KR101672394B1 - Wavelength tuning time measurement apparatus and method for the multi-wavelengths passive optical network - Google Patents

Abstract

A wavelength tuning time measurement apparatus and method for a multi-wavelength passive optical communication network are disclosed. An apparatus for measuring a wavelength tuning time according to an exemplary embodiment of the present invention is an apparatus for measuring a wavelength tuning time of a wavelength variable light source included in a multi-wavelength passive optical network (MW PON) system. The apparatus includes an optical filter for passing only light having a predetermined wavelength bandwidth, And a photodetector for detecting the light passing through the optical filter. The wavelength tuning time is a time from the time when the wavelength change signal is transmitted to the variable wavelength light source to the time when the photodetector continuously starts to sense light.

Description

TECHNICAL FIELD [0001] The present invention relates to a wavelength tuning time measurement apparatus and method for a multi-wavelength passive optical network,

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a Passive Optical Network (PON), and more particularly, to an apparatus and method for measuring a wavelength tuning time in a Multi-Wavelength Passive Optical Network (MW PON).

As a result of the development of optical communication technology and the rapid increase of Internet service demand, basic researches on the optical access network have been conducted since the early 2000s. As a result, FTTH (Fiber To The Home (FTTO), and Fiber To The Office (FTTO). At the same time, the proliferation of mobile IP terminals such as smart phones and tablet computers, the commercialization of IPTV services, and the proliferation of multimedia broadcasting / streaming services over the Internet, In order to cope with traffic increase, researches on next generation high-speed, high-capacity optical access network technology are being actively carried out.

Time Division Multiplexing (TDM) scheme and wavelength division multiplexing (WDM) schemes are applied to optical network technology to efficiently provide services to more subscribers with limited network resources have. Recently, optical subscriber networks (TDM) and WDM techniques have been studied. Attempts have also been made to integrate orthogonal frequency division multiplexing (OFDM) techniques, which are currently used in wireless communications, with optical network technology, which is an example of a hybrid technique in a broad sense.

In the WDM system or the hybrid system, communication can be performed using a plurality of wavelength bands, i.e., multiple wavelengths. As the use of the Internet increases and the demand for multimedia contents explosively increases, it is an important problem to increase the bandwidth of the network in both wired optical subscriber network and wireless network or both wired and wireless networks. Is attracting attention as a way to solve this problem. Accordingly, it is possible not only to provide a high-speed communication service to a large number of subscribers, but also to facilitate communication capacity and expansion of subscribers, and excellent communication security. Therefore, the multi-wavelength passive optical network (MW PON) employing the WDM scheme or the hybrid scheme is attracting great attention in the next generation high-speed, high-capacity optical network system.

The multi-wavelength passive optical network (MW PON) system includes a service provider apparatus (hereinafter, also referred to as an OLT) located at the central office (CO) side, a plurality of subscribers (Hereinafter also referred to as " ONUs ") and one or more optical multiplexers / demultiplexers or optical intensity splitters, Or an optical distribution unit (ODN)). In such an MW PON system, the network configuration may be changed depending on the type of the light source used, for example, a spectrum-divided light source, a wavelength-locked light source, or a wavelength independent light source. And the wavelength of the light used in the MW PON system can be fixed or variable between the OLT and the specific ONU.

2. Description of the Related Art In a WDM PON or a hybrid PON using a multi-wavelength passive optical communication network, for example, a wavelength multiplexing method, active research has been conducted on the use of a wavelength variable light source to efficiently utilize wavelength resources. The use of wavelength tunable light sources can solve the problems that may arise in producing, installing, and managing the light sources by wavelength. In addition, efficient and user-friendly services such as load balancing by assigning wavelengths dynamically or by quickly changing to a different wavelength when the link is switched can be used to establish a new link.

In order to establish communication between the OLT and each ONU using a wavelength variable light source, a wavelength tuning process or a wavelength tuning process is required in which the wavelength variable light source stably generates light of a wavelength different from the original wavelength. The wavelength tuning time may vary depending on the wavelength tuning process in the MW PON system or the wavelength interval between the channels to be changed. Therefore, wavelength tuning time of tunable light source should be considered in the link establishment procedure to the new wavelength between OLT and ONU. In particular, from the viewpoint of the MW PON system in which an optical intensity distributor other than a wavelength-dependent MUX is provided in the ODN, if the wavelength tuning time of the tunable light source is not sufficiently considered, the wavelength- It can be operated to affect channels of other wavelengths. Therefore, apparatus and procedures are required to clearly define the wavelength tuning time of the tunable light source and accordingly to measure the wavelength tuning time.

One aspect of the present invention is to provide an apparatus and method for measuring wavelength tuning time for measuring wavelength tuning time of a variable wavelength light source when an output wavelength of a wavelength variable light source provided in a multi-wavelength passive optical network is to be changed .

According to an aspect of the present invention, there is provided an apparatus for measuring wavelength tuning time according to an embodiment of the present invention includes a wavelength tuning time measuring apparatus for measuring a wavelength tuning time of a wavelength variable light source included in a multi-wavelength passive optical network And a photodetector for detecting light passing through the optical filter, wherein the wavelength tuning time is a time from when the wavelength change signal is transmitted to the wavelength variable light source And may be the time taken until the light begins to be continuously detected by the photodetector. The center of the predetermined wavelength bandwidth may be centered on an ITU-T channel grid.

According to an aspect of the embodiment, the transmission bandwidth of the optical filter may correspond to a channel wavelength range, which is a wavelength range required to operate with the performance required for the MW PON system.

According to another aspect of the present invention, the transmission bandwidth of the optical filter may correspond to a channel frequency range, which is a frequency range required to operate with the performance required by the MW PON system.

According to another aspect of the embodiment, the transmission bandwidth of the optical filter may correspond to a maximum spectral excursion.

According to another aspect of the present invention, the optical filter may be a multilayer thin film filter, a chirped optical waveguide bridgeline filter, a chirped optical fiber bridgeline filter, or an AWG (Arrayed Waveguide Gating) filter.

According to another aspect of the embodiment, the center wavelength of the optical filter may match the ITU-T channel grid. And the center wavelength of the optical filter may be changed.

According to another aspect of the embodiment, the wavelength tuning time may be utilized in a link establishment procedure or a link change procedure between the service provider apparatus and the subscriber apparatus of the MW PON system. For example, the present invention can be utilized in the case of moving to a newly allocated wavelength channel in the middle or after a process of activating an ONU of an MW PON system. As another example, when the OLT is included in a MW PON system, in order to operate some OLTs in the power save mode, the operation is stopped and the ONUs connected thereto are moved to move the wavelength channel to communicate with another OLT operating It can also be utilized. As another example, the present invention may be applied to a case where the wavelength resource is dynamically allocated in the MW PON system, or the output wavelength of the wavelength variable light source is drifted or is well maintained within a predetermined grid. .

According to an aspect of the present invention, there is provided a wavelength tuning time measuring method for measuring a wavelength tuning time of a tunable light source included in a multi-wavelength passive optical network (PON) system, Changing a wavelength of light generated from the wavelength variable light source, sensing light passing through an optical filter for passing only light of a predetermined wavelength bandwidth, and detecting a time from when the wavelength changing signal is transmitted to the wavelength variable light source And calculating the time taken until the start of the continuous light sensing in the sensing step as the wavelength tuning time. The center of the predetermined wavelength bandwidth may be aligned with an ITU-T channel grid.

According to an aspect of the embodiment, the transmission bandwidth of the optical filter may correspond to a channel wavelength range, which is a wavelength range required to operate with the performance required for the MW PON system.

According to another aspect of the present invention, the transmission bandwidth of the optical filter may correspond to a channel frequency range, which is a frequency range required to operate with the performance required by the MW PON system.

According to another aspect of the embodiment, the transmission bandwidth of the optical filter may correspond to a maximum spectral excursion.

According to another aspect of the present invention, the optical filter may be a multilayer thin film filter, a chirped optical waveguide bridgeline filter, a chirped optical fiber bridgeline filter, or an AWG (Arrayed Waveguide Gating) filter.

According to another aspect of the embodiment, the center wavelength of the optical filter may match the ITU-T channel grid. And the center wavelength of the optical filter may be changed.

According to another aspect of the embodiment, the wavelength tuning time may be utilized in a link establishment procedure or a link change procedure between the service provider apparatus and the subscriber apparatus of the MW PON system. For example, the present invention can be utilized in the case of moving to a newly allocated wavelength channel in the middle or after the activation process of the ONU of the MW PON system. As another example, when the OLT is included in a MW PON system, in order to operate some OLTs in the power save mode, the operation is stopped and the ONUs connected thereto are moved to move the wavelength channel to communicate with another OLT operating It can also be utilized. As another example, the present invention may be applied to a case where the wavelength resource is dynamically allocated in the MW PON system, or the output wavelength of the wavelength variable light source is drifted or is well maintained within a predetermined grid. .

According to another aspect of the present invention, the method may further include confirming whether the center wavelength of the optical filter is adjusted to the center wavelength of the target channel to be changed before the step of changing the wavelength of the wavelength variable light source .

According to the embodiment of the present invention, it is possible to measure a wavelength tuning time of a wavelength variable light source provided in a multi-wavelength passive optical network (MW PON). By using the wavelength tuning time, You can choose a light source. Particularly, when the wavelength tuning time measuring apparatus or method according to the present invention is used, the MW PON system can not affect the channel of another wavelength when changing the wavelength of the wavelength variable light source, Communication can be established between the ONU and the OLT after the change is completely completed.

1A is a block diagram illustrating an example of a multi-wavelength passive optical network system including a wavelength tunable light source.
1B is a block diagram illustrating another example of a multi-wavelength passive optical network system including a wavelength variable light source.
2 is a block diagram showing an example of the configuration of a wavelength tunable light source and its wavelength tuning time measuring apparatus included in the MW PON system.
FIG. 3 is a view for explaining a principle of measuring a wavelength tuning time in the wavelength tuning time measuring apparatus of FIG. 2. FIG.
FIG. 4 is a view for explaining another principle of measuring a wavelength tuning time in the wavelength tuning time measuring apparatus of FIG. 2. FIG.
5 is a flowchart illustrating a method of measuring a wavelength tuning time of a tunable light source included in an MW PON system according to an embodiment of the present invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings. The terms used are terms selected in consideration of the functions in the embodiments, and the meaning of the terms may vary depending on the user, the intention or custom of the operator, and the like. Therefore, the meaning of the terms used in the following embodiments is defined according to the definition when specifically defined in this specification, and unless otherwise defined, it should be interpreted in a sense generally recognized by those skilled in the art.

An apparatus or method for measuring wavelength tuning time according to an embodiment of the present invention to be described later can be applied to measure a variable tuning time or a wavelength tuning time of a wavelength variable light source used in a multi-wavelength passive optical network (PON) system. The wavelength tunable light source is a light source capable of generating light of different wavelengths, such as a wavelength division multiplexing passive optical communication network (WDM PON) system, a hybrid PON combining a TDM scheme and a WDM scheme, for example, a TWDM PON or an OFDM PON system Can be used. The wavelength tuning time in the MW PON system means that when the wavelength variable light source changes the wavelength of the existing light to start generating light of another wavelength, the light emitted from the wavelength variable light source is stabilized, This is the time required to achieve this. Here, the wavelength within the desired range may be a wavelength range in which the central wavelength is aligned with the ITU-T channel grid.

Changing the wavelength of a tunable light source in an MW PON system may be required in many cases. For example, it may be necessary to change the wavelength of the tunable light source when moving to a newly allocated wavelength channel during or after the activation of the ONU of the MW PON system. As another example, when the OLT is included in a MW PON system, in order to operate some OLTs in the power save mode, the operation is stopped and the ONUs connected thereto are moved to move the wavelength channel to communicate with another OLT operating It may be necessary to change the wavelength of the wavelength variable light source. As another example, when the wavelength resource is dynamically allocated in the MW PON system, or when the output wavelength of the tunable light source drifts or is held well within a predetermined grid, the wavelength tunable light source A wavelength change may be required.

The wavelength tuning process in the MW PON system can be subdivided into the following processes. For example, the wavelength tunable light source of the ONU may receive a wavelength variable command from the OLT using a PLOAM or OMCI channel, a wavelength change may be performed, and a subsequent procedure may be performed after the wavelength change is completed .

The wavelength tuning operation of the wavelength tunable light source may vary depending on the type and configuration of the multi-wavelength passive optical network (MW PON), but may occur in various cases. For example, an ONU (more specifically, a tunable light source included in the ONU) newly activated in the activation process of the ONU may need wavelength tuning to the allocated predetermined wavelength. And even if the assigned wavelengths are changed to different wavelengths after the ONU has been activated, the ONU may need wavelength tuning to the newly assigned wavelengths. The change of the allocated wavelength may be performed by an administrator of the network system for the purpose of managing wavelength resources or may be performed for the purpose of improving performance by load balancing of the network system .

A multi-wavelength passive optical network (MW PON) having such a wavelength variable light source can be utilized in various types of networks as well as existing optical communication networks. An example of this is utilized as a backbone network for a detachable wireless base station. In the separate type wireless base station, the radio equipment controller (Remote Controller) and the radio equipment (Remote End, RE) are installed separately from each other. The radio equipment controller (REC) performs digital baseband signal processing and radio base station control and management, and the radio equipment (RE) performs analog and wireless RF signals such as filtering, modulation, frequency conversion and amplification Send and receive. In addition, the separate wireless base station can place the radio equipment (RE) only inside the cell and the radio equipment control station (REC) at the central office, thereby achieving efficient cell operation. In addition, one or more radio equipment controller (REC) and a plurality of radio equipment (RE) can be networked with a multiwavelength passive optical communication network (MW PON). Hereinafter, the architecture of such a multi-wavelength passive optical network (MW PON) will be briefly described first.

1A is a block diagram illustrating an example of a multiwavelength passive optical network (MW PON) system having a wavelength variable light source, and FIG. 1B is a block diagram illustrating another example of a multiwavelength passive optical network (MW PON) system . 1A and 1B, there is a difference in whether the number of service provider apparatuses such as the OLT 10 is one (FIG. 1A) or plural (FIG. 1B) And a WDM unit 12 connected to the OLT 10 of FIG. The wavelength tunable light sources 11 and 31 may be provided in each of the OLT 10 and the ONU 30 as a subscriber device. In FIGS. 1A and 1B, a block diagram is shown for convenience of illustration.

The MW PON system shown in FIGS. 1A and 1B is a WDM PON system in which a plurality of subscriber units, that is, an ONU 30 does not share wavelengths, or a plurality of TDM PON systems are stacked in one OLT, May be a system that is assigned a different wavelength or may be a TDM PON system stacked by wavelength that can support traffic load balancing with dynamic wavelength tuning. Alternatively, the MW PON system may be a hybrid PON system combining all or some of the characteristics of the system described above. The MW PON system can be classified into any one of a plurality of classes based on the tunability and / or the tuning speed of wavelength of the ONU.

Referring to FIGS. 1A and 1B, the MW PON system includes an OLT 10, an ODN 20, and an ONU 30. The OLT 10 corresponds to a service provider apparatus, the ODN 20 corresponds to a local node or an optical distribution network, and the ONU 30 corresponds to a subscriber apparatus. One or more OLTs 10 are located on the central office (CO) side to transmit downlink data (? _A ,? _{A + 1} , ...,? _{A + n} ) from each of a plurality of ONUs 30, and the receiving the uplink data _{(λ b, λ b + 1} , ..., λ b + m) from the ONU (30), respectively.

The wavelength variable light sources 11 and 31 are included in the ONU 10 and the OLT 30 of the MW PON system, respectively. For example, the wavelength tunable light sources 11 and 31 may be located in the OLT 10 and / or in the plurality of ONUs 30, respectively. In this embodiment, there is no particular limitation on the type of the variable wavelength light source, and the type of the variable wavelength light source may vary depending on the type of the MW PON system. The use of wavelength tunable light sources not only solves the problems associated with the production, installation, and management of wavelength-dependent light sources, but also dynamically assigns wavelengths to achieve load balancing, So that smooth communication can be performed.

Each of the plurality of ONUs 30 transmits and receives downlink data and uplink data to and from the OLT 10 using the allocated unique wavelength. At this time, depending on the type of the MW PON system, the ONU 30 may transmit data only within the allocated transmission time, but the present embodiment is not limited thereto.

The ODN 20 includes one or more splitter or optical multiplexer / demultiplexer (WDM mux / demux), separates and demultiplexes the downstream transmitted from the OLT 10 by wavelength, Multiplexes the upstreams received from the respective ONUs 30_1, 30_2, ..., and 30_k and transmits them to the OLT 10. The process of demultiplexing and combining / multiplexing according to the number of splitter and optical multiplexer / demultiplexer may be composed of a plurality of stages. In FIGS. 1A and 1B, IF _PON refers to an interface of a passive optical communication network. In the present embodiment, there is no particular limitation thereto.

In order to send and receive data between one or more OLT 10 and each of a plurality of ONUs 30 in the MW PON system as shown in Figs. 1A and 1B, the OLT 10 and each ONU 30_1, 30_2, ..., , ≪ / RTI > 30_k). The process of establishing the link can use PLOAM or OMCI channel. If the process of setting up the link is subdivided, the process of initializing the wavelength to be used by each ONU 30_1, 30_2, ..., In other words, it can be classified into a process of assigning a wavelength to be used by each of the ONUs 30_1, 30_2, ..., and 30_k. In the link establishment process in the MW PON system including the tunable light sources 11 and 31, the wavelength tuning process of the wavelength tunable light sources 11 and 31 (time required therefor) is also included.

In the MW PON system including the splitter-based ODN 20, the ONU (e.g., the ONU 30 - k) newly installed in the system can operate only after being assigned an initial wavelength. The initial wavelength may include the wavelength for the downstream and the wavelength for the upstream. The assignment procedure of the initial wavelength, that is, the wavelength initialization procedure is essential for the activation of each ONU 30_k. When the new ONU 30_k is installed in the ODN 20, the initial downstream wavelength and the upstream wavelength are automatically and constantly spaced between the OLT 10 and the new ONU 30_k Should be assigned. This wavelength allocation process can be executed as a part of the activation of the new ONU 30_k. In order for the new ONU 30_k to properly communicate with the OLT 10, the downstream wavelength and the upstream wavelength for this new ONU 30_k should be specified as soon as possible and wavelength tuning may be required during the activation. In the MW PON system including the AWG (Arrayed Waveguide Gating) -based ODN 20, in the ODN 20 from the OLT 10 to the ONU 30 or from the ONU 30 to the OLT 10, Only can pass. In this case, the wavelength assignment may be done during the physical installation process.

If some wavelengths in the MW PON system are idle in case of low or heavy traffic and other wavelengths are heavily loaded, the ONUs of all or some of the ONUs to which the loaded wavelengths are assigned are switched to the idle wavelength May be an example of changing the wavelength assigned to the ONU. According to this, traffic can be balanced between available wavelengths and the PON operation can be maintained in a stable state. Alternatively, if most of the wavelengths are used in the MW PON system, but the traffic is small at each wavelength, the MW PON system may be efficiently operated by reducing the wavelength used. In this case, an arbitrary port of the OLT can be turned off and the ONU can be changed into a subset of the available wavelength, thereby saving power of the OLT.

The link setting or resetting process in the MW PON system includes a wavelength tuning process, which is a process from when an OLT or ONU having a tunable light source generates light to stably oscillate light at a predetermined wavelength. The wavelength tuning or wavelength tuning of the tunable light source includes oscillating the light of the wavelength assigned to the ONU in the link establishment process in the MW PON system as well as changing the wavelength of the light oscillated to the newly allocated wavelength. To this end, a wavelength tunable light source or a tunable optical transceiver (OTRx) may be installed in the ONU and / or OLT of the MW PON system.

However, in the wavelength tuning process, the wavelength tuning time may be different in the kind, characteristic, grade, etc. of the wavelength variable light source. Therefore, the wavelength tuning time of the tunable light source provided in the MW PON system must be considered in the link establishment process between the OLT and the ONU. That is, the wavelength tunable laser to be used in the MW PON system in which the wavelength tuning is frequently performed due to the dynamic allocation of the wavelength, etc., can be a very important performance parameter of the wavelength tuning time. For example, in an MW PON system, a plurality of classes may be classified according to a wavelength tuning speed or a wavelength tuning time. Since the wavelength tuning time may vary depending on the method of measurement, a uniform method of measuring the wavelength tuning time for the variable wavelength light source and a device implementing the same are required. And the wavelength tuning time of the tunable light source must meet the time required by the MW PON system.

FIG. 2 is a block diagram showing a configuration of a wavelength tunable light source included in the MW PON system of FIG. 1A or 1B and an apparatus for measuring wavelength tuning time of the wavelength tunable light source according to an embodiment of the present invention. In FIG. 2, reference numeral 100 denotes a wavelength variable light source, reference numeral 200 denotes a wavelength tuning time measuring apparatus, and reference numeral 300 denotes an attenuator. The attenuator 300 is an optional component to reduce the magnitude of the light intensity of the tunable light source 100 when the light intensity of the tunable light source 100 is too large to prevent the optical tuner 200 from overloading . 3 and 4 are views for explaining the principle of measuring the wavelength tuning time in the wavelength tuning time measuring apparatus 200 of FIG.

Referring to FIG. 2, the tunable light source 100 may include a wavelength variable laser 110 and a wavelength variable laser driving unit 120.

The tunable laser 110 is a means for generating light in a wide range of wavelengths (or frequencies), and there is no particular limitation on the kind in this embodiment. The wavelength tunable laser 110 can generate light of a predetermined wavelength (or frequency) within the range required for the MW PON system (see FIG. 1A or 1B) in which at least the tunable light sources 11 and 31 are provided. The tunable laser 110 may generate light having a predetermined wavelength (or frequency) under the control of the tunable laser driver 120 or may be generated by changing the wavelength (or frequency) of light that has been generated .

The tunable laser driver 120 is a means for driving the tunable laser 110, and there is no particular limitation on its specific configuration. The tunable laser driver 120 may transmit information about the wavelength (or frequency) of light to be generated by the tunable laser 110 to the wavelength tunable laser 110 by including the wavelength (or frequency) change signal. The tunable laser 110 can generate light of a predetermined wavelength in accordance with the wavelength information included in the wavelength tunable laser driver 120 when the tunable laser driver 120 receives the wavelength change signal. If a wavelength (or frequency) change signal including wavelength (or frequency) information indicating the second wavelength (or frequency) is received in a state where light is generated at the first wavelength (or frequency) (Or frequency) of the light to be generated can be changed from the first wavelength (or frequency) to the second wavelength (or frequency).

The wavelength tuning time measuring apparatus 200 is a device for measuring the wavelength tuning time of the wavelength tunable light source 100. The wavelength tuning time indicates the time required for the wavelength of the light output from the variable wavelength light source 100 to fall within a predetermined bandwidth range and stabilize from the time when the light generation command or the wavelength switch command is present . Here, the predetermined bandwidth range may mean a channel wavelength range. This channel wavelength range corresponds to each channel of the MW PON system and its value can be determined according to the requirements of the MW PON system. The wavelength tuning time measuring apparatus 200 may include an optical filter 210 and a photo detector 220.

The optical filter 210 is for passing light of a predetermined bandwidth, that is, light in a channel wavelength range. The light of a predetermined bandwidth indicates light having a center wavelength coinciding with a specific ITU-T channel grid. The channel wavelength range, which is the transmission bandwidth of the optical filter 210, corresponds to a wavelength range that falls within a maximum acceptable difference centered on a nominal central frequency of the channel, and the maximum spectral excitation (maximum spectral excursion). The maximum spectral excursion refers to a range from (nominal center frequency? Maximum allowable difference) to nominal center frequency + maximum allowable difference. According to this, the optical filter 210 is a means for passing light in the range of the maximum spectral excitation. Alternatively, the transmission bandwidth of the optical filter 210 may correspond to a channel frequency range, which is the frequency range required to operate with the performance required by the MW PON system.

The optical filter 210 may be a multilayer thin film filter, a chirped optical waveguide bridgeline filter, a chirped optical fiber bridgeline filter, or an AWG (Arrayed Waveguide Gating) filter. ) May correspond to the ITU-T channel grid, which may be changed.

The photodetector 220 is a means for detecting light that has passed through the optical filter 210. That is, only light passing through the optical filter 210 among the light generated by the tunable light source 110 reaches the photodetector 220, and the photodetector 220 detects the light passing through the optical filter 210 do. There is no particular limitation on the specific kind of the photodetector 220, but a means capable of detecting whether light is received irrespective of the wavelength is sufficient.

At this time, the photodetector 220 may generate information on the time at which the light passing through the optical filter 210 starts to reach consecutively, or may use it to calculate the wavelength tuning time. That is, even if light is intermittently or temporarily received after the wavelength change command, the photodetector 220 is not utilized in the calculation of the wavelength tuning time because the light generated from the tunable light source 100 is stabilized The light that has previously passed through the optical filter 210 temporarily can be detected through the photodetector 220 (see FIGS. 3 and 4).

According to an aspect of this embodiment, the wavelength tuning time can only output the calculated value directly calculated by the photodetector 220. In this case, the photodetector 220 may transmit the time at which the wavelength change signal is input (this signal may be transmitted from the tunable light source 100, in particular, the tunable laser driver 120 to the wavelength tuning time measuring apparatus 200 For example, the wavelength tuning time measuring apparatus 200 is provided with a separate control unit (not shown), and a wavelength change signal is supplied from the controller to the photodetector 220 and the tunable laser driving unit 120) to the time when light passing through the optical filter 210 is stably sensed can be determined as the wavelength tuning time.

Alternatively, the photodetector 220 may output only information regarding the time at which light passing through the optical filter 210 is stably detected. In this case, a separate control unit provided in the wavelength tuning time measuring apparatus 200 can calculate the wavelength tuning time. In this case, it is apparent to those skilled in the art that information on the time when the wavelength change signal is generated need not be transmitted to the photodetector 220.

The tuning time measuring apparatus 200 having the configuration as shown in Fig. 2 can be used to measure the wavelength range of the optical filter 210 or the maximum spectral excitation of the optical filter 210, which is provided from the same wavelength variable light source 100 The wavelength tuning time measured according to the size may vary. Hereinafter, this will be described in more detail with reference to FIG. 3 and FIG.

3 and 4 show waveforms of light emitted from the variable wavelength light source 100 when the tunable light source 100 (see FIG. 2) tunes the wavelength from the current wavelength to the target wavelength FIG. 3 is a wave graph for the wavelength of the generated light, and FIG. 4 is a wave graph for the frequency of the generated light. FIG. 3 illustrates a case where the wavelength tuning time varies when the pass wavelength of the optical filter 210 is changed. FIG. 4 illustrates a case where the wavelength tuning time varies when the pass frequency of the optical filter 210 is changed. Show.

3, the first case case I and the second case case II are cases where the pass bandwidth of the optical filter 210 is different and the value of the second case case II, Is larger than the first case (case (I)). According to this, the tuning time for case (I), t _a of the first case is larger than the tuning time for case (II), t _b of the second case. That is, when the passband width of the optical filter 210 is set small, the tuning time of the wavelength tunable light source 100 may be longer. This means that when the channel wavelength range or the maximum spectral excitation is set smaller in the MW PON system, the tunable light source 100 takes more time to perform wavelength tuning. Therefore, in the link establishment process of the MW PON system, the wavelength tuning time of the wavelength variable light source 100 should be considered according to the channel wavelength range of the system or the size of the maximum spectrum excitation.

Referring to FIG. 4, the third case (Case III) and the fourth case (Case IV) are cases where the pass frequency range of the optical filter 210 is different, Is larger than that in the third case (case (III)). According to this, the tuning time for case (III), t _c of the third case is larger than the tuning time for case (IV), t _d of the fourth case. That is, when the pass frequency range of the optical filter 210 is set to be small, the wavelength tuning time of the tunable light source 100 may be longer.

5 is a flowchart illustrating an example of a method of measuring a wavelength tuning time of a wavelength variable light source according to an embodiment of the present invention. The flowchart shown in FIG. 5 may be performed using the tunable light source 100 and the wavelength tuning time measuring apparatus 200 shown in FIG. And the wavelength tuning time may be determined according to the algorithm described with reference to Figs. 3 and 4. Fig. Hereinafter, a method of measuring the wavelength tuning time will be briefly described in order to avoid unnecessary redundancy description. Therefore, the matters not described in detail below with respect to the method of measuring the wavelength tuning time can be applied equally to those described with reference to FIG. 2 to FIG.

Referring to FIG. 5, first, it is checked whether the center wavelength of the optical filter 210 is set to the nominal center wavelength of the target channel to be changed (S10). If the center wavelength of the optical filter 210 is properly set, the wavelength of light generated from the variable wavelength light source is changed (S11). In this step S11, it may be a process of transmitting a wavelength change signal for changing to a second wavelength by the wavelength variable light source generating the light of the first wavelength. According to this embodiment, there is no limitation on the subject of transmitting the wavelength change signal to the wavelength variable light source.

As a result of step S11, the time when the light in the predetermined channel wavelength range or the maximum spectrum excitation starts to be received continuously is measured (S12). Here, the information indicating the predetermined channel wavelength range or maximum spectrum excitation may be included in the wavelength change signal transmitted in step S11. As described above, since the light generated by the wavelength variable light source takes some time to stabilize, this step is for measuring the time taken for such stabilization.

Subsequently, the time taken from the time when the wavelength change signal is transmitted in step S11 to step S12 is calculated (S13). This time is a time that must be considered in a link establishment procedure to set up a new link in a MW PON system with a tunable light source or to reset an existing link to a link of another wavelength. According to this embodiment, it is as described above that the stabilization time can be varied according to the channel wavelength range or the maximum spectrum excitation.

The above description is only an example of the present invention, and the technical idea of the present invention should not be interpreted as being limited by this embodiment. The technical idea of the present invention should be specified only by the invention described in the claims. Therefore, it is apparent to those skilled in the art that the above-described embodiments may be modified and embodied in various forms without departing from the technical spirit of the present invention.

10: OLT 12: WDM
20: ODN 30: ONU
11, 31: wavelength tunable light source

Claims (17)

A wavelength tuning time measuring apparatus for measuring a wavelength tuning time of a wavelength variable light source provided in a multi-wavelength passive optical network (MW PON) system,
An optical filter for passing only light of a predetermined wavelength bandwidth; And
And a photodetector for sensing light passing through the optical filter,
Wherein the wavelength tuning time is a time from a time when the wavelength change signal is transmitted to the wavelength variable light source to a time when the optical detector continuously starts to detect light. The method according to claim 1,
Wherein the transmission bandwidth of the optical filter corresponds to a channel wavelength range that is a wavelength range required to operate with performance required for the MW PON system. The method according to claim 1,
Wherein the transmission bandwidth of the optical filter corresponds to a channel frequency range that is a frequency range required to operate with the performance required by the MW PON system. The method according to claim 1,
Wherein the transmission bandwidth of the optical filter corresponds to a maximum spectral excursion. The method according to claim 1,
Wherein the optical filter is a multilayer thin film filter, a chirped optical waveguide brass grating filter, a chirped optical fiber brass grating filter, or an AWG (Arrayed Waveguide Gating) filter. The method according to claim 1,
Wherein the center wavelength of the optical filter is variable. The method according to claim 1,
Wherein the wavelength tuning time is utilized in a link setting procedure or a link changing procedure between the service provider apparatus and the subscriber apparatus of the MW PON system. 8. The method of claim 7,
In the link change procedure, when moving to a newly allocated wavelength channel in the middle of or after the activation of the ONU of the MW PON system, in the MW PON system including a plurality of OLTs, In the case of stopping the operation to operate in the save mode and moving wavelength channels so that ONUs connected to the ONUs can communicate with other OLTs in operation, when the wavelength resources are dynamically allocated in the MW PON system Or whether the output wavelength of the wavelength tunable light source is drifted or maintained well within a predetermined grid. A wavelength tuning time measuring method for measuring a wavelength tuning time of a wavelength tunable light source provided in a multi-wavelength passive optical network (MW PON) system,
Changing a wavelength of light generated from the wavelength variable light source;
Sensing light passing through an optical filter for passing only light of a predetermined wavelength bandwidth; And
And calculating the time taken from the time when the wavelength change signal is transmitted to the wavelength variable light source to the time when the light is continuously sensed in the sensing step as the wavelength tuning time. 10. The method of claim 9,
Wherein the transmission bandwidth of the optical splitter corresponds to a channel wavelength range that is a wavelength range required to operate at a performance required by the MW PON system. 10. The method of claim 9,
Wherein the transmission bandwidth of the optical filter corresponds to a channel frequency range that is a frequency range required to operate with the performance required by the MW PON system. 10. The method of claim 9,
Wherein the transmission bandwidth of the optical filter corresponds to a maximum spectral excursion. 10. The method of claim 9,
Wherein the optical filter is a multilayer thin film filter, a chirped optical waveguide brass grating filter, a chirped optical fiber brass grating filter, or an AWG (Arrayed Waveguide Gating) filter. 10. The method of claim 9,
Wherein the center wavelength of the optical filter is variable. 10. The method of claim 9,
Wherein the wavelength tuning time is utilized in a link setting procedure or a link changing procedure between the service provider apparatus and the subscriber apparatus of the MW PON system. 16. The method of claim 15,
In the link change procedure, when moving to a newly allocated wavelength channel in the middle of or after the activation of the ONU of the MW PON system, in the MW PON system including a plurality of OLTs, In the case of stopping the operation to operate in the save mode and moving wavelength channels so that ONUs connected to the ONUs can communicate with other OLTs in operation, when the wavelength resources are dynamically allocated in the MW PON system , Or whether the output wavelength of the wavelength tunable light source is drifted or maintained well within a predetermined grid. 10. The method of claim 9,
Further comprising the step of confirming whether the center wavelength of the optical filter is adjusted to the center wavelength of the target channel to be changed before the step of changing the wavelength of the wavelength tunable light source.

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