WO2016101466A1 - 一种智能odn标识系统及装置 - Google Patents
一种智能odn标识系统及装置 Download PDFInfo
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- WO2016101466A1 WO2016101466A1 PCT/CN2015/077432 CN2015077432W WO2016101466A1 WO 2016101466 A1 WO2016101466 A1 WO 2016101466A1 CN 2015077432 W CN2015077432 W CN 2015077432W WO 2016101466 A1 WO2016101466 A1 WO 2016101466A1
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- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04B—TRANSMISSION
- H04B10/00—Transmission systems employing electromagnetic waves other than radio-waves, e.g. infrared, visible or ultraviolet light, or employing corpuscular radiation, e.g. quantum communication
- H04B10/07—Arrangements for monitoring or testing transmission systems; Arrangements for fault measurement of transmission systems
- H04B10/071—Arrangements for monitoring or testing transmission systems; Arrangements for fault measurement of transmission systems using a reflected signal, e.g. using optical time domain reflectometers [OTDR]
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- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04B—TRANSMISSION
- H04B10/00—Transmission systems employing electromagnetic waves other than radio-waves, e.g. infrared, visible or ultraviolet light, or employing corpuscular radiation, e.g. quantum communication
- H04B10/07—Arrangements for monitoring or testing transmission systems; Arrangements for fault measurement of transmission systems
- H04B10/075—Arrangements for monitoring or testing transmission systems; Arrangements for fault measurement of transmission systems using an in-service signal
- H04B10/077—Arrangements for monitoring or testing transmission systems; Arrangements for fault measurement of transmission systems using an in-service signal using a supervisory or additional signal
- H04B10/0771—Fault location on the transmission path
Definitions
- the embodiments of the present invention relate to the field of communications technologies, and in particular, to an intelligent optical distribution network (ODN) identification system and device.
- ODN optical distribution network
- the label used for printing/pasting/binding on the cable is easy to be scattered, lost, illegible, and the label information is found one by one to find the target end.
- the search efficiency is caused by the above characteristics. Low, error-prone and other defects.
- Technique 3 Identifying both ends of the fiber jumper by illuminating the plastic fiber.
- the technology identification method is intuitive, efficient, and accurate.
- the quartz fiber and the plastic fiber work together, the size of the fiber increases, resulting in the entire wiring system cable.
- the quartz fiber transmission service Through a quartz fiber and multiple plastic fibers integrated into a fiber jumper connector, the quartz fiber transmission service, the plastic fiber transmits identification information to transmit the identification signal.
- both technologies 1 to 3 can intuitively identify the two ends of the fiber jumper, but it is impossible to visually and visually identify whether the connectors at both ends are reliably connected or not.
- Technology 4 Because it is a quartz The optical fiber and the plurality of glass fibers are fastened by a plurality of buckles, and the physical size of the fiber jumper diameter is increased to reduce the wiring capacity; and the technology 5 has the risk of incorrect label information entry. It can be seen that the existing various fiber-optic fiber-optic fiber identification technologies have corresponding technical drawbacks and affect the recognition efficiency. Therefore, how to provide a solution that can realize the identification of the fiber jumper without changing the original cable diameter and without inputting the tag information has become a technical problem to be solved.
- the present invention has been made in order to provide an intelligent ODN identification system and apparatus for solving the above problems, which is used to improve the recognition efficiency of fiber jumpers.
- an identifier including:
- Identifying an optical module configured to generate the identification light, and output the identification light to the optical coupler; and output the reliable connection indication signal after receiving the identification light fed back by the optical coupler;
- the optical coupler is configured to couple the identification light outputted by the identification optical module to the optical port, and output the optical fiber jumper to the receiving end through the connected fiber; and at the same time, receive the identification light sent by the receiving end through the fiber jumper, and The identification light is fed back to the identification light module.
- a fiber optic connector comprising: an identifier provided by the present invention, and an indicator light connected to the identifier, the display state of the indicator light being controlled by the identifier.
- a fiber optic connector identifier including: an optical processor, a second controller, and an indicator light;
- the optical processor is configured to: after receiving the identification light sent by the transmitting end through the fiber jumper, send a notification message to the second controller, and feed back the identification light to the sending end by using the fiber jumper;
- the second controller is configured to control the indicator light to be displayed in a preset manner after receiving the notification message.
- an intelligent optical distribution network ODN identification system including: a main controller, an optical fiber connector 1, a fiber connector 2, a fiber connector identifier, and a plurality of fiber jumpers;
- the main controller writes the target fiber hopping code information into the identifier of the fiber connector 1 and the identifier of the fiber connector 2; and controls the identifier of the fiber connector 1 and the fiber connector 2
- the identifier performs connection reliability detection of the optical link
- the fiber connector 1 is connected to a port A at one end of the target fiber jumper, and the fiber connector identifier is connected to the port B at the other end of the target fiber jumper; the fiber connector 1 is identified by the identifier and the fiber connector.
- the device detects the optical link reliability of the optical fiber connector 1, the target fiber jumper, and the fiber connector identifier by interworking the identification light, and passes the detection result through the fiber connector 1 and the fiber connector identifier. Indicator light indication;
- the fiber connector 2 When the optical link composed of the optical fiber connector 1, the target fiber jumper, and the fiber connector identifier is reliably connected, the fiber connector 2 is replaced with the fiber connector identifier and connected to the port B of the target fiber jumper;
- the identifier of the optical fiber connector 1 and the identifier of the optical fiber connector 2 detect the connection reliability of the optical link composed of the optical fiber connector 1, the target fiber jumper and the optical fiber connector 2 by means of mutual handshake communication. And the test results are indicated by the indicators on the fiber optic connector 1 and the fiber optic connector 2.
- the embodiment of the present invention solves the problem that the optical fiber jumper identification technology needs to change the optical fiber cable diameter by detecting the connection reliability of the optical link to detect the optical link and visually displaying the reliability of the indicator light. It is necessary to input label information and other problems affecting the identification efficiency, and it is implemented without changing the original cable diameter, visually and visually, and efficiently identify the two ends of the fiber jumper, and avoid the risk of incorrect label information at both ends of the fiber jumper. It can identify the technical effect of whether the fiber ends of the fiber jumper are reliably connected.
- FIG. 1 is a schematic diagram of a structure of a conventional smart fiber jumper
- FIG. 2 is a schematic structural diagram of a marker according to an embodiment of the present invention.
- FIG. 3 is a schematic structural diagram of a marking optical module according to an embodiment of the present invention.
- FIG. 4 is a schematic structural diagram of an optical fiber connector according to an embodiment of the present invention.
- FIG. 5 is a schematic structural diagram of an optical fiber connector identifier according to an embodiment of the present invention.
- FIG. 6 is a schematic structural diagram of a structural form 1 of an optical processor 410 according to an embodiment of the present invention.
- FIG. 7 is a schematic structural diagram of a structural form 2 of an optical processor 410 according to an embodiment of the present invention.
- FIG. 8 is a structural diagram of an ODN identification system of an intelligent optical distribution network according to an embodiment of the present invention.
- FIG. 9 is still another structural diagram of an intelligent optical distribution network ODN identification system according to an embodiment of the present invention.
- the embodiment of the present invention provides an identifier, as shown in FIG. 2, the identifier includes: an identification light module 210 and an optical coupler 220;
- the identification light module 210 is configured to generate the identification light and output the identification light to the optical coupler 220; and after receiving the identification light fed back by the optical coupler 220, output a reliable connection indication signal;
- the optical coupler 220 is configured to couple the identification light outputted by the identification optical module 210 to the optical port and output the optical fiber jumper to the receiving end through the connected fiber; and at the same time, receive the identification light sent by the receiving end through the optical fiber jumper, and The identification light is fed back to the identification light module 210.
- the optical coupler 220 can also couple the service light into the optical port.
- the service light from the optical port can be split to the service optical module that processes the service light.
- the identification light module 210 specifically includes: a first controller 211, a first light emitter 212, and a first light detector 213; wherein:
- the first controller 211 is configured to send a control instruction to the first light emitter
- the first light emitter 212 is configured to generate the identification light after receiving the control command, and output the identification light to the optical coupler 220;
- the first photodetector 213 is configured to send a notification message to the first controller 211 after detecting the identification light fed back by the optocoupler 220;
- the first controller 211 is further configured to output a reliable connection indication signal after receiving the notification message sent by the first photodetector 213.
- the wavelength of the identifier light generated by the first light emitter is different from the wavelength of the service light transmitted by the fiber jumper. For example, an 850 nm VCSEL light emitter is selected.
- the PIN photodiode is selected based on cost and cost performance.
- the identification light module can transmit and receive the identification light to share an optical path.
- the identification light module should be provided with a reflection filter, and the reflection filter can transmit the identification light emitted by the first light emitter 212.
- the marker light from the side of the photocoupler 220 is reflected to the first photodetector 213.
- the optical coupler 220 can be: a fiber coupler or a wavelength division multiplexing filter.
- the fiber coupler is preferably a Tap coupler.
- the identifier provided by this embodiment can transmit the identification light, and determine whether the optical link including the fiber jumper is reliable by detecting whether the identification light is received, and provides important support for identifying the fiber jumper.
- optical fiber connector adds an identifier 310 according to the first embodiment and an indicator light 320 connected to the identifier 310.
- the structure and function of the identifier 310 have been described in the first embodiment, and are not described herein.
- the indicator light 320 is mounted on the visible position of the fiber optic connector panel; the indicator light 320 can be, but is not limited to, an LED light; the display state of the indicator light 320 is controlled by the marker 310.
- the status of the indicator light includes color, brightness, blinking frequency, and so on.
- the identifier 310 can output a reliable connection indication signal, and the control indicator 320 lights up in a preset manner to indicate a reliable connection.
- the optical fiber connector of the embodiment is integrated with an identifier and an indicator light, and the optical fiber connector can effectively identify the fiber jumper.
- the embodiment provides a fiber optic connector identifier, as shown in FIG. 5, including: an optical processor 410, a second controller 420, and an indicator light 430; wherein:
- the optical processor 410 is configured to: after receiving the identification light sent by the transmitting end through the fiber jumper, send a notification message to the second controller 420, and feed back the identification light to the sending end by using a fiber jumper;
- the second controller 420 is configured to display the control indicator 430 in a preset manner after receiving the notification message.
- the control indicator 430 is solid green.
- optical processor 410 includes but is not limited to the following two types:
- Structural form 1 second photodetector 411A and reflective sheet 412A, as shown in FIG. 6;
- Structure 2 second photodetector 411A and second light emitter 412B, as shown in FIG. 7;
- the reflection sheet 412A is a transflective filter, and its main function is to transmit a part of the identification light to the second photodetector 411A after receiving the identification light sent by the transmitting end through the fiber jumper, and a part of the reflection light is transmitted back to the transmitting end. .
- the second photodetector 411A is configured to send a notification message to the second controller 420 after detecting the identification light transmitted by the reflective sheet 412A.
- the second photodetector 411A is configured to send a notification message to the second controller 420 after detecting the identification light sent by the transmitting end through the fiber jumper;
- the second controller 420 is further configured to send a control instruction to the second optical transmitter 412B after receiving the notification message;
- the second light emitter 412B is configured to generate the identification light according to the control instruction sent by the second controller 420, and feed the generated identification light to the transmitting end through the fiber jumper.
- the optical processor 410 can transmit and receive the identification light to share an optical path. Then, when the optical processor 410 adopts the structural form 2, the optical processor 410 should also be provided with a reflective filter, the reflective filter. The identification light emitted by the second light emitter 412B can be transmitted, and the identification light sent by the transmitting end is reflected to the second photodetector 411A, as shown in FIG. 7 .
- the fiber optic connector identifier of the embodiment further includes a power supply unit 440 configured to supply power to the optical processor 410, the second controller 420, and the indicator light 430.
- the optical fiber connector identifier of the embodiment can receive and feed back the identification light, and provide support for detecting the connection reliability of the optical link. At the same time, the indicator can be used to visually display whether the connection is reliable or not.
- An embodiment of the present invention provides an intelligent optical distribution network ODN identification system, as shown in FIG. 8, comprising: a main controller, a fiber connector 1, a fiber connector 2, a fiber connector identifier, and a plurality of fiber jumpers;
- the fiber connector 1, 2 is the fiber connector of the second embodiment, and the fiber connector identifier is the fiber connector identifier of the third embodiment. specific:
- the main controller writes the target fiber jumper code information into the identifier of the fiber connector 1 and the identifier of the fiber connector 2; and controls the identifier of the fiber connector 1 and the identifier of the fiber connector 2 to perform an optical link Connection reliability test;
- the fiber connector 1 is connected to the port A of the target fiber jumper, and the fiber connector identifier is connected to the port B of the other end of the target fiber jumper; the fiber connector 1 uses the identifier and the fiber connector identifier to communicate with each other by means of the identifier.
- the connection reliability of the optical link composed of the fiber connector 1, the target fiber jumper, and the fiber connector identifier is detected, and the detection result is indicated by an indicator on the fiber connector 1 and the fiber connector identifier;
- the fiber connector 2 When the optical link composed of the optical fiber connector 1, the target fiber jumper and the fiber connector identifier is reliably connected, the fiber connector 2 replaces the fiber connector identifier and is connected to the port B of the target fiber jumper; the identifier of the fiber connector 1 And the identifier of the optical fiber connector 2 detects the connection reliability of the optical link composed of the optical fiber connector 1, the target optical fiber jumper and the optical fiber connector 2 by means of mutual handshake communication, and connects the detection result through the optical fiber connection.
- the indicator lights on the device 1 and the fiber optic connector 2 are indicated.
- the fiber connector 1 and the fiber connection are also activated by the identifier.
- the indicator light on the device 2 is such that the display state of the indicator light indicates that the fiber connector 1 and the fiber connector 2 are in a standby state (such as a slow flash of green light).
- the optical fiber connector 1 detects the connection reliability of the optical link composed of the optical fiber connector 1, the target fiber jumper, and the fiber connector identifier by means of the identifier and the fiber connector identifier. Specifically, including:
- the optical fiber connector 1 uses the identifier to transmit the identification light to the fiber connector identifier;
- the optical fiber connector identifier receives the identification light sent by the optical fiber connector 1, the identification light is fed back to the optical fiber connector 1; otherwise, the connection of the optical link is determined to be unreliable;
- the optical fiber connector 1 When the optical fiber connector 1 receives the identification light fed back from the fiber connector identifier side, it determines that the optical link connection is reliable; otherwise, it determines that the optical link connection is unreliable.
- the identifier of the optical fiber connector 1 and the identifier of the optical fiber connector 2 are securely connected to each other through the mutual handshake communication, and the optical links formed by the optical fiber connector 1, the target optical fiber jumper, and the optical fiber connector 2 are reliable.
- Sex testing including:
- the optical fiber connector 1 and the optical fiber connector 2 use the identifier to send the identification light to the opposite end;
- the optical fiber connector 1 and the optical fiber connector 2 determine whether the identification light transmitted by the opposite end is received, and if so, it is determined that the optical link connection is reliable; otherwise, the connection of the optical link is determined to be unreliable.
- Step 1 The main controller sends a pending construction instruction to the background, and the background corresponds to the identifier corresponding to the optical fiber connector 1 and the optical fiber connector 2 according to the work order system, and the code information of the target fiber jumper is written into the identifier.
- the address of the background write identifier is in a closed loop handshake manner to ensure that the fiber jumper code information is correct.
- the main controller sends an indicator activation command to the identifiers of the optical fiber connector 1 and the optical fiber connector 2 through the background. After receiving the activation instruction, the identifier activates the LED indicator on the corresponding optical fiber connector, and uses the LED indicator state 1 ( If the green light flashes slowly, the optical fiber connector 1 and the optical fiber connector 2 are in a state to be constructed and connected.
- Step 2 The fiber jumper (defined at both ends as A1 and B1) is connected to the fiber connector 1 and the B1 terminal is connected to the fiber connector identifier.
- Step 3 After receiving the detection command sent by the main controller side, the identifier corresponding to the optical fiber connector 1 sends the identification light to the fiber connector identifier side.
- Step 4 If the optical fiber connector identifier receives the identification light sent by the identifier of the optical fiber connector 1, the indicator light is fed back to the identifier of the optical fiber connector 1, and the indicator light is controlled to be in a green light state; if not received When the identification light sent by the identifier of the optical fiber connector 1 is not lit, the optical connector identifier side indicator is not lit, indicating that the optical link is unreliable.
- the reasons for the unreliable optical link are: the connection between the optical fiber connector 1 and the fiber jumper port A1 is unreliable, the connection between the fiber connector identifier and the fiber jumper port B1 is unreliable, and the fiber connector 1 is connected to the fiber connector identifier. It is not the same fiber jumper, fiber jumper failure, fiber connector identifier failure or port abnormality.
- Step 5 If the identifier corresponding to the fiber connector 1 receives the identification light fed back by the fiber connector identifier, it is determined that the optical link connection is reliable, and the indicator light on the fiber connector 1 is slowly changed from green to green. If the indicator light is not received by the fiber connector identifier, the link of the optical link is unreliable. At this time, the indicator on the fiber connector 1 is still green and slowly flashing. Do further investigation.
- Step 6 Unplug the fiber connector identifier and connect the B1 port to the fiber connector 2.
- the system architecture is shown in Figure 9.
- Step 7 The optical fiber connector 1 and the optical fiber connector 2 communicate with each other through the identifier. If the handshake communication fails, the identification is performed by the respective indicator lights. If the handshake communication is successful, the optical connector 1 and the A1 port and the optical fiber connector 2 are represented. Both the B1 port and the B1 port are connected reliably, and both ends are from the same fiber jumper. At this time, the indicators on the fiber connector 1 and the fiber connector 2 are characterized as correct construction. After the indicator light is displayed for a period of time, the main controller can actively turn off the indicator light through the identifier; or, without any operation, the indicator that the correct construction is automatically turned off after a certain period of time.
- the quality inspector can also use the marker to perform the secondary inspection on the optical link after the construction.
- the process of the second inspection is as follows:
- the main controller issues a quality inspection command, and the background corresponds to the identifier corresponding to the fiber connector 1 and the fiber connector 2 according to the work order system, and activates the corresponding indicator corresponding to the fiber connector through the identifier, and identifies the fiber connection by the indicator state.
- the device 1 and the fiber optic connector 2 are in a stage to be re-inspected (because the fiber jumper connection has been completed at this time, only to verify that the connection is correct and reliable).
- the optical fiber connector 1 and the optical fiber connector 2 communicate with each other through the identifier. If both ends are connected reliably and the connectors are correct, the indicators on both ends are off, indicating that the connection is correct and reliable. If the handshake communication fails, the indicator light is in an alarm state, for example, the LED green light flashes rapidly.
- the embodiment of the present invention solves the problem that the optical fiber jumper identification technology needs to change the optical fiber cable diameter by detecting the connection reliability of the optical link to detect the optical link and visually displaying the reliability of the indicator light. It is necessary to input label information and other problems affecting the identification efficiency, and it is implemented without changing the original cable diameter, visually and visually, and efficiently identify the two ends of the fiber jumper, and avoid the risk of incorrect label information at both ends of the fiber jumper. It can identify the technical effect of whether the fiber ends of the fiber jumper are reliably connected.
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Abstract
本发明公开了一种智能ODN标识系统及装置,所述装置包括:标识器、光纤连接器、以及光纤接头识别器;其中,标识器包括:标识光模块,设置为产生标识光,并将所述标识光输出至光耦合器;以及在接收到光耦合器反馈的标识光后,输出可靠连接指示信号;光耦合器,设置为将所述标识光模块输出的标识光耦合到光端口后通过连接的光纤跳纤输出至接收端;以及将接收端通过光纤跳纤发送的标识光反馈至标识光模块。本发明中,将标识器应用与智能ODN标识系统,实现了在不改变原有缆径的情况下,通过标识光对光纤跳纤的高效标识。
Description
本发明实施例涉及通信技术领域,尤其涉及一种智能光配线网络(Optical Distribution Network,简称为ODN)标识系统及装置。
目前,光配线领域中,需要对大量的光纤跳纤、尾纤进行物理配线、连接,然而,如何在大量的光纤跳纤、尾纤中精确定位目标成为本领域的技术难题。目前存在的解决方案如下:
技术1:如图1所示,使用打印/粘贴/绑扎在电缆上的标签,该技术存在标签容易散落、丢失、字迹模糊、逐个翻看标签信息来找到目标端头,由于以上特点导致查找效率低、容易出错等缺陷。
技术2:通过发光二极管点亮线缆组件两端来定位到线缆两端,该技术对缆的类型有限制,必须是有金属加强筋或类似结构能够为二极管提供金属导通回路的结构形式的缆,使得应用范围被限制。
技术3:通过点亮塑料光纤的方式识别光纤跳纤两端,该技术识别方法直观、高效、准确,但由于是石英光纤和塑料光纤配合工作,导致光纤尺寸增加,故导致整个配线系统缆体积增大,从容量上来说,无形增加线缆管理的难度。
技术4:通过一根石英光纤与多根塑料光纤集成到一个光纤跳纤连接器上,石英光纤传递业务,塑料光纤传递识别信息的方式来传递识别信号。
技术5:通过在光纤跳纤连接器上增加电子标签,用电子标签体现和追踪光纤跳纤信息。该标签高效,但目前无法完全克服标签信息录入错误的风险。
综上所述,可知技术1~技术3,均能直观的识别光纤跳纤的两端,但无法实现直观、用目测方式识别两端连接器可靠连接与否;技术4:由于是一根石英光纤和多根玻璃光纤通过多个卡扣进行扣接,光纤跳纤直径物理尺寸增加,降低了配线容量;技术5存在标签信息录入错误的风险。可见,现有的各种光纤跳纤识别技术存在相应的技术弊端,影响识别效率。所以,如何提供一种解决方案,能够在不改变原有缆径以及无需录入标签信息的情况下,实现光纤跳纤的识别,成为目前亟待解决的技术问题。
发明内容
鉴于上述问题,提出了本发明以便提供一种解决上述问题的智能ODN标识系统及装置,用以提高光纤跳纤的识别效率。
依据本发明的一个实施例,提供一种标识器,包括:
标识光模块,设置为产生标识光,并将所述标识光输出至光耦合器;以及在接收到光耦合器反馈的标识光后,输出可靠连接指示信号;
光耦合器,设置为将所述标识光模块输出的标识光耦合到光端口后通过连接的光纤跳纤输出到接收端;同时,也能接收接收端通过光纤跳纤发送的标识光,并将标识光反馈至标识光模块。
依据本发明的另一个实施例,提供一种光纤连接器,包括:本发明提供的标识器,以及与所述标识器相连的指示灯,所述指示灯的显示状态由所述标识器控制。
依据本发明的第三个实施例,提供一种光纤接头识别器,包括:光处理器、第二控制器、以及指示灯;
所述光处理器,设置为当接收到发送端通过光纤跳纤发送的标识光后,向第二控制器发送通知消息,以及通过光纤跳纤向所述发送端反馈标识光;
所述第二控制器,设置为在接收到所述通知消息后,控制所述指示灯按预设方式显示。
依据本发明的第四个实施例,提供一种智能光分配网络ODN标识系统,包括:主控制器、光纤连接器1、光纤连接器2、光纤接头识别器、以及多个光纤跳纤;
所述主控制器,将目标光纤跳纤编码信息写入所述光纤连接器1的标识器和光纤连接器2的标识器;以及控制所述光纤连接器1的标识器和光纤连接器2的标识器进行光链路的连接可靠性检测;
所述光纤连接器1与目标光纤跳纤一端的端口A相连,所述光纤接头识别器与目标光纤跳纤另一端的端口B相连;所述光纤连接器1利用标识器与所述光纤接头识别器通过互通标识光的方式,对光纤连接器1、目标光纤跳纤和光纤接头识别器组成的光链路的连接可靠性进行检测,并将检测结果通过光纤连接器1和光纤接头识别器上的指示灯表示;
当光纤连接器1、目标光纤跳纤和光纤接头识别器组成的光链路为可靠连接时,所述光纤连接器2替换所述光纤接头识别器与目标光纤跳纤的端口B相连;所述光纤连接器1的标识器与所述光纤连接器2的标识器通过互相握手通讯的方式,对光纤连接器1、目标光纤跳纤和光纤连接器2组成的光链路的连接可靠性进行检测,并将检测结果通过光纤连接器1和光纤连接器2上的指示灯表示。
本发明实施例有益效果如下:
本发明实施例通过标识光对光链路的连接可靠性进行检测,并通过指示灯对可靠性进行直观显示的技术方案,解决了已有的光纤跳纤识别技术需要对光纤缆径进行改变或者需要录入标签信息等影响识别效率的问题,达到了在不改变原有缆径的情况下实施、可以直观目测、高效识别光纤跳纤的两端、避免光纤跳纤两端标签信息错误的风险以及可以识别光纤跳纤两端是否可靠连接的技术效果。
为了更清楚地说明本发明实施例或现有技术中的技术方案,下面将对实施例或现有技术描述中所需要使用的附图作一简单地介绍,显而易见地,下面描述中的附图仅仅是本发明的一些实施例,对于本领域普通技术人员来讲,在不付出创造性劳动性的前提下,还可以根据这些附图获得其他的附图。
图1为现有智能光纤跳纤结构示意图;
图2为本发明实施例涉及的标识器的结构示意图;
图3为本发明实施例涉及的标识光模块的结构示意图;
图4为本发明实施例涉及的光纤连接器的结构示意图;
图5为本发明实施例涉及的光纤接头识别器的结构示意图;
图6为本发明实施例中光处理器410结构形式一的结构示意图;
图7为本发明实施例中光处理器410结构形式二的结构示意图;
图8为本发明实施例提供的智能光分配网络ODN标识系统的架构图;
图9为本发明实施例提供的智能光分配网络ODN标识系统的又一架构图。
下面将结合本发明实施例中的附图,对本发明实施例中的技术方案进行清楚、完整地描述,显然,所描述的实施例仅仅是本发明一部分实施例,而不是全部的实施例。基于本发明中的实施例,本领域普通技术人员在没有做出创造性劳动前提下所获得的所有其他实施例,都属于本发明保护的范围。
实施例一
本发明实施例提供一种标识器,如图2所示,所述标识器包括:标识光模块210和光耦合器220;
标识光模块210,设置为产生标识光,并将所述标识光输出至光耦合器220;以及在接收到光耦合器220反馈的标识光后,输出可靠连接指示信号;
光耦合器220,设置为将标识光模块210输出的标识光耦合到光端口后通过连接的光纤跳纤输出到接收端;同时,也能接收接收端通过光纤跳纤发送的标识光,并将该标识光反馈至标识光模块210。
另外,为了兼容业务光,光耦合器220还可以将业务光也耦合进光端口;同时,也能将从光端口过来的业务光分光到处理业务光的业务光模块上。
其中,标识光模块210,如图3所示,具体包括:第一控制器211、第一光发射器212和第一光探测器213;其中:
第一控制器211,设置为向第一光发射器发送控制指令;
第一光发射器212,设置为接收到所述控制指令后,生成标识光,并将标识光输出至光耦合器220;
第一光探测器213,设置为在探测到光耦合器220反馈的标识光后,向第一控制器211发送通知消息;
第一控制器211,还设置为在接收到第一光探测器213发送的通知消息后,输出可靠连接指示信号。
本实施例中,由于标识器主要用于光纤跳纤两端的识别,所以第一光发射器生成的标识光的波长要与光纤跳纤传输的业务光的波长不同。例如,选择850nm VCSEL光发射器。而对于第一光探测器的选择,基于成本和性价比最优选择PIN光电二极管。
本实施例中,标识光模块发射和接收标识光可以共用一个光路,此时,标识光模块内应配备反射滤光片,该反射滤光片可以将第一光发射器212发出的标识光进行透射,将从光耦合器220侧来的标识光反射至第一光探测器213。
本实施例中,光耦合器220可以为:光纤耦合器或波分复用滤波片。其中,光纤耦合器优选为Tap耦合器。
本实施例提供的标识器可以发射标识光,并通过检测是否接收到标识光的方式,判定包含光纤跳纤的光链路是否可靠,为识别光纤跳纤提供了重要支持。
实施例二
本发明实施例提供一种光纤连接器,如图4所示,该光纤连接器在原有的架构基础上增设实施例一所述的标识器310,以及与标识器310相连的指示灯320。
本实施例中,标识器310的结构及功能已经在实施例一中进行了阐述,在此不作赘述。
本实施例中,指示灯320安装于光纤连接器面板的可视位置;指示灯320可以但不限于为LED灯;指示灯320的显示状态由标识器310控制。指示灯的状态包括颜色、亮灭、闪烁频度等。
本实施例中,标识器310可通过输出可靠连接指示信号,控制指示灯320按预设方式点亮,以表示可靠连接。
本实施例所述光纤连接器,集成有标识器和指示灯,利用该光纤连接器可以有效识别光纤跳纤。
实施例三
本实施例提供一种光纤接头识别器,如图5所示,包括:光处理器410、第二控制器420、以及指示灯430;其中:
光处理器410,设置为当接收到发送端通过光纤跳纤发送的标识光后,向第二控制器420发送通知消息,以及通过光纤跳纤向所述发送端反馈标识光;
第二控制器420,设置为在接收到所述通知消息后,控制指示灯430按预设方式显示。例如,控制指示灯430为绿光常亮。
其中,光处理器410的结构形式包括但不限于为如下两种:
结构形式一:第二光探测器411A和反射片412A,具体如图6所示;
结构形式二:第二光探测器411A和第二光发射器412B,具体如图7所示;
对于上述结构形式一:
反射片412A是半反半透的滤波片,它的主要作用就是当接收到发送端通过光纤跳纤发送的标识光后,将标识光一部分透射给第二光探测器411A,一部分反射回发送端。
第二光探测器411A,设置为当探测到反射片412A透射的标识光后,向第二控制器420发送通知消息。
对于上述结构形式二:
第二光探测器411A,设置为当探测到发送端通过光纤跳纤发送的标识光后,向第二控制器420发送通知消息;
第二控制器420,还设置为在接收到所述通知消息后,向第二光发射器412B发送控制指令;
第二光发射器412B,设置为根据第二控制器420发送的控制指令,生成标识光,并将生成的标识光通过光纤跳纤反馈至发送端。
本实施例中,光处理器410发射和接收标识光可以共用一个光路,那么,当光处理器410采用结构形式二时,光处理器410内还应配备反射滤光片,该反射滤光片可以将第二光发射器412B发出的标识光进行透射,将发送端发送的标识光反射至第二光探测器411A,具体如图7所示。
本实施例所述光纤接头识别器还包括:供电单元440,设置为为所述光处理器410、第二控制器420、以及指示灯430供电。
本实施例所述的光纤接头识别器可以接收并反馈标识光,为检测光链路的连接可靠性提供支持,同时,还可以通过指示灯对连接是否可靠进行直观显示。
实施例四
本发明实施例提供一种智能光分配网络ODN标识系统,如图8所示,包括:主控制器、光纤连接器1、光纤连接器2、光纤接头识别器、以及多个光纤跳纤;其中,光纤连接器1、2为实施例二所述的光纤连接器,光纤接头识别器为实施例三所述的光纤接头识别器。具体的:
主控制器,将目标光纤跳纤编码信息写入光纤连接器1的标识器和光纤连接器2的标识器;以及控制光纤连接器1的标识器和光纤连接器2的标识器进行光链路的连接可靠性检测;
光纤连接器1与目标光纤跳纤一端的端口A相连,光纤接头识别器与目标光纤跳纤另一端的端口B相连;光纤连接器1利用标识器与光纤接头识别器通过互通标识光的方式,对光纤连接器1、目标光纤跳纤和光纤接头识别器组成的光链路的连接可靠性进行检测,并将检测结果通过光纤连接器1和光纤接头识别器上的指示灯表示;
当光纤连接器1、目标光纤跳纤和光纤接头识别器组成的光链路为可靠连接时,光纤连接器2替换光纤接头识别器与目标光纤跳纤的端口B相连;光纤连接器1的标识器与光纤连接器2的标识器通过互相握手通讯的方式,对光纤连接器1、目标光纤跳纤和光纤连接器2组成的光链路的连接可靠性进行检测,并将检测结果通过光纤连接器1和光纤连接器2上的指示灯表示。
本实施例中,主控制器在将目标光纤跳纤编码信息写入光纤连接器1的标识器和光纤连接器2的标识器后,优选地,还通过标识器激活光纤连接器1和光纤连接器2上的指示灯,以使指示灯的显示状态表示光纤连接器1和光纤连接器2为待连接状态(如绿光慢闪)。
本实施例中,光纤连接器1利用标识器与光纤接头识别器通过互通标识光的方式,对光纤连接器1、目标光纤跳纤和光纤接头识别器组成的光链路的连接可靠性进行检测,具体包括:
光纤连接器1利用标识器向光纤接头识别器发送标识光;
光纤接头识别器若接收到光纤连接器1发送的标识光,则向光纤连接器1反馈标识光;否则,判定光链路的连接不可靠;
光纤连接器1若接收到光纤接头识别器侧反馈的标识光,则判定光链路连接可靠;否则,判定光链路的连接不可靠。
本实施例中,光纤连接器1的标识器与光纤连接器2的标识器通过互相握手通讯的方式,对光纤连接器1、目标光纤跳纤和光纤连接器2组成的光链路的连接可靠性进行检测,具体包括:
光纤连接器1和光纤连接器2利用标识器向对端发送标识光;
光纤连接器1和光纤连接器2判断是否接收到对端发送的标识光,若是,则判定光链路连接可靠;否则,判定光链路的连接不可靠。
为了更清楚的说明本发明所述系统的实施过程,下面结合实际应用的场景,给出本发明一个较佳的实施例,并结合对实施例的描述,进一步给出本发明的技术细节,使其能够更好地说明本发明所述系统的具体实现过程。
本发明实施例所述系统实现智能ODN标识的实现过程如下:
步骤1:主控制器向后台发出待施工指令,由后台根据工单系统连接光纤连接器1和光纤连接器2对应的标识器,将目标跳纤的编码信息写入标识器。优选地,后台写入标识器的地址采用闭环握手识别的方式,以确保光纤跳纤编码信息正确。主控制器通过后台向光纤连接器1和光纤连接器2的标识器发出指示灯激活指令,标识器接收到激活指令后,激活对应光纤连接器上的LED指示灯,用LED指示灯状态1(如绿光慢闪)标识光纤连接器1和光纤连接器2处于待施工操作和连接状态。
步骤2:将光纤跳纤(两端接口分别定义为A1和B1)A1端连接到光纤连接器1,B1端连接到光纤接头识别器。
步骤3,光纤连接器1对应的标识器接收到主控制器侧发送的检测指令后,向光纤接头识别器侧发送标识光。
步骤4,光纤接头识别器若接收到光纤连接器1的标识器发送的标识光,则向光纤连接器1的标识器反馈标识光,并控制自身指示灯为绿光常亮状态;若未接收到光纤连接器1的标识器发送的标识光,则光纤接头识别器侧指示灯不点亮,说明光链路不可靠。
产生光链路不可靠的原因有:光纤连接器1与光纤跳纤端口A1的连接不可靠、光纤接头识别器与光纤跳纤端口B1的连接不可靠、光纤连接器1与光纤接头识别器连接的不是同一根光纤跳纤,光纤跳纤故障,光纤接头识别器故障或端口异常等等。
步骤5,光纤连接器1对应的标识器若接收到光纤接头识别器反馈的标识光,则判定为光链路连接可靠,将光纤连接器1上的指示灯由绿光慢闪变为绿光常亮;反之,若未接收到光纤接头识别器反馈的标识光,则说明光链路链接不可靠,此时,光纤连接器1上的指示灯仍为绿光慢闪,需要对不可靠因素做进一步排查。
步骤6:拔下光纤接头识别器,将B1端口可靠连接到光纤连接器2,此时系统架构图如图9所示。
步骤7:光纤连接器1和光纤连接器2通过标识器互相握手通讯,若握手通讯失败,通过各自的指示灯进行表征;若握手通讯成功,表示光纤连接器1与A1端口、光纤连接器2与B1端口均已连接可靠,并且两端来自同一条光纤跳纤,此时,光纤连接器1和光纤连接器2上的指示灯表征为施工正确。在指示灯显示一段时间后,主控制器可以通过标识器主动关闭指示灯;或者,不做任何操作,表征施工正确的指示灯在常亮一定时间后自动关闭。
在通过上述方式进行施工后,质检人员还可以利用标识器对施工后的光链路进行二次检验,二次检验的过程如下:
主控制器发出质检指令,由后台根据工单系统连接光纤连接器1和光纤连接器2对应的标识器,并通过标识器激活对应光纤连接器对应的指示灯,用指示灯状态标识光纤连接器1和光纤连接器2处于待二次检验阶段(因为此时已完成光纤跳纤连接,仅仅为检验连接是否正确并可靠)。光纤连接器1与光纤连接器2通过标识器互相握手通讯。若两端均可靠连接并且接头正确,两端指示灯熄灭,表示连接正确、可靠;若握手通讯失败,指示灯呈现告警状态,例如LED绿光快速闪烁等。
显然,本领域的技术人员可以对本发明进行各种改动和变型而不脱离本发明的精神和范围。这样,倘若本发明的这些修改和变型属于本发明权利要求及其等同技术的范围之内,则本发明也意图包含这些改动和变型在内。
本发明实施例通过标识光对光链路的连接可靠性进行检测,并通过指示灯对可靠性进行直观显示的技术方案,解决了已有的光纤跳纤识别技术需要对光纤缆径进行改变或者需要录入标签信息等影响识别效率的问题,达到了在不改变原有缆径的情况下实施、可以直观目测、高效识别光纤跳纤的两端、避免光纤跳纤两端标签信息错误的风险以及可以识别光纤跳纤两端是否可靠连接的技术效果。
Claims (12)
- 一种标识器,包括:标识光模块,设置为产生标识光,并将所述标识光输出至光耦合器;以及在接收到光耦合器反馈的标识光后,输出可靠连接指示信号;光耦合器,设置为将所述标识光模块输出的标识光耦合到光端口后通过连接的光纤跳纤输出到接收端;以及将接收端通过光纤跳纤发送的标识光反馈至所述标识光模块。
- 如权利要求1所述的标识器,其中,所述标识光模块,具体包括:第一控制器、第一光发射器和第一光探测器;所述第一控制器,设置为向第一光发射器发送控制指令;所述第一光发射器,设置为接收到所述控制指令后,生成标识光,并将标识光输出至所述光耦合器;所述第一光探测器,设置为在探测到所述光耦合器反馈的标识光后,向所述第一控制器发送通知消息;所述第一控制器,还设置为在接收到第一光探测器发送的通知消息后,输出可靠连接指示信号。
- 如权利要求1所述标识器,其中,所述光耦合器包括以下之一:光纤耦合器和波分复用滤波片。
- 一种光纤连接器,其中,包括:权利要求1至3任意一项所述的标识器,以及与所述标识器相连的指示灯,所述指示灯的显示状态由所述标识器控制。
- 一种光纤接头识别器,包括:光处理器、第二控制器、以及指示灯;所述光处理器,设置为当接收到发送端通过光纤跳纤发送的标识光后,向第二控制器发送通知消息,以及通过光纤跳纤向所述发送端反馈标识光;所述第二控制器,设置为在接收到所述通知消息后,控制所述指示灯按预设方式显示。
- 如权利要求5所述的光纤接头识别器,其中,所述光处理器包括:第二光探测器和第二光发射器;所述第二光探测器,设置为当探测到发送端通过光纤跳纤发送的标识光后,向第二控制器发送通知消息;所述第二控制器,还设置为在接收到所述通知消息后,向所述第二光发射器发送控制指令;所述第二光发射器,设置为根据所述第二控制器发送的控制指令,生成标识光,并将生成的标识光通过光纤跳纤反馈至发送端。
- 如权利要求5所述的光纤接头识别器,其中,所述光处理器包括:第二光探测器和反射片;所述反射片,设置为当接收到发送端通过光纤跳纤发送的标识光后,将标识光一部分透射至第二光探测器,一部分向发送端反射;所述第二光探测器,设置为探测到所述反射片透射的标识光后,向第二控制器发送通知消息。
- 如权利要求5至7中任一项所述的光纤接头识别器,其中,所述光纤接头识别器还包括:供电单元,设置为为所述光处理器、第二控制器以及指示灯供电。
- 一种智能光分配网络ODN标识系统,其中,包括:主控制器、光纤连接器1、光纤连接器2、光纤接头识别器、以及多个光纤跳纤;所述主控制器,将目标光纤跳纤编码信息写入所述光纤连接器1的标识器和光纤连接器2的标识器;以及控制所述光纤连接器1的标识器和光纤连接器2的标识器进行光链路的连接可靠性检测;所述光纤连接器1与目标光纤跳纤一端的端口A相连,所述光纤接头识别器与目标光纤跳纤另一端的端口B相连;所述光纤连接器1利用标识器与所述光纤接头识别器通过互通标识光的方式,对光纤连接器1、目标光纤跳纤和光纤接头识别器组成的光链路的连接可靠性进行检测,并将检测结果通过光纤连接器1和光纤接头识别器上的指示灯表示;当光纤连接器1、目标光纤跳纤和光纤接头识别器组成的光链路为可靠连接时,所述光纤连接器2替换所述光纤接头识别器与目标光纤跳纤的端口B相连;所述光纤连接器1的标识器与所述光纤连接器2的标识器通过互相握手通讯的方式,对光纤连接器1、目标光纤跳纤和光纤连接器2组成的光链路的连接可靠性进行检测,并将检测结果通过光纤连接器1和光纤连接器2上的指示灯表示。
- 如权利要求9所述的系统,其中,所述主控制器,在将目标光纤跳纤编码信息写入所述光纤连接器1的标识器和光纤连接器2的标识器后,还包括:通过标识器激活光纤连接器1和光纤连接器2上的指示灯,以使指示灯的显示状态表示光纤连接器1和光纤连接器2为待连接状态。
- 如权利要求9或10所述的系统,其中,所述光纤连接器1利用标识器与所述光纤接头识别器通过互通标识光的方式,对光纤连接器1、目标光纤跳纤和光纤接头识别器组成的光链路的连接可靠性进行检测,包括:所述光纤连接器1利用标识器向光纤接头识别器发送标识光;所述光纤接头识别器若接收到光纤连接器1发送的标识光,则向所述光纤连接器1反馈标识光;否则,判定光链路的连接不可靠;所述光纤连接器1若接收到光纤接头识别器侧反馈的标识光,则判定光链路连接可靠;否则,判定光链路的连接不可靠。
- 如权利要求9或10所述的系统,其中,所述光纤连接器1的标识器与所述光纤连接器2的标识器通过互相握手通讯的方式,对光纤连接器1、目标光纤跳纤和光纤连接器2组成的光链路的连接可靠性进行检测,包括:所述光纤连接器1和光纤连接器2利用标识器向对端发送标识光;所述光纤连接器1和光纤连接器2判断是否接收到对端发送的标识光,若是,则判定光链路连接可靠;否则,判定光链路的连接不可靠。
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US11295135B2 (en) | 2020-05-29 | 2022-04-05 | Corning Research & Development Corporation | Asset tracking of communication equipment via mixed reality based labeling |
US11374808B2 (en) | 2020-05-29 | 2022-06-28 | Corning Research & Development Corporation | Automated logging of patching operations via mixed reality based labeling |
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