TW200820535A - Power supplier for fiber network remote switch controller - Google Patents

Abstract

Disclosed is a power supplier for fiber network remote switch controller which is applicable to be integrated to a fiber network system to serve a function of supplying power through a remote switch controller to the fiber network system. The invention features setting up a light source at a local end, and sending the beam emitted by the light source through the fiber transmission line to the remote switch controller. Furthermore, the light power of the beam is converted into electricity at the remote site and stored at a electricity storage module. By so doing, this invention enables the remote switch controller to accept the power stored at the electricity storage module and to be driven for executing the switch operation when the main channel of the fiber transmission line malfunctions and to call for switching to a backup channel.

Description

200820535 " Description of the Invention: [Technical Field] The present invention relates to a fiber optic network technology (particularly related to a fiber optic network remote switching controller power supply device, which can It is applied to a fiber-optic network system to provide a remote power supply-supplied function to the remote switching controller in the fiber-optic network system. '^ [Prior Art] • Optical network technology (optical netw〇rking) is a communication technology that uses optical fibers as a signal transmission medium, which allows different information systems (for example, computer systems or telephone systems). An analog or digital signal is transmitted between the laser beams. Since the laser beam has a higher frequency than the electronic signal and the radio wave, its transmission speed is much larger than that of the conventional wired and wireless communication systems. Passive Optical Network (P〇N) is a type of fiber network technology that is widely used by individuals and small business users. In practice, the p〇N passive domain network system uses a single fiber transmission line to provide two-way data transmission for network users. κ However, in practical applications, the single-fiber bidirectional passive optical network is easy to interrupt the data transmission function due to only one fiber break or other factors. One solution to this problem is to configure a primary channel and an alternate channel in the fiber transmission line; wherein the primary channel is initially set to the beam transmission path and when the primary channel fails, such as a wire break 5 19754 200820535 Switching the beam transmission path to the alternate channel. To achieve this function, the solution adopted is to set a local end switching control H and a remote switching control ^ at the two ends of the optical fiber transmission line. Switching the beam transmission path to the alternate channel when the primary channel fails. "In the case of the Bayesian application, the remote data processing device in the p〇N passive optical network system is a passive device (ie, it does not have its own Power supply), so how to make the remote switching controller receive power to perform the switching operation becomes a problem that needs to be solved first. [Summary of the Invention] The main purpose of this test is to provide an optical fiber. Network remote switching controller power supply unit that provides a remote power supply to the remote switching controller of the fiber network system The fiber optic network remote switching controller power supply device of the present invention is designed to be integrated into a fiber optic network system, in particular, a passive optical network system (Passive 0ptical Netw〇rk, p〇N), The utility model provides a remote power supply function for the remote switching controller in the driven optical network system. In the physical architecture, the optical network remote switching control crying power supply device of the present invention at least includes 2 decentralized units: (4) a local end energy supply unit, and (B) a remote energy storage unit; wherein the local end energy supply unit is integrated into the local end switching controller, and the at least includes: (A1 a light source module 'which generates a laser beam; and (A2) a beam multiplexing process, the module coupled to the beam output channel of the local fiber optic network data processing device for the light source The laser beam generated by the module is multiplexed in 19754 6 200820535: the beam wheel of the material processing equipment is transmitted to the laser beam through the fiber-optic transmission wheel at the deaf end (four) 1; ^ :: to: far Switching the controller, and at least: = taking a core group, which can intercept the laser light transmitted by the first beam interception through the fiber transmission line ... ^) a photoelectric energy conversion module, the basin may = ^_ group The energy of the intercepted laser beam is converted into an electrical 'and (8))-electric energy storage module, which can store the converted electrical energy of the group and utilize the switching action performed by the controller. The material switching feature features the fiber network remote (10) controller power supply for the subordinate ====, the local end 'and transmits the beam of the light source to the remote switching controller; and further After the light energy of the light beam is converted into electrical energy, it is stored in an electrical energy storage board. This method can cause the failure of the main channel of the optical fiber transmission line::: When the remote switching controller is responsible for switching it to the alternate channel, the switching control benefit can be provided by the energy storage module. The drive of the power supply performs this switching action. [Embodiment] Hereinafter, an embodiment of a power supply device for a fiber network remote switching controller of the present invention will be described in detail with reference to the accompanying drawings. Fig. 1 shows the application of the fiber optic network remote switching controller power supply unit 60 of the present invention. As shown in the figure, the optical network remote switching controller power supply device 60 of the present invention comprises two points in a specific implementation: 19754 7

The local end fiber network data processing device 1 is, for example, a fiber optic terminal device (〇ptical Une OLT) in the p〇N passive optical network system, and the remote fiber network data processing device 2 is, for example, an optical fiber. As shown in FIG. 2, the local end switching controller 40 includes, for example, two optical switches 41, 200820535, a unit, a local power supply unit (10), and The remote energy storage unit is configured to be integrated into a fiber optic network system, such as a Passive 〇ptical Netw〇rk (p〇N), and the fiber network system includes a local fiber a network data processing device, a remote fiber network data processing device 20, a fiber optic transmission line 3, a local end switching control, and a remote switching controller 5; wherein the optical fiber transmission line The road has a main channel 31 and a backup channel 32, for example, two optical fibers, wherein - the optical fiber serves as the main channel 31, and the other fiber serves as the standby channel %; and the local end switching controller 4 The remote switching controller When used in the optical fiber transmission line 3〇 failure of the main channel 31, the beam transmission path to switch to its backup path 32. For specific applications, 42; and as shown in FIG. 3, the remote switching controller 5 also includes two optical switches 51, 52. In actual operation, the local end fiber network data processing device 1〇 and the remote fiber network data processing device 2〇 can mutually transmit the 彳 号 beam through the optical fiber transmission line 30, wherein the local end fiber The network data processing device 10 has a beam output channel (Γχ) 11 and a beam wheeling channel (and Χ) 12' and the remote fiber network data processing device 20 also has a beam output channel (Γχ) 21 and A beam input channel (i?x) 22. Local end light 8 19754 200820535 "The fiber network data processing device 10 can shoot out from its beam output channel - the signal beam (10) U1)' its wavelength and the far end fiber optic network data processing device 20 can take its beam out of the channel (7 &gt ;) 21 emits a signal beam αρ(23) 'having a wavelength of 23. The local end switching controller and the remote switching controller 50 are initially set to the local end fiber optic network data processing device 10 and the far The end fiber network data processing device 2 is connected to the main channel 31 of the fiber transmission line 30, so that the signal beam is small and the failure occurs in the main channel 31 through the main channel 31. Immediately responding to switching both the local end fiber network data processing device 1 and the remote fiber network data processing device to the standby port 32 so that the two can still pass through in this situation. When the alternate channel 32 transmits the signal beam to each other to perform the switching action, the power required by the local end switching controller 4 can be directly supplied by the local fiber network data processing device 1; Since the controller 50 does not have a power source itself, it is responsible for supplying power by the fiber network remote switching controller power supply device of the present invention. As shown in Fig. 1, the fiber network of the present invention is remotely located. The basic architecture of the switching controller power supply device 60 includes at least two decentralized units A) a local end energy supply unit 100; and (B) a remote energy storage unit 200; wherein the local end energy supply unit 1 The system is integrated into the local switching controller 4〇, and the remote energy storage unit 2 is used to integrate to the remote switching controller 50. As shown in Fig. 2, the internal end of the local power supply unit 100 The architecture includes at least (A1) light source module 110; and (A2)-beam multiplexing processing module 19754 9 200820535 _ 120, and as in Figure 3, the internal structure of the remote energy storage unit 2〇〇 (B1) "Bundle Intercept Module 2l (), (B2) - Photoelectric Energy Conversion Module, 乂 and (B3) Energy Storage Module 230. The following describes the individual attributes and functions of these components. The light source module 110 is, for example, a laser light emitter, which can receive local light. The voltage & drive provided by the network data processing device 1G generates a laser beam (^2) having a wavelength of ^2, and; ί2 off; ^off; ί3.: beam multiplexing processing module 120 is, for example, a Wavelength Division Multiplexer (WDM), which is coupled to a beam output channel of the local end fiber network data processing device 1 to generate the light source module 110. The laser beam 〇i> (^2) is multiplexed/mastered into the beam output channel U, thereby passing the laser beam (and 2) together with the k-beam ΟΡ(;ί)) through the fiber The transmission line 3 is transmitted to the remote switching controller 50. The beam intercepting module 210 is also, for example, a Wavelength Division Multiplexer (WDM), which can be coupled to the beam output of the remote fiber network data processing device 20 as shown in FIG. The inlet channel 22, or the main channel 31 coupled to the fiber transmission line % as shown in FIG. 4, is used to intercept the laser beam transmitted from the local end energy supply unit 1 through the fiber transmission line 30. &p( 2 2). The photoelectric energy conversion module 220 can convert the energy of the laser beam 2 2) intercepted by the beam intercepting module 21 上述 into electrical energy. In a specific implementation, the photoelectric energy conversion module 220 can be, for example, a photo sensor or a solar cell, and can receive a photo-sensing current when receiving the laser beam 0P (^2). /#. The power storage module 230 can receive the photo-sensing current k output by the photoelectric energy conversion module 220, and store the photo-sensing current/noisy electric energy, and use the electric energy to drive the remote switching controller 50. The switching action performed. In a specific implementation, the power storage module 230 can be, for example, a rechargeable battery unit or a capacitor, and can store the photo-induced current/noisy electric energy output by the photoelectric energy conversion module 220, and the m The power is outputted as a drive voltage to simultaneously supply power to the two optical switches 51, 52 in the remote switch_controller 50. In addition to the embodiments shown in FIGS. 3 and 4, the remote energy storage unit 200 can also include an alternate channel beam intercepting group 240 coupled to the fiber optic transmission line as shown in FIG. The backup channel 32 of 30 is configured to intercept the laser beam transmitted from the local end energy supply unit 1 through the spare channel 32 of the optical fiber transmission line after the beam transmission path is switched from the main channel 31 to the backup channel 32. 〇p(;lj, and the intercepted laser beam 〇p(22) is similarly transmitted to the photoelectric energy conversion module to the amount conversion process. Hereinafter, the embodiments shown in FIGS. 2 and 3 are used. Explain the overall operation mode of the fiber-optic network remote switching controller power supply device 6 in this month. The lower μ is as shown in Figure 2 and Figure 3. At the beginning of the actual operation, the local end = change The controller 4G and the remote switching controller % are initially set to, respectively, to the primary communication 31, so that the local end fiber network data processing device 1〇, the extended fiber network data processing device 2 Can be transmitted through the main channel Η 19754 11 200820535 The k-beam (9P(2)), (9 households (A3). At the same time, the local light source module 11 in the local end energy supply unit 100 is also activated to generate a laser beam 0 corpse (乂2), the wavelength is 2 2, and 2 2 is closed and 妾A 3 , and the laser beam 〇P(^2) is injected into the multiplex mode by the beam multiplexing processing module 120 (ie, WDM). To the beam output channel n, the laser beam OP ("2) is transmitted to the remote switching controller 5 through the fiber transmission line 30 together with the signal beam 0 /> ι}. In the controller 50, the laser beam (J 2) is intercepted by the optical P-beam intercepting module 210 (ie, WDM) and transmitted to the photoelectric energy conversion mode, and 220, the photoelectric ring 1 conversion module 220 responsively converts the energy of the laser beam 2) into a photo-sensing current and stores the electrical energy of the photo-sensing current into the electrical energy storage module 230. Thereafter, when the main channel 31 of the optical fiber transmission line 30 fails, , the local end switching controller 4〇 and the remote switching controller 5() need to simultaneously switch the beam transmission path from the main channel 31 to the standby channel. When the local end switching controller 40 can accept the power supply provided by the local end fiber optic network bedding processing device 10 to perform the switching, the switching voltage is performed by the power storage module to perform the switching. In the embodiment shown in FIG. 5, after the beam transmission path is switched from the main channel 31 to the backup channel 32, the remote energy storage unit is still fine: the spare beam is worn. Group 24G to take the alternate channel ^ transmitted ^ = the field beam shape 2), and the intercepted laser beam & / > (2) is similarly transmitted to the photoelectric energy conversion module 22 转换 converted into Energy storage 12 19754 200820535 to the storage module 23G ° This allows the remote switching controller 5G to switch to the main switch after the main pass phantom repair needs to perform a switching operation of one, , and f Μ n± Pass: Two: T-switch controller 50 can accept the power storage module - the pen room to perform this reply switching action. In summary, the present invention provides a fiber optic network remote "power supply device, which can be applied to the integration of the "fiber network system" with the == system to provide a remote switching controller power supply settings - source The local end transmits the y money emitted by the light source to the remote switching controller through the optical fiber transmission line; and further converts the light energy of the light beam into electrical energy at the 遂 end, and then stores the light energy into a power storage module. . This method can be used in the main channel of the optical fiber transmission line. t is required to be switched by the remote switching controller to the standby P'. (4) The switching controller can accept the power provided by the power storage module. Drive to perform this switching action. The invention thus has excellent advancement and utility. The above is only the preferred embodiment of the present invention and is not intended to limit the scope of the technical content of the present invention. The 6th aspect of the present invention is broadly defined in the scope of the following claims. If any other person's technical entity or method is identical or equivalent to the one defined in the following patent application, it will be considered to be included in the scope of the patent application of the present invention. . BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is an application schematic diagram for displaying the application mode of the power supply device for the remote switching controller of the optical fiber network of the present invention; 19754 13 200820535 ... FIG. 2 is a schematic diagram of the architecture for displaying The local end energy supply single architecture in the power supply device of the optical fiber network terminal switching controller of the present invention; FIG. 3 is a schematic diagram of the architecture for displaying the power supply device of the optical network remote switching controller of the present invention. A first embodiment of the internal architecture of the remote energy storage unit; FIG. 4 is a schematic diagram showing the internal architecture of the remote energy storage unit in the power supply device of the remote network switching controller of the present invention. The second embodiment; FIG. 5 is a schematic diagram showing the third embodiment of the internal architecture of the remote energy storage unit in the power supply installation s of the fiber network remote switching controller of the present invention. [Main component symbol description] 10 Local end fiber network data processing device 11 Beam output channel (7>) 12 Beam input channel (and X) 20 Remote fiber network data processing device 21 Beam output channel (Γχ) 22 Beam input Channel (i?x) 30 fiber transmission line 31 main channel 32 alternate channel 40 local end switching controller 41 optical switcher 19754 14 200820535 42 50 51 52 60 100 110 optical switcher remote switching controller optical switcher optical switching The optical fiber network remote switching controller power supply device of the present invention, the local end energy supply unit light source module 120, the beam multiplexing processing module (WDM), the 远端200 remote energy storage unit 210, the beam intercepting module (WDM) 220 photoelectric Energy conversion module 230 power storage module 240 alternate channel beam intercepting module (WDM) 15 19754

Claims (1)

200820535 X. Patent application scope: L-type fiber-optic network remote switching controller power supply device, which can be integrated into a money network system, and the fiber-optic network system is provided with a local-end fiber-optic network data processing device, Remote optical fiber network data processing. Also provided for optical fiber transmission line, a local end switching controller, and - terminal switching control H · 'the towel is connected to the local optical fiber network data processing device and the optical fiber transmission line Remote fiber-optic network data processing equipment, and Gu Shi m,,, The utility model has an active channel and a standby channel; the fiber, and the circuit alternate channel switching control device at least comprise: a local energy supply unit and a remote energy storage unit; wherein the local power supply unit is integrated Switching control to the local end is 'and it includes at least: a light source module that can generate a laser beam; and a network processing group that is coupled to the beam output of the local fiber optic device a channel for injecting the laser beam of the source mode=produced into the local end stop “...the beam exit channel” by which the laser beam of the light source passes through the fiber transmission line And transmitting to the terminal switching controller; and wherein the remote energy storage unit is integrated into the remote switching, the at least comprising: a beam intercepting, which can be worn by the local end energy supply unit. 19954 16 200820535 a laser beam transmitted from a fiber optic transmission line; an optoelectronic energy conversion module that converts energy of the laser beam intercepted by the beam intercepting module into electrical energy; and an electrical energy storage module The utility model can store the electric energy converted by the photoelectric energy conversion module level, and use the electric energy to drive the switching action performed by the remote switching controller. 2; • The optical fiber network as described in claim 1 The remote control of the road is controlled by a power supply device, wherein the optical network system is a passive optical network (Passive Optical Network, Ρ0Ν). • The remote switching of the optical network as described in claim 1 The control is a power supply device, wherein the local fiber network data processing device is a optical line terminal (0LT), and the port fiber data processing device is a fiber network device (Optical Network Unit) , 0NU). 4. The fiber-optic network remote switching control _ state power supply device according to claim 1, wherein the light source module is a laser light emitter. 5. If the patent application scope is the first item The optical network remote switching controller power supply device, wherein the beam multiplexing processing module is a wavelength division multiplexer (Wavelength Division Multiplexer, WDM) 0 y • The remote switching control of the optical network described in item 1 of the patent application is a power supply device, wherein the beam intercepting module is a Wavelength Division Multiplexer (WDM). The fiber optic network remote switching controller power supply device of claim 1, wherein the beam intercepting module is coupled to the beam input channel of the optical network data processing device of the far-end 19774 17 7 200820535 8· ί^ . Tl. The fiber optic network remote switching control described in item 1 of the patent scope is provided. The beam intercepting module is coupled to the main channel of the fiber transmission line. The optical fiber network remote switching control and the Yiyuan source supply device described in item i of the patent scope of May are wherein the photoelectric energy conversion module is a light sensing type. Μ The fiber-optic network remote switching system according to the invention of claim i, wherein the photoelectric energy conversion module is a: a positive battery. u.= The remote control of the optical network as described in claim 1 is a power supply device, wherein the electrical energy storage module is a rechargeable battery unit. The optical network remote switching control described in item 1 of the patent application scope is a power supply device, wherein the electrical energy storage module is a capacitor. 3. The remote switching control of the optical network as described in claim 1 is a power supply device, wherein the remote energy storage unit further comprises: an alternate channel beam intercepting module coupled to the optical fiber transmission line The alternate channel of the path is used to intercept the laser beam transmitted from the local end energy supply unit through the alternate channel of the optical fiber transmission line after the beam transmission path is switched from the primary communication to the backup channel, and the intercepted beam is intercepted The laser beam is transmitted to the photoelectric energy conversion module to be converted into energy and stored in the electrical energy storage module, so that the remote switching control can accept the power provided by the electrical energy storage module to perform a recovery switching action. . 19754 18