JP4100214B2 - Mobile communication device - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
  The present invention relates to a portable communication device having a communication function for transmitting and receiving signals, and more particularly to a portable communication device having a photographing function.
[0002]
[Prior art]
  2. Description of the Related Art Conventionally, mobile phones that include a single focus lens and have a function of photographing a subject using the single focus lens are widely known. In addition, for example, the following patent document discloses a mobile phone that includes a cold mirror having a concave surface and has a function of photographing a subject using the cold mirror.
[0003]
  On the other hand, recent mobile phones are commercialized not only with a call function but also with a function capable of storing personal information and performing electronic payment.
[0004]
  This type of mobile phone may be used maliciously by a person who is not the owner of the mobile phone, such as leakage of personal information or unjustified electronic payment. It is required to check whether or not the user of the mobile phone is the owner, and to install a personal authentication function that permits the use of the mobile phone only when the user is the owner.
[0005]
[Patent Literature]
    Special Table 2002-530976
[0006]
[Problems to be solved by the invention]
  In response to this request, for example, the biometric information of the user of the mobile phone is photographed using the photographing function including the single focus lens and the cold mirror, and the photographed image and the registered image registered in advance are used. The following problems arise when attempting to implement the personal authentication function by permitting the use of the mobile phone only when these images match, and when these images match.
[0007]
  That is, in order to collate biometric information or the like, it is necessary to photograph the biometric information with relatively high accuracy (enlarged). It is necessary to make the focal position of the optical system mounted on the mobile phone different from the case of normal shooting.
[0008]
  Therefore, it is conceivable that the mobile phone is provided with an optical zoom mechanism that drives a zoom lens in the direction of the optical axis, for example, so that the focal length of the optical system can be changed. Since it is necessary to provide a place, a moving space for the zoom lens, etc., the size of the mobile phone inevitably increases, and the problem of durability of the drive unit arises.
[0009]
  The present invention has been made in view of the above circumstances, and provides a mobile communication device having a function capable of photographing a subject with high accuracy while avoiding problems of enlargement and durability of the device as much as possible. For the purpose.
[0010]
[Means for Solving the Problems]
  The invention according to claim 1 is a portable communication device provided with transmission / reception means for transmitting and receiving signals, an optical system having a large distortion in a peripheral region with respect to a central region, and an image formed by the optical system. An imaging unit that photoelectrically converts a light image of a subjectAn extraction unit for extracting an image projected on the imaging unit by the central region from an image related to the output signal of the imaging unit, an enlargement unit for enlarging the extracted image at a predetermined magnification, and the enlarged image The storage unit for storing, the first mode for storing the enlarged image in the storage unit, the specific information to be verified obtained from the extracted image, and the specific information stored in advance in a predetermined communication device are collated Therefore, a mode switching control unit that switches the mode between the second mode that causes the transmission / reception means to transmit the extracted image to the predetermined communication device;It is a portable communication apparatus provided with.
[0011]
  According to this invention, since the optical system has a large distortion in the peripheral area with respect to the central area, the optical image formed by the optical system is the optical image of the subject projected by the central area, The image is enlarged compared to the optical image of the subject projected by the peripheral area, and the image related to the output signal of the imaging unit shows the subject located on the center side larger than the subject located on the peripheral side. It becomes an image.
[0012]
  Therefore, the center region and the peripheral region of the optical system have a function of performing normal shooting such as snap shooting and landscape shooting, and the biological information can be captured with high accuracy by capturing, for example, biological information in the central region. it can.
[0013]
  Thereby, when collating biometric information etc. using this picked-up image, the collation can be performed with high precision.
[0014]
  Further, in a normal optical system (a lens in which the relationship between the height Y of the optical image to be formed, the focal length f, and the angle of view θ is represented by Y = f · tan θ), the zoom magnification equivalent to that in the central region is used. However, in the present invention, the use of the optical system as described above eliminates the need for the zoom mechanism and the like, compared with the case of using a normal optical system. Thus, it is advantageous in terms of durability and size.
[0015]
  Moreover, according to the present invention,When the light image of the subject is photoelectrically converted by the imaging unit, the extraction unit extracts an image projected on the imaging unit by the central region from the image related to the output signal of the imaging unit.
[0016]
  On the other hand, the mobile communication device has a first mode in which the extracted image is enlarged at a predetermined magnification by the enlargement unit, and the enlarged image is stored in the storage unit; A second mode for causing the transmission / reception means to transmit the extracted image to the predetermined communication device in order to collate with the unique information stored in advance in the communication device, and the mode switching control unit The mode is switched between the second mode.
[0017]
  As a result, a normal shooting function such as snap shooting or landscape shooting is checked against the mobile communication device and whether or not the user of the mobile communication device is the owner. A personal authentication function permitting use of the mobile communication device can be installed.
[0018]
  In addition, a configuration in which unique information to be collated with the specific information to be collated obtained from the extracted image is stored in advance, a specific information to be collated from the extracted image, and unique information stored in a predetermined communication device in advance. Since the predetermined communication device is provided with the configuration for performing the collation, it is not necessary to provide the storage unit in the device as compared to the case where the mobile communication device includes the storage unit that stores the unique information in advance. Accordingly, it is possible to reduce the size of the device and reduce the cost, to make it difficult to forge the unique information, and to prevent or suppress unauthorized use of the mobile communication device.
[0019]
  The invention described in claim 2A portable communication device having transmission / reception means for transmitting / receiving a signal, and photoelectrically converts an optical system having a large distortion in a peripheral region with respect to a central region and a light image of a subject formed by the optical system An imaging unit; an extraction unit that extracts an image projected on the imaging unit by the central region from an image related to an output signal of the imaging unit; an enlargement unit that enlarges the extracted image at a predetermined magnification; The first storage unit that stores the enlarged image, the second storage unit that stores the acquired unique information in advance, the unique information to be collated obtained from the extracted image, and the second storage unit that are stored in advance A collation unit that collates with unique information, a first mode in which the extracted image is enlarged at a predetermined magnification by the enlargement unit, and the enlarged image is stored in the first storage unit; Specific information to be matched Mode switching system for switching the mode between the second mode for matching the pre-stored specific information in the second storage unit Mobile communication device provided with a control unit.
[0020]
  According to this invention, since the optical system has a large distortion in the peripheral area with respect to the central area, the optical image formed by the optical system is the optical image of the subject projected by the central area, The image is enlarged compared to the optical image of the subject projected by the peripheral area, and the image related to the output signal of the imaging unit shows the subject located on the center side larger than the subject located on the peripheral side. It becomes an image.
[0021]
  Therefore, the center region and the peripheral region of the optical system have a function of performing normal shooting such as snap shooting and landscape shooting, and the biological information can be captured with high accuracy by capturing, for example, biological information in the central region. it can.
[0022]
  Thereby, when collating biometric information etc. using this picked-up image, the collation can be performed with high precision.
[0023]
  In addition, a normal optical system (the relationship between the height Y of the formed optical image, the focal length f, and the angle of view θ is Y = f · tan In order to obtain a zoom magnification equivalent to that in the central region with a lens represented by θ), a zoom mechanism or the like is required. However, in the present invention, by using the optical system as described above, A zoom mechanism or the like is unnecessary, which is advantageous in terms of durability and size as compared with the case of using a normal optical system.
[0024]
  Moreover, according to the present invention,When the light image of the subject is photoelectrically converted by the imaging unit, the extraction unit extracts an image projected on the imaging unit by the central region from the image related to the output signal of the imaging unit.
[0025]
  On the other hand, the mobile communication device includes a first mode in which the extracted image is enlarged at a predetermined magnification by the enlargement unit, and the enlarged image is stored in the first storage unit, and unique information of the collation target obtained from the extracted image And a second mode in which the unique information stored in advance in the second storage unit is collated, and the mode switching control unit can switch the mode between the first mode and the second mode. Done.
[0026]
  As a result, a normal shooting function such as snap shooting or landscape shooting is checked against the mobile communication device and whether or not the user of the mobile communication device is the owner. It can be equipped with a personal authentication function that permits the use of mobile communication devices.
[0027]
  In addition, a configuration in which unique information to be collated with the specific information to be collated obtained from the extracted image is stored in advance, a specific information to be collated from the extracted image, and unique information stored in a predetermined communication device in advance. Since the mobile communication device is provided with the configuration for performing the above verification, the configuration for performing the above verification is simplified.
[0028]
  Claim3The invention described in claim 1Or 2In the mobile communication device described in the above, the optical system has a single focal point lens that forms an optical image of a subject on the imaging surface of the imaging unit, and a peripheral region having a large distortion with respect to a central region, Between a first position where an optical image of a subject is formed with a single focus lens and a second position retracted from the first position so as to form an optical image of the subject with only the single focus lens. And a foveal lens configured to be relatively movable.
[0029]
  According to the present invention, when the foveal lens is positioned at the first position, the entire optical system has a large distortion in the peripheral region with respect to the central region, and the object projected by the central region Is enlarged as compared with the light image of the subject projected by the peripheral region. Therefore, the image related to the output signal of the imaging unit is an image in which the subject located on the center side is larger than the subject located on the peripheral side.
[0030]
  When the foveal lens is positioned at the second position, the entire optical system has the characteristics of a single focus lens, and the height Y, the focal length f, and the angle of view θ of the optical image to be formed. Thus, an image corresponding to the optical image represented by Y = f · tan θ can be obtained.
[0031]
  The invention according to claim 4A portable communication device having a transmission / reception means for transmitting / receiving a signal, wherein a single-focus lens that forms an optical image of a subject on an imaging surface of the imaging unit, and a peripheral region having a large distortion aberration with respect to a central region. A first position where an optical image of the subject is formed with the single focus lens, and a second position retracted from the first position so as to form an optical image of the subject with only the single focus lens. And a foveal lens configured to be relatively movable between and an imaging unit that photoelectrically converts a light image of a subject formed by the optical system.
[0032]
  According to the present invention, when the foveal lens is positioned at the first position, the entire optical system has a large distortion in the peripheral region with respect to the central region, and the object projected by the central region Is enlarged as compared with the light image of the subject projected by the peripheral region. Therefore, the image related to the output signal of the imaging unit is an image in which the subject located on the center side is larger than the subject located on the peripheral side.
[0033]
  Therefore, the center region and the peripheral region of the optical system have a function of performing normal shooting such as snap shooting and landscape shooting, and the biological information can be captured with high accuracy by capturing, for example, biological information in the central region. it can. Thereby, when collating biometric information etc. using this picked-up image, the collation can be performed with high precision.
[0034]
  In addition, a normal optical system (the relationship between the height Y of the formed optical image, the focal length f, and the angle of view θ is Y = f · tan In order to obtain a zoom magnification equivalent to that in the central region with a lens represented by θ), a zoom mechanism or the like is required. However, in the present invention, by using the optical system as described above, A zoom mechanism or the like is unnecessary, which is advantageous in terms of durability and size as compared with the case of using a normal optical system.
[0035]
  When the foveal lens is positioned at the second position, the entire optical system has the characteristics of a single focus lens, and the height Y, the focal length f, and the angle of view θ of the optical image to be formed. Thus, an image corresponding to the optical image represented by Y = f · tan θ can be obtained.
[0036]
DETAILED DESCRIPTION OF THE INVENTION
  An embodiment of the present invention will be described.
[0037]
  FIG. 1 is a diagram showing a schematic configuration of an embodiment of a mobile communication device according to the present invention.
[0038]
  As shown in FIG. 1, the mobile communication device 1 is a mobile phone that includes an operation unit 2, an audio input unit 3, an audio output unit 4, a display unit 5, an antenna 6, and an imaging unit 7.
[0039]
  The operation unit 2 has a plurality of push buttons to which numbers, functions, and the like are assigned, and is used for inputting telephone numbers and various commands.
[0040]
  The voice input unit 3 is used to input the voice of the user of the mobile communication device 1 and includes, for example, a microphone that converts the voice into an electrical signal.
[0041]
  The audio output unit 4 outputs sound or the like sent from other communication devices to the outside, and is configured by, for example, a speaker that converts an electrical signal into sound.
[0042]
  The display unit 5 displays a telephone number input by a push button, various setting screens for setting the operation of the mobile communication device 1, or an image taken by the imaging unit 7.
[0043]
  The antenna 6 is used to transmit and receive radio waves so as to communicate with other communication devices.
[0044]
  The imaging unit 7 includes an optical system 71 and an imaging device 72 (see FIG. 5), which will be described later, and captures a light image of a subject within the field of view of the optical system 71.
[0045]
  The mobile communication device 1 having the above configuration can communicate with the owner through a mobile communication device (not shown) owned by another person, such as a call or transmission / reception of an image captured by the imaging unit 7.
[0046]
  In addition to this function, the mobile communication device 1 of the present embodiment constructs a personal authentication system configured to be able to communicate with the computer 100 via a communication network, as shown in FIG. This personal authentication system is equipped with a security function.
[0047]
  The security function acquires the biological information of the user of the mobile communication device 1 (in this embodiment, the iris information of the eye), and uses the biological information to allow the user to own the mobile communication device 1 If the mobile communication device 1 is determined to be the owner of the mobile communication device 1, the use of the mobile communication device 1 is permitted, so that the person who is not the owner of the mobile communication device 1 is malicious. This is a function to prevent the use of.
[0048]
  The biological information is physical information unique to an individual person that does not change over time, and is information that can identify an individual person.
[0049]
  As will be described later, the collation of whether or not the user of the mobile communication device 1 is the owner of the device is a captured image of biometric information received by the computer 100 from the mobile communication device 1 via the communication network. And a photographed image of personal information relating to the owner of the mobile communication device 1 registered in the database of the computer 100.
[0050]
  The mobile communication device 1 according to the present embodiment includes a normal shooting mode in which normal shooting is performed and a matching shooting mode in which the above matching is performed. As described later, each image is generated for an image generated in each mode. The process up to is different. Switching between these photographing modes can be performed by operating a predetermined push button.
[0051]
  The mobile communication device 1 employs an optical system 71 (see FIG. 5) having characteristics described below as an optical system for capturing an optical image of a subject.
[0052]
  FIG. 2A is a graph showing the distortion aberration / field angle characteristics of the optical system 71, the horizontal axis is the distortion aberration X expressed as a percentage, and the vertical axis is the angle of view θ expressed in degrees (°). . FIG. 2B is a graph showing the angle of view / image height characteristics, the horizontal axis is the angle of view θ, and the vertical axis is the image height Y.
[0053]
  As shown in FIG. 2A, in the optical system 71, in a region where the field angle θ is small (a region up to about 5 degrees in FIG. 2), the distortion aberration X is a predetermined value Xi, and the field angle θ is the region. It has the characteristic of rapidly increasing when the value exceeds.
[0054]
  Here, the predetermined value Xi in the distortion aberration X is a value that looks like a natural image without a similar distortion when a human views an image of an optical image of a subject that has passed through the central region of the optical system 71. 3%. Of course, even if the predetermined value Xi is set to a value of 3% or less, for example, about 2% or about 1%, it looks like a natural image without similar distortion in human appearance.
[0055]
  FIG. 2A shows the characteristics of the optical system 71 having a distortion of about −70% at a half angle of view of about 50 degrees.
[0056]
  Due to this characteristic, as shown in FIG. 2B, the height Y of the optical image formed on the optical system 71 (hereinafter referred to as image height) Y is in a region where the angle of view θ is small (FIG. 2B). In the area on the left side of the dotted line), the image height Y is substantially linear with respect to the angle of view θ, and the amount of change with respect to the unit change of the angle of view θ is large.
[0057]
  On the other hand, in the region where the angle of view θ is large (the region on the right side of the dotted line shown in FIG. 2B), the image height Y is nonlinear with respect to the angle of view θ, and the amount of change with respect to the unit change of the angle of view θ is As the angle of view θ increases, it gradually decreases, and the image height Y becomes a substantially constant value.
[0058]
  In other words, the resolution is high in the region where the angle of view θ is small, and the resolution is low in the region where the angle of view θ is large.
[0059]
  Then, by appropriately setting the radius of curvature of the optical system 71 and the like, the optical system 71 is equivalent to the central region (corresponding to “region with a small angle of view θ”) of the optical system 71 where a large image height Y is obtained. Compared to the case where the zoom magnification is obtained by using a normal lens instead of the optical system 71, the zoom lens has a wide field of view and a peripheral region of the optical system 71 having the wide field of view (“region having a large angle of view θ”). Compared with the case where a normal lens is used instead of the optical system 71, the optical image of the subject is projected larger in the central region of the optical system 71.
[0060]
  In this sense, in the following description, the central region of the optical system 71 is referred to as a telephoto region, and the peripheral region is referred to as a wide-angle region.
[0061]
  A foveal lens is a lens that has a function of enlarging an image in a central region (corresponding to a telephoto region) in a visual field and compressing an image in a peripheral region (corresponding to a wide-angle region). It has features such as a natural image that is inconspicuous in the resolution and telephoto regions.
[0062]
  The normal lens mentioned above refers to a lens in which the relationship between the image height Y, the focal length f, and the field angle θ is represented by Y = f · tan θ.
[0063]
  By photographing using the optical system 71 having the above characteristics, the image output by the imaging unit 7 is a portion corresponding to a wide-angle region of the optical system 71 (hereinafter, as shown in FIG. 3, for example). While this portion is referred to as a wide-angle area), a wide area subject is compressed, while the portion corresponding to the telephoto area of the optical system 71 (hereinafter, this portion is referred to as a high-definition area) is located in the center portion. The subject is enlarged as compared with the subject located in the peripheral portion.
[0064]
  Therefore, the imaging unit 7 can capture a wide field of view while capturing the central portion of the capturing area with high resolution.
[0065]
  The mobile communication device 1 in the present embodiment has the following functions that use the characteristics of the optical system 71.
[0066]
  That is, as described above, in the telephoto area of the optical system 71, a large optical image of the subject is projected and a high-resolution image is obtained. As shown in FIG. 4, the user of the mobile communication device 1 By capturing the iris in the telephoto area of the optical system 71, it is possible to photograph the iris with high resolution. As a result, this captured image can be collated with a registered image described later with high accuracy. The high-definition area shown in FIG. 4 indicates an area captured in the telephoto area of the optical system 71.
[0067]
  Further, the optical system 71 can capture a subject with high resolution by capturing the subject in the telephoto area of the optical system 71 even in normal photographing. As will be described later, in the present embodiment, an image of a portion having a high resolution captured in the telephoto area of the optical system 71 is extracted and displayed on the display unit 5, so that the extracted image is displayed with a high resolution. Part 5 can be displayed.
[0068]
  FIG. 5 is a block diagram illustrating a configuration of the mobile communication device 1.
[0069]
  As shown in FIG. 5, the mobile communication device 1 includes an optical system 71, an image sensor 72, a signal processing unit 8, an A / D conversion unit 9, an image processing unit 10, an image memory 11, and a control unit 12. ing.
[0070]
  The optical system 71 corresponds to the optical system described above.
[0071]
  The imaging element 72 has a plurality of photoelectric conversion elements such as photodiodes arranged in a two-dimensional matrix, and the light receiving surface of each photoelectric conversion element has R (red), G (green), and B (blue) colors, respectively. This is a CCD color area sensor in which filters are arranged at a ratio of 1: 2: 1.
[0072]
  The image sensor 72 converts an optical image of the subject formed by the optical system 71 into electrical signals (images) of R (red), G (green), and B (blue) color components every 1/30 (seconds), for example. Signal) and output as R, G, B image signals. Note that the image sensor 72 may be a monochrome image sensor.
[0073]
  The image pickup device 72 performs image pickup operations such as start and end of the exposure operation of the image pickup device 72 and reading of output signals of each pixel (horizontal synchronization, vertical synchronization, transfer) in the image pickup device 72 by a timing generator (not shown). Be controlled.
[0074]
  The signal processing unit 8 performs predetermined analog signal processing on the analog image signal output from the image sensor 72. The signal processing unit 8 includes a CDS (correlated double sampling) circuit and an AGC (auto gain control) circuit, reduces noise of the image signal by the CDS circuit, and adjusts the level of the image signal by the AGC circuit.
[0075]
  The A / D conversion unit 9 converts the analog R, G, B image signals output from the signal processing unit 8 into digital image signals (hereinafter referred to as digital signals) composed of a plurality of bits. is there.
[0076]
  The image processing unit 10 applies black level correction for correcting the black level to a reference black level for each of the R, G, and B digital signals A / D converted by the A / D conversion unit 9, and white for the light source. White balance, R (red), G (green), B (blue) digital signals for level conversion of digital signals of R (red), G (green), B (blue) color components based on the standard Γ correction is performed to correct the γ characteristic.
[0077]
  The image memory 11 is a memory that temporarily stores an image output from the image processing unit 10 and is used as a work area for performing later-described processing on the image data by the control unit 12.
[0078]
  The operation unit 2 corresponds to the operation unit 2 shown in FIG. 1. For example, as shown by dotted lines A and B in FIG. 3, the operation unit 2 is used to set an image area (zoom magnification) displayed on the display unit 5. Includes zoom magnification setting operation section.
[0079]
  The control unit 12 includes a microcomputer having a built-in storage unit (a storage unit 126 described later) including, for example, a ROM that stores a control program and a RAM that temporarily stores data, and the mobile communication device 1 and the mobile communication described above. The driving of each member in the main body of the device 1 is organically controlled, and the photographing operation of the mobile communication device 1 is comprehensively controlled.
[0080]
  The control unit 12 functionally includes a mode switching control unit 121, a parameter setting unit 122, an extraction unit 123, an enlargement unit 124, an image rearrangement processing unit 125, and a storage unit 126.
[0081]
  When the mobile communication device 1 is turned on, the mode switching control unit 121 sets the collation shooting mode, collates biometric information in the collation photographing mode, and the captured image of the biometric information matches the registered image. When it is determined (the user is determined to be the owner), the mode is switched to the normal shooting mode.
[0082]
  Here, image generation processing in the collation shooting mode and the normal shooting mode will be described.
[0083]
  In the collation shooting mode, the mobile communication device 1 extracts an image of a preset area from the image temporarily stored in the image memory 11, and sends the extracted image to the computer 100 via the communication network. Send.
[0084]
  In the normal shooting mode, after extracting an image of a region corresponding to the zoom magnification instructed via the operation unit 2 from the image temporarily stored in the image memory 11, the extracted image is subjected to digital zoom. The display size of the display unit 5 is enlarged. Then, the enlarged image is displayed on the display unit 5, and when there is an image transmission instruction, it is transmitted to another communication device.
[0085]
  Returning to FIG. 5, the parameter setting unit 122 sets parameters corresponding to the area of the image extracted by the extraction unit 123 described later and the enlargement ratio of the enlargement unit 124. The parameter setting unit 122 sets a parameter corresponding to a predetermined zoom magnification in the collation shooting mode, and sets a parameter according to the zoom magnification set by the operation unit 2 in the normal shooting mode.
[0086]
  For example, the parameter setting unit 122 sets the parameter α1 for extracting the area indicated by the arrow C in the collation shooting mode as shown in FIG. 4, and in the normal shooting mode, as shown in FIG. When an operation for setting a certain zoom magnification is performed according to 2, the parameters α2 and α3 for extracting the regions indicated by the arrows A and B are set.
[0087]
  The extraction unit 123 extracts an image of a portion (hereinafter, referred to as a high-definition image) that has been greatly enlarged by the telephoto area in accordance with the parameters set by the parameter setting unit 122 from the images stored in the image memory 11. Is.
[0088]
  The enlargement unit 124 enlarges the image extracted by the extraction unit 123 to the display size of the display unit 5 according to the parameter set by the parameter setting unit 122 in the normal shooting mode.
[0089]
  The image rearrangement processing unit 125 applies the image enlarged by the enlargement unit 124 according to the size of the parameter set by the parameter setting unit 122 and, further, the size of the zoom magnification input by the operation unit 2. Distortion correction.
[0090]
  That is, when the zoom magnification is set to be smaller than a predetermined threshold, when the image extracted by the extraction unit 123 includes an image of a wide angle area, the image is distorted between the wide angle area and the high definition area. .
[0091]
  In order to eliminate this distortion, the image rearrangement processing unit 125 extracts some pixels from the image temporarily stored in the image memory 11 and generates one image (rearrangement image) with the extracted pixels. Therefore, by rearranging the extracted pixels based on a predetermined conversion table that determines how the pixel data of the extracted pixels is to be arranged, a rearranged image with little or no distortion is generated. .
[0092]
  Since the rearranged image is corrected for distortion, the visibility of the image on the display unit 5 is good. However, if the rearrangement process is performed, it takes much time, so the display unit The display of the captured image on 5 is delayed. As a result, the operability in shooting with the mobile communication device 1 such as missing a photo opportunity is reduced.
[0093]
  Therefore, in this embodiment, it is not shown whether to display a distorted image on the display unit 5 without performing the rearrangement process, or to display an image with less distortion on the display unit 5 by performing the rearrangement process. The switch is configured to be switchable so that the user can select one of them.
[0094]
  The image memory 14 is an image memory that temporarily stores the image data enlarged by the enlargement unit 124.
[0095]
  The display unit 5 corresponds to the display unit 5 in FIG. 1, and displays the image data temporarily stored in the image memory 15 as an image.
[0096]
  The image memory 14 temporarily stores the image data of the image extracted by the extraction unit 123.
[0097]
  The transmission / reception unit 15 has the configuration shown in FIG. 6, and communicates various data such as audio data and image data temporarily stored in the image memory 11 with other portable communication devices and the computer 100. Is what you do.
[0098]
  FIG. 6 is a block diagram illustrating a configuration of the transmission / reception unit 15.
[0099]
  As shown in FIG. 6, the transmission / reception unit 15 includes an audio input unit 3, an audio output unit 4, an antenna 6, a duplexer 15-1, an LNA (Low Noise Amplifier) 15-2, and a SAW (Surface Acoustic Wave) filter 15-3. PLL (Phase Locked Loop) frequency synthesizer 15-4, MIX 15-5, modulator / demodulator 15-6, speech codec 15-7, MIX 15-8, PA 15-9, and I / F unit 15-10.
[0100]
  The audio input unit 3, the audio output unit 4, and the antenna 6 correspond to the audio input unit 3, the audio output unit 4, and the antenna 6 shown in FIG.
[0101]
  The duplexer 15-1 includes a band-pass filter having a transmission frequency in the pass band and a band-pass filter having the reception frequency in the pass band, and separates the transmission signal and the reception signal.
[0102]
  The LNA 15-2 is a low noise amplifier that amplifies the received signal separated by the duplexer 15-1 among the signals received by the antenna 6.
[0103]
  The SAW filter 15-3 extracts only a signal addressed to the mobile communication device 1 from various signals included in the received signal.
[0104]
  Although not shown in detail, the PLL frequency synthesizer 15-4 includes a phase detector, a low-pass filter, a voltage control oscillator, and the like, and outputs a local oscillation signal generated thereby to the MIX 15-5.
[0105]
  The MIX 15-5 mixes the local oscillation signal from the PLL frequency synthesizer 15-4 with the output signal of the SAW filter 15-3.
[0106]
  The modem 15-6 performs spread modulation including modulation (primary modulation) for narrowing the band of the output signal (transmission data) of the voice codec and modulation (secondary modulation) using a predetermined code. Or despread demodulation on the output signal (received data) of MIX15-5.
[0107]
  The speech coder / decoder 15-7 encodes the speech signal input from the speech input unit 3 and outputs it to the modulator / demodulator 15-6, or decodes the output signal of the modulator / demodulator 15-6. Or output to the audio output unit 4.
[0108]
  The MIX 15-8 mixes the output signal of the modem 15-6 with the local oscillation signal from the PLL frequency synthesizer 15-4.
[0109]
  A PA (Power Amplifier) 15-9 amplifies an output signal from the MIX 15-8 and outputs the amplified signal to the duplexer 15-1.
[0110]
  The interface (I / F) unit 15-10 sends the command information input from the operation unit 2 to the modem 15-6, and sends the image signal from the modem 15-6 to the display unit 5. Is.
[0111]
  In the transmission / reception unit 15 having the above configuration, for example, when a reception signal (audio signal) is transmitted from another portable communication device and the audio signal is separated by the duplexer 15-1, the separated audio is obtained by the LNA 15-2. After the signal is amplified, an audio signal addressed to the mobile communication device 1 is extracted by the SAW filter 15-3.
[0112]
  The extracted speech signal is mixed with the local oscillation signal from the PLL frequency synthesizer 15-4 by the MIX 15-5, despread and demodulated by the modem 15-6, and then the speech codec 15-7. Decoding processing is performed and output to the audio output unit 4. Thereby, a sound is output from the sound output unit 4.
[0113]
  Further, the image signal transmitted from the other portable communication device is transmitted from the other portable communication device in the duplexer 15-1, the LNA 15-2, the SAW filter 15-3, the MIX 15-5, and the modem 15-6. After the same processing as that for the audio signal is performed, the image signal is output to the display unit 5 via the I / F unit 15-12. As a result, an image is displayed on the display unit 5.
[0114]
  On the other hand, when voice is input to the voice input unit 3 of the mobile communication device 1 in the transmitter / receiver 15, the voice codec 15-7 performs encoding processing on the voice signal, The spread modulation is performed by the modem 15-6.
[0115]
  The voice signal subjected to the spread modulation is mixed with the local oscillation signal from the PLL frequency synthesizer 15-4 by the MIX 15-8, and the mixed signal is amplified by the PA 15-9.
[0116]
  Then, the audio signal to be transmitted is separated by the duplexer 15-1, and this audio signal is transmitted from the antenna 6 to another portable communication device.
[0117]
  The image signal of the image taken by the mobile communication device 1 is output to the modem 15-6 via the I / F unit 15-10, and then the modem 15-6, MIX15-8, PA15−. 9 and the duplexer 15-1 are processed in the same manner as the audio signal input to the audio input unit 3 of the mobile communication device 1, and the audio signal is transmitted from the antenna 6 to another mobile communication device.
[0118]
  The storage unit 16 includes an image storage unit that stores captured images, and a table storage unit that stores commands and parameters input by the operation unit 2 in a table format.
[0119]
  As illustrated in FIG. 7, the computer 100 includes a control unit 101, a transmission / reception unit 102, and a storage unit 103.
[0120]
  The control unit 101 includes, for example, a microcomputer having a ROM that stores a control program and a RAM that temporarily stores data. The control unit 101 performs overall control of the operation of the computer and transmits biological information transmitted from the mobile communication device 1. A collation unit 1011 that performs collation is provided.
[0121]
  The collation unit 1011 reads the iris image (hereinafter referred to as a registered image) of the owner of the mobile communication device 1 stored in advance in the storage unit 103, and the registered image and the captured image transmitted from the mobile communication device 1. Are matched. When the collation is completed, the collation unit 1011 generates information indicating the result (hereinafter referred to as collation result information).
[0122]
  The transmission / reception unit 102 communicates collation result information, captured images, and the like with the mobile communication device 1 via the communication network.
[0123]
  The storage unit 103 stores in advance an image relating to the iris of the owner of the mobile communication device 1.
[0124]
  Next, a series of imaging processes of the mobile communication device 1 according to the present embodiment will be described.
[0125]
  FIG. 8 is a flowchart showing a series of imaging processing of the mobile communication device 1.
[0126]
  As shown in FIG. 8, when the normal photographing mode is selected by the operation unit 2 (YES in step # 1), it is determined whether or not the zoom magnification is set by the operation unit 2 (step # 2).
[0127]
  When the zoom magnification is set (YES in step # 2), the parameter setting unit 122 sets the parameter to α3 (step # 3), and when the zoom magnification is not set (NO in step # 2). The parameter setting unit 122 sets the parameter to α2 (step # 4).
[0128]
  When a shooting instruction is given by the operation unit 2 (YES in step # 5), imaging is performed by the image sensor 72 (step # 6), and the extraction unit 123 and the enlargement unit 124 temporarily store the image in the image memory 11. An image of an area corresponding to the parameter α2 or α3 set in step # 3 or # 4 is extracted from the stored image, and then enlarged to the display size of the display unit 5 (step # 7).
[0129]
  Thereafter, the enlarged image is displayed on the display unit 5 and stored in the storage unit 16 (step # 8). When there is an instruction to transmit the image (YES in step # 9), the transmission / reception unit 15 transmits the image to another communication device (step # 10).
[0130]
  When the power of portable communication device 1 is turned off after image transmission in step # 10 or without an image transmission instruction in step # 9 (YES in step # 11), a predetermined power-off process is performed. (Step # 12), and the process ends.
[0131]
  On the other hand, when the collation shooting mode is selected by the operation unit 2 in step # 1 (NO in step # 1), the parameter is set to α1 by the parameter setting unit 122 (step # 13).
[0132]
  When a shooting instruction is given by the operation unit 2 (YES in step # 14), imaging is performed by the image sensor 72 (step # 15), and is temporarily stored in the image memory 11 by the extraction unit 123. An image of an area corresponding to the parameter α1 set in step # 4 or # 13 is extracted from the image (step # 16).
[0133]
  Thereafter, the transmission / reception unit 15 transmits the extracted image to the computer 100 (step # 17), and the transmission / reception unit 15 receives from the computer 100 a signal indicating that the captured image matches the registered image (step # 18). Then, use of the portable communication device 1 is permitted (step # 19), and the process returns to step # 2.
[0134]
  On the other hand, when the transmitter / receiver 15 receives from the computer 100 a signal indicating that the captured image does not match the registered image (NO in step # 18), the use of the mobile communication device 1 is prohibited (step # 20). ) Then finish.
[0135]
  As described above, since the optical system 71 having the above-described characteristics is mounted, the biological information can be obtained by capturing biological information, for example, in the central region while having a function of performing normal photography such as snap photography and landscape photography. Can be photographed with high accuracy.
[0136]
  As a result, when the mobile communication device 1 is the owner by comparing the normal shooting function such as snap shooting or landscape shooting with the user of the mobile communication device 1 as the owner. Only a personal authentication function that permits the use of the mobile communication device 1 can be installed.
[0137]
  In addition, since the computer 100 is equipped with a configuration for storing the unique information in advance and a configuration for checking the unique information, a storage unit for storing the unique information in advance compared to the case where these configurations are provided in the mobile communication device. Can be reduced in size and cost, and the storage unit mounted on the computer 100 has a significantly larger storage capacity than the storage unit mounted on the portable communication device. Therefore, it is possible to easily construct a configuration in which unique information of a plurality of persons is stored and collated for one mobile communication device. Furthermore, it becomes difficult to forge the unique information, and unauthorized use of the mobile communication device can be prevented or suppressed.
[0138]
  In addition, since the optical system 71 as described above is mounted, a zoom mechanism or the like necessary for obtaining a zoom magnification equivalent to that of the central region with a normal optical system becomes unnecessary, and a normal optical system is used. Compared to the case, it is advantageous in terms of durability and size.
[0139]
  The present invention is not limited to the above embodiment, and the following embodiments (1) to (10) can be employed.
[0140]
  (1) In the above-described embodiment, the target of collation is the iris of the human eye. However, the present invention is not limited to this. For example, as shown in FIG. The information is not limited to handwriting, and may be, for example, a driver's license or a credit card that is already owned. In short, any information that has unique information can be used for verification.
[0141]
  (2) In the above embodiment, the registered image to be collated with the captured image is stored in the database of the computer 100 connected to the mobile communication device 1 via the communication network. You may make it memorize | store in the memory | storage part 16 with which the communication apparatus 1 was equipped.
[0142]
  (3) In the collation shooting mode, if a part of the image in the wide-angle area is also displayed on the display unit 5, the eye can be easily positioned with respect to the high-definition area.
[0143]
  (4) As shown in FIG. 10, when the entire face or a part of the face such as eyes and lips is displayed relatively large on the display unit 5 in the high-definition area, the portable communication device 1 functions as a hand mirror. be able to. Note that the presence of the wide-angle area makes it easy to position a desired part of the face in the high-definition area.
[0144]
  (5) As shown in FIG. 11, in a connection portion between the mobile communication device 1 main body and the imaging unit 7, the mobile communication device main body 1 a is provided with a columnar fitting portion 51 that protrudes toward the imaging unit 7, and this fitting. And a disk part 52 extending in the outer diameter direction at a suitable position in the axial direction of the joint part 51. On the other hand, the imaging unit 7 is formed with extending portions 74 and 75 each having a circular hole 73 extending toward the shaft side.
[0145]
  And the fitting part 51 formed in the portable communication apparatus main body 1a is fitted in the hole 73 formed in the extending parts 74 and 75 of the imaging part 7, and the disk part 52 is interposed between the extending parts 74 and 75. The wiring P that connects the board 76 of the image sensor 72 and the board (not shown) in the mobile communication device main body 1 a is inserted into the fitting portion 51. Thereby, the imaging part 7 is comprised so that rotation with respect to the portable communication apparatus main body 1a is possible.
[0146]
  Accordingly, as shown in FIG. 12, when the imaging unit 7 is rotated about the axis to the surface opposite to the display screen of the display unit 5 and the optical system 71 is directed to a predetermined position of the document, for example, Since characters in a predetermined range centered on the intersection between the optical axis and the document are displayed relatively large on the liquid crystal display unit 5, in this case, the portable communication device 1 can function as a magnifying glass.
[0147]
  (6) Also, as shown in FIG. 13, when the optical system 71 of the imaging unit 7 is directed to a sign or the like that is relatively far from the portable communication device 1, the intersection of the optical axis of the optical system 71 and the sign is set. Since a character in a predetermined range centered on the display unit 5 is displayed relatively large, in this case, the mobile communication device 1 can function as a telescope.
[0148]
  (7) Using the telephoto function described in (6), it is possible to construct a current position specifying system that specifies the location of the user of the mobile communication device 1.
[0149]
  As shown in FIG. 14, the current position specifying system includes a mobile communication device 1, a GPS (global positioning system) 200, and a computer 100.
[0150]
  The mobile communication device 1 outputs a radio wave to the GPS 200, and the GPS 200 receives this radio wave, identifies the approximate current position of the user of the mobile communication device 1, and uses this approximate current position information as the mobile communication device 1. Send to.
[0151]
  The mobile communication device 1 receives the current position information from the GPS 200, and photographs a marker existing around the current position, such as a company logo displayed on the building, by the imaging unit 7, and the image data and the above-described data The current position information is transmitted to the computer 100.
[0152]
  The computer 100 has a map database that stores map information, specifies the current position based on the image data transmitted from the mobile communication device 1 and the current position information, and identifies the current position and the surrounding area. The map information is transmitted to the mobile communication device 1.
[0153]
  Through this series of processing, the current position of the user of the mobile communication device 1 can be specified in detail. The marker may be a sign indicating the name of the intersection installed on the traffic signal at the intersection, or a nameplate.
[0154]
  (8) When performing normal imaging, the imaging unit 7 may be configured as follows in order to reduce image processing such as extraction processing, enlargement processing, or image distortion correction.
[0155]
  As shown in FIG. 15, on one side of the imaging unit 7, a foveal lens 71 a and a glass 78 are juxtaposed on the slide plate 77 with a predetermined interval, and the slide plate 77 is on the slide rail 79. Is configured to slide in the direction in which the foveal lens 71a and the glass 78 are juxtaposed.
[0156]
  Then, the optical system used for imaging is switched between the foveal lens 71 a and the glass 78 by sliding the slide plate 77. That is, an optical system that aligns the optical axis with a single focal point lens (not shown) disposed between the slide plate 77 and the image sensor 72 (not shown in FIG. 15), the foveal lens 71a and the glass 78. Switch between.
[0157]
  Thus, when the optical axes of the single focus lens and the foveal lens 71a are made to coincide, the entire optical system 71 has the characteristics of the foveal lens 71a. A fine image can be obtained.
[0158]
  On the other hand, when the optical axes of the single focus lens and the glass 78 are matched, the optical system 71 as a whole has the characteristics of the single focus lens. As a result, extraction processing, enlargement processing, image distortion correction, etc. An image with a constant image height can be obtained while reducing the image processing.
[0159]
  In addition, it is good also as a round hole (cavity) instead of the glass 78 as what is arranged in parallel with the foveal lens 71a.
[0160]
  (9) The present invention is not limited to checking the user of the mobile communication device 1, and for example, the product tag may be checked using the mobile communication device 1.
[0161]
  That is, at the time of product sorting or product picking in a warehouse, the tag attached to the product is photographed by the mobile communication device 1, and the tag information is transmitted to a predetermined computer. You may make it collate a tag.
(10) The present invention is not limited to the mobile phone as described above, and is, for example, a PDA (personal digital assistants), a digital still camera, a camera-integrated video recorder, or the like having a communication function and a photographing function. Can also be adopted.
[0162]
【The invention's effect】
  According to the first aspect of the present invention, the optical systemAsSince the optical system having a large distortion in the peripheral region with respect to the central region is mounted, the central region and the peripheral region of the optical system have a function of performing normal shooting such as snap shooting and landscape shooting. Thus, for example, by capturing biometric information, the biometric information can be photographed with high accuracy. When biometric information or the like is collated using the captured image, the collation can be performed with high accuracy.
[0163]
  In addition, in a normal optical system, a zoom mechanism or the like is required in order to obtain a zoom magnification equivalent to that in the central region. However, in the present invention, zooming is performed by using the optical system as described above. A mechanism or the like is not required, which is advantageous in terms of durability and size as compared with the case of using a normal optical system.
[0164]
  In addition, the extracted image is enlarged at a predetermined magnification by the enlargement unit, and the storage unit stores the enlarged image, the unique information to be collated obtained from the extracted image, and the predetermined communication device. A second mode in which the extracted image is transmitted to the predetermined communication device in order to collate with the unique information, and the mode switching control unit sets the first mode and the second mode. Since the mode is switched between the mobile communication device, the normal shooting function such as snap shooting and landscape shooting is compared with whether the user of the mobile communication device is the owner or not. Thus, a personal authentication function that permits the use of the mobile communication device only when the user is the owner can be installed.
[0165]
  In addition, a configuration in which unique information to be collated with the specific information to be collated obtained from the extracted image is stored in advance, a specific information to be collated from the extracted image, and unique information stored in a predetermined communication device in advance. Since the predetermined communication device is provided with the configuration for performing the collation, it is not necessary to provide the storage unit in the device as compared to the case where the mobile communication device includes the storage unit that stores the unique information in advance. Accordingly, it is possible to reduce the size of the device and reduce the cost, and it becomes difficult to forge the unique information, thereby preventing or suppressing unauthorized use of the mobile communication device.
[0166]
  According to the second aspect of the present invention, since an optical system having a large distortion in the peripheral region with respect to the central region is mounted as the optical system, the snap shooting and scenery are performed depending on the central region and the peripheral region of the optical system. When it has a function of performing normal shooting such as shooting, and by capturing biological information, for example, from the central area, the biological information can be captured with high accuracy, and biometric information is collated using the captured image The collation can be performed with high accuracy.
[0167]
  In addition, in a normal optical system, a zoom mechanism or the like is required in order to obtain a zoom magnification equivalent to that in the central region. However, in the present invention, zooming is performed by using the optical system as described above. A mechanism or the like is unnecessary, which is advantageous in terms of durability and size as compared with the case of using a normal optical system.
[0168]
  Also,A first mode in which the extracted image is magnified at a predetermined magnification by the enlarging unit, and the enlarged image is stored in the first storage unit; unique information to be collated obtained from the extracted image; and the second storage unit Since the mode switching control unit switches the mode between the first mode and the second mode, the mode switching control unit is configured to check the unique information stored in advance. The mobile communication device is compared only with a normal shooting function such as snap shooting or landscape shooting and whether or not the user of the mobile communication device is the owner, and only when the user is the owner And a personal authentication function that permits the use of.
[0169]
  In addition, a configuration in which unique information to be collated with the specific information to be collated obtained from the extracted image is stored in advance, a specific information to be collated from the extracted image, and unique information stored in a predetermined communication device in advance. Since the mobile communication device is provided with the configuration for performing the above verification, the configuration for performing the above verification can be simplified.
[0170]
  Claim3According to the invention described in (4), when the foveal lens is positioned at the first position, the entire optical system has a large distortion in the peripheral region with respect to the central region, and is projected by the central region. The optical image of the subject is magnified compared to the optical image of the subject projected by the peripheral region, and as a result, an image in which the subject located on the center side is larger than the subject located on the peripheral side is obtained. be able to.
[0171]
  When the foveal lens is positioned at the second position, the entire optical system has the characteristics of a single focus lens, and the height Y, the focal length f, and the angle of view θ of the optical image to be formed. Thus, an image corresponding to the optical image represented by Y = f · tan θ can be obtained.
[0172]
  According to invention of Claim 4,When the foveal lens is positioned at the first position, the entire optical system has a large distortion in the peripheral region with respect to the central region, and the optical image of the subject projected by the central region is It is magnified as compared with the optical image of the subject projected by the area. Therefore, the image related to the output signal of the imaging unit is an image in which the subject located on the center side is larger than the subject located on the peripheral side.
[0173]
  Therefore, the center region and the peripheral region of the optical system have a function of performing normal shooting such as snap shooting and landscape shooting, and the biological information can be captured with high accuracy by capturing, for example, biological information in the central region. it can. Thereby, when collating biometric information etc. using this picked-up image, the collation can be performed with high precision.
[0174]
  In addition, a normal optical system (the relationship between the height Y of the formed optical image, the focal length f, and the angle of view θ is Y = f · tan In order to obtain a zoom magnification equivalent to that in the central region with a lens represented by θ), a zoom mechanism or the like is required. However, in the present invention, by using the optical system as described above, A zoom mechanism or the like is unnecessary, which is advantageous in terms of durability and size as compared with the case of using a normal optical system.
[Brief description of the drawings]
FIG. 1 is a diagram showing a schematic configuration of an embodiment of a mobile communication device according to the present invention.
2A is a graph showing distortion and field angle characteristics of an optical system 71, and FIG. 2B is a graph showing field angle and image height characteristics;
FIG. 3 is a diagram illustrating an example of an image output by an imaging unit.
FIG. 4 is a diagram illustrating an example of an image output by an imaging unit.
FIG. 5 is a block diagram showing a configuration of a mobile communication device.
FIG. 6 is a block diagram illustrating a configuration of a transmission / reception unit.
FIG. 7 is a block diagram illustrating a configuration of a computer.
FIG. 8 is a flowchart showing a series of imaging processing of the mobile communication device.
FIG. 9 is a diagram illustrating an example of an image output by an imaging unit.
FIG. 10 is an explanatory diagram of a hand mirror function installed in a mobile communication device.
FIG. 11 is a diagram illustrating a rotation structure of a connection portion between the mobile communication device main body and the imaging unit.
FIG. 12 is an explanatory diagram of a magnifying glass function that is mounted when the imaging unit is configured to be rotatable with respect to the mobile communication device main body.
FIG. 13 is an explanatory diagram of a telescope function installed when the imaging unit is configured to be rotatable with respect to the mobile communication device main body.
FIG. 14 is an explanatory diagram of a current position specifying system constructed by installing a telephoto function in a mobile communication device.
FIG. 15 is a diagram illustrating a modification of the imaging unit.
[Explanation of symbols]
1 Mobile communication equipment
2 Operation part
5 display section
7 Imaging unit
12 Control unit
121 Mode switching controller
122 Parameter setting section
123 Extractor
124 Enlarged part
125 Image rearrangement processing unit
126 storage unit
71 Optical system
72 Image sensor
100 computers
101 Control unit
1011 Verification unit

Claims (4)

A portable communication device having a transmission / reception means for transmitting / receiving a signal,
An optical system whose peripheral region has a large distortion with respect to the central region;
An imaging unit that photoelectrically converts a light image of a subject formed by the optical system ;
An extraction unit that extracts an image projected on the imaging unit by the central region from an image related to an output signal of the imaging unit;
An enlargement unit for enlarging the extracted image at a predetermined magnification;
A storage unit for storing the enlarged image;
In the transmission / reception means, the first mode for storing the enlarged image in the storage unit, the unique information to be collated obtained from the extracted image and the unique information stored in advance in a predetermined communication device are collated. A mobile communication device comprising: a mode switching control unit that switches a mode between a second mode in which the extracted image is transmitted to the predetermined communication device. A portable communication device having a transmission / reception means for transmitting / receiving a signal,
An optical system whose peripheral region has a large distortion with respect to the central region;
An imaging unit that photoelectrically converts a light image of a subject formed by the optical system;
An extraction unit that extracts an image projected on the imaging unit by the central region from an image related to an output signal of the imaging unit;
An enlargement unit for enlarging the extracted image at a predetermined magnification;
A first storage unit for storing the enlarged image;
A second storage unit for storing the acquired unique information in advance;
A collation unit that collates the unique information to be collated obtained from the extracted image with the unique information stored in advance in the second storage unit;
A first mode for enlarging the extracted image at a predetermined magnification by the enlargement unit, and storing the enlarged image in the first storage unit, unique information of a collation target obtained from the extracted image, and the second A mode switching control unit for switching a mode with a second mode for collating with unique information stored in advance in the storage unit;
Mobile communication device equipped with. The optical system has a single-focus lens that forms an optical image of a subject on the imaging surface of the imaging unit, and a peripheral region that has a large distortion with respect to a central region. A center configured to be relatively movable between a first position where an image is formed and a second position retracted from the first position so as to form an optical image of a subject using only the single focus lens. The portable communication device according to claim 1, further comprising a foveal lens. A portable communication device having a transmission / reception means for transmitting / receiving a signal,
A single-focus lens that forms an optical image of a subject on the imaging surface of the imaging unit;
The peripheral region has a large distortion with respect to the central region, and the first position where the light image of the subject is formed with the single focus lens, and the light image of the subject is formed only with the single focus lens. Therefore, a foveal lens configured to be relatively movable between the second position retracted from the first position,
An imaging unit that photoelectrically converts a light image of a subject formed by the optical system;
Mobile communication device equipped with.

Images