KR100656856B1 - Triplexer Optical Module - Google Patents

Abstract

The present invention relates to a triplex optical module capable of performing not only bidirectional digital communication such as the Internet, but also analog optical signal distribution such as CATV using one optical cable.

The present invention provides an optical cable for outputting a digital downlink optical signal and an analog optical signal and inputting a digital uplink optical signal; A first filter for extracting the analog optical signal;

A first lens for focusing the analog optical signal extracted by the first filter; A first photoelectric conversion device for converting the light focused by the first lens into an electrical signal;

A second filter for extracting the digital downlink optical signal; A second lens for focusing the digital downlink optical signal extracted by the second filter; A second photoelectric conversion device converting the light focused by the second lens into an electrical signal; An all-optical converter for converting a digital upward electrical signal into an optical signal; And a third lens for focusing and outputting light output from the all-optical converter.

By using the present invention as described above it is possible to use a general lens in place of the existing expensive and difficult to align the collimating lens is cheaper and manufacturing time can be reduced, the number of lenses is also reduced from four to three There is an advantage that the number of parts is reduced.

Triplexer, Optical Cable, WDM Filter, Photo Diode, Laser Diode

Description

Triplexer Optical Module

1 is a block diagram of a triplex optical module according to the prior art

2 is a block diagram of a triplex optical module according to the present invention

3 is a block diagram of a triplex optical module according to another embodiment of the present invention

The present invention relates to a triplex optical module capable of performing not only bidirectional digital communication such as the Internet, but also analog optical signal distribution such as CATV using one optical cable.

Conventionally, for a bidirectional Internet using an optical cable, a diplexer that uses different wavelengths of up / down signals using WDM (Wavelength Division Multiplexing) technology has been used. Recently, analog signals such as CATV of various channels have been used. The need for a triplexer has emerged to add.

In accordance with such a necessity, the collimating lens is conventionally used as shown in FIG. 1 to configure the output of the lens to be parallel light.

The reason why the infinite optical system is constructed using the collimating lens is to reduce the optical loss due to the long distance between the optical cable, the photodiode and the laser diode.

In more detail, in the digital downlink signal, the light output from the optical cable 1 becomes parallel light through the collimating lens 2 so that the parallel light is only the first WDM filter 3 (analog downlink optical signal 1550nm). Reflected light) and reflected from the second WDM filter 4 (reflecting only the digital downlink light signal (1490 nm)) to filter only the wavelength (1490 nm) of the digital down signal so that the parallel light is again collimated lens (5). Through the integrated light is converted into an electrical signal in the first photodiode (PD1) (6) to become a digital downward electrical signal is input to the Internet PC.

In addition, the digital uplink signal is converted into a 1310nm uplink optical signal by a laser diode (LD) 7, and the output of the laser diode 7 is converted into parallel light by the collimating lens 8. Parallel light is converted into collimated light from the collimating lens 2 to be input to the optical cable 1.

Next, the analog downlink signal such as CATV is also the same as the digital downlink signal. The output (1550 nm) from the optical cable 1 is converted into parallel light by the collimating lens 2 so that the parallel light is converted into the first WDM filter. Reflected by (3), the collimating lens 9 is converted back into focused light, and is converted into an electrical signal by the second photodiode PD2: 10 to be transmitted to CATV or the like.

As a result, the prior art triplexer uses four collimating lenses 2, 5, 8, and 9.

However, since the collimating lens has to output parallel light unlike the general lens (focusing light output), the price is expensive, and the manufacturing time of the triplex optical module is compensated because the angle of alignment with the optical cable must be compensated. This takes a lot, and the manufacturing of the laser diode and the photodiode aligned with the collimating lens is essential, and thus, there is a disadvantage in that the manufacturing cost is high and the manufacturing time is very long.

The present invention provides a triplex optical module having a low manufacturing cost and a short manufacturing period in view of the above problems of the prior art.

The present invention for achieving the above object,

An optical cable for outputting a digital downlink optical signal and an analog downlink optical signal and inputting a digital uplink optical signal; A first filter for extracting the analog downlink optical signal;

A first lens for focusing the analog downlink optical signal extracted by the first filter;

A first photoelectric conversion device for converting the light focused by the first lens into an electrical signal; A second filter for extracting the digital downlink optical signal; A second lens for focusing the digital downlink optical signal extracted by the second filter; A second photoelectric conversion device converting the light focused by the second lens into an electrical signal; An all-optical converter for converting a digital upward electrical signal into an optical signal; And a third lens for focusing and outputting light output from the all-optical converter.

An embodiment of the present invention for achieving the above-described triplexer optical module will be described with reference to FIG.

The digital downlink optical signal (1490nm) for the Internet or the like output from the optical cable 11 is output with a divergence angle (for example, about 6 degrees) at a predetermined angle, reflecting the CATV optical signal (1550nm) and downlink digital optical signal. After passing through the first WDM filter 12 that transmits the signal 1490 nm and the upward digital optical signal 1310 nm, the second WDM filter 13 reflects the digital downward optical signal 1490 nm and reflects the general lens ( 14) and is concentrated at the output of the general lens 14, converted into an electrical signal in the photodiode PD1: 15, converted into a digital downward electrical signal, and output to the PC.

In addition, the digital up-electrical signal output from the PC or the like and input to the laser diode LD: 16 is converted into the optical signal 1310 nm from the laser diode 16 and focused by the general lens 17 to collect the second WDM filter ( 13) and the first WDM filter 12 to enter the optical cable 11 through the center point of the side end of the optical cable 11.

Finally, the analog downlink optical signal (1550 nm) for CATV and the like output from the end of the optical cable 11 is also output with a divergence angle (for example, 6 degrees) at a predetermined angle to reflect the optical signal for CATV (1550 nm). It is reflected by the first WDM filter 12 to be condensed by the general lens 18 and converted into an electrical signal in the photodiode (PD2: 19) is converted into an analog downward electrical signal.

As a result, using the present invention as described above it is possible to use a general lens using a finite optical system instead of a collimating lens using an existing expensive and difficult to align the infinite optical system can be cheaper and shorten the manufacturing time, the lens The number of parts is also reduced from 4 to 3 has the advantage that the number of parts is reduced.

On the other hand, the first WDM filter 12 and the second WDM filter 13 should ideally reflect only the CATV optical signal (1550 nm), respectively, and should reflect only the digital downlink optical signal (1490 nm).

In reality, however, it is difficult to manufacture a WDM filter having such a property, so that a small amount of digital downward optical signal (1490 nm) is also included at the output of the photodiode 19 side of the first WDM filter 12, so that a general lens ( There is a small amount of light directed to 18), but the digital downward optical signal (1490 nm) is mixed.

Similarly, not only the digital downlink optical signal (1490nm) for the photodiode 15 but also the analog downlink optical signal (1550nm) are mixed in the output of the port diode 15 side of the second WDM filter 13.

Accordingly, in another embodiment of the present invention, as shown in FIG. 3, the rejection filters 22 and 21 are disposed in the general lens 18 and the general lens 17, respectively, so that only the downlink analog light signal (1550 nm) and the downlink digital light are provided. If only a signal (1490nm) is input to the photodiode 19 and the photodiode 15, it is possible to construct a triplexer with better performance.

While the preferred embodiments of the present invention have been described above, it should be noted that the present invention is not limited to these embodiments, but various modifications can be made without departing from the spirit of the present invention.

For example, an optical power split filter may be used instead of the WDM filter used above.

When the present invention is configured as described above, a general lens using a finite optical system can be used, and the number of lenses can be reduced, resulting in a low manufacturing cost of the triplexer and a shortening of the manufacturing time.

Claims (8)

An optical cable for outputting a digital downlink optical signal and an analog downlink optical signal and inputting a digital uplink optical signal; A first filter for extracting the analog downlink optical signal; A first lens for focusing the analog downlink optical signal extracted by the first filter; A first photoelectric conversion device for converting the light focused by the first lens into an electrical signal; A second filter for extracting the digital downlink optical signal; A second lens for focusing the digital downlink optical signal extracted by the second filter; A second photoelectric conversion device converting the light focused by the second lens into an electrical signal; An all-optical converter for converting a digital upward electrical signal into an optical signal; And a third lens for focusing and outputting the light output from the all-optical converter. The optical module apparatus of claim 1, wherein the first and second filters are WDM filters. The optical module apparatus of claim 1, wherein the first and second filters are optical power split filters. The apparatus of claim 1, wherein the first and second photoelectric converters are photodiodes. The apparatus of claim 1, wherein the all-optical converter is a laser diode. The apparatus of claim 1, wherein a front end of the first and second lenses further includes a removal filter for removing light of an unnecessary wavelength. The optical module apparatus of claim 1, wherein the digital downlink and uplink optical signals are for the Internet. The optical module apparatus of claim 1, wherein the analog downlink optical signal is for CATV.

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