JP2008065851A - Information processing apparatus and recording medium - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an information processing apparatus in which operability of portable devices is improved. <P>SOLUTION: A display area C is virtually set at a position L1 in a recorded image, when an electronic camera is rotated in a prescribed direction around a Y-axis while an image within the display area C is displayed on the screen of an LCD 6, the display area C is virtually moved into the recorded image. When moved to a position L2, the image at the position L2 within the display area C is displayed on the screen of the LCD. By performing an operation for rotating the electronic camera around a Y-axis a plurality of times, the display area C moves an optional position on the recorded image. For example, the invention is applicable to a portable device such as a digital camera. <P>COPYRIGHT: (C)2008,JPO&INPIT

Description

  The present invention relates to an information processing apparatus and a recording medium, and for example, relates to an information processing apparatus and a recording medium in which an image displayed on a screen of the apparatus is scrolled or zoomed by moving or rotating the entire apparatus.

  Conventionally, when scrolling an image displayed on a screen or moving a cursor, a pointing device such as a joystick or a mouse is used. By moving the joystick in any direction, the image can be scrolled in any direction. In addition, the cursor displayed on the screen can be moved in any direction. Similarly, by moving the mouse in an arbitrary direction, the image displayed on the screen can be moved in an arbitrary direction, and the cursor displayed on the screen can be moved in an arbitrary direction.

  However, when scrolling the image displayed on the screen of the mobile device or moving the cursor in the menu screen, it may be possible to incorporate a joystick or the like into the mobile device. There was a problem that could not be said.

  The present invention has been made in view of such a situation, and makes it possible to easily operate an image or a menu screen displayed on a screen of a mobile device.

  An information recording apparatus according to one aspect of the present invention includes a display unit that displays at least one of an image, a character, and a graphic; a detection unit that detects at least one of movement and rotation of the display unit; Display changing means for changing display contents displayed on the display means in accordance with at least one of movement and rotation of the display means detected by the detecting means, and the display changing means comprises the display The display content displayed on the display means is changed according to the amount of movement or the amount of rotation due to the movement or rotation of the means a plurality of times.

  The information processing apparatus further includes an imaging unit that captures an image of a predetermined subject, and the detection unit detects at least one of movement and rotation of the display unit based on an output of the imaging unit. be able to.

  The display unit displays a menu screen on which a predetermined selection item is displayed, and the display change unit displays the selection item according to the movement or rotation of the display unit detected by the detection unit. The display of the menu screen can be changed so that a predetermined item is selected.

  The information processing apparatus may further include a prohibiting unit that prohibits the display changing unit from changing a display content displayed on the display unit.

  The display change means displays the display content displayed on the display means in response to detecting at least one of movement and rotation of the display means based on the highest contrast portion of the image being captured. The information processing apparatus is further provided with illumination means for irradiating the subject with light and increasing the contrast of the image to be captured when it is determined that the image being captured does not have a high-contrast portion. be able to.

  The detecting means can detect an azimuth and detect the rotation of the display means based on a time-series change of the detected azimuth.

  The detection means can be constituted by an electronic compass.

  The information processing apparatus further includes control means for controlling the imaging means to take an image of the subject and storing the image of the subject taken by the imaging means in the storage means, and the display changing means The control means causes the image pickup means to pick up an image of the subject and displays the image of the subject picked up by the image pickup means on the display means when the storage means is not storing the image. The display content can be changed.

  The display changing means can enlarge or reduce the display content displayed on the display means when the movement of the display means in the optical axis direction is detected based on the output of the imaging means.

  When the movement and rotation are detected while the predetermined switch is on, the prohibiting unit can prohibit the display changing unit from changing the display content displayed on the display unit.

  When the movement and rotation are detected while the predetermined switch is off, the prohibiting unit can prohibit the display changing unit from changing the display content displayed on the display unit.

  The display changing means rotates the display content displayed on the display means by a predetermined angle when rotation around a predetermined straight line perpendicular to the screen of the display means is detected based on the output of the imaging means. Can be made.

  The display changing means scrolls the display content displayed on the display means in a predetermined direction when rotation around a predetermined straight line parallel to the screen of the display means is detected based on the output of the imaging means. Can be made.

  One aspect of the recording medium of the present invention includes a display unit that displays at least one of an image, a character, and a figure, a detection unit that detects at least one of movement and rotation of the display unit, A recording medium used in an information processing apparatus including display change means for changing display contents displayed on the display means, wherein the display means detects a movement amount by a plurality of movements or rotations detected by the detection means. Alternatively, a program for controlling the display changing means is recorded so as to change the display content displayed on the display means in accordance with the amount of rotation.

  In one aspect of the present invention, at least one of an image, a character, and a figure is displayed on the display means, and at least one of movement and rotation of the display means is detected, and a plurality of detected display means The display content displayed on the display means is changed according to the amount of movement or the amount of rotation due to the movement or rotation of the rotation.

  According to one aspect of the present invention, the screen display can be changed by moving or rotating the entire apparatus. Accordingly, it is possible to improve the operability when changing the display content of the screen of a portable device or the like.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings.

  1 and 2 are perspective views showing a configuration example of an embodiment of an electronic camera to which the present invention is applied. In the electronic camera of the present embodiment, when photographing a subject, the surface directed to the subject is the surface X1, and the surface directed to the user side is the surface X2. A finder 2 used for confirming the photographing range of the subject, a photographing lens 3 that captures a light image of the subject, and a light emitting unit (strobe) 4 that emits light that illuminates the subject are provided at the upper end of the surface X1. .

  Further, when shooting is performed with the strobe 4 emitting light on the surface X1, the operation of the red-eye reduction LED 15 and the CCD 20 (FIG. 4) for reducing red-eye to emit light before the strobe 4 is emitted is stopped. Are provided with a photometric element 16 for performing photometry, and a colorimetric element 17 for performing color measurement when the operation of the CCD 20 is stopped. A zoom switch 60 is provided for optically or Digital zooming and playback images can be digitally zoomed.

  On the other hand, at the upper end of the surface X2 facing the surface X1 (the position corresponding to the upper end of the finder 2, the photographing lens 3 and the light emitting unit 4 on the surface X1), the finder 2 and the electronic camera 1 A speaker 5 is provided for outputting the sound recorded in the. Further, the LCD 6 and the operation keys 7 formed on the surface X2 are formed vertically below the viewfinder 2, the photographing lens 3, the light emitting unit 4, and the speaker 5. On the surface of the LCD 6, a so-called touch tablet 6 </ b> A that outputs position data corresponding to an instructed position by a touch operation of a pen-type pointing device described later is disposed.

  The touch tablet 6A is made of a transparent material such as glass or resin, and the user observes an image displayed on the LCD 6 formed inside the touch tablet 6A via the touch tablet 6A. Can do.

  The operation key 7 is a key that is operated when recording data is reproduced and displayed on the LCD 6. The operation key 7 detects an operation (input) by a user and supplies it to a CPU (central processing unit) 39 (FIG. 6). ing.

  The menu key 7 </ b> A among the operation keys 7 is a key that is operated when a menu screen is displayed on the LCD 6. The execution key 7B is a key operated when reproducing the recording information selected by the user.

  The cancel key 7 </ b> C is a key operated when the recording information reproduction process is interrupted. The delete key 7D is a key operated when deleting recorded information. The scroll key 7E is a key operated when the screen is scrolled up and down when a list of recorded information is displayed on the LCD 6.

  The surface X2 is provided with a slidable LCD cover 14 that protects the LCD 6 when not in use. As shown in FIG. 3, the LCD cover 14 covers the LCD 6 and the touch tablet 6A when moved in the vertical upward direction. When the LCD cover 14 is moved vertically downward, the LCD 6 and the touch tablet 6A appear, and a power switch 11 (described later) disposed on the surface Y2 is turned on by the arm portion 14A of the LCD cover 14. It is made like that.

  A surface Z that is the upper surface of the electronic camera 1 is provided with a microphone 8 that collects sound and an earphone jack 9 to which an earphone (not shown) is connected.

  The left side surface (surface Y1) is provided with a release switch 10 that is operated when imaging a subject and a continuous shooting mode changeover switch 13 that is operated when switching a continuous shooting mode at the time of shooting. The release switch 10 and the continuous shooting mode changeover switch 13 are arranged vertically below the viewfinder 2, the photographing lens 3 and the light emitting unit 4 provided at the upper end of the surface X1.

  On the other hand, on the surface Y2 (right side surface) facing the surface Y1, a recording switch 12 and a power switch 11 that are operated when recording sound are provided. The recording switch 12 and the power switch 11 are vertically lower than the finder 2, the photographing lens 3, and the light emitting unit 4 provided at the upper end of the surface X 1, similarly to the release switch 10 and the continuous shooting mode switching switch 13. Is arranged. Further, the recording switch 12 is formed to have almost the same height as the release switch 10 on the surface Y1, and is configured so as not to feel uncomfortable even if it is held with either the left or right hand.

  In addition, when one switch is pressed by making the height of the recording switch 12 and the release switch 10 different, if the opposite side is held with a finger in order to cancel the moment due to the pressing force, it is mistakenly made. The switch provided on the opposite side surface may not be pushed.

  The continuous shooting mode switch 13 is used when the user presses the release switch 10 to shoot a subject and sets whether to shoot only one frame of the subject or a predetermined plurality of frames. For example, when the pointer of the continuous shooting mode switch 13 is switched to the position where “S” is printed (that is, switched to the S mode), when the release switch 10 is pressed, only one frame is shot. Has been made to be done.

  Further, when the pointer of the continuous shooting mode switch 13 is switched to the position where “L” is printed (that is, the mode is switched to the L mode), if the release switch 10 is pressed, the release switch 10 During the pressed period, 8 frames are taken per second (that is, the low-speed continuous shooting mode is set).

  Further, when the pointer of the continuous shooting mode switch 13 is switched to the position where “H” is printed (that is, switched to the H mode), if the release switch 10 is pressed, the release switch 10 During the pressed period, 30 frames are taken per second (that is, the high-speed continuous shooting mode is set).

  Next, the internal configuration of the electronic camera 1 will be described. FIG. 4 is a perspective view showing an example of the internal configuration of the electronic camera shown in FIGS. 1 and 2. The CCD 20 is provided on the rear stage (surface X2 side) of the photographic lens 3, and photoelectrically converts a light image of a subject imaged through the photographic lens 3 into an electrical signal.

  The in-finder display element 26 is arranged in the field of view of the finder 2 and displays various function setting states and the like to the user who is viewing the subject through the finder 2.

  Four cylindrical batteries (AA batteries) 21 are vertically arranged on the lower side of the LCD 6, and the electric power stored in the battery 21 is supplied to each part. . Further, a capacitor 22 that accumulates charges for causing the light emitting unit 4 to emit light is disposed along with the battery 21 on the lower side of the LCD 6.

  On the circuit board 23, various control circuits for controlling each part of the electronic camera 1 are formed. A memory card 24 that can be inserted and removed is provided between the circuit board 23, the LCD 6, and the battery 21, and various types of information input to the electronic camera 1 are preset in the memory card 24, respectively. Is recorded in the area.

  Further, the LCD switch 25 arranged adjacent to the power switch 11 is a switch that is turned on only while the projection is pressed. When the LCD cover 14 is moved vertically downward, As shown in FIG. 5 (a), the arm portion 14 </ b> A of the LCD cover 14 can be switched on together with the power switch 11.

  When the LCD cover 14 is positioned vertically upward, the power switch 11 is operated by the user independently of the LCD switch 25. For example, when the LCD cover 14 is closed and the electronic camera 1 is not used, the power switch 11 and the LCD switch 25 are turned off as shown in FIG. In this state, when the user switches the power switch 11 to the on state as shown in FIG. 5C, the power switch 11 is turned on, but the LCD switch 25 remains off. On the other hand, when the LCD cover 14 is opened when the power switch 11 and the LCD switch 25 are in the OFF state as shown in FIG. 5B, as shown in FIG. The LCD switch 25 is turned on. Thereafter, when the LCD cover 14 is closed, only the LCD switch 25 is turned off as shown in FIG.

  In this embodiment, the memory card 24 can be inserted and removed, but a memory may be provided on the circuit board 23 so that various types of information can be recorded in the memory. Various information recorded in the memory (memory card 24) may be output to an external personal computer or the like via an interface (not shown).

  Next, an example of the internal electrical configuration of the electronic camera 1 of the present embodiment will be described with reference to the block diagram of FIG. The CCD 20 provided with a plurality of pixels photoelectrically converts a light image formed on each pixel into an image signal (electric signal). A digital signal processor (hereinafter referred to as DSP) 33 supplies a CCD horizontal drive pulse to the CCD 20 and controls the CCD drive circuit 34 to supply the CCD 20 with a CCD vertical drive pulse.

  The image processing unit 31 is controlled by the CPU 39 to sample the image signal photoelectrically converted by the CCD 20 at a predetermined timing and amplify the sampled signal to a predetermined level. The CPU 39 controls each unit according to a control program stored in a ROM (read only memory) 43. An analog / digital conversion circuit (hereinafter referred to as A / D conversion circuit) 32 digitizes the image signal sampled by the image processing unit 31 and supplies the digitized signal to the DSP 33.

  The DSP 33 controls the data bus connected to the buffer memory 36 and the memory card 24, temporarily stores the image data supplied from the A / D conversion circuit 32 in the buffer memory 36, and then stores the image data stored in the buffer memory 36. Data is read out and the image data is recorded on the memory card 24.

  Further, the DSP 33 stores the image data supplied from the A / D conversion circuit 32 in the frame memory 35 and displays it on the LCD 6, reads out the photographed image data from the memory card 24, decompresses the photographed image data, The decompressed image data is stored in the frame memory 35 and displayed on the LCD 6.

  Further, the DSP 33 repeatedly operates the CCD 20 while adjusting the exposure time (exposure value) until the exposure level of the CCD 20 reaches an appropriate value when the electronic camera 1 is activated. At this time, the DSP 33 may first operate the photometry circuit 51 and calculate the initial value of the exposure time of the CCD 20 corresponding to the light reception level detected by the photometry element 16. In this way, the exposure time of the CCD 20 can be adjusted in a short time.

  In addition, the DSP 33 performs data input / output timing management in recording to the memory card 24, storing the decompressed image data in the buffer memory 36, and the like.

  The buffer memory 36 is used to alleviate the difference between the data input / output speed with respect to the memory card 24 and the processing speed of the CPU 39, DSP 33, and the like.

  The microphone 8 inputs voice information (collects voice) and supplies the voice information to the A / D and D / A conversion circuit 42.

  The A / D and D / A conversion circuit 42 converts an analog signal corresponding to the sound detected by the microphone 8 into a digital signal, and then supplies the digital signal to the CPU 39 and the sound data supplied from the CPU 39. An analog audio signal is output to the speaker 5 as an analog signal.

  The photometric element 16 measures the amount of light in the subject and its surroundings and outputs the measurement result to the photometric circuit 51. The photometry circuit 51 performs predetermined processing on the analog signal that is the photometry result supplied from the photometry element 16, converts the analog signal into a digital signal, and outputs the digital signal to the CPU 39.

  The color measuring element 17 measures the color temperature of the subject and its surroundings and outputs the measurement result to the color measuring circuit 52. The color measurement circuit 52 performs predetermined processing on the analog signal that is the color measurement result supplied from the color measurement element 17, converts the analog signal into a digital signal, and outputs the digital signal to the CPU 39. Yes.

  The timer 45 has a built-in clock circuit, and outputs data corresponding to the current time to the CPU 39.

  The aperture driving circuit 53 is configured to set the aperture diameter of the aperture 54 to a predetermined value. The stop 54 is disposed between the photographing lens 3 and the CCD 20 and changes the aperture of light incident on the CCD 20 from the photographing lens 3.

  In response to a signal from the LCD switch 25, the CPU 39 stops the operation of the photometric circuit 51 and the colorimetric circuit 52 when the LCD cover 14 is open, and performs photometry when the LCD cover 14 is closed. The circuit 51 and the colorimetric circuit 52 are operated, and the operation of the CCD 20 (for example, an electronic shutter operation) is stopped until the release switch 10 is pressed halfway.

  When the operation of the CCD 20 is stopped, the CPU 39 controls the photometry circuit 51 and the color measurement circuit 52 to receive the photometry result of the photometry element 16 and the color measurement result of the color measurement element 17. .

  Then, the CPU 39 refers to a predetermined table, calculates a white balance adjustment value corresponding to the color temperature supplied from the color measurement circuit 52, and supplies the white balance adjustment value to the image processing unit 31. ing.

  That is, when the LCD cover 14 is closed, the LCD 6 is not used as an electronic viewfinder, so that the operation of the CCD 20 is stopped. Since the CCD 20 consumes a lot of power, the power of the battery 21 can be saved by stopping the operation of the CCD 20 in this way.

  Further, the CPU 39 performs image processing so that the image processing unit 31 does not perform various processes until the release switch 10 is operated when the LCD cover 14 is closed (until the release switch 10 is pressed halfway). The unit 31 is controlled.

  Further, the CPU 39 operates such that the aperture driving circuit 53 changes the aperture diameter of the aperture 54 until the release switch 10 is operated when the LCD cover 14 is closed (until the release switch 10 is pressed halfway). The aperture driving circuit 53 is controlled so as not to perform the operation.

  Further, the CPU 39 controls the strobe driving circuit 37 so that the strobe 4 emits light appropriately, and also controls the red-eye reduction LED driving circuit 38 to turn on the red-eye reduction LED 15 before causing the strobe 4 to emit light. It is made to emit light appropriately.

  Note that the CPU 39 can prevent the flash 4 from emitting light when the LCD cover 14 is open (that is, when the electronic viewfinder is used). In this way, the subject can be photographed in the state of the image displayed on the electronic viewfinder.

  In accordance with the date / time data supplied from the timer 45, the CPU 39 records information on the date / time of shooting as header information of the image data in the shot image recording area of the memory card 24. (That is, the shooting image data recorded in the shooting image recording area of the memory card 24 is accompanied by shooting date and time data).

  Further, the CPU 39 compresses the digitized audio information, temporarily stores the digitized and compressed audio data in the buffer memory 36, and then stores it in a predetermined area (audio recording area) of the memory card 24. It is made to record. At this time, recording date and time data is recorded in the audio recording area of the memory card 24 as header information of the audio data.

  The CPU 39 controls the lens driving circuit 30 and moves the photographing lens 3 to perform an autofocus operation, and also controls the diaphragm driving circuit 53 to control the diaphragm 54 disposed between the photographing lens 3 and the CCD 20. The opening diameter is changed.

  Further, the CPU 39 controls the in-finder display circuit 40 to display settings in various operations on the in-finder display element 26.

  The CPU 39 exchanges predetermined data with a predetermined external device (not shown) via an interface (I / F) 48.

  The CPU 39 receives a signal from the operation key 7 and processes it appropriately.

  When a predetermined position of the touch tablet 6A is pressed by a pen (pen-type instruction member) 41 operated by the user, the CPU 39 reads the XY coordinates of the pressed position of the touch tablet 6A, and the coordinate data (described later). Memo information) is stored in the buffer memory 36. The CPU 39 records the memo information stored in the buffer memory 36 in the memo information recording area of the memory card 24 together with the header information of the memo information input date and time.

  Next, various operations of the electronic camera 1 according to the present embodiment will be described. First, the electronic viewfinder operation in the LCD 6 of this apparatus will be described.

  When the user presses the release switch 10 halfway, the DSP 33 determines whether the LCD cover 14 is open from the value of the signal supplied from the CPU 39 and corresponding to the state of the LCD switch 25. If it is determined that is closed, the electronic viewfinder operation is not performed. In this case, the DSP 33 stops the processing until the release switch 10 is operated.

  When the LCD cover 14 is closed, the electronic viewfinder operation is not performed, so the CPU 39 stops the operations of the CCD 20, the image processing unit 31, and the aperture driving circuit 53. Then, instead of stopping the CCD 20, the CPU 39 operates the photometry circuit 51 and the color measurement circuit 52 and supplies the measurement results to the image processing unit 31. The image processing unit 31 uses these measurement result values when performing white balance control or luminance value control.

  When the release switch 10 is operated, the CPU 39 causes the CCD 20 and the aperture driving circuit 53 to operate.

  On the other hand, when the LCD cover 14 is opened, the CCD 20 performs an electronic shutter operation at a predetermined exposure time every predetermined time, photoelectrically converts the light image of the subject condensed by the photographing lens 3, and The image signal obtained by the operation is output to the image processing unit 31.

  The image processing unit 31 performs white balance control and luminance value control, performs predetermined processing on the image signal, and then outputs the image signal to the A / D conversion circuit 32. When the CCD 20 is operating, the image processing unit 31 uses the adjustment value used for white balance control and luminance value control calculated by the CPU 39 using the output of the CCD 20.

  The A / D conversion circuit 32 converts the image signal (analog signal) into image data that is a digital signal, and outputs the image data to the DSP 33.

  The DSP 33 outputs the image data to the frame memory 35 and causes the LCD 6 to display an image corresponding to the image data.

  As described above, in the electronic camera 1, when the LCD cover 14 is open, the CCD 20 performs an electronic shutter operation at a predetermined time interval, and each time the signal output from the CCD 20 is converted into image data. The electronic viewfinder operation is performed by outputting the image data to the frame memory 35 and continuously displaying the subject image on the LCD 6.

  Further, as described above, when the LCD cover 14 is closed, the electronic viewfinder operation is not performed, and the operations of the CCD 20, the image processing unit 31, and the aperture driving circuit 53 are stopped to save power consumption. ing.

  Next, shooting of a subject by this apparatus will be described.

  First, a case where the continuous shooting mode changeover switch 13 provided on the surface Y1 is switched to the S mode (a mode in which only one frame is shot) will be described. First, the power switch 11 shown in FIG. 1 is switched to the side where “ON” is printed to turn on the electronic camera 1. When the subject is confirmed with the finder 2 and the release switch 10 provided on the surface Y1 is pressed, the photographing process of the subject is started.

  When the LCD cover 14 is closed, when the release switch 10 is half-pressed, the CPU 39 restarts the operations of the CCD 20, the image processing unit 31, and the aperture drive circuit 53, and the release switch 10 When is fully pressed, the subject photographing process is started.

  An optical image of a subject observed with the finder 2 is condensed by the photographing lens 3 and formed on a CCD 20 having a plurality of pixels. The optical image of the subject imaged on the CCD 20 is photoelectrically converted into an image signal at each pixel and sampled by the image processing unit 31. The image signal sampled by the image processing unit 31 is supplied to the A / D conversion circuit 32 where it is digitized and output to the DSP 33.

  The DSP 33 once outputs the image data to the buffer memory 36, then reads the image data from the buffer memory 36, and follows a JPEG (Joint Photographic Experts Group) system that combines discrete cosine transform, quantization, and Huffman coding. The compressed image is recorded in the captured image recording area of the memory card 24. At this time, shooting date / time data is recorded in the shot image recording area of the memory card 24 as header information of the shot image data.

  When the continuous shooting mode switch 13 is switched to the S mode, only one frame is shot, and no further shooting is performed even if the release switch 10 is continuously pressed. When the release switch 10 is continuously pressed, the captured image is displayed on the LCD 6 when the LCD cover 14 is open.

  Secondly, a case where the continuous shooting mode switch 13 is switched to the L mode (a mode for performing continuous shooting of 8 frames per second) will be described. When the electronic switch 1 is turned on by switching the power switch 11 to the side printed “ON” and the release switch 10 provided on the surface Y1 is pressed, the photographing process of the subject is started.

  When the LCD cover 14 is closed, when the release switch 10 is half-pressed, the CPU 39 restarts the operations of the CCD 20, the image processing unit 31, and the aperture drive circuit 53, and the release switch 10 When is fully pressed, the subject photographing process is started.

  The light image of the subject observed with the viewfinder 2 is collected by the photographing lens 3 and formed on the CCD 20 having a plurality of pixels. The light image of the subject imaged on the CCD 20 is photoelectrically converted into an image signal at each pixel, and is sampled by the image processing unit 31 at a rate of 8 times per second. At this time, the image processing unit 31 thins out three-fourths of the image electrical signals of all the pixels of the CCD 20.

  That is, the image processing unit 31 divides the pixels of the CCD 20 arranged in a matrix into areas each having 2 × 2 pixels (four pixels) as shown in FIG. The image signal of one pixel arranged at a predetermined position is sampled, and the remaining three pixels are thinned out.

  For example, at the time of the first sampling (first frame), the pixel a at the upper left of each region is sampled, and the other pixels b, c, d are thinned out. At the time of the second sampling (second frame), the upper right pixel b in each region is sampled, and the other pixels a, c, d are thinned out. Hereinafter, at the time of the third sampling and the fourth sampling, the lower left pixel c and the lower right pixel d are sampled, and the other pixels are thinned out. That is, each pixel is sampled every four frames.

  The image signal sampled by the image processing unit 31 (image signal of one-fourth of all the pixels of the CCD 20) is supplied to the A / D conversion circuit 32, where it is digitized and output to the DSP 33.

  The DSP 33 once outputs the digitized image signal to the buffer memory 36, reads the image signal, compresses it according to the JPEG method, and then converts the digitized and compressed photographed image data to the photographed image of the memory card 24. Record in the recording area. At this time, shooting date / time data is recorded in the shot image recording area of the memory card 24 as header information of the shot image data.

  Thirdly, a case where the continuous shooting mode changeover switch 13 is switched to the H mode (a mode for performing continuous shooting of 30 frames per second) will be described. When the electronic switch 1 is turned on by switching the power switch 11 to the side printed “ON” and the release switch 10 provided on the surface Y1 is pressed, the photographing process of the subject is started.

  When the LCD cover 14 is closed, when the release switch 10 is half-pressed, the CPU 39 restarts the operations of the CCD 20, the image processing unit 31, and the aperture drive circuit 53, and the release switch 10 When is fully pressed, the subject photographing process is started.

  An optical image of a subject observed with the finder 2 is condensed by the photographing lens 3 and formed on the CCD 20. An optical image of a subject formed on the CCD 20 having a plurality of pixels is photoelectrically converted into an image signal at each pixel, and is sampled by the image processing unit 31 at a rate of 30 times per second. At this time, the image processing unit 31 thins out 8/9 pixels of the image electrical signals of all the pixels of the CCD 20.

  That is, the image processing unit 31 divides the pixels of the CCD 20 arranged in a matrix into areas each having 3 × 3 pixels as shown in FIG. The image electrical signal of one arranged pixel is sampled at a rate of 30 times per second, and the remaining 8 pixels are thinned out.

  For example, at the time of the first sampling (first frame), the upper left pixel a of each region is sampled, and the other pixels b to i are thinned out. At the time of the second sampling (second frame), the pixel b arranged on the right side of the pixel a is sampled, and the other pixels a, c to i are thinned out. Hereinafter, in the third and subsequent samplings, the pixel c, the pixel d,... Are sampled, and the other pixels are thinned out. That is, each pixel is sampled every nine frames.

  The image signal sampled by the image processing unit 31 (image signal of 1/9 of all the pixels of the CCD 20) is supplied to the A / D conversion circuit 32, where it is digitized and output to the DSP 33.

  The DSP 33 once outputs the digitized image signal to the buffer memory 36, reads the image signal, compresses it according to the JPEG method, and then converts the digitized and compressed photographed image data to the header information of the photographing date and time. Along with this, the image is recorded in the captured image recording area of the memory card 24.

  If necessary, the strobe 4 can be operated to irradiate the subject with light. However, when the LCD cover 14 is open, that is, when the LCD 6 is performing an electronic viewfinder operation, the CPU 39 can control the strobe 4 not to emit light.

  Next, an operation when inputting two-dimensional information (pen input information) from the touch tablet 6A will be described.

  When the touch tablet 6 </ b> A is pressed with the pen tip of the pen 41, the XY coordinates of the contacted part are input to the CPU 39. The XY coordinates are stored in the buffer memory 36. In addition, data can be written in locations corresponding to the respective points of the XY coordinates in the frame memory 35, and a memo corresponding to the touch of the pen 41 can be displayed at the XY coordinates of the LCD 6.

  As described above, since the touch tablet 6A is configured by a transparent member, the user can observe a point displayed on the LCD 6 (a point at a position pressed by the pen tip of the pen 41). It can be felt as if the pen input was made directly on the LCD 6. When the pen 41 is moved on the touch tablet 6 </ b> A, a line accompanying the movement of the pen 41 is displayed on the LCD 6. Furthermore, when the pen 41 is moved intermittently on the touch tablet 6 </ b> A, a broken line accompanying the movement of the pen 41 is displayed on the LCD 6. As described above, the user inputs memo information such as desired characters and figures on the touch tablet 6A (LCD 6).

  In addition, when a photographic information is displayed on the LCD 6, when memo information is input by the pen 41, the memo information is combined with the photographic image information in the frame memory 35 and displayed on the LCD 6 at the same time. .

  The user can select a color of the memo displayed on the LCD 6 from black, white, red, blue, and the like by operating a predetermined palette 100.

  When the execution key 7B of the operation key 7 is pressed after the memo information is input to the touch tablet 6A by the pen 41, the memo information stored in the buffer memory 36 is supplied to the memory card 24 together with the header information of the input date and time. , Recorded in the memo information recording area of the memory card 24.

  Note that the memo information recorded in the memory card 24 is information subjected to compression processing. Since the memo information input to the touch tablet 6A includes a large amount of information having a high spatial frequency component, if compression processing is performed by the JPEG method used for compression of the captured image, the compression efficiency is low and the amount of information is not reduced. This increases the time required for compression and decompression. Furthermore, since compression using the JPEG method is irreversible compression, it is not suitable for compression of memo information with a small amount of information (when decompressed and displayed on the LCD 6, gathers and blurs due to missing information are prominent). To end up).

  Therefore, in the present embodiment, the memo information is compressed by a run length method used in a fax or the like. The run-length method scans the memo screen in the horizontal direction, and the length of information (dots) for each color such as black, white, red, and blue, and the length of no information (portion without pen input). This is a method of compressing memo information by encoding the length.

  By using this run length method, it is possible to compress the memo information to the minimum, and even when the compressed memo information is expanded, it is possible to suppress the loss of information. Note that the memo information may be not compressed when the amount of information is relatively small.

  Further, as described above, when a photographic image is displayed on the LCD 6, when pen input is performed, the photographic image data and the memo information of the pen input are combined in the frame memory 35, and the combined image of the photographic image and the memo is obtained. Is displayed on the LCD 6. On the other hand, in the memory card 24, the photographed image data is recorded in the photographed image recording area, and the memo information is recorded in the memo information recording area. In this way, since the two pieces of information are recorded in different areas, the user can delete one of the images (for example, a memo) from the combined image of the photographed image and the memo, and each The image information can also be compressed by an individual compression method.

  When data is recorded in the voice recording area, the photographed image recording area, or the memo information recording area of the memory card 24, the list can be displayed on the LCD 6, as shown in FIG.

  On the display screen of the LCD 6 shown in FIG. 9, the date when the information was recorded (recorded date) (in this case, November 1, 1996) is displayed at the upper end of the screen, and the recorded year The number of the information recorded on the month and day and the recording time are displayed on the left side of the screen.

  A thumbnail image is displayed on the right side of the recording time. This thumbnail image is created by thinning out (reducing) the bitmap data of each image data of the photographed image data recorded in the memory card 24. Information with this display is information including photographed image information. That is, the information recorded (input) at “10:16” and “10:21” includes photographed image information, and the information recorded at other times includes image information. Not included.

  A memo icon “□” represents that a predetermined memo is recorded as line drawing information.

  A sound icon (note) is displayed on the right side of the thumbnail image display area, and the recording time (unit: seconds) is displayed on the right side of it (if no sound information is input, these are Do not show).

  As shown in FIG. 9, the user selects and designates information to be reproduced by pressing a desired voice icon in the list displayed on the LCD 6 with the pen tip of the pen 41, and the execution key 7B shown in FIG. Is pressed with the pen tip of the pen 41 to reproduce the selected information.

  For example, when the voice icon displaying “10:16” shown in FIG. 9 is pressed by the pen 41, the CPU 39 stores the voice data corresponding to the selected recording date (10:16) in the memory card. 24, and the audio data is expanded and supplied to the A / D and D / A conversion circuit 42. The A / D and D / A conversion circuit 42 converts the supplied audio data into an analog signal and reproduces it through the speaker 5.

  When playing back the captured image data recorded in the memory card 24, the user selects the desired thumbnail image by pressing the pen tip of the pen 41, and presses the execution key 7B to play back the selected information. .

  That is, the CPU 39 instructs the DSP 33 to read out the photographed image data corresponding to the photographing date / time of the selected thumbnail image from the memory card 24. The DSP 33 expands the photographed image data (compressed photographed image data) read from the memory card 24, stores the photographed image data in the frame memory 35 as bitmap data, and displays it on the LCD 6.

  The image shot in the S mode is displayed on the LCD 6 as a still image. It goes without saying that this still image is a reproduction of the image signal of all the pixels of the CCD 20.

  Images taken in the L mode are continuously displayed on the LCD 6 at a rate of 8 frames per second. At this time, the number of pixels displayed in each frame is a quarter of the total number of pixels of the CCD 20.

  Normally, the human eye reacts sensitively to degradation of the resolution of a still image, and thus thinning out still image pixels is perceived by the user as degradation of image quality. However, when the continuous shooting speed at the time of shooting is increased and 8 frames are shot per second in the L mode and this image is reproduced at a speed of 8 frames per second, the number of pixels of each frame is the number of pixels of the CCD 20. Although it is a quarter of the number, since the human eye observes eight frames of images per second, the amount of information that enters the human eye per second is twice that of a still image.

  That is, if the number of pixels in one frame of the image shot in the S mode is 1, the number of pixels in one frame of the image shot in the L mode is ¼. When an image (still image) taken in the S mode is displayed on the LCD 6, the amount of information that enters the human eye per second is 1 (= (number of pixels 1) × (number of frames 1)). On the other hand, when an image shot in the L mode is displayed on the LCD 6, the amount of information that enters the human eye per second is 2 (= (number of pixels 1/4) × (number of frames 8)) (that is, The human eye contains twice as much information as still images). Therefore, even when the number of pixels in one frame is reduced to ¼, at the time of reproduction, the user can observe the reproduced image without much concern for deterioration in image quality.

  Furthermore, in the present embodiment, different pixels are sampled for each frame, and the sampled pixels are displayed on the LCD 6, so that an afterimage effect occurs in the human eye and three-quarters per frame. Even if the pixels are thinned out, the user can observe the image shot in the L mode displayed on the LCD 6 without much concern about the deterioration of the image quality.

  In addition, images taken in the H mode are continuously displayed on the LCD 6 at a rate of 30 frames per second. At this time, the number of pixels displayed in each frame is 1/9 of the total number of pixels of the CCD 20, but for the same reason as in the L mode, the user does not care much about the deterioration of the image quality. An image taken in the H mode displayed on the LCD 6 can be observed.

  In the present embodiment, when the subject is imaged in the L mode and the H mode, the image processing unit 31 thins out the pixels of the CCD 20 to such an extent that the deterioration of the image quality at the time of reproduction is not concerned. The load can be reduced, and the DSP 33 can be operated at low speed and low power. This also makes it possible to reduce the cost and power consumption of the apparatus.

  By the way, in the present embodiment, as described above, not only a light image of a subject but also memo (line drawing) information can be recorded. In the present embodiment, modes for inputting these information (photographing mode and memo input mode) are provided, and these modes are appropriately selected according to the user's operation, and the information input is executed smoothly. It is made so that.

  Next, a method for scrolling the image displayed on the screen of the electronic camera 1 or moving the cursor by holding or holding the electronic camera 1 with the hand and rotating the electronic camera 1 will be described. .

  Here, a rotation axis for rotating the electronic camera 1 is defined as shown in FIG. That is, a straight line passing through the center of the surface Z from the center of the electronic camera 1 is defined as the Y axis, and a straight line passing through the center of the electronic camera 1 from the center of the surface Y2 is defined as the X axis. The user rotates the electronic camera 1 around these two axes.

  FIG. 11 is a flowchart showing a processing procedure when the movement and rotation of the electronic camera 1 is detected based on the image captured by the CCD 20 of FIG. First, in step S1, the CCD 20 captures an image. That is, the CPU 39 controls the image processing unit 31 and samples the image signal photoelectrically converted by the CCD 20 at a predetermined timing. The sampled image signal is converted into digital image data by the A / D conversion circuit 32 and is temporarily supplied to the buffer memory 36 by the DSP 33. Then, the image data stored in the buffer memory 36 is read out by the DSP 33 and subjected to compression processing, and then supplied to the memory card 24 and stored therein.

  Next, the process proceeds to step S2, and the CPU 39 determines whether or not the contrast of the image captured in step S1 is sufficient. That is, it is determined whether or not a portion with the highest contrast can be detected from the captured image. For example, when the background is completely dark, a contrast image cannot be captured. If it is determined that the highest contrast portion of the captured image can be detected, the process proceeds to step S5.

  On the other hand, if it is determined that the portion with the highest contrast cannot be detected, the process proceeds to step S3, where the CPU 39 controls the red-eye reduction LED drive circuit 38 to turn on the red-eye reduction LED 15. Thereby, light is irradiated to the object on the surface X1 side of the electronic camera 1. Next, in step S4, the image is captured by the CCD 20 again under the control of the CPU 39 in the same manner as described above. At this time, since the red-eye reduction LED 15 is lit, the captured image has a contrast, and a portion with the highest contrast can be detected. When the image capturing by the CCD 20 is completed, the CPU 39 controls the red-eye reduction LED drive circuit 38 and turns off the red-eye reduction LED 15.

In step S5, the CPU 39 detects the highest contrast portion of the image captured in the memory card 24, and in step S6, the coordinate value P ₁ (P _x , P _y ) on the screen of that portion. Is stored in the buffer memory 36, for example.

Next, in step S7, whether there is a coordinate value P ₀ of the portion having the highest contrast, which has been previously stored is determined. If it is determined that there is no previously stored coordinate value P ₀ , the process returns to step S1 and the processes after step S1 are executed again. The cycle in which steps S1 to S7 are executed can be set to, for example, 30 hertz (Hz) in accordance with the cycle for capturing an image. Therefore, the red-eye reduction LED 15 blinks intermittently at a cycle of 30 hertz (Hz).

  Further, when the background is completely dark, instead of the red-eye reduction LED 15, illumination light can be applied to the background using another illumination device (not shown) so that the CCD 20 can capture a contrast image. .

On the other hand, if it is determined that there is the previously stored coordinate value P ₀ , step S8
Then, the difference ΔP (ΔP _x , ΔP _y ) between the previously stored coordinate value P ₀ and the detected coordinate value P ₁ is obtained.

Next, the process proceeds to step S9, and the reproduced image displayed on the screen is scrolled by a predetermined number of pixels in a predetermined direction corresponding to the difference ΔP (ΔP _x , ΔP _y ).

  For example, it is assumed that the number of pixels in the horizontal direction of the CCD 20 is 640, the number of pixels in the horizontal direction of the LCD 6 is 280, and the entire photographing range that can be photographed by the CCD 20 can be displayed on the LCD 6. Then, for example, the electronic camera 1 is swung to the right, and it is detected that the subject image detected by the CCD 20 has moved to the left by 64 pixels, which is 1/10 of the number of pixels in the horizontal direction. In this case, the image on the LCD 6 is also scrolled to the left by 28 pixels, which is 1/10 of the number of pixels in the horizontal direction. When the electronic camera 1 is shaken in the vertical direction (vertical direction), the screen displayed on the LCD 6 is scrolled in the vertical direction basically in the same manner as when the electronic camera 1 is shaken in the horizontal direction.

  This makes it possible to move the electronic camera 1 up / down / left / right during playback as if the electronic camera 1 was moved up / down / left / right while monitoring the shooting screen with the LCD 6 during shooting. The playback screen can be scrolled as if the shooting screen is moving. Of course, with this setting as a default, the relationship between the amount of movement of the image captured by the CCD 20 and the amount of scrolling of the image displayed on the LCD 6 may be made variable so that the user can set it.

  As shown in FIG. 12A, for example, a predetermined area of an image of 640 pixels × 480 pixels is set as the display area A, and the image of the display area A is reproduced and displayed on the screen of the LCD 6 (zoomed state). When the user rotates the electronic camera 1 about the Y axis, the display area A virtually moves left and right on the image, and accordingly, the image displayed on the LCD 6 scrolls left and right. Similarly, when the user rotates the electronic camera 1 around the X axis, the display area A virtually moves up and down on the image, and accordingly, the image displayed on the LCD 6 scrolls up and down.

  Further, by giving the electronic camera 1 a rotation that combines a rotation about the X axis and a rotation about the Y axis, the display area A is virtually arranged in an arbitrary direction on the image by an arbitrary number of pixels. Can be moved. Therefore, the image displayed on the LCD 6 can be scrolled in an arbitrary direction.

  As shown in FIG. 12A, in the state where the display area A is set in the recorded image and the image in the display area A is displayed on the screen of the LCD 6, the zoom switch 60 shown in FIG. Is operated to zoom in on the image displayed on the LCD 6, for example, as shown in FIG. 12B, a display area B smaller than the display area A is virtually set on the image. Then, the image in the display area B is displayed on the entire screen of the LCD 6. That is, the image is further enlarged and displayed.

  As shown in FIG. 12B, even when the image is further enlarged, the display area B is virtually recorded by rotating the electronic camera 1 as in the case of FIG. It can be moved in any direction on the image. Accordingly, the enlarged image displayed on the LCD 6 scrolls in an arbitrary direction. Such enlargement of the reproduced image can be performed by operating the zoom switch 60 shown in FIG.

  Further, as shown in FIG. 13A, on the menu screen on which the predetermined selection item and the cursor are displayed, the cursor is moved by the movement or rotation of the electronic camera 1 to select the predetermined item. can do. In this example, the items “RECORDING”, “PLAY BACK”, “SLIDE SHOW”, and “SET UP” are arranged in the vertical direction, and the cursor moves in the vertical direction by the movement or rotation of the electronic camera 1. For example, by rotating the electronic camera 1 around the X axis and moving the cursor to the item “SET UP”, selecting the execution key 7B or pressing the release switch 10 causes “SET UP”. Can be selected. Thereby, the setup items as shown in FIG. 13B are displayed on the screen of the LCD 6.

  In this example, the setup items are displayed over two pages. By rotating the electronic camera 1 in the X-axis direction, the first and second pages can be alternately switched and displayed. The user displays a page with a desired setup item, uses the pen 41 or the like, moves a cursor (not shown) in accordance with the rotation of the camera, presses the release switch 10, or selects the effective key 7B. By selecting it.

  Next, in step S10 of FIG. 11, it is determined whether or not the user has instructed execution of another process. If it is determined that execution of another process is not instructed, the process returns to step S1 and the processes after step S1 are repeatedly executed. On the other hand, when it is determined that execution of another process is instructed, the process proceeds to step S11, the other process is executed, and the process ends.

  As described above, by moving or rotating the electronic camera 1, it is possible to easily scroll the image displayed on the screen and move the cursor, and in particular, it is possible to improve the operability of the portable device. .

  FIG. 14 is a block diagram showing a configuration example of another embodiment of an electronic camera to which the present invention is applied. In this embodiment, a piezoelectric gyro 61 and a piezoelectric gyro drive circuit 62 are provided in the embodiment shown in FIG. Other configurations and operations are the same as those described above with reference to FIG.

  The piezoelectric gyro 61 is configured to detect angular velocities caused by rotation with respect to two axes and output corresponding signals. The piezoelectric gyro drive circuit 62 supplies power to the piezoelectric gyro 61 and supplies a signal from the piezoelectric gyro 61 to the CPU 39.

  Next, referring to the flowchart shown in FIG. 15, a processing procedure when the rotation of the electronic camera 1 is detected using the piezoelectric gyro 61 and the image displayed on the screen is scrolled or the cursor is moved. explain.

  First, in step S 21, a signal corresponding to the angular velocity around the X axis detected by the piezoelectric gyro 61 is supplied to the CPU 39 via the piezoelectric gyro drive circuit 62. Next, in step S <b> 22, a signal corresponding to the angular velocity around the Y axis detected by the piezoelectric gyro 61 is supplied to the CPU 39 via the piezoelectric gyro 62. Next, the process proceeds to step S23, and the scroll direction and scroll amount of the image according to the angular velocity around the X axis and the angular velocity around the Y axis detected in steps S21 and S22 are calculated.

  Here, the relationship between the angular velocity and the scroll amount can be set as follows. That is, the horizontal shooting angle θ of the shooting lens 3 and the horizontal pixels of the LCD 6 are 280 pixels, and the entire shooting range is displayed on the LCD 6. For example, when it is detected from the angular velocity that the electronic camera 1 has rotated about the X axis by θ / 10, an image displayed on the LCD 6 is 28 pixels, which is 1/10 of the number of pixels in the horizontal direction of the LCD 6. Move up and down by the minute. Also, when the rotation of the electronic camera 1 around the Y axis is detected from the angular velocity, the image displayed on the LCD 6 is moved in the left-right direction basically in the same manner as when the electronic camera 1 is rotated around the X axis.

  As a result, when the electronic camera 1 is swung up, down, left, and right while monitoring the photographed image with the LCD 6 at the time of photographing, the electronic camera 1 is moved up, down, left and right at the time of reproduction. The reproduced image can be scrolled as if the captured image is moving. Of course, with this setting as a default, the relationship between the rotation amount of the electronic camera 1 and the scroll amount of the image displayed on the LCD 6 may be made variable so that the user can set it.

  In step S24, the image displayed on the screen of the LCD 6 is scrolled in the same manner as described above with reference to FIGS. 12 and 13 according to the scroll direction and scroll amount calculated in step S23. Move the cursor.

  In this way, the rotation of the electronic camera 1 is detected using the piezoelectric gyro 61, and the image displayed on the screen of the LCD 6 is scrolled or the cursor is moved in accordance with the rotation of the electronic camera 1 by the user. Can be moved.

  FIG. 16 is a block diagram showing a configuration example of still another embodiment of the electronic camera 1 to which the present invention is applied. In this embodiment, an electronic compass 71 and an electronic compass drive circuit 72 are provided in the embodiment shown in FIG. Other configurations and operations are the same as those described above with reference to FIG.

  The electronic compass 71 is constituted by a magnetic element such as a Hall element, and detects the azimuth by detecting geomagnetism. The electronic compass driving circuit 72 supplies electric power to the electronic compass 71 and supplies a signal corresponding to the direction detected by the electronic compass 71 to the CPU 39.

  Next, referring to the flowchart shown in FIG. 17, a processing procedure for detecting the rotation of the electronic camera 1 using the electronic compass 71 and scrolling the image displayed on the screen or moving the cursor. explain.

First, in step S31, the direction of the north pole is detected by the electronic compass 71. A signal corresponding to the detected direction of the north pole is supplied to the CPU 39 by the electronic compass drive circuit 72. Next, in step S <b> 32, the CPU 39 calculates a difference D _1x between the direction of the north pole and the X-axis direction with reference to the electronic camera 1 and stores it in the buffer memory 36. In step S <b> 33, the CPU 39 calculates the difference D _1y between the direction of the north pole and the Y-axis direction with reference to the electronic camera 1 and stores it in the buffer memory 36.

Next, in step S34, it is determined whether or not there are differences D _0x and D _0y between the previously stored north pole direction and the X-axis direction and Y-axis direction of the electronic camera 1. When it is determined that there is no difference D _0x or D _0y stored last time, the process returns to step S31, and the processes after step S31 are repeatedly executed. On the other hand, if it is determined that there is the difference D _0x , D _0y stored last time, the process proceeds to step S 35, and the CPU 39 compares the previous D _0x , D _0y with the currently detected D _1x , D _1y . Differences ΔD _x and ΔD _y are calculated.

Next, in step S36, the CPU 39 scrolls the image displayed on the screen of the LCD 6 by the corresponding number of pixels in the direction corresponding to the difference ΔD _x , ΔD _y . Alternatively, the cursor displayed on the screen of the LCD 6 is moved by the corresponding number of pixels in the direction corresponding to the difference ΔD _x , ΔD _y .

  It is assumed that the horizontal shooting angle of the shooting lens 3 is θ, the horizontal pixels of the LCD 6 are 280 pixels, and the entire shooting range is displayed on the LCD 6. For example, when the CPU 39 detects that the electronic camera 1 has been rotated by θ / 10 about the Y axis based on the displacement of the direction detected by the electronic compass, the image on the LCD 6 is also 1 / number of pixels in the horizontal direction. The left / right direction is moved by 28 pixels, which is 10 pixels. When the electronic camera 1 is rotated about the X axis, the image displayed on the LCD 6 is moved in the vertical direction basically in the same manner as when the electronic camera 1 is rotated about the Y axis.

  As a result, when the electronic camera 1 is swung up, down, left, and right while monitoring the photographed image with the LCD 6 at the time of photographing, the electronic camera 1 is moved up, down, left and right at the time of reproduction. The reproduced image can be scrolled as if the captured image is moving. Of course, with this setting as a default, the relationship between the rotation amount of the electronic camera 1 and the scroll amount of the image displayed on the LCD 6 may be made variable so that the user can set it.

  In step S37, it is determined whether or not the user has instructed execution of another process. If it is determined that execution of another process is not instructed, the process returns to step S1 and the processes after step S1 are repeatedly executed. On the other hand, when it is determined that execution of another process is instructed by the user, the process proceeds to step S38, the other process is performed, and the process ends.

  In this way, the electronic compass 71 is used to detect the rotation of the electronic camera 1, and the image displayed on the screen of the LCD 6 is scrolled or the cursor is moved as the user rotates the electronic camera 1. Can be moved.

  Further, as shown in FIG. 12, the present invention proposes a method of operating a magnification of a reproduced image by a zoom lens zooming member proposed by the present applicant in “Japanese Patent Application No. 8-153783” and the present invention. You may combine. As a result, electronic zooming during playback can be performed with the same operation as the zooming operation using the photographing lens 3, and scrolling during playback can be performed in the same manner as during shooting, improving usability. be able to.

  Next, with reference to the flowchart shown in FIG. 18, another method for detecting the movement and rotation of the electronic camera 1 and controlling the screen display based on the images captured in time series by the CCD 20 will be described. To do.

  First, in step S41, an image is captured by the CCD 20. That is, the CPU 39 controls the image processing unit 31 and samples the image signal photoelectrically converted by the CCD 20 at a predetermined timing. The sampled image signal is converted into digital image data by the A / D conversion circuit 32 and is temporarily supplied to the buffer memory 36 by the DSP 33. Then, the image data stored in the buffer memory 36 is read out by the DSP 33 and subjected to compression processing, and then supplied to the memory card 24 and stored therein.

  Next, proceeding to step S42, the CPU 39 determines whether or not the contrast of the image captured at step S41 is sufficient. That is, it is determined whether or not a plurality of portions with high contrast can be detected from the captured image. For example, when the background is completely dark, a contrast image cannot be captured. If it is determined that a plurality of high-contrast portions of the captured image can be detected, the process proceeds to step S45.

  On the other hand, if it is determined that a plurality of portions with high contrast cannot be detected, the process proceeds to step S43, and the CPU 39 controls the red-eye reduction LED drive circuit 38 to turn on the red-eye reduction LED 15. Thereby, light is irradiated to the object on the surface X1 side of the electronic camera 1. Next, in step S44, the image is captured by the CCD 20 again under the control of the CPU 39 in the same manner as described above. At this time, since the red-eye reduction LED 15 is lit, the captured image has contrast, and a plurality of portions with high contrast can be detected. When the image capturing by the CCD 20 is completed, the CPU 39 controls the red-eye reduction LED drive circuit 38 and turns off the red-eye reduction LED 15.

In step S45, the CPU 39 detects a plurality of high-contrast portions in the image captured in the memory card 24. In step S46, the coordinate values P _1n (P _xn , P _yn ) is stored in the buffer memory 36, for example. Here, n represents a number corresponding to a plurality of portions with high contrast.

Next, in step S47, it is determined whether or not there are coordinate values P _0n of a plurality of high-contrast portions stored last time. When it is determined that there is no previously stored coordinate value P _0n , the process returns to step S41, and the processes after step S41 are executed again. The cycle in which steps S41 to S47 are executed can be set to, for example, 30 hertz (Hz) in accordance with the cycle for capturing an image. Therefore, the red-eye reduction LED 15 blinks intermittently at a cycle of 30 hertz (Hz).

  Further, when the background is completely dark, instead of the red-eye reduction LED 15, illumination light can be applied to the background using another illumination device (not shown) so that the CCD 20 can capture a contrast image. .

On the other hand, if it is determined that there is a previously stored coordinate value P _0n , the process proceeds to step S48, and the difference ΔP _n (between the previously stored coordinate value P _0n and the currently detected coordinate value P _1n ( ΔP _xn , ΔP _yn ) is obtained.

In step S49, the CPU 39 causes the difference ΔP _n (ΔP _xn , ΔP _yn
), It is determined whether or not the electronic camera 1 has been translated in a direction substantially parallel to the optical axis direction of the photographing lens 3, as shown in FIG. This determination is performed based on the time-series changes of the plurality of high-contrast portions detected in step S45. For example, as shown in FIG. 20, when a plurality of high-contrast portions of an image captured by the CCD 20 move away from the vicinity of the center of the image or move toward the vicinity of the center of the image. The electronic camera 1 is determined to be translated in a direction substantially parallel to the optical axis direction of the lens 3.

  When it is determined that the movement of the electronic camera 1 is a parallel movement in a direction substantially parallel to the optical axis direction, the process proceeds to step S53, and zooming processing is performed under the control of the CPU 39. For example, when the electronic camera 1 is translated in the direction of the vector M1 in FIG. 19, the CPU 39 enlarges and displays the image being displayed on the screen of the LCD 6. On the other hand, when the electronic camera 1 is translated in the direction of the vector M2 in FIG. 19, the CPU 39 reduces the displayed image on the screen of the LCD 6 and displays it.

  On the other hand, if it is determined in step S49 that the movement of the electronic camera 1 is not a parallel movement in a direction substantially parallel to the optical axis direction of the lens 3, the process proceeds to step S50, and the electronic camera 1 is as shown in FIG. Then, it is determined whether or not the electronic camera 1 has been rotated by a predetermined angle around the Z axis passing through the center of the surface X2. This determination is performed based on the time-series changes of the plurality of high-contrast portions detected in step S45. For example, as shown in FIG. 21, when a plurality of high-contrast portions move so as to rotate by a predetermined angle around the center point of the image, the electronic camera 1 moves by a predetermined angle around the Z axis. It is determined that it has rotated.

  If it is determined that the electronic camera 1 has been rotated around the Z axis by a predetermined angle, the process proceeds to step S54, where it is determined whether the rotation of the electronic camera 1 is a clockwise rotation. If it is determined that the rotation is clockwise, in step S55, the image displayed on the screen of the LCD 6 is rotated clockwise by, for example, 90 degrees. On the other hand, if it is determined in step S54 that the rotation of the electronic camera 1 is not a clockwise rotation, the process proceeds to step S56, and the image displayed on the screen of the LCD 6 is rotated counterclockwise, for example, by 90 degrees.

  If it is determined in step S50 that the electronic camera 1 is not rotating about the Z axis, the process proceeds to step S51, and it is determined whether or not the scroll prohibition switch is pressed. Here, as the scroll prohibition switch, a dedicated switch may be newly provided, or the release switch 10 and the recording switch 12 may be substituted. In this case, when the release switch 10 or the recording switch 12 is pressed during reproduction, these switches are operated as a scroll prohibition switch.

  If it is determined that the scroll prohibit switch is pressed, the CPU 39 does not scroll the image displayed on the screen of the LCD 6, and thus returns to step S41, and the processes after step S41 are repeatedly executed. On the other hand, if it is determined that the scroll prohibit switch has not been pressed, the process proceeds to step S52.

In step S52, the reproduced image displayed on the screen is scrolled by a predetermined number of pixels in a predetermined direction corresponding to the difference ΔP _n (ΔP _xn , ΔP _yn ). The detailed scrolling procedure is the same as that described above with reference to the flowchart of FIG.

  When the process in step S53, step S55, step S56, or step S52 ends, the process proceeds to step S57. In step S57, it is determined whether another process has been instructed. When it is determined that no other process is instructed, the process returns to step S41, and the processes after step S41 are repeatedly executed. On the other hand, if it is determined that another process has been instructed, the process proceeds to step S58, and after the other process is executed, the process ends.

  For example, as shown in FIG. 22, the display area C is virtually set at a position L1 in the recorded image, and the electronic camera 1 is displayed with the image in the display area C displayed on the screen of the LCD 6. Is rotated in a predetermined direction around the Y axis, the display area C virtually moves in the recorded image. For example, suppose that it finally moved to the position L2. As a result, the image in the display area C at the position L2 is displayed on the screen of the LCD 6.

  In this state, when the display area in the recorded image is further moved to display the image in the display area C at the position L3 on the screen of the LCD 6, the hand holding the electronic camera 1 is further moved along the Y axis. It may be difficult to rotate in the above direction. In that case, the electronic camera 1 is rotated in the direction opposite to the above-described direction around the Y axis while pressing the scroll prohibition switch. Meanwhile, since the scroll prohibition switch is pressed, the image in the display area C at the position L2 on the recorded image is continuously displayed on the screen of the LCD 6.

  Next, the electronic camera 1 is rotated in a predetermined direction around the Y axis so as to stop pressing the scroll prohibition switch and virtually move the display area C from the position L2 to the position L3 on the recorded image. Move. Thereby, the display area C moves to the position L3 on the recorded image, and the image in the display area C at the position L3 is displayed on the screen of the LCD 6. In this way, by using the scroll prohibition switch, the display area C is moved to an arbitrary position on the recorded image by performing the operation of rotating the electronic camera 1 around the Y axis a plurality of times. Can do.

  That is, the moving distance of the display area C on the recorded image corresponding to the angle at which the electronic camera 1 can be rotated around the Y axis by one operation is larger than the size of the recorded image. Even in a small case, the display area C can be moved to an arbitrary position on the recorded image by repeating the rotation operation a predetermined number of times.

  Here, the case where the electronic camera 1 is rotated around the Y axis has been described, but the case where the electronic camera 1 is rotated around the X axis is recorded in the display area C in the same manner as described above. It can be moved up and down on the image. The same applies to the rotation that combines rotation around the X axis and rotation around the Y axis. In that case, the display area C can be moved in an arbitrary direction on the recorded image.

  As described above, by using the scroll prohibition switch, the operation of rotating the electronic camera 1 around the X axis or the Y axis, or the operation of rotating them in combination is performed in a plurality of times. Therefore, the display area C can be moved in an arbitrary direction by the rotation of the electronic camera 1 regardless of the size of the recorded image. That is, the image displayed on the screen of the LCD 6 can be scrolled in an arbitrary direction.

  In the above embodiment, the program for causing the CPU 39 to perform the processes shown in the flowcharts of FIGS. 11, 15, 17, and 18 is stored in the ROM 43 of the electronic camera 1, the memory card 24, or the like. can do. The program may be supplied to the user in a state stored in the ROM 43 or the memory card 24 in advance, or a CD-ROM (compact disc) so that the program can be copied to the ROM 43 or the memory card 24. -read only memory) may be supplied to the user. In this case, the ROM 43 can be configured by, for example, an electrically rewritable EEPROM (electrically erasable and programmable read only memory).

  In the above embodiment, the finder 2 is optical, but a liquid crystal finder using liquid crystal can also be used.

  In the above embodiment, the photographing lens, the finder, and the light emitting unit are arranged in this order from the left when viewed from the front of the electronic camera. However, it is also possible to arrange them from the right. .

  In the above embodiment, only one microphone is provided. However, it is also possible to provide two microphones on the left and right to record sound in stereo.

  Moreover, in the said embodiment, although various information was input using the pen-type instruction | indication apparatus, it is also possible to input using a finger | toe.

  Moreover, the display screen displayed on the LCD 6 is an example, and the display screen is not limited to this, and various layout screens can be used. Similarly, the types and layout of operation keys are only examples, and the present invention is not limited to these.

  In the above embodiment, the scrolling can be prohibited by pressing the scroll prohibition switch. Conversely, a scroll permission switch that permits scrolling is provided, and only while the scroll permission switch is being pressed. When the image displayed on the screen of the LCD 6 is scrolled according to the rotation of the electronic camera 1 and the scroll permission switch is not pressed, it is possible to prevent the image from scrolling even if the electronic camera 1 is rotated. . In this case, the release switch 10 and the recording switch 12 can be used as a scroll permission switch.

  In the above embodiment, the zooming process described above with reference to the flowchart of FIG. 18 is provided with a zooming prohibiting switch that prohibits the zooming process or a zooming permission switch that permits the zooming process. The same operation as that of the switch can be made possible. Even in this case, the release switch 10 and the recording switch 12 can be used as a zooming prohibition switch or a zooming permission switch.

  In each of the above embodiments, the case where the present invention is applied to an electronic camera has been described. However, the present invention can also be applied to other portable devices.

  Further, in each of the above embodiments, when the movement and rotation of the electronic camera 1 is detected based on the captured image, the detection is performed by a time-series change in the contrast of the captured image. It is also possible to detect the movement and rotation of the electronic camera 1 by a time-series change in the color of the. Alternatively, it may be detected by other image processing.

  Furthermore, in each of the above embodiments, a terminal for outputting a video signal can be provided so that an image or menu screen displayed on the LCD 6 of the electronic camera 1 can be displayed on an external television receiver or monitor. .

It is the perspective view which looked at one Embodiment of the electronic camera to which this invention was applied from the front side. FIG. 3 is a perspective view of the electronic camera 1 viewed from the back side with the LCD cover 14 opened. FIG. 3 is a perspective view of the electronic camera 1 viewed from the back side with the LCD cover 14 closed. 1 is a diagram illustrating an internal configuration example of an electronic camera 1. FIG. FIG. 5 is a diagram for explaining operations of the LCD switch 25 and the LCD cover 14 of the electronic camera 1. 2 is a block diagram showing an example of an electrical configuration inside the electronic camera 1. FIG. It is a figure for demonstrating a thinning process. It is a figure which shows the other example of a thinning process. 4 is a diagram showing an example of a display screen displayed on the LCD 6 of the electronic camera 1. FIG. It is a figure which shows the X-axis and the Y-axis defined on the basis of the electronic camera. 5 is a flowchart for explaining a method for detecting the movement and rotation of the electronic camera 1 based on the images captured in time series by the CCD 20 and controlling the screen display. It is a figure which shows the relationship between an image and the display area displayed on LCD6. It is a figure which shows a menu screen and a setup item selection screen. 3 is a block diagram illustrating another example of an electrical configuration inside the electronic camera 1. FIG. 7 is a flowchart for explaining a method for detecting the rotation of the electronic camera 1 based on the angular velocity detected by the piezoelectric gyro 61 and controlling the screen display. 4 is a block diagram showing still another example of an electrical configuration inside the electronic camera 1. FIG. It is a flowchart explaining the method of detecting rotation of the electronic camera 1 based on the azimuth | direction detected by the electronic compass 71, and controlling a screen display. It is a flowchart explaining the other method of detecting the movement and rotation of the electronic camera 1 based on the image taken in time series by CCD20, and controlling a screen display. 4 is a diagram illustrating an operation of translating the electronic camera 1 in a direction substantially parallel to the optical axis direction of the photographing lens 3. FIG. It is a figure which shows the time-sequential change of the image taken in by CCD20 when operation of FIG. 19 is performed. It is a figure which shows the time-sequential change of the image taken in by CCD20 when the electronic camera 1 is rotated around the Z-axis. It is a figure explaining the method of scrolling the image displayed on the screen of LCD6 using a scroll prohibition switch.

Explanation of symbols

1 Electronic Camera 2 Viewfinder 3 Shooting Lens 4 Light Emitting Unit (Flash)
5 Speaker 6 LCD (Display means)
6A Touch tablet 7 Operation key 7A Menu key 7B Execution key 7C Cancel key 7D Delete key 7E Scroll key 8 Microphone 9 Earphone jack 10 Release switch (prohibition means)
11 Power switch 12 Recording switch (prohibited means)
13 Continuous shooting mode switch 15 Red-eye reduction LED
16 Photometric element 17 Colorimetric element 20 CCD (detection means, imaging means)
21 Battery 22 Capacitor 23 Circuit board 24 Memory card (storage means)
26 Display element in viewfinder 30 Lens drive circuit 31 Image processing unit 32 Analog / digital conversion circuit (A / D)
33 Digital Signal Processor (DSP)
34 CCD drive circuit 35 Frame memory 36 Buffer memory 37 Strobe drive circuit 38 Red-eye reduction LED drive circuit 39 CPU (display change means, control means)
40 Display circuit in finder 41 Pen 42 A / D-D / A conversion circuit 43 ROM
45 timer 48 interface 51 photometric circuit 52 colorimetric circuit 53 aperture drive circuit 54 aperture 61 piezoelectric gyro (detection means)
62 Piezoelectric gyro drive circuit 71 Electronic compass (detection means)
72 Electronic compass drive circuit

Claims (14)

Display means for displaying at least one of images, characters, and figures;
Detection means for detecting at least one of movement and rotation of the display means;
Display changing means for changing display content displayed on the display means in accordance with at least one of movement and rotation of the display means detected by the detection means,
The information processing apparatus characterized in that the display change means changes display contents displayed on the display means in accordance with a movement amount or a rotation amount due to a plurality of movements or rotations of the display means. It further comprises an imaging means for imaging an image of a predetermined subject,
The information processing apparatus according to claim 1, wherein the detection unit detects at least one of movement and rotation of the display unit based on an output of the imaging unit. The display means displays a menu screen on which predetermined selection items are displayed,
The display change means changes the display of the menu screen so that a predetermined item of the selection items is selected according to the movement or rotation of the display means detected by the detection means. The information processing apparatus according to claim 1, wherein: The information processing apparatus according to claim 1, further comprising a prohibiting unit that prohibits the display changing unit from changing a display content displayed on the display unit. The display changing means displays the display contents to be displayed on the display means in response to detecting at least one of movement and rotation of the display means based on the highest contrast portion of the image being captured. change,
3. The illumination device according to claim 2, further comprising: an illuminating unit configured to irradiate the subject with light and increase the contrast of the image to be captured when it is determined that there is no high-contrast portion in the image being captured. Information processing device. The information processing apparatus according to claim 1, wherein the detection unit detects an azimuth and detects rotation of the display unit based on a time-series change of the detected azimuth. The information processing apparatus according to claim 6, wherein the detection unit includes an electronic compass. Control means for controlling the imaging means to take an image of the subject and storing the image of the subject taken by the imaging means in the storage means;
The display changing unit is configured to display the display unit when the control unit does not perform processing of causing the imaging unit to capture an image of the subject and storing the image of the subject captured by the imaging unit in the storage unit. The information processing apparatus according to claim 2, wherein the display content to be displayed is changed. The display change means enlarges or reduces the display content displayed on the display means when detecting movement of the display means in the optical axis direction based on the output of the imaging means. The information processing apparatus described in 1. The prohibiting means prohibits a process of changing display contents displayed on the display means by the display changing means when movement and rotation are detected while a predetermined switch is on. Item 5. The information processing apparatus according to Item 4. The prohibiting unit prohibits a process of changing display contents displayed on the display unit by the display changing unit when movement and rotation are detected while a predetermined switch is off. Item 5. The information processing apparatus according to Item 4. The display changing means rotates the display content displayed on the display means by a predetermined angle when detecting rotation around a predetermined straight line perpendicular to the screen of the display means based on the output of the imaging means. The information processing apparatus according to claim 2, wherein the information processing apparatus is an information processing apparatus. The display changing means scrolls the display content displayed on the display means in a predetermined direction when detecting a rotation around a predetermined straight line parallel to the screen of the display means based on the output of the imaging means. The information processing apparatus according to claim 2, wherein the information processing apparatus is an information processing apparatus. Display means for displaying at least one of images, characters and figures, detection means for detecting at least one of movement and rotation of the display means, and display contents displayed on the display means are changed. A recording medium used in an information processing apparatus comprising display change means,
A program for controlling the display changing means to change the display content displayed on the display means in accordance with the amount of movement or the amount of rotation caused by the movement or rotation of the display means detected by the detecting means. A recording medium characterized by being recorded.

Images