JPS58211119A - Photocoupler for bus transmission - Google Patents

Abstract

PURPOSE:To perform two-way optical transmission between both high-priority and low-priority stations and to receive a light signal even at an intermediate point, by using three beam convergent and internal reflective type rod lenses, and connecting an up- and a down-circuit mutually through a common optical fiber. CONSTITUTION:A photocoupler for bus transmision is equipped with optical fibers 1-5, beam convergence and internal reflection type rod lenses 10, 20, and 30, a photodiode 6, and a light emitting diode 7, and light incident from the optical fiber 1 to the port 11 of the rod lens 10 enters the port 21 of the rod lens 20 from a port 12 and then reaches the photodiode 6 from a port 22 through the optical fiber 4. Light emitted from the light emitting diode 7 is sent out to the optical fiber 2 through the optical fiber 5, and then through the ports 33 and 34 of the rod lens 30 from the ports 23 and 24 of the rod lens 20.

Description

[Detailed description of the invention] (Explanation of technical field) The present invention relates to an optical coupler in an optical bus transmission system.

(Explanation of prior art) FIG. 1 is a diagram showing the configuration of a conventional optical coupler.

In Figure 1, depending on the uplink and downlink,
As described above, the optical transmission system has the disadvantage that it is not possible to perform optical bus transmission completely.

(Objective of the Invention) The object of the present invention is to configure an upper line and a lower line using a common optical fiber, perform optical transmission in both directions from both the upper and lower end stations, and An object of the present invention is to provide an optical coupler configured so that optical signals coming from either direction can be received at an intermediate point.

(Description of Structure and Function of the Invention) The optical coupler for bus transmission according to the present invention includes first to third beam-focusing internal reflection type rod lenses and an internal connection optical fiber.

A first optical fiber, an internal connection optical fiber, and a second beam-focusing internal reflection rod lens are connected to the first beam-focusing internal reflection rod lens. Second
First and third beam-focusing internal reflection rod lenses, a photodiode, and a light emitting diode are connected to the beam-focusing internal reflection rod lens.

A second optical fiber, an internal connection optical fiber, and a second beam-focusing internal reflection rod lens are connected to the third beam-focusing internal reflection rod lens.

With the above configuration, the intensity of the optical signal entering the optical coupler from the first optical fiber is multiplied by 1/4, and the light emitting diode and
It reaches a photodiode and a second optical fiber.
The optical signal entering the optical coupler from the second optical fiber has its intensity multiplied by 1/4 and reaches the light emitting diode, the photodiode, and the first optical fiber.

The intensity of the nine-light signal output from the light emitting diode is multiplied by one, and the signal is outputted to the first and second optical fibers.

(Explanation of Examples) Hereinafter, the present invention will be explained in detail with reference to the drawings.

FIG. 2 is a diagram showing an embodiment of the optical coupler for bus transmission according to the present invention. In FIG. 2, the optical coupler for bus transmission according to the present invention includes first to fifth optical fibers 1.2.3.
4.5 and 1 First to third beam focusing internal reflection type rod lenses 10, 20 (9), a photodiode 6, and a light emitting diode 7 are provided. In the first beam-focusing internal reflection type rod lens 10, the first optical fiber 1 is connected to the boat 11, and the light incident from the boat 11 of the first beam-focusing internal reflection type rod lens 10 is indicated by a broken line. After passing through the first internal reflection film 100, the beam passes through the first internal reflection type rod lens 1.
Reach boat number 2 of 0. Since the boat 12 of the first beam-focusing internal reflection type rod lens 10 is connected to the boat 21 of the second beam-focusing internal reflection type rod lens 20, the light incident on the boat 21 passes through the second internal reflection film 200. The optical fiber reaches the boat 22 via the optical fiber, and further reaches the photodiode 6 through a fourth optical fiber. The light output from the light emitting diode 7 passes through the fifth optical fiber 5 and reaches the boat 23 of the second beam focusing internal reflection type rod lens 20 . The light incident on the boat 23 of the second beam focusing internal reflection type rod lens 20 is
reach. Since the boat 33 of the third beam-focusing internally reflective rod lens 30 is connected to the boat 24 of the second beam-focusing internally reflective rod lens 20 , the light that has reached the boat 24 is incident on the boat 33 . Light from the boat 33 of the third beam-focusing internally reflective rod lens 30 passes through the third internally reflective film 300 and reaches the boat 34 .

No. of the third beam focusing internal reflection type rod lens 30.

Since the boat 34 is connected to the second optical fiber,
The light reaching the boat 34 of the third beam-focusing internally reflective rod lens 30 is transmitted to the second optical fiber 2.

The first beam-focusing internal reflection type rod lens 10
internal reflection [100f The reflected light is from boat 13 to the third
The beam is transmitted to the optical fiber of the optical fiber and further enters the boat 32 of the third beam-focusing internal reflection rod lens 30 .

In the second beam focusing internal reflection type rod lens 20, the boats 21 and 22 form an optical transmission path.
1 and reflected by the second internal reflection film 200 reaches the boat 23 and is sent to the fifth optical cable 5.
In the third beam focusing internal reflection type rod lens 30, the boats 33 and 34 form an optical transmission path.
2 is directly isolated from the boat 34, and is connected to the boat 34 by forming a separate transmission path. That is, a portion of the light incident on the boat 33 of the third beam-focusing internal reflection type rod lens 30 is reflected via the third internal reflection film 300 and reaches the boat 34.

Figure 3 shows the first optical coupler in the optical coupler for bus transmission shown in Figure 2.
It is a figure showing an example of operation. In FIG. 3, the signal *: output from the light emitting diode 7 is transmitted to the fifth optical fiber 5.
2nd Beano Focusing Internal Reflection Rod Lens via 2
It enters the boat 23 of 0. The optical signal reaching the second internal reflection film 200 from the boat 23 is reflected here and
Vino, Boat 2 with Focused Internal Reflection Rod Lens 20
Reach 1. The optical signal reaching the boat 21 of the second beam-focusing internally reflective rod lens 20 passes through the boat 12 of the first beam-focusing internally reflective rod lens 10, and
The beam passes through the first internal reflection film 100 and reaches the boat 11 of the first beam-focusing internal reflection rod lens 10 before being output to the first optical fiber 1. In this process of transmission and reflection, reflection and transmission occur once each, so the reflection coefficient and transmission coefficient of each internal reflection film are set to 1, respectively.
4, the intensity of the light output from the light emitting diode 7 is attenuated by a factor of 1/4 in the first optical fiber 1.

The optical signal transmitted through the second internal reflection film 200 of the second beam-focusing internal reflection type rod lens reaches the boat 24 of the second beam-focusing internal reflection type rod lens 20, and then passes through the third beam-focusing internal reflection type rod lens 20. Type rod lens 30 boat 3
3 and the third internal reflection film 300 to reach the boat 34 . Third beam focusing internal reflection rod lens 3
The optical signal reaching the boat 34 of 0 is transferred to the second optical fiber 2
sent to. In this transmission process, the light passes through the internal reflection film twice, so the intensity of the light output from the light emitting diode 7 is twice as high as based on the above assumption.

To summarize the above description, the intensity of the optical signal output from the light emitting diode 7 is doubled to the first and second optical fibers 2 and is sent out simultaneously.

Figure 4 shows the second optical coupler in the optical coupler for bus transmission shown in Figure 2.
It is a figure showing an example of operation.

In FIG. 4, the optical signal incident from the first optical fiber reaches the first internal reflection film 100 via the boat 11 of the first beam-focusing internal reflection type rod lens 10.
74 of the light intensity is reflected by the internal reflection film 100, and the remaining 2 is transmitted.

The reflected optical signal is outputted to the third beam 7 eyeball 3 via the boat 13 of the first beam-focusing internal reflection type rod lens 10, and the third beam-focusing internal reflection type rod lens 30
is input to the boat 32 of

1/2 of the optical signal reaching the boat 32 of the third beam-focusing internally reflective rod lens 30 is reflected by the third internally reflective film 300, and the optical signal reaches the boat 34 of the third beam-focusing internally reflective rod lens 30. The optical signal is reflected twice in total, once for each optical fiber, and reaches the second optical fiber 2 from the first optical fiber 1, and the intensity of the optical signal is 4.

The optical signal transmitted by the first internal reflection film 100 of the first beam-focusing internal reflection type rod lens 10 reaches the boat 12 of the first beam-focusing internal reflection type rod lens 10, and the optical signal passes through the first internal reflection film 100 of the first beam-focusing internal reflection type rod lens 10, and then reaches the boat 12 of the first beam-focusing internal reflection type rod lens 10, A second beam is focused from the boat 21 of the internally reflective rod lens 20 to the second internally reflective film 200.
The optical signal that has reached the optical fiber is reflected by the light intensity and reaches the light emitting diode 7 through the boat 23 of the second beam focusing internal reflection type rod lens 20 and the fifth optical fiber 5.

The residual beam 1/
! The optical signal with the intensity reaches the photodiode 6 through the boat 22 of the second beam-focusing internal reflection rod lens 2o and the fourth optical fiber 4. In these processes, the intensity of the optical signal reaching the photodiode 6 and the intensity of the optical signal reaching the light emitting diode 7 are equal to each other.

That is, the light reaching the light emitting diode 7 passes through the first internal reflection film 100 and then passes through the second internal reflection film 200.
reflect from. On the other hand, the light reaching the photodiode 6 passes through the first internal reflection film 100 and then also through the second internal reflection film 200. Therefore, the intensity of the optical signals reaching these devices is 1/4 times the intensity of the incident light.

The optical signal incident on the optical coupler for bus transmission from the second optical fiber 2 is transmitted from the first optical fiber 1 in the same way as the incident multiplication signal, but in this case, the optical signal is transmitted through the first beam focusing internal reflection. This is equivalent to replacing the type rod lens 10 and the third beam focusing internal reflection type rod lens 30, and replacing the photodiode 6 and the light emitting diode 7.

Therefore, the operation can be explained in the same way as above based on such a bilaterally symmetrical structure.

Therefore, although the description is omitted in this specification, each light incident on the second optical fiber 2 has a light intensity of 1.
quadrupled first optical fiber 1, photodiode 6,
Also, what appears in the light emitting diode 7 is the same as that clarified by the above explanation.

(Detailed Description of the Invention) As explained above, the present invention uses an optical coupler for bus transmission constituted by three beam-focusing internal reflection type rod lenses and an optical fiber for interconnection to connect an upper line. This has the effect that it is possible to transmit optical signals in both directions via the downlink, and it is possible to simultaneously receive optical signals that have passed through the upper nine lines and optical signals that have passed through the downlink.

[Brief explanation of the drawing]

FIG. 1 is a diagram showing the configuration of a conventional optical coupler, FIG. 2 is a diagram showing the configuration of an embodiment of the optical coupler for bus transmission according to the present invention, and FIG. 3 is a diagram showing the configuration of an optical coupler for bus transmission according to the present invention. FIG. 4 is a diagram showing a first example of operation of the optical coupler, and FIG. 4 is a diagram showing a second example of operation of the optical coupler for bus transmission shown in FIG. 1.2.3.4.5... Optical fiber 6... Photodiode 7... Light emitting diode 10.20.30... Beam focusing internal reflection type rod lens 11.12.13.21.22. 23.24.31.3
2.33.34...Boat 100.200.300...Internal reflective film patent applicant
NEC Co., Ltd. Agent Patent Attorney Inoro Figure 5

Claims (1)

[Claims] a first beam-focusing internally reflective rod lens connected to the first optical fiber; and a second beam-focusing internally reflective rod lens connected to the first beam-focusing internally reflective rod lens, the light emitting diode, and the photodiode. rod lens and
a third beam-focusing internally reflective rod lens connected to the second beam-focusing internally reflective rod lens and a second optical fiber; a third beam-focusing internally reflective rod lens connected to the first beam-focusing internally reflective rod lens; 1. An optical coupler for bus transmission, comprising an internal connection optical fiber for connecting a beam focusing internal reflection type rod lens.