JP5111008B2 - Imaging apparatus and control method thereof - Google Patents

Description

  The present invention relates to an imaging apparatus and a control method thereof.

  In recent years, an imaging apparatus such as a digital camera generally has a continuous shooting function for continuously capturing images.

  In order to increase the number of images that can be continuously shot, it is necessary to increase the capacity of a buffer memory for storing captured images. However, mounting a large-capacity buffer memory leads to an increase in the cost of the imaging device. For this reason, Patent Document 1 discloses a mode in which priority is given to the number of storable images over image quality, and the number of storable images can be increased without changing the capacity of the buffer memory by thinning out the number of pixels. Has been.

Japanese Patent No. 2801002

  As in Japanese Patent Application Laid-Open No. 2004-133620, the simple separation of whether the image quality or the number of images is inevitable for the user because the image quality is inevitably deteriorated when the number of images is prioritized. In addition, when priority is given to image quality, the amount of buffer memory used per captured image increases, but no further improvement in image quality is attempted using the increased amount of memory used.

  The present invention aims to solve such problems of the prior art, and specifically, in the case where either a continuous shooting speed or image quality is required by effectively utilizing a limited buffer capacity. In this case, an imaging device that is convenient for the user and a control method thereof are provided.

The above-mentioned object is to provide an imaging device that converts an optical image of a subject into an electrical signal in units of pixels, a quantization unit that quantizes and outputs an electrical signal in units of pixels with a set number of quantization bits, and a quantization unit. Image generating means for generating recording image data from output data, an image buffer allocated to the storage device for storing the recording image data, and the recording image data is read from the image buffer, according to the set mode. Compression encoding means for performing the compression encoding processing, storage means for storing the setting relating to the compression rate in the compression encoding processing , and depending on the setting, the number of quantization bits of the quantization means and the image buffer of the storage device and control means for controlling the allocation, the control means, with reference to the settings for compressibility any speed and image quality to determine the priority, image quality priority If it is determined that the processing speed is prioritized, the number of image buffers to be allocated to the storage device is reduced and the capacity per image buffer is increased, and the quantizing means This is achieved by an imaging device characterized by increasing the number of digitized bits.

In addition, the above-described object is to provide an image sensor that converts an optical image of a subject into an electrical signal in units of pixels, a quantization unit that quantizes the electrical signals in units of pixels with a set number of quantization bits, and quantization Image generating means for generating recording image data from the data output by the means, an image buffer allocated to the storage device for storing the recording image data, and a mode set by reading the recording image data from the image buffer A control method for an imaging apparatus having compression encoding means for performing compression encoding processing in accordance with and storage means for storing settings relating to the compression rate in the compression encoding processing , wherein the control means a control step of controlling the allocation of the image buffer in the storage device and the number of quantization bits of the quantizer, the control process, the control means, ginseng related settings compressibility Then, the step of determining which of the processing speed and the image quality has priority, and the control means, when it is determined that the image quality has priority, than when the processing speed is determined to have priority A method for controlling an imaging apparatus, comprising: a step of reducing the number of image buffers allocated to a storage device, increasing the capacity per image buffer, and increasing the number of quantization bits of a quantization unit. Is also achieved.

  With such a configuration, according to the present invention, there is provided an imaging device that is easy to use for a user and a method for controlling the imaging device, regardless of whether continuous shooting speed or image quality is required by effectively utilizing a limited buffer capacity. realizable.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the drawings.
(Configuration of imaging device)
FIG. 1 is a diagram illustrating a configuration of a digital camera 100 as an example of an imaging apparatus according to an embodiment of the present invention.

  10 is an imaging lens, 12 is a shutter having a diaphragm function, 14 is an image sensor such as a CCD or CMOS sensor that converts an optical image of a subject into an electrical signal in pixel units, and 16 is an analog signal output (pixel signal) of the image sensor 14. ) Is converted to digital data and output. In the present embodiment, the number of quantization bits (number of bits per pixel) of the A / D converter 16 is variable and is set by the system control unit 50.

  The timing generator 18 supplies a clock signal and a control signal to the image sensor 14, the A / D converter 16, and the D / A converter 26, and is controlled by the memory controller 22 and the system controller 50.

The image processing unit 20 performs predetermined image processing such as pixel interpolation processing and color conversion processing on the data output from the A / D converter 16 or the data from the memory control unit 22.
Further, the image processing unit 20 performs predetermined calculation processing using the captured image data. Then, based on the obtained calculation result, the system control unit 50 controls the exposure control unit 40 and the distance measurement control unit 42, and TTL (through the lens) AF (autofocus), AE (automatic exposure). , EF (flash pre-emission) function is realized.

Further, the image processing unit 20 performs predetermined calculation processing using the captured image data, and also performs TTL AWB (auto white balance) processing based on the obtained calculation result.
The memory control unit 22 controls the A / D converter 16, the timing generation unit 18, the image processing unit 20, the image display memory 24, the D / A converter 26, the memory 30, and the compression / decompression unit 32.

  Data output from the A / D converter 16 is sent via the image processing unit 20 and the memory control unit 22, or data output from the A / D converter 16 is sent directly via the memory control unit 22 to the image display memory 24 or It is written in the memory 30.

  In the present embodiment, the image processing unit 20 and the memory control unit 22 function as an image generation unit that generates recording image data from data output from the A / D converter 16.

  Display image data written in the image display memory 24 is displayed by an image display unit 28 such as an LCD or an organic EL display via a D / A converter 26. An electronic viewfinder function can be realized by sequentially displaying the captured image data on the image display unit 28.

  The image display unit 28 can arbitrarily turn on / off the display according to an instruction from the system control unit 50. When the display is turned off, the power consumption of the digital camera 100 can be significantly reduced. it can.

The memory 30 is a storage device that stores captured still images and moving images, and is assigned an image buffer for storing a predetermined number of still images and a predetermined time of moving images. Therefore, high-speed and large-volume image writing can be performed on the memory 30 even in continuous shooting or panoramic imaging in which a plurality of still images are continuously captured. As will be described later, the number of image buffers allocated to the memory 30 is variable and is set by the system control unit 50.
The memory 30 can also be used as a work area for the system control unit 50.

  The compression / decompression unit 32 reads the recording image data stored in the memory 30 and performs a known data compression process or expansion process using adaptive discrete cosine transform (ADCT), wavelet transform, or the like. The processing result data is written in the memory 30.

  The exposure control unit 40 controls the shutter 12 having a diaphragm function, and also has a flash light control function in cooperation with the flash 48.

The distance measurement control unit 42 controls focusing of the imaging lens 10, and the zoom control unit 44 controls zooming of the imaging lens 10. The barrier control unit 46 controls the operation of the lens barrier 102 for protecting the imaging lens 10.
The flash 48 functions as an auxiliary light source at the time of imaging and also has a light control function. It also has a function of projecting AF auxiliary light.

  The exposure control unit 40 and the distance measurement control unit 42 are controlled using the TTL method. Based on the calculation result obtained by calculating the captured image data by the image processing unit 20, the system control unit 50 performs the exposure control unit 40 and the distance measurement. The controller 42 is controlled.

  The system control unit 50 is a CPU, for example, and controls the entire digital camera 100 by executing a program stored in the memory 52. The memory 52 stores constants, variables, programs, etc. for operating the system control unit 50.

  The display unit 54 is configured by a combination of output devices such as an LCD, an LED, and a speaker, for example, and outputs an operation state, a message, and the like using characters, images, sounds, and the like in accordance with execution of a program by the system control unit 50. . One or a plurality of display units 54 are installed at a position in the vicinity of the operation unit 70 of the digital camera 100 that is easily visible. A part of the display unit 54 is installed in the optical viewfinder 104.

  Examples of display contents of the display unit 54 include the following. Single shot / continuous shooting display, self-timer display, compression rate display, number of recorded pixels, number of recorded images, remaining number of images that can be captured, shutter speed display, aperture value display, exposure compensation display, flash display. Red-eye reduction display, macro imaging display, buzzer setting display, clock battery level display, battery level display, error display, information display with multiple digits, display status of recording media 200 and 210, communication I / F operation Display, date / time display, display showing connection status with external computer. Focus display, imaging preparation completion display, camera shake warning display, flash charge display, recording medium writing operation display, etc. A part of this is displayed in the optical viewfinder 104.

  Further, among the display contents of the display unit 54, examples of what is displayed by an LED or the like include the following. Focus display, imaging preparation completion display, camera shake warning display, camera shake warning display, flash charge display, flash charge completion display, recording medium writing operation display, macro imaging setting notification display, secondary battery charge status display, etc.

  Of the display contents of the display unit 54, what is displayed by a lamp or the like includes, for example, a self-timer notification lamp. This self-timer notification lamp may be used in common with AF auxiliary light.

  The nonvolatile memory 56 is an electrically erasable / recordable memory, and for example, an EEPROM or the like is used.

  The mode dial 60, the shutter switches 62 and 64, the image display ON / OFF switch 66, and the operation unit 70 constitute operation means for inputting various operation instructions and settings to the system control unit 50. These are composed of a single button or a combination of a plurality of buttons, switches, dials, touch panels, pointing by eye-gaze detection, voice recognition devices, and the like.

Here, a specific description of these operating means will be given.
The mode dial 60 is a switch for switching and setting each function mode such as power-off, automatic imaging mode, program imaging mode, panoramic imaging mode, playback mode, multi-screen playback / erase mode, PC connection mode, and the like.

  The first shutter switch (SW1) 62 is turned on by a first stroke (for example, half-pressed) of a shutter button (not shown) provided in the digital camera 100. When the first shutter switch (SW1) 62 is turned on, AF (autofocus) processing, AE (automatic exposure) processing, AWB (auto white balance) processing, EF processing, and the like are started.

  The second shutter switch (SW2) 64 is turned on by a second stroke (for example, full press) of a shutter button provided in the digital camera 100, and instructs to start a series of processes including exposure processing, development processing, and recording processing. . First, in the exposure process, a signal read from the image sensor 14 is written into the memory 30 via the A / D converter 16 and the memory control unit 22, and further, an operation in the image processing unit 20 and the memory control unit 22 is performed. Development processing using is performed. Further, a recording process is performed in which the image data is read from the memory 30, compressed by the compression / decompression unit 32, and written to the recording medium 200 or 210.

  The image display ON / OFF switch 66 is a display ON / OFF setting switch of the image display unit 28. When taking an image using the optical viewfinder 104, it is possible to save power by turning off the display of the image display unit 28 made of, for example, a TFT LCD or the like to cut off the current supply.

  The operation unit 70 includes various buttons and a touch panel. These buttons include the following: Menu button, set button, macro button, multi-screen playback page break button, single-shot / continuous-shot / self-timer switching button, menu move + (plus) button, menu move-(minus) button. Play image move + (plus) button, play image move-(minus) button, imaging image quality selection button, exposure compensation button, date / time setting button, compression mode switch, and the like.

  The compression mode switch is a switch for selecting a compression rate of JPEG (Joint Photographic Expert Group) compression, or for selecting a RAW mode in which a signal of an image sensor is directly digitized and recorded on a recording medium.

  In the present embodiment, for example, a normal mode and a fine mode are prepared as JPEG compression modes. The user of the digital camera 100 can select the normal mode when emphasizing the data size of the captured image and select the fine mode when emphasizing the image quality of the captured image.

  In the JPEG compression mode, the compression / decompression unit 32 reads the image data written in the memory 30, compresses it to the set compression rate, and then records it on the recording medium 200, for example.

  In the RAW mode, the image data is read as it is for each line according to the pixel arrangement of the color filter of the image sensor 14, and the image data written in the memory 30 is read via the A / D converter 16 and the memory control unit 22. Read and record on the recording medium 200.

  The power control unit 80 includes a battery detection circuit, a DC-DC converter, a switch circuit that switches a block to be energized, and the like, and detects whether or not a battery is installed, the type of battery, and the remaining battery level. Further, the power supply control unit 80 controls the DC-DC converter based on the detection result and the instruction of the system control unit 50, and supplies the necessary voltage to each unit including the recording media 200 and 210 for a necessary period. .

  The power source 86 includes a primary battery such as an alkaline battery or a lithium battery, a secondary battery such as a NiCd battery, a NiMH battery, or a Li battery, or an AC adapter, and is attached to the digital camera 100 by connectors 82 and 84.

  The recording media 200 and 210 such as a memory card and a hard disk have recording units 202 and 212 constituted by a semiconductor memory and a magnetic disk, interfaces 204 and 214 and connectors 206 and 216 with the digital camera 100. The recording media 200 and 210 are attached to the digital camera 100 via connectors 206 and 216 on the medium side and connectors 92 and 96 on the digital camera 100 side. Interfaces 90 and 94 are connected to the connectors 92 and 96. Whether or not the recording media 200 and 210 are attached is detected by the recording medium attachment / detachment detection unit 98.

  In the present embodiment, the digital camera 100 is described as having two interfaces and connectors for attaching a recording medium. However, any number of interfaces and connectors for attaching a recording medium can be provided. Different standard interfaces and connectors may be used for each system.

  As the interface and connector, for example, a PCMCIA card, a compact flash (registered trademark) card, or the like conforming to a standard can be used.

  Furthermore, when the interfaces 90 and 94 and the connectors 92 and 96 are made compliant with the standard, it is attached to image data and image data with other computers and peripheral devices such as printers by connecting various communication cards. Management information can be transferred.

  The lens barrier 102 covers the imaging unit including the lens 10 of the digital camera 100, thereby preventing the imaging unit from being dirty or damaged.

  The optical finder 104 is, for example, a TTL finder, and forms an image of a light beam that has passed through the lens 10 using a prism or a mirror. By using the optical viewfinder 104, it is possible to take an image without using the electronic viewfinder function of the image display unit 28. Further, as described above, some functions of the display unit 54 such as an in-focus display, a camera shake warning display, a flash charge display, a shutter speed display, an aperture value display, an exposure correction display, etc. are provided in the optical viewfinder 104. Information is displayed.

The communication unit 110 performs various communication processes such as RS232C, USB, IEEE1394, P1284, SCSI, modem, LAN, and wireless communication.
A connector (antenna in the case of wireless communication) 112 connects the digital camera 100 to another device via the communication unit 110.

(Operation)
Hereinafter, the operation of the digital camera 100 of the present embodiment having the configuration shown in FIG. 1 will be described.
2 and 3 are flowcharts for explaining main operations of the digital camera 100 of the present embodiment.

  Upon power-on such as battery replacement, the system control unit 50 initializes flags, control variables, and the like (S101), and initializes the image display of the image display unit 28 to an OFF state (S102).

  The system control unit 50 determines the setting position of the mode dial 60, and if the mode dial 60 is set to power OFF (S103), performs a predetermined end process (S105), and then returns the process to S103. . Here, the termination process includes, for example, the following process. Processing to end display of each display unit, processing to close the lens barrier 102. Also, processing for recording parameters, setting values, and setting modes including flags and control variables in the nonvolatile memory 56. Processing for shutting off unnecessary power to each part of the digital camera 100 including the image display unit 28 by the power control unit 80.

  On the other hand, if the mode dial 60 is set to another mode in S103, the system control unit 50 executes processing according to the selected mode (S104), and returns the processing to S103.

  If the mode dial 60 is set to the imaging mode in S103, the process proceeds to S106. In S106, the system control unit 50 uses the power supply control unit 80 to check the remaining capacity and operation status of the power supply 86 formed of a battery or the like. Then, it is determined whether or not the power source 86 has a problem in the operation of the digital camera 100. If there is a problem, the system control unit 50 uses the display unit 54 to display a predetermined warning by image or sound (S108), and returns the process to S103.

  If there is no problem with the power supply 86 (S106), the system control unit 50 determines whether or not the recording medium 200 or 210 has a problem in the operation of the digital camera 100, particularly the recording / reproducing operation (S107). If there is a problem, a predetermined warning is displayed by an image or sound using the system control unit 50 or the display unit 54 (S108), and the process returns to S103.

  If there is no problem in the recording medium 200 or 210, the system control unit 50 displays various setting states of the digital camera 100 using images and sounds using the display unit 54 (S109). If the image display of the image display unit 28 is ON, various setting states of the digital camera 100 can be displayed by using an image or sound using the image display unit 28.

  In step S116, the system control unit 50 sequentially displays captured image data of components necessary for generating a captured image for display, such as the image sensor 14, the image processing unit 20, and the memory control unit 22. The through display state is set, and the process proceeds to S119 (FIG. 3).

  In the through display state, the data sequentially written in the image display memory 24 via the image sensor 14, the A / D converter 16, the image processing unit 20, and the memory control unit 22 are transferred to the memory control unit 22 and the D The images are sequentially displayed by the image display unit 28 via the / A converter 26. Thereby, the image display part 28 can be functioned as an electronic viewfinder (EVF).

  In S119, the system control unit 50 checks the state of the shutter switch SW1 (62). If it is not ON, the process returns to S103, and if it is ON, the process proceeds to S122.

  In S122, the system control unit 50 performs a distance measurement process to focus the imaging lens 10 on the subject, performs a photometry process, and determines an aperture value and / or an exposure time (shutter speed) (S122). In the photometric process, the flash is set if necessary. Details of the distance measurement process and the photometry process in S122 will be described later with reference to FIG.

  When the distance measuring process and the photometric process are finished, the system control unit 50 checks the state of the shutter switch SW2 (64) and the shutter switch SW1 (62) in S125 and S126. When the shutter switch SW2 (64) is OFF and the shutter switch SW1 (62) is also OFF, the system control unit 50 returns the process to S103. If the shutter switch SW2 (64) is OFF and the shutter switch SW1 (62) remains ON, the system control unit 50 continues to execute the processes of S125 and S126. If the shutter switch SW2 (64) is turned on, the system control unit 50 advances the process to S127.

  In step S <b> 127, the system control unit 50 refers to the imaging parameter setting contents stored in the nonvolatile memory 56, for example. Then, according to the setting contents, allocation of the usage divisions of the memory 30 and the number of quantization bits (the number of bits per pixel) of the A / D converter 16 are determined. Details of the memory arrangement switching process will be described later with reference to FIGS.

In step S129, the system control unit 50 executes imaging processing for generating captured image data. Details of the imaging process will be described later with reference to FIG.
When the imaging process ends, the system control unit 50 performs a recording process including encoding of the captured image data, recording on a recording medium, and the like. Details of this recording process will be described later with reference to FIG.
When the recording process ends, the system control unit 50 returns the process to S103.

(Ranging / photometry processing)
FIG. 4 is a flowchart for explaining the details of the distance measurement process and the photometry process performed in S122 of FIG.
The system control unit 50 reads out the charge signal in units of pixels from the image sensor 14 and sequentially reads the captured image data into the image processing unit 20 via the A / D converter 16 (S201). Using this sequentially read image data, the image processing unit 20 is a predetermined used for TTL (through-the-lens) AE (automatic exposure) processing, EF (flash preflash) processing, and AF (autofocus) processing. The operation is performed.

  Note that the image processing unit 20 uses only pixels necessary for various calculations among pixels captured by the image sensor 14. Thereby, in TTL method AE, EF, AWB, and AF processes, it is possible to perform calculations suitable for different modes such as the center-weighted mode, the average mode, and the evaluation mode.

  Using the calculation result in the image processing unit 20, the system control unit 50 performs AE control using the exposure control unit 40 (S203) until it is determined that the exposure (combination of shutter speed and aperture) is appropriate (S202). ).

  Using the measurement data obtained by the AE control, the system control unit 50 determines whether or not the flash is necessary (S204). If the flash is necessary, the system controller 50 stores the flash flag in the internal memory or the memory 52, and stores the flash 48. Charge (S205).

  When it is determined that the exposure is appropriate (S202), the system control unit 50 stores measurement data and / or setting parameters in the internal memory or the memory 52 of the system control unit 50.

  Next, the system control unit 50 uses the image processing unit 20 until the white balance is determined to be appropriate using the calculation result in the image processing unit 20 and the measurement data obtained by the AE control (S206). The AWB control is performed by adjusting the processing parameters (S207).

  When it is determined that the white balance is appropriate (S206), the system control unit 50 stores measurement data and / or setting parameters in the internal memory or the memory 52 of the system control unit 50.

  Using the measurement data obtained by the AE control and the AWB control, the system control unit 50 performs focus detection processing and uses the distance measurement control unit 42 until it is determined that the imaging lens is focused on the subject (S208). Then, automatic focusing (AF) control is performed (S209).

  If it is determined that the in-focus state is obtained, the system control unit 50 stores the measurement data and / or setting parameters in the internal memory or the memory 52 of the system control unit 50, and ends the distance measurement process and the photometry process.

(Imaging processing)
FIG. 5 is a flowchart illustrating details of the imaging process performed in S129 of FIG.
The system control unit 50 controls the aperture value of the shutter 12 having the aperture function through the exposure control unit 40 according to the photometric data stored in the internal memory or the memory 52, opens the shutter (S301), and starts exposure of the image sensor 14. (S302).

  The system control unit 50 refers to the flash flag to determine whether or not the flash 48 needs to be emitted (S303), and if necessary, causes the flash to emit light (S304).

  The system control unit 50 waits for the exposure time corresponding to the photometric data to elapse (S305), and closes the shutter 12 when the exposure time elapses (S306). Then, a charge signal is read from the image sensor 14. The read charge signal is written into the memory 30 via the A / D converter 16, the image processing unit 20, and the memory control unit 22. Alternatively, the charge signal is written into the memory 30 from the A / D converter 16 not through the image processing unit 20 but only through the memory control unit 22 (S307).

At this time, the number of quantization bits of the image output from the A / D converter 16 follows the number of bits determined in S127.
Color processing (S310) is sequentially performed according to the set imaging mode, and then the processed image data is written in the memory 30. When the series of processing is finished, the imaging processing is finished.

(Record)
FIG. 6 is a flowchart for explaining the details of the recording process performed in S134 of FIG.
The system control unit 50 uses the memory control unit 22 to read the image data written in the memory 30, and the compression / decompression unit 32 performs compression encoding processing according to the set mode (S402). In the non-compression mode (RAW mode), compression encoding by the compression / decompression unit 32 is not performed. Then, processing for making the captured image file format, such as addition of header information, is performed. Then, the captured image file is written to the recording medium 200 or 210 such as a memory card via the interface 90 or 94 and the connector 92 or 96 (S403). When the writing is finished, the recording process is finished.

(Memory allocation switching)
FIG. 7 is a flowchart for explaining the details of the memory arrangement switching process performed in S127 of FIG.
The system control unit 50 refers to at least one of settings related to image quality and processing speed among settings related to imaging stored in the nonvolatile memory 56. Specifically, at least one of a setting relating to compression encoding, a setting relating to continuous shooting speed, and a setting relating to photographing sensitivity is referred to (S501).

Here, a case will be described in which all these three settings are referred to. In S502, S503, and S504, the system control unit 50
Whether the compression rate α of compression encoding is less than a predetermined compression rate (S502);
-Whether the continuous shooting speed is lower than a predetermined speed (S503),
Check whether the photographing sensitivity is higher than a predetermined sensitivity (ISO sensitivity) β.

  Here, the compression rate does not need to be set as a specific numerical value, and corresponds to options such as “uncompressed (RAW)”, “fine (JPEG)”, “normal (JPEG)”, etc. It may be set with a value. In this case, in S502, for example, it may be determined whether non-compression or high image quality is set.

  Similarly, the continuous shooting speed may be set to a value corresponding to options such as “high-speed continuous shooting”, “low-speed continuous shooting”, and “no continuous shooting”. In this case, in S503, for example, it may be determined whether “low speed continuous shooting” or “no continuous shooting” is set.

  Regarding the shooting sensitivity, it is possible to determine whether or not a shooting mode for performing high-sensitivity shooting, such as “candle mode” and “night scene shooting mode”, is set as well as a specific sensitivity setting.

  These are all examples of conditions for determining whether processing speed should be considered in preference to image quality, and the setting items, types of setting values, and setting values serving as threshold values are as exemplified here. It is not limited.

  If any of the above three conditions is satisfied, the system control unit 50 determines that image quality has priority over the processing speed or does not require the processing speed, and performs memory allocation (S507). Here, the memory arrangement selected when it is determined that the image quality is given priority is referred to as “memory arrangement 2”.

  Then, the system control unit 50 sets the number of quantization bits of the A / D converter 16 to B (bit) / pixel (S508). As will be described later, the number of quantization bits set here is larger than the number of quantization bits set when it is determined that the processing speed is prioritized.

  On the other hand, if all of the above three conditions are not satisfied, the system control unit 50 performs memory allocation on the assumption that the processing speed has priority over the image quality (S505). Here, the memory arrangement selected when it is determined that the processing speed is given priority is referred to as “memory arrangement 1”.

  Then, the system control unit 50 sets the number of quantization bits of the A / D converter 16 to A (bit) / pixel (S506). As will be described later, the number of quantization bits set here is smaller than the number of quantization bits set when it is determined that image quality is given priority.

  Here, only when the above three conditions are not satisfied, the memory arrangement 1 is used. However, the memory arrangement may be selected based on fewer conditions. For example, it may be configured such that only one of the above conditions is determined and the memory arrangement 2 is selected when the condition is satisfied, and the memory arrangement 1 is selected when the condition is not satisfied. For example, the memory arrangement 1 may be selected when the compression rate is equal to or higher than a predetermined value, the continuous shooting speed is equal to or higher than a predetermined value, or the photographing sensitivity is equal to or lower than a predetermined sensitivity.

FIG. 8 is a diagram illustrating an example of a memory arrangement in the digital camera 100 according to the present embodiment.
FIG. 8A shows an example of the memory arrangement 1 in this embodiment, and FIG. 8B shows an example of the memory arrangement 2 in this embodiment.

  As described above, the memory arrangement 1 is selected in the case of setting contents that are considered to require processing speed. The memory arrangement 1 has a smaller memory capacity per image buffer than the memory arrangement 2, and the memory capacity per image buffer is set so that at least two captured images can be stored in the memory 30. Yes. Further, the number of image buffers allocated in the memory arrangement 1 is set to be larger than the image buffers allocated in the memory arrangement 2. Therefore, in the example of FIG. 8, the number of image buffers in the memory arrangement 2 is one, but two or more may be allocated.

  Here, in the present embodiment, unlike the technique described in Patent Document 1, the number of pixels of the captured image does not change even if the memory arrangement 1 is selected or the memory arrangement 2 is selected. However, the number of quantization bits in the A / D converter 16 is different. For example, when memory arrangement 1 is selected, the number of quantization bits set in the A / D converter 16 is A (bit) / pixel, and when memory arrangement 2 is selected, the quantum set in the A / D converter 16 Assuming that the number of bits is B (bit) / pixel, B> A.

  Note that the number of quantization bits in the memory arrangement 1 is at least two in the memory 30 in consideration of other setting values (for example, compression rate) that affect the capacity of the captured image as necessary, and the memory arrangement 2 It is set so that a larger number of captured images can be stored.

  Thereby, even when it is determined that the processing speed is given priority, the memory capacity per captured image can be suppressed without reducing the number of pixels. In addition, when it is determined that image quality is given priority, by reducing the number of image buffers allocated to the memory and further increasing the amount of information per pixel, it is possible to improve the image quality by effectively utilizing the memory capacity. .

  In this way, by changing not only the number of image buffers allocated to the memory but also the number of quantization bits of the A / D converter 16, per captured image is independent of the compression rate in the subsequent compression encoding. Data capacity and image quality can be adjusted. Further, when it is determined that the image quality is given priority, the amount of information per pixel increases, so that a higher image quality can be realized.

  For example, when the memory arrangement is selected according to the compression rate setting, and when the RAW mode in which the image quality is determined to be prioritized is set, the JPEG encoding mode in which the processing speed is determined to be prioritized. Rather, the number of quantization bits set in the A / D converter 16 increases. Therefore, it is possible to further improve the image quality in the RAW shooting mode.

  FIG. 9 is an example of a timing chart of continuous shooting processing in the digital camera 100 of the present embodiment. Here, as shown in FIG. 8, it is assumed that two image buffers are allocated in the memory arrangement 1 and one image buffer is allocated in the memory arrangement 2.

  FIG. 9A is a timing chart corresponding to the memory arrangement 2, in which an image is written to the image buffer by the imaging process, an image is read from the image buffer by the image process, a recorded image is generated, and the file buffer is written. Write to the recording medium in the writing process. As shown in FIG. 9A, when there is one image buffer, only the imaging process and the writing process are processed in parallel among the imaging process, the image process, and the writing process.

  On the other hand, FIG. 9B is a timing chart corresponding to the memory arrangement 1, and in parallel with the image processing, the image is read from the image buffer 1, the recorded image is generated and written to the file buffer. Execute in parallel and write the image to the image buffer 2. As described above, by having two image buffers, it is possible to perform the imaging processing and the image processing in parallel, and the processing speed can be improved. As a result, high-speed continuous shooting can be realized.

  As described above, according to the present embodiment, it is determined by referring to at least one of the setting relating to the image quality of the captured image and the setting relating to the processing speed which of the image quality and the processing speed is prioritized. When the image quality is determined to be prioritized, the number of image buffers allocated to the memory is reduced as compared with the case where the processing speed is determined to be prioritized. Further, the number of quantization bits of the A / D converter that quantizes the pixel signal is increased as compared with the case where it is determined that the processing speed is prioritized.

  As a result, when it is determined that the image quality is given priority, it is possible to improve the image quality by effectively using the memory. When it is determined that the processing speed is given priority, parallel processing can be realized by increasing the number of image buffers, and high-speed continuous shooting can be realized. Therefore, it is possible to achieve both good usability and high image quality.

(Other embodiments)
In the above embodiment, when it is determined that image quality is prioritized, the number of quantization bits of the A / D converter that quantizes the pixel signal is increased as compared with the case where it is determined that processing speed is prioritized. However, the present invention is not limited to this.

  That is, as a result, it is only necessary to control the number of image buffers allocated to the memory so that the A / D converter quantizes with the same number of bits in both the image quality priority and the processing speed priority. It is also possible to control the number of bits until recording is performed.

  Specifically, the image processing unit 20 is provided with a function of converting and outputting the number of bits of data output from the A / D converter, and the quantization unit is configured together with the A / D converter. To. In the case where the processing speed is given priority, the image processing unit 20 performs a process of converting the image having the quantization bit number B from the A / D converter into the image having the quantization bit number A.

  In this case, the quantization bit number of the A / D converter is fixed to the bit number B in step S101 of FIG. 2, and is not changed thereafter. Then, in the flow of switching the memory arrangement, step S506 is “set processing for converting the number of quantization bits B into A” in FIG. 7 in the above embodiment, step S508 is deleted, It is different in that it goes to return.

1 is a diagram illustrating a configuration of a digital camera 100 as an example of an imaging apparatus according to an embodiment of the present invention. 3 is a flowchart for explaining main operations of the digital camera 100 according to the embodiment of the present invention. 3 is a flowchart for explaining main operations of the digital camera 100 according to the embodiment of the present invention. It is a flowchart explaining the detail of the ranging process and photometric process of the digital camera 100 which concerns on embodiment of this invention. It is a flowchart explaining the detail of the imaging process of the digital camera 100 which concerns on embodiment of this invention. 4 is a flowchart illustrating details of a recording process of the digital camera 100 according to the embodiment of the present invention. 4 is a flowchart illustrating details of a memory arrangement switching process of the digital camera 100 according to the embodiment of the present invention. It is a figure which shows the example of the memory arrangement | positioning in the digital camera 100 which concerns on embodiment of this invention. It is an example of the timing chart of the continuous shooting process in the digital camera 100 according to the embodiment of the present invention.

Claims (6)

An image sensor that converts an optical image of a subject into an electrical signal in units of pixels;
Quantization means for quantizing and outputting the electrical signal in pixel units with a set number of quantization bits,
Image generation means for generating image data for recording from data output by the quantization means;
An image buffer assigned to a storage device for storing the recording image data;
Compression encoding means for reading the image data for recording from the image buffer and performing compression encoding processing according to a set mode;
Storage means for storing a setting relating to a compression rate in the compression encoding process ;
According to the setting, the control means for controlling the number of quantization bits of the quantization means and the allocation of the image buffer in the storage device,
The control means refers to the setting relating to the compression ratio to determine which of processing speed and image quality is prioritized, and when it is determined that the image quality is prioritized, the processing speed is prioritized. The image pickup apparatus is characterized in that the number of image buffers to be allocated to the storage device is smaller and the capacity per image buffer is increased and the number of quantization bits of the quantization means is increased than in the case where it is determined that . It said storage means, to set Joo further memory of shooting sensitivity,
Said control means, said or compressibility is less than the predetermined compression ratio, if the previous SL photographic sensitivity satisfies either higher than the predetermined sensitivity, that determines that the image quality is prioritized The imaging apparatus according to claim 1, wherein:   The quantization means is an A / D converter, and the control means controls the number of quantization bits by controlling the number of bits of A / D conversion by the A / D converter. The imaging device according to claim 1 or 2.   The quantization means includes an A / D converter and an image processing means for changing the number of bits of data quantized by the A / D converter, and the control means performs an operation of the image processing means. The imaging apparatus according to claim 1, wherein the number of quantization bits is controlled by controlling. The control means includes
    If it is determined that the image quality is prioritized, one larger image buffer is allocated to the storage device than if it is determined that the processing speed is prioritized;
    When it is determined that the processing speed is prioritized, two smaller image buffers are assigned to the storage device than when it is determined that the image quality is prioritized, and the imaging process and the image generation by the image sensor The imaging processing and the processing for generating the recording image data are executed in parallel by using the image buffers one by one by the processing for generating the recording image data by means. The imaging device according to any one of 1 to 4. An image sensor that converts an optical image of a subject into an electrical signal in units of pixels;
Quantization means for quantizing and outputting the electrical signal in pixel units with a set number of quantization bits,
Image generation means for generating image data for recording from data output by the quantization means;
An image buffer assigned to a storage device for storing the recording image data;
Compression encoding means for reading the image data for recording from the image buffer and performing compression encoding processing according to a set mode;
A control method for an imaging apparatus having storage means for storing a setting relating to a compression rate in the compression encoding process ,
The control means comprises a control step of controlling the number of quantization bits of the quantization means and the allocation of the image buffer in the storage device according to the setting relating to the compression rate ,
The control step is
The control means referring to the setting to determine which of processing speed and image quality is prioritized;
When the control means determines that the image quality is prioritized, the number of image buffers allocated to the storage device is smaller and the number of image buffers per image buffer than when the processing speed is determined to be prioritized. And increasing the number of quantization bits of the quantization means,
A method for controlling an imaging apparatus, comprising:

Images