This application claims priority pursuant to 35 U.S.C. § 119(a) to Japanese Patent Application No. 2016-144155 filed on Jul. 22, 2016 in the Japan Patent Office, the disclosure of which is incorporated by reference herein in its entirety.
This disclosure relates to a position detection system, a position detection method, an image generation unit, and an image projection apparatus.
A method of detecting a position of a movable member by using a magnetic field generating member such as a Hall element known as a Hall sensor is available.
When the position is detected by using a position detection system, at first, it is determined whether a swing angle around the x-axis of a movable member is near the center of the movement. If it is determined that the swing angle is near the center of the movement, an output of a sensor is input to an analog-digital converter via an amplifier, with which a control in the vicinity of the center of the movement can be performed with higher accuracy.
However, when the position is detected by using conventional position detection systems, a range that can detect the position with higher accuracy and higher resolution may be limited to the vicinity of the center of the movement.
In one aspect of the present invention, a position detection system for detecting a position of a movable member is devised. The position detection system includes a magnetic field generation unit to generate a magnetic field, a magnetic field detection unit to detect a magnetic flux density of the magnetic field effecting the magnetic field detection unit from the magnetic field generation unit, the magnetic flux density of the magnetic field effecting the magnetic field detection unit changeable depending on a change of a position of the magnetic field detection unit relative to a position of the magnetic field generation unit, and to output a detection voltage corresponding to the magnetic flux density of the magnetic field detected by the magnetic field detection unit, the magnetic field detection unit disposed on the movable member, and circuitry. The circuitry amplifies the detection voltage, sets a reference voltage to be used as a reference for amplifying the detection voltage, and an amplification level of the detection voltage based on at least one of a voltage input to the magnetic field detection unit and a gain value set for the amplification of the detection voltage or both of the voltage input to the magnetic field detection unit and the gain value set for the amplification of the detection voltage, and changes the reference voltage to switch a region used for detecting the position of the movable member.
In another aspect of the present invention, a method of detecting a position of a movable member by using a magnetic field generation unit to generate a magnetic field, a magnetic field detection unit disposed on the movable member, is devised. The method includes detecting a magnetic flux density of the magnetic field effecting the magnetic field detection unit from the magnetic field generation unit, outputting a detection voltage corresponding to the magnetic flux density of the magnetic field detected by the magnetic field detection unit, the magnetic flux density of the magnetic field effecting the magnetic field detection unit changeable depending on a change of a position of the magnetic field detection unit relative to a position of the magnetic field generation unit, amplifying the detection voltage, setting a reference voltage to be used as a reference for amplifying the detection voltage, setting an amplification level of the detection voltage based on at least one of a voltage input to the magnetic field detection unit and a gain value set for the amplification of the detection voltage or both of the voltage input to the magnetic field detection unit and the gain value set for the amplification of the detection voltage, and changing the reference voltage to switch a region used for detecting the position of the movable member.
A more complete appreciation of the description and many of the attendant advantages and features thereof can be readily obtained and understood from the following detailed description with reference to the accompanying drawings, wherein:
The accompanying drawings are intended to depict exemplary embodiments of the present invention and should not be interpreted to limit the scope thereof. The accompanying drawings are not to be considered as drawn to scale unless explicitly noted, and identical or similar reference numerals designate identical or similar components throughout the several views.
A description is now given of exemplary embodiments of present disclosure. It should be noted that although such terms as first, second, etc. may be used herein to describe various elements, components, regions, layers and/or sections, it should be understood that such elements, components, regions, layers and/or sections are not limited thereby because such terms are relative, that is, used only to distinguish one element, component, region, layer or section from another region, layer or section. Thus, for example, a first element, component, region, layer or section discussed below could be termed a second element, component, region, layer or section without departing from the teachings of present disclosure.
In addition, it should be noted that the terminology used herein is for the purpose of describing particular embodiments only and is not intended to be limiting of present disclosure. Thus, for example, as used herein, the singular forms “a”, “an” and “the” are intended to include the plural forms as well, unless the context clearly indicates otherwise. Moreover, the terms “includes” and/or “including”, when used in this specification, specify the presence of stated features, integers, steps, operations, elements, and/or components, but do not preclude the presence or addition of one or more other features, integers, steps, operations, elements, components, and/or groups thereof. Furthermore, although in describing views illustrated in the drawings, specific terminology is employed for the sake of clarity, the present disclosure is not limited to the specific terminology so selected and it is to be understood that each specific element includes all technical equivalents that operate in a similar manner and achieve a similar result. Referring now to the drawings, one or more apparatuses or systems according to one or more embodiments are described hereinafter.
Hereinafter, a description is given of one or more embodiments of the present disclosure with reference to drawings. In this disclosure, components having the same or similar functional configuration among the embodiments of the present disclosure are assigned with the same references, and described by omitting the descriptions if redundant.
As disclosed in the following disclosure, a position detection system of the present disclosure can be applied to an image projection apparatus. Hereinafter, a description is given of the position detection system of the present disclosure applied to the image projection apparatus. It should be noted that the position detection system of the present disclosure can be applied to other apparatuses.
(Image Projection Apparatus)
In this disclosure, the projector 1 is used an example of image projection apparatuses. As illustrated in
In the following drawings, an X1-X2 direction indicates a width direction of the projector 1, a Y1-Y2 direction indicates a depth direction of the projector 1, and a Z1-Z2 direction indicates a height direction of the projector 1. Further, a side where the emission window 3 of the projector 1 is provided may be described as a upper side of the projector 1, and a side opposite to the emission window 3 may be described as a lower side of the projector 1 in the Z1-Z2 direction.
As illustrated in
The power supply 4 is connected to a commercial power supply, converts a voltage and a frequency of the commercial power supply to a voltage and a frequency for an internal circuit of the projector 1, and supplies power to the system control unit 10, the optical engine 15, the fan 20, and so on.
The main switch SW5 is used by a user to perform an ON/OFF operation of the projector 1. When the main switch SW5 is turned on when the power supply 4 is connected to the commercial power supply through a power cord, the power supply 4 starts to supply power to each of the units of the projector 1, and when the main switch SW5 is turned off, the power supply 4 stops the supply of power to each of the units of the projector 1.
The operating unit 7 includes a button and the like that receives various operations performed by a user, and is disposed on, for example, the top face of the projector 1. The operating unit 7 receives user operations such as a size, a color tone, and a focus adjustment of a projection image. The user operation received by the operating unit 7 is transmitted to the system control unit 10.
The external I/F 9 has a connection terminal connectable to a device such as a personal computer or a digital camera, and outputs image data transmitted from the connected device to the system control unit 10.
The image control unit 11 controls a digital micromirror device (DMD) 551 disposed in an image generation unit 50 of the optical engine 15 based on image data input via the external I/F 9 to generate an image to be projected to the screen S.
The movement control unit 12 controls a drive unit that moves a movable unit 55, movably disposed in the image generation unit 50, to control the position of the DMD 551 disposed in the movable unit 55. The drive unit will be described later in this disclosure.
The fan 20 is rotated under a control of the system control unit 10 to cool the light source 30 of the optical engine 15.
As illustrated in
The light source 30 is, for example, a high-pressure mercury lamp, a Xenon lamp, and a light-emitting diode (LED), and is controlled by the system control unit 10 to emit the light to the DMD 551 disposed in the image generation unit 50 via the light guide unit 40.
The light guide unit 40 includes, for example, a color wheel, a light tunnel, a relay lens and the like, and guides the light emitted from the light source 30 to the DMD 551 disposed in the image generation unit 50.
The image generation unit 50 includes, for example, a fixed unit 51 fixedly supported in the projector 1, and a movable unit 55 movably supported by the fixed unit 51. The movable unit 55 includes, for example, the DMD 551, and a position of the movable unit 55 with respect to the fixed unit 51 is controlled by the movement control unit 12 of the system control unit 10. The DMD 551 is an example of an image generation element or image generator, and the DMD 551 is controlled by the image control unit 11 of the system control unit 10, and the DMD 551 modulates the light emitted from the light source 30 and guided to the DMD 551 via the light guide unit 40 to generate a projection image. In this description, the fixed unit 51 may be also referred to as the non-movable unit or the first unit, and the movable unit 55 may be also referred to as the second unit.
The projection unit 60 includes, for example, a plurality of projection lenses, mirrors and the like, and enlarges an image generated by the DMD 551 of the image generation unit 50 to project an image to the screen S. The projection unit 60 is an example of a projection device.
(Configuration of Optical Engine)
A description is given of a configuration of each of units of the optical engine 15 in the projector 1.
The light source 30 is disposed at one side of the light guide unit 40, and emits light in the X2 direction. The light guide unit 40 guides the light emitted from the light source 30 to the image generation unit 50 disposed under the light guide unit 40. The image generation unit 50 uses the light emitted from the light source 30 and guided by the light guide unit 40 to generate a projection image. The projection unit 60 is disposed above the light guide unit 40, and projects the projection image generated by the image generation unit 50 to the outside of the projector 1.
The optical engine 15 of the embodiment is configured to project the image to a upward direction using the light emitted from the light source 30, but not limited thereto. For example, the optical engine 15 can be configured to project the image to a horizontal direction.
(Light Guide Unit)
As illustrated in
The color wheel 401 is, for example, a disk having filters of R (Red) color, G (Green) color, and B (Blue) color arranged in different portions in the disk such as different portions in a circumferential direction of the disk. The color wheel 401 is configured to rotate with a high speed to divide the light emitted from the light source 30 into the RGB colors with a time division manner.
For example, the light tunnel 402 is formed into a rectangular tube shape by attaching plate glasses. The light tunnel 402 reflects each of R, G, and B color light, coming from the color wheel 401, for a multiple times in the light tunnel 402 to homogenize luminance distribution of the light, and guides the light to the relay lenses 403 and 404.
The relay lenses 403 and 404 condense the light while correcting the axial chromatic aberration of the light exiting from the light tunnel 402.
The flat mirror 405 and the concave mirror 406 reflects the light exiting from the relay lenses 403 and 404 to the DMD 551 disposed in the image generation unit 50. The DMD 551 modulates the light reflected from the concave mirror 406 to generate a projection image.
(Projection Unit)
As illustrated in
The projection lens 601 includes, for example, a plurality of lenses, and forms a projection image generated by the DMD 551 of the image generation unit 50 on the reflection mirror 602. The reflection mirror 602 and the curved mirror 603 reflect the formed projection image by enlarging the projection image, and projects the enlarged projection image to the screen S or the like disposed outside the projector 1.
(Image Generation Unit)
As illustrated in
The fixed unit 51 includes a top plate 511 as a first fixed plate, and a base plate 512 as a second fixed plate. In the fixed unit 51, the top plate 511 and the base plate 512 are provided in parallel with each other with a given space therebetween. The fixed unit 51 is fixed to a bottom side of the light guide unit 40 by using four screws 520 illustrated in
The movable unit 55 includes the DMD 551, a movable plate 552 as a first movable plate, a DMD substrate 553 as a second movable plate, and a heat sink 554 as a heat radiating unit, and the movable unit 55 is movably supported by the fixed unit 51.
The DMD 551 is disposed on a upper face of the DMD substrate 553. The DMD 551 includes an image generation plane where a plurality of movable micromirrors are arranged in a lattice pattern. As to each of the micromirrors of the DMD 551, the mirror surface of each of the micromirrors of the DMD 551 is mounted tiltably about a torsion axis, and each of the micromirrors of the DMD 551 is ON/OFF driven based on an image signal transmitted from the image control unit 11 of the system control unit 10.
For example, in the case of “ON,” an inclination angle of the micromirror is controlled so as to reflect the light emitted from the light source 30 to the projection unit 60. Further, for example, in the case of “OFF,” an inclination angle of the micromirror is controlled in a direction for reflecting the light emitted from the light source 30 toward the OFF plate.
With this configuration, in the DMD 551, the inclination angle of each of the micromirrors is controlled by the image signal transmitted from the image control unit 11, and the DMD 551 modulates the light emitted from the light source 30 and guided by the light guide unit 40 to generate a projection image.
The movable plate 552 is supported in a space between the top plate 511 and the base plate 512 of the fixed unit 51, in which the movable plate 552 is movable in a direction parallel to the surfaces of the top plate 511 and the base plate 512.
The DMD substrate 553 is provided between the top plate 511 and the base plate 512 of the fixed unit 51, and is fixed to a lower face of the movable plate 552. The DMD 551 is disposed on the upper face of the DMD substrate 553, and thereby the DMD 551 is movable with the movable plate 552 that is disposed movably as described above.
The heat sink 554 radiates heat generated by the DMD 551, in which at least a part of the heat sink 554 is in contact with the DMD 551, which enables the DMD 551 to be efficiently cooled. The heat sink 554 suppresses an increase of the temperature of the DMD 551 so that occurrence of troubles such as a malfunction or a failure due to the increase of the temperature of the DMD 551 can be reduced. The heat sink 554 is provided movably together with the movable plate 552 and the DMD substrate 553. With this configuration, the heat generated by the DMD 551 can be radiated constantly.
(Fixed Unit)
As illustrated in
Each of the top plate 511 and the base plate 512 is formed from a plate member such as a flat plate formed of magnetic material such as iron or stainless steel. The top plate 511 and the base plate 512 are provided in parallel with each other by a plurality of supports 515 with a given space therebetween.
The top plate 511 has a central hole 514 provided at a position corresponding to the DMD 551 of the movable unit 55. Further, the base plate 512 has a heat transfer hole 519 formed at a position corresponding to the DMD 551, and a heat transfer unit 563 of the heat sink 554 (
As illustrated in
As illustrated in
Further, a plurality of supporting holes 526 is formed in the top plate 511. Each of the supporting holes 526 rotatably holds a supporting sphere 521 that movably supports the movable plate 552 from the upper side of the movable plate 552. Further, a plurality of supporting holes 522 is formed in the base plate 512. Each of the supporting holes 522 rotatably holds a supporting sphere 521 that movably supports the movable plate 552 from the lower side of the movable plate 552.
The upper end of the supporting hole 526 of top plate 511 is covered by a lid member 527, and the supporting hole 526 rotatably holds the supporting sphere 521. Further, a cylindrical holding member 523 having a female screw groove in its inner periphery is inserted into the supporting hole 522 of the base plate 512. The lower end of the cylindrical holding member 523 is covered by a position adjustment screw 524, and the cylindrical holding member 523 rotatably holds the supporting sphere 521.
The supporting spheres 521 rotatably held by the supporting holes 526 and 522 respectively formed in the top plate 511 and the base plate 512 are in contact with the movable plate 552 provided between the top plate 511 and the base plate 512 to movably support the movable plate 552 from the both faces of the movable plate 552.
As illustrated in
Each of the supporting spheres 521 is held such that at least a part of the supporting sphere 521 protrudes from the supporting holes 522 and 526, and are in contact with the movable plate 552 provided between the top plate 511 and the base plate 512. The movable plate 552 is supported b the rotatably provided supporting spheres 521 from both sides of the movable plate 552 so as to be supported in parallel to the top plate 511 and the base plate 512 and movably in a direction parallel to the surfaces of the top plate 511 and the base plate 512.
Further, as to the supporting sphere 521 disposed on the base plate 512, an amount of protrusion of the supporting sphere 521 from the upper end of the cylindrical holding member 523 can be changed by adjusting the position of the position adjustment screw 524. For example, when the position adjustment screw 524 is displaced in the Z1 direction, the amount of protrusion of the supporting sphere 521 increases so that an interval between the base plate 512 and the movable plate 552 is increased. Further, for example, when the position adjustment screw 524 is displaced in the Z2 direction, the amount of protrusion of the supporting sphere 521 decreases so that the interval between the base plate 512 and the movable plate 552 is reduced.
With this configuration, by changing the amount of protrusion of the supporting sphere 521 using the position adjustment screw 524, the interval between the base plate 512 and the movable plate 552 can be appropriately adjusted.
Further, as illustrated in
The position-detection magnet 541 and the Hall element 542 (
Further, as illustrated in
Each of the drive-use magnet units 531 includes two permanent magnets having rectangular parallelepiped shape and arranged in parallel along a long side of the two permanent magnets, and the two permanent magnets form a magnetic field effecting the heat sink 554. A combination of the drive-use magnet unit 531 and a drive coil 581 disposed on the upper face of the heat sink 554 configure a drive unit that moves the movable unit 55.
Further, the number and position of the supports 515 and the supporting spheres 521 provided in the fixed unit 51 are not limited to the configuration illustrated in the embodiment.
(Movable Unit)
As illustrated in
As described above, the movable plate 552 is provided between the top plate 511 and the base plate 512 of the fixed unit 51, and is supported movably in a direction parallel to the surfaces of the top plate 511 and the base plate 512 by the supporting spheres 521.
As illustrated in
The movable plate 552 and the DMD substrate 553 are linked and fixed with each other by screws inserted into the link use holes 573 in a state that an interval between the movable plate 552 and the DMD substrate 553 is adjusted such that the surface of the movable plate 552 and the image generation plane of the DMD 551 are set in parallel with each other, in which the movable plate 552 and the DMD substrate 553 can be fixed firmly by using an adhesive.
In the above described configuration, the movable plate 552 moves in a direction parallel to the surface of the movable plate 552, and the DMD 551 also moves with the movable plate 552. Therefore, if the surface of the movable plate 552 and the image generation plane of the DMD 551 are not in parallel with each other, the image generation plane of the DMD 551 may be inclined with respect to a moving direction of the DMD 551, with which an image may be distorted (i.e., image quality deteriorates).
Therefore, in the embodiment, the interval between the movable plate 552 and the DMD substrate 553 is adjusted with the screws inserted the link-use holes 573, and the surface of the movable plate 552 and the image generation plane of the DMD 551 are maintained in parallel with each other, with which deterioration of the image quality can be suppressed.
The support 515 of the fixed unit 51 is inserted in the movable range restriction hole 571, and the movable range restriction hole 571 restricts a movable range of the movable plate 552 by contacting with the support 515 when the movable plate 552 is largely moved due to, for example, vibration or some abnormality.
Further, the number, position, and the shape of the link-use holes 573 and the movable range restriction hole 571 are not limited to the configuration illustrated in the embodiment. Further, the movable plate 552 and the DMD substrate 553 can be connected or linked with each other using a configuration different from the configuration of the embodiment.
The DMD substrate 553 is provided between the top plate 511 and the base plate 512 of the fixed unit 51, and is linked to the lower face of the movable plate 552 as described above.
The DMD 551 is disposed on the upper surface of the DMD substrate 553. The DMD 551 is connected to the DMD substrate 553 via a socket 557 and the periphery of the DMD 551 is covered by a cover 558. The DMD 551 is exposed through the central hole 570 of the top plate 511 to the upper face side of the movable plate 552.
As to the DMD substrate 553, through holes 555 are formed in the DMD substrate 553 through which the screws 520 for fixing the top plate 511 to the light guide unit 40 are inserted. Further, as to the DMD substrate 553, notches 588 are formed at portions facing the link members 561 such that the movable plate 552 is fixed to the link members 561 of the heat sink 554.
For example, if the movable plate 552 and the DMD substrate 553 are both fixed to the link member 561 of the heat sink 554, the DMD substrate 553 may be distorted, and the image generation plane of the DMD 551 may be inclined with respect to the moving direction, in which there is a possibility that an image may be distorted. In view of this issue, the notches 588 are formed at peripheral portions of the DMD substrate 553 so that the link members 561 of the heat sink 554 are linked to the movable plate 552 while avoiding the DMD substrate 553.
With this configuration, since the heat sink 554 is connected and linked to the movable plate 552, a possibility that the DMD substrate 553 receives a load from the heat sink 554 can be reduced, and thereby an image distortion can be reduced. Therefore, the image quality can be maintained by maintaining the image generation plane of the DMD 551 parallel to the moving direction.
Further, the notch 588 is formed for the DMD substrate 553 by setting a size of the notch 588 greater than an area around the supporting holes 522 of the base plate 512 so that the supporting sphere 521 held on the base plate 512 contacts the movable plate 552 while avoiding the DMD substrate 553. With this configuration, the DMD substrate 553 is prevented from being distorted due to the load from the supporting sphere 521, and the image generation plane of the DMD 551 can be moved in parallel to the moving direction, with which the image quality can be maintained.
Further, the shape of the notch 588 is not limited to the shape exemplified in the embodiment. For example, instead of the notch 588, a through hole can be formed in the DMD substrate 553 as long as the DMD substrate 553 is not contact with the link members 561 of the heat sink 554 and the supporting sphere 521.
Further, as illustrated in
As illustrated in
As illustrated in
The concave portion 582 is formed at a position facing the drive-use magnet unit 531 disposed on the lower face of the base plate 512. A combination of the drive coil 581 attached to the concave portion 582 of the heat dissipation unit 556 and the drive-use magnet unit 531 disposed on the lower face of the base plate 512 configure the drive unit used for moving the movable unit 55 with respect to the fixed unit 51.
Further, through holes 562 are formed in the heat dissipation unit 556, through which the screws 520 for fixing the top plate 511 to the light guide unit 40 are inserted.
The link members 561 are formed at three portions while extending in the Z1 direction from the upper face of the heat dissipation unit 556, and the movable plate 552 is fixed to the upper end of each of the link members 561 by screws 564 (see
As illustrated in
As illustrated in
In the above described configuration, there is a space between the surface of the DMD substrate 553 and the image generation plane of the DMD 551, in which the space corresponds to the thickness of the socket 557 and the thickness of the DMD 551. If the DMD substrate 553 is placed above the upper side of the top plate 511, the space from the surface of the DMD substrate 553 to the image generation plane of the DMD 551 becomes a dead space, with which the apparatus configuration may become larger.
In the embodiment, by providing the DMD substrate 553 between the top plate 511 and the base plate 512, the top plate 511 is placed in the space from the surface of the DMD substrate 553 to the image generation plane of the DMD 551. With this configuration, the height in the Z1-Z2 direction can be reduced by effectively utilizing the space from the surface of the DMD substrate 553 to the image generation plane of the DMD 551, with which the apparatus configuration can be reduced. Therefore, the image generation unit 50 of the embodiment can be assembled not only to larger projectors but also to smaller projectors, in which versatility of the image generation unit 50 is enhanced.
(Drive Unit)
In the embodiment, the drive unit includes, for example, the drive-use magnet unit 531 disposed on the base plate 512, and the drive coil 581 disposed on the heat sink 554.
Each of the drive-use magnet unit 531a and the drive-use magnet unit 531b is configured with two permanent magnets, and the longitudinal direction of the two permanent magnets are set parallel to the X1-X2 direction. Further, the drive-use magnet unit 531c is configured with two permanent magnets, and the longitudinal direction of the two permanent magnets are set parallel to the Y1-Y2 direction. Each of the drive-use magnet units 531 respectively forms a magnetic field effecting the heat sink 554.
Each of the drive coils 581 is formed by an electric wire being wound about an axis parallel to the Z1-Z2 direction, and attached in the concave portion 582 formed on the upper face of the heat dissipation unit 556 of the heat sink 554.
The drive-use magnet unit 531 on the base plate 512 and the drive coil 581 on the heat sink 554 are provided at positions so as to face each other in a state that the movable unit 55 is supported by the fixed unit 51. When a current is made to flow in the drive coil 581, a Lorentz force used as a drive force for moving the movable unit 55 is generated for the drive coil 581 by the magnetic field formed by the drive-use magnet unit 531.
When the movable unit 55 receives the Lorentz force generated as the drive force between the drive-use magnet unit 531 and the drive coil 581, the movable unit 55 is linearly or rotationally displaced on the X-Y plane with respect to the fixed unit 51.
In the embodiment, the drive coil 581a and the drive-use magnet unit 531a, and the drive coil 581b and the drive-use magnet unit 531b disposed at the opposite positions in the X1-X2 direction configure a first drive unit. When a current is made to flow in the drive coil 581a and the drive coil 581b, a Lorentz force in the Y1 direction or Y2 direction is generated.
The movable unit 55 is moved in the Y1 direction or the Y2 direction by the Lorentz forces generated by the drive coil 581a and the drive coil 581b. Further, the movable unit 55 is displaced to rotate on the X-Y plane by a Lorentz force generated by the drive coil 581a and a Lorentz force generated by the drive coil 581b, which are generated in the opposite directions.
For example, when a current is made to flow in the drive coil 581a to generate a Lorentz force in the Y1 direction, and a current is made to flow in the drive coil 581b to generate a Lorentz force in the Y2 direction, the movable unit 55 is displaced to rotate into a counterclockwise direction when viewed from the top. Further, when a current is made to flow in the drive coil 581a to generate a Lorentz force in the Y2 direction, and a current is made to flow in the drive coil 581b to generate a Lorentz force in the Y1 direction, the movable unit 55 is displaced to rotate into a clockwise direction when viewed from the top.
Further, in the embodiment, the drive coil 581c and the drive-use magnet unit 531c configure a second drive unit. The drive-use magnet unit 531c is arranged such that the longitudinal direction of the drive-use magnet unit 531c is orthogonal to the longitudinal direction of the drive-use magnet unit 531a and the drive-use magnet unit 531b. In this configuration, when a current is made to flow in the drive coil 581c, a Lorentz force in the X1 direction or X2 direction is generated, and then the movable unit 55 is moved in the X1 direction or the X2 direction by the Lorentz force generated by the drive coil 581c.
The magnitude and direction of the current to be made to flow in each of the drive coils 581 is controlled by the movement control unit 12 of the system control unit 10. The movement control unit 12 controls a movement direction (linear or rotation direction), a movement amount, and a rotation angle of the movable plate 552 by controlling the magnitude and direction of the current to be made to flow in each of the drive coils 581.
Further, a heat transfer hole 559 is formed in the base plate 512 at a portion facing the DMD 551 provided in the DMD substrate 553, and the heat transfer unit 563 of the heat sink 554 is inserted through the heat transfer hole 559. Further, through holes 560 are formed in the base plate 512, and the screws 520 for fixing the top plate 511 to the light guide unit 40 are inserted through the through holes 560.
As to the movable unit 55 of the embodiment, the weight of the heat sink 554 is set greater than the total weight of the movable plate 552 and the DMD substrate 553. Therefore, the center of gravity position of the movable unit 55 in the Z1-Z2 direction is located near the heat dissipation unit 556 of the heats sink 554.
In this configuration, for example, if the drive coil 581 is disposed on the movable plate 552, and a Lorentz force used as a drive force acts the movable plate 552, the center of gravity position of the movable unit 55 and the drive force generation plane locating the drive coil 581 is separated from each other in the Z1-Z2 direction. This situation similarly occurs when the drive coil 581 is provided in the DMD substrate 553.
In the configuration that the center of gravity position of the movable unit 55 and the drive force generation plane are separated, the center of gravity position is set as a support point in the Z1-Z2 direction, and the drive force generation plane is used as an action point in the Z1-Z2 direction, with which a swing like a pendulum may occur. Since a moment acting the drive force generation plane increases as the interval between the support point and the action point becomes longer, the greater the interval of the center of gravity position of the movable unit 55 and the drive force generation plane in the Z1-Z2 direction, the greater the vibration, and it becomes difficult to control the position of the DMD 551.
Further, if the movable unit 55 shakes like a pendulum, the load acting to the movable plate 552, and the top plate 511 and the base plate 512 supporting the movable plate 552 becomes greater, with which distortion and breakage may occur to each of the plates, and thereby an image may be distorted.
Therefore, in the embodiment, by providing the drive coil 581 in the concave portion 582 of the heat sink 554, as illustrated in
Therefore, as to the movable unit 55 of the embodiment, the moving direction of the movable unit 55 can be maintained in a direction parallel to the X-Y plane without swinging like a pendulum so that the above described problems such as distortion and breakage of each plate may not occur, and an operational stability of the movable unit 55 can be enhanced, and the position of the DMD 551 can be controlled with a higher precision. Further, the positions of the drive-use magnet unit 531a, 531b, 531c and the drive coil 581a, 581b, 581c can be respectively changed, in which the drive-use magnet units 531 are disposed on a side of the heat sink 554 closer to the base plate 512, and the drive coils 581 are disposed on a side of the base plate 512 closer to the heat sink 554, and the same effect of preventing the above described problems such as distortion and breakage of each plate can be devised.
Further, it is preferable that the center of gravity position of the movable unit 55 and the drive force generation plane are matched in the Z1-Z2 direction. For example, by appropriately changing the depth of the concave portion 582 to which the drive coil 581 is attached, and the shape of the heat dissipation unit 556 of the heat sink 554, the center of gravity position of the movable unit 55 and the drive force generation plane can be matched in the Z1-Z2 direction.
(Position Detection System)
In the embodiment, the position detection system includes the position-detection magnet 541 disposed on the base plate 512, and the Hall element 542 disposed on the DMD substrate 553. The position-detection magnet 541 and the Hall element 542 are arranged to face with each other in the Z1-Z2 direction.
The Hall element 542 is an example of a magnetic sensor, and the position-detection magnet 541 is provided at a position opposite to the Hall element 542. The Hall element 542 outputs a signal, corresponding to a change of the magnetic flux density effecting from the position-detection magnet 541, to the movement control unit 12 of the system control unit 10. The movement control unit 12 detects a position of the Hall element 542 with respect to the fixed unit 51 based on the signal transmitted from the Hall element 542, and then detects a position of the DMD 551 provided in the DMD substrate 553 based on the detected position of the Hall element 542.
In the embodiment, the top plate 511 and the base plate 512, formed of magnetic material, function as yoke plates and configure a magnetic circuit with the position-detection magnet 541. Further, the magnetic flux generated by the drive unit including the drive-use magnet unit 531 and the drive coil 581, provided between the base plate 512 and the heat sink 554, concentrates on the base plate 512, which functions as the yoke plate, with which the leakage of the magnetic flux from the drive unit to the position detection system is suppressed.
Therefore, at the Hall element 542 disposed on the lower face side of the DMD substrate 553, the influence of the magnetic field formed by the drive unit including the drive-use magnet unit 531 and the drive coil 581 is reduced so that the Hall element 542 can output a signal corresponding to the change of the magnetic flux density of the position-detection magnet 541 without being affected by the magnetic field generated by the drive unit. Therefore, the movement control unit 12 can detect the position of the DMD 551 with higher accuracy.
With this configuration, based on the output of the Hall element 542 with the reduced influence from the drive unit, the movement control unit 12 can detect the position of the DMD 551 with enhanced precision or accuracy. Therefore, the movement control unit 12 can control the magnitude and direction of the current to be made to flow to each of the drive coils 581 depending on the detected position of the DMD 551, and can control the position of the DMD 551 with enhanced precision or accuracy.
Further, the configuration of the drive unit and the position detection system are not limited to the above described configuration exemplified in the embodiment. The number and position of the drive-use magnet unit 531 and the drive coil 581 provided as the drive unit can be set differently from those of the embodiment as long as the movable unit 55 can be moved to any positions within a given range. Further, the number and position of the position-detection magnet 541 and the Hall element 542 used for configuring the position detection system can be set differently from those of the embodiment as long as the position of the DMD 551 can be detected.
For example, the position-detection magnet 541 can be disposed on the top plate 511 while the Hall element 542 can be disposed on the movable plate 552. Further, for example, the position detection system can be provided between the base plate 512 and the heat sink 554, and the drive unit can be provided between the top plate 511 and the base plate 512. In these configurations, it is preferable to provide a yoke plate between the drive unit and the position detection system so that the influence of the magnetic field from the drive unit to the position detection system can be reduced. Further, since the controlling of the position of the movable unit 55 becomes difficult when the weight of the movable unit 55 increases, each of the drive-use magnet unit 531 and the position-detection magnet 541 is preferably disposed on the fixed unit 51 such as the top plate 511 or the base plate 512.
Further, the top plate 511 and the base plate 512 can be partially formed of magnetic material if the leakage of magnetic flux from the drive unit to the position detection system can be reduced. For example, each of the top plate 511 and the base plate 512 can be formed by stacking a plurality of members including a flat plate-like or sheet-like member made of magnetic material. If at least a part of the base plate 512 is formed of magnetic material to function as the yoke plate to prevent leakage of magnetic flux from the drive unit to the position detection system, the top plate 511 can be formed of non-magnetic material.
(Image Projection)
As described above, as to the projector 1 of the embodiment, a projection image is generated by the DMD 551 provided in the movable unit 55, and the position of the movable unit 55 is controlled by the movement control unit 12 of the system control unit 10.
For example, the movement control unit 12 controls the position of the movable unit 55 with a given cycle corresponding to a frame rate set for an image projection operation so that the movable unit 55 can move with a faster speed between a plurality of positions distanced with each other less than a distance of an arrangement interval of the plurality of micromirrors of the DMD 551, in which the image control unit 11 transmits an image signal to the DMD 551 corresponding to a position of the movable unit 55 shifted by the movement of the movable unit 55 to generate a projection image.
For example, the movement control unit 12 reciprocally moves the DMD 551 between a first position P1 and a second position P2 distanced with each other less than the distance of the arrangement interval of the plurality of micromirrors of the DMD 551 in the X1-X2 direction and the Y1-Y2 direction with a given cycle. In this configuration, the image control unit 11 controls the DMD 551 to generate a projection image corresponding the position of the movable unit 55 shifted by the movement of the movable unit 55 to generate a projection image, with which the resolution level of the projection image can be set about two times of the resolution level of the DMD 551. Further, the resolution level of the projection image can be set greater than the two times of the resolution level of the DMD 551 by increasing the number of positions used for the movement of the DMD 551.
As above described, when the movement control unit 12 moves or sifts the DMD 551 together with the movable unit 55, the image control unit 11 can generate a projection image corresponding to a sifted position of the DMD 551, with which an image having a resolution level higher than the resolution level of the DMD 551 can be projected.
Further, as to the projector 1 of the above described embodiment, the movement control unit 12 can control the DMD 551 and the movable unit 55 concurrently, which means the movement control unit 12 can rotate the DMD 551 and the movable unit 55 concurrently, with which a projection image can be rotated without reducing a size of the projection image. Conventionally, an image generator (e.g., DMD) is fixed in a projector, in which a size of a projection image is required to be reduced to rotate the projection image while maintaining an aspect ratio of the projection image. By contrast, the DMD 551 can be rotated in the projector 1 of the embodiment. Therefore, a projection image can be rotated without reducing a size of the projection image, and an inclination of the projection image can be adjusted.
As described above, as to the image generation unit 50 of the embodiment, the DMD 551 is provided movably, and an image can be generated with higher resolution by shifting the DMD 551.
Further, in the embodiment, the drive force to move the movable unit 55 acts the heat sink 554, and the interval between the center of gravity position of the movable unit 55 and the drive force generation plane in the Z1-Z2 direction is reduced. Therefore, a swinging of the movable unit 55 like a pendulum can be prevented, and thereby the stability of movement operation of the movable unit 55 can be enhanced. Therefore, the position of the DMD 551 can be controlled with higher precision or accuracy.
Further, in the embodiment, the top plate 511 and the base plate 512, formed of magnetic material, function as the yoke plates and configure the magnetic circuit with the position-detection magnet 541 used for the position detection system, with which the influence of the magnetic field generated by the drive unit to the position detection system is reduced. Therefore, the movement control unit 12 can detect the position of the DMD 551, shifted with a higher speed, with higher precision or accuracy based on the output of the Hall element 542, and can control the position of the DMD 551 with enhanced precision or accuracy.
As above described, the position detection system PS can be applied to a projector or the like. More specifically, in one example case of
Further, as illustrated in
As illustrated in
A description is given of the electronic circuit EC employed for the position detection system PS of the embodiment with reference to
As illustrated in
Further, as illustrated in
In this configuration, when the Hall voltage Vh is amplified, the second DA converter DAC2 can change or adjust a voltage used as a reference for the amplification (hereinafter, reference voltage Vref). Further, the second operational amplifier OP2 can adjust an amplification level by adjusting a gain value. Further, as to the position detection system PS, the Hall voltage Vh can be amplified without using the operational amplifier circuit CR2. Specifically, the position detection system PS can change a current value to be made to flow in the Hall element 542 to output the Hall voltage Vh with a greater value, with which the amplification level of the Hall voltage Vh is changed. Further, the amplification level of the Hall voltage Vh can be changed by changing or adjusting both of the gain value set for the operational amplifier circuit CR2 and the current value to be made to flow in the Hall element 542. Hereinafter, a description is given of a case that the gain value set for the second operational amplifier OP2 is changed or adjusted for changing or adjusting the amplification level of the Hall voltage Vh.
In this example configuration, a voltage output from the second operational amplifier OP2 (i.e., voltage that is input to the AD converter ADC) is referred to as the “output voltage Vout” as illustrated in
Vout=Vref+Am×Vh (1)
Then, a relationship of the Hall voltage Vh and a detectable position range can be set as described below.
In an example case of
Further, in the example case of
Then, it is assumed that the “reference voltage Vref=1.5V” and the “gain value Am=30 times” are set. In this case, a relationship of the output voltage Vout and the Hall voltage Vh can be expressed by the following formula (2) based on the above formula (1).
Vout=1.5+30×Vh (2)
Then, if the AD converter ADC performs the AD conversion by converting analog values to digital values with a resolution defined by “B (bit),” the resolution within the above mentioned detectable position range can be expressed by the following formula (3). Further, the detectable position range can be expressed by the following formula (4).
Resolution=2×RA/2B (3)
Detectable position range=−RA to +RA=2×RA (4)
Then, a relationship of the output voltage Vout (i.e., voltage obtained by amplifying the Hall voltage Vh) and the detectable position range can be set as described below with reference to
As illustrated in
Further, a slope SF of a profile illustrated in
Then, to enhance the resolution, the gain value (i.e., slope SF in
Further, the output voltage Vout can be increased by increasing the current value to be made to flow in the Hall element 542. For example, when the current value to be made to flow in the Hall element 542 is increased for two times, the output voltage Vout can be increased for two times.
For example, when a value of the slope SF is increased to two times of the value used in
Vout=1.5+60×Vh (5)
As illustrated in
Resolution=RA/2B (6)
Detectable position range=−(½)RA to +(½)RA=RA (7)
When the slope SF is set greater as illustrated in
In this configuration, one mode that sets a priority on a width of the detectable position range is referred to as a “detection range priority mode,” which is indicated in
Further, the intercept IP (i.e., reference voltage Vref) is changed from the intercept IP indicated in
When the intercept IP of “0” is set as indicated in
Vout=0+60×Vh (8)
When the slope SF and the intercept IP are set as illustrated in
Resolution=RA/2B (9)
Detectable position range=0 to +RA=RA (10)
Further, as to the settings of
Further, the intercept IP (i.e., reference voltage Vref) is changed from the intercept IP indicated in
When the intercept IP of “3.0” is set as indicated in
Vout=3.0+60×Vh (11)
When the slope SF and the intercept IP are set as illustrated in
Resolution=RA/2B (12)
Detectable position range=−RA to 0=RA (13)
As above described, when the reference voltage Vref (i.e., intercept IP) is changed, the position detection system PS can switch regions used for detecting the position such as from a first region AR1 (
Further, when the settings of
Further, the number of switchable regions is not limited to two regions. For example, the number of switchable regions can be three of more depending on the amplification level. For example, when the amplification level is “3 times,” the number of switchable regions can be three regions, and when the amplification level is “4 times,” the number of switchable regions can be four regions.
Further, even if the amplification level is “2 times,” a third region AR3 is preferably set as described below.
The third region AR3 is preferably a region having the center position of the region where a movable member is located with higher probability, wherein the position where the movable member is located with higher probability varies depending on specifications and/or usages. For example, in the example configuration of
It is preferable that the number of times of switching of the regions is smaller. If the regions are frequently switched, the position detection precision may be reduced. Therefore, as illustrated in
(Sequence of Changing Amplification Level and Reference Voltage)
At step S01, the position detection system PS sets an initial value. For example, the initial value is used to set the detection range priority mode for the position detection system PS. Specifically, when the initial value is set, the position detection system PS is set with the values indicated in
At step S02, the position detection system PS determines whether the “resolution priority mode” is to be applied. For example, when a user inputs a mode change instruction to the position detection system PS, the position detection system PS changes the “detection range priority mode” to the “resolution priority mode.” Therefore, when the user performs a given operation, the position detection system PS determines that the “resolution priority mode” is to be applied.
When the position detection system PS determines that the “resolution priority mode” is to be applied (step S02: YES), the position detection system PS proceeds the sequence to step S03. By contrast, when the position detection system PS determines that the “resolution priority mode” is not applied (step S02: NO), the position detection system PS ends the sequence.
At step S03, the position detection system PS changes the amplification level. For example, the position detection system PS changes or adjusts at least one of the current value to be made to flow in the Hall element 542 and the gain value set for the operational amplifier to change the amplification level of the Hall voltage Vh. For example, when the amplification level is changed for “2 times,” the slope SF is changed as indicated from
Then, the position detection system PS determines a region to be used for detecting the position. In the sequence illustrated in
At step S04, the position detection system PS determines whether the to-be-used region is the first region AR1. For example, as above described, when the Hall element 542 is located near “0” and the third region AR3 is the to-be-used region, the position detection system PS determines that the to-be-used region is not the first region AR1 (step S04: NO).
When the position detection system PS determines that the to-be-used region is the first region AR1 (step S04: YES), the position detection system PS proceeds the sequence to step S05. By contrast, when the position detection system PS determines that the to-be-used region is not the first region AR1 (step S04: NO), the position detection system PS proceeds the sequence to step S06.
At step S05, the position detection system PS sets a reference voltage Vref of the first region AR1. For example, as illustrated in the example case of
At step S06, the position detection system PS determines whether the to-be-used region is the second region AR2. For example, as above described, when the Hall element 542 is located near “0” and the third region AR3 is the to-be-used region, the position detection system PS determines that the to-be-used region is not the second region AR2 (step S06: NO).
When the position detection system PS determines that the to-be-used region is the second region AR2 (step S06: YES), the position detection system PS proceeds the sequence to step S07. By contrast, when the position detection system PS determines that the to-be-used region is not the second region AR2 (step S06: NO), the position detection system PS proceeds the sequence to step S08.
At step S07, the position detection system PS sets a reference voltage Vref of the second region AR2. For example, as illustrated in the example case of
At step S08, the position detection system PS sets a reference voltage Vref of the third region AR3. For example, as illustrated in the example case of
(Functional Configuration)
The magnetic field generation unit PSF1 generates the magnetic field M (
When the magnetic field M (
The amplification unit PSF3 amplifies the Hall voltage Vh output from the magnetic field detection unit PSF2. For example, the amplification unit PSF3 can be implemented or devised as an amplification circuit by the operational amplifier circuit CR2 (
The setting unit PSF4 sets the reference voltage Vref and the amplification level MF to the amplification unit PSF3. Further, the setting unit PSF4 changes the reference voltage Vref to switch a region used for detecting the position. For example, the setting unit PSF4 can be implemented or devised by the constant current circuit CR1 (
As above described, the position detection system PS can detect the position of the movable member based on the detection voltage detected by the magnetic field detection unit PSF2 when the magnetic field detection unit PSF2 detects the magnetic flux density B of the magnetic field M effecting the magnetic field detection unit PSF2 from the magnetic field generation unit PSF1. Then, the position detection system PS can amplify the detection voltage by using the amplification unit PSF3.
As illustrated in the example case of
Further, by switching the regions as above described, the position detection system PS can use the detectable position range of “2×RA” used in the example case of
In the above described configuration, the above described formula (1) is used in the embodiment.
Vout=Vref+Am×Vh (1)
In the above described configuration, when the reference voltage Vref alone is changed or adjusted (i.e., gain value Am is not changed), the region to be used for the position detection operation is changed (i.e., the center position of the to-be-used region is changed) while the resolution and a width of the detectable position range are not changed as indicated in the example cases of
Further, when the gain value Am alone is changed or adjusted (i.e., reference voltage Vref is not changed), the width of the detectable position range and the resolution are changed. For example, when the gain value Am alone is increased, the width of the detectable position range is set narrower without changing the center position of the to-be-used region, and thereby the resolution can be set higher as indicated by comparing the example cases of
In the above described configuration, when the resolution is set higher by setting the gain value Am with a greater value, the width of the detectable position range is set narrower. Therefore, after the resolution is set higher, the to-be-used region (i.e., the center position of the to-be-used region) can be shifted by changing or adjusting the reference voltage Vref, with which the detectable position range can be set wider for the position detection system PS of the embodiment, and thereby the position detection system PS can detect the position of the movable member with higher resolution and the wider detectable position range. Therefore, in the embodiment, each one of the reference voltage Vref and the gain value Am is changed or adjusted in view of the width of the detectable position range and the resolution to be used for the position detection operation.
According to the above described embodiment of the present invention, the position detection system can detect a position of the movable member with enhanced resolution and a wider detection range.
Further, although the position detection system PS is applied to the projector in the above described embodiment, the position detection system PS can be applied to other devices or apparatuses other than the projector.
Numerous additional modifications and variations for the modules, the units, the image generation units, the image projection apparatuses, and the apparatuses are possible in light of the above teachings. It is therefore to be understood that within the scope of the appended claims, the description of present disclosure may be practiced otherwise than as specifically described herein. For example, elements and/or features of different examples and illustrative embodiments may be combined each other and/or substituted for each other within the scope of present disclosure and appended claims.
Each of the functions of the described embodiments may be implemented by one or more processing circuits or circuitry. Processing circuitry includes a programmed processor, as a processor includes circuitry. A processing circuit also includes devices such as an application specific integrated circuit (ASIC), digital signal processor (DSP), field programmable gate array (FPGA), and conventional circuit components arranged to perform the recited functions.
Number | Date | Country | Kind |
---|---|---|---|
2016-144155 | Jul 2016 | JP | national |
Number | Name | Date | Kind |
---|---|---|---|
5285313 | Kobayashi et al. | Feb 1994 | A |
20050050569 | Yamanaka et al. | Mar 2005 | A1 |
20060284495 | Seo et al. | Dec 2006 | A1 |
20070091181 | Serikawa et al. | Apr 2007 | A1 |
20090039875 | Hoshino | Feb 2009 | A1 |
20100033820 | Omi | Feb 2010 | A1 |
20110019157 | He | Jan 2011 | A1 |
20140036239 | Mashitani | Feb 2014 | A1 |
20150219983 | Mashitani et al. | Aug 2015 | A1 |
20150264291 | Tani et al. | Sep 2015 | A1 |
20160154294 | Fujioka et al. | Jun 2016 | A1 |
20160198134 | Mikawa et al. | Jul 2016 | A1 |
Number | Date | Country |
---|---|---|
4-031835 | Feb 1992 | JP |
405316414 | Nov 1993 | JP |
2001-350196 | Dec 2001 | JP |
2008-070494 | Mar 2008 | JP |
2008-225158 | Sep 2008 | JP |
2008-292647 | Dec 2008 | JP |
2010-243686 | Oct 2010 | JP |
2011-027821 | Feb 2011 | JP |
2012-181386 | Sep 2012 | JP |
2013-117629 | Jun 2013 | JP |
2016-102945 | Jun 2016 | JP |
2016-102946 | Jun 2016 | JP |
WO2016067519 | May 2016 | WO |
Number | Date | Country | |
---|---|---|---|
20180023976 A1 | Jan 2018 | US |