JP2005101874A - Imaging apparatus - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To prevent a finder image from blurring due to parallax caused, by switching a camera in performing magnification by switching a plurality of cameras having different focal distances. <P>SOLUTION: A cellular phone 2 is provided with a camera unit 18. The camera unit 18 is provided with a wide-angle camera, having a wide angle lens 20 and a telephotographic camera, having a telephoto lens 21. The camera unit 18 is provided with a range finder, a ranging light is projected from a light-projecting lens 22a toward an object, and a reflected light thereof is received by a light-receiving lens 22b to measure the photographing distance to the object. An effective imaging area is set in an imaging element of the wide angle camera so that the parallax between the wide-angle lens 20 and the telephoto lens 21 using a distance signal corresponding to the photographing distance, and the finder image is displayed on an LCD 15 by an imaging signal from the effective imaging area. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

  The present invention relates to an imaging apparatus capable of changing an imaging magnification, and more particularly to an imaging apparatus suitable for use in a small information terminal device such as a mobile phone or a PDA (Personal Digital Assistant).

  In recent years, an imaging apparatus using a solid-state imaging device such as a CCD image sensor or a CMOS type image sensor is incorporated in a small information terminal device such as a mobile phone or a PDA. An imaging device, a so-called digital camera, converts a subject image optically obtained by a photographic lens into an imaging signal using a solid-state imaging device, and electronically captures and records the image. As the density of pixels increases, the practicality as an imaging device is also increasing.

  In order to use such digital cameras more effectively, various studies have been made to provide a zoom function. In order to realize the zoom function, there are an optical zoom method in which the photographing lens itself is constituted by a zoom lens, or an electronic zoom method in which an image signal obtained from an image sensor is subjected to signal processing to electronically change a subject image. The optical zoom method can capture images with high resolution, but it not only increases the number of lenses, but also requires a lens moving mechanism, which makes it difficult to use in small terminal devices such as mobile phones. On the other hand, the electronic zoom system as known in Patent Documents 1 and 2 does not require a movable part and is effective in making it compact, but there is a drawback that resolution degradation is conspicuous as the zoom magnification increases.

  Both of the electronic zoom methods described in Patent Documents 1 and 2 are used in combination with an optical zoom method using a zoom lens. In the one described in Patent Document 1, an object image is optically enlarged by an optical zoom, and then an object is further expanded. The image is enlarged by the electronic zoom method, and it is inevitable that the resolution of the subject image is deteriorated together with the enlargement by the electronic zoom. The camera described in Patent Document 2 takes into account that the resolution of the zoom lens itself is high in the central portion of the imaging plane and low in the peripheral portion, and requires a peripheral portion of the subject image formed on the image sensor. When taking a picture, the image magnification is enlarged by electronic zoom using an image signal from the center of the image sensor, and the image magnification is enlarged by optical zoom when there is a concern about resolution degradation due to electronic zoom. I am doing so.

  However, since the cameras described in these patent documents all use a zoom lens, it is difficult to apply to a small information terminal device as described above. Against this background, an imaging device consisting of a wide-angle digital camera that combines a wide-angle lens and an image sensor and a telephoto digital camera that combines a telephoto lens and an image sensor is incorporated into a mobile phone, and either one is selected depending on the magnification. It has been studied to obtain a zoom function by selecting an image signal from an image sensor and combining electronic zoom processing. According to this, it is possible to perform photographing with less degradation of resolution as compared with the case of simply enlarging one type of image pickup signal with electronic zoom. In this case, it is of course possible to use three or more types of digital cameras having different focal lengths.

JP 2000-51253 A JP 2000-184259 A

  In the case of using the above-described imaging apparatus in which a plurality of digital cameras are combined, the optical axes of the individual photographing lenses are different, so that the subject images obtained through the respective image sensors are parallaxed. On the other hand, the subject image is confirmed and framed by a display device such as an LCD (Liquid Crystal Display) at the time of photographing the subject, but the displayed image is an imaging signal from one of the digital cameras selected according to the scaling operation. It is displayed based on. Therefore, when magnifying while performing the magnification operation while observing the displayed image, there is no problem while the magnification is being changed with the electronic zoom, but if the digital camera is switched during the magnification, In the moment, the subject image is shifted by an amount corresponding to the parallax in the display screen, which not only impairs the quality of the image pickup apparatus but is also not preferable in terms of operability such as reframing.

  The present invention was made in order to solve the above problems, and its purpose is to combine a plurality of digital cameras and select one of them in accordance with a zooming operation, and use a switchover configuration. An object of the present invention is to provide an imaging apparatus in which a subject image is not shifted in a screen of a display device when a digital camera is switched.

  In achieving the above object, the imaging device of the present invention is arranged close to each other toward the same subject side, provided with a plurality of photographing lenses having different focal lengths, and provided for each of these photographing lenses. A plurality of image sensors that output an image signal corresponding to the subject image formed by the photographing lens, and an image signal from the plurality of image sensors that is selectively switched according to an input signal from the zoom operation unit Switching means, and moving and adjusting the imaging center of at least one of the imaging elements to a pseudo imaging center so that the image centers of the subject images captured by each imaging element coincide with each other. An effective imaging area based on a reference is set, an extraction means for extracting an imaging signal from the effective imaging area, and an imaging signal selected by the switching means and the extraction means. And a display means for displaying the finder image Te.

  The zooming operation unit may be a multifocal switching operation unit that selects and switches one of a plurality of image sensors step by step, but preferably performs signal processing on an effective image signal obtained from each image sensor. In order to enhance the photographing function, it is effective to use an electronic zoom operation unit that is used together with an electronic zoom processing unit that electronically changes the size of the subject image. If the optical axes of the respective photographing lenses are made parallel to each other, each imaging element can be obtained from a known deviation amount and deviation direction between the optical axes and a distance signal obtained by a distance measuring device that measures the distance to the subject. An accurate effective area can be set within the imaging area.

  According to the imaging apparatus using the present invention, the finder image displayed on the display device does not shift in the display screen due to the scaling operation, and high-quality finder display is possible. Even when the electronic zoom is used together, the center of the finder image is not shifted in the display screen, and a smooth scaling display can be performed.

  FIG. 1 shows the appearance of a mobile phone incorporating the imaging device of the present invention. The cellular phone 2 includes a receiver unit 10 and a transmitter unit 11, which are connected to each other by a hinge portion 12 so as to be foldable. The receiver unit 10 includes an antenna 13, a receiver speaker 14, and a liquid crystal display (LCD) 15, and an electronic display such as an EL (electroluminescence) display can be used instead of the LCD 15.

  A camera unit 18 is further incorporated in the receiver unit 10 so as to be rotatable. A short-focus wide-angle lens 20 and a long-focus telephoto lens 21 are exposed on one surface of the camera unit 18. Behind these lenses, CCD image sensors are incorporated as imaging elements that convert the subject image formed by each lens into an electrical imaging signal, and constitute individual wide-angle cameras and telephoto cameras, respectively. ing. By rotating the dial 18a integrated with the camera unit 18, the camera unit 18 can be rotated within a range of 180 ° about a horizontal axis. Either the person photographing position facing forward or the general photographing position in which the camera unit 18 is rotated outward in the same direction by rotating the camera unit 18 so that the lenses 20 and 21 face upward. Positioned by click mechanism. The focal length of the wide-angle lens 20 is about 24 mm in terms of a photographic camera, and the focal length of the telephoto lens 21 is similarly about 60 mm. However, the focal length is not necessarily limited to these, and the focal lengths are relatively different. Good.

  The camera unit 18 incorporates a known active distance measuring device, and a distance measuring light projecting lens 22a and a light receiving lens 22b are exposed outside the respective lenses. Near-infrared light is projected from the light projection lens 22a toward the subject. When the reflected light enters the light receiving lens 22b, a PSD (Position Sensinig Device) provided in the back receives the light, and a photoelectric signal corresponding to the light receiving position is obtained. Since this photoelectric signal is a value corresponding to the distance to the subject, it can be used as a distance signal to the subject. A pan-focus type lens is used for the wide-angle lens 20 and the telephoto lens 21, and basically focusing is not necessary. For example, the telephoto lens 21 having a shallow depth of field or both lenses can be used. If it is moved in the direction of the optical axis in accordance with a distance signal obtained by the distance measuring device, it is possible to perform autofocusing.

  The transmitter unit 11 is provided with an operation unit 27 including a transmission microphone 24, a selection key 25, a dial key 26, and the like. These keys are basically used as an operation unit for calling or sending mail. In the vicinity of the cursor keys 28a and 28b in the selection key 25, indices T (tele) and W (wide) are attached. These cursor keys 28a and 28b are used as zoom operation keys during camera shooting. The enter key 29 is used as a release key for taking a still image. Reference numeral 30 denotes a memory card mounted in the memory slot of the transmitter unit 11 and is used for recording image data obtained by the imaging apparatus.

  FIG. 2 is a functional block diagram showing the electrical configuration of the mobile phone. The system controller 32 constituted by a microcomputer mainly includes an audio processing circuit 33 that controls audio input / output of the reception speaker 14 and the transmission microphone 24 and a wireless communication interface 34 that performs transmission / reception via the antenna 13. In addition to controlling the function of the telephone, when the use in the camera mode is set by the operation unit 27, the imaging device including the camera unit 18 is controlled.

  CCD image sensors 36 and 37 are provided on the image planes of the wide-angle lens 20 and the telephoto lens 21, respectively, and upon receiving a driving pulse from the CCD driver 38, an imaging signal of a subject image obtained by each lens is output. These image signals are converted into digital signals after well-known signal processing such as analog amplification, gamma correction, and color balance correction by signal processing circuits 39 and 40, respectively, and written into frame memories 42 and 43 by the system controller 32, respectively. These image data are read each time an image signal for one screen is output from the CCD image sensors 36 and 37. Therefore, the wide-angle image data obtained by the wide-angle camera is sequentially updated in the frame memory 42. The telephoto image data obtained by the telephoto camera is sequentially updated in the frame memory 43.

  When used in the camera mode, a ranging command is transmitted from the system controller 32 to the driver 45 at regular intervals, and ranging light in the near infrared range is irradiated from the infrared light emitting diode (IRED) 46 through the projection lens 22a. The distance measuring light reflected by the subject is received by the PSD 48 through the light receiving lens 22 b, and a photoelectric signal corresponding to the light receiving position is input to the distance calculating circuit 49. The distance calculation circuit 49 calculates a digitized distance signal according to the value of the input photoelectric signal and inputs it to the system controller 32.

  The rotation position detection sensor 50 detects whether the camera unit 18 is set at the person photographing position or the general photographing position, and inputs the set position information to the system controller 32. Since the top and bottom of the subject image changes depending on the orientation of the camera unit 18, the system controller 32 switches the top and bottom of the display image and the captured image according to the position information.

  One of the wide-angle image data and the telephoto image data updated in the frame memories 42 and 43 is input to the image data processing circuit 52 by a selection signal from the system controller 32. The image data processing circuit 52 receives the area information from the effective area setting circuit 53 and the electronic zoom information from the image magnification setting circuit 54 and performs signal processing on either the input wide-angle image data or telephoto image data. And write it into the image data memory 55. The image data written in the image data memory 55 is sent to the LCD driver 56. The LCD driver 56 modulates the image data in accordance with the size of the LCD 15 and the number of display pixels, and displays a finder image on the LCD 15.

  When the cursor key 28a is pressed in the camera mode, a clock pulse is added during the pressing and the number is written in the magnification counter 57. When the cursor key 28b is pressed, the count value of the magnification counter 57 is subtracted. The count-up is not performed after the count value of the scaling counter 57 reaches the limit value, and the count-down is not performed even after being subtracted to the initial value. Based on the count value of the magnification counter 57, it is determined which image data in the frame memories 42 and 43 is read by the image data processing circuit 52, and is input from the image magnification setting circuit 54 to the image data processing circuit 52. Electronic zoom information is determined.

  When the wide-angle image data is read by the image data processing circuit 52, the effective area setting circuit 53 sets a part of all the imaging areas of the CCD image sensor 36 of the wide-angle camera as an effective area. When this effective area information is input, the image data processing circuit 52 reads only image data belonging to the effective area from the frame memory 42. The setting of the effective area is determined according to the distance signal input from the distance calculation circuit 49.

  When framing is performed on the LCD 15 and the enter key (which becomes a release button) 29 is pressed, the image data stored in the image data memory 55 at that time is frozen. When a predetermined operation is performed on the operation unit 27, the freeze image is recorded on the memory card 30 by the media controller 60, and then the freeze image is cleared. When an operation that does not require recording is performed, recording to the memory card 30 is not performed, and a freeze image clear process is performed.

  Hereinafter, the operation when the mobile phone 2 is used in the camera mode will be described with reference to the flowchart shown in FIG. By switching to the camera mode, the imaging signals output from the CCD image sensor 36 of the wide-angle camera and the CCD image sensor 37 of the telephoto camera are subjected to predetermined signal processing by the signal processing circuits 39 and 40, respectively, and then framed. Wide-angle image data and telephoto image data are transferred to the memories 42 and 43.

  On the other hand, by switching to the camera mode, the system controller 32 transmits a distance measurement command to the driver 45, and the IRED 46 projects distance measurement light toward the subject through the light projection lens 22a. The distance measuring light reflected from the subject is imaged on the PSD 48 through the light receiving lens 22b, and the distance calculation circuit 49 calculates the distance signal based on the photoelectric signal and inputs it to the system controller 32.

  If the scaling operation has not been performed, the count value of the scaling counter 57 is an initial value (for example, “0”). When the cursor key 28a is pressed, zooming to the telephoto side is performed, and the count value of the zooming counter 57 is counted up, for example, every 0.2 seconds while the cursor key 28a is being pressed. As shown in FIG. 4, the image data processing circuit 52 reads wide-angle image data from the frame memory 42 until the count value of the scaling counter 57 reaches “C1” from “0”.

  When the zooming operation to the telephoto side is further performed and the count value of the zooming counter 57 changes from “C1” to “C2”, the telephoto image data in the frame memory 43 is received by the image data processing circuit 52 in response to this. It will be read. When the zooming operation to the wide-angle side is performed, when the count value of the zooming counter 57 changes from “C2” to “C1”, switching from reading the telephoto image data to reading to the wide-angle image data is performed. It is done.

  Further, in the process in which the count value of the magnification counter 57 changes from “0” to “C1”, the electronic zoom magnification changes from “× 1” to “× 2.5”. When the electronic zoom magnification is input to the image data processing circuit 52, the image data processing circuit 52 performs an enlargement process on the wide-angle image data in accordance with the input electronic zoom magnification, and the processed image data is stored in the image data memory 55. Forward to. This enlargement process is performed by enlarging the image data in the rectangular area corresponding to the electronic zoom magnification up to one screen with the screen center of the wide-angle image data as a reference. The higher the electronic zoom magnification, the narrower the rectangular area. . Therefore, although the pixel density is coarsened and the image quality is lowered depending on the degree of enlargement, the deterioration of the image quality can be made inconspicuous unless the electronic zoom magnification is extremely increased. In this example, since the focal length of the wide-angle lens 20 is 24 mm in terms of a photographic camera, an image is obtained at a magnification that changes the focal length of the wide-angle lens 20 from 24 mm to 60 mm by performing a process of gradually increasing the electronic zoom magnification. Data can be obtained.

  When the count value of the magnification counter 57 changes from “C1” to “C2”, the image data processing circuit 52 reads the telephoto image data from the frame memory 43 instead of the frame memory 42. At this time, the electronic zoom magnification is returned to “× 1” again, and when the zooming operation to the telephoto side is continued, the electronic zoom magnification changes from “× 1” to “× 2.5”. Since the telephoto image data stored in the frame memory 43 is obtained through the telephoto lens 21 having a focal length of 60 mm in terms of a photographic camera, the focal length of the telephoto lens 21 is changed from 60 mm to 150 mm by electronic zoom processing. Image data can be obtained at such a magnification.

  As described above, an imaging apparatus having a zoom magnification of 6.25 times can be obtained from shooting corresponding to a focal length of 24 mm to shooting corresponding to a focal length of 150 mm. In addition, since the electronic zoom magnification with respect to the image data obtained from the CCD image sensors 36 and 37 is only 2.5, extreme deterioration in image quality can be prevented. Of course, if the focal lengths of the wide-angle lens 20 and the telephoto lens 21 are about 25 mm and 50 mm and the electronic zoom magnification is suppressed to about “× 2”, a higher quality image can be obtained.

  By the way, since a wide-angle camera and a telephoto camera that are independent from each other are switched, the wide-angle image data, the screen center, and the telephoto image data screen center do not match due to the parallax between them. Therefore, when the image data is read by the image data processing circuit 52, the subject image displayed on the LCD 15 is simply read from the frame memory 43 instead of the wide-angle image data from the frame memory 42. Inevitably shifts at the moment of switching.

  In order to solve this problem, the effective area setting circuit 53 is used, and processing is performed so that the center of the subject image based on the wide-angle image data matches the center of the subject image based on the telephoto image data serving as the reference. FIG. 5 is a conceptual explanatory diagram of this correction processing. Since the optical axis 20a of the wide-angle lens 20 and the optical axis 21a of the telephoto lens 21 are parallel to each other, the imaging center of the CCD image sensor 36 behind the wide-angle lens 20 is assumed when the subject K1 at the shooting distance L1 is assumed. The optical axis 20a passing through S0 and the optical axis 21a passing through the imaging center of the CCD image sensor 37 behind the telephoto lens 21 are directed to different points of the subject K1.

  In order to eliminate the influence of the parallax due to the optical axis deviation, when the imaging signal is read out from the CCD image sensor 36, a line segment connecting the intersection P1 between the subject K1 and the optical axis 21a and the center of the wide-angle lens 20 is a CCD. The intersection S1 with the imaging surface of the image sensor 36 is set as a pseudo imaging center, and the effective imaging area of the CCD image sensor 36 is set based on this. Similarly, for the subject K2 at the shooting distance L2, the intersection S2 of the line segment from P2 is set as a pseudo imaging center, and the effective imaging area is set based on this. For this reason, when displaying the finder image on the LCD 15 or recording the image data of the subject image on the memory card 30, the image signal from the entire imaging area is used for the CCD image sensor 36 on the wide-angle camera side. In other words, an imaging signal belonging to the effective imaging area is extracted and used equivalently.

  The setting of the effective imaging area is specifically as shown in FIGS. FIGS. 6A and 6B show examples of subject images from the wide-angle camera and the telephoto camera at the shooting distance L1, and FIGS. 7A and 7B similarly show subject images at the shooting distance L2. The state of is expressed. The outermost rectangular outline W1 indicated by a broken line in FIG. 6A corresponds to the entire imaging area of the CCD image sensor 36, and the intersection of the diagonal lines corresponds to the imaging center S0. The inner rectangular outline W2 shown in practice corresponds to the effective imaging area determined based on the pseudo imaging center S1.

  The size of the effective imaging area, that is, the size of the area surrounded by the outline W2 is determined according to how much the pseudo imaging center is shifted depending on the imaging distance. That is, as can be seen from FIG. 6 and FIG. 7, the closer the shooting distance is, the closer the pseudo imaging center is to the right side (the optical axis side of the telephoto camera), so the closest distance that can be shot should be set short. It is necessary to narrow the effective imaging area. When the size and pixel pitch of the CCD image sensor 36 are fixed, the image quality deteriorates as the effective imaging area is narrowed. To cope with this, the CCD image sensor 36 used in the wide-angle camera has It is preferable to use an image pickup area having a size larger than that of the CCD image sensor 37 on the telephoto camera side or a fine pixel pitch.

  As can be seen from FIG. 5, how much the pseudo imaging centers S1 and S2 should be shifted from the imaging center S0 is uniquely determined by the imaging distances L1 and L2. Therefore, the positions of the imaging centers S1 and S2 can be determined according to the distance signal from the distance calculation circuit 49, and the effective imaging area W2 is obtained based on this. Then, the image data processing circuit 52 extracts image data included in the effective imaging area W2 when reading wide-angle image data from the frame memory 42, and further performs electronic zoom processing based on the pseudo imaging centers S1 and S2. The image data for one screen after processing is written in the image data memory 55. When image data from the signal processing circuit 39 is transferred to the frame memory 42, it is possible to extract only those belonging to the effective imaging area based on the pseudo imaging centers S1 and S2. Further, what belongs to the effective imaging area may be extracted at the stage of the imaging signal before digitally converting the imaging signal to image data.

  The image data thus written in the image data memory 55 has the same image center as that of the telephoto image data transferred to the frame memory 43, so that the image data processing circuit 52 is in the middle of performing the scaling operation. Even if the image data read source is switched between the frame memory 42 and the frame memory 43, the center of the subject image by the image data written in the image data memory 55 does not move. Accordingly, the finder image displayed on the LCD 15 is not shifted by the scaling operation, and smooth scaling display is performed.

  In the above embodiment, the CCD image sensor 37 on the telephoto camera side is used as a reference, and the effective imaging area of the CCD image sensor 36 on the wide angle side is adjusted with the imaging center fixed. This is because the subject image on the wide angle side has a smaller image magnification and is not conspicuous even if the movement of the pseudo imaging center is adjusted, but in principle, the CCD image sensor 36 on the wide angle side. It is also possible to adjust the movement of the effective imaging area with the CCD image sensor 37 on the telephoto side.

  It is also possible to set the optical axes 20a and 21a of the wide-angle lens 20 and the telephoto lens 21 so as to intersect at a predetermined shooting distance position. In this case, it is necessary to perform a pseudo movement adjustment process of the imaging center for both the CCD image sensors 36 and 37 according to the shooting distance, and whether the distance is shorter or longer than the predetermined shooting distance. Accordingly, it is necessary to change the moving direction of the pseudo imaging center. Furthermore, the present invention can also be applied when three or more types of digital cameras having different focal lengths are combined. Further, for example, the present invention can be applied to a multifocal type imaging apparatus that switches three or more digital cameras having different focal lengths according to a magnification operation, and an electronic zoom function is not necessarily required.

  The setting of the effective imaging area, especially the pseudo imaging center moving process, requires shooting distance information to the subject. In the above embodiment, an active distance measuring device is used. Not limited to only. For example, in the case of the above-described embodiment, the telephoto lens 21 serving as a reference for parallax correction can be moved and adjusted in the direction of the optical axis, and the contrast of the captured image is the highest as used in a general digital camera. It is also possible to employ a contrast-type autofocus mechanism that moves the telephoto lens so that the focus position of the telephoto lens at that time can be used for shooting distance information to the subject.

  For example, when the shooting distance is 5 m or more, the parallax becomes small, and the shift of the finder image is hardly noticeable on the display screen 15a of the LCD 15 without necessarily performing the moving process of the imaging center. Therefore, when the shooting distance is longer than a predetermined distance, the process of moving the pseudo imaging center may be omitted. Note that the shooting distance is not only calculated as a continuous value, but is also measured from close to infinity in two steps of perspective, or about 3 to 5 steps, and the movement of the pseudo imaging center is adjusted accordingly. Even if the steps are performed step by step, it is possible to display a finder image that is practically satisfactory.

1 is an external view of a mobile phone using the present invention. FIG. 2 is a functional block diagram showing an electrical configuration of the mobile phone in FIG. 1. It is a flowchart which shows the basic process under camera mode. It is a timing chart showing the state of electronic zoom and camera switching when a zooming operation is performed. It is explanatory drawing of the setting method of an effective imaging area. It is a conceptual diagram which shows an example of the to-be-photographed image image | photographed with a wide-angle camera and a telephoto camera at the shooting distance L1. It is a conceptual diagram which shows an example of the to-be-photographed image image | photographed with a wide angle camera and a telephoto camera at the shooting distance L2.

Explanation of symbols

2 Mobile phone 15 LCD
18 Camera unit 20 Wide-angle lens 21 Telephoto lens 46 IRED
48 PSD
42, 43 Frame memory 52 Image data processing circuit 53 Effective area setting circuit 54 Image magnification setting circuit 55 Image data memory

Claims (3)

A plurality of photographic lenses that are arranged close to each other toward the same subject and have different focal lengths,
A plurality of image sensors provided for each of these photographic lenses, for outputting an imaging signal corresponding to a subject image formed by each photographic lens;
A switching means for selectively switching and outputting the imaging signals from the plurality of imaging elements in accordance with an input signal from the scaling operation unit;
The imaging center of at least one of the imaging elements is adjusted to move to the pseudo imaging center so that the image centers of the subject images captured by the imaging elements coincide with each other, and effective imaging based on the pseudo imaging center is performed. An extraction means for setting an area and extracting an imaging signal from the effective imaging area, and a display means for displaying a finder image based on the imaging signal selected by the switching means and the extraction means are provided. Imaging device.   The zoom operation unit is an electronic zoom operation unit, and includes an electronic zoom processing unit that electronically changes the size of a subject image by performing signal processing on an effective imaging signal obtained from each imaging device. The imaging apparatus according to claim 1.   The optical axes of the plurality of photographing lenses are parallel to each other, and the imaging signal extraction unit sets the effective area according to a distance signal from a distance measuring device that measures a distance to a subject. The imaging apparatus according to 1 or 2.

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