KR102535583B1 - WDM Access Network Structure - Google Patents

Abstract

Accordingly, the present invention provides an existing WDM access network configuration method and a method of doubling or quadrupling the number of lines between both ends by reducing the wavelength interval on the communication path by two or four times compared to the price of the end optical wavelength. present.
According to the present invention, according to the present invention, it is possible to reduce the wavelength spacing by 2 or 4 times in the link while maintaining the DWDM of 100 GHz wavelength spacing at both ends of the communication, thereby reducing the difficulty of the wavelength spacing of the terminal wavelength multiplexing devices. Since more lines are provided while maintaining the WDM access network, it is possible to construct a cost-effective WDM access network.

Description

WDM Access Network Structure

The present invention relates to a wavelength division multiplexing (WDM) access network structure, and relates to a method capable of increasing the number of lines compared to the existing generalized line (communication path capable of simultaneous transmission and reception) configuration.

In order to effectively use optical fibers in long-distance communication, WDM technology has been introduced and used for a long time. In general, WDM multiplexes a plurality of light wavelengths at one location using a WDM filter and sends them through a single optical fiber, and separates the multiplexed light wavelengths at another location using a WDM filter. Here, since each wavelength serves as a communication channel, as many optical fibers as the number of multiplexed wavelengths can be effectively used.

Compared to 4th generation LTE technology, 5th generation LTE technology drastically reduces the number of fronthaul optical signal lines as the base station's wireless service radius (cell size) is drastically reduced, so the use of dense wavelength division multiplexing (DWDM) technology is common. is being considered However, many telecommunication operators are already using various types of WDM access networks as shown in FIG. 1 to build a 4G LTE fronthaul, and apply Coarse Wavelength Division Multiplexing (CWDM) technology as a wavelength multiplexing method. Therefore, in order to build a 5G LTE fronthaul, a method of expanding the number of lines by including a plurality of DWDM wavelengths in each CWDM band as shown in FIG. 2 is being considered.

Intervals between optical wavelengths to be multiplexed are standardized as 100 GHz intervals or 50 GHz intervals in the International Standard (ITU-T). Of these, the 100 GHz wavelength spacing is more widespread than the 50 GHz wavelength spacing, so it can be seen that it has a relatively advantageous aspect in commercial applications. On the other hand, in a WDM network, the narrower the wavelength interval, the higher the number of lines, so the narrower the wavelength interval, the more advantageous it is in terms of optical fiber usage efficiency.

KR 10-1738722 B1

The present invention has been devised to solve this problem, and as an embodiment, the wavelength interval on the transmission line is narrowed to 50 GHz or 25 GHz while maintaining the 100 GHz wavelength interval (terminal wavelength interval) at both ends of the optical communication, so that eventually per optical fiber Its purpose is to provide a network structure capable of increasing the number of lines.

In order to achieve the above object, the WDM access network structure according to the present invention includes: a WDM transmission filter for multiplexing transmission wavelengths at a predetermined wavelength interval at one end of a communication path; a WDM receiving filter that separates received light wavelengths at regular wavelength intervals; A circulator that directs the transmitted light wavelengths to the other end and inputs the light wavelengths received at the other end to the WDM receiving filter, and the other end of the communication path includes the same configuration to perform a symmetric process, A plurality of light wavelengths transmitted from one end of the communication path and a plurality of light wavelengths transmitted from the other end of the communication path have a difference in wavelength by half of the distance between the light wavelengths of the terminals.

One end of the communication path and the other end of the communication path each further include an interleaver, and each end is composed of two light wavelength groups, and the light wavelengths between the two groups differ by half the distance between the end light wavelengths. The light wavelengths of one end and the light wavelengths of the other end may differ by a quarter of the distance of the end light wavelengths.

According to the present invention, according to the present invention, while maintaining DWDM of 100 GHz wavelength spacing at both ends of communication, the wavelength spacing can be reduced by 2 or 4 times in the link, thereby reducing the difficulty of wavelength spacing of end-wavelength multiplexing devices. Since more lines are provided while maintaining the same, cost-effective WDM access network construction is possible.

1(a) is a WDM access network configured in a ring shape based on WDM. 1(b) is a WDM access network configured in the form of a tree based on WDM. One end is the communication station 100 and includes a WDM filter 110 for multiplexing wavelengths. The other end is located in a remote location and consists of a plurality of ADFs (311 ~, add drop filter) and RU (511 ~, Remote Unit), which is a remote end communication device. On the other hand, in the tree-type structure, the WDM filter 400 is configured instead of the ADF 311- at the remote location.
2 illustrates the concept of a DWDM over CWDM wavelength multiplexing method in which each CWDM channel is further divided into DWDM wavelength intervals to arrange wavelengths in the CWDM method.
3 shows a form in which wavelengths multiplexed at 100 GHz wavelength intervals are connected by a conventional method at both ends of a communication channel in a DWDM over CWDM structure.
4 shows a DWDM over CWDM method proposed in this patent as an embodiment. (a) shows a structure that realizes DWDM with 50 GHz intervals in the link while DWDM with 100 GHz wavelength intervals at both ends. (b) describes the multiplexed wavelength interval in detail along with the communication direction.
5 shows a DWDM over CWDM scheme proposed as another embodiment in this patent. (a) shows a structure realizing DWDM with 25 GHz intervals in the link, while DWDM with 100 GHz wavelength intervals at both ends. (b) describes the multiplexed wavelength interval in detail along with the communication direction.

Hereinafter, embodiments of the present invention will be described in detail so that those skilled in the art can easily practice with reference to the accompanying drawings. However, the present invention may be implemented in many different forms and is not limited to the embodiments described herein. And in order to clearly explain the present invention in the drawings, parts irrelevant to the description are omitted, and similar reference numerals are attached to similar parts throughout the specification.

In adding reference numerals to components of each drawing, it should be noted that the same components have the same numerals as much as possible even if they are displayed on different drawings. In addition, in describing the present invention, if it is determined that a detailed description of a related known configuration or function may obscure the gist of the present invention, the detailed description will be omitted.

Also, terms such as first, second, A, B, (a), and (b) may be used in describing the components of the present invention. These terms are only used to distinguish the component from other components, and the nature, order, or order of the corresponding component is not limited by the term. Throughout the specification, when a part 'includes' or 'includes' a certain component, it means that it may further include other components without excluding other components unless otherwise stated. . In addition, terms such as '??unit' and 'module' described in the specification mean a unit that processes at least one function or operation, which may be implemented by hardware, software, or a combination of hardware and software. Hereinafter, A preferred embodiment of the present invention will be described with reference to the accompanying drawings.

The present invention uses 100 GHz wavelength multiplexing at both ends of the communication path and realizes DWDM with a more detailed 50 GHz or 25 GHz wavelength spacing in the link, thereby increasing the number of lines while maintaining the wavelength multiplexing burden of communication equipment at both ends. It relates to a technology that can be equipped, and an application example is a CWDM over DWDM wavelength multiplexing structure, and an optimal application example is a 5G LTE fronthaul.

One end multiplexes a plurality of wavelengths arranged at 100 GHz intervals and transmits them to the other end, and the other end multiplexes the wavelengths arranged at 100 GHz intervals, but the center wavelengths of each wavelength are transmitted to the center of one end. Shift the wavelengths by 50 GHz. Connect the DWDM filter for transmission and the DWDM filter for reception with a circulator. This circulator directs the multiplexed transmission wavelengths to the other end, and directs the multiplexed reception light wavelengths transmitted from the other end to the receiving DWDM filter, so that the transmission wavelengths and the reception wavelengths are separated. At the other end, the transmission DWDM filter and the reception DWDM filter are connected with a circulator like the one end so that the same function as the one end is performed. From this configuration, wavelengths are multiplexed at 100 GHz wavelength intervals at both ends, whereas wavelengths are multiplexed at 50 GHz intervals at the link between both ends, thereby realizing the advantages of 100 GHz high-density wavelength multiplexing and 50 GHz high-density wavelength multiplexing at the same time. .

In addition, by adding an interleaver (a device that alternately arranges wavelengths) in the above structure, ultra-high-density wavelength multiplexing with a 25 GHz wavelength interval is realized in the link, so that both ends maintain high-density wavelength multiplexing with a 100 GHz wavelength interval while linking It is possible to further increase the number of phases. That is, at one end, a DWDM filter for first transmission with a wavelength interval of 100 GHz and a DWDM filter for second transmission with a wavelength interval of 100 GHz with a center wavelength shifted by 50 GHz are connected as a first interleaver, and at one end, a DWDM filter for transmission of 100 GHz A first receiving DWDM filter having a wavelength interval and a second receiving DWDM filter having a wavelength interval of 100 GHz having a center wavelength shifted by 50 GHz are connected by a second interleaver. The first interleaver and the second interleaver are connected by a circulator. On the other hand, the other end also has a DWDM filter, an interleaver, and a circulator in a symmetrical structure with one end, and the wavelengths of 100 GHZ intervals of this end are moved by 25 GHz compared to the 100 GHz wavelengths of the other end. let it

3 shows an embodiment in which wavelengths multiplexed at a wavelength interval of 100 GHz are connected by a conventional method at both ends of a communication channel in a DWDM over CWDM structure. One end includes transmission wavelengths 250 at 100 GHz wavelength intervals, a DWDM filter 130 that multiplexes transmission wavelengths, reception light wavelengths 260 at 100 GHz wavelength intervals, a DWDM filter 140 separating reception light wavelengths, It consists of a CWDM filter (120). Another CWDM filter 410 located at the other end and corresponding to the CWDM filter at one end, DWDM filters 420 and 430 located at the remote place and corresponding to the DWDM filters in the communication station 100 consists of N DWDM optical wavelengths 250 multiplexed at 100 GHz intervals in the communication station 100 are transmitted to the other end through one channel of the CWDM filter, and N The DWDM optical wavelengths 260 are transmitted to the communication station 100 through another channel of the CWDM filter. Accordingly, in this embodiment, since two channels of the CWDM filter are used to construct a line for bidirectional communication, the number of lines per channel of the CWDM filter is N/2. Here, N means the number of optical wavelengths multiplexed at 100 GHz wavelength intervals.

4 shows a DWDM over CWDM method proposed in this patent as an embodiment. In addition to the components of FIG. 3, circulators 160 and 460 are further included in the communication station 100 and remote locations, respectively. The N transmission light wavelengths 250 multiplexed at 100 GHz intervals in the communication station 100 go through the circulator 160 to a remote location through one channel of the CWDM filter 120, and pass through the CWDM filter 410 at the remote location. Through the same channel as the CWDM filter 120 in the communication station, the circulator 460 in the remote area passes through the DWDM filter 420 in the remote area.

On the other hand, the process of transmitting light wavelengths from the remote location to the communication station is performed symmetrically with the process of transmission from the communication station to the remote location. There is a difference between the N transmission wavelengths 250 multiplexed at 100 GHz intervals and each center wavelength by 50 GHz. 4(a) more clearly explains this wavelength arrangement, that is, light wavelengths at 100 GHz intervals are transmitted in one direction, and light wavelengths shifted at 50 GHz are transmitted in the opposite direction, even at 100 GHz intervals, Accordingly, the 100 GHz wavelength intervals 250 and 260 are maintained at each communication end, but the wavelengths are arranged at 50 GHz wavelength intervals 280 in the link. Accordingly, in this embodiment, since one channel of the CWDM filter is used to construct a line for bidirectional communication, the number of lines per channel of the CWDM filter is N. Here, N means the number of wavelengths multiplexed at 100 GHz wavelength intervals.

5 shows a DWDM over CWDM scheme proposed as another embodiment in this patent. In addition to the components of FIG. 4 , interleaver 170 , 171 , 440 , 441 are further included in the communication station 100 and the remote location, respectively. In the communication station 100, N transmission light wavelengths 250 multiplexed at intervals of 100 GHz and another N transmission light wavelengths 251 are multiplexed in the interleaver 170. The transmission light wavelengths 251 of one group and the transmission light wavelengths 252 of another group have a center wavelength difference of 50 GHz. Accordingly, when the two groups 251 and 252 pass through the interleaver 170, the wavelengths are multiplexed at intervals of 50 GHz. The multiplexed transmission light wavelength goes to a remote destination through one channel of the CWDM filter 120 via the circulator 160, and from the CWDM filter 410 in the remote area through the same channel as the CWDM filter 120 in the communication station to the remote destination. It is input to the interleaver 440 through the circulator 460 in . The light wavelengths passing through the interleaver 440 are separated into two wavelength groups 251 and 252 and pass through the DWDM filters 420 and 421, respectively.

On the other hand, the process of transmitting light wavelengths from the remote location to the communication station is performed symmetrically with the process of transmission from the communication station to the remote location. There is a difference between the N transmission wavelengths 251 and 252 multiplexed at 100 GHz intervals and each center wavelength by 25 GHz. 5(a) more clearly explains this wavelength arrangement, that is, the light wavelengths of two groups at 100 GHz intervals 270 are transmitted in one direction, where the wavelengths between the two groups have a difference of 50 GHz (290 ), and the two groups of light wavelengths equally spaced at 100 GHz but shifted by 25 GHz (295) are propagated in opposite directions. Accordingly, 100 GHz wavelength intervals (251, 252, 261, 262) are maintained at each communication end, but wavelengths are arranged at 25 GHz wavelength intervals (295) in the link. Accordingly, in this embodiment, since one channel of the CWDM filter is used to construct a line for bidirectional communication, the number of lines is doubled, so the number of lines per channel of the CWDM filter is 2N. Here, N means the number of wavelengths of one group (251 or 252) multiplexed at 100 GHz wavelength intervals.

Although the present invention has been described in detail with reference to preferred embodiments, the present invention is not limited to the above embodiments, and the technical field to which the present invention belongs without departing from the gist of the present invention claimed in the following claims. Anyone skilled in the art will extend the technical spirit of the present invention to the extent that various variations or modifications are possible.

According to the method for constructing a WDM access network according to an embodiment of the present invention, multiplexing of a certain wavelength interval is used at both ends of a communication path and WDM of a finer wavelength interval is realized in a link, thereby reducing the burden of wavelength multiplexing on communication equipment at both ends. While maintaining, it is possible to provide more lines. As an application example, a CWDM over DWDM wavelength multiplexing structure can be cited. As an optimal application example, it can be a 5th generation LTE fronthaul, so the possibility of commercialization or business is sufficient, and it is an invention with industrial applicability because it can be clearly implemented in reality. am.

100: communication bureau
120: CWDM filter
130,131: DWDM filter
140,141: DWDM filter
160: circulator
170,171: interleaver
210: 20nm spacing CWDM
250: 100 GHz spacing DWDM
251: N transmission light wavelengths multiplexed at the communication station or N reception light wavelengths at a remote location
252: N different transmission light wavelengths multiplexed at the communication station or other N receiving light wavelengths at a remote location
260: 100GHz spacing DWDM
261: N receiving optical wavelengths at the communication station or N transmitting optical wavelengths multiplexed at a remote location
262: N different reception light wavelengths at the communication station or other N transmission light wavelengths multiplexed at a remote location
270: 100 GHz spacing DWDM
280: 50GHz spacing DWDM
290: 50GHz spacing DWDM
295: 25GHz spacing DWDM
410: CWDM filter
420,421: DWDM filter
430,431: DWDM filter
440,441: interleaver
460: circulator

Claims (2)

As a WDM access network structure,
At one end of the communication path,
a WDM transmission filter that multiplexes transmission wavelengths at regular wavelength intervals;
a WDM receiving filter that separates received light wavelengths at regular wavelength intervals;
A circulator for directing the transmitted light wavelengths to the other end and inputting the light wavelengths received at the other end to the WDM receiving filter,
The other end of the communication path also performs a symmetrical process including the same configuration,
The plurality of light wavelengths transmitted from one end of the communication path and the plurality of light wavelengths transmitted from the other end of the communication path have a wavelength difference by half of the terminal light wavelength interval,
WDM access network structure. According to claim 1,
One end of the communication path and the other end of the communication path each further include an interleaver,
Each end consists of two light wavelength groups,
The light wavelengths between these two groups differ by half the longitudinal light wavelength interval,
The difference between the light wavelengths of one end and the light wavelengths of the other end is a quarter of the distance between the end light wavelengths.
WDM access network structure characterized by.

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