JP3796269B2 - Electronic still camera and operation control method thereof - Google Patents

Description

[0001]
【Technical field】
The present invention relates to an electronic still camera having a continuous shooting memory and an operation control method thereof.
[0002]
[Prior art]
In an electronic still camera, image data obtained by shooting is temporarily stored in a frame memory inside the electronic still camera. The stored image data is compressed and then stored in an external storage device such as a memory card.
[0003]
A frame memory provided in a conventional electronic still camera has a capacity capable of storing image data for one frame (one picture). Also, every time one frame is shot, a sequence is taken in which image data obtained by shooting is compressed and stored in an external storage device. Even in the continuous shooting mode in which two or more frames are continuously shot, the next frame cannot be shot until the image data once stored in the frame memory is compressed and stored in the external storage device. It was.
[0004]
The time from shooting to storage of image data in the external storage device is about 700 [msec] even when the time required for exposure control is excluded when a memory card composed of SRAM is used as the external storage device. (It takes about 150 [msec] for data reading from CCD and signal processing, and about 550 [msec] for compression processing and card writing). About 1 [sec] when using a memory card composed of flash memory (about 150 [msec] for reading data from CCD and signal processing, and about 850 [msec] for compression processing and card writing, etc. ) Time.
[0005]
Therefore, the conventional electronic still camera cannot perform continuous photographing of two frames or more per second, and there is a problem that the user misses a shutter chance.
[0006]
DISCLOSURE OF THE INVENTION
An object of the present invention is to provide an electronic still camera and an operation control method thereof capable of performing continuous photographing at high speed.
[0007]
The electronic still camera according to the present invention is an electronic still camera in which a memory card is detachably mounted, and a plurality of frames of subjects are taken at predetermined time intervals while being shutter-released by a shutter-release button. Image capturing means for continuously capturing images and outputting video signals respectively representing a plurality of subject images obtained by the image capturing, and converting the image signals output from the image capturing means into digital image data suitable for storage in a memory Signal processing means for conversion, memory means having a capacity capable of storing digital image data for a plurality of frames converted by the signal processing means, and digital image data output from the signal processing means are output from the signal processing means. Write control means for controlling the memory means to write sequentially to the memory means each time, Data compression means for compressing the digital image data stored in the release means, and after the shutter release by the shutter release button is released, the compression means compresses the digital image data stored in the memory means. Compression / storage control means for storing the compressed digital image data for each frame in the memory card.
[0008]
An electronic still camera operation control method according to the present invention is an electronic device that includes a solid-state electronic image sensor, processes a video signal output from the solid-state electronic image sensor, and stores it in a detachably mounted memory card. In the still camera, while the shutter is released by the shutter release button, a plurality of frames of the subject image are continuously captured at predetermined time intervals, and the plurality of frames of the subject image are obtained from the solid-state electronic image sensor. Capacities capable of obtaining respective video signals, converting the video signals into digital image data suitable for storage in a memory, and storing the converted digital image data for a plurality of frames into digital image data for a plurality of frames Is written to the memory each time it is converted, and shutter release with the shutter release button After being divided, performs compression of the digital image data stored in the memory, the compressed digital image data is to stored in the memory card.
[0009]
Memory means or memory includes SRAM, DRAM, flash memory, optical memory, and the like.
[0010]
According to the present invention, while the shutter is released by the shutter release button, the subject images of a plurality of frames are continuously captured at predetermined time intervals. A plurality of subject images obtained by imaging are output as video signals from the solid-state electronic imaging device. The output video signal is converted into digital image data suitable for storage in the memory. The electronic still camera is provided with memory means having a capacity capable of storing digital image data for a plurality of frames. Digital image data for a plurality of frames is sequentially stored in the memory means. When the shutter release by the shutter release button is released, the digital image data stored in the memory means is compressed frame by frame. The compressed digital image data is stored in a memory card that is detachably attached to the electronic still camera.
[0011]
According to the present invention, in the continuous shooting operation, image processing by the solid-state electronic image sensor, reading of the video signal from the solid-state electronic image sensor, signal processing including conversion of the video signal to digital image data, and temporary storage of the image data to the memory The first half sequence consisting of memory is continuously repeated a plurality of times at regular time intervals. After the end of the first half sequence, the second half sequence consisting of compression of the image data and storage of the compressed image data in the memory card is executed for each frame. A relatively time-consuming second half sequence is postponed, and only the first half sequence is repeated continuously. Therefore, the time from imaging of one frame to imaging of the next frame is shortened, and high-speed continuous shooting is possible.
[0012]
By using a memory means that can store data at high speed, digital image data for each frame obtained by imaging can be stored quickly. This also shortens the time from the imaging of one frame to the imaging of the next frame.
[0013]
Preferably, the memory means is composed of a plurality of memories. The electronic still camera according to the present invention includes a plurality of connection means for mounting the plurality of memories. The connection means includes a connector and the like. Each of the memories is detachably connected to each of the plurality of connection means. Thereby, the user of the electronic still camera can increase or decrease the number of memories to be mounted according to the number of continuous shooting frames required. Also, the user can select the memory installation as an option.
[0014]
More preferably, the electronic still camera according to the present invention comprises means for determining the number of continuously shootable frames representing the number of frames of the subject image that can be stored in the memory means, display means for displaying the determined number of continuously shootable frames, And a display control means for decreasing the number of continuously shootable frames displayed on the display means one by one each time a subject image is taken.
[0015]
The number of continuously shootable frames representing the number of frames of the subject image that can be stored in the memory is obtained. The number of continuously shootable frames is displayed on the display means. Thereby, the user can easily know how many frames can be continuously shot in the continuous shooting mode. Further, the number of frames that can be continuously shot is decreased by one each time an image is taken. Thereby, the user can easily know how many remaining frames can be captured.
[0016]
Also, if the number of frames that can be continuously shot becomes 0, the digital image data obtained by the imaging cannot be stored in the memory. Therefore, the shutter release by the shutter release button is invalidated and the imaging (the first half sequence) is performed. It is preferable to stop.
[0017]
Further, the electronic still camera according to the present invention is a calculation means for calculating the number of remaining frames representing the number of frames of the subject image that can be stored in the memory card, and the display means for displaying the number of remaining frames calculated by the calculation means. And the display control means for reducing the number of remaining frames displayed on the display means one by one each time a subject image is taken.
[0018]
The number of remaining frames representing the number of frames of the subject image that can be stored in the memory card is calculated. The calculated number of remaining frames is displayed on the display means. Thus, the user can easily know how many frames of digital image data can be stored in the memory card in the continuous shooting mode. Further, every time an image is taken, the number of remaining frames is decreased by one. Therefore, the user can easily know how many frames can be captured.
[0019]
When the number of remaining frames becomes 0, the digital image data obtained by imaging cannot be stored in the memory card. Therefore, the shutter release by the shutter button is invalidated and imaging (the first half sequence) is stopped. It is preferable.
[0020]
[Explanation of Examples]
FIG. 1 is a block diagram showing an electrical configuration of an electronic still camera. This electronic still camera includes a memory card 19 (external storage medium) for storing image data representing a subject image shot in the single shooting mode and the continuous shooting mode, and a plurality of frames shot in the continuous shooting mode. Additional memory boards M1 to Mn (auxiliary memories attached as options) for temporarily storing image data representing the subject image are connected.
[0021]
The memory card 19 contains a semiconductor memory and is detachable from a connector C0 provided in the electronic still camera. The memory card 19 is electrically connected to various buses of the electronic still camera (memory controller 18) by being attached to the connector C0. The memory card 19 stores one frame of compressed image data (compressed image data) as one file. The number of bytes (length) of the compressed image data of each file is fixed to a fixed value (number of bytes T). The memory card 19 is provided with a directory for managing files and a FAT (File Allocation Table). In addition, the memory card 19 is provided with an area (date data area) for storing date data representing the date when image data of each file is captured in association with each file. The memory card 19 will generally be removed and installed by a user of an electronic still camera.
[0022]
The expansion memory boards M1 to Mn are detachable from connectors C1 to Cn provided on the electronic still camera, respectively. The expansion memory boards M1 to Mn are electrically connected to various buses of the electronic still camera by being attached to the connectors C1 to Cn, respectively. Each of the connectors C1 to Cn is numbered sequentially from 1 to n. Additional memory boards can be attached to all n connectors. An arbitrary number of additional memory boards of n or less can be attached to some connectors. When connecting additional memory boards to some of the connectors, it is promised that the additional memory boards will be installed in ascending order starting with connector C1 numbered 1.
[0023]
The expansion memory boards M1 to Mn are generally provided inside the electronic still camera. The additional memory boards M1-Mn will be installed mainly by the manufacturer of this electronic still camera. Of course, it can also be installed by the user.
[0024]
The additional memory board M1 has two frame memories 51 ₁ And 52 ₁ (SRAM, DRAM, flash memory, etc.), memory controller 53 provided corresponding to these frame memories ₁ And 54 ₁ And buffer memory 55 ₁ It has.
[0025]
Each frame memory has a storage capacity sufficient to store image data for one frame obtained by photographing. Therefore, the additional memory board M1 can store two frames of image data obtained by photographing.
[0026]
Buffer memory 55 ₁ Is frame memory 51 ₁ Or 52 ₁ Used to temporarily store image data to be written to or read from these frame memories. Memory controller 53 ₁ Is frame memory 51 ₁ Image data to frame memory and frame memory 51 ₁ Controls reading of image data from. Memory controller 54 ₁ Is frame memory 52 ₁ Write image data to frame memory 52 ₁ Controls reading of image data from.
[0027]
Memory controller 53 ₁ And 54 ₁ Each has a status register therein. A predetermined specific code (A) is set in these status registers. This code A is used when the compression CPU 23 confirms whether or not the additional memory board M1 is attached to the connector C1.
[0028]
The configuration of the other extension memory board Mi (i = 2 to n) is the same as that of the extension memory board M1. By connecting i expansion memory boards, 2i frames of image data can be stored in the entire expansion memory board.
[0029]
One frame memory is used to write image data to the frame memories 51i and 52i of these additional memory boards Mi (i = 1 to n) or read image data from these frame memories. Selected. This selection is performed by the compression CPU 23 selecting the corresponding memory controller (either 53i or 54i) through the selector 22.
[0030]
The operation of the electronic still camera is mainly controlled by the compression CPU 23, the display CPU 31 and the main CPU 37. These CPUs 23, 31 and 37 execute processing such as shooting and recording in a single shooting mode and a continuous shooting mode, which will be described later, while communicating with each other.
[0031]
The compression CPU 23 controls processing of image data obtained by photographing, controls writing of image data into the frame memories 17, 51i and 52i and reading from the frame memory, and processed image data (compressed image data). ) To the memory card 19 and reading from the memory card. The display CPU 31 controls the start and end of the photographing process based on the operation of various operation buttons and signals from the sensors and the display control, in particular, based on the operation of the shutter release button 35 by the user. The main CPU 37 performs automatic focusing (AF) control and automatic exposure (AE) control.
[0032]
The internal ROM of the compression CPU 23 stores programs and data necessary for shooting processing in advance. FIG. 6 shows data and programs stored in advance in the internal ROM of the compression CPU 23.
[0033]
The continuous-shootable frame number calculation program is a program for obtaining the number L of frames that can be continuously shot in the continuous shooting mode (hereinafter referred to as “the number of continuously-shootable frames”).
[0034]
When the shutter release button 35 is half-pressed, the compression CPU 23 obtains the number L of continuously shootable frames as follows in accordance with this continuous shootable frame number calculation program.
[0035]
First, the compression CPU 23 sequentially accesses the expansion memory boards M1 to Mn via the selector 22 and the connectors C1 to Cn, and the memory controller 53 of the expansion memory board Mi. _i And 54 _i Read the code A of the status register provided in The compression CPU 23 is a memory controller 53 _i And 54 _i The code read from the status register is compared with the reference code A stored in the internal ROM. If these codes match, the compression CPU 23 determines that the additional memory board Mi is connected. If they do not match (in many cases, the code A cannot be read from the memory controller because the additional memory is not connected), it is determined that it is not connected. The compression CPU 23 sequentially repeats the above-described processing from the additional memory boards M1 to Mn, and counts the number of connected additional memory boards (the count value is k). When it is determined for the first time that it is not connected, the count is stopped. In this way, the number k of additional memory boards connected is obtained.
[0036]
Subsequently, the compression CPU 23 obtains the value of the number L of continuously shootable frames based on the count value k. In the continuous shooting mode, the image data of the first frame is stored in the frame memory 17. The image data for the second frame and thereafter are stored in the additional memory boards M1 to M _k Are sequentially stored in each frame memory. Therefore, the number L of continuously shot frames when k additional memory boards are connected is L = 2 · k + 1. The number L of continuously shootable frames is given to the display CPU 31.
[0037]
The remaining frame number calculation program is a program for calculating the number N of image data frames (hereinafter referred to as “remaining frame number”) that can be stored in the memory card 19.
[0038]
The compression CPU 23 calculates the remaining frame number N according to the remaining frame number calculation program when the shutter release button 35 is half-pressed. First, the compression CPU 23 gives a FAT read command of the memory card 19 to the memory controller 18. The memory controller 18 reads FAT from the memory card 19 based on this command.
[0039]
When the memory card 19 is attached, the memory controller 19 gives the FAT read from the memory card 19 to the compression CPU 23. The compression CPU 23 obtains the free capacity of the memory card 19 based on the read FAT. Further, the compression CPU 23 refers to the number of bytes T of the compressed image data for one frame stored in advance in the internal ROM. The compression CPU 23 obtains the number N of remaining frames based on the number of bytes T for one frame and the obtained free space. The compression CPU 23 provides the display CPU 31 with data (mounting detection data) indicating the obtained number N of remaining frames and that the memory card 19 is mounted.
[0040]
When the memory card 19 is not attached, the memory controller 18 provides the compression CPU 23 with data indicating that the memory card 19 is not attached (non-attachment detection data). When the compression CPU 23 receives the non-loading detection data from the memory controller 18, the compression CPU 23 gives the non-loading detection data to the display CPU 31.
[0041]
The time α stored in the internal ROM of the compression CPU 23 represents the time that the compression CPU 23 uses as its internal timer after the shutter release button 35 performs the shutter release (the button 35 is fully pressed). Yes.
[0042]
During this time α, the display CPU 31 provides the compression CPU 23 with data necessary for photographing processing such as white balance data. The compression CPU 23 sets gain data necessary for image signal processing in the signal processing circuit 12 and the like.
[0043]
The time β represents an interval time between the shooting of one frame and the shooting of the next frame in the continuous shooting mode. The value of β is determined according to the number of frames continuously shot per second. For example, when three frames are continuously shot per second, β = 7 VD (1 VD = 1/60 seconds) is determined.
[0044]
The number of bytes S of one block is used when compressing image data obtained by imaging. Image data for one frame is divided into a plurality of blocks, and data compression is performed for each block according to an ADCT (Adaptive Discrete Cosine Transform) algorithm. The compressed data of each block is converted into a Huffman code. Thereafter, each block is adjusted to the length of this number of bytes S (fixed length processing). When the number of bytes of the block (encoded block) converted to the Huffman code is less than S, dummy data is added to the block so that the number of bytes becomes S. When the number of bytes of the encoded block exceeds S, the compression process and the Huffman encoding process are repeated until the number of bytes reaches S. The product of the number of bytes S and the number of divided blocks is the number of bytes T of image data for one frame.
[0045]
The single shooting mode program is a compression CPU shooting processing program executed in the single shooting mode. The continuous shooting mode program is a compression CPU imaging processing program executed in the continuous shooting mode. The contents of these two programs will be described in detail in the operation of the electronic still camera in the following single shooting mode and continuous shooting mode.
[0046]
Data used in the photographing process is stored in the internal RAM of the compression CPU 23. FIG. 7 shows data stored in the internal RAM of the compression CPU 23.
[0047]
The setting mode data is data representing the state of the continuous shooting / single shooting switch 36. When the continuous shooting / single shooting switch 36 is set to the single shooting mode, the setting mode data is data representing the single shooting mode. When the continuous shooting / single shooting switch 36 is set to the continuous shooting mode, the setting mode data is data representing the continuous shooting mode. When the shutter release button 35 is half-pressed, the display CPU 31 reads the state of the continuous / single shooting switch 36 and supplies the state of the switch 36 to the compression CPU 23 as setting mode data. The compression CPU 23 selects one of the single shooting mode program and the continuous shooting mode program in accordance with the setting mode data, and performs shooting processing.
[0048]
White balance data (WB data) is gain data set in a white balance adjustment circuit included in the signal processing circuit 12. The display CPU 31 obtains the value of the WB data based on the color detection signal of the color sensor 34. The WB data is given from the display CPU 31 to the compression CPU 23 during the time α after the shutter release.
[0049]
The imaging permission time zone γ represents a time zone in which imaging by the CCD 11 is permitted. This imaging permission time zone is determined based on the shutter speed (open time of the focal plane shutter 29) obtained by the main CPU 37 during the automatic exposure (AE) process. A time period obtained by rounding up the fraction less than 1 VD (1/60 seconds) of the opening time of the shutter 29 to an integer multiple of VD (n · VD; n is an integer) is defined as the imaging permission time zone γ. For example, when the opening time (shutter speed) of the shutter 29 is 0.3 VD or 0.5 VD, the imaging permission time zone γ is 1 VD. The shutter 29 is opened during this imaging permission time zone. The shutter speed (shutter speed data) is given from the main CPU 37 to the display CPU 31 and stored in the internal RAM of the display CPU 31. The shutter speed data is given from the display CPU 31 to the compression CPU 23 during the time α after the shutter release. The compression CPU 23 obtains an imaging permission time zone based on the shutter speed data and stores it in the internal RAM.
[0050]
The date data is data representing the current date that is measured by a real time clock 32 (real time clock; hereinafter referred to as “RTC”). During the time α after the shutter release is performed, the display CPU 31 reads the current date from the RTC 32 and supplies it to the compression CPU 23 as date data. When the compressed image data is stored in the memory card 19 as a file, the date data is stored in the date data area of the memory card 19 in association with the file.
[0051]
The continuous shooting number represents the number of frames shot in the continuous shooting mode. Each time one frame is shot, the compression CPU 23 increases the value of the number of continuously shot frames one by one in order. This number of continuously shot frames is used when compressing image data after shooting.
[0052]
In the internal ROM of the display CPU 31, as shown in FIG. 8 (A), a program necessary for photographing processing performed by the display CPU 31 is stored in advance. The single shooting mode program is a display CPU shooting processing program executed in the single shooting mode. The continuous shooting mode program is a display CPU imaging processing program executed in the continuous shooting mode. The contents of these two programs will be described in detail in the operation of the electronic still camera in the following single shooting mode and continuous shooting mode.
[0053]
Data used in the photographing process is stored in the internal RAM of the display CPU 31. FIG. 8B shows data stored in the internal RAM of the display CPU 31.
[0054]
The mounted / unmounted detection data is data indicating whether or not the memory card 19 is mounted. This data is given from the compression CPU 23 to the display CPU 31 when the shutter release button 35 is half-pressed as described above.
[0055]
The number N of remaining frames and the number L of frames that can be continuously shot are as described above, and are given from the compression CPU 23 to the display CPU 31. The setting mode data is data representing the state of the continuous shooting / single shooting switch 36 as described above. The shutter speed data is data representing the opening time of the shutter 29 and is given from the main CPU 37 to the display CPU 31.
[0056]
In an EEPROM 27 (Electrically Erasable Programmable ROM), the gain data of the gamma correction circuit included in the signal processing circuit 12, the gain data of the reproduction circuit 16, and the reference voltage of the A / D conversion circuit 13, as shown in FIG. Representing data is stored in advance. During the time α after the shutter release, these data are read out by the compression CPU 23 and converted into analog signals by the D / A conversion circuit 15, and then the signal processing circuit 12, the reproduction circuit 16 and the A / D. Each is supplied to the conversion circuit 13.
[0057]
[Operation of electronic still camera in single-shot mode]
When using the electronic still camera, the user turns on the power switch 47 provided in the electronic still camera. Thereby, an ON signal is given from the power switch 47 to the display CPU 31. Even when the power switch 47 of the electronic still camera is in the OFF state, the display CPU 31 is supplied with power by the auxiliary power circuit 26 (battery or the like), and the display CPU 31 is in the sleep state. In response to an ON signal from the power switch 47, the display CPU 31 starts from the sleep state and starts operating. First, the display CPU 31 turns on the power switch SW3. As a result, power is supplied from the main power supply circuit 25 to all circuits except the clock generator 24 (hereinafter referred to as “CG”) and the compression CPU 23.
[0058]
The user of the electronic still camera selects either the continuous shooting mode or the single shooting mode in advance with the continuous shooting / single shooting switching switch 36 when shooting. When the single shooting mode is selected, the processing shown in the time chart of FIG. 2 is performed.
[0059]
When the shutter release button 35 is half-pressed by the user, a half-press signal is given from the shutter release button 35 to the display CPU 31. Thereby, the display CPU 31 reads the state (setting mode / data) of the continuous shooting / single shooting switching switch 36 and stores the setting mode / data in the internal RAM. When the switch 36 is set to the single shooting mode, the display CPU 31 selects a single shooting mode program stored in advance in its internal ROM. When the switch 36 is set to the continuous shooting mode, the display CPU 31 selects a processing program in the continuous shooting mode stored in advance in its internal ROM. Here, since the single shooting mode is set, the display CPU 31 selects a single shooting mode program. The display CPU 31 performs single shooting mode processing according to this processing program.
[0060]
The display CPU 31 first turns on the switch SW1 of the power supply circuit 25. As a result, power is supplied to the compression CPU 23 and the compression CPU 23 is activated (time t1).
[0061]
Further, when the display CPU 31 receives the half-press signal, the display CPU 31 sends setting mode data (in this case, this data represents the single shooting mode) to the compression CPU 23, and at the same time, the number L of continuous frames and the number N of remaining frames. Is supplied to the compression CPU 23 (reference numeral 101 in FIG. 2). The compression CPU 23 stores the received setting mode data in the internal RAM (FIG. 7).
[0062]
In response to the request signal, the compression CPU 23 calculates the remaining frame number N according to the remaining frame number program. First, the compression CPU 23 turns on the switch SW2 of the power supply circuit 25 (time t2). As a result, power is supplied to a CG (Clock Generator) 24. By supplying power to the CG 24, the clock signal is converted into a Y / C processing circuit 14, a memory controller 18, and a compression / decompression circuit 21 (a common clock signal line from the CG 24 is connected to these three circuits. Is supplied). This allows these circuits to operate. As will be described later, when the reset signal supplied from the compression CPU 23 to the CG 24 is at a low level (L level), the CCD 11, the signal processing circuit 12, and the A / D conversion circuit even if power is supplied to the CG 24. No clock signal is given to 13.
[0063]
As described above, the compression CPU 23 obtains the number N of remaining frames (reference numeral 102).
[0064]
Subsequently, as described above, the compression CPU 23 obtains the number L of consecutively shootable frames according to the program for calculating the number of continuously shootable frames (reference numeral 102).
[0065]
The compression CPU 23 gives the obtained number L of continuous frames and the number N of remaining frames to the display CPU 31 (reference numeral 103). In addition, if the memory card 19 is attached, the compression CPU 23 gives data (attachment detection data) indicating that to the display CPU 31.
[0066]
The display CPU 31 stores the value of the number L of continuous frames, the number of remaining frames N, and mounting detection data in the internal RAM (FIG. 8B). The value of the remaining frame number N and the value of the continuously shootable frame number L are displayed on the display device 33 (liquid crystal display device or the like) (reference numeral 104 represents the display start time). The number N of remaining frames is indicated by the number N. When the number of remaining frames is 0, the number 0 is displayed. Similarly, the number L of consecutively shootable frames is indicated by the number L, and when L = 0, the number 0 is displayed.
[0067]
Thereafter, the compression CPU 23 selects a single shooting mode processing program based on the setting mode data stored in the internal RAM, and performs processing in the single shooting mode according to this program.
[0068]
When the memory card 19 is not attached, the memory controller 18 provides the compression CPU 23 with data indicating that the memory card 19 is not attached (non-attachment detection data). When the compression CPU 23 receives the non-loading detection data from the memory controller 18, the compression CPU 23 gives this data to the display CPU 31 (reference numeral 103). The display CPU 31 stores this data in the internal RAM. The display CPU 31 displays on the display device 33 that the memory card 19 is not installed. At this time, the number of remaining frames is not displayed.
[0069]
The display device 33 is attached to the surface of the body of the electronic still camera. The user can see from the outside of the electronic still camera that the remaining number of frames N displayed on the display device 33 or the memory card is not attached. When the number N of remaining frames is displayed, the user can know the number of frames that can be shot by viewing the number of remaining frames displayed. If it is displayed that the memory card 19 is not installed, the user will know that no memory card is installed and will install a memory card as needed.
[0070]
When these processes are completed, the compression CPU 23 turns off the power switch SW2 and stops supplying the clock signal to the memory controller 18 and the like (time t3).
[0071]
Further, the display CPU 31 gives the main CPU 37 a start command for automatic focusing (AF) processing and automatic exposure (AE) processing. When the main CPU 31 receives the AF and AE start commands, the AE-CPU 38 sends a photometry start command to the AF-CPU 41 and the AF and CPU 41 starts a ranging and focusing command according to the processing program stored in the internal ROM. Give each. Thereby, AE and AF are performed (reference numerals 105 and 106).
[0072]
The AE sensor 39 (photo diode, etc.) detects the brightness of the subject. A signal (brightness signal) representing the detected brightness is given to the AE-CPU 38. When receiving a photometric start command, the AE-CPU 38 takes in a brightness signal and obtains a photometric value based on this. This photometric value is given to the main CPU 37.
[0073]
The AE-CPU 38 determines whether the exposure is underexposed (the subject is too dark) or overexposed (the subject is too bright) based on the brightness signal. In the case of underexposure, the AE-CPU 38 displays an underexposure warning on the display device 40 (liquid crystal display device or the like) provided in the viewfinder. In the case of overexposure, the AE-CPU 38 displays an overexposure warning on the display device 40. The user can see this warning to know whether the exposure is underexposed or overexposed.
[0074]
The calculation of the photometric value and the warning display of overexposure or underexposure are performed according to a program stored in the internal ROM of the AE-CPU 38.
[0075]
The main CPU 37 obtains the aperture value and shutter speed (focal plane shutter 29 opening time) based on the given photometric value. The aperture value is given to the aperture controller 45. The aperture control device 45 controls the aperture 30 based on the given aperture value. Data representing the shutter speed (shutter speed data) is stored in the internal RAM of the main CPU 37. The shutter speed data is used to measure the time from opening to closing of the focal plane shutter 29.
[0076]
The shutter speed data is given from the main CPU 37 to the display CPU 31. The display CPU 31 stores the shutter speed data in its internal RAM (FIG. 8B).
[0077]
The lens CPU 42 determines the zoom position of the lens according to the processing program stored in the internal ROM. Data representing the zoom position is given to the AF-CPU 41. The AF sensor 44 detects the distance from the camera to the subject. Data representing this distance is given to the AF-CPU 41.
[0078]
When the AF-CPU 41 receives a ranging and focusing start command, it calculates a ranging value. For the calculation of the distance measurement value, data representing the zoom position of the lens from the lens CPU 42 and data representing the distance from the AF sensor 44 are used. The AF-CPU 41 drives the AF motor 43 based on the distance measurement value, adjusts the position of the lens, and focuses on the subject. When these processes are completed, the AF-CPU 41 gives a process completion notification to the main CPU 37. These processes of the AF-CPU 41 are performed according to programs stored in the internal ROM.
[0079]
When the AF control and the AE control are completed, the main CPU 37 gives an AF and AE completion notification to the display CPU 31. Further, the main CPU 37 commands the AE-CPU 38 to display the release permission on the display device 40. The AE-CPU 38 displays the release permission on the display device 40 in accordance with this instruction. Thereby, the user can know that the shutter release is possible.
[0080]
Upon receiving notification of completion of AF control and AE control from the main CPU 37, the display CPU 31 waits for input of a shutter release signal (full press signal) from the shutter release button 35. When receiving the full-press signal from the shutter release button 35, the display CPU 31 sets the release signal supplied to the compression CPU 23 to a high level (H level) (time t4). If the full-press signal from the shutter release button 35 has already been given to the display CPU 31 during the AF control and AE control, the display CPU 31 immediately sets the release signal to the H level.
[0081]
When the release signal supplied to the compression CPU 23 becomes H level, the compression CPU 23 turns on the power switch SW2 again (time t4). Further, the compression CPU 23 starts an internal timer and measures the time α (time t4).
[0082]
During this time α, the display CPU 31 creates WB data based on the color signal from the color sensor 34. The display CPU 31 reads the current date from the RTC 32. The display CPU 31 gives the compression CPU 23 the WB data, date, and shutter speed data obtained at the time of the AE control (reference numeral 107). The compression CPU 23 stores the WB data and date data in the internal RAM (FIG. 7). Further, the compression CPU 23 obtains the imaging permission time zone γ based on the shutter speed data, and stores this in the internal RAM (FIG. 7).
[0083]
During this time α, the compression CPU 23 obtains the gain data of the gamma correction circuit included in the signal processing circuit 12, the gain data of the reproduction circuit 16, and the reference voltage of the A / D conversion circuit 13 from the EEPROM 27. Represent data is read (FIG. 9). These data are converted into analog signals by the D / A conversion circuit 15 (electronic volume) and then set in the signal processing circuit 12, the reproduction circuit 16 and the A / D conversion circuit 13, respectively (reference numeral 108). The WB data given from the display CPU 31 to the compression CPU 23 is converted into an analog signal by the D / A conversion circuit 15 (electronic volume), and then set in the white balance adjustment circuit included in the signal processing circuit 12. (Reference numeral 108).
[0084]
A time sufficient for the display CPU 31 and the compression CPU 23 to perform the above processing is set as a time α.
[0085]
When the timer finishes counting the time α, the compression CPU 23 sets the reset signal given to the CG 24 to the H level (time t5). When this reset signal becomes H level, the CG 24 receives a horizontal transfer signal and a vertical transfer signal for the CCD 11, a clamp pulse signal for the signal processing circuit 12, a sampling clock signal for the A / D conversion circuit 13, The compression CPU 23 is supplied with a vertical synchronization reference signal (VD signal). The CG 24 continuously supplies a clock signal to the Y / C processing circuit 14, the memory controller 18, and the compression / decompression circuit 21 (including while the reset signal is at L level).
[0086]
The compression CPU 23 measures the time by counting the VD signal supplied from the CG 24 after the time α has elapsed. The compression CPU 23 sets the imaging permission time zone γ (FIG. 7) stored in the internal RAM to CG24 after the time 2VD has elapsed since the time α has elapsed (reference numeral 109).
[0087]
The CG 24 provides the CCD 11 with a stored charge sweep signal after a time of 3 VD has elapsed since the time α has elapsed. The CCD 11 sweeps out charges based on this signal. The sweeping process is performed to reset the CCD 11 before exposure.
[0088]
The CCD 11 is ready to store imaging charges after a time of 4 VD has elapsed from the elapse of time α (time t6). This state is maintained during the imaging permission time zone γ (a time that is an integral multiple of VD). The CG 24 counts the imaging permission time zone γ based on the imaging permission time zone γ set in the CG 24 by the compression CPU 23.
[0089]
Further, the compression CPU 23 sets the shutter signal to the H level when the time of 4 VD has elapsed after the elapse of time α (time t6). When the shutter signal becomes H level, the display CPU 31 gives a shutter opening command to the main CPU 37. When the main CPU 37 receives a shutter opening command from the display CPU 31, the main CPU 37 gives a shutter opening signal to the shutter control device 46. Thus, the shutter control device 46 opens the focal plane shutter 29.
[0090]
By opening the shutter 29, the subject image is formed on the surface of the CCD 11 through the imaging lens 28.
[0091]
The main CPU 37 measures the shutter opening time based on the shutter speed data stored in the internal RAM. Then, after the shutter opening time has elapsed since the shutter 29 was opened, the main CPU 37 gives a shutter closing signal to the shutter control device 45. As a result, the shutter control device 45 closes the shutter 29. As described above, a time longer than the time during which the focal plane shutter 29 is open (shutter open time) is set as the imaging permission time zone. Therefore, the focal plane shutter 29 is opened and closed during this imaging permission time period.
[0092]
The CG 24 gives a charge transfer signal to the CCD 11 after the imaging permission time zone γ (an integral multiple of VD) has elapsed (time t7). As a result, an analog video signal representing each pixel of the subject image is read from the CCD 11 and applied to the signal processing circuit 12. When the CCD 11 has 1280 × 1024 pixels (about 1.3 million pixels), it takes 8 VD to read out the analog video signals for all the pixels from the CCD 11.
[0093]
The signal processing circuit 12 includes a white balance adjustment circuit and a gamma correction circuit. The video signal input from the CCD 11 to the signal processing circuit 12 is subjected to white balance adjustment and gamma correction by these circuits (reference numeral 111). Particularly, since the level range of the video signal is narrowed by the gamma correction, the A / D conversion circuit 13 having a small number of bits can be used.
[0094]
The analog video signal output from the signal processing circuit 12 is supplied to the A / D conversion circuit 13 and converted into digital image data (reference numeral 111). This digital image data is given to the Y / C processing circuit 14. The Y / C processing circuit 14 controls the luminance image data Y and the color image data (the color difference data RY and BY dot-sequentially) from the digital image data supplied from the A / D conversion circuit 13 under the control of the compression CPU 23. Data) C is generated.
[0095]
The compression CPU 23 instructs the memory controller 18 to capture image data. Thus, the generated luminance image data Y and color image data C are taken into the memory controller 18 and stored in the frame memory 17 (DRAM, SRAM, etc.) (reference numeral 111).
[0096]
While the video signal from the CCD 11 is being processed, the compression CPU 23 updates the directory and FAT of the memory card 19 in order to store the image data obtained by photographing (reference numeral 110). When this process ends, the compression CPU 23 sets the shutter signal to the L level (time t8).
[0097]
When the shutter signal becomes L level, the display CPU 31 provides a shutter 29 winding signal (shutter charge signal) to the shutter control device 46 via the main CPU 37. With this signal, the shutter control device 46 winds up the shutter 29 and prepares for the next shooting.
[0098]
Further, when the shutter signal becomes L level, the display CPU 31 gives a compression command to the compression CPU 23 (reference numeral 112).
[0099]
When receiving the compression command, the compression CPU 23 gives a read command for the image data stored in the frame memory 17 to the memory controller 18. As a result, the luminance image data Y and the color image data C stored in the frame memory 17 are read out by the memory controller 18 and supplied to the compression / expansion circuit 21. Further, the compression CPU 23 gives the compression command and data representing the number of bytes S used in the fixed length processing to the compression / expansion circuit 21.
[0100]
The compression / decompression circuit 21 divides the image data Y and C into a plurality of blocks and performs ADCT conversion for each block (reference numeral 113). These data (block data) subjected to the ADCT conversion are stored again in the frame memory 17 by the memory controller 18. Subsequently, the block data is again applied from the frame memory 17 to the compression / decompression circuit 21 and is Huffman encoded for each block.
[0101]
In the compression / decompression circuit 21, the Huffman-encoded block data (encoded block data) is adjusted to data having a length of S bytes given from the compression CPU 23 (fixed length processing). When the number of bytes of the encoded block data is less than the length S, dummy data is added to the encoded block data and converted to the length S. When the length of the encoded block data exceeds the length S, the compression and encoding processes are repeated again until the length becomes equal to or shorter than the length S, and dummy data is added as necessary (reference numeral 113). ).
[0102]
The image data subjected to the compression, encoding and fixed length processing in this way is stored in the memory card 19 by the memory controller 18 (reference numeral 114). In addition, the compression CPU 23 gives the date data stored in the internal RAM to the memory controller 18. The memory controller 18 stores the date data in the date data area of the memory card 19 in association with the image data (file) (reference numeral 114).
[0103]
Thereafter, post-processing (processing such as releasing a mechanism for preventing the memory card from being removed while data is being written to the memory card) is performed (reference numeral 114).
[0104]
Further, the compression CPU 23 turns off the power switch SW2 and sets the reset signal to the CG 24 to L level. Further, the display CPU 31 turns off the power switch SW1 and sets the release signal to L level. As a result, the electronic still camera enters a standby state for the next photographing (time t9).
[0105]
If the value of the remaining frame number N (remaining frame number N displayed on the display device 33) stored in the internal RAM of the display CPU 31 is 0, or the memory card 19 is not loaded, the shutter release is performed. Even if the shutter release signal from the button 35 is given to the display CPU 31, the display CPU 31 ignores this signal. That is, in this case, even if the shutter release button 35 is used for shutter release, the display CPU 31 does not set the release signal to the H level. Thereby, the compression CPU 23 does not set the shutter signal to the H level. Therefore, even if the user performs shutter release, photographing processing (processing such as opening and closing of the shutter and capturing of a video signal) is not performed.
[0106]
The reproduction circuit 16 converts the luminance image data Y and the color image data C into NTSC signals. The NTSC signal from the reproduction circuit 16 is sent to an external display device (CRT display device or the like) or recording device (VTR or the like) connected to the electronic still camera. When the NTSC signal is sent to the display device, the captured image is reproduced on the display screen. When the NTSC signal is sent to the VTR, it is recorded on a magnetic tape or the like. The image data before compression stored in the frame memory 17 can be supplied to the reproduction circuit 16. The compressed image data stored in the memory card 19 can be decompressed by the compression / expansion circuit 21 and then given to the reproduction circuit 16. Also, the image data output from the Y / C processing circuit 14 can be input to the reproduction circuit 16. These will be switched by a playback mode setting switch (not shown).
[0107]
[Operation of electronic still camera in continuous shooting mode]
When the continuous shooting mode is selected by the continuous shooting / single shooting switching switch 36, the processing of the continuous shooting mode shown in the time charts of FIGS. 3 to 5 is performed. A process when three frames are continuously shot is shown. The continuation of FIG. 3 is shown in FIG. The continuation of FIG. 4 is shown in FIG. The same processes as those in FIG. 2 are denoted by the same reference numerals.
[0108]
The compression CPU 23 and the display CPU 31 select a continuous shooting processing program (FIG. 6 and FIG. 8A) stored in advance in each internal ROM based on the setting mode data, and perform the continuous shooting mode processing.
[0109]
The processing at the times t1 to t4 is the same as the processing in the single shooting mode described above, and therefore the description thereof is omitted here.
[0110]
The display CPU 31 maintains the release signal at the H level while the user is performing shutter release (full pressing) with the shutter release button 35.
[0111]
From time t5 to t8, the first frame is shot, and the image data obtained by this shooting is processed and stored in the frame memory 17. The difference from the processing shown in FIG. 2 is that the compression CPU 23 does not update the directory and FAT of the memory card 19 during the processing of the image data (there is no processing indicated by reference numeral 110). The compression CPU 23 writes 1 in the area of the number of continuously shot frames in the internal RAM during the processing of the image data (reference numeral 130) (FIG. 7).
[0112]
When the writing of the image data to the frame memory 17 is completed, the compression CPU 23 sets the shutter signal to the L level (time t8).
[0113]
When the shutter signal becomes L level, the display CPU 31 decreases the value of the number L of continuously shootable frames and the number N of remaining frames stored in the internal RAM by 1, respectively. Further, the display CPU 31 decrements the values of the number L of continuously shootable frames and the number N of remaining frames displayed on the display device 33 by 1 (reference numeral 118).
[0114]
The compression CPU 23 sets the shutter signal to L level, and then measures the time β (FIG. 6) stored in advance in the internal ROM. The compression CPU 23 measures the time β by counting the VD signal given from the CG 24.
[0115]
After a further time of 3VD has elapsed since the time β has elapsed, the compression CPU 23 sets the imaging permission time zone to CG24 (reference numeral 116). This process is the same as the process denoted by reference numeral 109. As the imaging permission time zone to be set, the same one as that at the time of photographing the first frame (stored in the internal RAM of the compression CPU 23) is used as it is. In the continuous shooting mode, AE and AF are performed prior to shooting of the first frame, and thereafter AE and AF are not performed.
[0116]
When the time of 4 VD further elapses after the elapse of time β, the compression CPU 23 sets the shutter signal to the H level (time t11). As a result, the second frame is shot. The exposure processing, the reading of the video signal from the CCD 11, and the processing by the signal processing circuit 12, the A / D conversion circuit 13 and the Y / C processing circuit 14 (reference numeral 117) are the same as the first frame processing indicated by the reference numeral 111. It is.
[0117]
The compression CPU 23 increases the value of the number of continuously shot frames stored in the internal RAM by 1 to 2 (reference numeral 131).
[0118]
The display CPU 31 decreases the value of the number of remaining frames N and the value of the number L of consecutive frames that can be stored in the internal RAM by 1 (reference numeral 121). Further, the display CPU 31 decreases each of the values displayed on the display device 33 by one.
[0119]
The image data output from the Y / C processing circuit 14 passes through the buffer memory 20 and the connector C1, and the buffer memory 55 of the additional memory board M1. ₁ Given to. The compression CPU 23 passes through the selector 22 to the memory controller 53 of the additional memory board M1. ₁ Is given a command to import image data. This command causes the memory controller 53 ₁ The buffer memory 55 ₁ The image data given to the frame memory 51 ₁ (Reference numeral 117).
[0120]
Thereafter, the time β is measured and preparation for photographing the third frame is performed (reference numeral 119 in FIG. 4, sweeping out the charge of the CCD 11). Thereafter, the third frame is shot (time t15). The compression CPU 23 passes through the selector 22 to the memory controller 54 of the additional memory board M1. ₁ Is given a command to import image data. This command causes the memory controller 54 ₁ The buffer memory 55 ₁ The image data of the third frame given to the frame memory 52 ₁ (Reference numeral 120).
[0121]
The compression CPU 23 increases the value of the number of continuously shot frames stored in the internal RAM by 1 to 3 (reference numeral 132).
[0122]
The values of the number of remaining frames N and the number of continuously shootable frames L stored in the internal RAM of the display CPU 31 are each decreased by 1 (reference numeral 122). Each of these values displayed on the display device 33 is also decreased by one.
[0123]
Thereafter, when the user releases the shutter release of the shutter release button 35, the display CPU 31 sets the release signal to the L level (time t17). As a result, the compression CPU 23 knows that continuous shooting has stopped, and thereafter stops setting the shutter signal to the H level. As a result, the fourth and subsequent frames are not shot.
[0124]
The display CPU 31 sets the release signal to L level and then gives a compression command to the compression CPU 23 (reference numeral 123).
[0125]
Upon receiving this compression command, the compression CPU 23 updates the directory and FAT of the memory card 19 in order to store the image file having the number of continuously shot frames (here, 3) stored in the internal RAM (reference numeral 124). ).
[0126]
Subsequently, the compression CPU 23 performs compression processing on the image data stored in the frame memory based on the number of continuously shot frames. Here, since the value of the number of continuous shot frames is 3, the frame memories 17 and 51 ₁ And 52 ₁ The image data stored in is the processing target.
[0127]
First, the image data stored in the frame memory 17 is given to the compression / decompression circuit 21. The image data given to the compression / decompression circuit 21 is subjected to compression, Huffman coding, and fixed length processing. The compressed image data is stored in the memory card 19 (reference numeral 125 in FIG. 4). The date data stored in the internal RAM of the compression CPU 23 is associated with the compressed image data (file) and stored in the date data area of the memory card 19 (reference numeral 125).
[0128]
Next, the frame memory 51 of the expansion memory board M1 ₁ Is compressed, Huffman encoded and fixed-length processed by the compression / expansion circuit 21 and stored in the memory card 19 (reference numeral 126 in FIGS. 4 to 5). Date data is also stored in the memory card 19 (reference numeral 126). Next, the frame memory 52 of the additional memory board M1 ₁ Is compressed, Huffman encoded and fixed-length processed by the compression / expansion circuit 21, and stored in the memory card 19 (reference numeral 127 in FIG. 5). Date data is also stored in the memory card 19 (reference numeral 127).
[0129]
Thereafter, post-processing (processing such as releasing a mechanism for preventing the memory card from being removed while data is being written to the memory card) is performed (reference numeral 123). After finishing the post-processing, the compression CPU 23 sets the reset signal to the CG 24 to the L level. Further, the compression CPU 23 turns off the switch SW2, and stops the power supply to the CG 24. Further, the compression CPU 23 sets the shutter signal to H level to notify the display CPU 31 that the recording of the image data on the memory card 19 is completed (time t18).
[0130]
When the display CPU 31 receives a notice of completion of recording of the image data in the memory card 19, the display CPU 31 turns off the switch SW1 and stops the power supply to the compression CPU 23 (time t19). As a result, the electronic still camera enters a standby state for the next shooting.
[0131]
Even in the continuous shooting mode, when the value of the remaining frame number N is 1, the number 1 is displayed on the display device 33. When the value of the number N of remaining frames becomes 0, the number 0 is displayed on the display device 33. Further, when the value of the number L of continuously shootable frames is 1, the number 1 is displayed on the display device 33. When the value of the number L of continuously shootable frames becomes 0, the number 0 is displayed on the display device 33.
[0132]
In the continuous shooting mode, when the value of at least one of the remaining frame number N and the continuous shooting possible frame number L becomes 0 during shooting, the shutter release signal from the shutter release button 35 is received. Even if given to the display CPU 31, the display CPU 31 ignores this signal. Thus, even when shutter release is performed by the shutter release button 35, the electronic still camera does not perform the photographing operation. The display CPU 31 sets the release signal given to the compression CPU 23 to the L level and gives a compression command to the compression CPU 23. The image data of one or a plurality of frames obtained by shooting until the shooting operation is stopped is read from the frame memory and subjected to compression, Huffman coding, and fixed length processing. The processed image data is stored in the memory card 19. Thereafter, post-processing is performed, and the electronic still camera enters a standby state.
[0133]
In continuous shooting, when the frame memory of all the installed additional memory boards is full, the number L of frames that can be continuously shot becomes zero. As described above, the continuous shooting operation is stopped, and the image data stored in the frame memory is compressed and stored in the memory card. When the image data of one or more frame memories in the expansion memory board is read and the image data can be stored in these frame memories, the shutter release button 35 is set in the continuous shooting mode. Even if is fully pressed, no shooting operation is performed. That is, the next shooting cannot be performed until the compression of the image data stored in all the frame memories and the storage to the memory card are completed.
[0134]
Even when the memory card 19 is not attached, the display CPU 31 ignores the shutter release signal from the shutter release button 35 as described in the processing in the single shooting mode.
[0135]
It is also possible to obtain shutter speed data by performing AE for each frame shot in the continuous shooting mode. The imaging permission time zone γ can be obtained based on the shutter speed data, and this time γ can be set in the CG 24 every time each frame is shot.
[0136]
In the above embodiment, a mechanical shutter is provided, but it goes without saying that an electronic shutter whose shutter speed is defined by the drive of the CCD (time from charge sweeping to accumulated charge reading) can also be used. .
[Brief description of the drawings]
FIG. 1 is a block diagram showing an electrical configuration of an electronic still camera.
FIG. 2 is a time chart showing processing of an electronic still camera in single shooting mode.
FIG. 3 is a time chart showing processing of the electronic still camera in continuous shooting mode.
FIG. 4 is a time chart showing processing of the electronic still camera in continuous shooting mode.
FIG. 5 is a time chart showing processing of the electronic still camera in continuous shooting mode.
FIG. 6 shows the contents of the internal ROM of the compression CPU.
FIG. 7 shows the contents of the internal RAM of the compression CPU.
8A shows the contents of the internal ROM of the display CPU, and FIG. 8B shows the contents of the internal RAM of the display CPU.
FIG. 9 shows the contents of an EEPROM.
[Explanation of symbols]
11 CCD (solid-state electronic image sensor)
12 Signal processing circuit
13 A / D converter circuit
14 Y / C processing circuit
15 D / A converter circuit
16 Playback circuit
17, 51 ₁ ~ 51 _n , 52 ₁ ~ 52 _n Frame memory
18, 53 ₁ ~ 53 _n , 54 ₁ ~ 54 _n Memory controller
19 Memory card
20, 55 ₁ ~ 55 _n Buffer memory
21 Compression / decompression circuit
22 Selector
23 Compression CPU
24 Clock generation circuit (clock generator)
25 Main power circuit
26 Auxiliary power circuit
28 Imaging lens
29 Focal plane shutter
30 aperture
31 display CPU
32 Real time clock
35 Shutter release button
36 Continuous / Single-shot switch
37 Main CPU
43 AF motor
M1 to Mn expansion memory board
C0 to Cn connector

Claims (5)

In an electronic still camera in which a memory card is detachably mounted,
While the shutter is released by the shutter release button, a plurality of frames of the subject image are continuously captured at predetermined time intervals, and a video signal representing each of the plurality of frames of the subject image obtained by the imaging is output. Imaging means,
Signal processing means for converting a video signal output from the imaging means into digital image data suitable for storage in a memory;
Memory means having a capacity capable of storing digital image data of a plurality of frames converted by the signal processing means;
Write control means for controlling the digital image data output from the signal processing means to be sequentially written in the memory means each time it is output from the signal processing means;
Data compression means for compressing the digital image data stored in the memory means;
Means for obtaining the number of continuously shootable frames representing the number of frames of the subject image that can be stored in the memory means;
When the number of frames that can be continuously shot is 1 or more, after the shutter release by the shutter release button is released, the compression means compresses the digital image data stored in the memory means for each frame. Compression / storage control means for storing the obtained digital image data in the memory card frame by frame
When the number of frames that can be continuously shot is 0, the shutter release by the shutter release button is forcibly disabled, the imaging is stopped, and the compression means compresses the digital image data stored in the memory means. Imaging / compression / storage control means for storing compressed digital image data in the memory card for each frame,
Calculating means for calculating the number of remaining frames representing the number of frames of the subject image that can be stored in the memory card ;
Display means for displaying the number of continuously shootable frames calculated by the means for determining the number of continuously shootable frames and the number of remaining frames calculated by the calculating means; and
Display control means for decreasing the number of continuously shot frames and the number of remaining frames displayed by the display means one by one each time a subject image is captured ;
Electronic still camera equipped with. The memory means comprises a plurality of memories;
A plurality of connection means for mounting a plurality of the memories respectively;
Each of the memories is detachably connected to each of the plurality of connection means.
The electronic still camera according to claim 1. When the number of remaining frames becomes 0, the second shutter control unit is configured to disable the shutter release by the shutter release button and stop the imaging.
The electronic still camera according to claim 1 or 2. In an electronic still camera comprising a solid-state electronic image sensor and processing a video signal output from the solid-state electronic image sensor and storing it in a detachably mounted memory card,
While the shutter is being released by the shutter release button, a plurality of frames of the subject image are continuously captured at predetermined time intervals, and video signals representing the plurality of frames of the subject image are respectively output from the solid-state electronic image sensor. Get
The above video signal is converted into digital image data suitable for storage in memory,
The converted digital image data for a plurality of frames is sequentially written to a memory having a capacity capable of storing the digital image data for a plurality of frames each time it is converted.
Find the number of frames that can be taken continuously, representing the number of frames of the subject image that can be stored in the memory
When the number of frames that can be continuously shot is 1 or more, after the shutter release by the shutter release button is released, the digital image data stored in the memory is compressed, and the compressed digital image data is stored in the memory card. Remember,
When the number of frames that can be continuously shot is 0, the shutter release by the shutter release button is forcibly disabled, the imaging is stopped, the digital image data stored in the memory is compressed, and the compressed digital image data is Memorize in the above memory card,
Calculate the remaining number of frames representing the number of frames of the subject image that can be stored in the memory card,
The calculated number of frames that can be taken continuously and the calculated number of remaining frames are displayed on the display screen.
Each time a subject image is captured, the number of frames that can be taken continuously and the number of remaining frames are decreased by one .
Electronic still camera operation control method. Exposing a solid-state electronic image sensor, reading out a video signal from the solid-state electronic image sensor, signal processing including conversion of the video signal into digital image data, temporary storage of digital image data in a memory, and storing image data in the memory In an electronic still camera that executes a series of shooting and recording sequences consisting of reading from and compressing, and storing compressed image data in a memory card,
The first half sequence consists of the above exposure, readout, signal processing and temporary storage,
The latter half sequence consists of the above compression processing and storage,
While the shutter release is being performed by the shutter release button, the first half sequence is continuously executed at regular time intervals to obtain image data of a plurality of frames temporarily stored in the memory,
Find the number of frames that can be shot continuously, representing the number of frames that can be stored in the memory
When the number of frames that can be shot continuously is 1 or more, after the shutter release is released by the shutter release button, the second half sequence is executed for each frame of image data.
When the number of frames that can be continuously shot is 0, the first half sequence is forcibly terminated, and the second half sequence is started.
Calculate the remaining number of frames representing the number of frames of the subject image that can be stored in the memory card,
The calculated number of frames that can be taken continuously and the calculated number of remaining frames are displayed on the display screen.
Each time the first half sequence for one frame is executed, the displayed number of continuous shots and the number of remaining frames are decreased by one .
Electronic still camera operation control method.

Images