JP5609238B2 - Optical structure, portable terminal, and lens position detection method - Google Patents

Description

The present invention relates to an optical chemical structure, the portable terminal, and a position detection method of the lens.

  In recent years, a piezoelectric element is used for moving a lens in a small electronic device such as a mobile phone in order to realize an autofocus function or a zooming function. The piezoelectric element generates dielectric polarization inside, and generates a voltage when an external force such as vibration or pressure is applied.

  In such an electronic device, as shown in FIGS. 12A and 12B, when the autofocus function or the zooming function is realized, the electronic apparatus is moved to the focus (focus) position (JP) as a target position. Once the lens 14 is moved to the mechanical end, the piezoelectric element 18 is vibrated for a predetermined time. Here, the “mechanical end” refers to a limit position where the lens 14 can move rearward (image sensor 11 side) in the lens barrel 15 with reference to FIG. 12. On the other hand, the “macro end” refers to a limit position where the lens 14 is in focus on the macro side, that is, the limit position where the lens 14 can move forward (opening 15a side) in the lens barrel 15. . In addition, “10 cm” in FIG. 12B is a general minimum value of the macro shooting range of a small camera mounted on a mobile phone or the like.

  According to this position control, the position of the lens 14 is controlled after the lens 14 is constantly moved to the mechanical end. For this reason, even if the lens is positioned at or near the target position by the previous position control, it is necessary to move the lens 14 again from the mechanical end, so the lens position control is not efficient.

  On the other hand, a piezoelectric element is used for moving the lens, and a plurality of permanent (MR) elements fixed to the lens and a plurality of permanent N / S poles arranged alternately along the moving direction of the lens. An electronic device that detects the position of a lens using a magnet is known (for example, see Patent Document 1).

  According to this technique, since the control unit of the electronic device can know the position of the lens, the position control of the lens can be made efficient based on the position information. That is, it is only necessary to move the lens from the current lens position to JP without returning the lens to the mechanical end, thereby improving the efficiency of lens position control.

Japanese Patent Laid-Open No. 9-43479

  However, in this technique, in addition to the piezoelectric element and its driver, extra components such as an MR element and its driver and a plurality of permanent magnets are required for detecting the position of the lens. For this reason, there is a problem that it is difficult to apply to a small communication device such as a mobile phone, which is increasingly required to be smaller, thinner and cost-saving in recent years.

  The present invention has been made in view of the above problems, and an object of the present invention is to provide an optical structure capable of efficiently controlling the position of a lens while responding to downsizing, thinning, and cost saving of electronic devices. And

The optical structure of the present invention is an optical structure that realizes a focus function or a zooming function by moving a lens in the optical axis direction,
A frictional engagement with a lens mount that supports the lens, and a guide member for moving the lens mount in the optical axis direction;
An actuator element that converts an electric signal input from the outside into a vibration signal, and converts a vibration signal received from the outside into an electric signal;
Control for inputting first and second electric signals to the actuator element, causing the actuator element to transmit first and second vibration signals, respectively, and receiving an electric signal based on an external vibration signal from the actuator element. And comprising
The actuator element transmits the first vibration signal to the guide member based on the first electric signal from the control unit, and moves the lens along the guide member in the optical axis direction together with the lens mount. And based on the second electric signal from the control unit, the second vibration signal is transmitted to the guide member,
The control unit includes the second electric signal, a third electric signal obtained by converting a reflected wave signal, which is a third vibration signal generated by reflecting the second vibration signal by the lens mount, by the actuator element, And detecting the position of the lens in the optical axis direction and inputting the first electric signal to the actuator element to move the lens from the detected lens position to a target lens position. Let
In the actuator element, the vibration direction of the first vibration signal is substantially orthogonal to the direction of the electric field formed between the electrodes in the actuator element in order to cause the vibration.
The actuator element outputs a drive signal electrode terminal group used for inputting the first and second electrical signals corresponding to the first and second vibration signals, and a third electrical signal corresponding to the reflected wave signal. And a reflected wave signal electrode terminal group to be used,
The actuator element is a piezoelectric element made of at least one material selected from the group consisting of PZT ceramics, piezoelectric single crystals, and polymer resin / ceramic composite materials,
The drive signal electrode terminal group and the reflected wave signal electrode terminal group in the piezoelectric element are disposed in a direction substantially orthogonal to the polarization direction of the piezoelectric element.
It is characterized by that.

The mobile terminal of the present invention is a mobile terminal equipped with a camera device that realizes a focus function or a zooming function by moving a lens to a predetermined position,
The camera device includes the optical structure for realizing the focus function or the zooming function.

The lens position detection method of the present invention is a method used for an optical structure that realizes a focus function or a zooming function by moving the lens in the optical axis direction,
The optical structure is frictionally engaged with a lens mount that supports the lens, and a guide member for moving the lens mount in the optical axis direction;
An actuator element that converts an electric signal input from the outside into a vibration signal, and converts a vibration signal received from the outside into an electric signal;
Inputting first and second electric signals to the actuator element, transmitting the first and second vibration signals from the actuator element, respectively, and receiving an electric signal based on an external vibration signal from the actuator element; ,
The actuator element transmits the first vibration signal to the guide member based on the first electrical signal, moves the lens together with the lens mount along the guide member in the optical axis direction, and Transmitting the second vibration signal to the guide member based on two electrical signals;
Based on the time difference between the second electrical signal and the third electrical signal obtained by converting the reflected wave signal, which is a third vibration signal generated by the reflection of the second vibration signal by the lens mount, by the actuator element, Detecting the position of the lens in the optical axis direction, inputting the first electric signal to the actuator element, and moving the lens from the detected lens position to a target lens position; Prepared,
In the actuator element, the vibration direction of the first vibration signal is substantially orthogonal to the direction of the electric field formed between the electrodes in the actuator element in order to cause the vibration.
The actuator element outputs a drive signal electrode terminal group used for inputting the first and second electrical signals corresponding to the first and second vibration signals, and a third electrical signal corresponding to the reflected wave signal. And a reflected wave signal electrode terminal group to be used,
The actuator element is a piezoelectric element made of at least one material selected from the group consisting of PZT ceramics, piezoelectric single crystals, and polymer resin / ceramic composite materials,
The drive signal electrode terminal group and the reflected wave signal electrode terminal group in the piezoelectric element are disposed in a direction substantially orthogonal to the polarization direction of the piezoelectric element.
And wherein a call.

  ADVANTAGE OF THE INVENTION According to this invention, while responding to size reduction, thickness reduction, and cost saving of an electronic device, the optical structure which can perform position control of a lens efficiently can be provided.

(A) is a front view which shows the external appearance of the mobile telephone which incorporated the camera apparatus, (b) is a rear view which shows the external appearance of the mobile phone. It is a block diagram which shows the mechanical structure and electrical structure of a camera apparatus. It is a block diagram which shows the electrical structure of an auto focus (AF) driver. It is a structural diagram showing a configuration of a piezoelectric element. (A) is a figure which shows the signal for lens movement, the signal for lens position detection, and a reflected wave signal, (b) is a figure which shows the rattle correction signal. It is a flowchart which shows the autofocus control operation | movement of a camera apparatus. (A) is a structural diagram showing the autofocus control operation of the camera device, (b) is a schematic diagram showing the autofocus control operation of the camera device. It is a structural diagram which shows another structure of a piezoelectric element. FIG. 6 is a structural diagram showing still another configuration of a piezoelectric element. FIG. 6 is a structural diagram showing still another configuration of a piezoelectric element. FIG. 6 is a structural diagram showing still another configuration of a piezoelectric element. (A) is a structural diagram showing the autofocus control operation of the camera device of the reference example, and (b) is a schematic diagram showing the autofocus control operation of the camera device. It is a flowchart which shows another autofocus control operation | movement of a camera apparatus.

  Embodiments of the present invention will be described below. The present invention can be applied to various mobile phones, mobile devices such as electronic cameras (digital cameras), PDAs (Personal Digital Assistant), and camera devices mounted on electronic devices such as small PCs (Personal computers). . In other words, the embodiments described below are for illustrative purposes and do not limit the scope of the present invention. Therefore, those skilled in the art can employ embodiments in which each of these elements or all of the elements are replaced with equivalent ones, and these embodiments are also included in the scope of the present invention.

  As shown in FIGS. 1A and 1B, a mobile phone 100 according to an embodiment of the present invention is a foldable type, and a first casing 101 and a second casing 102 are hinge portions. It is connected via an opening 100a.

  The cellular phone 100 includes a camera device 10 having an optical structure that realizes a camera function, and a rectangular LCD display unit 100d that includes an LCD (Liquid Crystal Display). The camera device 10 is disposed in a lower portion of the first housing 101, and the display unit 100 d is disposed in the front side center portion of the first housing 101. And the image image | photographed with the camera apparatus 10 can be displayed on the display part 100d.

  In addition, a distance meter 27 for measuring the distance between the subject and the mobile phone 100 using ultrasonic waves is disposed in the upper part on the back side of the first housing 101. The distance meter 27 has a conventionally well-known configuration including an output unit that outputs ultrasonic waves and an input unit (none of which is shown) that receives ultrasonic waves reflected by the subject. The distance between the subject and the mobile phone 100 is measured based on the time difference between the timing at which the ultrasonic wave is output from the output unit and the timing at which the ultrasonic wave is received at the input unit, and the result is carried as a digital signal. It outputs to the optical system control part 20 (refer FIG. 2) in the telephone 100 inside. In addition, in addition to ultrasonic waves, infrared rays can be used for distance measurement here.

  As shown in FIGS. 1A and 1B, the second casing 102 of the mobile phone 100 accepts an input of a character string or a number from the user in addition to the imaging key 25 that functions as a shutter button. An operation unit 103 having operation keys such as a numeric keypad is provided. The imaging key 25 is used as a trigger switch that operates a shutter (not shown) of the camera device 10 and generates image data by the image sensor 11 (see FIG. 2). The imaging key 25 also functions as an autofocus switch that serves as a trigger for adjusting the focus of the lens by computer control, and a switch for operating the distance meter 27.

  In addition, an imaging mode setting button 26 for setting the mobile phone 100 to an imaging mode (camera mode) in which the camera device 10 operates is provided on the right side surface of the second housing 102 by a pressing operation with a finger. ing.

  As shown in FIG. 2, the camera device 10 includes a lens barrel 15, a ring-shaped support base 15 s that supports the lens barrel 15 from the rear, a lid member 16 that closes the inside of the lens barrel 15, and a lens 14 for imaging. ing.

  On the front side of the lens barrel 15, an opening 15 a for collecting light from the subject into the camera device 10 is provided. In the lens barrel 15, an image sensor (CCD (Charge Coupled Device)) 11 as an image sensor is disposed on the front surface of the lid member 16. In this embodiment, a CCD is used as the image sensor 11, but a CMOS (Complementary Metal Oxide Semiconductor) may be used instead of the CCD.

  The image sensor 11 has a rectangular light receiving region (not shown) in which a plurality of light receiving elements are arranged in a matrix. A shutter (not shown) of the camera device 10 is operated with the operation of the imaging key 25 as a trigger. Then, the light that enters the inside of the lens barrel 15 through the opening 15 a travels along the optical axis 19 and is collected by the lens 14, and then the optical image is received by the light receiving region on the image sensor 11.

  In addition to the lens 14, a guide shaft 17 a and a support shaft 17 b extending in the front-rear direction are accommodated inside the lens barrel 15 so that the lens 14 is sandwiched with the rear end portion fixed to the support base 15 s. Has been.

  And the lens 14 is hold | maintained at the ring-shaped lens mount 14a, and the guide shaft 17a is penetrated by the peripheral part below the lens mount 14a, and is engaged by friction. Further, a support shaft 17b is inserted through the upper peripheral portion of the lens mount 14a and engaged by friction. With this structure, a predetermined vibration signal is applied to the guide shaft 17a in the axial direction, so that the lens 14 can move in the front-rear direction while being held by the lens mount 14a.

  As shown in FIG. 2, the inside of the lens barrel 15 is further electrically connected to the piezoelectric element 18 as the actuator element and the piezoelectric element 18, and an electric signal is input to and output from the piezoelectric element 18. An autofocus driver 12 (hereinafter referred to as “AF driver 12”) is accommodated. The piezoelectric element 18 and the AF driver 12 are fixed to the support base 15s and the lid member 16, respectively. The piezoelectric element 18 is an element that generates dielectric polarization inside. When a vibration signal is applied from the outside, the piezoelectric element 18 generates an electric signal (analog voltage) that changes in accordance with the vibration, and conversely sawtooth, triangular, sine, etc. When an electrical signal whose value changes in time series is input, a vibration signal that changes according to the voltage is generated. This generated vibration signal changes in accordance with the amplitude (maximum voltage value) and application time (time period) of the electrical signal. In addition, the generated electrical signal changes according to the amplitude of the vibration signal and the time period of vibration. That is, if the amplitude of the vibration signal is large, the amplitude of the electric signal is correspondingly increased. If the time period of the vibration signal is long, the application time of the electric signal is correspondingly increased. Further, if the amplitude of the electrical signal is large, the amplitude of the vibration signal is correspondingly increased. If the application time of the electrical signal is long, the time period of the vibration signal is correspondingly increased.

  The piezoelectric element 18 is coupled to an end portion on the rear (image sensor 11) side of the guide shaft 17a that functions as a vibration transmission spring. When the piezoelectric element 18 vibrates by the lens movement signal 30 which is the first electric signal from the AF driver 12, a first vibration signal is transmitted to the guide shaft 17a, and the lens 14 causes the guide shaft 17a and the support shaft to be transmitted by this vibration. It moves in the front-rear direction along 17b.

  As shown in FIG. 2, the mobile phone 100 further includes an optical system that is a CPU (Central Processing Unit) as an electronic component in addition to the flexible substrate 13 on which the lid member 16 of the camera device 10 is disposed. A control unit 20, a RAM (Random Access Memory) 21, a ROM (Read Only Memory) 22, a CCD signal processing circuit 23, a flash memory 24, and an A / D converter 29 are provided. These electronic components are disposed on the flexible substrate 13. The same operation can be realized by using a DSP (Digital Signal Processor) instead of the CPU.

  The RAM 21, ROM 22, and CCD signal processing circuit 23 are each electrically connected to the optical system control unit 20. The image sensor 11 is electrically connected to a CCD signal processing circuit 23 via an A / D converter 29. The CCD signal processing circuit 23 is electrically connected to the flash memory 24 and the LCD display unit 100d (see FIG. 1). It is connected to the. The optical system control unit 20 exchanges commands and data with the RAM 21, ROM 22, and CCD signal processing circuit 23 for imaging processing by the camera device 10. The CCD signal processing circuit 23 receives image data from the image sensor 11 as a digital signal by a preprocessing circuit (not shown) and an A / D converter 29, and performs various image processing. Then, the CCD signal processing circuit 23 displays the image data after the image processing as an image by a plurality of pixels of the LCD display unit 100d. The CCD signal processing circuit 23 stores various image data that are digital signals in the flash memory 24.

  The ROM 22 stores an operating system (OS) program necessary for the operation of the entire control system, other operation application programs, and various data. The optical system control unit 20 stores these programs from the ROM 22 into the RAM 21. Read and execute. The RAM 21 temporarily stores data and programs and is used as a work area. The RAM 21 stores programs and data read from the ROM 22 and other information necessary for information processing.

  As shown in FIG. 2, an imaging key 25, an imaging mode setting button 26, and an operation unit 103 (see FIG. 1) are electrically connected to the optical system control unit 20. Symbols, text input information, and on / off external signals are received from these switches and used for program processing in the optical system control unit 20. A distance meter 27 is electrically connected to the optical system control unit 20 via an interface circuit (not shown). The distance data measured by the distance meter 27 is converted into the focus (focal point) position of the lens 14 by a program process using a table (conversion table) in the optical system control unit 20. Further, by operating the imaging key 25, the optical system control unit 20 operates a shutter (not shown) of the camera device 10 and causes the image sensor 11 to generate image data. Further, by operating the imaging mode setting button 26, the mobile phone 100 is set to an imaging mode in which the camera device 10 operates by the optical system control unit 20.

  In this embodiment, the piezoelectric element 18 is used as a drive source, and the optical image formed on the image sensor 11 is focused by moving the lens 14 along the guide shaft 17a and the support shaft 17b together with the lens mount 14a. Done. That is, the piezoelectric element 18 is controlled by the optical system control unit 20 via the AF driver 12. In other words, the piezoelectric element 18 transmits the first vibration signal to the rear end of the guide shaft 17a with the focus position based on the distance meter 27 calculated by the optical system control unit 20 as a target value, and transmits the lens 14 to the optical axis. Move in the direction of the axis 19. Thereby, an autofocus process for forming an image of the focus of the lens 14 on the image sensor 11 (imaging surface) is executed.

  As shown in FIG. 3, the AF driver 12 includes a signal output electric circuit system including a first signal amplifier circuit 1001, an output circuit 1003, and an output terminal 12b1, a second signal amplifier circuit 1002, an input circuit 1004, and an input And a signal input electric circuit system including the terminal 12b2.

  The AF driver 12 further includes a piezoelectric element connection terminal 12a, a changeover switch 12s for switching both electric circuit systems on the piezoelectric element 18 side, and a control signal input terminal 12c.

  The piezoelectric element connection terminal 12a, the first signal amplification circuit 1001, and the second signal amplification circuit 1002 are connected via a changeover switch 12s. The first signal amplifier circuit 1001, the output circuit 1003, and the output terminal 12b1 are connected in series. Further, the second signal amplifier circuit 1002, the input circuit 1004, and the input terminal 12b2 are connected in series. The changeover switch 12s is connected to the piezoelectric element 18 via the piezoelectric element connection terminal 12a.

  An electrical signal that is an analog voltage from the piezoelectric element 18 is amplified to a predetermined voltage value by the first signal amplifying circuit 1001, converted to a digital signal by the output circuit 1003, further subjected to filter processing and signal processing, and then output. It is output to the optical system controller 20 via the terminal 12b1. On the other hand, the digital signal from the optical system control unit 20 is converted into an electrical signal that is an analog voltage by the input circuit 1004, then amplified to a predetermined voltage value by the second signal amplification circuit 1002, and output to the piezoelectric element 18. The The output circuit 1003 and the input circuit 1004 are electrically connected to the optical system control unit 20 via the output terminal 12b1 and the input terminal 12b2.

  The control signal input terminal 12 c is electrically connected to the optical system control unit 20. Based on the control signal which is a digital signal received at the control signal input terminal 12c, the changeover switch 12s switches the connection between the piezoelectric element 18 and the signal output electric circuit system and the signal input electric circuit system of the AF driver 12. It has become. That is, when a control signal is input from the optical system control unit 20, the piezoelectric element 18 and the signal output electrical circuit system are connected, and an electrical signal that is an analog voltage from the piezoelectric element 18 is converted into a digital signal, and the optical signal is transmitted. The status is output to the system control unit 20. On the other hand, when the input of the control signal from the optical system control unit 20 is stopped, the piezoelectric element 18 and the signal input electric circuit system are connected, and the digital signal from the optical system control unit 20 is a predetermined analog voltage. It is converted into a certain electric signal and is output to the piezoelectric element 18.

As shown in FIG. 4, the piezoelectric element 18 according to the present embodiment is fixed to a support base 15s.
The piezoelectric element 18 includes a drive signal plus terminal 18a, a drive signal minus terminal 18b, a drive signal plus electrode 18c, and a drive signal minus electrode 18d. The drive signal plus terminal 18a is electrically connected to the drive signal plus electrode 18c, and the drive signal minus terminal 18b is electrically connected to the drive signal minus electrode 18d. A piezoelectric active layer 18e is interposed between the drive signal plus electrode 18c and the drive signal minus electrode 18d. In FIG. 4, the piezoelectric element 18 is fixed to the support base 15s at the end face on the drive signal minus electrode 18d side, but may be fixed to the support stand 15s on the end face on the drive signal plus electrode 18c side. Good.

  For the piezoelectric active layer 18e, at least one selected from the group consisting of PZT (lead zirconate titanate) ceramics, piezoelectric single crystals, and polymer resin / ceramic composite materials can be preferably used. Moreover, you may mix these multiple types of materials in the piezoelectric active layer 18e. Among them, it is preferable to use PZT ceramics because of high energy conversion efficiency for converting input power into vibration signal energy.

  In this state, the lens movement signal 30 (first electric signal) and the lens position detection signal 40 (second electric signal) which are predetermined electric signals from the AF driver 12 to the driving signal plus terminal 18a and the driving signal minus terminal 18b. Is applied to the piezoelectric active layer 18e by the drive signal plus electrode 18c and the drive signal minus electrode 18d. Here, in the piezoelectric active layer 18e, the polarization direction of the crystal dipole is set in the front-rear direction of FIG. 2 according to the direction of the applied voltage. For this reason, the piezoelectric active layer 18e expands and contracts in the front-rear direction by a so-called piezoelectric effect, and corresponds to the lens movement signal 30 (first electric signal) and the lens position detection signal 40 (second electric signal), respectively. Thus, the first and second vibration signals which are vibration signals are generated.

  In this case, as shown in FIG. 4, the transmission direction (vibration direction) of the vibration signal of the piezoelectric active layer 18e is substantially orthogonal to the drive signal plus electrode 18c and the drive signal minus electrode 18d. That is, the vibration direction of the vibration signal of the piezoelectric active layer 18e is substantially parallel to the direction of the electric field formed by the electrodes in the piezoelectric element 18. Then, the vibration signal is transmitted to the end portion of the guide shaft 17a located in front of the piezoelectric element 18. The vibration signal here includes the first and second vibration signals, and the first and second electric signals corresponding to the first and second vibration signals are shown in FIG. These are the lens movement signal 30 and the lens position detection signal 40 shown.

  The lens movement signal 30 and the lens position detection signal 40 will be described with reference to FIG. When the lens is moved, the lens position detection signal 40 that is the second electric signal is output from the AF driver 12 first, and then the lens movement signal 30 that is the first electric signal is output from the AF driver 12. As described above, the lens movement signal 30 and the lens position detection signal 40 are output from the AF driver 12 with a predetermined amplitude and a predetermined cycle at a timing that does not overlap in time. This prevents temporal interference between both electrical signals, and the first and second vibration signals transmitted from the piezoelectric element 18 corresponding to both electrical signals are completely separated in time. Further, here, as shown in FIG. 5A, the reflected wave signal 40a which is the third vibration signal generated by reflecting the lens position detection signal 40 by the lens mount 14a in the piezoelectric element 18 is also reflected and returned. Therefore, the lens movement signal 30 and the lens position detection signal 40 are transmitted and received at a timing that does not overlap in time.

  In FIG. 5A, the lens movement signal 30 indicated by the solid line located above the time axis is the lens position L, that is, when the current focal position of the lens 14 is located closer to the mechanical end than JP. Are output from the AF driver 12. On the other hand, a lens movement signal 31 indicated by a broken line located below the time axis in the figure is output from the AF driver 12 when the lens position L is located on the macro end side from JP. is there. Here, the “mechanical end” refers to a limit position where the lens 14 can move rearward (image sensor 11 side) in the lens barrel 15 with reference to FIG. On the other hand, the “macro end” refers to a limit position where the lens 14 is in focus on the macro side, that is, the limit position where the lens 14 can move forward (opening 15a side) in the lens barrel 15. . Further, “10 cm” in FIG. 7B is a general minimum value of the macro shooting range of a small camera mounted on a mobile phone or the like.

  Further, as shown in FIG. 5A, the lens movement signal 30 and the lens position detection signal 40 are both in an asymmetrical sawtooth shape. At this time, the negative electrode 18d is set to the ground (ground) side. As a result, each electric signal is composed of a rising portion where the voltage rises gently and a falling portion where the voltage drops suddenly. With reference to FIG. 2, the guide shaft 17a moves forward slowly. , Repeat the rapid backward movement. Each electric signal may be composed of a rising portion where the voltage suddenly rises and a falling portion where the voltage gradually falls.

  When the guide shaft 17a gently moves forward, the lens mount 14a also moves forward by the frictional force between the guide shaft 17a and the lens mount 14a. On the other hand, when the guide shaft 17a suddenly moves backward, the lens mount 14a tends to stay in place due to inertia (only the guide shaft 17a moves backward). By repeating such an operation, the lens mount 14a and the lens 14 can be displaced (moved) forward.

  Since the reflected wave signal 40a is a third vibration signal generated by reflecting the second vibration signal by the lens mount 14a, there is a steep change in the lens moving signal 30 as shown in FIG. Suppressed, rounded, and distorted waveform.

  Returning to FIG. 4, when the piezoelectric element 18 receives the reflected wave signal 40a from the outside, an electric field that alternately changes in the piezoelectric active layer 18e is generated by the vibration. Then, a predetermined electrical signal is induced on the drive signal plus electrode 18c and the drive signal minus electrode 18d. Then, the electric signal is output from the drive signal plus terminal 18 a and the drive signal minus terminal 18 b of the piezoelectric element 18 toward the AF driver 12.

  Hereinafter, the operation (autofocus control operation) of the camera apparatus 10 of the present embodiment will be described with reference to the flowchart of FIG. This autofocus control operation is executed by a lens position control program stored in the ROM 22.

  As shown in FIG. 6, first, after the mobile phone 100 is powered on, the optical system control unit 20 of the mobile phone 100 determines whether or not the mobile phone 100 is set to the imaging mode. That is, the optical system control unit 20 determines whether or not the imaging mode setting button 26 has been operated (step S101).

  If the optical system control unit 20 determines that the imaging mode setting button 26 is not operated (step S101: No), the optical system control unit 20 continues the determination state (standby state) of whether or not the imaging mode setting button 26 is operated (step S101).

  On the other hand, when the imaging mode setting button 26 is operated and the optical system control unit 20 determines that the mobile phone 100 is set to the imaging mode (step S101: Yes), the imaging key 25 as an autofocus switch is operated. It is detected whether it was done.

If the optical system control unit 20 determines that the imaging key 25 has not been operated (step S102: No), the optical system control unit 20 continues to determine whether or not the imaging key 25 has been operated (standby state) (step S102).
On the other hand, when the optical system control unit 20 determines that the imaging key 25 has been operated (step S102: Yes), the optical system control unit 20 starts an autofocus control operation (step S103).

  That is, the optical system control unit 20 first determines a focus position (hereinafter referred to as “JP”), which is a focused position, using a predetermined table based on the distance data from the distance meter 27. This JP is the target position of the lens position in the autofocus control.

  In subsequent step S <b> 104, the optical system control unit 20 controls the piezoelectric element 18 via the AF driver 12. That is, a predetermined electrical signal (analog voltage) is supplied from the AF driver 12 to the piezoelectric element 18 based on the digital signal from the optical system control unit 20. Here, of the two types of first and second electric signals having different amplitudes and application times, a lens position detection signal 40 that is a second electric signal is output from the AF driver 12 to the piezoelectric element 18. Based on the lens position detection signal 40, the piezoelectric element 18 transmits a second vibration signal to the rear end of the guide shaft 17a (see FIGS. 2 and 4). The second vibration signal is transmitted along the guide shaft 17a and reaches the lens mount 14a. Then, it is reflected by the lens mount 14a, is transmitted as a reflected wave signal 40a as a third vibration signal along the guide shaft 17a, and returns to the piezoelectric element 18 (step S104).

  Then, the optical system control unit 20 determines whether or not the piezoelectric element 18 has received the reflected wave signal 40a (see FIG. 5A). That is, it is determined whether or not the piezoelectric element 18 has output a third electrical signal corresponding to the reflected wave signal 40a. Whether or not the third electric signal is derived from the reflected wave signal 40a is determined based on the input / output timing and frequency of the third electric signal. That is, when based on the input / output timing of the third electric signal, the optical system control unit 20 sets the changeover switch 12s of the AF driver 12 to the signal output electric circuit system at the timing of outputting the third electric signal to the piezoelectric element 18. Control is performed so as not to receive the third electric signal from the piezoelectric element 18. On the other hand, at the timing of receiving the third electrical signal from the piezoelectric element 18, the optical system control unit 20 switches the changeover switch 12 s of the AF driver 12 to the signal input electrical circuit system side and outputs the third electrical signal to the piezoelectric element 18. Control to not perform. On the other hand, when based on the frequency, a filter circuit (not shown) built in the output circuit 1003 (see FIG. 3) of the AF driver 12 is used to selectively receive only a specific frequency signal from the piezoelectric element 18. To. Further, in order to remove noise having the same frequency as that of the reflected wave signal 40a from the lens mount 14a, the optical system control unit 20 provides a threshold value for the maximum value (peak value) of the signal amplitude (voltage value), and is higher than the threshold value. In the case of a signal having a peak value, it is determined that the signal is a reflected wave signal 40a and used for detection of the lens position. Here, the threshold value is determined by the arrangement and shape of the guide shaft 17a, the lens mount 14a, and the like, and may be set to 20 to 80% of the peak value of the sawtooth lens position detection signal 40. Preferably (step S105).

  If it is determined that the piezoelectric element 18 has not received the reflected wave signal 40a (step S105: No), the optical system control unit 20 continues outputting the lens position detection signal 40 a predetermined number of times in step S104. If the detection cannot be performed within the predetermined number of times, the autofocus control process is once ended (step S108).

  On the other hand, when it is determined that the reflected wave signal 40a is received (step S105: YES), the optical system control unit 20 receives both signals (lens position detection) transmitted and received by the piezoelectric element 18 as shown in FIG. The half of the time difference Δt (sec) between the signal 40 for use and the reflected wave signal 40 a) is multiplied by the transmission speed v (mm / sec) of the signal. Then, the optical system control unit 20 calculates and acquires the lens position L (L = Δt × v (mm) / 2) from the piezoelectric element 18 to the lens 14 (lens position detection operation) (step S106).

  In subsequent step S107, the optical system control unit 20 compares JP with the lens position L, and as shown in (i) of FIG. 7B, the lens position L, that is, the current focal position of the lens 14. 7 is located on the mechanical end side with respect to the JP, the lens movement signal 30 (FIG. 5 (a)) is sent to the piezoelectric element 18 with reference to FIG. 7 (a). )) Is supplied from the AF driver 12. Then, the optical system control unit 20 transmits the first vibration signal corresponding to the separation distance between the lens position L and JP from the piezoelectric element 18 to the guide shaft 17a with a predetermined amplitude and a predetermined period, at least one period or more. . On the other hand, when the optical system control unit 20 determines that the lens position L is located closer to the macro end than JP as shown in (ii) of FIG. 7B, FIG. Referring to FIG. 5, a lens movement signal 31 (see FIG. 5A) that is a first electric signal is supplied from the AF driver 12 to the piezoelectric element 18. Then, the optical system control unit 20 transmits the first vibration signal corresponding to the separation distance between the lens position L and JP from the piezoelectric element 18 to the guide shaft 17a with a predetermined amplitude and a predetermined period, at least one period or more. . Thereby, referring to FIG. 7A, the lens 14 moves to the front side or the rear side and stops at JP, and autofocus (automatic focus setting) is realized. That is, focusing by the computer control of the camera device 10 is completed (step S107).

  Thereafter, the optical system control unit 20 once ends the autofocus control process here (step S108).

According to this embodiment, the following operational effects are obtained.
That is, by using the piezoelectric element 18 not only for the movement operation of the lens 14 but also for the position detection operation of the lens 14, extra elements such as an MR element and its driver, a plurality of permanent magnets, etc. are used to detect the position of the lens 14. Auto focus control (lens position control) can be performed at low cost without using parts.
As a result, the cellular phone 100 according to the present embodiment can cope with downsizing, thinning, and cost saving, and can efficiently control the lens position.

In addition, this invention is not limited to embodiment mentioned above, A various deformation | transformation and application are possible.
For example, in the above embodiment, the technical idea of the present invention is applied to the autofocus process of the camera device. However, the present invention is not limited to this, and the technical idea of the present invention can be applied to, for example, zooming processing as long as a certain effect can be realized by lens position control.

  In the above-described embodiment, the driving signal plus terminal 18a and the driving signal minus terminal 18b of the piezoelectric element 18 are used for the lens movement signal 30 and the lens position detection signal 40, which are the first and second electric signals. The input and the output of the third electric signal corresponding to the reflected wave signal 40a which is the third vibration signal were performed. However, the present invention is not limited to this, and it is also possible to provide dedicated electrode terminals for the input of the first and second electric signals and the output of the third electric signal corresponding to the third vibration signal.

In this case, referring to FIG. 8, electrodes dedicated to the input of the first and second electric signals and the output of the third electric signal corresponding to the third vibration signal according to the modification of the present embodiment, respectively. The piezoelectric element 118 provided with terminals will be described. Here, the piezoelectric element 118 is fixed to the support base 15s at the end face on the drive signal minus electrode 18d side, but may be fixed to the support stand 15s at the end face on the drive signal plus electrode 18c side.
As shown in FIG. 8, the piezoelectric element 118 includes a drive signal plus terminal 18a, a drive signal minus terminal 18b, a drive signal plus electrode 18c, and a drive signal minus electrode 18d as a drive signal electrode terminal group. And. Here, the drive signal plus terminal 18a is electrically connected to the drive signal plus electrode 18c, and the drive signal minus terminal 18b is electrically connected to the drive signal minus electrode 18d. In the piezoelectric element 118, the drive signal electrode terminal group is used for inputting the lens movement signal 30 (first electric signal) and the lens position detection signal 40 (second electric signal).
Furthermore, the piezoelectric element 118 includes a reflected wave signal plus terminal 18f, a reflected wave signal minus terminal 18g, a reflected wave signal plus electrode 18h, and a reflected wave signal minus electrode 18k as a reflected wave signal electrode terminal group. And. The reflected wave signal plus terminal 18f is electrically connected to the reflected wave signal plus electrode 18h, and the reflected wave signal minus terminal 18g is electrically connected to the reflected wave signal minus electrode 18k.
Here, between the drive signal plus electrode 18c and the drive signal minus electrode 18d, and between the reflected wave signal plus electrode 18h and the reflected wave signal minus electrode 18k, the piezoelectric activity is all. The layer 18e (a part thereof) is interposed. In the piezoelectric element 118, this reflected wave signal electrode terminal group is used for the output of the third electric signal generated by the reflected wave signal 40 a (third vibration signal).
The drive signal electrode terminal group of the piezoelectric element 118 has a structure in which a part of the piezoelectric active layer 18e is sandwiched between the drive signal plus electrode 18c and the drive signal minus electrode 18d. Here, in the piezoelectric active layer 18e, the polarization direction of the crystal dipole is set in the front-rear direction according to the direction of the applied voltage. Therefore, when the lens movement signal 30 and the lens position detection signal 40 are applied to both the electrodes 18c and 18d, the piezoelectric active layer 18e sandwiched between the drive signal plus electrode 18c and the drive signal minus electrode 18d. Performs telescopic motion in the front-rear direction. Further, when the telescopic motion is directed to the support base 15s, it is pushed back to the front side by the support base 15s. Accordingly, the first and second vibration signals are transmitted (transmitted) from the piezoelectric element 118 to the guide shaft 17a on the front side.
On the other hand, the reflected wave signal electrode terminal group of the piezoelectric element 118 has a structure in which a part of the piezoelectric active layer 18e is sandwiched between the reflected wave signal plus electrode 18h and the reflected wave signal minus electrode 18k. When the piezoelectric element 118 receives the reflected wave signal 40a as the third vibration signal from the outside, the piezoelectric element 118 alternates with the piezoelectric active layer 18e sandwiched between the reflected wave signal positive electrode 18h and the reflected wave signal negative electrode 18k by the vibration. Electric field is generated. Then, a predetermined analog voltage is induced on the reflected wave signal plus electrode 18h and the reflected wave signal minus electrode 18k. Then, the third electric signal, which is the analog voltage, is output from the reflected wave signal plus terminal 18 f and the reflected wave signal minus terminal 18 g toward the AF driver 12.
In the piezoelectric element 118, an optimum resonance frequency is set for the drive signal electrode terminal group and the reflected wave signal electrode terminal group by adjusting the distance between the electrodes. According to this, the third electrical signal corresponding to the lens position detection signal 40, which is the second electrical signal, and the reflected wave signal 40a, which is the third vibration signal, is input / output from the piezoelectric element 118 at a time overlapping timing. This can contribute to shortening the time required for autofocus control.
In the piezoelectric element 118 shown in FIG. 8, the reflected wave signal electrode terminal group is arranged on the support base 15s side, and the drive signal electrode terminal group is arranged on the guide shaft 17a side. It is also possible to arrange the drive signal electrode terminal group on the support base 15s side and the reflected wave signal electrode terminal group on the guide shaft 17a side.

Furthermore, in the technical idea of the present invention, the drive signal plus / minus electrodes and the reflected wave signal plus / minus electrodes may each have a laminated structure.
In this case, a piezoelectric element 218 having a laminated structure of drive signal plus / minus electrodes 218c and 218d according to a modification of the present embodiment will be described with reference to FIG. Here, the piezoelectric element 218 is fixed to the support base 15s at the end face on the drive signal plus electrode 218c and the drive signal minus electrode 218d side, but the reflected wave signal plus electrode 18h and the reflected wave signal minus electrode 18k. The end surface on the side may be fixed to the support base 15s.
As shown in FIG. 9, the piezoelectric element 218 includes a drive signal plus terminal 18a, a drive signal minus terminal 18b, a drive signal plus electrode 218c, and a drive signal minus electrode 218d as a drive signal electrode terminal group. And. Here, the drive signal plus terminal 18a is electrically connected to the drive signal plus electrode 218c, and the drive signal minus terminal 18b is electrically connected to the drive signal minus electrode 218d. In the piezoelectric element 218, the driving signal electrode terminal group is used for inputting the lens movement signal 30 (first electric signal) and the lens position detection signal 40 (second electric signal).
The reflected wave signal electrode terminal group of the piezoelectric element 218 shown in FIG. 9 has the same configuration as the reflected wave signal electrode terminal group of the piezoelectric element 118 shown in FIG.
As shown in FIG. 9, in the piezoelectric element 218, each of the drive signal positive electrode 218c and the drive signal negative electrode 218d has a plurality (three in FIG. 9) of plate-like unit electrodes, Each unit electrode has a laminated structure. Further, each unit electrode (positive electrode) of the drive signal plus electrode 218c and each unit electrode (negative electrode) of the drive signal minus electrode 218d are alternately laminated.
As shown in FIG. 9, in the drive signal electrode terminal group of the piezoelectric element 218, a part of the piezoelectric active layer 18e is sandwiched between the drive signal plus electrode 218c and the drive signal minus electrode 218d. have. That is, the piezoelectric active layer 18e (a part thereof) is disposed between the unit electrode of the drive signal plus electrode 218c and the unit electrode of the drive signal minus electrode 218d which are adjacent to each other. .
Here, in the piezoelectric active layer 18e, the polarization direction of the crystal dipole is set in the front-rear direction according to the direction of the applied voltage. Specifically, as shown in FIG. 9, a part of the piezoelectric active layer 18e sandwiched between the unit electrode of the drive signal plus electrode 218c and the unit electrode of the drive signal minus electrode 218d is adjacent to each other + The-direction is a different polarization state.
Therefore, when the lens movement signal 30 and the lens position detection signal 40 are applied to both the electrodes 218c and 218d, the unit electrodes of the drive signal plus electrode 218c and the drive signal minus electrode 218d which are adjacent to each other are applied. A part of the piezoelectric active layer 18e sandwiched between the unit electrodes expands and contracts in the front-rear direction. Further, when the telescopic motion is directed to the support base 15s, it is pushed back to the front side by the support base 15s. Therefore, a part of the piezoelectric active layer 18e sandwiched between the unit electrode of the drive signal plus electrode 218c and the unit electrode of the drive signal minus electrode 218d is adjacent to each other as shown in FIG. The first and second vibration signals are always transmitted (transmitted) from the piezoelectric element 218 to the front side, i.e., the guide shaft 17a side, even if the directions are polarized.
In such a piezoelectric element 218, the thickness of the piezoelectric active layer 18e between each unit electrode of the drive signal electrode terminal group is reduced, and the drive signal electrode terminal group is compared with the piezoelectric elements 18 and 118 having a non-stacked structure. Thus, a high electric field can be generated in the drive signal electrode terminal group by the first and second electric signals having a lower applied voltage. That is, a large amount of mechanical strain can be obtained with a low driving voltage of the piezoelectric element. As a result, the driving voltage for the movement and position detection of the lens 14 decreases, so that the replacement frequency and charging frequency of the battery power source can be reduced.

Referring to FIG. 10, a piezoelectric element 318 having a laminated structure of reflected wave signal plus / minus electrodes 318h and 318k in addition to drive signal plus / minus electrodes 218c and 218d according to a modification of the present embodiment. explain. Here, the piezoelectric element 318 is fixed to the support base 15s at the end face on the drive signal plus electrode 218c and the drive signal minus electrode 218d side, but the reflected wave signal plus electrode 318h and the reflected wave signal minus electrode 318k. The end surface on the side may be fixed to the support base 15s.
The drive signal electrode terminal group of the piezoelectric element 318 shown in FIG. 10 has the same configuration as the drive signal electrode terminal group of the piezoelectric element 218 shown in FIG.
As shown in FIG. 10, the piezoelectric element 318 includes a reflected wave signal plus terminal 18f, a reflected wave signal minus terminal 18g, a reflected wave signal plus electrode 318h, and a reflected wave as a reflected wave signal electrode terminal group. A negative electrode for signal 318k. The reflected wave signal plus terminal 18f is electrically connected to the reflected wave signal plus electrode 318h, and the reflected wave signal minus terminal 18g is electrically connected to the reflected wave signal minus electrode 318k. In the piezoelectric element 318, the electrode terminal group for the reflected wave signal is used for the output of the third electric signal generated by the reflected wave signal 40a (third vibration signal).
Here, each of the reflected wave signal positive electrode 318h and the reflected wave signal negative electrode 318k has a plurality of (three in FIG. 10) plate-like unit electrodes, and each unit electrode has a laminated structure. It has become. Further, each unit electrode (positive electrode) of the reflected wave signal positive electrode 318h and each unit electrode (negative electrode) of the reflected wave signal negative electrode 318k are alternately stacked.
As shown in FIG. 10, in the reflected wave signal electrode terminal group of the piezoelectric element 318, a part of the piezoelectric active layer 18e is sandwiched between the unit electrodes of the reflected wave signal plus electrode 318h and the reflected wave signal minus electrode 318k. Has a structure. That is, (a part of) the piezoelectric active layer 18e is interposed between the unit electrode of the reflected wave signal plus electrode 318h and the unit electrode of the reflected wave signal minus electrode 318k which are adjacent to each other.
Here, in the piezoelectric active layer 18e, the polarization direction of the crystal dipole is set in the front-rear direction according to the direction of the applied voltage. Specifically, as shown in FIG. 10, a part of the piezoelectric active layer 18e sandwiched between the unit electrode of the reflected wave signal plus electrode 318h and the unit electrode of the reflected wave signal minus electrode 318k is adjacent to each other. The + and − directions are in different polarization states.
In such a piezoelectric element 318, the thickness of the piezoelectric active layer 18e between the unit electrodes of the reflected wave signal electrode terminal group is reduced, and the reflected wave signal electrode terminal group is a piezoelectric element 18, 118, 218 having a non-stacked structure. As compared with the above, it is possible to generate a higher electric field in the reflected wave signal electrode terminal group with the third vibration signal having a lower signal amplitude. That is, a large amount of mechanical strain can be obtained with a vibration signal to a low piezoelectric element. As a result, the change in analog voltage induced in the reflected wave signal electrode terminal group due to the generated electric field also increases, so that the detection sensitivity of the reflected wave signal 40a can be improved.

  In the above embodiment, the piezoelectric active layer 18e of the piezoelectric element 18 is polarized in the front-rear direction, and the transmission direction (vibration direction) of the vibration signal is orthogonal to the drive signal plus electrode 18c and the drive signal minus electrode 18d. I did it. However, the present invention is not limited to this. For example, as shown in FIG. 11, in the piezoelectric element 418 according to the modification of the present embodiment, the drive signal plus electrode 48c and the drive signal minus electrode 48d are the crystal bipolar layers of the piezoelectric active layer 48e. It is also possible to arrange it so as to be substantially parallel to the polarization direction of the child. According to this, the vibration direction of the lens moving signal 30 is substantially orthogonal to the direction of the electric field formed between the electrodes in the piezoelectric element 18 in order to cause the vibration. The expansion / contraction motion of the piezoelectric active layer 48e generated by the electric field is pushed back to the front side by the support base 15s. That is, although the generation efficiency of vibration is reduced, the electrodes 48c and 48d are perpendicular to the transmission direction (vibration direction) of the vibration signal, so that separation occurs between the electrodes 48c and 48d and the piezoelectric active layer 48e. Can be difficult.

  In the above embodiment, the focus position (JP) of the lens 14 is determined using the separation distance between the subject measured by the distance meter 27 and the camera device 10 (mobile phone 100), and the piezoelectric element 18 is used. The current position of the lens 14 (lens position L) was determined, and autofocus control was performed to move the lens to JP. In this control, since the current position of the lens 14 is not detected after the lens movement signal 30 is transmitted from the piezoelectric element 18, the position of the lens 14 fluctuates after the lens movement signal 30 is transmitted. In this case, accurate autofocus control is not performed. However, the present invention is not limited to this. For example, even after the lens movement signal 30 is transmitted from the piezoelectric element 18, the current position of the lens 14 is further detected using the piezoelectric element 18, and the position of the lens 14 is determined based on the distance between the two. It is also possible to perform control. According to this, since the position of the lens 14 is once fed back to the optical system controller 20, more accurate autofocus control can be performed.

  In the above embodiment, the lens movement signal 30 and the lens position detection signal 40 are transmitted from the piezoelectric element 18 and are used for the movement of the lens 14 and the position detection of the lens 14, respectively. However, the present invention is not limited to this, and as shown in FIG. 5B, in addition to these signals, a backlash correction signal 50 for correcting backlash of the lens 14 can be transmitted from the piezoelectric element 18. The backlash correction signal 50 preferably has an amplitude smaller than that of the lens movement signal 30 so that the lens 14 does not move by mistake. Further, the timing at which the backlash correction signal 50 is transmitted from the piezoelectric element 18 can be arbitrarily set as long as it does not overlap with the transmission timing of the lens movement signal 30 and the lens position detection signal 40. For example, a rattling detection operation of the lens 14 based on a digital signal from the AF driver 12 → a rattling correction operation of the lens 14 by transmitting a rattling correction signal 50 to the guide shaft 17 a → a normal lens moving operation → a lens position detection process (JP )) → Rack detection operation → Backlash correction operation sequence can be set. In this case, immediately after the backlash correction operation is performed, a backlash detection operation for checking the result of the correction operation can be performed.

  In the above-described embodiment, an operation flow (see FIG. 6) that can flexibly cope with the case where the lens 14 is moved to an arbitrary position due to vibration or the like due to the handling of the mobile phone 100 by the user is employed. However, the present invention is not limited to this, and as shown in FIG. 13, it is also possible to add the following steps S104a and S108a to the flowchart shown in FIG. According to this, depending on the handling of the mobile phone 100 by the user, an effective operation flow can be realized when the lens 14 does not move.

  In the flowchart shown in FIG. 13, in step S <b> 103 a subsequent to step S <b> 103, the optical system control unit 20 determines whether or not the previous lens position information is stored in the RAM 21. That is, it is determined whether or not the lens position information as a result of the previous autofocus control exists in the RAM 21 (step S103a).

  If the optical system control unit 20 determines that the previous lens position information is not stored in the RAM 21 (step S103a: NO), the optical system control unit 20 performs the processes of steps S104 to S106. On the other hand, when it is determined that the previous lens position information is stored in the RAM 21 (step S103a: YES), the processing of steps S104 to S106 is skipped and the processing of steps S107 and S107a is performed.

  In step S107a, the optical system control unit 20 stores the current lens position in the RAM 21 in preparation for the next autofocus control (step S107a) and once ends the autofocus control process here (step S108).

DESCRIPTION OF SYMBOLS 10 Camera apparatus 14 Lens 14a Lens mount 17a Guide shaft (guide member)
17b Support shaft 18 Piezoelectric element (actuator element)
19 Optical axis 20 Optical system control unit (control unit)
30 Lens movement signal (first electrical signal)
40 Lens position detection signal (second electrical signal)
100 mobile phone

Claims (10)

An optical structure that realizes a focus function or a zooming function by moving a lens in the optical axis direction,
A frictional engagement with a lens mount that supports the lens, and a guide member for moving the lens mount in the optical axis direction;
An actuator element that converts an electric signal input from the outside into a vibration signal, and converts a vibration signal received from the outside into an electric signal;
Control for inputting first and second electric signals to the actuator element, causing the actuator element to transmit first and second vibration signals, respectively, and receiving an electric signal based on an external vibration signal from the actuator element. And comprising
The actuator element transmits the first vibration signal to the guide member based on the first electric signal from the control unit, and moves the lens along the guide member in the optical axis direction together with the lens mount. And based on the second electric signal from the control unit, the second vibration signal is transmitted to the guide member,
The control unit includes: the second electric signal; and a third electric signal obtained by converting a reflected wave signal, which is a third vibration signal generated by reflecting the second vibration signal by the lens mount, to the actuator element . Based on the time difference , the position of the lens in the optical axis direction is detected, and the first electrical signal is input to the actuator element, and the lens is moved from the detected lens position to a target lens position. Let
In the actuator element, the vibration direction of the first vibration signal is substantially orthogonal to the direction of the electric field formed between the electrodes in the actuator element in order to cause the vibration.
The actuator element outputs a drive signal electrode terminal group used for inputting the first and second electrical signals corresponding to the first and second vibration signals, and a third electrical signal corresponding to the reflected wave signal. And a reflected wave signal electrode terminal group to be used,
The actuator element is a piezoelectric element made of at least one material selected from the group consisting of PZT ceramics, piezoelectric single crystals, and polymer resin / ceramic composite materials,
The drive signal electrode terminal group and the reflected wave signal electrode terminal group in the piezoelectric element are disposed in a direction substantially orthogonal to the polarization direction of the piezoelectric element.
An optical structure characterized by that. The actuator elements, optical structure of claim 1, said first oscillating signal, and transmits at different timings and the second oscillation signal. The actuator elements, optical structure according to claim 1 or 2, characterized in that said second oscillation signal, and transmits at a higher frequency than the first oscillation signal. The actuator elements, said second oscillation signal, an optical structure according to any one of claims 1 to 3, characterized in that sending a small vibration amplitude than the first oscillation signal. The actuator element outputs a drive signal electrode terminal group used for inputting the first and second electrical signals corresponding to the first and second vibration signals, and a third electrical signal corresponding to the reflected wave signal. Instead of the reflected wave signal electrode terminal group to be used, the drive signal electrode terminal group used for inputting the first and second electric signals corresponding to the first and second vibration signals, and the reflected wave signal optical according to any one of claims 1 to 4, characterized in that it comprises an electrode terminal group, which functions as both a reflected wave signal electrode terminals used for output of the third electrical signal corresponding to the Construction. The driving signal electrode terminal group, optical structure according to any one of claims 1 to 5, characterized in that it is configured to include an electrode group having a structure formed by laminating the positive electrode and the negative electrode alternately. The reflected wave signal electrode terminal group, optical structure according to any one of claims 1 to 6, characterized in that it is configured to include an electrode group having a structure formed by laminating the positive electrode and the negative electrode alternately . The actuator element is characterized in that a vibration direction of the first vibration signal is substantially parallel to a direction of an electric field formed between electrodes in the actuator element to cause the vibration. the optical structure according to any one of 1 to 7. A mobile terminal equipped with a camera device that realizes a focus function or a zooming function by moving a lens to a predetermined position,
The mobile device according to any one of claims 1 to 8 , wherein the camera device includes the optical structure according to any one of claims 1 to 8 to realize the focus function or the zooming function. A method used for an optical structure that realizes a focus function or a zooming function by moving a lens in an optical axis direction,
The optical structure is frictionally engaged with a lens mount that supports the lens, and a guide member for moving the lens mount in the optical axis direction;
An actuator element that converts an electric signal input from the outside into a vibration signal, and converts a vibration signal received from the outside into an electric signal;
Inputting first and second electric signals to the actuator element, transmitting the first and second vibration signals from the actuator element, respectively, and receiving an electric signal based on an external vibration signal from the actuator element; ,
The actuator element transmits the first vibration signal to the guide member based on the first electrical signal, moves the lens together with the lens mount along the guide member in the optical axis direction, and Transmitting the second vibration signal to the guide member based on two electrical signals;
Based on the time difference between the second electrical signal and the third electrical signal obtained by converting the reflected wave signal, which is a third vibration signal generated by the reflection of the second vibration signal by the lens mount, by the actuator element, Detecting the position of the lens in the optical axis direction, inputting the first electric signal to the actuator element, and moving the lens from the detected lens position to a target lens position; Prepared,
In the actuator element, the vibration direction of the first vibration signal is substantially orthogonal to the direction of the electric field formed between the electrodes in the actuator element in order to cause the vibration.
The actuator element outputs a drive signal electrode terminal group used for inputting the first and second electrical signals corresponding to the first and second vibration signals, and a third electrical signal corresponding to the reflected wave signal. And a reflected wave signal electrode terminal group to be used,
The actuator element is a piezoelectric element made of at least one material selected from the group consisting of PZT ceramics, piezoelectric single crystals, and polymer resin / ceramic composite materials,
The lens position detection method, wherein the drive signal electrode terminal group and the reflected wave signal electrode terminal group in the piezoelectric element are arranged in a direction substantially orthogonal to the polarization direction of the piezoelectric element.

Images