FIG. 5, the development parameter generation unit 201 obtains a gradation histogram from the RAW data of the frame A ′, and the distribution of the gradation histogram is widely distributed from the minimum value to the maximum value. The contrast ratio is calculated as follows. The calculated contrast ratio is set as the value of the intermediate parameter 1 of the frame A ′, and since there is no previous frame, the value of the intermediate parameter 1 is used as it is as the value of the development parameter 1 of the frame A ′.

  For the frame B ′ of the RAW moving image at time t2 in FIG. 5, the development parameter generation unit 201 obtains a gradation histogram from the RAW data of the frame B ′, and the distribution of the gradation histogram is widely distributed from the minimum value to the maximum value. The contrast ratio is calculated as follows. The development parameter generation unit 201 sets the calculated contrast ratio as the value of the intermediate parameter 1 of the frame B ′. Similar to the calculation of the white balance value described above, the development parameter generation unit 201 uses the equation 1 to calculate the frame B from the value of the development parameter 1 of the frame A ′ and the value of the intermediate parameter 1 of the frame B ′. The value of development parameter 1 of 'is generated. In the example of FIG. 5, since the value of the intermediate parameter 1 of the frame B ′ of the RAW moving image is 500 and the value of the development parameter 1 of the past frame A ′ is 1000, the development parameter 1 of the current frame B ′. The value is 875.

<Development parameter: Saturation>
The intermediate parameter 2 and the development parameter 2 are development parameters that determine the saturation of the development result, and the value of the development parameter 2 corresponds to the saturation of the development result.
The development parameter generation unit 201 obtains an average luminance value and an average color difference value from the input RAW moving image data of one frame, and determines an amplification gain G of the development unit for the color difference value.
When the average color difference data ARB and ARG (each value 0 to 100) of one frame of RAW moving image data have a specific combination, the gain G is 1.4 times. Here, that the values of ARB and ARG have a specific combination means that the values of ARB and ARG satisfy the relationship represented by Equation 2 below.
21 ≦ ARB ≦ 30, 21 ≦ ARG ≦ 30 (Formula 2)

  When the average color difference data satisfies this condition, it can be determined that the screen constituting the RAW moving image data includes many elements that are easy to remember vivid impressions as memory colors, such as sky and plants. In such a case, by multiplying the gain G by 1.4, such an element is expressed with emphasis.

For the frame A ′ of the RAW moving image at time t 1 in FIG. 5, the development parameter generation unit 201 calculates the average color difference data ARB and ARG from the RAW data of the frame A ′ and calculates the gain G. Here, the values of the average color difference data ARB and ARG obtained from the RAW data of the frame A ′ do not satisfy the condition of Equation 2, and the gain G is 50.
The development parameter generation unit 201 sets the calculated gain G value 50 as the value of the intermediate parameter 2 of the frame A ′. Since there is no past frame in the frame A ′ of the RAW moving image, the value 50 of the intermediate parameter 2 is used as the value of the development parameter 2 of the frame A ′ as it is.

  With respect to the frame B ′ of the RAW moving image at time t <b> 2 in FIG. 5, the development parameter generation unit 201 calculates the average color difference data ARB and ARG from the RAW data of the frame B ′ and calculates the gain G. Here, since the values of the average color difference data ARB and ARG obtained from the RAW data of the frame B ′ satisfy Expression 2, the gain G is multiplied by 1.4 to be 70. The development parameter generation unit 201 sets the calculated gain G value 70 as the value of the intermediate parameter 2 of the frame B ′. The development parameter generation unit 201 uses the equation 1 from the value of the development parameter 2 of the frame A ′ and the value of the intermediate parameter 2 of the frame B ′, as in the case of the white balance and contrast described above. The value of development parameter 2 of 'is calculated. In the example of FIG. 5, since the value of the intermediate parameter 2 of the frame B ′ of the RAW moving image is 70 and the value of the development parameter 2 of the past frame A ′ is 50, the development parameter 2 of the current frame B ′. The value is 55. Thus, since the value of the development parameter 2 of the current frame is calculated using the value of the development parameter 2 of the previous frame, a sudden change in saturation in the image data of the development result is suppressed.

<Development>
The developing unit 202 in FIG. 4 develops each frame of the RAW moving image using the values of the development parameter 0, the development parameter 1, and the development parameter 2 generated by the development parameter generation unit 201 as described above.
The display unit 204 displays image data obtained by development by the development unit 202.

<Determination of development parameters>
FIG. 6 is a flowchart of a process related to reproduction of a RAW moving image according to the second embodiment.
Here, with reference to FIGS. 4 to 6, a processing flow relating to storage of a plurality of development parameters in the reproduction, pause, and resumption of the RAW moving image in the present embodiment will be described.
The processing contents of step S101, step S103, step S104, step S106, and step S107 in FIG. 6 are the same as the processing contents described in FIG.

In step S202, the storage parameter determination unit 200 determines that the development parameter 0, the development parameter 1, and the development parameter 2 generated by the development parameter generation unit 201 should store the values during the pause of RAW video playback. It is determined whether or not. In the example of FIG. 5, the process of step S202 is executed at time t5 when the user performs an operation to input an instruction to pause the playback of the RAW moving image.
The storage parameter determination unit 200 determines that the values of white balance and contrast are development parameters that should be stored during RAW video playback pause. This is because a sudden change in white balance and contrast is easily noticed by the viewer. In the example of FIG. 5, the storage parameter determination unit 200 determines that the development parameter 0 value 4695K and the development parameter 1 value 868 of the frame E ′ of the RAW moving image at time t5 are stored during the RAW moving image playback pause. .

On the other hand, it may be difficult for viewers to notice changes in saturation. For example, if the development result is black or white image data, even if the development parameter value for determining the saturation changes largely before and after the resumption of reproduction, the viewer does not feel uncomfortable.
In the present embodiment, the storage parameter determination unit 200 develops when the average color difference data (color difference values) ARB and ARG obtained from one frame of RAW moving image data takes values within a predetermined range (values of 45 to 65). It is determined that the value of parameter 2 is not saved.

In the example of FIG. 5, it is assumed that the average color difference data ARB and ARG obtained from the RAW data of the frame E ′ at time t5 take values of 45 to 65. At this time, the storage parameter determination unit 200 calculates the value 61 of the development parameter 2 of the frame E ′ obtained from Expression 1 from the value 80 of the intermediate parameter 2 of the frame E ′ and the value 55 of the development parameter 2 of the frame D ′. It is determined that the video is not saved while the video is paused. When at least one of the average color difference data ARB or ARG of the RAW moving image frame when the instruction to pause playback is input does not take a value of 45 to 46, the storage parameter determination unit 200 sets the development parameter 2 of the frame. It is determined that the value is saved.
Then, the storage parameter determination unit 200 outputs the development parameter value determined to be stored to the development parameter storage unit 203.

In step S203, the development parameter storage unit 203 stores the parameters determined to be stored by the storage parameter determination unit 200.
In step S204, it is determined whether or not the storage parameter determination unit 200 determines whether or not there is an unprocessed development parameter. If there is an unprocessed development parameter, the processing in steps S202 and S203 is performed. Repeated.
In the example of FIG. 5, the parameter storage unit 203 stores only the development parameter 0 value 4695K and the development parameter 1 value 868 for the frame E ′ at time t5 when the instruction to pause playback of the RAW moving image is input. The value 61 of the development parameter 2 is not saved.

<Resume>
The processing contents of steps S103 and S104 in FIG. 6 are the same as the steps with the same numbers in FIG. In the example of FIG. 5, the process of step S104 in FIG. 6 is executed at time t10 when an instruction to resume playback of the RAW moving image is input.
In step S207, the development parameter generation unit 201 generates an intermediate parameter value from the RAW moving image data for one frame at the time when the instruction to resume reproduction of the RAW moving image is input. In the example of FIG. 5, the development parameter generation unit 201 determines the value of the intermediate parameter 0 (6000K), the value of the intermediate parameter 1 (1200), and the intermediate parameter 2 from the RAW data of the frame F ′ of the RAW moving image at time t10. A value (50) is generated.

Further, the development parameter generation unit 201 reads the development parameter value of the past frame for the development parameter for which the development parameter value of the past frame is stored in the development parameter storage unit 203. Then, the development parameter value of the current frame is calculated using Equation 1 from the read development parameter value of the past frame and the generated intermediate parameter value of the current frame. In the example of FIG. 5, the development parameter 0 value (4695K) and the development parameter 1 value (868) of the frame E ′ one frame past the frame F ′ of the RAW moving image at the time of resuming the reproduction are stored in the development parameter storage unit 203. Has been. Accordingly, the development parameter generation unit 201 reads the development parameter 0 value 4695K and the development parameter 1 value 868 of the frame E ′ from the development parameter storage unit 203. Then, the development parameter generation unit 201 uses the expression 1 to develop the development of the frame F ′ from the value 4695K of the development parameter 0 of the read frame E ′ and the value 6000K of the intermediate parameter 0 of the generated frame F ′. The value of parameter 0 is calculated (5021K). Further, the development parameter generation unit 201 uses the expression 1 to develop the frame F ′ from the read development parameter 1 value 868 of the frame E ′ and the generated intermediate parameter 1 value 1200 of the frame F ′. The value of parameter 1 is calculated (951).

  On the other hand, for the development parameters for which the development parameter values of the past frame are not stored in the development parameter storage unit 203, the development parameter generation unit 201 uses the generated intermediate parameter value of the current frame as it is as the development parameter value of the current frame. To do. In the example of FIG. 5, the value of the development parameter 2 of the frame E ′ that is one frame before the frame F ′ of the RAW moving image at the time of resuming reproduction is not stored in the development parameter storage unit 203. Therefore, for the development parameter 2, the development parameter generation unit 201 sets the value 50 of the intermediate parameter 2 of the frame F ′ at time t10 as the value 50 of the development parameter 2.

  Here, the development parameter 2 is a parameter for determining the saturation as described above. Therefore, even if a value having no correlation with the value of the development parameter 2 used for development of the frame E ′ at the time of suspension (time t5) is used in the development of the frame F ′ at the time of resuming reproduction (time t10), the developed image It is considered that viewers do not feel uncomfortable when viewing data.

According to the image processing apparatus of this embodiment, it is possible to reduce the data amount of development parameter values stored in the development parameter storage unit 203.
Thereafter, development and reproduction of the RAW moving image are performed in the same manner as at time t2 in FIG.

<Determination of scene break>
The development parameter generation unit 201 can detect the scene segmentation of the RAW moving image by adding a scene segmentation flag to the data for one frame of the RAW video. In this case, the development parameter generation unit 201 transmits the detection result to the storage parameter determination unit 200, and if it is a scene break, it can be determined that the development parameter is not stored.

DESCRIPTION OF SYMBOLS 10 Image processing apparatus, 101 Development parameter generation part, 102 Development part, 103 Development parameter storage part

Claims (5)

An image processing apparatus that reproduces a RAW moving image while developing it by developing RAW data of each frame of the RAW moving image and outputting image data of each frame obtained by the development in parallel.
Based on the intermediate parameter value, which is a development parameter value generated from the RAW data of the current frame of the RAW moving image, and the development parameter value used for developing the RAW data of the previous frame from the current frame of the RAW moving image. A development parameter generation unit for generating a development parameter value used for developing the RAW data of the current frame of the moving image;
A developing unit that develops RAW data of each frame of the RAW moving image using the development parameter value generated by the development parameter generation unit;
A development parameter storage unit that stores development parameter values used to develop the RAW data of the frame when playback of the RAW video is stopped;
Have
The development parameter generation unit generates a development parameter value used for developing the RAW data of the frame when the reproduction is resumed after the reproduction of the RAW moving image is stopped, and an intermediate parameter generated from the RAW data of the frame when the reproduction is resumed. An image processing apparatus that generates the image based on the value and the development parameter value used for developing the RAW data of the frame when the reproduction stored in the development parameter storage unit is stopped. A storage parameter determination unit that determines a development parameter that does not store a value used for developing the raw data of the frame when the reproduction of the raw video is stopped;
The development parameter storage unit does not store the development parameter value determined not to be stored by the storage parameter determination unit among the development parameter values used for developing the RAW data of the frame when the reproduction of the RAW moving image is stopped. The image processing apparatus according to claim 1.   The storage parameter determination unit determines not to store the development parameter for determining the saturation when the color difference value calculated from the RAW data of the frame when the reproduction of the RAW moving image is stopped is a value within a predetermined range. The image processing apparatus according to claim 2.   The image processing apparatus according to claim 2, wherein the storage parameter determination unit determines not to store all the development parameters when the frame when the playback of the RAW video is stopped is a scene break. A method for controlling an image processing apparatus that reproduces while developing a RAW moving image by performing development of RAW data of each frame of the RAW moving image and outputting image data of each frame obtained by the development in parallel.
Based on the intermediate parameter value, which is a development parameter value generated from the RAW data of the current frame of the RAW moving image, and the development parameter value used for developing the RAW data of the previous frame from the current frame of the RAW moving image. A development parameter generation step for generating a development parameter value used for developing the RAW data of the current frame of the moving image;
A development step of developing RAW data of each frame of the RAW moving image using the development parameter value generated in the development parameter generation step;
A development parameter storage step for storing a development parameter value used for developing the raw data of the frame when the reproduction of the raw video is stopped;
Have
In the development parameter generation step, the development parameter value used for developing the RAW data of the frame when the reproduction is resumed after the reproduction of the RAW moving image is stopped, and the intermediate parameter generated from the RAW data of the frame when the reproduction is resumed. And a development parameter value used for developing the RAW data of the frame when the reproduction saved in the development parameter saving step is stopped.

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