JP2017211419A - Optical module - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an optical module capable of separating signals even if wavelength bands of a transmission signal and a reception signal are narrow.SOLUTION: An embodiment of the present invention discloses an optical module that comprises: an optical transmitter for outputting a first optical signal; an optical receiver for receiving a second optical signal; a holder including an optical fiber which the first optical signal is input into and the second optical signal goes out from; a first optical filter which is disposed between the optical transmitter and the holder, lets the first optical signal pass through and reflects the second optical signal; a first parallel optical lens disposed between the first optical filter and the optical transmitter; and a second parallel optical lens disposed between the first optical filter and the holder.SELECTED DRAWING: Figure 1

Description

  The embodiment relates to an optical module used for optical communication.

  In general, an optical module is a module in which various optical communication functions are accommodated in a single package and can be connected to an optical fiber. Recently, a bidirectional optical module that combines an optical transmitter that uses a laser diode with low power consumption and can be used over a long distance as a light source, and an optical receiver that performs optical communication using a photodiode. Is mainly used.

  The bidirectional optical module includes an optical transmitter, an optical receiver, an optical filter, an optical fiber, a holder in which the optical fiber is accommodated, and the like. The transmission signal output from the optical transmitter passes through the optical filter and enters the optical fiber, and the reception signal output from the optical fiber is reflected by the optical filter and enters the optical receiver.

  The optical filter is generally inclined at 45 degrees to separate the transmission signal and the reception signal. However, when the wavelength interval of the transmission / reception signal is several nanometers, the optical isolation of the transmission / reception wavelength (difference in transmission between the transmission signal and the reception signal) is caused by the difference in transmission characteristics between S-polarized light and P-polarized light. It is difficult to separate the wavelengths so as to satisfy 25 dB.

  Therefore, in a bidirectional optical module having a transmission / reception wavelength interval of several nanometers, a beam splitter that distributes optical power is used instead of a WDM filter that can separate wavelengths. However, since the beam splitter transmits 50% of the incident light and reflects 50%, the following problems occur.

  As a first problem, in order to perform long-distance transmission using a bidirectional optical module, a high optical coupling efficiency is required when the output from the laser diode is collected on an optical fiber. . However, when a beam splitter is used, 50% is transmitted and 50% is reflected, so that a loss of a filter of 3 dB occurs and sufficient optical coupling efficiency cannot be obtained.

  As a second problem, in order to perform long-distance transmission using the bidirectional optical module, not only the optical coupling efficiency of the laser diode but also the reception sensitivity of the photodiode must be good. However, when the light output from the optical fiber is reflected by the filter and enters the photodiode, a high receiving sensitivity cannot be obtained due to the loss of the 3 dB filter.

  Finally, in a bi-directional optical module with a wavelength interval of several nanometers, sufficient optical isolation between the transmitted and received signals cannot be ensured, so that the transmission signal can affect the received signal and reduce communication quality (optical Crosstalk).

  Embodiments of the present invention provide an optical module that can separate signals even when the wavelength band of a transmission signal and a reception signal is narrow.

  An embodiment of the present invention provides an optical module having improved optical coupling efficiency between a transmission signal and an optical fiber.

  Embodiments of the present invention provide an optical module with improved photodiode receiving sensitivity.

  Embodiments of the present invention provide an optical module with improved optical crosstalk.

  The problems to be solved by the present invention are not limited to the problems mentioned above, and other problems not mentioned here can be clearly understood by those skilled in the art from the following description.

  An optical module according to an embodiment of the present invention includes an optical transmitter that outputs a first optical signal, an optical receiver that receives a second optical signal, the first optical signal is incident, and the second optical signal is emitted. A first optical filter that is disposed between the optical transmitter and the holder, transmits the first optical signal and reflects the second optical signal, and the first optical filter. And a first parallel light lens disposed between the optical transmitter and a second parallel light lens disposed between the first optical filter and the holder.

  An isolator disposed between the first parallel light lens and the optical transmitter may be included.

  The optical transmitter may include a light source and a first focus lens that collects a first optical signal emitted from the light source.

  The first optical signal emitted from the light source is converged by the first focus lens, and the point where the first optical signal converges is a point between the first parallel light lens and the isolator. it can.

  The first parallel light lens can convert the first light signal into parallel light, and the second parallel light lens can collect the first light signal converted into the parallel light.

  The second parallel light lens can convert the second optical signal emitted from the optical fiber into parallel light.

  A reflection mirror that reflects the second optical signal reflected by the first optical filter to the optical receiver side may be included.

  A second optical filter disposed between the reflecting mirror and the optical receiver may be included.

  The second optical signal converted into the parallel light is reflected by the first optical filter and the reflecting mirror, and the second optical signal reflected by the reflecting mirror passes through the second optical filter and receives the light. Can be incident on the machine.

  The optical transmitter, the optical receiver, and the holder may be inserted, and the first optical filter, the first parallel light lens, and the second parallel light lens may be disposed therein.

  An isolator disposed between the first parallel light lens and the optical transmitter; a reflecting mirror that reflects the second optical signal reflected by the first optical filter toward the optical receiver; and the reflecting mirror And a second optical filter disposed between the optical receiver and the optical receiver.

  A support block coupled to the housing and accommodating the first parallel light lens, the first optical filter, the isolator, the reflecting mirror, and the second optical filter may be included.

  The holder can accommodate the second parallel light lens.

  The holder can accommodate the first parallel light lens, the second parallel light lens, the first optical filter, the reflecting mirror, and the second optical filter.

  An adjustment member for fixing the optical transmitter to the housing; the adjustment member being coupled to the housing; and a second adjustment inserted into the first adjustment member and coupled to the optical transmitter. And a member.

  The isolator may be disposed inside the second adjustment member.

  According to the embodiment of the present invention, signals can be separated even when the wavelength band of the transmission signal and the reception signal is narrow.

  In addition, the optical coupling efficiency between the transmission signal and the optical fiber can be improved.

  In addition, the receiving sensitivity of the photodiode can be improved.

  Also, optical crosstalk can be improved.

  The various and beneficial advantages and effects of the present invention are not limited to those described above, but can be more easily understood in the course of describing specific embodiments of the present invention.

The conceptual diagram of the optical module by one Example of this invention. The figure which shows the movement path | route of the 2nd optical signal output from the optical fiber. The graph which shows the reflectance curve (Reflectance Curve) of S wave and P wave by incident angle. The graph which shows the transmission curve (Transmission Curve) of a 45 degree filter and a 15 degree filter. The graph which shows the transmission characteristic with respect to the parallel light and convergent light which inject into a 1st optical filter. The figure which shows the movement path | route of the 1st optical signal output from the optical transmitter. The graph which shows the BER curve at the time of turn-on and turn-off of an optical transmitter. The figure which shows the structure of a support block. Drawing which shows composition of a holder. The conceptual diagram of the optical module by the other Example of this invention. Drawing which shows the structure of the holder of FIG.

  While the invention is amenable to various modifications and alternative forms, specific embodiments have been shown by way of example in the drawings and will be described in detail.

  However, this should not be construed as limiting the invention to the specific embodiments, but should be understood to include all modifications, equivalents or alternatives that fall within the spirit and scope of the invention.

  The terms used in the present invention are merely used to describe particular embodiments and are not intended to limit the present invention. The singular form includes the plural form unless the context clearly dictates otherwise.

  In the present invention, terms such as “comprising” or “having” are intended to indicate that there is a feature, number, step, action, component, part, or combination thereof described in the specification. It should be understood that it does not exclude the possibility of the presence or addition of one or more other features or numbers, steps, actions, components, parts or combinations thereof in advance. is there.

  In addition, it should be understood that the drawings attached to the present invention are shown enlarged or reduced for convenience of explanation.

  Hereinafter, the present invention will be described in detail with reference to the drawings. The same or corresponding components regardless of the reference numerals are assigned the same reference numerals, and redundant description thereof will be omitted.

  FIG. 1 is a conceptual diagram of an optical module according to an embodiment of the present invention.

Referring to FIG. 1, the bidirectional optical transceiver module receives a holder 210 into which an optical fiber 221 is inserted, an optical transmitter 300 that outputs a first optical signal L ₁ to the optical fiber 221, and a second optical signal L ₂ . a receiving optical receiver 400, a first optical filter 510 first optical signal _{L 1} is the second optical signal _{L 2} passes through the reflecting, the second optical signal _{L 2} reflected by the first optical filter 510 A reflecting mirror 540 that reflects toward the optical receiver 400 is included.

  Case 100 includes a plurality of housing units into which optical fiber 221, optical transmitter 300, and optical receiver 400 are inserted. The optical fiber 221 and the optical transmitter 300 are arranged to face each other in the case 100, and the optical receiver 400 can be arranged in a direction perpendicular to the direction in which the optical fiber 221 is inserted. However, the present invention is not necessarily limited thereto, and the optical transmitter 300 can be arranged in a direction perpendicular to the direction in which the optical fiber 221 is inserted.

  The optical fiber 221 is disposed on one side of the case 100. The stub 220 in which the optical fiber 221 is accommodated can be inserted into the holder 210. A connector 230 to which an external optical channel can be connected can be coupled to the holder 210. Such a structure can be a receptacle type, but the structure of the holder is not particularly limited.

The optical fiber 221 may transmit the first optical signal L ₁ output from the optical transmitter 300 to the outside, or output the second optical signal L ₂ received from the outside toward the first optical filter 510. it can.

The optical transmitter 300 transfers the first optical signal L ₁ to the outside via the optical fiber 221. The first optical signal L ₁ can have a wavelength different from the wavelength of the second optical signal L ₂ output from the optical fiber 221. The optical transmitter 300 may include a light source 310, a header 340, and a first focus lens 320. The optical transmitter 300 having such a structure may have a TO-CAN (TO-Controller Area Network) structure.

  The light source 310 is composed of a semiconductor light emitting element, and converts an electrical signal into an optical signal and outputs it. A laser diode can be used as the light source 310. A laser diode is suitable as a light source for optical communication because it consumes less power, has a narrow spectrum, and can finely collect high-power light.

  The header 340 on which the light source 310 is seated is formed in a disk shape, and a plurality of connecting pins are inserted therethrough. The connecting pins form an electrical path between the light source 310 and an external circuit board (not shown).

The first focus lens 320 can collect the first optical signal L ₁ output from the light source 310. The first focus lens 320 can be properly positioned to allow transfer of the first optical signal L ₁ to the optical fiber 221 side.

The distance adjustment member 700 includes a first adjustment member 710 disposed on the other side of the case 100 and a second adjustment member 720 inserted and fixed to the first adjustment member 710. Depending on the degree of insertion of the second adjusting member 720 and the first regulating member 710, the second optical signal L ₂ emitted from the optical transmitter 300 can be the distance to reach the optical fiber 221 is adjusted. Therefore, the optical coupling efficiency of the optical transmitter 300 can be adjusted according to the insertion depth of the second adjustment member 720 and the first adjustment member 710. The optical transmitter 300 is inserted and fixed to one side of the second adjustment member.

Optical receiver 400 converts the second optical signal L ₂ received via the optical fiber 221 from the outside into an electrical signal. The optical receiver 400 may include a photodiode (Photo Diode). When an optical signal enters the photodiode, a reverse current proportional to the amount of incident light flows. That is, the optical receiver 400 can convert an optical signal into an electrical signal by changing an output current according to the amount of incident light.

The first optical filter 510 can be disposed between the optical transmitter 300 and the optical fiber 221 as a WDM filter. The first optical filter 510 can be designed to pass only an optical signal having a specific wavelength. For example, the first optical filter 510 can pass the first optical signal L ₁ output from the optical transmitter 300 and can reflect the second optical signal L ₂ output from the optical fiber 221. The first optical filter 510 has a tilt angle smaller than about 20 so that the optical signal can be separated even when the wavelength interval between the first optical signal L ₁ and the second optical signal L ₂ is narrow. Can be attached to.

Reflector 540 can change the second optical signal L ₂ of the path reflected by the first optical filter 510 is mounted on the support block 600 to the optical receiver 400 side. The reflecting mirror 540 may be manufactured by attaching another reflecting member to the support block 600. However, the reflecting mirror 540 is not necessarily limited thereto, and a reflecting region may be directly formed on the inclined surface of the supporting block 600. it can.

The second optical filter 530, a blocking filter (or 0 degree filter), passing the second optical signal _{L 2} reflected by the first optical filter 510 and the reflecting mirror 540. The second optical signal L _{2 that} has passed through the second optical filter 530 is transmitted to the light receiving element 420 of the optical receiver 400, and is converted into an electrical signal by the optical receiver 400.

The isolator 520 removes the reflected noise by blocking the first optical signal L ₁ and / or the second optical signal L ₂ from being incident on the optical transmitter 300 after being reflected inside the case 100. Can do.

  The isolator 520 may include a polarizer that passes only an optical signal having a preset polarization component, an analyzer, and a Faraday rotator that rotates and rotates the optical signal input therein.

  FIG. 2 is a diagram showing a movement path of the second optical signal output from the optical fiber, FIG. 3 is a graph showing a reflectance curve of the S wave and the P wave according to the incident angle, and FIG. It is a graph which shows the transmission curve (Transmittance Curve) of a 45 degree filter and a 15 degree filter, and FIG. 5 is a graph which shows the transmission characteristic with respect to the parallel light and convergent light which inject into a 1st optical filter.

Referring to FIG. 2, the second optical signal L ₂ emitted from the optical fiber 221 includes main light L ₂₁ and diverging lights L ₂₂ and L ₂₃ . The main light L ₂₁ can be defined as light traveling from the optical fiber 221 toward the first optical filter 510 along the main path (optical axis), and the diverging lights L ₂₂ and L ₂₃ are defined as the main path and the predetermined path. It can be defined as light traveling at an angle.

Second parallel light lens 560, a second optical signal L ₂ emitted from the optical fiber 221 can be converted into parallel light. Since the second optical signal L ₂ of the divergent light L _22, L ₂₃ is converted into parallel light, the line width of the second optical signal L ₂ can be made small Ku as compared with the case where not converted into parallel light. Therefore, the second parallel light lens 560 and the optical fiber 221 can be disposed adjacent to each other. Second optical signal line width L ₂ which is converted into parallel light, can to about 100μm not a 200 [mu] m, but the embodiment is not limited thereto.

The second optical signal L ₂ converted into parallel light is incident on the incident surface 511 of the first optical filter 510. The first optical filter 510 may have a first angle θ ₁ of about 8 to 18 degrees with respect to the normal line P ₁ . Illustratively, the angle of the first optical filter may be 12 degrees.

When the first angle θ ₁ is less than 8 degrees, the reflection angle becomes smaller and the reflected second optical signal L ₂ is incident again on the optical fiber 221 or loss due to interference occurs, resulting in a decrease in reception sensitivity. There is a problem to do.

Further, when the first angle θ ₁ exceeds 18 degrees, there is a problem in that the transmission / reflection curve of the optical filter is distorted due to the difference in filter reflectivity due to polarized light and the characteristics of the optical filter are deteriorated.

With reference to Figure 3, when the second optical signal L ₂ is an incident angle to be incident on the first optical filter 510 is more than about 18 degrees, it can be seen that the difference in reflectance of S-polarized light and P-polarized light increases.

Therefore, if the first angle θ ₁ is adjusted to about 8 to 18 degrees, the difference in reflectance (Reflectance) depending on the polarization direction is reduced, and the wavelength bandwidth of the first optical signal L ₁ and the second optical signal L ₂ is small. Even in this case, the optical signal can be effectively separated.

  Referring to FIG. 4, in order to obtain 25 dB isolation (Isolation), a 45 degree filter must have a wavelength interval of about 21 nm. In the case of a 15 degree filter, the performance is sufficiently exhibited even at an interval of about 11 nm. I can confirm that I can do it.

  However, referring to FIG. 5, when the light incident on the first optical filter 510 is a convergent light (Focus Beam) incident at a predetermined angle, the inclination of the transmission characteristic between the transmission region and the reflection region is obtained. Is formed gently, so that sufficient optical isolation cannot be ensured.

  That is, when the wavelength interval between the first optical signal and the second optical signal is several nanometers or less, it is sufficient if the incident light is convergent light even if the filter angle is adjusted to 8 to 18 degrees. Optical isolation cannot be ensured.

  According to the embodiment of the present invention, since the light incident on the first optical filter 510 is converted into parallel light and incident on the first optical filter 510, the transmission band characteristic can be relatively constant. . Illustratively, sufficient optical isolation (about 20 dB) can be ensured even when the wavelength interval between the transmission signal and the reception signal is about 6.0 nm.

Further, referring to FIG. 2, the reflecting mirror 540 may be disposed at an angle θ ₂ of about 26 degrees to 35 degrees with respect to the normal line P ₁ . When such a condition is satisfied, the second optical signal L ₂ incident by the first optical filter 510 can be reflected toward the optical receiver 400.

The second optical signal L ₂ reflected by the reflecting mirror 540 and incident on the second optical filter 530 is mostly parallel light and is not reflected by the second optical filter 530. Accordingly, the second optical signal L ₂ is, loss of light does not occur because it is incident perpendicularly.

The second optical signal L ₂ having passed through the second optical filter 530, the second focus lens 410 is condensed, it can be incident on the light receiving element. As described above, the line width of the second optical signal _{L 2,} since the narrow about 100μm to 200 [mu] m, without a parallel light lens, general optical receiver with a converging lens (eg: PIN-TIA , APD, etc.) can be used. Therefore, the part cost can be reduced.

According to an embodiment of the present invention, the second optical signal L ₂ is converted into parallel light, is incident on the first optical filter 510, a loss of the filter is small, most of the light is transmitted to the optical receiver Can do. Therefore, reception sensitivity can be increased.

  FIG. 6 is a diagram illustrating a moving path of the first optical signal output from the optical transmitter.

Referring to FIG. 6, the first optical signal L ₁ output from the light source 310 of the optical transmitter includes main light L ₁₁ and diverging light L ₁₂ and L ₁₃ . Toward the light source 310 to the optical fiber 221 along the main path of the main light L ₁₁ (optical axis) can be defined as a light traveling, divergent light L _12, L ₁₃ may have a main path and a predetermined angle Can be defined as traveling light.

Main light _{L 11} and the divergent light _{L 12, L 13} may be converged by the first focusing lens 320 of the optical transmitter. The point S ₁ at which the first optical signal L ₁ converges may be a point between the first parallel light lens 550 and the isolator 520. A convergent point can be defined as a point where a plurality of diverging lights L ₁₂ and L ₁₃ are close to each other and a focus is collected.

According to such a configuration, the area of light passing through the isolator 520 can be relatively reduced. The price of the isolator 520 increases as the effective diameter (Clear Aperture) increases. In the embodiment of the present invention, the position of the isolator 520 is arranged near the point S ₁ where the first optical signal L ₁ converges, and the effective diameter of the isolator 520 can be reduced, thereby reducing the unit cost.

The first parallel light lens 550 can convert the divergent light L ₁₂ and L ₁₃ into parallel light. That is, all of the main light L ₁₁ and the diverging lights L ₁₂ and L ₁₃ can be converted into parallel light while passing through the first parallel light lens 550. The first parallel light lens 550 may be a collimator lens. Thus, the first optical signal L ₁ is in a state of being converted into parallel light, so passing through the first optical filter 510 can be narrow wavelength interval to ensure a sufficient light isolation.

Second parallel light lens 560 may focus the first optical signal L ₁ is converted into parallel light. That is, the second parallel light lens 560, a first optical signal L ₁ is condensed, the second optical signal L ₂ can be converted into parallel light. The collected first optical signal L ₁ can enter the optical fiber 221 of the stub 220. Therefore, the optical coupling efficiency can be improved.

  According to the embodiment of the present invention, the WDM filter is used as the first optical filter, and the first optical signal is converted into parallel light and incident on the first optical filter, so that the filter loss is small and the optical coupling efficiency is improved. can do.

  Furthermore, according to the embodiment of the present invention, a general focus lens can be mounted instead of the parallel light lens as the lens arranged in the optical transmitter. The collimator optical system has a good alignment margin for the X, Y, and Z axes, but a margin for the tilting angle is not good. Therefore, when a collimator optical system is used, a very precise process is required, so that the manufacturing process can be complicated.

  FIG. 7 is a graph showing a BER curve when the optical transmitter is turned on and turned off.

  Referring to FIG. 7, when the turn-on signal is output from the optical transmitter and the turn-off signal is output, it is confirmed that the difference in the reception sensitivity of the optical receiver is about 0.5 dB. Can do. This is considered that the first optical signal output by the optical transmitter is mostly output to the outside and is not incident on the light receiving element as noise.

  That is, according to the embodiment of the present invention, it is determined that the optical separation of the transmission signal and the reception signal having a narrow wavelength interval is effectively controlled by the first optical filter, and the optical crosstalk is suppressed. Therefore, the receiving sensitivity of the light receiving element is also increased.

  When a bidirectional optical module having a transmission / reception wavelength interval of several nanometers is manufactured using an optical system as in the embodiment of the present invention, high optical power, excellent reception sensitivity, and low crosstalk characteristics are provided so that long-distance transmission is possible. It is possible to apply a general structure LD / PD TO-CAN (TO-Controller Area Network), and to manufacture a product with productivity and price competitiveness.

  FIG. 8 is a diagram showing the configuration of the support block, and FIG. 9 is a diagram showing the configuration of the holder.

  Referring to FIGS. 2 and 8, the support block 600 may accommodate the first parallel light lens 550, the first optical filter 510, the isolator 520, the reflecting mirror 540, and the second optical filter 530.

  According to the embodiment of the present invention, the receiving sensitivity can be improved because each component is arranged at an accurate position simply by inserting the holder 210 into the case 100 and inserting the support block 600 into the case 100.

  The support block 600 may form a first receiving groove 640 in which the first parallel light lens 550 is inserted and a second receiving groove 650 in which the isolator 520 is disposed on one side. The support block 600 includes an inclined surface 620 to which the reflecting mirror 540 is attached, a step portion 630 formed on the upper surface of the inclined surface 620 and where the second optical filter 530 is disposed, and a groove that penetrates the inclined surface 620 ( Groove) 610. A first optical filter 510 can be disposed on the inclined portion 611 of the groove 610. Referring to FIG. 9, the second parallel light lens 560 may be disposed in a groove 211 formed in front of the holder 210.

  FIG. 10 is a conceptual diagram of an optical module according to another embodiment of the present invention, and FIG. 11 is a diagram illustrating a configuration of the holder of FIG.

  Referring to FIGS. 10 and 11, the holder 210 can accommodate the first parallel light lens 550, the second parallel light lens 560, the first optical filter 510, the reflecting mirror 540, and the second optical filter 530. According to such a configuration, since all the components are mounted on the holder 210, the components can be arranged at accurate positions only by mounting, and the reception sensitivity can be improved. In this case, the support block can be omitted.

  The distance adjustment member 700 includes a first adjustment member 710 coupled to the case 100 and a second adjustment member 720 inserted into the first adjustment member 710 and coupled to the optical transmitter 300. At this time, the isolator 520 may be disposed inside the second adjustment member 720.

  Referring to FIG. 11, the holder 210 includes a first accommodating portion 213 that accommodates the first parallel light lens 550, and a second inclined portion 212 that is formed on the bottom surface of the first accommodating portion 213 and in which the reflecting mirror 540 is disposed. , A protrusion surface 214 formed on the side wall of the second inclined portion 212 where the first optical filter 510 is disposed, and an upper end flat portion 215 where the second optical filter 530 is disposed.

100: Case 210: Holder 221: Optical fiber 300: Optical transmitter 400: Optical receiver 510: First optical filter 520: Isolator 530: Second optical filter 540: Reflective mirror 550: First parallel light lens 560: Second Parallel light lens

Claims (16)

An optical transmitter for outputting a first optical signal;
An optical receiver for receiving the second optical signal;
A holder including an optical fiber through which the first optical signal is incident and the second optical signal is emitted;
A first optical filter disposed between the optical transmitter and the holder, wherein the first optical signal is transmitted and the second optical signal is reflected;
A first parallel light lens disposed between the first optical filter and the optical transmitter;
An optical module comprising: a second parallel light lens disposed between the first optical filter and the holder.   The optical module according to claim 1, further comprising an isolator disposed between the first parallel light lens and the optical transmitter.   The optical module according to claim 2, wherein the optical transmitter includes a light source and a first focus lens that condenses the first optical signal emitted from the light source.   The first optical signal emitted from the light source is converged by the first focus lens, and a point where the first optical signal converges is a point between the first parallel light lens and the isolator. Item 4. The optical module according to Item 3. The first parallel light lens converts the first optical signal into parallel light,
The optical module according to claim 4, wherein the second parallel light lens condenses the first optical signal converted into the parallel light.   The optical module according to claim 1, wherein the second parallel light lens converts the second optical signal emitted from the optical fiber into parallel light.   The optical module according to claim 6, further comprising a reflecting mirror that reflects the second optical signal reflected by the first optical filter toward the optical receiver.   The optical module according to claim 7, further comprising a second optical filter disposed between the reflecting mirror and the optical receiver.   The second optical signal converted into the parallel light is reflected by the first optical filter and the reflecting mirror, and the second optical signal reflected by the reflecting mirror passes through the second optical filter and passes through the light. The optical module according to claim 8, which is incident on a receiver.   The optical transmitter, the optical receiver, and the holder are inserted, and includes a case in which the first optical filter, the first parallel light lens, and the second parallel light lens are disposed. The optical module as described. An isolator disposed between the first parallel light lens and the optical transmitter;
A reflecting mirror that reflects the second optical signal reflected by the first optical filter toward the optical receiver;
The optical module according to claim 10, further comprising: a second optical filter disposed between the reflecting mirror and the optical receiver.   The optical module according to claim 11, further comprising a support block coupled to a housing and accommodating the first parallel light lens, the first optical filter, the isolator, the reflecting mirror, and the second optical filter.   The optical module according to claim 12, wherein the holder accommodates the second parallel light lens.   The optical module according to claim 11, wherein the holder accommodates the first parallel light lens, the second parallel light lens, the first optical filter, the reflecting mirror, and the second optical filter.   The adjustment member includes an adjustment member for fixing the optical transmitter to the housing, and the adjustment member includes a first adjustment member coupled to the housing, and a second adjustment member inserted into the first adjustment member and coupled to the optical transmitter. The optical module according to claim 14, comprising:   The optical module according to claim 15, wherein the isolator is disposed inside the second adjustment member.