JP2018165784A - Laser module and image projection apparatus - Google Patents

Abstract

Provided is a laser module that can be fixed in different directions and has the same heat dissipation property when fixed in any direction. A plurality of laser elements 12a to 12c having different oscillation wavelengths and a plurality of laser elements 12a to 12c are assembled and symmetrical with respect to a plane 30 formed by light emitting points 28 of the plurality of laser elements 12a to 12c. The housing 10 and the laser beam from the plurality of laser elements 12 a to 12 c are incident, and the laser beams are combined and emitted to the front surface 40 side that intersects the plane 30 of the housing 10. A laser module comprising: dichroic prisms 14a and 14b; and fixing portions 18 provided symmetrically with respect to the plane 30 on both side surfaces 42 and 44 located on both sides of the plane 30 of the housing 10 and fixed to external components. [Selection] Figure 3

Description

  The present invention relates to a laser module and an image projection apparatus.

  There is known a laser module that includes a plurality of laser elements and synthesizes laser beams from these laser elements and emits them to the outside (for example, Patent Documents 1 and 2). As an example of an apparatus including a laser module, an image projection apparatus such as a head-mounted display that directly projects an image on a user's retina by irradiating the user's eyes with laser light emitted from the laser module is known. (For example, Patent Documents 3 and 4).

JP 2000-12957 A JP 2003-66369 A JP 2009-258686A Japanese Patent Application Laid-Open No. 2015-111231

  For example, when the laser module is used in an eyeglass-type image projection device such as a head-mounted display, it is desirable to fix the laser module to the eyeglass vine in consideration of fiber routing and portability, and a right eye laser. More preferably, the module is fixed to the right-eye vine and the left-eye laser module is fixed to the left-eye vine. In this case, the right eye laser module and the left eye laser module have different fixing directions and heat dissipation directions, so it is conceivable to design laser modules dedicated to the right eye and the left eye. However, considering the manufacturing cost, it is desirable that the same laser module can be shared for the right eye and the left eye.

  The present invention has been made in view of the above problems, and a laser module that can be fixed in different directions and that has the same heat dissipation property when it is fixed in any direction, and enables the same optical layout, and the laser module An object of the present invention is to provide an image projection apparatus including the above.

  The present invention includes a plurality of laser elements having different oscillation wavelengths, a casing in which the plurality of laser elements are assembled, and a symmetrical shape with respect to a plane formed by light emitting points of the plurality of laser elements, and the casing And an optical element that receives laser beams from the plurality of laser elements, synthesizes the laser beams, and emits them to the front side intersecting the plane of the casing, and both sides of the plane of the casing And a fixing portion that is provided symmetrically with respect to the plane and fixed to an external part on both side surfaces positioned at the side.

  The said structure WHEREIN: The said fixing | fixed part can be set as the structure provided higher than the area | regions other than the said fixed part in the both sides | surfaces of the said housing | casing.

  In the above-described configuration, a light receiving element that is assembled to the housing and monitors the intensity of the laser light emitted from the plurality of laser elements is provided, and the optical element and the light receiving element are symmetrical with respect to the plane. And can be configured to be assembled to the housing.

  In the above configuration, the plurality of laser elements, the optical element, and the light receiving element may be positioned between both side surfaces of the casing and assembled to the casing.

  In the above configuration, the casing has a frame shape in which a space is provided inside, and the plurality of laser elements are assembled to the casing so as to emit the laser light toward the space. The said optical element can be set as the structure assembled | attached to the said housing | casing located in the said space.

  The said structure WHEREIN: The said laser beam radiate | emitted from the said several laser element and passed through the said optical element can be set as the structure condensed by the lens on the same position outside the said housing | casing.

  The said structure WHEREIN: The said laser beam radiate | emitted from these laser elements can be set as the structure which injects into the said optical element without passing through a lens.

  The said structure WHEREIN: It can be set as the structure provided with the film which is provided in the both sides | surfaces of the said housing | casing and suppresses reflection of light.

  The present invention provides the laser module according to any one of the above, a scanning optical member that scans the laser light emitted from the laser module, and the laser light scanned by the scanning optical member is projected onto a user's retina. And a projection optical member that projects an image on the retina.

  In the above-described configuration, the image projection device has a pair of vines having an eyeglass shape and an attachment part to which the laser module can be attached, and the attachment part of one of the pair of vines is attached to the attachment part. A distance from the mounting portion of the one vine of the light emitting points of the plurality of laser elements when the fixing portion of one side surface of the two side surfaces of the housing constituting the laser module is mounted; The other vine of light emitting points of the plurality of laser elements when the fixing portion on the other side surface of the two side surfaces of the housing constituting the laser module is attached to the attachment portion of the other vine. The distance from the attachment portion may be an equal distance.

  According to the present invention, it is possible to obtain a laser module that can be fixed in different directions and has the same heat dissipation property even when fixed in any direction, and enables the same optical layout.

FIG. 1 is a diagram of an image projection apparatus including the laser module according to the first embodiment viewed from above. 2A is a front view of the laser module according to the first embodiment, FIG. 2B is a side view of FIG. 2A viewed from the direction A, and FIG. 2C is FIG. ) Is a side view seen from the B direction. FIGS. 3A and 3B are exploded perspective views of the laser module according to the first embodiment. FIG. 4 is a perspective view for explaining assembly of the laser element to the housing. FIG. 5 is a diagram illustrating the focal point of the laser light emitted from the laser module according to the first embodiment. FIG. 6 is an exploded perspective view of the laser module according to the first modification of the first embodiment. FIG. 7A to FIG. 7D are plan views of the light receiving element.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings.

  FIG. 1 is a diagram of an image projection apparatus including the laser module according to the first embodiment viewed from above. As shown in FIG. 1, the image projection apparatus 500 includes a laser module 100, a lens 60, a mirror 62, a scanning mirror 64, a projection mirror 66, an image input unit 68, and a control unit 70.

  The image projection apparatus 500 is a glasses type. The glasses have a pair of vines 72 and a pair of lenses 74. Each of the pair of vines 72 is provided with a laser module 100, a lens 60, a mirror 62, and a scanning mirror 64. The laser module 100 is attached to each attachment portion 78 of the pair of vines 72. A projection mirror 66 is provided for each of the pair of lenses 74. For example, the image input unit 68 and the control unit 70 may be provided in an external device (for example, a portable terminal) without being provided in the glasses, or may be provided in the vine 72 of the glasses.

  Image data is input to the image input unit 68 from a camera and / or recording device (not shown). The control unit 70 controls the emission of the laser beam 76 from the laser module 100 based on the input image data. As described above, the image data is converted by the laser module 100 into the laser beam 76 that is an image beam.

  The control unit 70 is, for example, a control circuit, and may be a processor such as a CPU (Central Processing Unit) or a dedicated circuit. If the camera is installed at an appropriate position of the image projection device 500 in the direction of the user's line of sight, the image of the line of sight captured by this camera can be projected onto the user's retina 82. Also, a so-called virtual reality (AR) image is projected by projecting an image input from a recording device or by superimposing a camera image and an image from the recording device on the control unit 70. You can also.

  The lens 60 is a compound lens of a collimator lens and an objective lens, and converts the laser light 76 emitted from the laser module 100 into convergent light that slightly converges from the divergent light. The lens 60 may be integrated with the laser module 100 or may be a separate component from the laser module 100.

  The mirror 62 reflects the laser beam 76 that has passed through the lens 60 toward the scanning mirror 64. The scanning mirror 64 scans the laser beam 76 in a two-dimensional direction to obtain projection light for projecting an image on the user's retina 82. The scanning mirror 64 is, for example, a MEMS (Micro Electro Mechanical System) mirror, and scans the laser beam 76 in the two-dimensional direction of the horizontal direction and the vertical direction. In the first embodiment, the scanning mirror 64 is described as an example of the scanning optical member. However, if the scanning optical member can scan the laser beam, for example, lithium tantalate niobate (KTN), which is an electro-optical material, is used. Other scanners such as crystals may be used.

  The laser beam 76 scanned by the scanning mirror 64 is incident on a projection mirror 66 provided on a surface of the eyeglass lens 74 of the glasses 74 on the user's eyeball 80 side. The projection mirror 66 projects an image on the retina 82 by projecting the laser light 76 scanned by the scanning mirror 64 onto the retina 82 of the user. The user recognizes the image by the afterimage effect of the laser light 76 projected on the retina 82. Since each of the pair of vines 72 of the glasses is provided with the laser module 100 or the like, the user can recognize an image with both eyes.

  The projection mirror 66 is designed so that the convergence position of the laser light 76 scanned by the scanning mirror 64 is near the pupil 84. The projection mirror 66 does not need to be in contact with the lens 74 of the glasses, and may be at a position where the laser light 76 can be irradiated to the retina 82 through the pupil 84. Further, depending on the application, the lens 74 may not be provided by the projection mirror 66 alone. In the first embodiment, the case where the projection mirror 66 is used as the projection optical member will be described as an example. However, the projection optical member only needs to be able to project laser light onto the retina 82, and may be a diffraction grating or a lens, for example. . When a lens is used as the projection optical member, it can be realized by disposing a non-condensing mirror and disposing the lens on the eyeball 80 side of the mirror, and also arranging the optical system such as the laser module 100 and the scanning mirror 64 Thus, it is possible to adopt a configuration in which laser light is projected onto the retina 82 using only a lens.

  The laser beam 76 scanned by the scanning mirror 64 is condensed before the projection mirror 66 and enters the projection mirror 66 as divergent light. As a result, the laser beam 76 is incident on the cornea 88 as substantially parallel light by the condensing power of the projection mirror 66, and is condensed near the retina 82 by the crystalline lens 86.

  2A is a front view of the laser module according to the first embodiment, FIG. 2B is a side view of FIG. 2A viewed from the direction A, and FIG. 2C is FIG. ) Is a side view seen from the B direction. 2A to 2C, the laser module 100 includes a housing 10, laser elements 12a to 12c, dichroic prisms 14a and 14b, a mirror 16, a fixing unit 18, and a light receiving element. 20a, 20b. The width W of the housing 10 is, for example, about 4 mm, the height H is, for example, about 11 mm, and the depth D is, for example, about 16 mm.

  The housing 10 is made of a metal having a high thermal conductivity such as an aluminum alloy or a magnesium alloy. The housing 10 has a frame shape having a space 22 inside. The space 22 is formed through the housing 10 in the width direction from one side surface 42 to the other side surface 44. The front surface 40 of the housing 10 is provided with a hole 24 through which the space 22 communicates with the outside, and the laser beams from the laser elements 12a to 12c are combined and emitted to the outside.

  The laser elements 12 a to 12 c are, for example, TO-CAN package type semiconductor laser diodes, and are assembled to the housing 10 so that laser light is emitted toward the space 22 provided in the housing 10. The laser element 12a is assembled on the back surface 46 of the housing 10, and oscillates red laser light, for example. The laser element 12b is assembled on the upper surface 48 of the housing 10, and oscillates, for example, green laser light. The laser element 12c is assembled above the hole 24 on the front surface 40 of the housing 10, and oscillates blue laser light, for example. For example, the wavelength of red laser light is 610 nm to 660 nm, the wavelength of green laser light is 515 nm to 540 nm, and the wavelength of blue laser light is 440 nm to 460 nm.

  The dichroic prisms 14 a and 14 b are optical elements having functions of transmitting, reflecting, and synthesizing laser light, and are located in the space 22 and assembled to the housing 10. For example, red laser light oscillated from the laser element 12a and, for example, green laser light oscillated from the laser element 12b enter the dichroic prism 14a without passing through a lens. At this time, for example, red laser light oscillated from the laser element 12a is split into transmitted light and reflected light by the dichroic prism 14a. For example, green laser light oscillated from the laser element 12b is split into transmitted light and reflected light by the dichroic prism 14a. The red laser light that has passed through the dichroic prism 14a and the green laser light that has been reflected by the dichroic prism 14a are combined and transmitted through the dichroic prism 14b to be emitted to the hole 24 that can be emitted to the outside. For example, blue laser light oscillated from the laser element 12c is substantially totally reflected by the mirror 16, enters the dichroic prism 14b without passing through the lens, and is split into transmitted light and reflected light. The blue laser light reflected by the dichroic prism 14b is combined with the combined light combined by the dichroic prism 14a and emitted to the hole 24 that can be emitted to the outside. On the other hand, the red laser light reflected from the dichroic prism 14a and the green laser light transmitted through the dichroic prism 14a are emitted to the light receiving element 20a. Further, the blue laser light transmitted through the dichroic prism 14b is emitted to the light receiving element 20b.

  The spectral characteristics of the dichroic prism 14a are such that the reflected red laser light has a higher light intensity than the transmitted red laser light, and the transmitted green laser light is higher than the reflected green laser light. It is comprised so that it may become intensity | strength. That is, the dichroic prism 14a splits the red laser light oscillated by the laser element 12a into transmitted light and reflected light, and makes the amount of transmitted light smaller than the amount of reflected light. For example, the spectral characteristics of the red laser light of the dichroic prism 14a are 15% transmission and 85% reflection. The dichroic prism 14a splits the green laser light oscillated by the laser element 12b into transmitted light and reflected light, and makes the amount of reflected light smaller than the amount of transmitted light. For example, the spectral characteristics of the green laser light of the dichroic prism 14a are 15% reflection and 85% transmission.

  The spectral characteristics of the dichroic prism 14b are configured such that the transmitted blue laser light has higher light intensity than the reflected blue laser light. That is, the dichroic prism 14b splits the blue laser light oscillated by the laser element 12c into transmitted light and reflected light, and makes the amount of reflected light smaller than the amount of transmitted light. For example, the spectral characteristics of the blue laser light of the dichroic prism 14b are 15% reflection and 85% transmission.

  The case of a dichroic prism as an example of an optical element that transmits, reflects, and synthesizes laser light will be described as an example, but other optical elements such as a plate-like dichroic mirror may be used.

  As described above, the dichroic prisms 14a and 14b have spectral characteristics in which the amount of laser light emitted to the outside is smaller than the amount of laser light incident on the light receiving elements 20a and 20b. Since the laser light emitted from the laser module 100 is applied to the retina 82, the light intensity is preferably small. For this reason, it is conceivable to reduce the light intensity of the laser light oscillated by the laser elements 12a to 12c, but there is a limit (for example, about several mW) in the oscillation of the laser light having a low light intensity, and the light intensity is higher than that. It is difficult to stably oscillate a small laser beam. However, by using the dichroic prisms 14a and 14b having the above spectral characteristics, laser light having a light amount smaller than the laser light oscillated by the laser elements 12a to 12c is emitted from the laser module 100 to the outside. The light intensity of the laser beam emitted to the outside can be reduced while realizing stable oscillation of the laser beam by ~ 12c.

  The fixing portion 18 is provided on each of the pair of side surfaces 42 and 44 of the housing 10. The fixing portion 18 has a hole 26 that penetrates the housing 10 from one side surface 42 to the other side surface 44 of the housing 10. The laser module 100 is fixed to an external component by passing a screw or the like through the hole 26 of the fixing portion 18. The fixing portion 18 is formed so as to be one step higher than the surroundings. That is, the fixing portion 18 provided on the side surface 42 of the housing 10 is formed one step higher than the region other than the fixing portion 18 on the side surface 42, and the fixing portion 18 provided on the side surface 44 of the housing 10 is fixed to the side surface 44. It is formed one step higher than the region other than the portion 18. Thereby, when the laser module 100 is fixed to the external component, only the fixing portion 18 of the housing 10 comes into contact with the external component.

  The light receiving elements 20 a and 20 b are semiconductor photodiodes, for example, and are assembled to the lower surface 50 of the housing 10 outside the housing 10. The light receiving element 20a is assembled at a position sandwiching the dichroic prism 14a and the housing 10, receives the laser light oscillated by the laser element 12a and the laser element 12b and dispersed by the dichroic prism 14a. The light receiving element 20b is assembled at a position sandwiching the dichroic prism 14b and the housing 10, and receives the laser light oscillated by the laser element 12c and dispersed by the dichroic prism 14b. The current (monitor value) output by the light receiving elements 20 a and 20 b by photoelectric conversion is input to the control unit 70. The control unit 70 performs feedback control of the laser elements 12a to 12c based on the monitor values of the light receiving elements 20a and 20b.

  As the laser module 100 is further downsized, the light receiving elements 20a and 20b are also downsized to reduce the light receiving area. For this reason, we are anxious about the fall of the detection accuracy of light receiving element 20a, 20b. However, as described above, laser light having a light quantity more than half of the laser light oscillated by the laser elements 12a to 12c by the dichroic prisms 14a and 14b is emitted to the light receiving elements 20a and 20b. The amount of laser light that can be detected is increased, and a decrease in detection accuracy can be suppressed.

  FIG. 7A to FIG. 7D are plan views of the light receiving element. FIG. 7A is a plan view of the light receiving element 20a, and FIG. 7B is a plan view of the light receiving element 20b. As shown in FIG. 7A, the light receiving element 20a has a sensitivity in the wavelength band of the red laser light and a light receiving region 90 for receiving the red laser light and a sensitivity in the wavelength band of the green laser light and the green laser. And a light receiving region 92 for receiving light. As shown in FIG. 7B, the light receiving element 20b is configured to have a light receiving region 94 that receives the blue laser light with sensitivity in the wavelength band of the blue laser light. At this time, the light receiving regions 90 to 94 do not define the laser light emission range. For example, the combined light of the red laser light and the green laser light is emitted within a predetermined range as shown by the one-dot chain line in FIG. Is done.

  The red laser light may be totally transmitted through the dichroic prism 14a, and the green laser light may be totally reflected by the dichroic prism 14a and synthesized, and may be split into transmitted light and reflected light by the dichroic prism 14b. In this case, the spectral characteristics of the dichroic prism 14b are configured such that the combined light that is reflected is higher in intensity than the combined light of the transmitted red laser light and green laser light, and the blue laser light is configured in the same manner as described above. Is done. In this case, as shown in FIG. 7C, the light receiving element 20b includes a light receiving region 90 having sensitivity in the wavelength band of red laser light, a light receiving region 92 having sensitivity in the wavelength band of green laser light, and blue laser light. And the light receiving region 94 having sensitivity in the wavelength band, and the light receiving element 20a becomes unnecessary. Further, as shown in FIG. 7D, the light receiving element 20b has a light receiving region 95 that has sensitivity to all the wavelength bands of red laser light, green laser light, and blue laser light and receives all the laser light. In addition, the red laser light, the green laser light, and the blue laser light are emitted while being shifted in time, and are monitored by the light receiving element 20b only during the time during which each laser light is emitted. The element 20a is not necessary.

  Thus, the light receiving element may include a plurality of light receiving regions having sensitivity in each of the wavelength bands of the plurality of laser beams oscillated by the plurality of laser elements, or a plurality of laser beams oscillated by the plurality of laser elements. One light receiving region having sensitivity in all the wavelength bands may be provided.

  The laser elements 12 a to 12 c, the dichroic prisms 14 a and 14 b, the mirror 16, and the light receiving elements 20 a and 20 b are located between the side surfaces 42 and 44 of the casing 10 and assembled to the casing 10.

  FIGS. 3A and 3B are exploded perspective views of the laser module according to the first embodiment. 3A shows the housing 10 and the fixing portion 18, and FIG. 3B shows the laser elements 12a to 12c, the dichroic prisms 14a and 14b, the mirror 16, and the light receiving elements 20a and 20b. As shown in FIGS. 3A and 3B, a plane formed by the light emitting points 28 of the laser elements 12 a to 12 c is a plane 30. A portion where the plane 30 intersects the housing 10 and the dichroic prisms 14a and 14b is also indicated by a one-dot chain line. The housing 10 has a symmetrical shape with respect to the plane 30. The front surface 40, the back surface 46, the upper surface 48, and the lower surface 50 of the housing 10 intersect the plane 30. That is, the center lines of the front surface 40, the back surface 46, the upper surface 48, and the lower surface 50 of the housing 10 coincide with the plane 30. The side surfaces 42 and 44 of the housing 10 are located on both sides of the plane 30 and are, for example, surfaces parallel to the plane 30. The fixing portions 18 provided on the side surfaces 42 and 44 of the housing 10 are provided symmetrically with respect to the plane 30. The dichroic prisms 14 a and 14 b, the mirror 16, and the light receiving elements 20 a and 20 b are assembled to the housing 10 in a symmetrical shape with respect to the plane 30.

  That is, the side surfaces 42 and 44 on which the fixing portion 18 is provided are parallel to the laser beam emission direction, and the light emitting points 28 of the laser elements 12a to 12c are equidistant from the side surfaces 42 and 44 and the side surfaces 42 and 44. Located in the center between. Therefore, when the laser module 100 is attached to each attachment portion 78 of the pair of vines 72 as shown in FIG. 1, one side surface 42 of the laser module 100 is attached to one vine 72 and the other vine 72 is attached to the other vine 72. The other side surface 44 of the other laser module 100 is attached, and the light emission points 28 of the laser elements 12 a to 12 c of the respective laser modules 100 are equidistant from the respective attachment portions 78.

  FIG. 4 is a perspective view for explaining assembly of the laser element to the housing. Before assembling the laser elements 12 a to 12 c to the housing 10, the dichroic prisms 14 a and 14 b and the mirror 16 are assembled to the housing 10. The laser elements 12a to 12c are in the X-axis direction (width direction of the housing 10), the Y-axis direction (height direction of the housing 10), and the Z-axis direction (depth direction of the housing 10) with respect to the housing 10. Can be moved in parallel with each other, and can be rotated with respect to the X, Y, and Z axes. When the laser elements 12 a to 12 c are assembled to the housing 10, the laser light oscillated by the laser elements 12 a to 12 c is condensed at the same position outside the laser module 100 by a lens disposed at the subsequent stage of the dichroic prism 14 b. As described above, the laser elements 12a to 12c are translated and rotated along the X axis, the Y axis, and the Z axis to adjust the optical axis and the focal length, and are fixed with an adhesive (not shown). The light receiving elements 20a and 20b may be fixed in advance to the design position on the lower surface 50 of the housing 10, or may be adjusted and fixed at an optimal position after adjusting and fixing the laser elements 12a to 12c. When adjusting and fixing the light receiving elements 20a and 20b, the light receiving elements 20a and 20b are arranged in the X-axis direction (width direction of the housing 10) and the Z-axis direction (depth of the housing 10) with respect to the lower surface 50 of the housing 10. The light receiving element can be adjusted to a more optimal position. The light intensity of the laser light oscillated by the laser elements 12a to 12c is controlled to an appropriate light intensity by the control unit 70 of the first embodiment that receives the current signal from the light receiving elements 20a and 20b.

  FIG. 5 is a diagram illustrating the focal point of the laser light emitted from the laser module according to the first embodiment. As shown in FIG. 5, the laser elements oscillated by the laser elements 12 a to 12 c are obtained by moving the laser elements 12 a to 12 c in parallel with the X axis, the Y axis, and the Z axis and performing optical axis alignment. The dichroic prisms 14a and 14b are combined on the same axis and are condensed at the same position outside the laser module 100 by the lens 60 arranged at the rear stage of the dichroic prism 14b to form one focal point 32. In FIG. 1, the focal point 32 corresponds to a point where the laser light 76 is condensed after the scanning mirror 64 and before the projection mirror 66.

  According to the laser module 100 of the first embodiment, as shown in FIGS. 2A to 3A, the housing 10 is symmetrical with respect to the plane 30 formed by the light emitting points 28 of the laser elements 12a to 12c. I am doing. The fixing portion 18 is provided symmetrically with respect to the plane 30 on the side surfaces 42 and 44 of the housing 10. Accordingly, the laser module 100 can be fixed to an external component with the same optical layout by the fixing portion 18 on both the side surfaces 42 and 44 of the housing 10. Therefore, the laser module 100 can be fixed to any of the pair of vines 72 of the eyeglass-type image projection device 500 while the direction of the emitted laser light remains in the direction of the projection mirror 66. Further, even if the laser module 100 is fixed to the external component by any one of the fixing portions 18 on the side surfaces 42 and 44 of the casing 10, the casing 10 is symmetrical with respect to the plane 30 and the fixing section 18 is on the plane 30. Since it is provided symmetrically, similar heat dissipation can be obtained. The symmetrical shape of the housing 10 and the symmetrical arrangement of the fixing portions 18 are preferably a completely symmetrical shape and a completely symmetrical arrangement from the viewpoint of heat dissipation, but hardly affect the heat dissipation of a manufacturing error. The shape and arrangement may differ to some extent.

  The fixing part 18 is provided higher than the area other than the area where the fixing part 18 is provided on the side surfaces 42 and 44 of the housing 10. Thereby, when the laser module 100 is fixed to an external component by the fixing portion 18, only the fixing portion 18 of the side surfaces 42 and 44 of the housing 10 comes into contact with the external component. For this reason, the laser module 100 is fixed to the external part by the fixing part 18 on either of the side surfaces 42 and 44 of the housing 10, and the same heat dissipation can be easily obtained while minimizing optical distortion caused by the fixing. Become.

  As shown in FIG. 3B, the dichroic prisms 14 a and 14 b, the mirror 16, and the light receiving elements 20 a and 20 b are assembled to the housing 10 so as to be symmetrical with respect to the plane 30. As described above, the parts assembled to the housing 10 are also symmetrical with respect to the plane 30, so that the laser module 100 can be fixed to the external parts by the fixing portions 18 of the side surfaces 42 and 44 of the housing 10. It is easy to obtain the same heat dissipation. 2A to 2C, the laser elements 12a to 12c, the dichroic prisms 14a and 14b, the mirror 16, and the light receiving elements 20a and 20b are provided between the side surfaces 42 and 44 of the housing 10. And is assembled to the housing 10. Thereby, the dichroic prisms 14 a and 14 b, the mirror 16, and the light receiving elements 20 a and 20 b can be easily assembled so as to be symmetrical with respect to the plane 30.

  As shown in FIGS. 2B and 2C, the laser elements 12 a to 12 c are assembled to the housing 10 so that the laser light is emitted toward the space 22 provided inside the housing 10. . The dichroic prisms 14 a and 14 b are located in the space 22 and assembled to the housing 10. Thereby, the laser module 100 can be reduced in size. By downsizing the laser module 100, it becomes easy to attach the laser module 100 to the eyeglass vine 72 in the eyeglass-type image projection apparatus 500 of FIG.

  Further, in the plane 30 formed by the light emitting points 28 of the laser elements 12a to 12c, the distance to the fixing portion 18 on the side surface 42 is equal to the distance to the fixing portion 18 on the side surface 44. For this reason, when the fixing part 18 of the one side 42 of the housing | casing 10 which comprises the laser module 100 is fixed to the attachment part 78 of one vine of a pair of vines 72, and the other vine attachment part 78. When the fixing portion 18 of the other side surface 44 of the housing 10 constituting the laser module 100 is fixed, the distance from the mounting portion 78 of the light emitting point 28 of the laser elements 12a to 12c is the same. Therefore, with the configuration of the laser module 100, when the laser module 100 is attached to both of the pair of vines 72 of the image projection apparatus 500, it can be attached thermally and optically symmetrically. As a result, the same laser module 100 can be attached to both the right eye and the left eye with minimal influence on the thermal and optical performance.

  Further, the image projection apparatus 500 may be an image projection apparatus for one eye, and the laser module 100 may be attached only to one of the vines 72. When the image projection apparatus 500 is attached to either the left or right vine 72, the same heat dissipation as in the same fixing method is used. Therefore, it is possible to provide a laser module having a reduced manufacturing cost and an image projection apparatus including the laser module.

  In the image projection apparatus 500 including the laser module 100, when the focal positions of the laser beams emitted from the laser elements 12a to 12c are shifted from each other, color reproducibility is deteriorated and it becomes difficult to project a high-quality image. However, according to the first embodiment, as shown in FIG. 5, the laser light emitted from the laser elements 12 a to 12 c and passing through the dichroic prisms 14 a and 14 b is condensed at the same position outside the housing 10 by the lens 60. The For this reason, it is possible to project a high-quality image while suppressing a decrease in color reproducibility.

  As shown in FIG. 5, the laser beams emitted from the laser elements 12a to 12c are incident on the dichroic prisms 14a and 14b without passing through the lens. Thus, since no lens is provided between the laser elements 12a to 12c and the dichroic prisms 14a and 14b, the laser module 100 can be reduced in size. That is, in the configuration shown in FIG. 5, since there is only one lens 60, the aberration when using a plurality of lenses and the decrease in color reproducibility can be suppressed, and at the same time, the laser module 100 can be downsized. Realized.

  FIG. 6 is an exploded perspective view of the laser module according to the first modification of the first embodiment. As illustrated in FIG. 6, in the laser module 110 according to the first modification of the first embodiment, a film 34 that suppresses reflection of laser light emitted from the laser elements 12 a to 12 c is provided on the side surfaces 42 and 44 of the housing 10. ing. The film 34 is formed of, for example, an AR (Anti-Reflection) sheet in which a dielectric material is laminated by vapor deposition or sputtering, or a light absorption sheet using a continuous fine porous resin. Since other configurations are the same as those of the first embodiment, the description thereof is omitted.

  As in the first modification of the first embodiment, the film 34 may be provided on the side surfaces 42 and 44 of the housing 10. Thereby, the stray light of the laser beam radiate | emitted from laser element 12a-12c can be suppressed. Moreover, the incidence of light from the outside can also be suppressed. The film 34 is flat on the side surfaces 42 and 44 of the casing 10 so that the heat dissipation and the suppression of stray light are almost the same even when fixed to an external component by any of the fixing portions 18 of the side surfaces 42 and 44 of the casing 10. It is preferable to be provided symmetrically with respect to 30.

  In the laser module according to the first embodiment and the first modification of the first embodiment, the case where the laser elements 12a to 12c that oscillate red, green, and blue laser beams are illustrated as an example, but laser beams with other wavelengths are oscillated. It is also possible to have three or more laser elements. Further, in the first embodiment and the first modification of the first embodiment, the case of the image projection apparatus is shown as an example of the apparatus provided with the laser module. However, other apparatuses may be used.

  Although the embodiments of the present invention have been described in detail above, the present invention is not limited to such specific embodiments, and various modifications and changes can be made within the scope of the gist of the present invention described in the claims. It can be changed.

DESCRIPTION OF SYMBOLS 10 Housing | casing 12a-12c Laser element 14a, 14b Dichroic prism 16 Mirror 18 Fixed part 20a, 20b Light receiving element 22 Space 24, 26 Hole 28 Light emitting point 30 Plane 32 Focus 34 Film 40 Front 42, 44 Side 46 Back 48 Upper surface 50 Lower surface 60 Lens 62 Mirror 64 Scanning Mirror 66 Projection Mirror 68 Image Input Unit 70 Control Unit 72 Glasses Vine 74 Glasses Lens 76 Laser Light 78 Mounting Unit 80 Eyeball 82 Retina 84 Pupil 86 Lens 88 Cornea 90-95 Light-Receiving Area 100, 110 Laser Module 500 image projector

Claims (10)

A plurality of laser elements having different oscillation wavelengths;
A housing that is assembled with the plurality of laser elements and is symmetrical with respect to a plane formed by light emitting points of the plurality of laser elements;
An optical element that is assembled to the housing, receives laser light from the plurality of laser elements, synthesizes the laser light, and emits the laser light to the front side that intersects the plane of the housing;
A laser module comprising: fixing portions provided symmetrically with respect to the plane on both side surfaces of the casing located on both sides of the plane, and fixed to external parts.   2. The laser module according to claim 1, wherein the fixing portion is provided higher than a region other than the fixing portion on both side surfaces of the housing. A light receiving element that is assembled to the housing and monitors the intensity of the laser light emitted by the plurality of laser elements;
The laser module according to claim 1, wherein the optical element and the light receiving element are assembled to the casing in a symmetrical shape with respect to the plane.   The laser module according to claim 3, wherein the plurality of laser elements, the optical element, and the light receiving element are located between both side surfaces of the casing and are assembled to the casing. The housing has a frame shape in which a space is provided inside,
The plurality of laser elements are assembled to the housing so as to emit the laser light toward the space,
5. The laser module according to claim 1, wherein the optical element is located in the space and is assembled to the housing. 6.   The laser module according to any one of claims 1 to 5, wherein the laser light emitted from the plurality of laser elements and passed through the optical element is condensed at the same position outside the housing by a lens. .   The laser module according to any one of claims 1 to 6, wherein the laser light emitted from the plurality of laser elements is incident on the optical element without passing through a lens.   The laser module according to claim 1, further comprising a film that is provided on both side surfaces of the housing and suppresses reflection of light. A laser module according to any one of claims 1 to 8,
A scanning optical member that scans the laser light emitted from the laser module;
An image projection apparatus comprising: a projection optical member that irradiates a user's retina with the laser light scanned by the scanning optical member and projects an image on the retina. The image projection device has a pair of vines having a shape of glasses and having an attachment portion to which the laser module can be attached,
The plurality of laser elements when the fixing portion on one side surface of both sides of the housing constituting the laser module is attached to the attachment portion of one of the pair of vines. The fixing portion on the other side surface of the two side surfaces of the housing constituting the laser module is attached to the distance from the attachment portion of the one vine of the light emitting point and the attachment portion of the other vine. The image projection apparatus according to claim 9, wherein the distance from the attachment portion of the other temple of the light emitting points of the plurality of laser elements is equal.

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