JP2007110441A - Imaging apparatus and processing method thereof - Google Patents

Abstract

An imaging apparatus and a processing method therefor are provided in which a plurality of output stages are arranged and which are appropriately operated according to usage conditions.
A digital camera 10 has a resolution at which a control unit 30 indicates a first speed mode, a resolution at which a second speed mode is relatively faster than a VGA (Video Graphics Array), and an HDTV (High Definition TeleVision). ) Is generated, a control signal 114 is generated according to the determination result, the drive mode control unit 32 is controlled according to the control signal 114, and the control signal 92 supplied from the drive mode control unit 32 is The driver 28 and the image pickup unit 14 are controlled by the control of the timing signal generator 26 according to the above, and the obtained image signals 68 and 70 are set to two outputs or one output. Are controlled so as to correspond to the number of outputs of the imaging unit.
[Selection] Figure 1

Description

  The present invention relates to an imaging apparatus. The image pickup apparatus according to the present invention relates to a technical field using an image pickup element having a plurality of output stages corresponding to high-speed readout of signal charges.

  For the purpose of high-speed reading of an image sensor, Patent Documents 1 and 2 are proposed for an image sensor and an image pickup apparatus that have multiple outputs or have a plurality of horizontal transfer paths in order to realize this purpose. The imaging device disclosed in Patent Document 1 discloses that only a signal charge obtained from a selected portion of a screen is read, the signal charge is transferred, and read out as an analog signal from two output amplifiers. In addition, the solid-state imaging device and the driving method thereof in Patent Document 2 disclose that the screen is not divided into right and left parts, but is divided into upper and lower parts, and horizontal transfer paths are arranged on the upper end side and the lower end side, respectively, and image signals are read out. is doing.

  Furthermore, the solid-state imaging device of Patent Document 3 discloses that one end of a horizontal transfer path is branched into two and an output stage is selected according to sensitivity.

JP 2004-194023 Japanese Patent Laid-Open No. 11-103421 JP-A-8-2998626

  By the way, Patent Documents 1 and 2 are advantageous in that they are excellent in high-speed performance in signal reading because a plurality of output stages are arranged. However, in order to realize these, correction is required by various processes corresponding to power saving and screen division. Japanese Patent Application Laid-Open No. 2004-228561 is superior in that it obtains an image signal having an appropriate image quality by selecting a sensitivity according to the shooting environment, but is disadvantageous in terms of high-speed signal reading.

  SUMMARY OF THE INVENTION It is an object of the present invention to provide an imaging apparatus and a processing method therefor that eliminate such drawbacks of the prior art and allow a plurality of output stages to be arranged and operate appropriately according to usage conditions.

  In order to solve the above-described problem, the present invention generates an image signal based on a signal charge obtained by photoelectric conversion of incident light from an object scene, and has a plurality of output means for outputting the image signal. In the imaging apparatus driven according to the operation status, the apparatus generates a control signal for controlling the operation of the imaging means according to any one of a plurality of outputs and one output, and a control signal corresponding to the control signal. A timing generation unit that generates a timing signal of the imaging unit, a drive signal generation unit that generates a drive signal according to the timing signal, and at least an image signal of an output system corresponding to the number of outputs of the output unit, Including pre-processing means for noise removal and digitization, and processing control means for controlling processing for each output system of the pre-processing means in accordance with a control signal. And determining whether or not a plurality of outputs is a second speed mode that is relatively faster than the first speed mode, and generating a control signal according to the determination result. In the first speed mode, the process is controlled to one output system, and in the second speed mode, the process is controlled to a plurality of output systems.

  In the imaging apparatus of the present invention, the control means determines whether or not the second speed mode is relatively faster than the first speed mode, and generates a control signal according to the determination result. Accordingly, the timing generation unit, the drive signal generation unit, and the processing control unit are controlled, the imaging unit is imaged according to the drive from the drive signal generation unit, and the obtained image signal is set to a plurality of outputs in the second speed mode. In the first speed mode, a normal image signal is read out, and the processing control unit operates the preprocessing unit to which the image signal is supplied so as to correspond to the number of outputs of the imaging unit, so that it operates appropriately according to the use situation. Can be made. Thereby, useless operation can be avoided.

  In order to solve the above-described problems, the present invention generates an image signal based on a signal charge obtained by photoelectric conversion of incident light from an object field, and drives the image signal in accordance with an operation situation. In the imaging processing method for outputting a plurality of images, the method includes either a first step for acquiring preset conditions, or a second speed mode that is relatively faster than the first speed mode for the acquired set conditions. A second step of generating a control signal according to the determination result and a generation of a timing signal for outputting a plurality of image signals according to the determination result including the second speed mode. 3, a fourth step for setting generation of a normal timing signal for outputting only one image signal based on a determination result including the first speed mode, and a determination result including the second speed mode. A fifth step of setting at least noise removal and digitization to the image signals of a plurality of output systems, and at least noise removal to an image signal of one output system supplied by a determination result including the first speed mode And the sixth step of setting digitization and the image data of a plurality of output systems digitized and supplied by the determination result including the second speed mode are rearranged for each pixel, and the pixels are changed in a normal dot-sequential manner. A seventh step of setting, and an eighth step of setting the output of image data of one output system that is digitized and supplied based on the determination result including the first speed mode, and imaging is performed according to each setting. The image data is obtained through preprocessing.

  The imaging processing method of the present invention acquires a set condition, determines whether or not the condition includes any of a second speed mode that is relatively faster than the first speed mode, and responds to the determination result. The control signal is generated, and a timing signal is generated to output a plurality of image signals based on the determination result including the second speed mode, and at least noise removal and digitization of the supplied image signals of the plurality of output systems are performed. Is set, the image signals of a plurality of output systems to be supplied are rearranged for each pixel, pixel change is set in a normal dot-sequential manner, and only one image signal is output according to the determination result including the first speed mode. Set to generate a normal timing signal, set at least noise removal and digitization to the supplied image signal of one output system, and output the image signal of the supplied one output system The process in accordance with the output captured by a constant because it can be operated properly in accordance with each mode, it is possible to avoid unnecessary operation.

  Next, an embodiment of an imaging apparatus according to the present invention will be described in detail with reference to the accompanying drawings.

  In this embodiment, the imaging apparatus of the present invention is applied to a digital camera 10. The illustration and description of parts not directly related to the present invention are omitted. In the following description, the signal is indicated by the reference number of the connecting line in which it appears.

  As shown in FIG. 1, the digital camera 10 includes an optical system 12, an imaging unit 14, a preprocessing unit 16, an input image adjustment unit 18, a corresponding array processing unit 20, a signal processing unit 22, a clock generator 24, and a timing signal generator. Device 26, driver 28, control unit 30, drive mode control unit 32, operation unit 34, media control unit 36, media 38 and monitor 40.

  The optical system 12 has a function of forming an image corresponding to the operation of the operation unit 34 although the imaging unit 14 does not illustrate the incident light from the object scene. The optical system 12 adjusts the angle of view and the focal length according to the zoom operation and half-press operation of the operation unit 34.

  The imaging unit 14 is provided with a color filter segment corresponding to the arrangement position of the light receiving element in the incoming light arrival direction. The imaging element 44 of the imaging unit 14 has a function of color-separating incident light, converting the separated color component light into a signal charge by a light receiving element, and outputting an electrical signal. As shown in FIG. 2, the image pickup device 44 of the present embodiment shifts the pixels in adjacent rows from the pixel pitch PP in the same horizontal direction by shifting the color filter segments of the three primary colors R, G, and B by 1/2 pixel pitch. Arranged. Focusing on the color G, the color filter segments are arranged in a lattice pattern, and the colors R and B are arranged in a complete checkered pattern. Although the vertical transfer path is not shown in the imaging unit 14 in FIG. 2, the signal charges accumulated according to exposure are read out to the vertical transfer path and sequentially transferred in the vertical direction. In the image sensor 44, a line memory 48 is formed between the vertical transfer path and the horizontal transfer path 46. The signal charges transferred vertically are supplied to the horizontal transfer path 46 (46a, 46b) via the line memory 48. In the horizontal transfer path 46, the horizontal transfer path 46a located on the left side from the central portion C that divides the number of light receiving elements forming the imaging region into approximately two equal parts is the left half of the horizontal transfer path 46, and from the center C to the right side. The horizontal transfer path 46b that is positioned is the right half of the horizontal transfer path 46. An analog electric signal is output from the horizontal transfer path 46 (46a, 46b) only from the output amplifiers 50 and 52 or one of them according to the drive mode described later.

  The image sensor 44 will be further described. The image pickup device 44 includes a vertical transfer path (VCCD) and a line memory (LM) 48 formed so as to bypass the light receiving device. Since these are the same as the conventional configuration, they are not shown and will be omitted. The vertical transfer path is driven by four-phase drive signals φV1 to φV4.

  Here, attention is paid to the horizontal transfer path 46 (46a, 46b) which is a feature of the present embodiment. As shown in FIG. 3, the horizontal transfer paths 46 (46a, 46b) form horizontal transfer paths 46 (46a, 46b). Four-phase drive signals φH1 to φH4 are applied to the horizontal transfer path 46. The feature of the present embodiment is as follows. That is, the horizontal transfer path 46a electrically connects the electrodes 54 and 56 to form a set of electrodes, and the electrode arrangement of `` H2 and H1 '' is repeated at the end from the center C toward the left end, and The horizontal transfer path 46b located on the right side from the central part C is electrically connected to the electrodes 54 and 56 independently, and the electrode arrangement of the ends `` H4, H2, H3 and H1 '' from the central part C to the right end is arranged. It is a repeating point. As described above, when the electrodes 54 and 56 are paired, the number is equal to the number of columns of the vertical transfer path. This depends on the fact that the line memory 48 is provided between the vertical transfer path and the horizontal transfer path 46, and only the signal charges of the columns connected to the line memory 48 by the arrangement of the line memory 48 are transferred to the horizontal transfer path 46. Can be read and stored temporarily.

  The imaging device 44 is the same as the disclosed contents of the prior art except for the electrode arrangement (alignment) of the horizontal transfer path 46 and the timing of the drive waveform described later. As disclosed contents, as shown in FIG. 4, first, a well layer 64 having a conductivity type opposite to the substrate is formed on the surface layer side of the one conductivity type semiconductor substrate 62. Impurity layers (transfer channels) 58 and 60 having a conductivity type opposite to that of the well layer 64 are formed on the substrate surface in the well layer 64 to be formed. The impurity layers 58 and 60 correspond to transfer channels. In the impurity layers 58 and 60, the impurity layer 60 forms a relatively thin impurity layer. On the substrate 62, the first electrode 54 is formed via the insulating layer 66, and the second electrode 56 is formed via the insulating layer 66 for each of the electrode 54 and the substrate 62. An impurity layer 58 is formed under the electrode 54, and an impurity layer 60 is formed under the electrode 56. However, the pitch of each electrode is different.

  Next, FIG. 5 shows driving in the case where the obtained signal charges are transferred in the left and right directions. The left side of FIG. 5 shows the timings of the horizontal drive signals φH1 to φH4 and the horizontal synchronization signal for transferring signal charges. The potentials in the impurity layers 58 and 60 corresponding to this timing are shown on the right side.

  The signal charge transferred from the vertical transfer path is temporarily stored in the impurity layer 58 located under the electrode 56. The signal charge located at the central portion C here is initially stored separately under the electrodes H1 and H4.

  Next, by applying the drive signal φH4 to the electrode H4 at a low voltage, the signal charge immediately below the electrode H4 moves below the electrode H1. After that, the drive signals φH1 and φH4 are taken as a set, and the opposite-phase drive signals φH2 and φH3 are applied as a set to this set, so that the signal charges 4, 2, 3 and 1 of the horizontal transfer path 46a are leftward The signal charges 6, 8, 5, and 7 of the horizontal transfer path 46b are sequentially transferred in the right direction.

  Further, as shown in FIG. 6 in the horizontal transfer path 46, for example, the signal charge transferred to the horizontal transfer path 46 is sent in the left direction, that is, in one direction. The timing of the drive signal for realizing such signal charge transfer is shown on the left side of FIG. The potentials of the impurity layers 58 and 60 corresponding to this timing are shown on the right side.

  The signal charge transferred from the vertical transfer path is temporarily stored in the impurity layer 58 located under the electrode 54 via the impurity layer 60 located under the electrode 56. The drive signals φH1 and φH3 are set as one set, and the drive signals φH2 and φH4 having opposite phases are applied as a set to the set. As a result, all the signal charges on the horizontal transfer paths 46a and 46b are transferred in the left direction.

  The imaging device 44 is not limited to this embodiment, and as shown in FIG. 7, half of the electrodes to which the 8-phase drive signals φH1 to φH8 are applied are formed on the horizontal transfer path 46 (46a, 46b). May be. The horizontal transfer path 46 is the same as the image sensor 44 of FIG. 3 except for the electrode configuration described above.

  These electrodes are the same in that they are divided into a horizontal transfer path 46a and a horizontal transfer path 46b located on the left side from the central portion C when the number of columns of the light receiving elements is approximately divided into two. In the horizontal transfer path 46a, the electrodes 54 and 56 are wired so as to be electrically independent, and the electrode arrangement of “H4, H3, H2, and H1” is repeated from the center C toward the left end. Also in the horizontal transfer path 46b, the electrodes 54 and 56 are wired electrically independently, and the electrode arrangement of “H5, H6, H7 and H8” is repeated from the center C toward the right end.

  It is clear that the cross section of the broken line 7A-7A shown in FIG. 8 differs only in the electrode configuration. When the signal charges transferred to the horizontal transfer path 46 with this electrode configuration are sent in two directions left and right with the central portion C as a boundary, the timings of the drive signals φH1 to φH8 are shown on the left side of FIG. The potentials in the impurity layers 58 and 60 of FIG. 8 formed at this timing are shown on the right side.

  The signal charge transferred from the vertical transfer path to the horizontal transfer path 46 is temporarily stored in the impurity layer 58 located under the electrode 54 via the impurity layer 60 located under the electrode 56. In particular, the signal charge located at the center C is initially stored separately under the electrodes H3 and H5. By applying a low voltage (L level) drive signal φH5, the signal charge located under the electrode H5 moves under the electrode H3. After that, when the drive signals φH1, φH2, φH6 and φH7 are made into a set, and the drive signals φH3, φH4, φH5 and φH8 having a phase opposite to the set of drive signals are applied to the electrodes, the horizontal transfer path 46a The signal charge is transferred in the left direction in the figure, and the signal charge in the horizontal transfer path 46b is transferred in the right direction in the figure.

  Next, FIG. 10 shows the drive and potential when transferring in one direction with this electrode configuration. Here, the data is transferred in the left direction in FIG. The signal charges transferred from the vertical transfer path to the horizontal transfer path 46 via the line memory 48 are temporarily accumulated in the impurity layer 58 positioned below the electrode 54 via the impurity layer 60 positioned below the electrode 56. The Drive signal φH1, φH2, φH5, and φH6 as a set, and drive the opposite phase drive signals φH3, φH4, φH7, and φH8 as a set to this set, so that it moves leftward across all horizontal transfer paths 46a and 46b. Forwarded to

  Although not shown, the horizontal transfer paths 46a and 46b are driven by driving signals φH2, φH3, φH6, and φH7 as a set and driving signals φH1, φH4, φH5, and φH8 that are opposite in phase to this set. Can be transferred to the right across all. A mirror image can be generated by transferring in the right direction. For example, it can be used for an image projected on an in-vehicle rearview mirror.

  In this way, by changing the electrode wiring and changing the drive timing, it becomes possible to arbitrarily select the two transfer directions. As a result, transfer in two directions and transfer in one direction can be properly used according to the user's request. In horizontal transfer in only one direction, the output of the imaging unit 14 is only the output OS1 (Output Signal 1).

  In addition, although the example which applies the drive signal of 4 phases and 8 phases was demonstrated to the image pick-up element 44, it is not limited to this, You may make it give a drive signal of 6 phases. 2 is a timing chart for explaining the number of outputs and the operation in accordance with the operation of a release shutter button in the digital camera of FIG. 1. In addition, the image pickup element 44 is not limited to the pixel shift type as shown in FIG. 2, and it goes without saying that the image pickup element 44 is also effective in an image pickup element type in which the pixels in which the light receiving elements are arranged in a lattice shape are not shifted.

  Returning to FIG. 1, the imaging unit 14 outputs two analog electric signals 68 and 70 from the imaging device 44 to the preprocessing unit 16.

  The preprocessing unit 16 has an analog front end (AFE) function. This function includes noise removal for the analog electrical signals 68 and 70 by correlated double sampling (CDS), and digitization of the noise-removed analog electrical signals 68 and 70, that is, A / D conversion. Two analog electric signals 68 and 70 are supplied to the pre-processing unit 16, but in the case of one system input, the drive mode control unit 32 is operated so that only one system is operated for CDS and A / D conversion. Receive control. The preprocessing unit 16 outputs two systems of output signals 72 and 74 to the input image adjustment unit 18 corresponding to the two systems of input.

  The input image adjusting unit 18 has a function of sampling output data of each system, that is, image data by sampling at a frequency, for example, a frequency twice that of the output signals 72 and 74 simultaneously supplied as two systems of output. The input image adjusting unit 18 is not limited to this function, and the supplied output signals 72 and 74 may be stored in respective memories (not shown). The obtained output signal 76 is supplied to the corresponding array processing unit 20 via the bus 78 and the signal line 80.

  The correspondence array processing unit 20 has a function of correcting the arrangement of pixel data of image data obtained as outputs of two systems, for example, in a dot-sequential order corresponding to scanning lines, and combining them into a single image. When the output from the preprocessing unit 16 is one system, the input image adjustment unit 18 and the corresponding array processing unit 20 do not need to adjust the input image or perform processing for changing the arrangement. The corresponding array processing unit 20 outputs the obtained image data to the signal processing unit 22 via the signal line 80, the bus 78, and the signal line 82.

  The signal processing unit 22 has a function of synchronizing based on supplied image data and generating a Y / C signal using the synchronized image data. The signal processing unit 22 also has a function of converting the generated Y / C signal into, for example, a liquid crystal monitor signal. Further, the signal processing unit 22 has a function of compressing the Y / C signal generated according to the recording mode and decompressing and restoring and reproducing based on the compressed signal. The recording mode includes JPEG (Joint Photographic Experts Group), MPEG (Moving Picture Experts Group), RAW mode, and the like. The signal processing unit 22 supplies the image data processed in the recording mode to the media control unit 36 from the signal line 82, the bus 78, and the signal line 86. The signal processing unit 22 outputs a liquid crystal monitor signal 84 to the monitor 40.

  The clock generator 24 has a function of generating a reference clock signal. The clock generator 24 generates a clock according to the control signal 88 from the control unit 30. The clock generator 24 outputs the generated clock signal 90 to the timing signal generator 26. The clock generator 24 also preferably has a function of generating a clock corresponding to the sampling frequency of the output signals 72 and 74.

  The timing signal generator 26 has a function of generating various timing signals such as a vertical and horizontal synchronization signal, a field shift gate signal, a vertical and horizontal timing signal, and an OFD (Over-Flow Drain) signal for the imaging unit 14. . This function generates various timing signals 94 according to the control signal 92 from the drive mode control unit 32. The timing signal generator 26 outputs various timing signals 92 to the driver 28. In particular, the timing signal generator 26 supplies a horizontal timing signal for driving the horizontal transfer path 46 to 2 outputs / 1 output to the driver 28 in accordance with the control signal 92. The timing signal generator 26 also has a function of generating various sampling signals and operation clocks used not only in the imaging unit 14 but also in each unit including the preprocessing unit 16, for example. The timing signal generator 26 supplies various sampling signals 96 to the drive mode control unit 32.

  The driver 28 has a function of generating vertical and horizontal drive signals corresponding to drive modes using various timing signals 94 supplied. The driver 28 supplies vertical and horizontal drive signals 98 to the imaging unit 14.

  The control unit 30 has a function of generating various control signals according to an operation signal 100 from the operation unit 34 described later. The control unit 30 includes a setting / operation correspondence control function unit 102 and a power determination control function unit 104, as shown in FIG. The setting / operation correspondence control function unit 102 acquires the operation signal 100 from the operation unit 34 as a setting condition, and generates various control signals according to the setting condition. Further, as shown in FIG. 12, the setting / operation correspondence control function unit 102 includes a 2-output / 1-output control function unit 106, a power supply / shut-off control function unit 108, a power saving control function unit 110, and a power capacity threshold setting. A functional unit 112 is included. The 2-output / 1-output control function unit 106 controls the output from the horizontal transfer path 46 to one of two outputs and one output in accordance with a moving picture mode setting, a continuous shooting speed setting, and a release shutter button pressing operation which will be described later. For example, the control signal 114 is output to the drive mode control unit 32 of FIG.

  The power supply / shutoff control function unit 108 has a function of generating a control signal for controlling power supply / shutdown in accordance with the control of the 2-output / 1-output control function unit 106. Further, the power saving control function unit 110 has a function of generating a control signal for controlling the normal voltage / voltage drop of the used voltage in accordance with the control of the 2-output / 1-output control function unit 106. For example, in the case of performing one output control, the power saving control function unit 110 may perform control so that power or voltage is reduced with respect to one output system to be operated and power to the output system to be stopped is further reduced. . This may be controlled by the power supply / shutoff control function unit 108. The power capacity threshold setting function unit 112 has a function of setting a power capacity threshold in advance, and supplies this setting to the power determination control function unit 104. The threshold value is supplied from the operation unit 34.

  The power determination control function unit 104 uses the power supply type, the threshold value, and the user setting as the determination conditions, and makes a determination based on at least one of the power supply type, the threshold value, and the user setting, and a combination to perform an operation according to the power. A control signal is generated.

  Returning to FIG. 1, the control unit 30 also generates a control signal 88 for operating the clock generator 24. Then, the control unit 30 generates a control signal 116 for each unit. Each unit corresponds to, for example, the input image adjustment unit 18, the correspondence array processing unit 20, the signal processing unit 22, the media control unit 36, and the like. In this way, the control unit 30 outputs the generated control signals 88, 102, and 104 to the above-described units via the clock generator 24, the drive mode control unit 32, and the bus 78, respectively.

  The drive mode control unit 32 generates a control signal 92 to the timing signal generator 26 according to the supplied control signal 114, and selects and supplies the sampling signal 96 from the timing signal generator 26 to the preprocessing unit 16. It has a function. The drive mode control unit 32 supplies the sampling signals 118 to 124 to the preprocessing unit 16. The drive mode control unit 32 controls the supply of sampling signals 118 to 124 for two CDSs and A / D converters (not shown).

  As shown in FIG. 13, the operation unit 34 is collectively expressed as a power switch 126, a zoom button 128, a menu display changeover switch 130, a selection key 132, a moving image mode setting unit 134, a continuous shooting speed setting unit 136, and a release. A shutter button 138 is included. The power switch 126 brings the digital camera 10 into power on / off. The zoom button 128 changes the angle of view of the field including the subject and adjusts the focal length of the subject according to the change. The menu display changeover switch 130 is a switch for moving a selection cursor by switching a menu displayed on the liquid crystal monitor, and includes, for example, a cross key. The selection key 132 is a key for selecting the selected menu item.

  The moving image mode setting unit 134 determines whether to display a moving image on the liquid crystal monitor, for example, by setting a flag value. With this setting, the digital camera 10 displays the scene image captured on the monitor 40 as a through image. The moving image mode setting unit 134 includes items for setting the resolution, the number of display frames, and the continuous shooting speed. The item of resolution is an item for selecting the resolution of the VGA (Video Graphics Array) standard which is, for example, the HDTV (High-Definition TeleVision) standard / standard. The number of display frames is an item for selecting either 30/15.

  The continuous shooting speed setting unit 136 is provided with a plurality of continuous shooting speeds and sets the speed for continuous shooting, and is set according to 2 outputs / 1 output. The continuous shooting speed is an item for setting the continuous shooting speed for an image having a certain number of pixels. With regard to the continuous shooting speed, the solid imaging device is operated with the former being set as one output and the latter being set as two outputs based on the setting of the number of continuous shots smaller than the threshold for the number of continuous shots and the number of continuous shots greater than this threshold.

  The release shutter button 138 has a function of selecting an operation timing and an operation mode of the digital camera 10 according to a half-press / full-press operation. The release shutter button 138 operates AE (Automatic Exposure) and AF (Automatic Focusing) in response to a half-press operation. In this operation, an appropriate aperture, shutter speed and focus distance are obtained using an image obtained by moving image display. Further, the release shutter button 138 sends a recording start / recording end timing to the control unit 30 by a full press operation, and provides an operation timing according to the setting mode of the digital camera 10. Setting modes include still image recording and moving image recording.

  The media control unit 36 has an interface control function for controlling recording / reproduction of image data in accordance with, for example, a recording medium to be handled. The media control unit 36 can control the writing / reading of the image data 140 to / from a PC (Personal Computer) card which is a semiconductor recording medium, and can control writing / reading with the built-in USB (Universal Serial Bus) controller. . The media 38 has various semiconductor card standards.

  As the monitor 40, a liquid crystal monitor or the like is used. The monitor 40 displays the image data 84 supplied from the signal processing unit 22.

  With this configuration, the operation of the digital camera 10 can be optimized according to whether or not the signal charge read from the horizontal transfer path 46 is 2 outputs / 1 output.

  Next, the operation of the digital camera 10 will be briefly described. As shown in FIG. 14, the digital camera 10 acquires preset setting conditions after power-on (step S10). It is determined whether the setting condition is HDTV (step S12). When HDTV is set as the resolution (YES), the process proceeds to the 2-output drive setting (to step S14). If VGA is set as the resolution (NO), the process proceeds to drive setting for one output (go to step S16).

  Next, the timing signal generator 26 is set to a two-output driving condition by the control signal 114 (step S14). In addition, this one-output drive setting sets the timing signal generator 26 to the one-output drive condition by the control signal 114 (step S16).

  The control unit 30 generates a control signal 114 for controlling the horizontal transfer of the imaging unit 14 with two outputs by the two-output / one-output control function unit 106 according to the conditions set for the two-output driving. The control signal 114 is output not only to the drive mode control unit 32 but also to the input image adjustment unit 18 and the corresponding array processing unit 20 (step S18). In particular, the drive mode control unit 32 is set to supply two systems of sampling signals 118 to 124 to the preprocessing unit 16 in response to inputs of two outputs.

  Further, the control unit 30 generates a control signal 114 for controlling the horizontal transfer of the imaging unit 14 with one output by the two-output / one-output control function unit 106 in accordance with the condition set for driving one output. The control signal 114 is output not only to the drive mode control unit 32 but also to the input image adjustment unit 18 and the corresponding array processing unit 20. The drive mode control unit 32 is set so as to supply one system of sampling signals 118 and 122 to the preprocessing unit 16 in response to an input of one output.

  After such setting, the object scene is imaged (step S22). The imaging unit 14 reads out the image signal obtained by the imaging with the number of outputs corresponding to the setting, and outputs it to the preprocessing unit 16. The preprocessing unit 16 performs noise removal and digitization (step S24). In particular, in the case of two outputs, the preprocessing unit 16 performs noise removal and digitization on the image signals 68 and 70 using the supplied sampling signals 118 to 124. Further, in the case of one output, the preprocessing unit 16 performs noise removal and digitization on the image signal 68 using the supplied sampling signals 118 and 122. In this case, the preprocessing unit 16 is slower than the previous two outputs and has the same processing speed as before.

  Next, in the case of one output, the image input adjustment unit 18 and the corresponding array processing unit 20 perform through processing on the supplied image data 72 and supply it to the signal processing unit 22. On the other hand, in the case of two outputs, the supplied image data 72 and 74 are simultaneously captured by the image input adjustment unit 18 and the captured image data 80 is rearranged by the corresponding array processing unit 20. As a result, the correspondence array processing unit 20 obtains one image and outputs the image data to the signal processing unit 22.

  The signal processing unit 22 performs synchronization and Y / C data processing according to the resolution based on the supplied image data 82 (step S28). The signal processing unit 22 displays the image data 84 converted for the liquid crystal monitor (step S30). After this display, it is determined whether or not to end (step S32). When the operation signal 100 for instructing the end is supplied (YES), the digital camera 10 ends the operation. If the operation signal 100 is continued or no instruction is given (NO), the operation is continued, and the series of processes described above are repeated after imaging (to step S22). Further, when the operation is continued, the process may return to the determination as to whether or not it is an HDTV (to step S12).

  When operated in this manner, an image signal can be read out from the imaging unit 14 at an optimum frame rate and displayed.

  Further, the digital camera 10 may be distinguished not only by the control according to the resolution but also by the frame rate to be displayed. This case is shown in FIG. In the subsequent procedures including FIG. 15, the same reference numerals are assigned to the same procedures as those in FIG. 14, and the description is omitted to avoid repeated description. In this case, after acquiring the setting condition, the digital camera 10 determines whether or not the frame rate is 30 frames / second (step S34). In the case of 30 frames / second (YES), the process proceeds to the 2-output drive setting (step S14). If 15 frames / second is set (NO), the process proceeds to drive setting for one output (step S16). In this way, the operation speed of signal charge reading may be distinguished by the vertical frequency. By applying this distinction, it is possible to deal with display restrictions of the monitor 40 and the like.

  Furthermore, the control of the digital camera 10 may be switched based on the continuous shooting speed. As shown in FIG. 16, after acquiring the setting condition, the digital camera 10 determines whether or not the continuous shooting speed is 5 frames / second or more (step S36). When the value is 5 frames / second or more (YES), the process proceeds to the 2-output drive setting (step S14). If a value smaller than 5 frames / second is set (NO), the process proceeds to drive setting for one output (step S16). As described above, it is preferable to distinguish the signal charge reading speed from the solid-state imaging device according to the continuous shooting speed related to the image reading speed. By applying this distinction, it is possible to cope with restrictions on image recording.

  FIG. 17 shows an embodiment in which power is controlled in accordance with the operation of the digital camera 10. Hereinafter, the same reference numerals are given to portions common to the previous embodiment, and the description thereof is omitted. The digital camera 10 of FIG. 17 characterizes this embodiment by disposing different components in the components of FIG. A different component is the power control unit 142.

  The power control unit 142 has a function of controlling power supply to the output gate (OG) and amplifier of the image sensor 44 and the CDS and A / D converter of the preprocessing unit 16 according to the control signal 144. The power control unit 142 controls power supply by at least power supply / cutoff of unused OGs and amplifiers in the image sensor 44 and power supply / cutoff of the CDS, A / D converter, amplifier, etc. of the preprocessing unit 16. To do. For this reason, the power control unit 142 includes a power supply line 146 that provides power supply / cut-off for OGs and amplifiers that are not used by the image sensor 44, and three power supply lines 148 to 152 for one system for the preprocessing unit 16, respectively. Connecting. The power control unit 142 has a built-in power changeover switch that operates according to the control signal 144, and controls power supply to the power supply lines 146 to 152. A power supply line that always supplies power is not shown. The control signal 144 is a signal for controlling the power supply of the preprocessing unit 16. The control signal 144 is generated by the power supply / cutoff control function unit 108 of the control unit 30.

  Further, the power control unit 142 is not limited to the power supply / cutoff control, and when controlling the output of the imaging unit 14 to one output system, the power control unit 142 is configured to stop the operation compared to the power supplied to the output system to be operated. The power supply to the output system may be set so as to be further reduced and actually operated.

  Although not shown, when the drive mode control unit 32 disclosed in the previous embodiment is not provided, the control unit 30 transmits the generated control signal 114 to the timing signal generator 26 as shown in FIG. Supply.

  The operation of the digital camera 10 of this embodiment will be described. After acquiring the setting conditions, it is determined whether or not there are two outputs (step S38). In the case of two outputs (YES), the process proceeds to a process of supplying all power to the preprocessing unit 16 (to step S40). In the case of one output (NO), the process proceeds to a process for shutting off the power supply to the output system (to step S42).

  Next, the power control unit 142 sets all the power supply to the output amplifier of the image sensor 44 and the preprocessing unit 16 to supply (step S40). In response to this control, the power control unit 142 uses the power control unit 142 to supply power to the output amplifier of the image sensor 44 and the preprocessing unit 16 only in one output system. It sets so that the power supply to the other output system in the output amplifier and the pre-processing unit 16 not to be cut off (step S42). Thereafter, the operation is performed in the same manner as in the previous embodiment.

  As a result, power consumption can be reduced as compared with the case where power is always supplied to the preprocessing unit 16.

  Further, the digital camera 10 may use the voltage variable function-equipped driver 28a of FIG. 19 in the configuration of FIG. The driver 28a with a variable voltage function shown in FIG. 19 has a function of varying the drive voltage in accordance with the supplied control signal 154. The driver 28a with a variable voltage function can vary the drive voltage from 16V to 5V, for example. The control signal 154 is generated by the power saving control function unit 110 of the control unit 30.

  The power saving control function unit 110 generates the control signal 154 so that the drive voltage is driven at 16 V / 5 V according to 2 outputs / 1 output.

  The operation in this case is shown in FIG. After acquiring the setting conditions, it is determined whether or not there are two outputs (step S38). In the case of two outputs (YES), the process proceeds to a process of supplying all power to the preprocessing unit 16 (to step S40). In the case of one output (NO), the process proceeds to the process of cutting off the power supply to the output system (to step S42).

  Next, the power control unit 142 sets all the power supply to the output amplifier of the image sensor 44 and the preprocessing unit 16 to supply (step S40). In response to this control, the power control unit 142 uses the power control unit 142 to supply power to the output amplifier of the image sensor 44 and the preprocessing unit 16 only in one output system. It sets so that the power supply to the other output system in the output amplifier and the pre-processing unit 16 not to be cut off (step S42).

  After controlling the supply of power, in the case of two outputs, the drive voltage of the image sensor 44 is set to 15 V (step S44). On the other hand, in the case of 1 output, the drive voltage of the image sensor 44 is set to 5 V (step S46). Thereafter, the operation is performed in the same manner as in the previous embodiment.

  With this operation, it is possible to further reduce the power consumption and prevent the backflow of charges in the image sensor 44.

  The power in the digital camera 10 is not limited to this configuration example, but can also be controlled by supplying / cutting off a clock signal to the CDS and A / D converter of the preprocessing unit 16. Since the CDS and the A / D converter do not operate due to the interruption of the clock signal, power consumption is not performed when the operation is stopped. In this case, the digital camera 10 is preferably configured as shown in FIG. In this embodiment, a power control unit 142 and a clock supply control unit 156 are included. The power control unit 142 controls only the power supply to the image sensor 44 by the power line 146.

  The clock supply control unit 156 has a function of controlling supply / cutoff of a sampling clock signal supplied to the CDS and A / D converter of the preprocessing unit 16. Clock signals 158 and 160 are supplied from the clock generator 24 or the timing signal generator 26 to the clock supply control unit 158. The clock supply control unit 158 operates according to the control signal 144 generated by the power saving control function unit 110. In particular, the clock supply control unit 158 connects the clock supply lines 162 and 164 to the CDS and A / D converters including those not used as operations. The clock supply control unit 158 has a changeover switch that switches supply / cutoff according to the control signal 144.

  The operation of the digital camera 10 will be described. As shown in FIG. 22, the digital camera 10 determines whether there are two outputs after acquiring the setting conditions (step S38). In the case of two outputs (YES), the processing proceeds to the supply processing of the clock signals 162 and 164 to the preprocessing unit 16 (to step S48). In the case of one output (NO), the process proceeds to the process of shutting off the supply of the clock signal of one output system (to step S50).

  Next, with two outputs, the clock signals 162 and 164 are supplied to the two-output systems to the preprocessing unit 16 (step S48). In one output, power is supplied to one output system, and the clock signal supply to the other output system is cut off (step S50).

  Next, the power control unit 142 sets all the output amplifiers of the image sensor 44 to supply (step S40). In addition, in the power control of one output, in response to this control, the power control unit 142 supplies power to the output amplifier of the image sensor 44 as only one output system, and power to the output amplifier not used by the image sensor 44 It sets so that supply may be interrupted (step S42).

  After controlling the power supply in this way, the operation is performed in the same manner as in the previous embodiment. This operation can further reduce power consumption.

  Further, the digital camera 10 may not only control the power consumption associated with the imaging operation, but also control the power according to the power capacity. FIG. 23 shows a configuration example in the latter power control.

  The digital camera 10 in FIG. 23 includes a remaining capacity determination unit 166 in addition to the configuration in FIG. In addition, the digital camera 10 includes components that are normally included, that is, a battery 168, an AC (Alternate Current) adapter 170, and a power supply unit 172. The remaining capacity determination unit 166 acquires, for example, the capacity threshold value from the power supply capacity threshold setting function unit 112 of the control unit 30, compares the remaining capacity of the battery 168 with the capacity threshold value, and determines whether or not the remaining capacity is satisfied. Has the function of The remaining capacity determination unit 166 exchanges the capacity threshold value and the determination result 174. The battery 168 is connected to the remaining capacity determination unit 166. In addition, a battery 168 and an AC adapter 170 are connected to the power supply unit 172. The power determination control function unit 104 of the control unit 30 generates the control signal 144 according to the determination result indicating whether or not the remaining capacity is satisfied.

  The operation in this case is shown in FIG. Although not shown in the procedure of FIG. 24, the power is turned on and the setting conditions are acquired in advance (step S10). After acquiring the setting conditions, it is determined whether or not the remaining capacity of the battery 168 is equal to or greater than the battery capacity threshold value 174 (step S52). When it is determined that the remaining capacity is equal to or greater than the battery capacity threshold value 174 (YES), the process proceeds to the power supply process (step S40). If it is determined that the remaining capacity is less than the battery capacity threshold value 174 (NO), the process proceeds to the power shut-off process (step S42). Although not shown, it is preferable to control the drive voltage output by the driver 28a as shown in FIG. The description of the subsequent procedure is omitted.

  By operating in this way, the battery life of the digital camera 10 can be extended.

  It is desirable that the digital camera 10 informs the user of the current process in order to keep the battery. For such notification, a predetermined symbol or character may be displayed on the monitor 40 under the control of the control unit 30. As a procedure, as shown in FIG. 25, after some settings for one output are completed, the control unit 30 instructs the monitor 40 to display power saving information after, for example, step S20 (step S54). . After instructing this display, a series of processes from imaging to display are sequentially performed. In each of these processes, in the display process, the monitor 40 displays that it is operating with power saving together with the captured object scene image. By checking this display, the user can know the current situation in which some of the processes in the digital camera 10 are slow. Since the user is alerted about the situation of the digital camera 10, the user can take pictures based on the situation where the digital camera 10 can take pictures.

  By the way, the digital camera 10 is not limited to the operation that gives priority to the situation of the digital camera 10 in this way, and may give priority to the user's intention. The procedure for handling the latter case is shown in FIG. In the procedure shown in FIG. 26, some procedures may be added between the determination in the case of making one output in FIG. 25 and the power interruption process.

  When controlling the digital camera 10 to one output, the control unit 30 informs the monitor 40 of the transition to the power saving mode and displays whether or not to approve the transition (step S56).

  The monitor 40 displays “Yes” indicating approval or “No” indicating prohibition. Upon receiving this display, the user moves the cursor and selects one with the selection key. When the transition to the power saving mode is prohibited (NO), the process is performed when there is sufficient power even though the remaining capacity of the battery 168 is small. That is, the digital camera 10 proceeds to the power supply process (to step S40). Further, when the transition to the power saving mode is permitted (YES), the process proceeds to the power cut-off process (to step S42).

  By operating in this way, each process is performed with priority given to the user's intention, and a flexible response process can be performed by increasing the degree of freedom of selection.

  The power supply in the digital camera 10 is either the battery 168 or the AC adapter 170 as shown in FIG. When the battery 168 is used, the digital camera 10 can provide convenience that is portable, but the operation time is limited by the battery life. Further, when using the AC adapter 170, the digital camera 10 is not limited to securing sufficient power and operating time. However, the digital camera 10 is limited to the range of the cable length that the AC adapter 170 has. Thus, the battery 168 and the AC adapter 170 have contradictory conveniences.

  When the digital camera 10 is operated while paying attention to the capacity of the power supply, if it is known which one of the battery 168 and the AC adapter 170 is used, it is effective in selecting two outputs / 1 output. Therefore, the digital camera 10 of FIG. 27 uses a power supply unit 172a with a connection detection function for the power supply unit 172 of FIG. The power supply unit with connection detection function 172a has a function of detecting whether the AC adapter 170 is connected or disconnected. The power supply unit with connection detection function 172a outputs the detection result to the control unit 30 by the flag 176. In the control unit 30, the power determination control function unit 104 generates the control signal 144.

  The operation of the digital camera 10 will be described. The operation procedure in FIG. 28 is obtained by adding connection determination of the AC adapter 170 to the operation procedure in FIG. 25 (step S60). In this procedure, the power supply unit with connection detection function 172a determines the connection of the AC adapter 170, and when this connection is detected, for example, outputs a flag 176 (“1”) to the control unit 30. When the power determination control function unit 104 receives the flag 176 (“1”) (YES), the control unit 30 proceeds to the two-output operation procedure because the power supply is sufficient (to step S40). Further, when it is determined that the AC adapter 170 is not connected, the power supply unit with connection detection function 172a outputs, for example, a flag 176 (“0”) to the control unit 30. When the power determination control function unit 104 receives the flag 176 (“0”) (NO), the process proceeds to a process for determining the remaining capacity of the battery 168 (step S52). Thereafter, the digital camera 10 operates according to the procedure shown in FIG.

  By operating in this way, it is possible to check the connection of the AC adapter 170 and always control the operation to two outputs, thereby speeding up the processing compared to one output.

  So far, a through image in the digital camera 10, that is, a moving image display on the monitor 40 has been disclosed. This moving image display is not recorded, and the digital camera 10 has specified processing as 2 outputs / 1 output mainly in accordance with image quality, readout speed (continuous shooting), power supply control, and the like.

  Incidentally, the 2-output / 1-output process in the digital camera 10 may be defined based on whether or not to record. The operation will be described using the digital camera 10 of FIG. A setting condition is acquired (step S10). After acquiring the setting conditions, it is determined whether or not non-recording is performed according to the setting conditions and the pressing operation of the release shutter button 138 (step S62). If the condition is moving image display or pressing operation is half-pressed and moving image shooting mode (YES), the process proceeds to the 2-output drive setting (to step S14). If the condition is the still image shooting mode and the pressing operation is in the fully pressed state (NO), the process proceeds to the one-output drive setting (to step S16). Thereafter, processing is performed in the same manner as described with reference to FIG. In this embodiment, non-recording corresponds to display and recording is also set. Therefore, the process of step S30 is a display / recording process. If the process is to be continued in the end determination (NO), the process returns to the non-recording determination process (to step S62). This is because the digital camera 10 is determined according to the pressing operation of the release shutter button 138 from the viewpoint of display / recording.

  The 2-output drive may be set for the through image, AE, and AF, or may be set for the through image and AE. In particular, as shown in FIGS. 30 and 31, it is desirable to use two outputs for the AE processing after the half-pressing operation (S1). Further, as shown in FIGS. 30 and 31, the driving of one output is preferably set to one output in the exposure and signal charge readout period after the full-pressing operation (S2). As shown in the timing chart of FIG. 31, the digital camera 10 may be set to drive one output during the AF process.

  By driving in this way, it is possible to operate in an appropriate operating environment according to the processing speed required in each mode, and it is possible to improve the image quality of an image that is appropriately obtained according to this operation.

1 is a block diagram illustrating a schematic configuration of a digital camera to which an imaging apparatus according to the present invention is applied. It is a top view which shows schematic structure of the image pick-up element used with the imaging part of FIG. FIG. 3 is a plan view illustrating an electrode configuration in the vicinity of a boundary between two horizontal transfer paths including a line memory in the image sensor of FIG. 2. FIG. 4 is a cross-sectional view when the image pickup device of FIG. 3 is cut along a broken line 3A-3A. FIG. 3 is a diagram illustrating driving for transferring signal charges in two left and right directions by two horizontal transfer paths in the image sensor of FIG. 2. FIG. 3 is a diagram for describing driving for transferring signal charges in one direction by two horizontal transfer paths in the image sensor of FIG. 2. FIG. 3 is a plan view illustrating another electrode configuration in the vicinity of a boundary between two horizontal transfer paths including a line memory in the image sensor of FIG. 2. It is sectional drawing at the time of cut | disconnecting the image pick-up element of FIG. 7 by the fracture | rupture line 7A-7A. It is a figure explaining the drive which transfers the signal charge by two horizontal transfer paths in the image pick-up element of FIG. It is a figure explaining the drive which transfers the signal charge by one horizontal direction by the two horizontal transfer paths in the image pick-up element of FIG. It is a functional block diagram which shows the schematic function in the control part of FIG. FIG. 12 is a functional block diagram illustrating control function units included in the setting / operation correspondence control function unit of FIG. 11; It is a figure which shows the structure of the operation part of FIG. 2 is a flowchart illustrating an operation procedure according to resolution in the digital camera of FIG. 1. 2 is a flowchart illustrating an operation procedure according to a frame rate in the digital camera of FIG. 1. It is a flowchart explaining the operation | movement procedure according to the continuous shooting speed in the digital camera of FIG. It is a block diagram which shows other schematic structures of the digital camera to which the imaging device which concerns on this invention is applied. 18 is a flowchart for explaining an operation procedure according to the number of outputs of the imaging unit in the digital camera of FIG. It is a block diagram which shows other schematic structures of the digital camera to which the imaging device which concerns on this invention is applied. 18 is a flowchart illustrating a procedure for setting and operating a drive voltage in accordance with the number of outputs of the imaging unit in the digital camera of FIG. It is a block diagram which shows other schematic structures of the digital camera to which the imaging device which concerns on this invention is applied. FIG. 22 is a flowchart illustrating a procedure for setting and operating a clock signal and power supply / cutoff according to the number of outputs of the imaging unit in the digital camera of FIG. It is a block diagram which shows other schematic structures of the digital camera to which the imaging device which concerns on this invention is applied. 24 is a flowchart for explaining an operation procedure for supplying / cutting off power according to the battery capacity in the digital camera of FIG. 24 is a flowchart for explaining an operation procedure for supplying / cutting off power according to the battery capacity in the digital camera of FIG. 24 is a flowchart for explaining an operation procedure for supplying / cutting off power according to the battery capacity in the digital camera of FIG. It is a block diagram which shows other schematic structures of the digital camera to which the imaging device which concerns on this invention is applied. 24 is a flowchart for explaining an operation procedure for supplying / cutting off power according to a power supply destination and a battery capacity in the digital camera of FIG. 2 is a flowchart illustrating an operation procedure according to whether recording is possible in the digital camera of FIG. 1. 2 is a timing chart for explaining the number of outputs and the operation in accordance with the operation of a release shutter button in the digital camera of FIG. 1. 2 is a timing chart for explaining the number of outputs and the operation in accordance with the operation of a release shutter button in the digital camera of FIG. 1.

Explanation of symbols

10 Digital camera
12 Optical system
14 Imaging unit
16 Pre-processing section
18 Input image adjustment section
20 Supported array processing section
22 Signal processor
24 clock generator
26 Timing signal generator
28 drivers
30 Control unit
32 Drive mode controller
34 Control panel

Claims (8)

An imaging apparatus in which an imaging means having a plurality of output means for generating an image signal based on a signal charge obtained by photoelectric conversion of incident light from an object scene and outputting the image signal is driven in accordance with an operation situation In the apparatus,
Control means for generating a control signal for controlling the operation of the imaging means in accordance with either a plurality of outputs or one output;
Timing generating means for generating a timing signal of the imaging means in response to the control signal;
Drive signal generating means for generating a drive signal in accordance with the timing signal;
Preprocessing means for removing noise and digitizing at least the image signals of the output system corresponding to the number of outputs of the output means;
Processing control means for controlling processing for each output system of the preprocessing means according to the control signal,
The control means determines whether the plurality of outputs is a second speed mode that is relatively faster than the first speed mode among the plurality of outputs and one output, and performs control according to the determination result Generate a signal,
The image processing apparatus, wherein the processing control unit controls processing to one output system in a first speed mode and controls processing to a plurality of output systems in a second speed mode.   The imaging apparatus according to claim 1, wherein the second speed mode is a standard having a resolution that is relatively higher than that of the first speed mode.   2. The image pickup apparatus according to claim 1, wherein the second speed mode is a frame rate standard that is relatively higher than that of the first speed mode.   2. The image pickup apparatus according to claim 1, wherein the second speed mode is a setting of a continuous number of continuous shots that is relatively higher than that of the first speed mode. In an imaging processing method for generating an image signal based on a signal charge obtained by photoelectric conversion of incident light from an object field, and outputting a plurality of the image signals by driving according to an operation state, the method includes:
A first step of acquiring preset conditions;
A second step of determining whether or not the acquired set condition includes any of the second speed modes that are relatively faster than the first speed mode, and generating a control signal according to the determination result;
A third step of setting generation of a timing signal for outputting a plurality of the image signals according to a determination result including the second speed mode;
A fourth step of setting generation of a normal timing signal for outputting only one of the image signals according to a determination result including the first speed mode;
A fifth step of setting at least noise removal and digitization to the image signals of the plurality of output systems supplied by the determination result including the second speed mode;
A sixth step of setting at least noise removal and digitization to the image signal of one output system supplied by the determination result including the first speed mode;
A seventh step of setting pixel changes in a normal dot-sequential manner by rearranging image data of a plurality of output systems supplied in a digitized manner based on a determination result including the second speed mode for each pixel;
An eighth step of setting the output of image data of one output system supplied in a digitized manner based on the determination result including the first speed mode,
An imaging processing method, wherein imaging is performed according to each of the settings, and the image data is obtained through the preprocessing.   6. The imaging processing method according to claim 5, wherein the second speed mode is a standard having a relatively higher resolution than that of the first speed mode.   6. The imaging processing method according to claim 5, wherein the second speed mode is a standard with a relatively higher frame rate than the first speed mode.   6. The imaging processing method according to claim 5, wherein the second speed mode is a setting of a number of continuous shots relatively higher than that of the first speed mode.

Images