MICROLENS ARRAY AND OPTICAL SYSTEM INCLUDING THE SAME

US 20170074481A1
Filed: 11/23/2016
Published: 03/16/2017
Est. Priority Date: 05/27/2014
Status: Active Grant

First Claim

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1. A microlens array including N microlenses arranged in a predetermined direction on an x-y plane, wherein a projection onto the x-y plane of the lens vertex of each microlens is arranged in the vicinity of a lattice point of a reference lattice on the x-y plane, the lattice spacing of the reference lattice in the predetermined direction being D (millimeters), and when a boundary between microlenses is referred to as a side of a lens, a distance between two sides facing each other is approximately equal to D, andwherein a distance between a projection onto the x-y plane of a lens vertex i and a projection onto the x-y plane of a side between the lens vertex i and a lens vertex i+1 is
D/2+ε

_i

and for the N microlenses,

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Abstract

A microlens array includes N microlenses arranged in a predetermined direction on an x-y plane. A projection onto the x-y plane of the vertex of each microlens is arranged in the vicinity of a lattice point of a reference lattice on the x-y plane, the lattice spacing of the reference lattice in the predetermined direction being D/M (millimeters) where M is a positive integer. A distance between two sides of a lens facing each other is approximately equal to D, and a distance between the projection onto the x-y plane of the vertex of the lens and the projection onto the x-y plane of a side of the lens is D/2+εi. Letting n represent the refractive index of the material of each microlens and letting f (millimeters) represent the focal length of each microlens, the following relationships are satisfied.

$\frac{0.0042}{D} < \frac{D}{2 f} = \frac{D (n - 1)}{2 R}$ $0.0048 \sqrt{f} {1 + {(D / 2 f)}^{2}} < σ < 0.014 \sqrt{f} {1 + {(D / 2 f)}^{2}}$ $σ^{2} = \sum_{i = 1}^{N} \frac{{(ɛ_{i} - \overline{ɛ})}^{2}}{N}$ $\overline{ɛ} = \sum_{i = 1}^{N} \frac{ɛ_{i}}{N} = 0$

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18 Claims

1. A microlens array including N microlenses arranged in a predetermined direction on an x-y plane, wherein a projection onto the x-y plane of the lens vertex of each microlens is arranged in the vicinity of a lattice point of a reference lattice on the x-y plane, the lattice spacing of the reference lattice in the predetermined direction being D (millimeters), and when a boundary between microlenses is referred to as a side of a lens, a distance between two sides facing each other is approximately equal to D, andwherein a distance between a projection onto the x-y plane of a lens vertex i and a projection onto the x-y plane of a side between the lens vertex i and a lens vertex i+1 is
D/2+ε
- _i
  
  and for the N microlenses,
- View Dependent Claims (2, 3, 4, 5, 6, 7, 8, 9, 10, 11)
- - 2. A microlens array according to claim 1, wherein in the x-y plane, a boundary between the lens vertex i and the lens vertex i+1, which are adjacent to each other in the predetermined direction, is the perpendicular bisector of the line connecting the lens vertex i and the lens vertex i+1, or an amount of displacement of the boundary from the perpendicular bisector is negligible.
  - 3. A microlens array according to claim 1, wherein the reference lattice is rectangular or hexagonal.
  - 4. A microlens array according to claim 1, wherein a projection onto the x-y plane of the vertex of each microlens is displaced by η
    - _iin the predetermined direction from the corresponding lattice point so as to generate ε
      
      i.
  - 5. A microlens array according to claim 4, wherein the predetermined direction is x and y directions, the reference lattice on the x-y plane is rectangular, the lattice spacing D in the x direction being represented by Dx and the lattice spacing D in the y direction being represented by Dy, and a projection onto the x-y plane of the vertex of each microlens is displaced by (η
    - _xi, η
      
      _yi) from the corresponding lattice point where η
      
      _xirepresents η
      
      _iin the x direction and η
      
      _yirepresents η
      
      _iin the y direction.
  - 6. A microlens array according to claim 1, wherein the predetermined direction is x and y directions, the reference lattice on the x-y plane is rectangular in the x and y directions, and in the vicinity of the center of each of the microlenses, the curvature radius in the x direction is Rx (millimeters) and the curvature radius in the y direction is Ry (millimeters).
  - 7. A microlens array according to claim 1, wherein the relationship
  - 8. A microlens array according to claim 1, wherein the relationship
    0.0064√
    - {square root over (f)}{1+(D/2f)²}<
      
      σ
      
      <
      
      0.014√
      
      {square root over (f)}{1+(D/2f)²}is further satisfied.
  - 9. A microlens array according to claim 1, wherein the vertex positions of plural microlenses are displaced with respect to one another in the direction that is perpendicular to the x-y plane so as to weaken a dark spot.
  - 10. A microlens array according to claim 9, wherein the vertex positions of microlenses are uniformly distributed in the direction perpendicular to the x-y plane in the range from 0 to 0.551(n−
    - 1) (micrometers) with respect to a predetermined value of thickness of the microlens that is a distance from the vertex to the bottom of the microlens array.
  - 11. A microlens array according to claim 1, wherein when the maximum value of the absolute value of ε
    - i is represented by |ε
      
      _i|_max, the relationship
      |ε
      
      _i|_max<
      
      3σ
      
      is satisfied.

12. An optical system including a light source emitting lights, the minimum wavelength of the lights being λ
- (micrometers), and a microlens array configured to diverge the lights from the light source,wherein the microlens array includes N microlenses arranged in a predetermined direction on an x-y plane, a projection onto the x-y plane of the lens vertex of each microlens is arranged in the vicinity of a lattice point of a reference lattice on the x-y plane, the lattice spacing of the reference lattice in the predetermined direction being D (millimeters), and when a boundary between microlenses is referred to as a side of a lens, a distance between two sides facing each other is approximately equal to D, andwherein a distance between a projection onto the x-y plane of a lens vertex i and a projection onto the x-y plane of a side between the lens vertex i and a lens vertex i+1 is
  D/2+ε
  
  _i
  
  and for the N microlenses,
- View Dependent Claims (13, 14, 15, 16, 17, 18)
- - 13. An optical system according to claim 12, wherein in the x-y plane, a boundary between the lens vertex i and the lens vertex i+1, which are adjacent to each other in the predetermined direction, is the perpendicular bisector of the line connecting the lens vertex i and the lens vertex i+1, or an amount of displacement of the boundary from the perpendicular bisector is negligible.
  - 14. An optical system according to claim 12, wherein in the microlenses of the microlens array, the relationship
  - 15. An optical system according to claim 12, wherein in the microlenses of the microlens array, the relationship
    0.0064√
    - {square root over (f)}{1+(D/2f)²}<
      
      σ
      
      <
      
      0.014√
      
      {square root over (f)}{1+(D/2f)²}further satisfied.
  - 16. An optical system according to claim 12, wherein the vertex positions of plural microlenses are displaced with respect to one another in the direction that is perpendicular to the x-y plane so as to weaken a dark spot.
  - 17. An optical system according to claim 16, wherein the vertex positions of microlenses are uniformly distributed in the direction perpendicular to the x-y plane in the range from 0 to λ
    - /(n−
      
      1) with respect to a predetermined value of thickness of the microlens that is a distance from the vertex to the bottom of the microlens array.
  - 18. An optical system according to claim 16, wherein the optical system includes light sources of n different values of wavelength λ
    - 1, λ
      
      2, . . . and λ
      
      n, andletting λ
      
      multi represent a constant that is determined such that letting Remi represent the reminder when λ
      
      multi is divided by λ
      
      i, the relationship
      Remi<
      
      (λ
      
      i/10) or Remi>
      
      (9λ
      
      i/10)is satisfied for any i, the vertex positions of the microlenses are uniformly distributed in the direction perpendicular to the x-y plane in the range from 0 to λ
      
      multi/(n−
      
      1) with respect to a predetermined value of thickness of the microlens that is a distance from the vertex to the bottom of the microlens array.

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Current Assignee
Nalux Co., Ltd (Nalux Holdings Corp.)
Original Assignee
Nalux Co., Ltd (Nalux Holdings Corp.)
Inventors
OKANO, Masato, NISHIO, Yukinobu, SEKI, Daisuke, FUJIMURA, Kayoko, KUWAGAITO, Tomohito

Granted Patent

US 10,443,811 B2
Time in Patent Office

Days
Field of Search
US Class Current

1/1
CPC Class Codes

F21V 5/004   using microlenses

F21Y 2115/30   Semiconductor lasers

G02B 19/0014   at least one surface having...

G02B 27/425   in illumination systems mas...

G02B 3/0043   Inhomogeneous or irregular ...

MICROLENS ARRAY AND OPTICAL SYSTEM INCLUDING THE SAME

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MICROLENS ARRAY AND OPTICAL SYSTEM INCLUDING THE SAME

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Abstract

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