TWI356628B - - Google Patents

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an electronic image pickup apparatus, and more particularly to an electronic image pickup apparatus having a zoom function and capable of reducing a depth dimension. [Prior Art] In recent years, digital cameras, PDAs, mobile phones, and the like in which electronic imaging devices are incorporated have appeared, and these are imaging devices that are expected to have an electronic image with high image quality, high zoom ratio, and low depth. In response to such a request, various electronic camera devices have been proposed. Japanese Patent Publication No. 1 discloses that a first lens element is provided as a second lens element, and a first guiding means for guiding the second lens element to draw a predetermined trajectory in the optical path of the first lens element and performing magnification switching; And guiding the second lens element to perform a focus adjustment on the first lens element by drawing a predetermined trajectory different from the trajectory of the first guiding means in the optical path, and performing the focus adjustment on the extension of the first guiding means with respect to the first The magnification switching device of the plurality of second guiding means that the guiding means alternates. In addition, Japanese Patent Document 2 describes a zoom camera having a second group or more, and is characterized in that it includes a zoom drive ring for driving a specific lens group, and is disposed adjacent to the zoom drive ring to drive other specifics. a focus and zoom drive ring for the lens group; a drive source for rotating the focus and zoom drive ring in the forward and reverse directions; and formed on the opposite portion of the zoom drive ring and the focus and zoom drive ring. a clutch mechanism formed by the engagement portion that pushes the zoom drive ring in response to the rotation of the focus and zoom drive ring, and the clutch device that does not push the rotary feed portion from -5 to 1356628, by the air feed portion The focus operation is performed by the rotation of the focus and zoom drive ring, and the zoom operation is performed by the interlocking of the focus and zoom drive ring and the zoom drive ring of the engaging portion. . Further, Japanese Patent Document 3 describes a thin optical system that can be mounted on a small-sized digital camera or the like, and is characterized in that, in order to reduce the thickness, a zigzag imaging optical system that is a zigzag optical axis and that holds a power of a zigzag is used. A first group GF having a negative power, a diaphragm S, and a second group GR having a positive power are provided, and the first group GF has an optical axis meandering member that holds power, and the optical axis meandering member has a flat surface. The reflecting surface is a zigzag imaging optical system in which at least one of the incident surface and the emitting surface is formed by a surface formed by a curved surface that is rotationally symmetrical with respect to the optical axis. Further, Japanese Patent Document 4 describes an electronic imaging device having an extremely thin depth direction in which a mode of an optical system capable of maintaining high specifications and performance and capable of overcoming constraints on movement of a moving group at the time of magnification change is used. The object side sequentially includes a 1-1st group G-1 composed of a negative lens group and a reflective optical element P for optical path bending, and a 1st to 2nd group G1-2 including one positive lens, and has a positive zigzag In the second group G2 of the force, when the wide-angle end is doubled to the telephoto end, only the second group G2 moves to the object side, and the optical path zigzag zoom optical system and the electronic imaging element I disposed on the image side are electronically imaged. Device. Japanese Patent Laid-Open Publication No. JP-A No. 2003-A No. 2003-43354 [Problem to be Solved by the Invention] However, Japanese Patent Laid-Open Publication No. 1 is a problem in which the image is blurred by the infinitely close and the macro region every time the focus region is passed when zooming is performed, and the focus needs to be repeated. Further, in Patent Document 2, when the zoom magnification is changed and the image is moved to the telephoto side or the wide-angle side, there is a problem that the photographed image becomes blurred. Further, in Japanese Patent Laid-Open No. 3, since the fixed lens is disposed before the crucible, there is a need to precisely align the optical axes of the fixed and front fixed lenses, the assembly takes time, and when the outer casing of the detector is large, The problem of increasing the size in the thickness direction due to the outer casing. Further, in Japanese Patent Laid-Open No. 4, since optical power is applied to the incident surface of the reflective optical element to form a curved surface, the reflected optical element is expensive, and it takes a long time to assemble with other optical elements. The present invention has been made in view of the current state of the art, and an object thereof is to provide an electronic imaging device which can be inexpensive, has high image quality, has a high zoom ratio, and has a small depth. [Means for Solving the Problem] The image display device according to the present invention includes: a first lens group closest to the subject side; and a second lens 1356628 mirror group that moves to change the magnification image; a third lens group that operates differently from the second lens group is obtained by multiplying the photographic image; and a driving means is provided for the second lens group and the third lens group along the optical axis in accordance with the driving amount of the driving means a lens group moving means for moving a cam groove of a predetermined amount and changing the total magnification of the second lens group and the third lens group, wherein the electronic imaging device is characterized in that the cam groove of the lens group moving means is In the zoom region formed from the wide-angle end to the telephoto end, the second lens group and the third lens group are in a pan-focus state, and at least one of the wide-angle end and the telephoto end is extended. The cam region is configured to move at least one of the second lens group or the third lens group along the optical axis in the extended cam region, and to perform focusing for focus adjustment Movement. An electronic imaging device according to the present invention includes: a first lens group closest to the subject side; and a second lens group that moves to change the imaging image to perform the second lens in order to change the imaging image The third lens group in which the group is different in operation and the driving means are provided, and the second lens group and the third lens group are moved by a predetermined amount of the cam groove in accordance with the driving amount of the driving means, and the second lens is changed. The lens group moving means for the total magnification of the group and the third lens group is characterized in that the cam groove of the lens group moving means is provided with the second lens in a zooming region from the wide-angle end to the telephoto end In the region in which the group and the third lens group are in the pan-focus state, at least one of the second lens group and the third lens group is fixed to the optical axis direction so that the focus region of the entire lens group can be moved. -8- 1356628 The electronic imaging device according to the present invention is characterized in that the wide-angle end and the telephoto end have an extended cam area to perform a focusing operation, and the wide-angle end and the telephoto end focus area are provided with a focusing area having a specific zoom area. Large execution width. An electronic imaging device according to the present invention includes a second lens group that reciprocates along an optical axis in a zoom region, and a focus region in the zoom region is set to not include the second lens group The direction of movement is near the point of change. An electronic imaging device according to the present invention is characterized in that the first lens group is a reflection optical means including a curved path from an object. An electronic imaging device according to the present invention is characterized in that an electronic imaging element is provided. An electronic imaging device according to the present invention is characterized in that it includes a focus control means for receiving a signal from an image pickup element and performing focus adjustment control of the drive means. An electronic imaging device according to the present invention is characterized in that: a mode selection means having a selectable pan focus mode and an auto focus mode is provided, and when the pan focus mode is selected by the mode setting means, the focus control means is a drive control lens In the group moving means, the lens group in the wide-angle end state and the telephoto end state is disposed in the pan-focus position in the extended cam region. An electronic imaging device according to the present invention is characterized in that the lens group moving means is a focus adjusting portion that provides a wide-angle marco region in an extended cam region at a front end of the wide-angle end, and/or in a telephoto The focus adjustment of the telephoto macro on the extended cam area of the front end is 1356628. The electronic imaging device according to the present invention is characterized in that the extended cam area of the lens group moving means is in accordance with the wide-angle end or the telephoto end to the infinity position. The order of the very close position of the photographing and the position of the macro photographing is usually formed. In the electronic imaging device of the present invention, the cam groove of the lens group moving means includes a first cam groove for determining a movement amount of the second lens group, and a first amount of movement of the third lens group. a cam groove, wherein the first cam groove is a wide-angle side extended cam region that is disposed in the order of a macro region, a wide-angle end, a very close-range region, and a wide-angle end infinite region, and a zoom region; And a telephoto side extended cam region configured from the cam region to the distal end infinity region, the telephoto end normal region, and the telephoto macro region, wherein the second cam groove is configured to have an optical toward the wide-angle end A wide-angle extended cam region in the non-moving region in the axial direction, and an extended cam region having a non-moving region in the direction of the optical axis in the zoom region and the telephoto end. An electronic imaging device according to the present invention includes: a first lens group closest to the subject side; and a second lens group that moves to change the photographic image to perform the second lens in order to change the photographic image a third lens group in which the group is different in operation; and a driving means for moving the second lens group and the third lens group by a predetermined amount of the cam groove in accordance with the driving amount of the driving means, and changing the second lens The lens group moving means for the total magnification of the group and the third lens group is characterized in that the cam groove of the lens group moving means is provided with a movement amount for determining the second through - 10356628 mirror group The first cam groove and the second cam groove for determining the amount of movement of the third lens group determine the width of the second cam in the zoom region for the buffer region, and the buffer region is driven by the lens group moving means The third lens group moves in a single direction, does not move when driven in the opposite direction, and can drive the lens while maintaining the third lens group fixed in the optical axis direction. In the moving means, the lens group moving means is a driving means for driving the lens driving means to be opposite to the one direction by driving the second and third lens groups in one direction by the lens group moving means to end the variable magnification operation. In the direction, the focus adjustment for moving the second lens group in the buffer region is performed in a state where the position of the third group lens group is maintained. An electronic imaging device according to the present invention includes: a first lens group closest to the subject side; and a second lens group that moves to change the imaging image to perform the second lens in order to change the imaging image a third lens group in which the group is different in operation; and a driving means for shifting the second lens group and the third lens group by a predetermined amount of the cam groove ′ in accordance with the driving amount of the driving means, and changing the second lens The lens group moving means for the total magnification of the group and the third lens group is characterized in that the cam groove of the lens group moving means is provided with a first cam groove for determining the amount of movement of the second lens group And a second cam groove for determining the amount of movement of the third lens group, wherein a buffer region is formed to constitute a width of a cam groove in a zoom region of the second cam groove, and the buffer region is driven in a direction by the lens group moving means Then, when the position of the third lens group is moved and the drive is in the opposite direction, the position is not moved, and the drive can be driven while maintaining the fixed position of the third lens light -11 - 1356628. In the lens group moving means, the first cam groove and the second cam groove are provided with at least one extended region of the wide-angle side and the extended region of the telephoto side, and only the second lens group is moved to stop the third lens group from executing the focus. The adjusted focus adjustment area includes a buffer area that constitutes a width of a cam groove in the zoom area of the second cam groove, and the buffer area moves the arrangement position of the third lens group when the lens group moving means is driven in one direction, and drives When it is in the opposite direction, it does not move, and the lens group moving means can be driven while maintaining the optical axis direction of the third lens. The lens group moving means is the driving means for the second and third by the lens group moving means. After the lens group is driven in one direction and the zooming operation is completed, the lens driving means is driven in a direction opposite to the one direction, and the second lens group is executed in a state where the position of the third group lens group is maintained and fixed. The focus adjustment of the movement in the above buffer area. An electronic imaging device according to the present invention is characterized in that the first lens group is a reflection optical means including a curved path from an object. According to the electronic imaging device of the present invention, the third lens group is held so as not to move when the movement of the second lens group in the buffer region is completed. In the electronic imaging device according to the present invention, the size of the buffer region of the second cam groove in the optical axis direction is larger than the wide angle side of the telephoto side. An electronic imaging device according to the present invention is characterized in that, at the end of the magnification changing operation of the lens driving means, the lens driving means is stopped from -12 to 1356628 from the wide angle to the telephoto side, and the telephoto side is wide-angled At this time, it is driven from a predetermined amount and a wide angle to the far side after passing the stop position. An electronic imaging device according to the present invention is characterized in that, when the zooming operation of the lens driving means is performed from the telephoto side to the wide-angle side, the driving source is stopped and terminated, and when the wide-angle side is on the telephoto side, It is the end of the drive from the far side to the wide angle side after passing the stop position. An electronic imaging device according to the present invention is characterized in that the magnification changing operation of the lens driving means is stopped from either the wide-angle side to the telephoto side or from the telephoto side to the wide-angle side Then, the above-mentioned driving source is reversed, and the second lens group is moved to the pan-focus position by using the buffer region, and the electronic imaging device according to the present invention is characterized in that the lens driving means is operated in the buffer region. At the same time, the second lens group and the third lens group are kept moving while maintaining the interval between the lens groups, and the focus adjustment region for focus adjustment is realized. An electronic imaging device according to the present invention is an electronic imaging device including: a first lens group closest to the subject side; a second lens group that moves to change the magnification image; and a magnification-capture image a third lens group that operates differently from the second lens group; and a driving means that moves the second lens group and the third lens group by a predetermined amount by a driving amount of the driving means a lens group moving means for changing the total magnification of the second lens group and the third lens group, wherein the cylindrical member forming the cam groove of the lens group moving means is supported It is possible to move only in the direction of the optical axis - 13 - 1356628. The above-mentioned lens moving means changes the driving direction to the opposite direction from a predetermined position, and the cylindrical member moves to the optical axis direction without rotation, and maintains the second lens group and The third lens group performs focus adjustment while maintaining the group interval. According to the electronic imaging device of the present invention, the third lens group is provided with a second reflection optical means for forming a third optical axis by forming a light beam that is bent along the second optical axis. In the electronic imaging device according to the present invention, the meandering direction of the light beam generated by the second reflecting optical means is a substantially right angle with respect to the second optical axis. An electronic imaging device according to the present invention is characterized in that it includes means for connecting at least one of the first lens group and at least one of the third lens groups. An electronic imaging device according to the present invention is characterized in that it includes a component that connects at least one of the first lens groups and at least one of the third lens groups, and a means for connecting the lens group moving means. An electronic imaging device according to the present invention is characterized in that it has a light beam that is bent along a first optical axis from a subject, and includes a first reflection optical means for forming a second optical axis, and is located closest to the subject side. a first lens group; a second lens group including at least one or more groups for moving from a wide angle to a telephoto; and a driving means for generating a driving force for moving the second lens group: a movement amount determining means for determining a movement amount required for the magnification of the second lens group; a regulation means for matching the optical axis of the lens group -14356628 2 and the second optical axis; The light beam of the second optical axis includes a third lens group that forms a second reflection optical means of the third optical axis; and the image lens is located on the most image side to convert the object into an electrical signal. Camera means. An electronic imaging device according to the present invention is characterized in that it includes a component that fixes at least one of the first lens groups and at least one of the third lens groups, and the mechanism means fixes the driving means and the At least one of the movement amount determining means and the above-mentioned regulation means. An electronic imaging device according to the present invention is characterized in that it includes an optical axis adjustment mechanism that matches the first, second, and third optical axes. An electronic imaging device according to the present invention is characterized in that it has a light beam that is bent along a first optical axis from a subject, and includes a first reflection optical means for forming a second optical axis, and is located closest to the subject side. a first lens group; a second lens group including at least one or more groups for moving from a wide angle to a telephoto; and a driving means for moving the second lens group to be doubled: determining the second The magnification of the lens group is determined by the movement amount determining means for the required movement amount; the third lens group including the second reflection optical means for forming the third optical axis is bent over a part of the light beam along the second optical axis; a first imaging means for converting a subject image passing through the third lens group into an electric signal; and a residual light beam which is not bent by the second reflection optical means among the light beams along the second optical axis The subject image 1 is converted into a second imaging means of the electrical signal. An electronic imaging device according to the present invention is characterized in that one of the first and second imaging means is for animation photography, and the other is for still photography -15 - 1356628. An electronic imaging device according to the present invention is characterized in that a screen image signal is outputted by using the image capturing means for moving pictures, and the image capturing means for still picture photography is used only when a still picture signal is generated. An electronic imaging device according to the present invention is characterized in that: a lens having at least one or more groups for moving a light beam from a subject from a wide angle to a telephoto position; a driving means for generating a driving force for moving the group; an imaging means for converting the subject into an electrical signal; a display means for performing various displays by the image captured by the imaging means; and executing a dialogue, mail, and data a communication means such as a transmission or an Internet connection; a rechargeable secondary battery; and a power control for controlling power supply from the secondary battery to the driving means, the imaging means, the display means, and the communication means Preferably, the power control means limits the supply of power to the respective means in accordance with a predetermined relationship. An electronic imaging device according to the present invention is characterized in that the predetermined relationship of the power control means is changeable according to a user. An electronic imaging device according to the present invention is characterized in that the predetermined relationship of the power control means is changed in accordance with the amount of residual charge of the secondary battery. An electronic imaging device according to the present invention is characterized in that the predetermined relationship between the power control means includes prohibiting supply of electric power to the communication means to the driving means and the imaging means, or supplying power to the communication means. The above-mentioned driving means and the above-mentioned imaging means are prohibited from supplying power to -16-% 1356628. An electronic imaging device according to the present invention is characterized in that the predetermined relationship between the power control means includes a speed change of the driving means, a frame rate change of the imaging means, a display brightness change of the display means, and communication of the communication means. At least one of the speed changes. An electronic imaging device according to the present invention is characterized in that: a lens group including at least one or more groups for moving a light beam from a subject from a wide angle to a telephoto position; And a driving means for generating a driving force for moving: an imaging means for converting a subject into an electrical signal; and a display means for displaying a display of the image captured by the imaging means: performing a dialogue, mail, data transmission, a communication means such as an internet connection; a rechargeable secondary battery; a charging means for converting the voltage of the secondary battery into a high voltage; and having an electric energy conversion to be accumulated in the charging means The lighting means of the light source energy, and the power control means for controlling the power supply from the secondary battery to the driving means, the imaging means, the display means, the communication means, and the charging means, wherein the power control means is The power supply to each of the above means is limited according to the prescribed relationship. An electronic imaging device according to the present invention is characterized in that the charging means is a high voltage for causing an oscillation operation to occur in response to a pulse signal from the outside. An electronic imaging device according to the present invention is characterized in that the pulse signal input to the charging means is at least -17 depending on at least one of a state of charge of the charging means and a residual amount of charge of the secondary battery. - 1356628 The electronic imaging device according to the present invention is characterized in that the power control means supplies power to the driving means, the imaging means, the display means, and the communication. At the time of the means, the supply of electric power to the above charging means is restricted or prohibited. In the electronic imaging device according to the present invention, the power control means calculates the power that can be supplied in response to the amount of residual charge of the secondary battery, and supplies the power to the driving means, the imaging means, the display means, and the like. In the communication means, when the secondary battery is left over, the supply means is supplied with electric power, and the amount of electric power supplied is controlled so as not to exceed the supply capacity of the secondary battery. An electronic imaging device according to the present invention is characterized in that: a lens group including at least one or more groups for moving a light beam from a subject from a wide angle to a telephoto position; And a driving means for generating a driving force for moving; an imaging means for converting the subject into an electrical signal; a display means for performing various displays by the image captured by the imaging means; and performing dialogue, mail, and data transmission a communication means such as an internet connection; a rechargeable secondary battery; a charging means for converting the voltage of the secondary battery into a high voltage; and having an electric energy to be accumulated in the charging means Converting into a lighting means for light energy, and controlling power supply from the secondary battery to the driving means, the imaging means, the display means, the communication means, and the charging means. The electric power control means, the electric power of the above - 18 - 1356628 control means is to lower the setting condition of the luminous frequency of the illumination means when the residual charge amount of the secondary battery is reduced. An electronic imaging device according to the present invention includes: a first optical means located closest to a subject side including a reflection optical means for bending a light beam from a first optical axis of the subject into a second optical axis; a second lens group that moves along the second optical axis for zooming, a third lens group that performs different operations from the second lens group for zooming, and a second lens group that moves the second lens group and the third lens group a lens group moving means; an image capturing means for converting the subject image into an electric signal; and a display means for displaying an animation output and/or a still picture output generated by the image capturing means, wherein the electronic image capturing device is characterized by a first frame body having at least the imaging means and the display means; the second frame body having a shutter means for instructing an imaging operation of the imaging means to be incorporated; and a plurality of shutter means including the shutter means The surface of the characters, symbols, etc., which are printed, imprinted, etc., by the means of operation and the functions of the above-mentioned operating means, and the above-mentioned majority of operating means; and the above-described means of explanation; The hinge means for rotatably holding the second frame body portion in the first frame body portion, and when the second frame body portion is in the open photographing state with respect to the first frame body portion, the second frame body portion is provided The position of the first frame body can be folded, and in the image capturing position, the positive position of the character and the symbol of the instruction means is approximately the same as the longitudinal direction of the display means, and the short side direction of the display means is The second optical axes are approximately parallel, and the long side of the imaging possible region of the imaging means is substantially parallel to the longitudinal direction of the display means. The electronic imaging device P according to the present invention is characterized in that the long side meat of the electronic -19-1356628 imaging device is regarded as an up-and-down direction, and the vertical position is taken as a standard. An electronic imaging device according to the present invention is characterized in that the first optical means is constituted by a right-angle prism and does not have optical power of either of positive and negative. An electronic imaging device according to the present invention includes: a first optical means located closest to a subject side including a reflection optical means for bending a light beam from a first optical axis of the subject into a second optical axis; a second lens group that moves along the second optical axis for zooming, a third lens group that performs different operations from the second lens group for zooming, and a second lens group that moves the second lens group and the third lens group a lens group moving means; an imaging means for converting the subject image into an electrical signal; and a display means for displaying an animation output and/or a still picture output generated by the imaging means, wherein the electronic imaging device is characterized by The optical power of either the positive or negative is not held by the first optical means as a whole or by the optical components constituting the first optical means. According to the electronic imaging device of the present invention, the reflected optical means is approximately 90 degrees bent along the long side of the effective imaging region of the imaging means. An electronic imaging device according to the present invention includes: a first optical imaging device that includes a reflection optical means that bends a light beam from a first optical axis of a subject into a second optical axis, and is located closest to the subject side Optical means: a second lens group that moves along the second optical axis for zooming; a third lens group that performs a different operation from the second lens group for zooming; -20 - 1356628, the second lens a group, a magnification of the third lens group, a lens group moving means for each moving lens group, and an imaging means having a rectangular effective imaging region for converting the subject image into an electric signal, wherein the reflecting optical means is only In the image circle beam in which the approximate diagonal length of the rectangular effective imaging region of the imaging means is used as the diameter, the rectangle is effectively imaged. The beam of the area passes through. According to the electronic imaging device of the present invention, the reflected optical means is bent about 90 degrees along the long side of the effective imaging region of the imaging means. [Effect of the Invention] According to the present invention, since the focus structure in the zoom lens mechanism of the electronic image pickup apparatus is simplified, it is possible to obtain an electronic imaging apparatus which is small in size and high in zoom ratio and high in image quality. Further, according to the present invention, since the configuration of the zoom optical system is pan-focal, even in the operation of zooming to the telephoto side and the wide-angle side, blurring of the photographic image is not caused. In addition, since it can be infinitely far-reaching and macro-focusing operation at the farthest side and/or the widest angle side, it is possible to obtain a sharp image with a focus on the farthest side and the widest angle side. According to the present invention, since the optical system includes the means for reflecting light, the size in the depth direction can be reduced, and even if the electronic imaging device according to the present invention is mounted on an electronic device such as a mobile phone, the electronic device can be reduced. thickness. Further, since the attached lens is not provided on the reflection optical means closest to the subject side -21 - 1356628, the optical axis alignment can be easily performed, and the thickness of the electronic imaging device can be reduced. Further, by providing the reflection optical means on the imaging element side, it is possible to prevent an increase in the thickness of the electronic imaging device caused by the thickness of the outer casing of the image pickup element, and it is possible to make the electronic imaging device thinner. Further, according to the present invention, since the size of the refractive optical system is suppressed to the minimum required for photographing, the electronic imaging apparatus can be reduced. Further, according to the present invention, when the electronic device having the configuration is used in the vertically long position, the electronic imaging device can be disposed in the lateral direction, and particularly suitable for holding the mobile phone of the portrait at the longitudinal position. Camera unit. According to the present invention, since the electronic imaging device includes the power control means, the power consumption of the electronic imaging device can be minimized, and the consumption of the secondary battery of the electronic device equipped with the electronic imaging device can be minimized. [Embodiment] Hereinafter, an embodiment of an electronic imaging device according to the present invention will be described. 1 is a view showing a mobile phone to which an embodiment of an electronic imaging device according to the present invention is applied. (a) is a front view showing an appearance, and (b) is a front view showing an electronic imaging device mounted, and FIG. FIG. 3 is a front view showing the state of use of the mobile phone shown in FIG. 1, and FIG. 3 is a view showing the electronic imaging device according to the embodiment, wherein (a) is a longitudinal sectional view of the electronic imaging device, and (b) is an electron. Fig. 4 is a development view showing a detailed cam profile of another example of the Z cam of the electronic imaging device according to the embodiment, and Fig. 5 is a view showing a third embodiment of the cam cam 22- 1356628 of the Z cam of the imaging device. Fig. 6 is a block diagram showing a control circuit of an electronic imaging device according to an embodiment. In the present example, the electronic imaging device 100 is built in the mobile phone 10 as shown in Fig. 1. The mobile phone 10 has a digital camera function in addition to a telephone, mail, and web page viewing machine. In the present embodiment, the mobile phone 10 is provided with a photographing window 11, an stroboscopic light-emitting portion window 12, and an antenna 14 of the electronic imaging device 1 as shown in Fig. 2 . Then, in this example, the mobile phone 10 is configured such that the first frame body portion 20 and the second frame body portion 30 can be folded and connected by the hinge device 40. When the mobile phone 10 according to the present example is not in use, the first frame body portion 20 and the second frame body portion 30 are folded, and when the mobile phone is used, as shown in FIG. 2, the two are opened. The state of the frames 20, 30. In the state shown in FIG. 2, the first frame body portion 20 has the liquid crystal display means 21 and the speaker 22. On the second frame body portion 30, there are an input button 31 including a number or a character, and a flash button 33. The operation button 32. In order to explain the function of each button, the input button 3 1 and the operation button 32 have surface descriptions of characters and symbols to be printed or printed. Then, in this example, the mobile phone 1 is in the photographing state, and the positive position of the character and the symbol of the above-described explanation means is substantially the same as the longitudinal direction of the display means, and the short side direction of the display means and the electronic imaging described above. The longitudinal direction of the apparatus 100 is approximately parallel, and the long side of the imaging possible area of the imaging means is approximately -23 - 1356628 lines from the longitudinal direction of the display means = that is, in this example, the image is photographed In the portrait, the longitudinal direction is regarded as the vertical direction, and the vertical position is taken as a standard. Next, an electronic imaging device 100 according to the present invention will be described. In the present embodiment, the electronic imaging device 100 is a four-group zoom lens that is optically three times as shown in Figs. 3 and 5. In this example, the first group 110 is composed of 稜鏡111 and 112112. The second group 120 is composed of two negative lenses 121 and 122 and a frame 123 holding the negative lenses 121 and 122. The third group 130 is composed of two positive lenses 131 and 132 and one negative lens 133 and a frame 134. The fourth group 140 has one positive lens 141. In this example, the first group 110 and the fourth group 140 are fixed to the lens barrel, and the second group 120 and the third group 130 are moved along the optical axis. In the present example, the first group 110 is composed of a crucible 111 that is bent by a light beam along the first optical axis 01 from a subject (not shown) by 90 degrees. The entrance surface and the exit surface of the crucible 111 are formed by an optical plane having no positive and negative optical power, and the aluminum is vapor-deposited on the back surface of the zigzag surface of the right-angled equilateral triangle. The optical axis which is bent at 90 degrees in accordance with 稜鏡1Π is regarded as the second optical axis 02. Further, an electronic imaging device 150 is disposed behind the fourth group 140. The electronic imaging device 150 is composed of an imaging element 151 such as a CCD element, a casing 152 for holding the element, a holding frame 153 for holding the casing 152, and an IR cut filter 154 for blocking infrared light. In this example, the holding frame 153 is configured to be movable along the second optical axis to move on the fixed frame 142 holding the positive lens 141. This is used in manufacturing engineering to perform focus adjustment. The IR cut filter 154 is applicable to any of the absorption type and the anti-24 - 1356628 type, and this embodiment uses a reflection type. In this example, as shown in FIGS. 3 and 5, the frame 123 of the second group 120 and the frame 134 of the third group 130 are in the frame 112 and the holding frame 153 of the first group 110. Along the second optical axis 02, the suspension shaft 171 that is transported in parallel with the second optical axis and the first group Π0 and the second group that are held by the rotation stop valve 172 are moved. Further, the frame 123 of the second group and the frame 134 of the third group are arranged with the inter-group spring 173, and are excited in the pulling direction. Next, the drive mechanisms of the second group 120 and the third group 130 will be described. In this example, the pins 124 and 135 are formed in the frame 123 and the frame 134 of the second group 120 and the third group 130, and are embedded in the cam of the Z cam 160 driven by the stepping motor 181 of the drive source 180. Grooves 161, 162. The stepping motor 181 has 20 or so cogging points in one rotation. Further, the stepping motor 181 is engaged with the gear 163 provided at the Z cam end via the reduction gear train 182 to constitute the drive source 180. The Z cam 160 is a cylindrical cam that rotates about 300 degrees between the Wide end and the Tele end, and has two crown grooves 161 and 162 for the second group and the third group. In the present example, the second group cam groove 161 is composed of a zoom area 161a, a wide-angle side extension area 161b, and a telephoto side extension area 161c from the wide-angle end to the telephoto end. Further, the third group cam groove 162 is composed of a zoom area 162a, a wide-angle side extension area 162b, and a telephoto side extension area 162c from the wide-angle end to the telephoto end. In this example, as shown in Fig. 3(b), the second group 120 is retracted from Wide to std in the -25-1356628 focal region 161a, and proceeds from std to Tele. At this time, the third group 130 is monotonously advanced from Wide to Tele in the zoom area 162 A. The third group of movements is larger than the second group, and the distance between the groups of the second group and the third group in Tele is the smallest. Further, in this example, in the Wide end and the Tele end, the wide-angle side extension area 162b and the telephoto side extension area 162c of the third group cam groove 162 are at right angles to the second optical axis, and the third group is not to the second optical. The axis 02 moves. In addition, the second group cam groove 161 is one of the wide-angle side extension region 161b and the telephoto side extension region 162c of the Wide end and the Tele end, and is gradually directed toward the second optical axis 02 as viewed from the std side. The body side is continuously discharged. In the portion, the third group 130 is fixed to the surface of the third group 130, and the second group 120 is continuously discharged, and the focusing operation is performed from infinity to normal to very close to macro. Although the focus can be achieved by advancing the second group 120 and the third group 130 by the same amount at the same time, since the amount of movement required is large, in this example, the third group 130 is fixed, and only the second group is fixed. 120 advances, performing the focus from infinity to near the near side. Further, in this example, the cam groove of the portion other than the Tele end of the Wide end is determined to be in the shape of a so-called pan-focus cam groove in order to make the focus from infinite to close. Next, the Z cam 160 shown in Fig. 4 will be described. In this example, the second group cam groove 161 and the third group cam groove 162 are formed on the Z cam 160 in the same manner as the Z cam. In this example, focus areas 162d, 162e, and 162f are formed in the zoom area 16 2a of the third group use cam groove 162 at three points of wide angle, standard, and telephoto. The focus area 162d -26- 1356628 is such that each cam groove is disposed perpendicular to the optical axis, and the third group 130 is not moved to the optical axis 02 direction. Therefore, the variable focus ratio of the lens is constant. Then, in the region corresponding to the second group cam groove 161 of each of the focus regions 162d, 162e, and 162f, the second group 120 is moved along the optical axis 02 to be in focus. In this example, the focus areas 162d, 162e, and 162f are smaller than the focus areas provided at the wide-angle end and the telephoto end, and are provided with an adjustment width. Further, in this example, the wide-angle side extension area and the telephoto side extension area provided at the wide-angle end and the telephoto end are set to infinity at the entrance end of each area. Therefore, the second group cam groove 161 is in the above-mentioned zoom area. A change point 161d of the moving direction is formed. In this example, the focus area in the cam area is formed to avoid the above-described deflection point 161d. In this way, smooth focus can be performed. Next, a control circuit of the electronic imaging device will be described. Fig. 6 is a block diagram showing a control circuit of the electronic image pickup apparatus according to the present example. The control circuit of this example is a variable focus switch 21 1 disposed on the mobile phone 10, and a release switch 21 1 (flash button in FIG. 2) is connected to the camera unit control means 210, according to the zoom switch 211 and the release switch 221 After the operation, the zoom control unit 214 drives the zoom motor 215 that rotationally drives the stepping motor 181 of the Z cam 160. The zoom motor control means 214 is a zoom position encoder 213 connected to the zoom position and a zoom reset encoder 216 for returning the zoom position to the initial position.

Further, the camera unit control means 210 is an AF control means 221 having control for performing auto focus, and AF -27-1356628 connected to the AF control means is controlled by the motor control means 222 to drive the AF motor 223. Further, the AF motor control means 222 is connected to the AF position encoder 224. In this example, the AF motor and the above-described zoom motor 215 are the same stepping motor 181. That is, as shown in Fig. 3, in this example, the electronic imaging device 1 is between the widest angle and the most distant region, and the lens is in the pan-focus state 'in the extended region 161a of the cam grooves 161, 162. , 161b, 162a, 162b 'execute focus. Therefore, the stepping motor operates as a zoom motor from the widest angle to the farthest direction, and the AF motor is operated in the extended regions 161a, 161b, 162a, and 162b. Further, in the present example, the macro mode input means 22 (the button of the mobile phone 1) and the macro mode control means 226 are provided on the mobile phone 1 which performs the shooting of the macro mode. The control circuit is provided with a CCD image sensor 237 (151 in Fig. 3) as an image pickup device, and the image signal from the CCD image sensor is transmitted via the A/D converter 236 via the still picture processing means 234 and the still picture compression means 232. It is stored in memory 23 1 . Similarly, the image signal of the CCD image sensor 237 is stored in the memory 231 via the A/D converter 236 via the still picture processing means 235 and the still picture compression means 233. Further, in this example, the CCD image sensor is automatically exposed and adjusted by the AE control means 225. Further, in the present embodiment, the mobile phone 10 is displayed and controlled by the display control means 238, and includes a display means 239 (liquid crystal display unit 21 in Fig. 2) for color display still or animation. In this example, the stroboscopic light-emitting portion for illumination of a subject is provided (the light is emitted from the stroboscopic light-emitting portion window 12 in Figs. 1-28 - 8 1356628), and the stroboscopic light-emitting portion 245 is connected to be stroboscopically charged. The means 242 and the charging voltage detecting means 243 are charged and controlled. Further, in this example, the stroboscopic charging control means 24 1 is a high voltage that performs an oscillating operation in response to a pulse signal from the outside, and the stroboscopic light-emitting portion 245 is provided with a stroboscopic light-emitting control means 244 for controlling stroboscopic light emission. The portion 24 5 can emit an appropriate amount of light. Further, in this example, the overall control means 250 for controlling the entire mobile phone is provided, and the transmission and reception control means 252, the transmission means 253, and the antenna 254 having the telephone function are provided. Further, an operation means such as a button having a mobile phone is provided, and a microphone 255 (34 in Fig. 2) and a speaker 256 (the same as 22). Then, the electronic imaging device 100 according to the present embodiment is an efficient power consumption control including a secondary battery (not shown) that performs a limited capacitance to the entire mobile phone 10. That is. The power control means 24 includes an imaging means including a stepping motor 181 for moving the lens group, a CCD imaging element 237 for converting a subject image into an electric signal, and the like, and includes an imaging means including the above-mentioned imaging means The photographed image displays display means such as various display means 23, and the like, and performs communication communication such as performing dialogue, mail, data transfer, internet connection, etc., and controls power supply from the secondary battery. This is a power supply for performing communication means such as telephone conversation, mail, web page browsing, data transmission, and photographing means for photographing electronic portraits in a predetermined relationship. This prescribed relationship is changed in response to the amount of residual charge of the secondary battery. -29- 1356628 Specifically, the predetermined relationship in the power control means 240 may include prohibiting the supply of power to the communication means to the driving means and the imaging means, or supplying power to the communication means. It is prohibited to supply electric power to the above-described driving means and the above-described imaging means. Further, the power control means 240 may include at least one of a speed change of the driving means, a frame rate change of the imaging means, a display brightness change of the display means, and a communication speed change of the communication means. Further, the power control means 240 is configured to transmit the pulse signal to the stroboscopic charging means 242 to at least the frequency and load of at least one of a charging state of the charging means and a residual charge amount of the secondary battery. Any of the ratios will vary. Further, the power control means 204 limits or prohibits the supply of electric power to the charging means when the electric power is supplied to the driving means, the imaging means, the display means, and the communication means. Further, the power control means 240 calculates the power that can be supplied in response to the amount of residual charge of the secondary battery, and supplies the power to the driving means, the imaging means, the display means, and the communication means, and the secondary battery has In the remaining time, the electric power is supplied to the charging means, and the amount of electric power supplied is controlled so as not to exceed the supply capacity of the secondary battery while controlling the pulse signal. Further, when the power control means 240 is such that the amount of residual charge of the secondary battery is reduced, the frequency of light emission of the stroboscopic light-emitting portion 245 can be lowered. Then, the above-described prescribed relationship of the power control means 240 is set to -30 - 1356628 and can be changed according to the user. The size in the depth direction can be reduced, and the thickness of the electronic device can be reduced even if the electronic imaging device according to the present invention is mounted on an electronic device such as a mobile phone. Further, since the incident lens is not provided on the most reflective optical means on the subject side, the optical axis can be easily and easily calibrated, and the thickness of the electronic imaging device can be reduced. Further, the power consumption of the electronic imaging device can be minimized, and the consumption of the secondary battery of the mobile phone equipped with the electronic imaging device can be minimized. Next, an electronic imaging device according to another embodiment will be described. Fig. 7 is a view showing an electronic imaging device 300 according to another embodiment, wherein (a) is a longitudinal sectional view of the electronic imaging device, and (b) is a cam profile showing a Z cam of the electronic imaging device. In the electronic imaging device 300 according to the present embodiment, the position of the first electronic imaging device 1A and the driving source 360 described above is changed to the first group 110 side. The drive source 360 of this example is constituted by a stepping motor 361 and a gear train 362, and transmits the driving force to the gear 163 of the Z cam 160. According to this example, the overall length of the electronic imaging device 300 can be shortened. Next, a modification of another electronic imaging device will be described. In this example, only the cam profile of the Z cam 410 is different from the above embodiments. Fig. 8 is a cam profile view showing a Z cam 410 according to a modification of the electronic imaging device according to the embodiment. In the present example, the second group cam groove 441 is composed of a zoom area 411a, a wide-angle side extension area 411b, and a telephoto side extension area 411c from the wide-angle end to the telephoto end. Further, the third group cam groove 412 is composed of a zoom area 412a, a wide-angle side extension area 4 12b, and a telephoto side extension area 412c from the wide-angle end to the telephoto end of the -31 - 1356628. In the present example, in the Wide end and the Tele end, the wide-angle side extended region 412b of the third group cam groove 412 is at a right angle to the second optical axis, and the third group is not moved in the second optical axis 02 direction. Further, the second group cam groove 41 1 is continuously discharged toward the object side of the second optical axis 02 as viewed from the std side in the wide-angle side extension region 41 lb of the Wide end. The second group 120 is continuously released from the third group 130 on the one side of the portion, and the focusing operation from the pan focus to the macro is performed. Further, in the Tele end, the telescopic side extension region 412c of the third group cam groove 412 is at a right angle to the second optical axis, and the third group is not moved to the second optical axis direction 02», and the second group cam is used. The groove 411 is viewed from the std side at the distal end extension region 41 lc of the Tele end so as to be gradually pulled into the imaging element side of the second optical axis 02. The third group 130 is fixed to the second group 120, and the pan-focus operation of the pan-focus to tele landscape is performed. Further, in this example, the cam groove of the portion other than the Tele end of the Wide end is determined to be in the shape of a so-called pan-focus cam groove in order to make the focus infinitely calibrated to a close distance. Next, a modification of another electronic imaging device will be described. In this example, the cam profile of only the Z cam 420 is different from the above embodiments. Fig. 9 is a cam profile view showing a Z cam 420 according to a modification of the electronic imaging device according to the embodiment. In the present example, the second group cam groove 421 is composed of a zoom area 42 1a from the wide-angle end to the telephoto end -32-% 1356628 end, and a wide-angle side extension area extension area 42 lc. Further, the third group is constituted by a zoom area 422a, a field 422b, and a telephoto side extension area 422c which are convex from the wide-angle end to the telephoto end. In this example, in the Wide end, the third group cam groove extension region 422b is at a right angle to the second optical axis, and moves in the second optical axis 02 direction. In the wide-angle side extension region 421b of the second group t wide end, the object is pulled from std toward the object side of the second optical axis 02. The third group 130 is fixed to the second group 120, and the focusing operation of the focus operation is performed until the close to the Widem. Further, in the Tele end, the third group cam groove extending region 422c is at a right angle to the second optical axis, and moves to the second optical axis direction 02. Further, the second group is used in the distal end extension region 42 lc of the Tele end to be continuously discharged from the std side to the side of the imaging element side of the second optical axis 02, and the third group 130 is fixed to the second group 120, and Tele is extremely close. Pan-focus action. Furthermore, in this example, the end of the Wide end of the Wide side is such that the focus can be infinitely calibrated to a close distance, which is the shape of the cam groove that is determined to be a pan focus. Next, another embodiment of the image forming apparatus 500 according to the present invention will be described. In this example, it is photographed in the zoom region 421b, and the telescopic side wheel groove 422 is wide-angle side extension region 4 1 2 lacking the wide-angle side 3 group is not viewed toward the third wheel groove 421 on the side of the portion: To the Wide Macro ~ Macro is very close to 422. The farthest side of the third group is the inactive cam groove 421 which is viewed gradually. The cam groove in which the Te 1 e 〇〇 to the portion is executed in this portion can be an electronic camera for performing the focus, and the cam profile of the -33-1356628 Z cam 550 is different from the above embodiments. Fig. 1 is a cam profile view showing a Z cam 420 according to a modification of the electronic imaging device according to the embodiment. In the present example, the second group cam groove 551 is formed in a zoom line 551a, a wide-angle side extension area 551b, and a telephoto side extension area 551c which are formed on the straight line from the wide-angle end to the telephoto end, and the size of the optical axis direction is constituted. It is approximately the same size as the width of the pin 124 of the second group 120 described above. Further, the third group cam groove 55 2 is constituted by a focus area 5 52a from the wide-angle end to the telephoto end, and a wide-angle side extension area 5 5 2b' telephoto side extension area 5 52c. In this example, the optical axis direction of the wide-angle extension region 552b and the telephoto side extension region 552c is approximately the same as the width of the latch 135 of the third group 130, and is formed in the optical axis direction of the zoom region 552a. Large size. Further, in this example, the third group 130 has an appropriate frictional force, and once positioned, it can be kept as far as possible without touching the cam 552. This is, for example, increasing the friction between the suspension shaft 171 and the frame 134, or making the frame 134 vertical with respect to the optical axis. According to the present embodiment, as shown in FIG. 11, after the Z cam 550 is rotated so as to become the predetermined zoom ratio, even if the Z cam 50 is rotated from i in FIG. 11 to Π, the latch engaged with the cam groove 551 is engaged. When the 124 is moved, the latch 135 disposed in the cam groove 552 does not move. Therefore, if the first group 110 is moved for focusing in this range, and in this example, the telephoto side extension area and the wide angle extension area can be focused in the same manner as the above examples. -34- 1356628 Therefore, according to this example, focusing can be performed in all zoom areas, and a high-quality image can be obtained. Further, in the above embodiment, the size of the optical axis direction of the cam 5 52 can be widened toward the telephoto side as indicated by reference numeral 553 in Fig. 11 . According to the present example, when the focus is performed in the zoom area, the amount of movement of the second group 120 can be increased. Next, an electronic imaging device 600 according to an embodiment of the present invention will be described. Fig. 11 is a schematic diagram showing an electronic imaging device according to another embodiment, and Fig. 12 is a cam profile showing a Z cam of the electronic imaging device shown in Fig. 11. Fig. 13 is a view showing the cam profile of the Z cam of the electronic image pickup apparatus shown in Fig. 11. The electronic imaging device 600 according to this example is capable of driving the Z cam 650 in parallel with respect to the optical axis, and drives the Z cam as an inverse cam. Therefore, in this example, in addition to the cam grooves 653 for moving the Z cam 650 in addition to the cam grooves 651 and 652 of the second group and the third group, the cam groove 653 is provided to be engaged with the cam groove 653. Support frame 62 3. The electronic imaging device 600 according to the present example includes the Z cam 650, the third group 620', the third group 630, and the second group 620 and the third group 630, as shown in FIG. The frames 621 and 631 of the cam grooves 651 and 652 of the z cam 650 are combined. Then, in this example, a screw lever 642, is attached to the stepping motor 641 as a drive system, and a nut member 643 locked to the screw shaft 642 is provided to drive the support frame 623. By the movement of the support frame 623, the z cam 65 0 is rotated, and the second group 62 0 and 630 are zoomed. Further, the cam groove 651 and the -35-1356628 cam groove 652 can be formed in the same manner as the cam groove of each of the above-described examples as shown in Fig. 13. Again, in this case, the first! The group 610, the fourth group 640, the image sensor 650, and the slide shaft 654 are fixed to the apparatus body 661 of the image pickup apparatus 600. Further, in this example, as shown in Fig. 12, the Z cam 650 and the second group 620 are provided. The third group 630 and the entire drive system 640 are configured to be non-rotating and movable on the optical axis (indicated by arrow A in FIGS. 12 and 13). Therefore, the Z cam 650 is as shown in FIG. Generally, it is mounted so as to be rotatable and slidable on the sliding shaft 654 which is disposed in parallel with the optical axis 02 of the apparatus body 661. Further, in this example, the Z cam 650, the second group 620, the third group 630, and the drive system 64 are all focused along the slide shaft 654 by means of a means such as a stepping motor. [Industrial Applicability] According to the present invention, since the focusing structure in the zoom lens mechanism of the electronic electronic camera is simplified, it is possible to obtain an electronic imaging device having a high zoom ratio and high image quality. Further, according to the present invention, since the configuration of the zoom optical system is pan-focal, even in the operation of zooming to the telephoto side and the wide-angle side, blurring of the photographic image is not caused. Further, since the most telescopic side and/or the widest angle side are configured to be infinitely distant, very close, and macro-focusing operations, it is possible to obtain a sharp image having a focus on the farthest side and the widest angle side. Further, according to the present invention, since the optical system includes reflected light means, the size in the depth direction can be reduced, and the electronic imaging device according to the present invention can be mounted on an electronic device such as a mobile phone. On the machine, the thickness of the electronic device can also be reduced. Furthermore, since the attached lens is not provided on the reflective optical means closest to the subject side, the optical axis calibration can be easily performed, and in addition, it can be reduced. The thickness of the electronic camera. Further, by providing the reflection optical means on the imaging element side, it is possible to prevent an increase in the thickness of the electronic imaging device caused by the thickness of the outer casing of the image pickup element, and it is possible to make the electronic imaging device thinner. Further, according to the present invention, since the size of the refractive optical system is suppressed to the minimum required for photographing, the electronic imaging apparatus can be reduced. Further, according to the present invention, when the electronic device having the configuration is used in the vertically long position, the electronic imaging device can be disposed in the lateral direction, and particularly suitable for holding the mobile phone of the portrait at the longitudinal position. Camera unit. According to the present invention, since the electronic imaging device is provided with the power control means, the power consumption of the electronic imaging device can be minimized, and the consumption of the secondary battery of the electronic device equipped with the electronic imaging device is minimized. . Further, the present invention can be used in addition to mobile phones, and can be used in other electronic devices such as PDAs and compact digital cameras. BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a view showing a mobile phone in which the electronic telephone device according to the present invention is applied. FIG. 1(a) is a front view showing an appearance, and (b) is a view. Front view of the equipped electronic camera. Fig. 2 is a front elevational view showing the state of use of the mobile phone shown in Fig. 1. Fig. 3 is a view showing an electronic imaging device according to an embodiment, wherein (a) is a longitudinal sectional view of the electronic imaging device, and (b) is a cam profile of the Z cam of the electronic imaging device. Fig. 4 is a development view showing a detailed cam profile of another example of the Z cam of the electronic imaging device according to the embodiment. Fig. 5 is a cross-sectional view showing the electronic imaging device shown in Fig. 3. Fig. 6 is a block diagram showing a control circuit of the electronic imaging device according to the embodiment. Fig. 7 is a view showing an electronic imaging device according to another embodiment, wherein (a) is a longitudinal sectional view of the electronic imaging device, and (b) is a cam profile showing a Z cam of the electronic imaging device. Fig. 8 is a cam profile view showing a Z cam of a modified example of the electronic imaging device according to the embodiment. Fig. 9 is a cam profile view showing a Z cam of a modified example of the electronic imaging device according to the embodiment. Fig. 10 is a cam profile view showing a Z cam of the electronic imaging device according to another embodiment. Fig. 11 is a schematic view showing an electronic imaging device according to another embodiment. -38- 1356628 Fig. 12 is a view showing a Z cam mounting state of the electronic image pickup apparatus shown in Fig. 11. Fig. 13 is a view showing the cam profile of the Z cam of the electronic image pickup apparatus shown in Fig. 11. [Description of Symbols of Main Components] I 〇: Mobile Phone II: Photographic Window 1 2 : Strobe Light Unit Window 1 3 : Mobile Phone Body 14 : Antennas 20 and 30 : Frame, 20 : First Frame Body 2 1 : LCD display means 22: speaker 30: second frame body 3 1 : input button 32 : operation button 3 3 : shutter button 34 : microphone 40 : hinge device 1 : electronic imaging device 1 1 〇: group 1 1 1 1 :稜鏡-39- 1356628 Π 2 : 稜鏡 frame 120 : 2nd group 121 , 122 : Negative lens 123 : Frame 124 , 135 : Pin 130 : Group 3 1 3 1 , 1 3 2 : Positive lens 133: Negative lens 134: Frame 1 3 5 : Latch 140: Group 4 1 4 1 : Positive lens 142: Fixed frame 1 5 0 : Electronic imaging device 1 5 1 : Imaging element 1 5 2 : Housing 1 5 3 : Holding frame 154 : IR cut filter 160 : Z cam 161 : 2nd group cam groove 1 6 1 a : Zoom area 16 1b : Wide angle side extension area. Field 1 6 1 c : Telephoto side extension area 162 : Group 3 Use cam groove -40 1356628 162a 162c 163 : 17 1: 172 : 173 : 180: 18 1: 182: 190 : 191 : 192 : 195 : 196 : 197 : 198 : 199 : 221 : 01 : : Wide-angle side extension area: Remote extension area gear suspension shaft rotation check valve group spring drive source stepping motor reduction gear train reflection optical system right angle 稜鏡 prism frame camera system imaging element housing holding frame IR cut filter release switch 1st optical axis 02 : 2 Optical axis

Claims (1)

1356628 Pickup, Patent Application No. 1. An electronic imaging device comprising: a first lens group closest to the subject side; a second lens group that moves to change the photographic image; a third lens group in which the second lens group operates differently; and a driving means for moving the second lens group and the third lens group by a predetermined amount along the optical axis in accordance with the driving amount of the driving means a lens group moving means for changing a total magnification of the second lens group and the third lens group, wherein the cam lens of the lens group moving means is formed from a wide angle end to In the zoom region at the telephoto end, the second lens group and the third lens group may be in a pan-focus state, and at least one of the wide-angle end and the telephoto end may have an extended cam region at the extended cam. In the region, at least one of the second lens group or the third lens group is moved along the optical axis, and focus movement for focus adjustment can be performed. 2. An electronic imaging device comprising: a first lens group closest to the subject side; a second lens group that moves to zoom the image; and the second lens group for zooming the image a third lens group that is different in operation; and a drive means for shifting the second lens group and the third lens group by a predetermined amount of the cam groove - 42 - 1356628 ' in accordance with the driving amount of the driving means The lens group moving means for increasing the total magnification of the second lens group and the third lens group is characterized in that: the cam groove of the lens group moving means is provided in the zoom region from the wide-angle end to the telephoto end In the region in which the second lens group and the third lens group are in the pan-focus state, at least one of the second lens group and the third lens group is fixed to the optical axis direction so that focus of the entire lens group can be focused. region. 3. The electronic imaging device according to claim 2, wherein the wide-angle end and the telephoto end have an extended cam area to perform a focusing operation, and the wide-angle end and the telephoto end focus area are provided with a zoom area. The large execution width of the focus area. 4. The electronic imaging device according to claim 2, wherein the second lens group that reciprocates along the optical axis in the zoom region is provided, and the focus region in the zoom region is set. The vicinity of the moving direction change point of the second lens group is not included. 5. The electronic imaging device according to claim 1 or 2, wherein the first lens group is a reflection optical means including a curved path from an object. 6. The electronic imaging device according to claim 1 or 2, wherein the electronic imaging device is provided. 7. The electronic imaging device according to claim 6, wherein the electronic imaging device includes a focus control device that receives a signal from the imaging device and performs focus adjustment control of the driving means. In the electronic imaging device described in the first or second aspect of the invention, the mode selection means having the selectable pan focus mode and the auto focus mode is provided, and the pan focus is selected by the mode setting means. In the mode, the focus control means is a drive control lens group moving means, and the lens group in the wide-angle end state and the telephoto end state is disposed at the pan focus position in the extended cam area. 9. The electronic imaging device according to claim 1 or 2, wherein the lens group moving means is provided with a focus of a wide-angle macro region in an extended cam region at a front end of the wide-angle end. The adjustment portion, and/or the focus adjustment portion of the telephoto macro is disposed on the extended cam region at the front end of the telephoto end. 10. The electronic imaging device according to claim 1 or 2, wherein the extended cam region of the lens group moving means is in accordance with a position from a wide-angle end or a telephoto end to an infinity position, which is usually in close proximity to the camera. The order from the photographing position is formed. The electronic imaging device according to the first or second aspect of the invention, wherein the cam groove of the lens group moving means is provided with a first cam groove for determining a movement amount of the second lens group, and determining the first In the second cam groove of the movement amount of the lens group, the first cam groove is formed to extend in the order of the macro region, the wide-angle end, the wide-angle end, and the wide-angle end infinite region in the cam region. a cam region; and a self-variable region; and a telephoto side extended cam region configured from the cam region in the distal end infinity region, the telephoto end normal region, and the telephoto macro region, the second cam-44 - 1356628 The groove is a wide-angle extended cam region constituting a non-moving region having an optical axis direction toward the wide-angle end, and an extended cam region having a non-moving region having a direction toward the optical axis in the zoom region and the telephoto end. 12. An electronic imaging device comprising: a first lens group closest to a subject side; a second lens group that moves to change a magnification image; and the second lens group to perform a magnification imaging image a third lens group that is different in operation; and a driving means for shifting the second lens group of the second lens group 'the third lens group by a predetermined amount of the cam groove in accordance with the driving amount of the driving means, and changing the second lens group And a lens group moving means for increasing the total magnification of the third lens group, wherein the cam lens of the lens group moving means is provided with a first cam groove for determining a movement amount of the second lens group. And a second cam groove for determining a movement amount of the third lens group, wherein a width of the second cam groove in the zoom region is determined in order to realize a buffer region, wherein the buffer region is driven in a direction by the lens group moving means The lens group moves, and does not move when driven in the opposite direction, and the lens group moving means can be driven while maintaining the third lens group fixed in the optical axis direction. The lens group moving means is a driving means for driving the second and third lens groups in one direction by the lens group moving means to end the variable magnification operation, and driving the lens driving means in a direction opposite to the one direction. Focus adjustment for moving the second lens group in the buffer region is performed while maintaining the position of the third group lens group. 13. An electronic imaging device comprising: a -45 - 1356628 1 lens group closest to a subject side; and a second lens group that moves for zooming a photographic image: a third lens group in which the second lens group operates differently; and a driving means for shifting the second lens group and the third lens group by a predetermined amount of the cam groove ′ according to the driving amount of the driving means The lens group moving means for increasing the total magnification of the second lens group and the third lens group is characterized in that the cam groove of the lens group moving means is provided with a number of movements for determining the second lens group a cam groove and a second cam groove for determining a movement amount of the third lens group include a buffer region that constitutes a width of a cam groove in a zoom region of the second cam groove, and the buffer region is driven by the lens group moving means When the direction is one direction, the arrangement position of the third lens group is moved, and when it is driven in the opposite direction, the position is not moved, and the original shape of the optical axis of the third lens is maintained to be driven. In the group moving means, the first cam groove and the second cam groove are provided with at least one extended region of the wide-angle side extension region and the extended region of the telephoto side, and only the second lens group is moved to stop the third lens group from performing focus adjustment. a focus adjustment region having a buffer region constituting a width of a cam groove in a zoom region of the second cam groove, wherein the buffer region moves the arrangement position of the third lens group when the lens group moving means is driven in one direction, and is driven to In the opposite direction, the lens group moving means is driven while maintaining the optical axis direction of the third lens, and the lens group moving means is a driving means for moving the hand group by the lens group - 46 - 1356628 (2) After the third lens group is driven in one direction and the variable magnification operation is completed, the lens driving means is driven in a direction opposite to the one direction, and the first position is maintained while maintaining the position of the third group lens group. The focus adjustment of the lens group in the above buffer region is adjusted. The electronic imaging device according to claim 12, wherein the first lens group is a reflection optical means including a curved path from the subject. 15. The electronic imaging device according to claim 12, wherein the third lens group is held so as not to move when the second lens group is moved in the buffer region. The electronic imaging device according to claim 12, wherein the optical axis direction of the buffer region of the second cam groove is larger than a wide angle side of the telephoto side. The electronic imaging device according to claim 12, wherein the lens driving means ends the zooming operation, and the lens driving means is stopped from the wide angle to the telephoto side. When the side is wide to the wide angle, it is driven from the predetermined amount and wide angle to the far side after passing the stop position. 18. The electronic imaging device according to claim 12, wherein the zooming operation of the lens driving means stops the driving source when the zooming operation is from the telephoto side to the wide angle side. The time from the wide-angle side to the telephoto side is the end of the drive from the predetermined side to the wide-angle side after passing the stop position. 19. The apparatus of claim 3, wherein the zooming operation of the lens driving means is from a wide angle side to a telephoto side or from a telephoto side to the telephoto side. When the wide-angle side is stopped, the drive source is reversed after the stop, and the second lens group is moved to the pan-focus position using the buffer region to stop the end. The electronic imaging device according to claim 12, wherein when the lens driving means operates in the buffer region, the interval between the lens group and the third lens group is maintained. The focus adjustment area for focus adjustment is realized while moving in a certain state. 21. An electronic imaging device comprising: a first lens group closest to a subject side; a second lens group that moves to change a magnification image; and the second lens group to perform a magnification imaging image a third lens group that is different in operation; and a driving means for shifting the second lens group and the third lens group by a predetermined amount of the cam groove in accordance with the driving amount of the driving means, and changing the second lens group And a lens group moving means for increasing the total magnification of the third lens group, wherein the cylindrical member forming the cam groove of the lens group moving means is supported to be movable only in a predetermined size in the optical axis direction In the lens moving means, the driving direction is changed to the opposite direction from the predetermined position, and the cylindrical member is moved to the optical axis direction without rotation, and the second lens group and the third lens group holding group interval are maintained. Focus adjustment. The electronic imaging device according to any one of claims 1, 2, 12, 13 or 21, wherein the third lens group has a shape of -48-1356628 A second reflection optical means for forming a third optical axis by the light beam of the optical axis. The electronic imaging device according to claim 22, wherein the meandering direction of the light beam generated by the second reflecting optical means is a substantially right angle with respect to the second optical axis. The electronic imaging device according to claim 22, further comprising: means for connecting at least one of the first lens group and at least one of the third lens groups. The electronic imaging device according to claim 22, further comprising: a component that connects at least one of the first lens group and at least one of the third lens group, and the lens group The means of connection of mobile means. 2. 6. An electronic imaging apparatus characterized by having a light beam that is meandering along a first optical axis from a subject, and including a first reflection optical means for forming a second optical axis, located closest to the subject side First lens group: a second lens group including at least one or more groups for moving from a wide angle to a telephoto: a driving means for generating a driving force for moving the second lens group; a movement amount determining means for determining a movement amount required for the magnification of the second lens group; a regulation means for matching the optical axis of the second lens group with the second optical axis; and the meandering along the second optical The beam of the axis includes a third lens group that forms the second reflection optical means of the third optical axis: and an imaging means that is located on the most image side and converts the subject into an electrical signal. 27. The electronic imaging device of the invention of claim 26, wherein the electronic imaging device is provided with at least one of the first lens group and at least one of the third lens groups. The mechanism means fixes at least one of the driving means, the movement amount determining means, and the regulation means. The electronic imaging device according to claim 26, wherein the optical axis adjustment mechanism that matches the first, second, and third optical axes is provided. An electron imaging apparatus characterized by having a light beam that is meandered along a first optical axis from a subject, and includes a first reflection optical means for forming a second optical axis, and is located closest to the object side. a first lens group; a second lens group including at least one or more groups for moving from a wide angle to a telephoto; a driving means for moving the second lens group to be doubled; and the second lens is determined The movement amount determining means for the magnification of the group is a third lens group that includes a second portion of the light beam along the second optical axis and includes a second reflection optical means for forming the third optical axis; a first imaging means for converting a subject image passing through the third lens group into an electric signal; and a residual light beam which is not bent by the second reflection optical means among the light beams along the second optical axis The subject image 1 is converted into a second imaging means of the electrical signal. The electronic imaging device according to claim 28, wherein one of the first and second imaging means is for animation photography, and the other is for still photography. 3. The electronic imaging device according to claim 30, wherein the screen image signal is output by using the above-described moving image capturing means, -50-1356628, when the still picture shooting signal is generated, the still picture shooting is used. Camera means. An electronic imaging apparatus comprising: a lens group including at least one or more groups for moving a light beam from a subject from a wide angle to a telephoto; and in order to zoom in the lens group; Driving means for generating driving force for moving: an imaging means for converting a subject into an electrical signal; a display means for performing various displays by including an image captured by the imaging means; performing dialogue, mail, data transmission, a communication means such as an internet connection; a rechargeable secondary battery; and a power control means for controlling power supply from the secondary battery to the driving means, the imaging means, the display means, and the communication means, The power control means limits the supply of electric power to the respective means in accordance with a predetermined relationship. The electronic imaging device according to claim 32, wherein the predetermined relationship of the power control means is changeable according to a user. The electronic imaging device according to claim 32, wherein the predetermined relationship of the power control means is changed in accordance with a residual charge amount of the secondary battery. The electronic imaging device according to the third aspect of the invention, wherein the predetermined relationship of the power control means includes prohibiting supply of the communication means to the driving means and the imaging means. The electric power or the electric power supplied to the communication means is prohibited from being supplied to the driving means and the imaging means. The electronic imaging device according to claim 32, wherein the predetermined relationship between the power control means includes a speed change of the driving means, a frame rate change of the imaging means, and the display means At least one of display brightness change and communication speed change of the communication means. 37. An electronic imaging device characterized by having a lens group including at least one or more groups for moving a light beam from a subject from a wide angle to a telephoto: in order to zoom in on the lens group a driving means for generating a driving force for moving; an imaging means for converting a subject into an electrical signal; and means for displaying a display including an image captured by the imaging means: performing dialogue, mail, data transmission, internet a communication means such as a network connection; a rechargeable secondary battery; a charging means for converting the voltage of the secondary battery into a high voltage; and having an electric energy source to be accumulated in the charging means An illumination means for light energy, and a power control means for controlling power supply from the secondary battery to the driving means, the imaging means, the display means, the communication means, and the charging means, wherein the power control means is based on The prescribed relationship limits the supply of electricity to each of the above means. The electronic imaging device according to claim 37, wherein the charging means is a high voltage that causes an oscillation operation to occur in response to a pulse signal from the outside. The electronic imaging device according to claim 38, wherein the pulse signal input to the charging means is at least in response to a state of charge of the charging means and a residual charge amount of the secondary battery - 52- In the electronic imaging device described in claim 37, the above-mentioned power control means is supplied to the above-mentioned electric power control device. The driving means, the imaging means, the display means, and the communication means restrict or prohibit the supply of electric power to the charging means. The electronic imaging device according to claim 37, wherein the power control means calculates the power that can be supplied in response to the amount of residual charge of the secondary battery, and supplies the power to the driving means and the imaging means. And the display means and the communication means, and when the secondary battery is left over, the supply means is supplied with electric power, and the amount of electric power supplied is controlled so as not to exceed the supply of the secondary battery while controlling the pulse signal. ability. 42. An electronic imaging apparatus comprising: a lens group including at least one or more groups for moving a light beam from a subject from a wide angle to a telephoto; and in order to zoom in the lens group; a driving means for generating a driving force for moving; an imaging means for converting a subject into an electrical signal; a display means for performing various displays by the image captured by the imaging means; and performing dialogue, mail, data transmission, a communication means such as an internet connection; a rechargeable secondary battery; a charging means for converting the voltage of the secondary battery into a high voltage; and having an electric energy conversion to be accumulated in the charging means The illumination means of the light source energy, and the power control means for controlling the power supply from the secondary battery to the driving means, the imaging means, the display means, the communication means, and the charging means of the above -53-356628 When the power control means is such that the residual charge amount of the secondary battery is reduced, the illumination hand should be lowered. Setting conditions of the light emission frequency. 43. An electronic imaging device comprising: a first optical means located closest to a subject side including a reflection optical means for bending a light beam from a first optical axis of the subject into a second optical axis; a second lens group that moves along the second optical axis, a third lens group that performs different operations from the second lens group, and a lens that moves the second lens group and the third lens group a group moving means; an image capturing means for converting the subject image into an electric signal; and a display means for displaying an animation output and/or a still picture output generated by the image capturing means, wherein the electronic image capturing device is characterized by: a first frame body having at least the imaging means and the display means; the second frame body having a shutter means for instructing an imaging operation of the imaging means to be incorporated; and a plurality of shutter means including the shutter means The surface of the characters, symbols, etc., which are printed and imprinted by the operation means and the above-mentioned operation means, and the above-mentioned majority operation means; and the above-mentioned explanation means part, and A hinge means for rotatably holding the second frame body portion in the first frame body portion, and when the second frame body portion is in an open photographing state with respect to the first frame body portion, the second frame body portion is provided The position of the first frame body can be folded. In the above-mentioned shooting position, the position of the letter and symbol of the above-mentioned explanation means is approximately the same as the longitudinal direction of the display means, and the display means is short. The side direction is approximately parallel to the second optical axis, and the long side of the imaging possible region of the imaging means is substantially parallel to the longitudinal direction of the display means. The electronic imaging device according to the first aspect of the invention, wherein the longitudinal direction of the electronic imaging device is taken as a vertical direction, and the vertical position is taken as a standard. The electronic imaging device according to claim 43, wherein the first optical means is constituted by a right angle , and does not have optical power of either of positive and negative. 46. An electronic imaging device comprising: a first optical means located closest to a subject side including a reflection optical means for bending a light beam from a first optical axis of the subject into a second optical axis; a second lens group that moves along the second optical axis, a third lens group that performs different operations from the second lens group, and a lens that moves the second lens group and the third lens group a group moving means; an image capturing means for converting the subject image into an electric signal; and a display means for displaying an animation output and/or a still picture output generated by the image capturing means, wherein the electronic image capturing device is characterized by: Regardless of the first optical means as a whole or the optical components constituting the first optical means, the optical power of either of the positive and negative is not held. The electronic imaging device according to claim 46, wherein the reflective optical means is approximately 90 degrees along the long side of the effective imaging-55-1356628 region of the imaging means. An electronic imaging device comprising: a first optical means located closest to a subject side including a reflection optical means for bending a light beam from a first optical axis of the subject into a second optical axis; a second lens group that is moved along the second optical axis by zooming; a third lens group that performs different operations from the second lens group for zooming; and a change of the second lens group and the third lens group a lens group moving means for each moving lens group; and an imaging means having a rectangular effective imaging area for converting the subject image into an electric signal, wherein the reflecting optical means is only effective imaging of the rectangular shape of the imaging means In the image circle beam whose approximate diagonal length is the diameter, the light beam of the effective imaging area of the rectangle passes. The electronic imaging device according to claim 48, wherein the reflective optical means is bent about 90 degrees along a long side of an effective imaging region of the imaging means. 3