JP5605382B2 - Optical module - Google Patents

Description

  The present invention relates to an optical module provided with a lens component.

  An optical module that converts an electrical signal into an optical signal or converts an optical signal into an electrical signal is known. Such an optical module includes an optical fiber, a photoelectric conversion element, and a lens component that guides light from the optical fiber to the photoelectric conversion element (see, for example, Patent Documents 1 and 2).

Japanese Patent No. 4805657 JP 2009-163212 A

  In such an optical module, for example, it is known that light emitted from the lens unit and incident on the light receiving element is reflected and incident on the lens component as reflected return light, thereby degrading the optical signal incident on the lens component. It has been.

  With regard to this optical signal degradation, the technique described in Patent Document 1 proposes to devise the lens shape of the lens unit so that the reflected return light from the light receiving element is not coupled to the optical fiber. However, in the method described in Patent Document 1, the lens shape becomes special and the manufacturing cost increases.

  In the technique described in Patent Document 2, the photoelectric conversion device and the light are arranged so that the optical coupling efficiency (coupling loss) is within an allowable value by using the positioning uneven portions provided in the photoelectric conversion device and the optical coupling element. The attachment position in the XY direction (a plane perpendicular to the optical axis) of the coupling element is defined. However, the method described in Patent Document 2 does not mention the influence of reflected return light. Further, it is stated that the positional deviation in the Z-axis direction (optical axis direction) does not require strict management from the viewpoint of coupling loss (see paragraph [0066]).

  An object of the present invention is to provide an optical module that can be manufactured at a low cost with little deterioration in communication quality due to reflected return light.

The optical module of the present invention capable of solving the above problems includes a transmission-side optical fiber, a light-emitting element, a first lens portion facing the transmission-side optical fiber, and a second lens portion facing the light-emitting element. In a lens component that optically connects the light emitting element and the transmission side optical fiber, including a transmission side optical system including:
The numerical aperture of the first lens unit is NA1, the numerical aperture of the second lens unit is NA2, the magnification of the lens component is M, the radius of the light emitting surface of the light emitting element is Φ1, and the maximum mounting position error of the light emitting element is When d1, the core diameter of the transmission side optical fiber is Φ2, and the mounting position maximum error of the transmission side optical fiber is d2, the following inequalities (1) to (3) are established.
The reflected return light intensity is 10 dB or more lower than the case where the light coupling efficiency between the light emitting element and the transmission side optical fiber is the maximum, and the light coupling efficiency is the maximum. In this case, the decrease in optical coupling efficiency is 1 dB or less.
MΦ1 <Φ2 (1)
M (d1 + Φ1 / 2) <Φ2 / 2-d2 (2)
NA1 / M <NA2 (3)
In addition, it is preferable that the tip of the transmission-side optical fiber is located at a position offset from the focal position of the first lens unit by 50 μm to 100 μm in the optical axis direction.

  The optical module further includes a light receiving side optical system including a receiving side optical fiber, a light receiving element, a third lens part facing the receiving side optical fiber, and a fourth lens part facing the light receiving element, The overall optical coupling efficiency in the transmission side optical system and the reception optical system is preferably such that the decrease in optical coupling efficiency with respect to maximum efficiency is 3 dB or more and 6 dB or less.

  In the optical module, the third lens unit is disposed such that the receiving-side optical fiber is positioned at a focal position, and the fourth lens unit is configured such that the light receiving element is positioned at the focal position. It is preferable that at least one of the third lens portion and the fourth lens portion is an aspheric lens.

  In the optical module, the first lens unit and the third lens unit are formed on a fiber side connection surface, and the second lens unit and the fourth lens unit are formed on an element side connection surface, The third lens unit is disposed so that the receiving-side optical fiber is positioned at the focal position, and the fourth lens unit is disposed so that the light receiving element is positioned at the focal position, and the second lens It is preferable that the portion is disposed so that the light emitting element is located at the focal position, and the first lens portion is disposed at a position offset in the optical axis direction with respect to the third lens portion.

  According to the present invention, it is possible to suppress deterioration in communication quality due to reflected return light reflected by the end face of the transmission side optical fiber by offsetting the focal position of the first lens unit by a predetermined amount in the optical axis direction. Accordingly, it is possible to suppress deterioration in communication quality due to reflected return light while suppressing an increase in manufacturing cost due to molding the lens component into a complicated and special shape.

It is a perspective view which shows the optical module provided with the lens array component which concerns on this embodiment. It is a perspective view which shows the state which removed the resin housing. It is a perspective view which shows the state which removed the housing. (A) is the figure which looked at the board | substrate shown in FIG. 3 from the top, (b) is the figure which looked at the board | substrate shown in FIG. 3 from the side. It is a top view of the lens array component and connector component which comprise the optical module which concerns on this embodiment. It is sectional drawing which follows the width direction of the lens array component which comprises the optical module which concerns on this embodiment. It is AA sectional drawing of the lens array component of FIG. 5, and a connector component which comprise the optical module which concerns on this embodiment. It is BB sectional drawing of the lens array component of FIG. 5, and a connector component which comprise the optical module which concerns on this embodiment. It is a graph which shows the relationship between the offset amount from the focus position of a transmission side fiber side lens part, and reflected reflected light intensity. It is a graph which shows the relationship between the offset amount from the focus position of a transmission side fiber side lens part, and optical coupling efficiency. It is a graph which shows the relationship between the offset amount from the focus position of a transmission side fiber side lens part, and optical coupling efficiency.

Hereinafter, an example of an embodiment of an optical module according to the present invention will be described with reference to the drawings.
The optical module according to the present embodiment is used for signal (data) transmission in optical communication technology or the like, and is electrically connected to an electronic device such as a personal computer to be connected to input / output electric signals. An optical signal is transmitted after being converted into a signal.

As shown in FIGS. 1 to 3, the optical module 1 is attached to an end of an optical cable 3. The optical cable 3 is a single-core or multi-core optical cable.
The optical cable 3 includes a plurality (four in this case) of optical fiber cores (optical elements) 7, a resin sheath 9 covering the optical fiber core 7, and the optical fiber core 7 and the sheath 9. And a metal braid 13 interposed between the outer cover 9 and the tensile strength fiber 11. That is, in the optical cable 3, the optical fiber core wire 7, the tensile strength fiber 11, the metal braid 13, and the jacket 9 are arranged in this order from the center toward the outside in the radial direction.

  As the optical fiber core 7, an optical fiber (AGF) whose core and clad are quartz glass, a plastic optical fiber (HPCF: Hard Plastic Clad Fiber) whose clad is made of hard plastic, and the like can be used. When a thin HPCF having a glass core diameter of 80 μm is used, it is difficult to break even if the optical fiber core wire 7 is bent to a small diameter.

  The jacket 9 is made of, for example, PVC (poly vinyl chloride) which is a non-halogen flame retardant resin. The outer diameter of the jacket 9 is about 4.2 mm. The tensile strength fiber 11 is, for example, an aramid fiber, and is built in the optical cable 3 in a bundled state.

 The metal braid 13 is made of, for example, a tin-plated lead wire, and has a braid density of 70% or more and a knitting angle of 45 ° to 60 °. The outer diameter of the metal braid 13 is about 0.05 mm.

 The optical module 1 includes a housing 20, an electrical connector 22 provided on the front end (tip) side of the housing 20, and a substrate 24 accommodated in the housing 20.

 The housing 20 includes a metal housing 26 and a resin housing 28. The metal housing 26 includes a housing member 30 and a fixing member 32 that is connected to the rear end portion of the housing member 30 and fixes the optical cable 3.

 The housing member 30 is a cylindrical hollow member having a substantially rectangular cross section. The accommodating member 30 defines an accommodating space for accommodating the substrate 24 and the like. An electrical connector 22 is provided on the front end side of the housing member 30, and a fixing member 32 is connected to the rear end side of the housing member 30.

 The fixing member 32 includes a plate-like base portion 34, a cylindrical portion (not shown) protruding toward the optical cable 3, a pair of first projecting pieces 38 projecting forward from both sides of the base portion 34, and both sides of the base portion 34. A pair of second projecting pieces 40 projecting rearward are provided. The pair of first projecting pieces 38 are respectively inserted from the rear part of the housing member 30 and are in contact with and connected to the housing member 30. A pair of 2nd overhang | projection piece 40 is connected with the boot 46 of the resin housing 28 mentioned later. The fixing member 32 includes a base portion 34, a cylindrical portion, a first overhanging piece 38, and a second overhanging piece 40 that are integrally formed of sheet metal.

 The tube portion has a substantially cylindrical shape and is provided so as to protrude rearward from the base portion 34. The tube portion holds the optical cable 3 in cooperation with caulking (not shown). Specifically, after the outer cover 9 is peeled off, the optical fiber core wire 7 of the optical cable 3 is inserted into the cylindrical portion, and the tensile fiber 11 is disposed along the outer peripheral surface of the cylindrical portion. And caulking is arrange | positioned on the tensile strength fiber 11 arrange | positioned on the outer peripheral surface of a cylinder part, and caulking is crimped. Thereby, the tensile strength fiber 11 is sandwiched and fixed between the cylindrical portion and the caulking ring, and the optical cable 3 is held and fixed to the fixing member 32.

 The end of the metal braid 13 of the optical cable 3 is joined to the base 34 with solder. Specifically, the metal braid 13 is disposed so as to cover the outer periphery of the caulking ring (cylinder portion) in the fixing member 32, and its end is extended to one surface (rear surface) of the base 34 and is soldered. It is joined. Thereby, the fixing member 32 and the metal braid 13 are thermally connected. Further, the fixing member 32 is coupled to the rear end portion of the accommodating member 30, whereby the accommodating member 30 and the fixing member 32 are physically and thermally connected. That is, the housing member 30 and the metal braid 13 of the optical cable 3 are thermally connected.

 The resin housing 28 is made of, for example, a resin material such as polycarbonate and covers the metal housing 26. The resin housing 28 includes an exterior housing 44 and a boot 46 connected to the exterior housing 44. The exterior housing 44 is provided so as to cover the outer surface of the housing member 30. The boot 46 is connected to the rear end portion of the exterior housing 44 and covers the fixing member 32 of the metal housing 26. The rear end portion of the boot 46 and the outer cover 9 of the optical cable 3 are bonded by an adhesive (not shown).

 The electrical connector 22 is a part that is inserted into a connection target (such as a personal computer) and is electrically connected to the connection target. The electrical connector 22 is disposed on the front end side of the housing 20 and protrudes forward from the housing 20. The electrical connector 22 is electrically connected to the substrate 24 by a contact 22a.

  The board | substrate 24 is accommodated in the accommodation space of the metal housing 26 (accommodating member 30). Further, as shown in FIGS. 4A and 4B, a control semiconductor 50 and a light emitting / receiving element 52 are mounted on the substrate 24. The substrate 24 electrically connects the control semiconductor 50 and the light emitting / receiving element 52. The substrate 24 has a substantially rectangular shape in plan view and has a predetermined thickness. The substrate 24 is an insulating substrate such as a glass epoxy substrate or a ceramic substrate, and circuit wiring is formed on the surface or inside thereof using gold (Au), aluminum (Al), copper (Cu), or the like. The control semiconductor 50 and the light emitting / receiving element 52 constitute a photoelectric conversion unit.

  The control semiconductor 50 includes a drive IC (Integrated Circuit) 50a, a CDR (Clock Data Recovery) device 50b that is a waveform shaper, and the like. The control semiconductor 50 is disposed on the front end side of the surface 24 a in the substrate 24. The control semiconductor 50 is electrically connected to the electrical connector 22.

  The light receiving / emitting element 52 includes a plurality (here, two) of light emitting elements 52a and a plurality (here, two) of light receiving elements 52b. The light emitting element 52a and the light receiving element 52b are disposed on the substrate 24 on the rear end side of the surface 24a. As the light emitting element 52a, for example, a light emitting diode (LED: Light Emitting Diode), a laser diode (LD: Laser Diode), a surface emitting laser (VCSEL: Vertical Cavity Surface Emitting LASER), or the like can be used. For example, a photodiode (PD) can be used as the light receiving element 52b.

  The light emitting / receiving element 52 is optically connected to the optical fiber core wire 7 of the optical cable 3. Specifically, as shown in FIG. 4B, a lens array component (lens component) 55 is disposed on the substrate 24 so as to cover the light emitting / receiving element 52 and the driving IC 50a.

  The lens array component 55 is connected to a connector component 54 attached to the end of the optical fiber core wire 7. The lens array component 55 inputs the light emitted from the light emitting element 52a to the optical fiber core 7 and inputs the light transmitted through the optical fiber core 7 to the light receiving element 52b. Thereby, the optical fiber core wire 7 and the light emitting / receiving element 52 are optically coupled.

  In the optical module 1 having the above configuration, an electrical signal is input from the electrical connector 22 to the control semiconductor 50 via the wiring of the substrate 24. The electric signal input to the control semiconductor 50 is output from the control semiconductor 50 to the light emitting / receiving element 52 through the wiring of the substrate 24 after the level adjustment and waveform shaping by the CDR device 50b. The light emitting / receiving element 52 that receives the electric signal converts the electric signal into an optical signal, and emits the optical signal from the light emitting element 52 a to the optical fiber core wire 7 through the lens array component 55.

  The optical signal transmitted through the optical cable 3 is incident on the light receiving element 52b through the lens array component 55. The light emitting / receiving element 52 converts the incident optical signal into an electrical signal, and outputs the electrical signal to the control semiconductor 50 via the wiring of the substrate 24. In the control semiconductor 50, the electrical signal is output to the electrical connector 22 after predetermined processing is performed on the electrical signal.

  The lens array component 55 will be described with reference to FIGS. FIG. 5 is a plan view of the lens array component 55 and the connector component 54 constituting the optical module 1 according to this embodiment, and FIG. 6 is along the width direction of the lens array component 55 constituting the optical module according to this embodiment. 7 is a cross-sectional view of the lens array component 55 and the connector component 54 of FIG. 5 constituting the optical module 1 according to the present embodiment, and FIG. 8 is a diagram of the optical module 1 according to the present embodiment. FIG. 6 is a cross-sectional view of the lens array component 55 and the connector component 54 of FIG.

  As shown in FIGS. 5 to 8, the lens array component 55 has a fiber-side connection surface 55 a that faces the optical fiber core wire 7. A plurality of fiber side lens portions 62 are formed on the fiber side connection surface 55a. The lens array component 55 has an element-side connection surface 55 b that faces the light emitting / receiving element 52. A plurality of element side lens portions 65 are formed on the element side connection surface 55b.

  The plurality of fiber side lens units 62 and the plurality of element side lens units 65 are arranged side by side in one direction and have different optical axes. The lens array component 55 has a reflecting surface 67. The reflection surface 67 optically connects the fiber side lens unit 62 and the element side lens unit 65 having different optical axes.

  The fiber side lens unit 62 and the element side lens unit 65 are formed of collimating lenses that convert incident light into parallel light and collect and output the parallel light. Such a lens array component 55 is integrally formed by resin injection molding.

  Of the four fiber side lens portions 62, two of them are transmission fiber side lens portions (first lens portions) 62A facing the transmission side optical fiber core wire 7a of the optical signal. The other two are a receiving fiber side lens portion (third lens portion) 62B facing the optical signal receiving side optical fiber core wire 7b.

  Of the four element side lens portions 65, two of them are a transmitting element side lens portion (second lens portion) 65A facing the light emitting element 52a. The other two are a receiving element side lens portion (fourth lens portion) 65B facing the light receiving element 52b.

  The lens array component 55 has a plate-like portion 61 extending in a direction intersecting with the arrangement direction of the fiber side lens portions 62. The plate-like portion 61 is provided on the side opposite to the fiber side lens portion 62 with respect to the reflecting surface 67. The plate-like portion 61 is formed so as to extend in a direction intersecting with the arrangement direction of the element side lens portions 65. The lens array component 55 has a pair of leg portions 72 formed on both sides of the plate-like portion 61 and extending from the rear end side to the front end side.

  The lens array component 55 has a front end rib portion 73 formed thicker than the plate-like portion 61 on the front end side. Further, a rear end rib portion 74 is formed on the rear end side of the plate-like portion 61 over the width direction.

  Further, the front end rib portion 73 of the lens array component 55 is formed with guide pins 69 protruding toward the connector component 54 side in the vicinity of both ends thereof. These guide pins 69 can be inserted into positioning holes 71 formed in the connection end face of the connector component 54 as shown in FIG. Then, by inserting these guide pins 69 into the positioning holes 71, the connector component 54 is positioned with respect to the lens array component 55, and the optical fiber core wire 7 is disposed at a position facing the fiber side lens portion 62. The

  Further, the plate-like portion 61 has a concave portion 81 formed on the upper surface thereof. The concave portion 81 is an inclined surface whose wall on the connection side is gradually inclined upward toward the connection side, and this inclined surface forms a part of the reflection surface 67. On the upper surface of the plate-like portion 61, a flat portion 83 formed in a planar shape is formed on the side opposite to the connection side of the recess 81. The flat portion 83 is formed so as to be adjacent to the reflecting surface 67 through the concave portion 81.

  As shown in FIG. 6, the lens array component 55 has a pair of leg portions 72 formed on both sides of the plate-like portion 61 and extending from the rear end side to the front end side. The leg portion 72 includes a positioning portion 75 that protrudes toward the circuit board 24 and an adhesive portion 76 that is adjacent to the positioning portion 75. The positioning part 75 is fixed in contact with the circuit board 24 on the positioning surface 75a.

  The leg portion 72 separates the element side lens portion 65 of the lens array component 55 from the circuit board 24 by a predetermined length, and is provided at a position facing the element side lens portion 65 with the element side lens portion 65 interposed therebetween. The positioning portion 75 is provided at the tip of the leg portion 72 on the circuit board 24 side, and protrudes from the adhesive portion 76 toward the circuit board 24. As a result, only the positioning surface 75 a comes into contact with the circuit board 24 at the front end surface of the leg portion 72 on the circuit board 24 side.

  In addition, a gap is generated between the bonding portion 76 and the circuit board 24 in a state where the positioning surface 75 a of the positioning portion 75 is in contact with the circuit board 24. This gap is an adhesive filling space S. The adhesive filling space S is filled with an adhesive. The lens array component 55 is bonded and fixed to the circuit board 24 with this adhesive.

  The circuit board 24 on which the lens array component 55 is mounted is provided with a first metal pad 78 and a second metal pad 79 made of a metal thin film on the mounting surface side. The second metal pads 79 are formed at positions corresponding to the positioning portions 75 of the lens array component 55 so as to face each other with the first metal pad 78 interposed therebetween. The light emitting / receiving element 52 is mounted on the first metal pad 78.

  Further, only the positioning portion 75 of the lens array component 55 is in contact with the second metal pad 79, and the adhesive is filled with an adhesive between the adhesive portion 76 of the lens array component 55 and the second metal pad 79. Only S is filled. Thereby, it is possible to prevent the adhesive from being interposed between the second metal pad 79 and the positioning portion 75 of the lens array component 55. That is, when the positioning surface 75a comes into contact with the circuit board 24, the distance between the light emitting element 52a and the element side lens portion 65 is defined to be a predetermined amount. Further, the adhesive is filled in the adhesive filling space S, and even if the adhesive is thermally expanded, the separation distance between the light emitting element 52a and the element side lens portion 65 is hardly affected. For this reason, the optical coupling efficiency is unlikely to fluctuate even when the environmental temperature changes.

  In the lens array component 55 as described above, the optical signal from the light emitting element 52a is incident from the transmitting element side lens portion 65A and reflected by the reflecting surface 67, whereby the optical path is changed to the connection side, and the plate-like portion 61 is obtained. Is transmitted from the transmitting fiber side lens portion 62A and reaches the transmitting side optical fiber core wire 7a. Such a transmission side optical fiber 7a, a light emitting element 52a, a transmission fiber side lens portion 62A (first lens portion) facing the transmission side optical fiber core 7a, and a transmission facing the light emitting element 52a. A region including the element side lens unit 65A (second lens unit) is referred to as a transmission side optical system.

Further, the optical signal from the receiving side optical fiber core wire 7 b enters from the receiving fiber side lens part 62 B, is transmitted along the extending direction of the plate-like part 61, and is reflected by the reflecting surface 67 so that the optical path is changed. It is changed downward, and is emitted from the receiving element side lens unit 65B and reaches the light receiving element 52b. Such a receiving side optical fiber core 7b, a light receiving element 52b, a receiving fiber side lens part 62B (third lens part) facing the receiving side optical fiber core line 7b, and a receiving side facing the light receiving element 52b. A region including the element side lens unit 65B (fourth lens unit) is referred to as a reception side optical system.
As a result, an optical signal is transmitted between the optical fiber core wire 7 and the light emitting / receiving element 52 via the lens array component 55.

  Next, the mounting accuracy of the lens array component 55 with respect to the substrate 24 and the connector component 54 will be described. More specifically, the amount of displacement of the lens portions 62 and 65 of the lens array component 55 with respect to the light receiving / emitting element 52 or the end face of the optical fiber core wire 7 will be described.

First, the amount of deviation from the ideal mounting position in the direction orthogonal to the optical axis between the lens portions 62A and 65A in the transmission side optical system and the end faces of the light emitting element 52a and the transmission side optical fiber core wire 7a will be described.
The amount of deviation in this direction is, for example, the amount of deviation of the transmission side optical fiber core 7a with respect to the transmission fiber side lens portion 62A, and the optical coupling efficiency between the transmission fiber side lens portion 62A and the transmission side optical fiber core wire 7a. Is set so that the decrease in the optical coupling efficiency with respect to the maximum efficiency is 1 dB or less with respect to the ideal mounting position where the maximum efficiency is shown. Further, in the optical path on the transmission side that passes through the transmission fiber side lens unit 62A and the transmission element side lens unit 65A, the reflected return light intensity is the highest in the optical coupling efficiency between the light emitting element 52a and the transmission side optical fiber core wire 7a. The amount of deviation is set to be 10 dB or more smaller than the case.

First, the latter, that is, from the viewpoint of reflected return light intensity will be described. FIG. 9 shows the end face of the transmission-side optical fiber 7a having a core diameter φ of 70 mm at a position offset in the optical axis direction from the focal position 62As of the transmission-fiber-side lens 62A. Is a graph showing the relationship between the offset amount in the optical axis direction from the focal position 62As of the transmitting fiber side lens portion 62A and the reflected return light intensity when is positioned. The horizontal axis represents the offset amount [mm], and the vertical axis represents the reflected return light intensity [dB].
When the offset amount is 0 mm, that is, when the offset amount is disposed at the focal position 62As of the transmitting fiber side lens portion 62A, the optical coupling efficiency between the light emitting element 52a and the transmitting side optical fiber core wire 7a is maximized. It can be seen that the reflected return light intensity decreases as the offset amount increases compared to when the offset amount is 0 mm. When the offset amount is 50 μm (0.05 mm) or more, the reflected return light intensity is 10 dB or more smaller than that when the optical coupling efficiency is maximum.

FIG. 10 shows a transmission fiber when the end surface of the transmission side optical fiber core 7a having a core diameter φ of 70 mm is positioned at a position offset in the optical axis direction from the focal position 62As of the transmission fiber side lens portion 62A. It is a graph which shows the relationship between the offset amount of the optical axis direction from the focus position 62As of the side lens part 62A, and optical coupling efficiency. The horizontal axis represents the offset amount [mm], and the vertical axis represents the optical coupling efficiency [dB].
When the offset amount is 0 mm, that is, when the end surface of the transmission side optical fiber 7a is arranged at the focal position 62As of the transmission fiber side lens portion 62A, the light of the light emitting element 52a and the transmission side optical fiber 7a. The coupling efficiency is maximum. Compared to when the offset amount is 0 mm, the optical coupling efficiency decreases as the offset amount increases. If the offset amount is 100 μm (0.1 mm) or less, the decrease in the optical coupling efficiency with respect to the maximum efficiency is 1 dB or less.

  FIG. 11 shows, for comparison, an offset amount [μm] in the optical axis direction from the focal position 62As of the transmission fiber side lens portion 62A when the transmission side optical fiber core wire 7a having a core diameter of φ62.5 μm is used. It is a graph which shows the relationship between optical coupling efficiency [dB]. In this case, if the offset amount is 100 μm (0.1 mm) or less, the decrease in the optical coupling efficiency with respect to the maximum efficiency may exceed 1 dB. Therefore, the core diameter of the optical fiber is 70 μm (0.07 mm) or more. Preferably there is.

  As described above, when the offset amount is 50 μm to 100 μm, the reflected return light intensity is 10 dB or more smaller than the case where the optical coupling efficiency between the light emitting element 52a and the transmission side optical fiber core 7a is maximum, and the optical coupling efficiency is increased. The decrease in the optical coupling efficiency with respect to the case where the optical coupling efficiency between the light emitting element 52a and the transmission side optical fiber core 7a is maximum is 1 dB or less, and the communication quality is extremely good.

  In the simulation as described above, the positional deviation of the light emitting element 52a and the transmission side optical fiber core 7a in the in-plane direction perpendicular to the optical axis with respect to the lens array component 55 is not considered. Therefore, in order to obtain the optical module 1 having the optical characteristics as described above, the lens array component 55, the optical fiber core wire 7, the light emitting / receiving element 52, and the like constituting the optical module 1 may be designed as follows.

The numerical aperture of the transmitting fiber side lens portion 62A is NA1,
The numerical aperture of the transmitting element side lens unit 65A is NA2,
The magnification of the lens array component 55 is M,
The radius of the light emitting surface of the light emitting element 52a is Φ1,
The maximum mounting position error of the light emitting element 52a is d1,
The core diameter of the transmission side optical fiber core wire 7a is Φ2,
The mounting position maximum error of the transmission side optical fiber core 7a is d2,
, The following inequalities (1) to (3) are established.

MΦ1 <Φ2 (1)
M (d1 + Φ1 / 2) <Φ2 / 2-d2 (2)
NA1 / M <NA2 (3)

If the inequality (1) is satisfied, the light emitted from the light emitting element 52a can be incident on the transmission side optical fiber core 7a. If the inequality (2) is satisfied, the light emitted from the light emitting element 52a is transmitted even if the light emitting element 52a and the transmission-side optical fiber core wire 7a are most greatly displaced from the ideal mounting position with respect to the lens array component 55. It can enter into the side optical fiber core wire 7a. If the inequality (3) is satisfied, the light from the transmitting element side lens unit 65A can be incident on the end surface of the transmitting fiber side lens unit 62A.
As described above, by establishing the above inequalities (1) to (3), it is possible to suppress the occurrence of coupling loss due to the displacement in the in-plane direction perpendicular to the optical axis, and to realize the optical module 1 having high optical coupling efficiency. it can.

  Therefore, in the optical module of the present embodiment, the tip of the transmission-side optical fiber is located at a position offset by a predetermined amount in the optical axis direction from the focal position of the first lens unit, and the inequalities (1) to (1) to By setting so that (3) is established, it is possible to realize an optical module that has high optical coupling efficiency and can suppress deterioration in communication quality due to reflected return light.

  Next, the relationship between the lens parts 62 and 65 in the receiving side optical system and the end face of the light receiving element 52 or the optical fiber core wire 7 will be described. In this receiving side optical system, the overall optical coupling efficiency in the above transmitting side optical system and the receiving optical system is set so that the decrease in the optical coupling efficiency with respect to the maximum efficiency is 3 dB or more and 6 dB or less. By reducing the optical coupling efficiency in the receiving side optical system in this way, it is possible to maintain good communication quality and reliably prevent exceeding the maximum receivable light intensity of the light receiving element.

Such a receiving-side optical system includes a receiving-side optical fiber core 7b, a light-receiving element 52b, and a receiving-fiber-side lens unit 62B (first lens) that optically connects the receiving-side optical fiber core 7b and the light-receiving element 52b. 3 lens portion) and a receiving element side lens portion 65B (fourth lens portion).
The receiving fiber side lens portion 62B is arranged so that the end surface of the receiving side optical fiber core wire 7b is positioned at the focal position 62Bs. The receiving element side lens unit 65B is arranged so that the light receiving surface of the light receiving element 52b is positioned at the focal position 65Bs.
Further, at least one of the receiving fiber side lens unit 62B and the receiving element side lens unit 65B does not optically couple part of the light emitted from the receiving side optical fiber core wire 7b, so that the light in the receiving side optical system can be reduced. An aspheric lens that reduces the coupling efficiency is preferable. For example, an optical coupling region that optically couples the receiving side optical fiber 7b and the light receiving element 52b is provided at the center of the lens, and non-optical coupling that does not optically couple the receiving side optical fiber 7b and the light receiving element 52b to the outer periphery thereof. A region may be provided.

  Thereby, the receiving fiber side lens unit 62B and the receiving side optical fiber core wire 7b are easily optically connected with a predetermined optical coupling efficiency. That is, when the end face of the receiving optical fiber core 7b is positioned at the focal position 62Bs of the receiving fiber side lens 62B, the receiving optical fiber 7b and the light receiving element 52b are optically coupled with a desired optical coupling efficiency. The receiving-side optical fiber core wire 7b and the light-receiving element 52b can be accurately arranged with respect to the lens array component 55 at the position where the lens array component 55 is placed. For this reason, the transmitting fiber side lens portion 62A has a larger projecting dimension from the fiber side connection surface 55a than the receiving fiber side lens portion 62B, so that high optical coupling efficiency and reflection return are achieved in the transmitting side optical system. A configuration is realized in which light suppression is achieved and a predetermined optical coupling efficiency is obtained in the reception-side optical system.

  By the way, in the optical module 1, the light incident on the transmitting element side lens unit 65A from the light emitting element 52a and emitted from the transmitting fiber side lens unit 62A is reflected by the end face of the transmitting side optical fiber core wire 7a and reflected. The return light may interfere with the light from the light emitting element 52a and the intensity of the light from the light emitting element 52a may be attenuated (reflection attenuation). The reflection attenuation is caused by the light emitting element 52a and the transmitting element side lens unit 65A. Between the lens array component 55 and the end faces of the light emitting / receiving element 52 and the optical fiber core wire 7.

  In order to reduce such reflection attenuation, it is conceivable that the lens shape of the lens portion is devised so that the reflected light from the end face of the transmission side optical fiber core wire 7a does not enter the transmission element side lens portion 65A. However, in this case, the lens portion has a complicated and special shape, and the manufacturing cost of the lens array component 55 increases.

  On the other hand, in the optical module 1 according to the present embodiment, the reflection attenuation is caused by the reflected return light generated between the light emitting element 52a and the transmission side optical fiber 7a in the transmission side optical system of the optical module 1. We focus on the fact that it is dominant. For example, the reflected return light between the light emitting element 52a and the light receiving element 52b is attenuated in the process of transmission, so that the degree of contribution to the deterioration of communication quality is small. Therefore, in this embodiment, the reflection attenuation is improved by adjusting the projecting dimension of the transmitting fiber side lens portion 62A from the fiber side connection surface 55a. Specifically, in the optical path passing through the transmission fiber side lens unit 62A and the transmission element side lens unit 65A, the reflected return light intensity is the highest in the optical coupling efficiency between the light emitting element 52a and the transmission side optical fiber core wire 7a. The transmission fiber side lens is 10 dB or more smaller than the case, and the decrease in the optical coupling efficiency with respect to the case where the optical coupling efficiency of the light emitting element 52a and the transmission side optical fiber 7a is the maximum is 1 dB or less. The end face of the distal end of the transmission side optical fiber 7a is located at a position offset in the optical axis direction from the focal position 62As of the part 62A.

  That is, according to the optical module 1 of the present embodiment, the focal position 62As of the transmission fiber side lens portion 62A is offset in the optical axis direction. Thereby, interference between the reflected light at the end face of the transmission side optical fiber core 7a and the optical signal from the light emitting element 52a is suppressed, and the return loss due to the reflected return light is suppressed. Therefore, it is possible to minimize the positional shift in the direction orthogonal to the optical path, suppress the coupling loss, and suppress the return loss. In addition, while the transmitting side optical system is arranged offset from the focal position in the optical axis direction, the receiving side optical system is arranged at the focal position, and the lens shape is aspherical to obtain a predetermined optical coupling efficiency. By adopting such a configuration, it becomes easy to mount each optical member, and an increase in manufacturing cost can be avoided.

  In the optical path passing through the transmission fiber side lens unit 62A and the transmission element side lens unit 65A, the transmission element side lens unit 65A is disposed such that the light emitting surface of the light emitting element 52a is positioned at the focal position 65As. Yes. As described above, the focal position 62As of the transmission fiber side lens portion 62A is offset in the optical axis direction. As a result, the optical coupling loss is slightly reduced on one side of the optical path on the transmission side. Therefore, in the transmitting element side lens unit 65A on the other side of the optical path, the optical coupling loss is set not to decrease. is there. Thereby, both the optical coupling loss and the return loss of the optical path on the transmission side can be suppressed.

  In this embodiment, the example in which the focal position 62As of the transmission fiber side lens portion 62A is offset in the optical axis direction has been described. However, the transmission side optical fiber core wire is placed at the focal position 62As of the transmission fiber side lens portion 62A. 7a may be arranged so that the focal position 65As of the transmitting element side lens portion 65A is offset from the light emitting surface of the light emitting element 52a in the optical axis direction.

  As described above, in the optical module 1 according to the present embodiment, an optical system that emphasizes reflection attenuation is designed in the optical path on the transmission side, and an optical system that emphasizes coupling loss is designed in the optical path on the reception side. A lens array component 55 that distinguishes the optical path from the optical path on the receiving side is employed.

  Examples of specific design values based on the above design include Examples 1 to 3 shown in Table 1.

  As mentioned above, although this invention was demonstrated using the embodiment, the technical scope of this invention is not limited to the range as described in the said embodiment. It will be apparent to those skilled in the art that various modifications and improvements can be made to the above-described embodiment.

  For example, in the above-described embodiment, an example in which the transmission fiber side lens portion 62A protrudes from the lens array component 55 has been described. However, the transmission fiber side lens portion 62A is configured to be recessed in the lens array component 55. May be. Alternatively, the position of the end face of the optical fiber core wire 7 may be adjusted and shifted from the focal positions of the lens portions 62 and 65 in the optical axis direction. Alternatively, a step is provided on the substrate 24, the light emitting surface of the light emitting element 52a and the light receiving surface of the light receiving element 52b are offset, and the light emitting element 52a is shifted from the focal position 65As of the transmitting element side lens portion 65A in the optical axis direction. It may be arranged at a different position.

  Further, the above-described optical module has a reflected return light intensity that is 10 dB or more smaller than the case where the light coupling efficiency between the light emitting element and the transmission side optical fiber is maximum, and the light coupling efficiency is the light of the light emitting element and the transmission side optical fiber. As a configuration in which the decrease in optical coupling efficiency with respect to the case where the coupling efficiency is maximum is 1 dB or less, the tip of the transmission-side optical fiber is positioned at a position offset in the optical axis direction from the focal position of the first lens unit. However, other forms can also be applied.

  That is, the end face of the transmission side optical fiber or the first end face of the transmission side optical fiber is not disposed at the position offset in the optical axis direction from the focal position of the first lens unit (that is, in a state of being disposed at the focal position). An anti-reflective coating may be applied to the surface of one lens part.

1: optical module, 7a: transmission side optical fiber (transmission side optical fiber), 7b: reception side optical fiber (reception side optical fiber), 52a: light emitting element, 52b: light receiving element, 62A: transmission fiber Side lens part (first lens part), 62As, 62Bs, 65As, 65Bs: focal position, 62B: reception fiber side lens part (third lens part), 65A: transmission element side lens part (second lens part) , 65B: receiving element side lens part (fourth lens part), 55: lens array component (lens part), 55a: fiber side connection surface, 55b: element side connection surface

Claims (5)

A transmission-side optical system including a transmission-side optical fiber, a light- emitting element, a first lens unit facing the transmission-side optical fiber, and a second lens unit facing the light-emitting element ; a reception-side optical fiber; A light-emitting element and a transmission-side optical fiber , each including: an element; a third lens portion facing the reception-side optical fiber; and a reception-side optical system including a fourth lens portion facing the light-receiving element . And in an optical module comprising a lens component for optically connecting the light receiving element and the receiving side optical fiber ,
The numerical aperture of the light emitting element is NA1,
The numerical aperture of the transmission side optical fiber is NA2,
The magnification of the transmission side optical system is M,
The diameter of the light emitting surface of the light emitting element .phi.1, the mounting position maximum error in a direction perpendicular to the optical axis of the light emitting element d1,
The core diameter of the transmission side optical fiber is Φ2, the mounting position maximum error in the direction perpendicular to the optical axis of the transmission side optical fiber is d2,
Is set so that the following inequalities (1) to (3) hold:
The reflected return light intensity is 10 dB or more smaller than the case where the optical coupling efficiency between the light emitting element and the transmission side optical fiber is maximum,
In so that decrease Do less 1dB optical coupling efficiency with respect to the case where the optical coupling efficiency is an optical coupling efficiency is maximum of the transmission optical fiber and the light emitting element, the optical axis direction from the focal position of the first lens unit The tip of the transmission side optical fiber is located at a position offset to
The third lens unit is disposed such that the receiving-side optical fiber is positioned at a focal position thereof,
The fourth lens unit is arranged such that the light receiving element is positioned at a focal position thereof,
At least one of the third lens unit and the fourth lens unit so that the total optical coupling efficiency in the transmission side optical system and the reception optical system is 3 dB or more and 6 dB or less with respect to the maximum optical coupling efficiency. Is an optical module composed of aspherical lenses .
MΦ1 <Φ2 (1)
M (d1 + 1/2 · Φ1 ) < 1/2 · Φ2 − d2 (2)
NA1 / M <NA2 (3) 2. The optical module according to claim 1, wherein a distal end of the transmission-side optical fiber is located at a position offset from a focal position of the first lens unit by 50 μm to 100 μm in the optical axis direction. The lens component further includes a positioning portion including a positioning surface,
The positioning portion is fixed to the substrate in a state where the positioning surface is in contact with the substrate so that the light emitting element mounted on the substrate and the second lens portion are separated by a predetermined length. The optical module according to claim 1 or 2 . In the lens component, the positioning portion is fixed to the substrate with an adhesive,
The positioning portion has an adhesive filling space on the outer periphery of the positioning surface, according to claim 3, wherein the lens component by the adhesive filled in the adhesive filling space, characterized in that it is fixed to the substrate The optical module as described in. The first lens portion and the third lens portion are formed on a fiber side connection surface,
The second lens portion and the fourth lens portion are formed on the element side connection surface,
The third lens unit is disposed such that the receiving-side optical fiber is positioned at a focal position thereof,
The fourth lens unit is arranged such that the light receiving element is positioned at a focal position thereof,
The second lens unit is disposed so that the light emitting element is positioned at a focal position thereof,
The optical module according to claim 1 , wherein the first lens unit is disposed at a position offset in the optical axis direction with respect to the third lens unit.

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