KR100525041B1 - Optical network unit in passive optical network - Google Patents

Abstract

The present invention relates to a wavelength division multiplexing passive optical subscriber network using a wavelength division multiplexing and demultiplexing apparatus, wherein the subscriber side optical connector (ONU) receives light from a light source of the base station side optical terminal (OLT) to receive an optical signal. Create The subscriber side optical coupler modulates the light provided from the base station side by adjusting the drive current of the semiconductor optical amplifier and transmits the modulated optical signal to the base station side optical terminal. Therefore, the light source is not installed in the subscriber-side optical connector to secure the wavelength stability and the light output stability and can be implemented at low cost.

Description

Subscriber side optical connector of passive optical subscriber network {Optical network unit in passive optical network}

The present invention relates to a wavelength division multiplexing passive optical subscriber network using a wavelength division multiplexing and demultiplexing device. More particularly, the present invention relates to a wavelength division multiplexing passive optical subscriber network capable of economically constructing a passive optical subscriber network. A subscriber side optical connector is provided.

Passive optical subscriber networks of wavelength division multiplexing / demultiplexing methods have attracted attention as next generation subscriber networks for the high-speed, high-capacity information age. Passive optical subscriber network of wavelength division multiplexing system can provide each subscriber with a very high speed and a large amount of information by assigning individual wavelengths.In spite of these advantages, the cost of network construction, especially subscriber side optical connector (Optical) Due to the price problem of Network Unit (ONU), economic feasibility has not been secured yet. In the passive optical subscriber network of the wavelength division multiplexing method, the subscriber side optical connector is individually required for each subscriber, so that the price and mass supply problem of the optical connector must be solved for practical use.

The highest cost portion of the subscriber optical connector is the configuration of the individual light sources and the packaging costs for their stable operation. In the passive optical subscriber network of wavelength division multiplexing, wavelength stability and optical output stability of transmission / reception light become the most important technical elements.In case that the subscriber-side optical connector has a light source individually, the wavelength stability and optical Output stability can be secured. In the case of an optical line terminal (OLT) of a base station, the conditions of use can be expected to be very stable, but in the case of a subscriber-side optical connector, the conditions of use are very variable according to the environment of each subscriber. Therefore, in order to secure not only the wavelength stability of the optical connector but also the light output stability, a separate temperature control device or a wavelength monitoring and adjusting device is required in the optical connector, and a high packaging technology is required. As such, the cost required to secure the operational stability of the optical connector acts as an increase factor in the subscriber-side optical connector price, which ultimately makes practical use of the wavelength division multiplex passive optical subscriber network. Therefore, for the practical use of the wavelength division multiplex passive optical subscriber network, the implementation of a subscriber side optical connector that can operate stably in a subscriber use environment and can be configured at low cost must be technically solved.

The passive optical subscriber network of the conventional wavelength division multiplexing scheme will now be described with reference to FIGS.

Referring to Fig. 1, a base station side optical terminal is composed of a broadband light source 1, a wavelength demultiplexer 2, an optical modulator 3 and a wavelength multiplexer 4, and the subscriber side optical connector 5 emits light. It consists of a diode (LED) and an optical filter.

Light generated by the broadband light source 1 is separated into wavelengths for each channel in the wavelength demultiplexer 2, and the optical modulator 3 modulates the light separated into wavelengths for each channel to generate an optical signal. The optical signal generated by the optical modulator 3 is transmitted to the subscriber side via the optical fiber via the wavelength multiplexer 4. On the other hand, the optical filter of the subscriber-side optical connector 5 separates the light of the channel wavelength from the broadband light generated from the light emitting diode (LED), and multiplexes it with the wavelength multiplexer 6 and transmits it to the base station side through the optical fiber.

The wavelength division multiplexing passive optical subscriber network uses a broadband light source (1) and a wavelength demultiplexer (4) to make a light source for each channel without using an expensive advanced light source for the base station side optical terminal. The optical signal is generated by an indirect modulation method using a separate optical modulator (3) rather than direct modulation. In this case, since the base station side light source 1 is a broadband light source, the channel wavelength width becomes wider, and thus high speed transmission or long distance transmission is impossible. In addition, there is no cost savings since the actual price of the optical modulator 3 used for indirect modulation is never low compared to the price of advanced light sources such as DFB laser diodes or DBR laser diodes. In addition, the cost can be reduced by using a direct-modulation light emitting diode in the subscriber-side optical connector 5, but the broadband width of the light source is limited by the wavelength width of the optical filter due to the broadband light emission characteristics of the light emitting diode. The light source is formed, making high speed transmission and long distance transmission impossible. On the other hand, since a general optical filter has a temperature dependency in which a wavelength changes with temperature, a separate temperature stabilization device is required to secure wavelength stability of an optical terminal of a subscriber because the wavelength of the light source changes with temperature. In addition, in order to maintain the output of the light source emitted from the broadband light source or the light emitting diode at the same level as the laser diode, an expensive optical amplifier is required.

Referring to FIG. 2, the broadband light generated by the broadband light source 11, which is the basic light source on the subscriber side, is incident to the wavelength demultiplexer 13 through the optical circulator 12, and the wavelength demultiplexer 13. The channel is separated and input to the FP laser diode 14. In this case, the light input to the FP laser diode 14 has a wavelength distribution with respect to the channel wavelength by the wavelength demultiplexer 13. Therefore, the FP laser diode 14 oscillates within the channel wavelength range by the wavelength locking phenomenon in which the oscillation mode is fixed in the input wavelength spectrum, thereby operating as a light source of the channel wavelength. The optical signal for information transmission is generated in a direct modulation scheme in the FP laser diode 14.

The wavelength division multiplexing passive optical subscriber network achieves cost reduction by using a relatively inexpensive FP laser diode 14 for a subscriber side optical connector. However, since the oscillation mode of the FP laser diode 14 is all within the spectral band width of each channel of the wavelength demultiplexer 13, the oscillation mode has a plurality of oscillation modes. Therefore, mode dispersion due to a plurality of oscillation modes is limited to high speed and long distance transmission. In addition, since the wavelength of the oscillation mode changes within the spectrum of the input light source according to the change in the operating temperature of the FP laser diode 14, the wavelength and the light output of the oscillation mode change, and mode hopping occurs under a specific condition. And ultimately, the wavelength stability and the light output stability of the light source cannot be secured. Therefore, in order to secure the operational stability of the FP laser diode 14, a separate temperature control device such as a TEC cooling device is necessary. In addition, in the conventional network structure, a separate broadband light source and an optical circulator must be installed on the subscriber side, and a stable space and an auxiliary device such as a power source for operating the same must be secured. In addition to the optical demultiplexing device for separating and receiving the light transmitted from the base station for each channel, each subscriber additionally needs a demultiplexing device which serves as a filter for separating the broadband light source into each subscriber light source. The disadvantage of not sharing the demultiplexer for reception is inevitable.

Referring to FIG. 3, the broadband light generated by the broadband light source 21, which is the basic light source on the subscriber side, is incident to the wavelength demultiplexer 23 through the optical circulator 22, and the wavelength demultiplexer 23. Each channel is separated and input to the reflective optical amplifier 24. In this case, the light of each channel wavelength determined by the filter action of the wavelength demultiplexer 23 is amplified by the reflective optical amplifier 24 and then reflected again, and is then multiplexed by the wavelength multiplexer 23 to be optical circulators. It is transmitted to the base station side via 22.

The wavelength division multiplex passive optical subscriber network is intended to solve the light output instability at the subscriber side, which is a problem of the prior art by not providing a light source to each subscriber side optical connector. However, ultimately, since the broadband light source is used as the basic light source of the subscriber side separately from the base station light source, it is necessary to secure the operational stability of the broadband light source in order to secure optical wavelength stability and light output stability. In particular, in such a conventional network structure, since a broadband light source and an optical circulator must be separately installed on the subscriber side, a stable space and an auxiliary device such as a power source for operating the same are also required. In addition, since the spectral band width of the channel used is determined by the wavelength multiplexer, it becomes a broadband light source, thereby limiting the transmission distance or transmission speed in the long distance high speed transmission. In addition to the optical demultiplexing device for receiving and transmitting the light transmitted from the base station by channel, the demultiplexing device, which acts as a filter for separating the broadband light source into each light source of the subscriber, is additionally needed. There is a drawback in that the demultiplexer cannot be shared with the receiver.

Therefore, in the present invention, the subscriber side of the wavelength division multiplex passive optical subscriber network can solve the above disadvantages by causing the subscriber side optical connector to generate an optical signal using the light provided from the light source of the base station side optical terminal (OLT). The object is to provide an optical connector.

In order to achieve the above object, the subscriber side optical coupler of the wavelength multiplex type passive optical subscriber network according to the present invention is an optical coupler for providing an incident or output path of an optical signal, and a semiconductor optical fiber having both ends connected to two output terminals of the optical coupler, respectively. And an optical detector for detecting an optical signal output through the optical coupler to the outside, and when receiving the optical signal, the incident optical signal is separated from the optical coupler and then amplified by the semiconductor optical amplifier, respectively. Is detected, and when the optical signal is transmitted, light from an external light source is provided to the semiconductor optical amplifier through the optical coupler, and the optical signal generated by the modulation is transmitted to the outside.

In addition, the subscriber side optical coupler of the wavelength multiple passive passive optical subscriber network according to the present invention for achieving the above object is an optical coupler for providing an incident or exit path of the optical signal, the optical coupler connected to one output end of the optical coupler And a semiconductor optical amplifier having an input terminal connected to the other output terminal of the optical coupler, and when an optical signal is received, the incident optical signal is detected by the optical detector after being separated from the optical coupler, and the optical signal is transmitted. When the light from the external light source is provided to the semiconductor optical amplifier through the optical coupler, the optical signal generated by the modulation is configured to be reflected and transmitted to the outside.

A loop mirror connected to an output terminal of the semiconductor optical amplifier and reflecting the optical signal is further provided, or a monitoring optical detector for detecting the operation of the semiconductor optical amplifier is further provided.

The output terminal of the semiconductor optical amplifier is characterized in that the total reflection coating.

The semiconductor optical amplifier is characterized in that the antireflection coating on at least one of the input terminal and the output terminal.

The semiconductor optical amplifier is characterized in that the gain medium is divided into a gain region and a modulation region, a high current is applied for the gain region, and a driving current is adjusted for the modulation region.

The external light source is a light source of the base station side optical terminal, the semiconductor optical amplifier is characterized in that the gain is modulated in accordance with the adjustment of the drive current.

The subscriber side optical connector is integrated on the optical waveguide platform.

The subscriber side optical connector of the present invention amplifies and modulates the light provided from the light source of the base station side optical terminal with a semiconductor optical amplifier to generate an optical signal. The semiconductor optical amplifier generates an optical signal by modulating light by a method of adjusting a driving current or the like. Since the light provided from the base station side optical terminal is secured in wavelength and output stability, by sharing it as a light source, the subscriber side optical connector can secure wavelength and output stability without a separate stabilization device. Therefore, it does not use a separate light source and a temperature control device for securing operational stability, and does not require a high packaging cost, so it is possible to configure a subscriber side optical connector at low cost.

If a low-cost FP laser diode or the like is employed to form a low cost subscriber-side optical connector, the transmission speed and the transmission distance will be limited. Therefore, in the conventional subscriber-side optical connector, the spectral band width of the light source is very narrowly managed to enable high-speed transmission or long-distance transmission. For this purpose, an expensive light source such as a DFB laser or a DBR laser is employed. However, since the subscriber-side optical connector of the present invention shares and uses an advanced light source built in the base station-side optical terminal, high-speed and long-distance transmission is possible without a separate light source.

Since the subscriber side optical connector of the present invention is configured to amplify, modulate and retransmit the light provided from the light source of the base station side optical terminal, there is no need to individually determine the wavelength of the subscriber side optical connector. Conventional subscriber-side optical terminals use terminals of different wavelengths separately, and therefore, a plurality of substitutes for different wavelengths should be provided in preparation for a failure, but one type of substitute for the subscriber-side optical connector according to the present invention. Only may be provided.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

4 is a block diagram illustrating a passive optical subscriber network of a wavelength multiplexing method according to a preferred embodiment of the present invention.

The light source of the base station side optical terminal 40 is composed of laser diodes (LD lambda 1 to LD lambda n) 41 having wavelengths for respective channels. The optical signal modulated by the integrated modulation scheme in the laser diode 41 is sent to the wavelength division multiplexer 42, and the optical signal multiplexed in the wavelength division multiplexer 42 is the optical circulator 45 and the optical fiber 46. It is transmitted to the subscriber side via. On the other hand, the optical signal received from the subscriber side via the optical fiber 46 is separated from the transmission light in the circulator 45, and then input to the wavelength division demultiplexer 44, each of the wavelength division demultiplexer 44 The signal is detected by being separated into the channels and input to the photo detectors PD (λ1) to PD (λn) 43.

On the other hand, the wavelength multiplexed optical signal transmitted from the base station side optical terminal 40 is inputted to the wavelength division demultiplexer 48 of the subscriber side through the optical fiber 46, and divided into wavelengths for each channel, and then each subscriber side optical signal. It is transmitted to the connector (ONU 1 to ONU n) 47. The subscriber side optical connector 47 receives the optical signal through the built-in optical detector. On the other hand, in order to transmit the optical signal from the subscriber side receives the light that does not carry the signal provided from the base station side to generate the optical signal, and reflects the generated optical signal through the mirror and transmits to the base station side. At this time, the subscriber-side optical connector 47 modulates the light provided from the base station side to generate an optical signal. Preferably, a semiconductor optical amplifier can be used for optical modulation, and the driving current of the semiconductor optical amplifier is adjusted. Amplification and modulation of light can be realized simultaneously. The light transmitted from each subscriber side optical connector 47 is multiplexed by the wavelength division multiplexer 48 and transmitted to the base station side optical terminal 40.

In the passive optical subscriber network of the wavelength division multiplex proposed in the present invention, the subscriber side optical connector 47 is not provided with a light source requiring a separate light oscillation. That is, since light is received in a manner of sharing the light source 41 of the base station side optical terminal 40, and an optical signal is generated and transmitted, an efficient optical subscriber network can be configured. In general, the base station side optical terminal has a very stable management environment, and because all channels are managed in a batch, the management cost burden per channel is very low compared to the individual management cost in the subscriber side optical connector. Therefore, in the optical subscriber network proposed by the present invention, the use environment for stable operation of the light source is managed only at the base station side, and the subscriber side does not need a separate stabilization device for stabilizing the operating wavelength and light output of the light source. In addition, the subscriber side can configure the optical subscriber network using only the wavelength multiplexer and the optical interconnector in the subscriber's home, and therefore, the broadband light source and the separate space and power supply for stably operating the subscriber's home are not required. Can configure an optical subscriber network.

5A to 5C are diagrams for describing a preferred embodiment of a subscriber side optical connector according to the present invention shown in FIG.

The subscriber side optical connector 47 of the present invention can be configured by combining an optical modulator, a semiconductor optical amplifier, an optical detector, an optical coupler, and other individual components, but in this case, the packaging cost of the individual components is duplicated, thereby increasing the manufacturing cost. . Accordingly, the present invention utilizes a hybrid integrated method in which each component is mounted on a optical waveguide platform in a chip state in order to enable low-cost and mass production of subscriber-side optical connectors.

Referring to FIG. 5A, the optical signal received from the base station side optical terminal 40 is separated through the waveguide type optical coupler 55 formed on the optical waveguide platform 51 and then integrated in a flip chip or the like. Incidents are respectively provided at both ends of the amplifier SOA 52. The optical signal amplified by the semiconductor optical amplifier 52 is again output upward through the waveguide optical coupler 55. At this time, a part of the output light is incident on the photo detector 54 to receive the optical signal. The optical coupler 55 provides an entrance or exit path of the optical signal, and outputs the optical signal received from the base station side optical terminal 40 into two optical signals. The semiconductor optical amplifier 52 may be configured, for example, as a mirror in the form of a loop made of an optical waveguide on the optical waveguide platform 51, and an optical amplifier is configured in the loop mirror to amplify and re-reflect light. Can be lost.

In order to transmit the optical signal, the semiconductor optical amplifier 52 receives light in a state where no signal provided from the light source 41 of the base station side optical terminal 40 is loaded, and the semiconductor optical amplifier 52 receives a laser diode driver ( An optical signal is generated by modulating the incident light in accordance with the signal provided from 56). The signal modulation is performed by gain modulation according to the drive current adjustment of the semiconductor optical amplifier 52. At this time, if the anti-reflective coating 53 on both ends of the semiconductor optical amplifier 52 can freely enter and exit the optical signal and prevent the oscillation of light.

Referring to FIG. 5B, the optical signal received from the base station side optical terminal 40 is separated through the waveguide optical coupler 65 formed on the optical waveguide platform 61 and then integrated by a flip chip or the like. Incident on the 64 and the semiconductor optical amplifier 62, respectively, the optical detector 64 receives the optical signal. The optical coupler 65 for providing an entrance or exit path of the optical signal is output by separating the optical signal received from the optical terminal 40 on the base station side into two optical signals.

In order to transmit the optical signal, the semiconductor optical amplifier 62 receives light in a state where no signal provided from the light source 41 of the base station side optical terminal 40 is loaded, and the semiconductor optical amplifier 62 receives a laser diode driver ( An optical signal is generated by modulating the incident light in accordance with the signal provided from 66). At this time, if the anti-reflective coating 63 on both ends of the semiconductor optical amplifier 62, it is possible to freely enter and exit the optical signal. In addition, when the optical waveguide loop mirror 67 is formed at the rear end of the semiconductor optical amplifier 62, the optical signal received from the base station side is reflected by the mirror 67 and passes through the semiconductor optical amplifier 62 again, thereby amplifying the optical signal. This can be done. The signal modulation is performed by a laser diode (LD) integrated modulation scheme which is generally used, and an optical signal is generated by modulating a gain by adjusting a driving current of the semiconductor optical amplifier 62. In addition, if necessary, the gain medium of the semiconductor optical amplifier 62 is divided into a gain region and a modulation region, a high current for high gain is applied to the gain region, and the driving current of the modulation region is properly adjusted to provide an effective optical signal modulation. It becomes possible.

Referring to FIG. 5C, the optical signal received from the base station side optical terminal 40 is separated through the waveguide type optical coupler 75 formed on the optical waveguide platform 71 and then integrated by a flip chip or the like. Incident on the 74 and the semiconductor optical amplifier 72, the optical signal is received by the photo detector 74. The optical coupler 75 for providing an entrance or exit path of the optical signal is output by separating the optical signal received from the optical terminal 40 at the base station side into two optical signals.

In order to transmit the optical signal, the semiconductor optical amplifier 72 receives light in a state where no signal provided from the light source 41 of the base station side optical terminal 40 is loaded, and the semiconductor optical amplifier 72 receives a laser diode driver ( An optical signal is generated by modulating the incident light in accordance with the signal provided from 76). At this time, if one side of the semiconductor optical amplifier 72 is the anti-reflective coating (73a) and the other side is a total reflection coating (73b) it can reflect the light from the back of the semiconductor optical amplifier (72). In this case, it is possible to monitor the transmission state of the semiconductor optical amplifier 72 by integrating the monitoring optical detector chip 77 for sensing the operation state of the semiconductor optical amplifier 72. However, since the transmission state monitoring of the subscriber side optical connector 47 can be performed at the base station side, the above-described monitoring optical detector 77 is not necessarily required.

By configuring the subscriber side optical connector 47 as described above, it is possible to efficiently share the light source 41 of the base station side optical terminal 40 with the subscriber side optical connector 47. Since the same optical network is completely shared, it is possible to construct a low-cost, economical wavelength division multiplexing optical subscriber network.

Although the present invention has been described in detail with reference to the above preferred embodiments, the present invention is not limited to the above embodiments, and various modifications may be made by those skilled in the art within the scope of the technical idea of the present invention. Do.

As described above, according to the present invention, the following effects can be expected.

First, it is possible to secure the wavelength stability and optical output stability of the subscriber-side optical connector without a separate operation stabilization device. Conventionally, an expensive operation stabilization device or an advanced packaging technique is required to secure operational stability of the subscriber side optical connector, but according to the present invention, the subscriber side optical connector can be constructed more economically.

Secondly, since the subscriber-side optical connector generates an optical signal using the advanced light source of the base station-side optical terminal, high speed and long distance transmission are possible without additional costs. Conventionally, since the oscillation wavelength width of the light source of the subscriber side optical terminal must be managed very narrowly for high speed transmission or long distance transmission, an expensive advanced light source such as a DFB laser or a DBR laser has been employed. By sharing the light source, high speed and long distance transmission are possible without additional cost.

Third, subscriber-side optical connectors do not need to determine channel wavelengths individually. In the conventional subscriber-side optical connector, a plurality of substitutes should be provided for each wavelength according to the number of wavelengths used in preparation for a failure, but according to the present invention, one type of substitute may be provided to prepare for a failure.

Fourth, in the optical subscriber network of the present invention, the subscriber side includes only the wavelength multiplexer and the optical interconnector in the subscriber's home. Therefore, since the broadband light source and a separate space or a power supply for operating the same are not required outside the subscriber's house, the optical subscriber network can be configured at low cost.

1 to 3 is a block diagram illustrating a conventional wavelength multiplex passive optical subscriber network.

Figure 4 is a block diagram illustrating a wavelength multiplex passive optical subscriber network according to an embodiment of the present invention.

5A to 5C are block diagrams for explaining an embodiment of a subscriber side optical connector according to the present invention;

<Explanation of symbols for the main parts of the drawings>

1, 11, 21: light source 2, 13, 23, 44, 48: wavelength demultiplexer

3: light modulator 4, 6, 42: wavelength multiplexer

5, 47: subscriber side optical connector 12, 22, 45: optical circulator

14, 41: laser diode 24: reflective optical amplifier

40: base station side optical terminal 43, 54, 64, 74, 77: photo detector

46: optical fiber 51, 61, 71: optical waveguide platform

52, 62, 72: semiconductor optical amplifiers 53, 63, 73a: antireflective coating

55, 65, 75: waveguide optical coupler 56, 66, 76: laser diode driver

67: loop mirror 73b: total reflection coating

Claims (9)

An optical coupler providing an entry or exit path of an optical signal, A semiconductor optical amplifier having both ends connected to two output terminals of the optical coupler, It includes a photo detector for detecting an optical signal output to the outside through the optical coupler, When receiving an optical signal, the incident optical signal is separated from the optical coupler and then amplified by the semiconductor optical amplifier, respectively, and detected by the optical detector, When transmitting an optical signal, light from an external light source is provided to the semiconductor optical amplifier through the optical coupler, and the optical signal generated by the modulation is configured to be transmitted to the outside. Subscriber side optical connector. An optical coupler providing an entry or exit path of an optical signal, An optical detector coupled to one output of the optocoupler, A semiconductor optical amplifier having an input coupled to the other output terminal of the optocoupler; When receiving an optical signal an incident optical signal is detected by the photo detector after being separated from the optical coupler, In the case of transmitting an optical signal, light from an external light source is provided to the semiconductor optical amplifier through the optical coupler, and an optical signal generated by modulation is configured to be transmitted to the outside. Photoelectric connector. 3. The subscriber side optical connector of a wavelength multiplex passive optical subscriber network according to claim 2, further comprising a loop mirror connected to an output of said semiconductor optical amplifier and reflecting said optical signal. 3. The subscriber side optical connector of a wavelength multiplex passive passive optical subscriber network according to claim 2, wherein the output end of the semiconductor optical amplifier is totally coated. 3. The subscriber side optical connector of a wavelength multiplex passive optical subscriber network according to claim 2, further comprising a monitoring optical detector for sensing the operation of the semiconductor optical amplifier. The semiconductor optical amplifier of claim 1 or 2, wherein the gain medium is divided into a gain region and a modulation region, a high current is applied for the gain region, and a driving current is adjusted for the modulation region. A subscriber side optical connector of a wavelength multiplex passive optical subscriber network. 3. The subscriber-side optical connector of a wavelength multiplexing passive optical subscriber network according to claim 1 or 2, wherein the external light source is a light source of a base station side optical terminal. 3. The subscriber side optical connector of a wavelength multiplex passive optical subscriber network according to claim 1 or 2, wherein the semiconductor optical amplifier has a gain modulated according to adjustment of a driving current. 3. The subscriber-side optical connector of a wavelength multiplex passive optical subscriber network according to claim 1 or 2, wherein the subscriber-side optical connector is integrated on an optical waveguide platform.