JP4403323B2 - POSITION DETECTION DEVICE, CAMERA DEVICE, AND LENS POSITION DETECTION METHOD - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
  The present invention relates to a position detection device, a camera device, and a lens position adjustment method for detecting the position of a movable lens such as a focus lens.
[0002]
[Prior art]
  In the video camera apparatus, an objective lens and an imaging element are disposed in a lens barrel, and a movable lens such as a zoom lens and a focus lens is disposed between the objective lens and the imaging element. The position detection of the movable lens is performed by a position detection sensor including a position detection element attached to a lens barrel serving as a fixed portion and a magnet attached to the movable lens side. The position detection element outputs a detection signal approximately approximated to a sine wave having a predetermined period. A position detection circuit that generates position information of the position detection sensor based on this detection signal, that is, position information of the movable lens, generates position information using the whole including the vicinity of the maximum value and the minimum value of the sine wave.
[0003]
[Problems to be solved by the invention]
  However, when the output level is in the vicinity of the maximum value and the minimum value, the change in the output level is small with respect to the change in the position of the movable lens. In addition, if there is variation such as distortion in the vicinity of the maximum value or the minimum value, accurate position information cannot be generated. Therefore, with such a position detection sensor, the position control of the movable lens cannot be performed accurately, and the movable lens cannot be accurately moved.
[0004]
  By the way, some video camera devices have been reduced in size to be portable. In this type of video camera device, the image pickup unit and the microphone are disposed at extremely close positions. For this reason, when the position detection sensor for detecting the position of the movable lens described above is used in a small video camera device, acoustic noise based on the fact that the movable lens does not move smoothly is collected by the microphone. Become. On the other hand, in a video camera device that is downsized, it is difficult to dispose the microphone and the imaging unit separately.
[0005]
  Accordingly, an object of the present invention is to provide a position detection device that can accurately detect the positions of the first and second magnetic heads.
[0006]
  It is another object of the present invention to provide a camera device including a lens position detection circuit that can accurately detect the position of a movable lens used in the camera device.
[0007]
  Furthermore, it aims at providing the lens position detection method which can detect the position of the movable lens used for a camera apparatus correctly.
[0008]
[Means for Solving the Problems]
  The position detection device according to the present invention is to solve the above-described problems.Magnets having magnetic signals recorded at a predetermined pitch, first and second magnetic heads arranged at predetermined intervals to detect magnetic signals recorded on the magnets, and the first and second magnets The first and second detection signals detected by the head are converted into first and second digital signals, and the first and second digital signals are converted at the intersection level of the first and second digital signals. , By switching to a digital signal having a larger output level change, and calculating the relative position of the first and second magnetic heads with respect to the magnet, and under the control of the position detection circuit, A voltage application circuit for applying a voltage to the first and second magnetic heads, and the position detection circuit outputs the first voltage and the second voltage to the first and second magnetic heads when power is turned on. To be applied to The voltage application circuit is controlled to capture at least one period of the first and second digital signals to obtain their maximum and minimum values, and from the maximum and minimum values, the voltage application circuit An increase rate between the applied voltage and the first and second detection signals of the first and second magnetic heads is obtained, and a predetermined required for the first and second detection signals is obtained based on the increase rate. Then, the voltage application circuit is controlled so that the predetermined voltage is applied.
[0009]
  In addition, the camera device according to the present invention is to solve the above-described problems.A movable lens disposed between a fixed lens and an imaging element disposed in the lens barrel and / or between the fixed lenses or a magnet on which the magnetic signal is recorded at a predetermined pitch; First and second magnetic heads which are attached to the lens barrel or the movable lens at a predetermined interval and detect magnetic signals recorded on the magnet, and first and second magnetic heads detected by the first and second magnetic heads. The first and second detection signals are converted into first and second digital signals, and the output level of the first and second digital signals changes at the intersection level of the first and second digital signals. Switching to the larger digital signal, calculating the relative position of the first and second magnetic heads with respect to the magnet, and detecting the position of the movable lens; and the position detection circuit And a voltage application circuit for applying a voltage to the first and second magnetic heads, and the position detection circuit outputs the first voltage and the second voltage when the power is turned on. The voltage application circuit is controlled so as to be applied to the second magnetic head, and at least one period of the first and second digital signals is taken to obtain the maximum value and the minimum value thereof, and the maximum value is obtained. An increase rate between the voltage applied by the voltage application circuit and the first and second detection signals of the first and second magnetic heads is obtained from the value and the minimum value, and based on the increase rate, the first The predetermined voltage required for the second detection signal is determined, and then the voltage application circuit is controlled so as to apply the predetermined voltage.
[0010]
  Furthermore, the lens position adjustment method according to the present invention is to solve the above-described problems.Magnetic signals are recorded at an interval of approximately 200 μm to approximately 320 μm, and the phase difference between the outputs of the movable lens or the magnet attached to the lens barrel provided with the movable lens is approximately 90 °. The first and second magnetic heads attached to the lens barrel or the movable lens are moved, and the first and second detection signals detected by the first and second magnetic heads are at least for one cycle. Converting and capturing the first and second digital signals; holding the maximum and minimum values of the first and second digital signals; and the maximum values of the first and second digital signals; Calculating the relative positions of the first and second magnetic heads with respect to the magnet based on the minimum value, and detecting the position of the movable lens. And the second electric Is applied to the first and second magnetic heads, and at least one period of the first and second digital signals is captured to determine their maximum and minimum values, and from the maximum and minimum values, The change rate of the first voltage and the second voltage and the increase rate of the change of the first and second detection signals are obtained, and the first and second detection signals are required based on the increase rate. A predetermined voltage is determined, and the predetermined voltage is applied to the first and second magnetic heads during actual use thereafter.
[0011]
DETAILED DESCRIPTION OF THE INVENTION
  A video camera device to which the present invention is applied will be described below with reference to the drawings.
[0012]
  This video camera device is downsized to a portable size and is formed in a substantially rectangular shape as a whole. An imaging unit 1 that captures an image of a subject is provided on the front surface of the video camera device. As shown in FIG. 1, the imaging unit 1 includes a plurality of fixed lenses and a movable lens arranged in a lens barrel 2 serving as a fixed unit with optical axes aligned. Specifically, an objective lens 3 that is a fixed lens and a fixed lens group 4 including a plurality of fixed lenses are disposed in the lens barrel 2, and a movable lens is provided between the objective lens 3 and the fixed lens group 4. A zoom lens 5 is disposed, and a focus lens 7 which is a movable lens is disposed between the fixed lens group 4 and the image sensor 6.
[0013]
  The objective lens 3, which is a fixed lens, is attached to the attachment plate 3 a, and the attachment plate 3 a is attached to the lens barrel 2 so as to face outward from the lens barrel 2. The fixed lens group 4 is also attached to the attachment plate 4a and attached to the barrel 2 by an attachment mechanism (not shown). The image sensor 6 is a charge coupled device (CCD), for example, and is fixedly attached to the attachment plate 6a.
[0014]
  The zoom lens 5 which is a movable lens is attached to the attachment plate 5a. A guide hole (not shown) is formed at one end of the mounting plate 5a, and a guide shaft 8 disposed substantially parallel to the optical axis in the lens barrel 2 is inserted into the guide hole. Further, a guide member 9 is attached to the other end side of the attachment plate 5a, and a guide shaft 11 disposed in the lens barrel 2 in parallel with the optical axis is inserted into the guide member 9. Moreover, the focus lens 7 which is a movable lens is attached to the attachment plate 7a. A guide hole (not shown) is formed at one end of the mounting plate 7a, and a guide shaft 8 is inserted into the guide hole. A guide member 12 is attached to the attachment plate 7a on the other end side. A guide shaft 11 is inserted through the guide member 12. That is, the zoom lens 5 and the focus lens 7 are supported in the lens barrel 2 by the guide shafts 8 and 11 parallel to the optical axis via the mounting plates 5a and 7a in the lens barrel 2, so It is attached to be movable.
[0015]
  The zoom lens 5 and the focus lens 7 are moved in the optical axis direction by the drive mechanisms 13 and 14 as shown in FIG. A drive mechanism 13 for moving the zoom lens 5 and a drive mechanism 14 for moving the focus lens 7 are disposed on the guide shaft 11 side, and both are made of a linear motor. Since the drive mechanism 13 and the drive mechanism 14 have the same configuration, the following description will be given with the same reference numerals.
[0016]
  The drive mechanisms 13, 14 include voice coils 15, 15 attached to the guide members 9, 12, and magnetic circuit parts 16, 16 composed of magnets and yokes attached to the lens barrel 2. When a drive signal is supplied to the voice coils 15 and 15, the drive mechanisms 13 and 14 generate a drive force (Lorentz force) in the optical axis direction, and move the zoom lens 5 and the focus lens 7 in the optical axis direction.
[0017]
  By the way, the currents flowing through the voice coils 15 and 15 constituting the drive mechanisms 13 and 14 are controlled based on the outputs of the position detection mechanisms 21 and 22 that detect the positions of the zoom lens 5 and the focus lens 7, respectively. That is, the video camera device to which the present invention is applied calculates the current position, moving speed, acceleration, and the like of the zoom lens 5 and the focus lens 7 based on the outputs of the position detection mechanisms 21 and 22, and feeds back these data. Servo control is performed to control the drive current. Since it is required to move the zoom lens 5 and the focus lens 7 to desired positions with high accuracy in as short a time as possible, the positions of the zoom lens 5 and the focus lens 7 are very important for detection. High accuracy is required.
[0018]
  Here, a specific configuration of these position detection mechanisms 21 and 22 will be described. The position detection mechanism 21 for the zoom lens and the position detection mechanism 22 for the focus lens have the same structure. Therefore, as shown in FIG. The lens 7 will be described simply as the movable lens 25.
[0019]
  As shown in FIGS. 2 and 3, the position detection mechanism 30 includes a magnet 31 connected to the movable lens 25 and a magnet 31.Tube2 is provided with sensors 32a and 32b. Then, the magnet 31 moves with the movement of the movable lens, whereby the magnet 31 and the sensors 32a and 32b move relatively.
[0020]
  As shown in FIG. 3, the magnet 31 is composed of a plurality of magnetic poles 31a each having a width of λ / 2, and the adjacent magnetic poles 31a are magnetized in opposite directions. Considering the fine adjustment required for the movable lens 25, λ is 200 μm to 320 μm, for example, 200 μm. Also,The entire length of the magnet 31 corresponds to the movable range of the movable lens 25, that is, the zoom lens 5 or the focus lens 7.
[0021]
  As shown in FIG. 3, the sensor 32a is composed of two magnetoresistive elements (hereinafter referred to as MR elements) 32a1 and 32a2 formed on a substrate 29, for example, as a thin film. Is connected to the power source Vcc, the other end is connected to the ground G, and the connection point of the two MR elements 32a1 and 32a2 is the output of the sensor 32a. Similarly, the sensor 32b includes two MR elements 32b1 and 32b2 connected in series, one end of which is connected to the power supply Vcc, the other end is connected to the ground G, and the connection point is the output of the sensor 32b. As shown in FIG. 4, when λ / 4 is 180 degrees, the MR elements 32a1 and 32b1 and the MR elements 32a2 and 32b2 are arranged apart from each other by an integral multiple of 180 degrees, that is, an integral multiple of λ / 4. In addition, the MR element 32a1 and the MR element 32b1 are disposed 90 degrees apart from each other by an integer multiple of λ / 8. Specifically, the interval between the MR element 32a1 and the MR element 32b1 is approximately 50 μm.
[0022]
  Further, as shown in FIG. 5, the position detection mechanism 30 includes a differential amplifier 33 for adding an offset voltage to the outputs of the sensors 32a and 32b (hereinafter simply referred to as the sensor 32), and the output of the differential amplifier 33 as position data. Convert to analog /DigitalBased on the position data from the converter (hereinafter referred to as A / D converter) 34 and the A / D converter 34, it flows to the voice coils 15, 15 constituting the drive mechanisms 13, 14.RuThe position calculation circuit 35 that controls the drive current and outputs control data for controlling the power supply voltage and the offset voltage of the sensor 32, and converts the control data from the position calculation circuit 35 into an analog voltage.Digital/ Analog converter (hereinafter referred to as D / A converter) 36.
[0023]
  When the magnet 31 is moved relative to the sensors 32a and 32b, the sensors 32a and 32b are substantially approximated to a sine wave having a phase shift of 90 degrees and a period of λ as shown in FIG. (Hereinafter referred to as A phase signal and B phase signal). These A-phase signal and B-phase signal are supplied to the differential amplifier 33 as shown in FIG.
[0024]
  The differential amplifier 33 subtracts an offset voltage described later from the A-phase signal and the B-phase signal, and supplies the subtraction result to the A / D converter 34. The A / D converter 34 converts the A-phase signal and the B-phase signal, to which the offset voltage has been added, into 8-bit data, for example, and supplies the data to the position calculation circuit 35.
[0025]
  The position calculation circuit 35 is composed of, for example, a microprocessor, and based on the data from the A / D converter 34, two-phase data is obtained at the intersection of them.switchingOn the other hand, for example, the position, moving direction, moving speed, and acceleration of the movable lens are calculated, and for example, zoom control data for moving the zoom lens 5 is generated so that the angle of view set by the operation of the user is generated. Then, focus control data for moving the focus lens 7 is generated so that the output of the focus sensor (not shown) is zero. That is, when the output level of the sensor is in the vicinity of the maximum value, the change in the output level of the sensor is small with respect to the change in the position of the movable lens. However, in this video camera device to which the present invention is applied, the two sensors 32a and 32b The output phase is set to 90 degrees, and the outputs of the sensors 32a and 32b are switched so that a signal having high sensitivity to the position can always be obtained at their intersection. Thereby, the movable lens 25 can be accurately moved to the target position.
[0026]
  In addition, the position calculation circuit 35 is described later in consideration of variations in mounting of the sensor 32 and / or the magnet 31 for each video camera device, temperature characteristics of the MR elements 32a1, 32a2, 32b1, 32b2, and / or the magnet 31 and secular changes. Gain control data and offset control data for controlling the gain and offset voltage of the sensor 32 are generated.
[0027]
  D / A converter 36Converts these control data into analog voltages, applies them to the sensors 32a and 32b, and supplies them to the differential amplifier 33. As the microprocessor, an A / D converter or a type incorporating a D / A converter may be used. In this case, an external A / D converter 34 and / or a D / A converter are used. 36 is not necessary.
[0028]
  Position as aboveCalculationSpecific operation of the circuit 35InThis will be described with reference to the flowchart shown in FIG.
[0029]
  For example, when the user turns on the power of the video camera device, in step S1, the position calculation circuit 35 causes the gain control data V so that the gain of the sensor 32 becomes a predetermined gain._gain1Offset control data V that does not apply an offset voltage such that the differential amplifier 33 outputs the output of the sensor 32 as it is._offset0Are supplied to the D / A converter 36. The D / A converter 36 receives the gain control data V_gain1, Offset control data V_offset0Are converted into analog voltages, respectively, and gain control data V_gain1Is supplied to the sensor 32 as a power supply voltage and the offset control data V_offset0Is supplied to the negative input terminal of the differential amplifier 33.
[0030]
  By the way, the output of the sensor 32 is the MR element 32a.₁~ 32b₂Is proportional to the voltage applied to. Therefore, the voltage applied to the sensor 32 immediately after the power is turned on is constant in any video camera device. However, as described above, the attachment of the sensor 32 and / or the magnet 31 is different for each video camera device. Therefore, the output of the sensor 32 for each video camera device, that is, the data input to the position calculation circuit 35 is different.
[0031]
  In step S2, the position calculation circuit 35 performs control to move the movable lens 25 so as to obtain at least 200 μm, that is, at least one period of A-phase signal and B-phase signal, for example, from the reference position. The maximum and minimum values of the sensor 32 output are set to MAX.₁, MIN₁Remember as.
[0032]
  In step S3, the position calculation circuit 35 receives the gain control data V_gain2And offset control data V_offset0Is supplied to the D / A converter 36.
[0033]
  In step S4, the position calculation circuit 35 performs control to move the movable lens 25 again so that an A-phase signal and a B-phase signal for at least one cycle are obtained, and the maximum value of the output of the sensor 32 obtained at this time. And the minimum value MAX₂, MIN₂Remember as.
[0034]
  In step S5, the position calculation circuit 35Is the gain V according to Equation 1 below._gainIs calculated and supplied to the D / A converter 36 as gain control data, and the offset voltage V_offsetIs calculated according to the following equation 2 and supplied to the negative input terminal of the differential amplifier 33 as offset control data.
[0035]
V_gain= {(V_top-V_bottom)-(MAX₁-MIN₁)}
÷ {(MAX₂-MIN₂)-(MAX₁-MIN₁)}
× (V_gain2-V_gain1) + V_gain1
... Formula 1
V_offset= (V_top+ V_bottom) / 2- (V_gain-V_gain1)
÷ (V_gain1-V_gain2) × {(MAX₁+ MIN₁) / 2
-(MAX₂+ MIN₂) / 2} + (MAX₁+ MIN₁) / 2
+ V_offset0
... Formula 2
Where V_top, V_bottomIs a predetermined voltage required for the sensor 32 output. That is, the position calculation circuit 35By the above-described operation, as shown in FIG._gain1To V_gain2The rate of increase of the output amplitude of the sensor 32 when it is changed to is obtained, and based on this rate of increase, the output amplitude of the sensor 32 is (V_top-V_bottom)gainV_gainAnd offsetVoltageV_offsetAsk for. Thus, even if there are variations in the attachment of the sensor 32 and / or the magnet 31 at the time of manufacture for each video camera device, all the video camera devices are turned on after the power is turned on and the above processing is performed. A substantially equal sensor output is obtained. In other words, mechanical adjustment of the attachment of the sensor 32 and the magnet 31 that has been conventionally required at the time of manufacture can be eliminated. In addition, sensor output fluctuations caused by, for example, temperature changes during the day and night, summer and winter, and changes in characteristics over time can be calibrated at all times.
[0036]
  Then, the position calculation circuit 35, as described above, moves and moves the movable lens 25 based on the A phase signal and the B phase signal that are the outputs of the sensor 32 calibrated as described above, that is, the sensors 32a and 32b. The direction, moving speed, and acceleration are detected, and control is performed to move the movable lens 25 to a desired position with high accuracy in as short a time as possible. Specifically, the position calculation circuit 35 uses the portion where the accuracy of the A-phase signal and the B-phase signal is high, that is, switches the signal used at the intersection of the A-phase signal and the B-phase signal to remove the portion where the slope is steep. The control is performed to move the movable lens to the target position accurately.
[0037]
  By the way, since the A / D converter 34 is used to capture the data of the A phase signal and the B phase signal into the position calculation circuit 35, the captured data is discrete, and the A / D converter Depending on the sampling frequency of 34, the intersection of the A-phase signal and the B-phase signal may not be detected accurately. Therefore, in the video camera device to which the present invention is applied, the number of samples held in the position calculation circuit 35 is set to at least one cycle of the A-phase signal and the B-phase signal, and the switching between the A-phase signal and the B-phase signal is performed as described above. As shown in FIG. 6, the switching level above the A phase, the switching level below the A phase, the switching level above the B phase obtained by interpolation, and the switching below the B phase obtained by interpolation. I try to do it at the level. In the video camera device to which the present invention is applied, for example, the magnet 31 is attached obliquely to the sensor 32, and the maximum value of the A-phase signal and the B-phase signal due to the difference in the relative position of the sensor 32 with respect to the magnet 31. In order to eliminate fluctuations in (amplitude), the A-phase signal and the B-phase signal are, for example,minimum valueas well asMaximum valueIs associated with 0 and 255, and is always normalized with 256 bits.
[0038]
  Here, a specific example of normalization and switching operations of the A-phase signal and the B-phase signal in the position calculation circuit 35 will be described with reference to the flowchart shown in FIG.
[0039]
  In step S11, the position calculation circuit 35 receives the data of the A phase signal and the B phase signal (hereinafter referred to as individual data) input from the sensor 32 via the differential amplifier 33 for offset adjustment and the A / D converter 34. The sample values are sequentially fetched for at least one period, and the respective sample values of the A-phase signal and the B-phase signal are obtained in the order in which they were taken (hereinafter referred to as the maximum value before the A phase, It is determined whether it is larger than the previous maximum value. If it is, the process proceeds to step S12. If not, the process proceeds to step S13.
[0040]
  In step S12, the position calculation circuit 35 holds the sample values of the A phase signal and the B phase signal that are larger than the previous maximum value of the A phase and the previous maximum value of the B phase, respectively, as new maximum values. move on.
[0041]
  In step S13, the position calculation circuit 35 determines whether the sample values of the A phase signal and the B phase signal are smaller than the previous minimum value of the A phase and the previous minimum value of the B phase, respectively. The process proceeds to step S14. If not applicable, the process proceeds to step S15.
[0042]
  In step S14, the position calculation circuit 35 holds the sample values of the A phase signal and the B phase signal, which are smaller than the previous minimum value of the A phase and the previous minimum value of the B phase, as new minimum values. move on.
[0043]
  In step S15, the position calculation circuit 35 normalizes each sample value of the A-phase signal and the B-phase signal with the maximum value and the minimum value obtained in steps S12 and S14, and proceeds to step S16. That is, in the position calculation circuit 35, for example, the magnet 31 and the sensor 32 are attached with a relative inclination by the processing of step S11 to step S15, and the output amplitude of the sensor 32 depends on the relative position of the sensor 32 with respect to the magnet 31. Even when fluctuates, it is possible to obtain an A-phase signal and a B-phase signal whose maximum and minimum values are always constant.
[0044]
  By the way, in the processing from step S11 to step S14, there is a possibility that noise larger than the maximum value is erroneously held. Therefore, the video camera device to which the present invention is applied has the following processing.
[0045]
  That is, in step S16, the position calculation circuit 35 determines whether the sample value of the A-phase signal is the center value of the amplitude of the A-phase signal. If applicable, the process proceeds to step S17. If not, the process proceeds to step S19. move on.
[0046]
  In step S17, the position calculation circuit 35 determines whether the sample value of the B phase signal corresponding to the sample value of the A phase signal, which is the center value of the amplitude, is larger than the center value of the amplitude of the B phase signal. If yes, go to Step S18, otherwise go to Step S19.
[0047]
  In step S18, the position calculation circuit 35 sets the current sample value of the B phase signal as the maximum value of the B phase signal, and proceeds to step S19.
[0048]
  In step S19, the position calculation circuit 35 determines whether the sample value of the B-phase signal is the center value of the amplitude of the B-phase signal. If applicable, the process proceeds to step S20. If not, the process proceeds to step S22.
[0049]
  In step S20, the position calculation circuit 35 determines whether the sample value of the A phase signal corresponding to the sample value of the B phase signal, which is the center value of the amplitude, is larger than the center value of the amplitude of the A phase signal. If yes, go to Step S21, otherwise go to Step S22.
[0050]
  In step S21, the position calculation circuit 35 sets the current sample value of the A phase signal as the maximum value of the A phase signal, and proceeds to step S22.
[0051]
  In step S22, each sample value of the A phase signal and the B phase signal is normalized by the maximum value and the minimum value obtained in step S18 and step 21, and the process proceeds to step S23. That is, since the phase of the A-phase signal and the B-phase signal differ by 90 degrees, when either one is the center value of the amplitude, the other is the maximum value or the minimum value. Therefore, even if the position calculation circuit 35 erroneously holds the noise as the maximum value of the A-phase signal or the B-phase signal in the processing of steps S11 to S15,S16-stepSBy the process of 21, the correct maximum value of each phase signal can be obtained.
[0052]
  By the way, as described above, the position calculation circuit 35 receives the A-phase signal and the B-phase signal as discrete sample values, and cannot accurately identify the intersection of the A-phase signal and the B-phase signal. Therefore, in the video camera to which the present invention is applied, switching between the A phase signal and the B phase signal is performed by the following processing.
[0053]
  In step S23, as shown in FIG. 10, the position calculation circuit 35 sequentially converts each sample value to a switching level crossA above the A phase that is a predetermined level.₁And the current sample value is the switching level crossA₁If it is true, the process proceeds to step S24. If not, the process proceeds to step S27.
[0054]
  In step S24, the position calculation circuit 35 determines whether the current sample value of the B-phase signal is larger than the center value of the amplitude of the B-phase signal. If applicable, the process proceeds to step S25. Proceed to step S26.
[0055]
  In step S25, the position calculation circuit 35 interpolates the previous sample value and the current sample value, for example, the switching level curB above the B phase according to Equation 3 below.₁Calculate the stepSProceed to 27.
[0056]
curB₁=
curB-{(crossA-curA) (curB-prevB)}
/ {(PrevA-curA)}
... Formula 3
  Here, crossA is the switching level of the A phase, and the switching level crossA above the A phase shown in FIG.₁Or lower switching level crossA₂, And prevA, prevB, curA, and curB are the previous sample value of the A phase, the previous sample value of the B phase, the current sample value of the A phase, and the current sample value of the B phase, as shown in FIG.
[0057]
  On the other hand, in step S26, the position calculation circuit 35 calculates the switching level curB below the B phase according to Equation 3.₂And the process proceeds to step S27.
[0058]
  In step S27, the position calculation circuit 35 sequentially converts each sample value to a switching level crossA below the A phase that is a predetermined level.₂And the current sample value is the switching level crossA₂The process proceeds to step S28 if applicable, and to step S31 if not applicable.
[0059]
  In step S28, the position calculation circuit 35 determines whether the current sample value of the B-phase signal is larger than the center value of the amplitude of the B-phase signal. If applicable, the process proceeds to step S29. Proceed to
[0060]
  In step S29, the position calculation circuit 35 calculates the switching level curB above the B phase according to Equation 3.₁Calculate the stepSProceed to 31.
[0061]
  On the other hand, in step S30, the position calculation circuit 35 calculates the switching level curB below the B phase according to Equation 3.₂And the process proceeds to step S31.
[0062]
  In step S31, the position calculation circuit 35 calculates each sample value of the A phase signal and the B phase signal as the A phase.as well asNormalize at the upper and lower switching levels of the B phase to obtain position data.
[0063]
  That is, in the video camera to which the present invention is applied, the normalization by the maximum value and the minimum value and the normalization by the upper and lower switching levels are performed twice, and the A phase and the B phase after the first normalization are performed. The level at the position at which the values are almost the same, that is, the voltage is held as the A-phase switching level, and the switching level of the A-phase is not updated during the normal operation after the initialization operation. The B-phase switching level is the level when the previous sample value obtained by the previous normalization of the A-phase during normal operation is compared with the current sample value and straddling the A-phase switching level. It is said.
[0064]
  Since the video camera apparatus performs switching between the A-phase signal and the B-phase signal as described above, the position of the movable lens 25 can be accurately detected. Therefore, the movable lens 25 can be smoothly moved by the drive mechanisms 13 and 14. Movable lens that can move25It is possible to prevent the generation of acoustic noise accompanying the deterioration of the positional accuracy. In particular, a video camera device that is downsized to a portable size and in which the positions of the drive mechanisms 13 and 14 and the microphone are arranged very close to each other is particularly effective because acoustic noise is not collected by the microphone. is there.
[0065]
  The video camera device to which the present invention is applied has been described with reference to the drawings. However, the present invention is not limited to this, and so-called a still image is captured.DigitalThe present invention can also be applied to a camera device. In the above-described example, the case where the sensor is attached to the lens barrel 2 and the magnet is attached to the movable lens has been described. Conversely, the sensor is attached to the movable lens and the magnet is attached to the lens barrel. At any rateGood.
[0066]
【The invention's effect】
  According to the present invention, the first and second detection signals detected by the first and second magnetic heads are converted into the first and second detection signals.DigitalConverted into a signal, the first and secondDigitalThe first and second at the intersection level of the signalDigitalOf the signals, the one whose output level change is largerDigitalSince the positions of the first and second magnetic heads are detected by switching to the signal, a signal with high sensitivity to the position can be obtained. Therefore, the position of the magnetic head can be accurately detected, and for example, the position of a movable lens such as a camera device can be accurately detected.
In addition, even if there are variations in the mounting of magnetic heads and / or magnets at the time of manufacturing for each camera device, after the power is turned on and the above processing is performed, all the camera devices have substantially the same sensor. Output is obtained. In other words, it is possible to eliminate the need for mechanical adjustment of the mounting of the magnetic head and the magnet, which has been conventionally required at the time of manufacture. In addition, fluctuations in the output of the magnetic head due to, for example, temperature changes during the day and night, summer and winter, and changes in characteristics over time can be calibrated at all times during use.
[Brief description of the drawings]
FIG. 1 is a cross-sectional view of a lens barrel of a video camera device to which the present invention is applied.
FIG. 2 is a side view of an essential part of a driving mechanism for a movable lens.
FIG. 3 is a perspective view of a position detection mechanism that detects the position of a movable lens.
FIG. 4 is a side view showing a relationship between a sensor and a magnet constituting the position detection mechanism.
FIG. 5 is a block diagram showing a control system of a position detection mechanism.
FIG. 6 is a diagram showing output characteristics of a two-phase sensor.
FIG. 7 is a flowchart showing a procedure for adjusting a gain / offset.
FIG. 8 is a diagram showing a sensor gain and a sensor output level.
FIG. 9 is a flowchart showing a switching procedure of two-phase sensors.
FIG. 10 is a diagram for explaining a calculation example of a B-phase switching voltage.
[Explanation of symbols]
DESCRIPTION OF SYMBOLS 1 Image pick-up part, 2 lens barrel, 3 objective lens, 4 fixed lens group, 5 zoom lens, 6 image pick-up element, 7 focus lens, 13, 14 drive mechanism (linear motor), 21, 22 position detection mechanism, 31 magnet, 32a 32b MR sensor, 34 A / D converter, 35 position calculation circuit, 36 D / A converter

Claims (10)

A magnet in which magnetic signals are recorded at a predetermined pitch;
First and second magnetic heads disposed at a predetermined interval and detecting magnetic signals recorded on the magnet;
Converting the first and second detection signals detected by the first and second magnetic heads to the first and second digital signals, said first at the intersection level of the first and second digital signal and of the second digital signal, a position detecting circuit is switched to a digital signal having a larger change in the output level, to calculate a relative position with respect to the magnet of the first and second magnetic heads,
A voltage application circuit for applying a voltage to the first and second magnetic heads under the control of the position detection circuit ;
The position detection circuit controls the voltage application circuit so as to apply the first voltage and the second voltage to the first and second magnetic heads when the power is turned on. At least one period of the digital signal is captured, and the maximum value and the minimum value thereof are obtained. From the maximum value and the minimum value, the voltage applied by the voltage application circuit and the first of the first and second magnetic heads. And determining a predetermined voltage required for the first and second detection signals based on the increase rate, and then applying the predetermined voltage. A position detection device for controlling the voltage application circuit . The switching of the first digital signal and said second digital signal, the position detecting device of the first and second resultant claim 1 wherein done Ru by switching level interpolation of the digital signal. The predetermined pitch of the magnetic signal recorded on the magnet is about 200 μm to about 320 μm, and the first and second magnetic heads generate a sine wave and shift the phase of the sine wave by about 90 °. position detecting device according to claim 1, wherein that are arranged in relation. A movable lens disposed between a fixed lens and an imaging element disposed in the lens barrel and / or between the fixed lenses or a magnet on which the magnetic signal is recorded at a predetermined pitch;
First and second magnetic heads attached to the lens barrel or the movable lens at a predetermined interval and detecting magnetic signals recorded on the magnet;
Converting the first and second detection signals detected by the first and second magnetic heads to the first and second digital signals, said first at the intersection level of the first and second digital signal and of the second digital signal, is switched to the digital signal towards a change in the output level is high, and calculate the relative position with respect to the magnet of the first and second magnetic heads, the position of the movable lens A lens position detection circuit to detect ;
A voltage application circuit for applying a voltage to the first and second magnetic heads under the control of the position detection circuit;
The position detection circuit controls the voltage application circuit so as to apply the first voltage and the second voltage to the first and second magnetic heads when the power is turned on. At least one period of the digital signal is captured, and the maximum value and the minimum value thereof are obtained. From the maximum value and the minimum value, the voltage applied by the voltage application circuit and the first of the first and second magnetic heads. And determining a predetermined voltage required for the first and second detection signals based on the increase rate, and then applying the predetermined voltage. A camera device for controlling the voltage application circuit . Predetermined pitch of recorded magnetic signal to the magnet is in the substantially 200μm~ approximately 320 .mu.m, the first and second magnetic head generates a sine wave, shifted approximately 90 ° to the sine wave phase position the camera apparatus according to claim 4, wherein that are arranged in relation. The lens position detecting circuit holds the maximum value and the minimum value of the first and second digital signals, based on these maximum and minimum values, the intersection point level of the first and second digital signal calculating camera apparatus according to claim 5, wherein you. The lens position detecting circuit, the first and second digital signals normalized by the maximum value and the minimum value, based on the normalized first and second digital signals, said first and second The camera apparatus according to claim 6, wherein the intersection level of the digital signal is calculated. Magnetic signals are recorded at intervals of approximately 200μm~ approximately 320 .mu.m, the movable lens or magnet the movable lens is attached to the barrel which is disposed, so that the phase difference of each output is approximately 90 ° and moving the first and second magnetic heads attached to the barrel or the movable lens, the first and second detection signals detected by said first and second magnetic head at least one period Converting and capturing the first and second digital signals;
Holding the maximum and minimum values of the first and second digital signals;
Based on the maximum and minimum values of the first and second digital signals, calculates the relative position of the first and second magnetic heads relative to the magnet, and detecting the position of the movable lens With
Further, when the power is turned on, the first voltage and the second voltage are applied to the first and second magnetic heads, and at least one period of the first and second digital signals is taken in. A value and a minimum value are obtained, and an increase rate of the change in the first voltage and the second voltage and the change in the first and second detection signals is obtained from the maximum value and the minimum value, and based on the increase rate Then, a predetermined voltage required for the first and second detection signals is determined, and in the subsequent actual use, the predetermined voltage is applied to the first and second magnetic heads. Method. A step of calculating, based the intersection level of the first and second digital signal to the maximum and minimum values of said first and second digital signals,
Of the first and second digital signal at the intersection level of the first and second digital signals, further comprising claim 8, wherein the lens position detection and a step of switching to a digital signal towards a change in the output level is high Method. 10. The lens position detection method according to claim 9, wherein when one of the first and second digital signals has a center value of amplitude, it is determined that the other digital signal has a maximum value or a minimum value. .

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