JP2005020420A - Passive optical network testing apparatus - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a passive optical network testing apparatus for simplifying the structure of the apparatus and reducing the cost. <P>SOLUTION: Virtual ONUs 12-1 to 12-31 simulate an operation of two or more optical subscriber line terminating devices according to a control frame received from the optical subscriber line terminal station device. An allotment processing unit 13 allots the frame to either of the virtual ONUs 12-1 to 12-31 according to an identifier included in a testing frame received from Ethernet (R) frame generator/tester. Then, the structure of the apparatus can be simplified and the cost can be reduced. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a PON (Passive Optical Network), which is a medium-shared communication in which a plurality of home-side devices share a medium and transmit data, and in particular, EPON (Transmission of data as Ethernet (R) frames) The present invention relates to a passive optical network test apparatus for testing an ONU (optical subscriber line terminating apparatus) or OLT (optical subscriber line terminal apparatus) connected to Ethernet (R) PON).
[0002]
[Prior art]
In recent years, the Internet has become widespread, and users can access various information on sites operated in various parts of the world and obtain the information. Accordingly, demand for broadband access such as ADSL (Asymmetric Digital Subscriber Line) and FTTH (Fiber To The Home) is rapidly increasing.
[0003]
FIG. 7 is a block diagram showing a schematic configuration of a conventional PON system. This PON system mainly branches an OLT 101 installed in a telephone office or the like, a plurality of ONUs 102-1 to 102-n mainly installed in each home, and an optical signal transmitted from the OLT 101 to split the ONU 102-1. 102-n, a splitter 105 for converging optical signals sent from the ONUs 102-1 to 102-n and sending them to the OLT 101, and a user terminal 111 connected to each of the ONUs 102-1 to 102-n including. Note that the first ONU 102-1 to the n-th ONU 102-n have the same configuration.
[0004]
The OLT 101 sends the data received via the upper network 109 to the ONUs 102-1 to 102-n via the transmission path 104 and the splitter 105. Further, the OLT 101, based on the report 107 transmitted from the ONUs 102-1 to 102-n, transmits the transmission start time of data stored in the buffers 103-1 to 103-n in the ONUs 102-1 to 102-n and The grant permission amount is calculated, and the grant 106 into which the instruction signal is inserted is sent to the ONUs 102-1 to 102-n via the transmission path 104 and the splitter 105.
[0005]
For example, when the ONU 102-1 receives the uplink information frame 108 from the user terminal 111 via the lower network 110, the uplink information frame 108 is temporarily stored in the buffer 103-1. When the ONU 102-1 receives the grant 106 from the OLT 101, the ONU 102-1 notifies the OLT 101 with the report 107 of the data amount in the buffer 103-1 at the time designated by the grant 106. The uplink information frame 108 arrives in variable length packet units.
[0006]
When the ONU 102-1 receives the grant 106 in which the instruction signal is inserted from the OLT 101, the ONU 102-1 transmits the data in the buffer 103-1 to the OLT 101 together with the report 107 based on the instruction signal.
[0007]
FIG. 8 is a sequence diagram for explaining the operation procedure of the conventional PON system. This sequence diagram is for the operations of the OLT 101 and the ONU 102-1, but the same is true for the operations of the other ONUs 102-2 to 02-n.
[0008]
At the operation time start time T0, the OLT 101 has already calculated an RTT (Round Trip Time) for the ONUs 102-1 to 102-n. At time Ta1, the OLT 101 transmits a grant 121 including the report transmission start time Tb2 to the ONU 102-1, in order to notify the transmission request amount. This report transmission start time Tb2 is calculated so as not to collide with reports transmitted from other ONUs.
[0009]
When the ONU 102-1 receives the grant 121 for itself, the ONU 102-1 calculates the requested transmission amount by referring to the data amount stored in the buffer 103-1, and the OLT 101 receives the report transmission start time Tb2 included in the grant 121. A report 122 including the requested transmission amount is transmitted.
[0010]
When the OLT 101 receives the report 122, the OLT 101 calculates a value that is equal to or less than the fixed or variable maximum allowable transmission amount and can transmit as much data as possible in the buffer included in the report 122, and grants the calculation result as the allowable transmission amount. 123. When the transmission request amount included in the report 122 is zero, the operation result by the OLT 101 is zero and no bandwidth is allocated. However, since the ONU 102-1 needs to transmit the report, the OLT 101 causes the ONU 102-1 to send the report. The grant 123 is always transmitted.
[0011]
The transmission start time Tb4 included in the grant 123 uses the calculated scheduled ONU data reception time, the previous ONU transmission permission amount, the RTT related to the current ONU, and the guard time which is a fixed time, and data and reports. Is calculated so as not to collide with data or reports from other ONUs. The OLT 101 calculates a time Ta3 at which the grant 123 including the transmission permission amount and the transmission start time Tb4 is transmitted so that the grant 123 arrives at the ONU 102-1 by the transmission start time Tb4.
[0012]
When the ONU 102-1 receives the grant 123 for itself, the ONU 102-1 sends the data 124 corresponding to the transmission permission amount to the OLT 101 together with the report including the next transmission request amount at the transmission start time Tb4 included in the grant 123. This report is sent immediately before or after the data. When the report is sent immediately before the data, the value to be reported to the OLT 101 as the send request amount is the data amount stored in the buffer 103-1 and the data 124. This is the difference from the amount of data.
[0013]
When the OLT 101 receives the data and the report 124, the OLT 101 sends the data to the upper network 109, and the report is processed in the same manner as the processing for the report 122. The processing described above is performed independently for all the ONUs 102-1 to 102-n, and the processing from time Ta3 to time Ta4 is repeated until the operation time ends.
[0014]
FIG. 9 is a diagram illustrating an example of a distributed allocation method. This diagram is a sequence diagram showing bandwidth allocation when the number of ONUs is 3, and transmission / reception of grants and reports between OLT-ONUs.
[0015]
The OLT 101 sequentially sends grants 131 to 133 to the ONUs 102-3, 102-2, and 102-1. When the OLT 101 receives the reports 134 to 136 from the ONUs 102-3, 102-2, and 102-1, it first sends a grant 137 to the ONU 102-3 that permits transmission of data.
[0016]
The OLT 101 receives the data 138 sent from the ONU 102-3 and sends a grant 139 to the ONU 102-2 in parallel with this. Thereafter, similar processing is repeated, and the OLT 101 sequentially allocates bands to the ONUs 102-1 to 102-3 and repeats data reception.
[0017]
As prior art related to this, there is “IPACT: A Dynamic Protocol for an Ethernet® PON” (Glen Kramer et al., Pp 74-80, IEEE Commun, Feb. 2002.). This prior art relates to a dynamic allocation method in an EPON type FTTH service, in which an OLT sends a report to each ONU independently, and each time the OLT issues a grant to the corresponding ONU. It is about.
[0018]
FIG. 10 is a diagram showing an example of a conventional test apparatus for testing an ONU connected to such a PON system. This test apparatus includes a normative OLT 101, normative ONUs 102-1 to 102-31, a splitter 105, an ONU 150 to be tested, and an Ethernet (R) frame generator / tester 151. This test apparatus assumes a PON that can accommodate a maximum of 32 ONUs.
[0019]
In addition to the ONU 150 to be tested, 31 reference ONUs 102-1 to 102-31 are connected to this test apparatus in order to apply a system load. For these reference ONUs 102-1 to 102-31, ONUs whose operations are guaranteed are used. In addition, as the norm OLT 101, the one whose operation is guaranteed is used.
[0020]
The Ethernet (R) frame generator / tester 151 generates an Ethernet (R) frame in place of a server connected to the upper network 109 and a terminal connected to the lower network 110 to generate the norm OLT 101, norm ONU 102-1 to 102-31 or to the ONU 150 to be tested. The ONU 150 under test is tested by receiving an Ethernet (R) frame from the norm OLT 101, the norm ONUs 102-1 through 102-31, or the ONU 150 under test.
[0021]
The test apparatus having such a configuration verifies whether the ONU 150 to be tested operates correctly, whether the ONU 150 to be tested does not adversely affect other reference ONUs 102-1 to 102-31, and the like.
[0022]
In addition, this test apparatus can also use the OLT as a test target. In this case, the normative OLT 101 shown in FIG. 10 is replaced with the tested OLT to be tested, and the ONU 120 under test is replaced with the normative ONU. With such a configuration of the test apparatus, it is verified whether the OLT under test correctly accommodates the maximum number of ONUs and can perform data communication correctly.
[0023]
Furthermore, it is possible to simultaneously verify the operation of the OLT under test and the operation of the ONU under test by replacing only the reference OLT 101 shown in FIG. 10 with the OLT to be tested.
[0024]
[Non-Patent Document 1]
“IPACT: A Dynamic Protocol for an Ethernet® PON” (Glen Kramer et al., Pp 74-80, IEEE Commun, Feb. 2002.).
[0025]
[Problems to be solved by the invention]
During the development and manufacture of OLT and ONU, operation verification as a PON system is necessary, and the above-described test apparatus is used. However, since it is necessary to verify the operation of the OLT or the ONU in the maximum configuration of the PON, it is necessary to accommodate about 32 ONUs in the OLT. For this reason, there is a problem that the scale of the test apparatus becomes large, and the economical efficiency and the convenience are deteriorated.
[0026]
The present invention has been made to solve the above problems, and a first object is to provide a passive optical network test apparatus capable of simplifying the configuration of the apparatus and reducing the cost. Is to provide.
[0027]
To provide a passive optical network test apparatus capable of easily setting an attribute of a virtual ONU accommodated in a PON.
[0028]
[Means for Solving the Problems]
The passive optical network test apparatus according to claim 1 is a passive optical network test apparatus for testing an optical subscriber line terminating device or an optical subscriber line terminal device connected to the passive optical network. In accordance with the control frame received from the optical subscriber line terminal equipment, the simulation means for simulating the operation of a plurality of optical subscriber line termination equipment and the identifier included in the frame for the test received from the outside Correspondingly, a distribution means for distributing the frame to any of the optical subscriber line terminating devices simulated by the simulation means.
[0029]
Since the simulation means simulates the operation of a plurality of optical subscriber line terminating devices according to the control frame received from the optical subscriber line terminal station device, the configuration of the device can be simplified and the cost can be reduced. It becomes possible to do.
[0030]
The passive optical network test apparatus according to claim 2 is the passive optical network test apparatus according to claim 1, wherein the distribution means extracts an identifier included in a frame for a test received from the outside. And a storing means for storing the identifier cut out by the cutting means and the identifier of the optical subscriber line terminating device simulated by the simulating means in association with each other.
[0031]
The storage means stores the identifier cut out by the cutting means and the identifier of the optical subscriber line terminating device simulated by the simulation means in association with each other. It becomes possible to change.
[0032]
The passive optical network test apparatus according to claim 3 is the passive optical network test apparatus according to claim 1 or 2, wherein the simulation means receives a frame from the optical subscriber line terminal apparatus. A plurality of optical subscribers for simulating according to a control frame received from the optical subscriber line terminal apparatus via the receiving means and a transmission means for transmitting the frame to the optical subscriber line terminal apparatus; Control means for generating a control frame for the line terminating device and transmitting the control frame to the optical subscriber line terminal device via the transmitting means.
[0033]
The control means generates a control frame of a plurality of optical subscriber line terminating devices to be simulated according to the control frame received from the optical subscriber line terminal equipment via the receiving means, and the optical subscriber via the transmission means Since the data is transmitted to the line end station apparatus, it is possible to perform a test in the same state as when a plurality of optical subscriber line end apparatuses are connected to the passive optical network.
[0034]
The passive optical network test apparatus according to claim 4 is the passive optical network test apparatus according to claim 3, wherein the control means simulates a plurality of optical subscriber lines to be simulated in response to an instruction from the control terminal. Set the attributes of the end device.
[0035]
Therefore, an arbitrary attribute can be set for the simulated optical subscriber line terminating device.
[0036]
The passive optical network test apparatus according to claim 5 is the passive optical network test apparatus according to claim 3 or 4, wherein the control means simulates a plurality of optical subscriptions according to an instruction from the control terminal. Sets the virtual propagation delay of the subscriber line termination device.
[0037]
Therefore, it is possible to simulate a situation where the optical subscriber line terminating device is connected to a long optical fiber.
[0038]
A passive optical network test apparatus according to claim 6 is the passive optical network test apparatus according to any one of claims 1 to 5, further comprising a frame test machine for generating a test frame, and a frame test. And an interface means for transmitting / receiving a frame to / from the frame testing machine and outputting the received frame to the distribution means. To the second port.
[0039]
Therefore, it is possible for the frame tester to realize tests in various load conditions by transmitting frames to a plurality of optical subscriber line terminating devices and optical subscriber line terminal devices that are simulated by the simulation means. Become.
[0040]
The passive optical network test apparatus according to claim 7 is the passive optical network test apparatus according to claim 6, wherein the optical subscriber line terminating apparatus to be tested is connected to the third port of the frame test apparatus. Is done.
[0041]
Therefore, it becomes possible for the frame tester to realize tests in various load states by transmitting a frame to the optical subscriber line terminating device to be tested.
[0042]
DETAILED DESCRIPTION OF THE INVENTION
FIG. 1 is a block diagram showing a schematic configuration of a test apparatus according to an embodiment of the present invention. This test apparatus includes a norm OLT 1, an ONU 2 to be tested, a pseudo ONU 3, an Ethernet (R) frame generator / tester 4, a control terminal 5 that controls the pseudo ONU 3, and a splitter 8. This test apparatus assumes a PON that can accommodate a maximum of 32 ONUs.
[0043]
In addition to the ONU 2 to be tested, a pseudo ONU 3 is connected to the test apparatus in order to apply a system load. The pseudo ONU 3 realizes the operation of the reference ONUs 102-1 to 102-31 in the conventional test apparatus shown in FIG. 10 in a pseudo manner, and details thereof will be described later.
[0044]
The norm OLT 1 is connected to the ONU 2 to be tested and the pseudo ONU 3 through the optical fiber 6 and the splitter 8. The pseudo ONU 3 and the Ethernet (R) frame generator / tester 4 are connected by, for example, one Ethernet (R) 7.
[0045]
The norm OLT1 is connected to one port of the Ethernet (R) frame generator / tester 4, the ONU 2 under test is connected to another port of the Ethernet (R) frame generator / tester 4, and the pseudo ONU 3 is connected to the Ethernet (R) frame generator / It is connected to another port of the tester 4.
[0046]
FIG. 2 is a block diagram for explaining details of the pseudo ONU 3. The pseudo ONU 3 is connected to a PON-PHY unit 11 that controls the physical layer of the ONU, virtual ONUs 12-1 to 12-31, a distribution processing unit 13, a LAN transmission / reception IF (Interface) 14, and a control terminal 5. A control unit 15 that performs overall control of the pseudo ONU 3 and an OR circuit 16 are included.
[0047]
The LAN transmission / reception IF 14 is connected to one port of the Ethernet (R) frame generator / tester 4 via the Ethernet (R) 7 and transmits / receives Ethernet (R) frames to / from the Ethernet (R) frame generator / tester 4. To do.
[0048]
The distribution processing unit 13 selects a virtual ONU with reference to an identifier of an Ethernet (R) frame output from the LAN transmission / reception IF 14, for example, a VLAN (Virtual LAN) ID, and outputs an Ethernet (R) frame. Further, the distribution processing unit 13 outputs the Ethernet (R) frame output from the virtual ONUs 12-1 to 12-31 to the LAN transmission / reception IF 14. Since the downstream frames are time-divided, the distribution processing unit 13 can multiplex the Ethernet (R) frames output from the virtual ONUs 12-1 to 12-31 by simply outputting them to the LAN transmission / reception IF 14 as they are.
[0049]
The virtual ONUs 12-1 to 12-31 calculate the transmission period of the upstream frame based on the grant frame to itself, and output a laser-on signal during the transmission period. The OR circuit 16 calculates and outputs a logical sum of the laser-on signals output from the virtual ONUs 12-1 to 12-31.
[0050]
When receiving the upstream frame from the virtual ONUs 12-1 to 12-31, the PON-PHY unit 11 converts the electrical signal into an optical signal in synchronization with the laser on signal output from the OR circuit 16, and sends the upstream frame to the splitter 8. Is sent out.
[0051]
The control unit 15 is connected to the control terminal 5, and in accordance with a command from the control terminal 5, which virtual ONU is operated, what attribute or VLAN ID is set in which virtual ONU, etc. Take control.
[0052]
The virtual ONUs 12-1 to 12-31 have a configuration in which portions corresponding to the PON-PHY unit and the LAN transmission / reception IF are deleted from a general ONU, but if it appears as if there are a plurality of ONUs from the PON side, The entity can be anything. Further, the data path may be common and only the PON control protocol may operate independently.
[0053]
Further, a virtual propagation delay may be added as a unique attribute of the virtual ONU. When the virtual ONU time is updated with the time stamp value in the frame sent from the OLT, the ONU is connected via a long optical fiber by updating it with the time returned by the virtual propagation delay. It becomes possible to simulate.
[0054]
The Ethernet (R) frame generator / tester 4 sets a VLAN in a port connected to the pseudo ONU 3 and links it with the distribution process by the distribution processing unit 13 described above. As a result, it is possible to selectively inject traffic from the Ethernet (R) frame generator / tester 4 to the virtual ONUs 12-1 to 12-31, thereby realizing an arbitrary load situation.
[0055]
FIG. 3 is a block diagram illustrating an example of the configuration of the virtual ONUs 12-1 to 12-31. In FIG. 2, the virtual ONUs 12-1 to 12-31 are shown as individual ones. However, as shown in FIG. 3, the virtual ONUs 12-1 to 12-31 and the laser ON OR circuit 16 may be shared. Is possible. Hereinafter, this common virtual ONU is referred to as a virtual ONU group.
[0056]
The virtual ONU group includes a receiving unit 21 that receives frames via the PON-PHY unit 11, a PON control unit 22 that performs overall control of the virtual ONU group, and a buffer that accumulates frames received from the distribution processing unit 13. The memory 23 and the transmission part 24 which transmits the flame | frame accumulate | stored in the buffer memory 23 via the PON-PHY part 11 are included.
[0057]
The receiving unit 21 refers to the ONU identifier described in the PON header of the received frame, and discards the destination frame other than the virtual ONUs 12-1 to 12-31 that has jurisdiction. In the case of a frame addressed to the virtual ONUs 12-1 to 12-31 managed by the received frame, the frame type is further referred to to distinguish between the PON control frame and the user frame. If the received frame is a PON control frame, the PON control frame is sent to the PON control unit 22. If the received frame is a user frame, the user frame is sent to the distribution processing unit 13.
[0058]
The buffer memory 23 stores the user frame received from the distribution processing unit 13 in a queue for each virtual ONU. Furthermore, it may be stored in a queue for each service class.
[0059]
The PON control unit 22 terminates all the PON control frames under the jurisdiction of the virtual ONUs 12-1 to 12-31, generates PON control frames as necessary, and sends them to the norm OLT 1. Further, the PON control unit 22 joins or leaves the virtual ONU in accordance with an instruction from the control unit 15. Therefore, a PON control frame according to the protocol negotiated with the OLT is transmitted to and received from the norm OLT 1.
[0060]
The PON control unit 22 checks the queue status for each virtual ONU in the buffer memory 23 while the virtual ONU joins the PON, and sends a PON control frame such as an upstream bandwidth request inquiry, bandwidth request, bandwidth allocation, etc. A period during which frames can be sent within the PON interval is acquired by transmitting / receiving to / from the norm OLT 1. Then, the PON control unit 22 causes the transmission unit 24 to transmit the user frames queued in the buffer memory 23 during that period.
[0061]
In addition, when transmitting the PON control frame to the norm OLT 1, the PON control unit 22 once writes the PON control frame in the buffer memory 23, and transmits the PON control frame to the transmitting unit 24 during a period when transmission is permitted by the norm OLT 1. Send it.
[0062]
Furthermore, the PON control unit 22 may terminate the maintenance monitoring frame, generate a response maintenance monitoring frame, and cause the transmission unit 24 to transmit the generated maintenance monitoring frame in the same manner as the PON control frame. The PON control unit 22 outputs a laser on signal to the PON-PHY unit 11 while sending a user frame, a PON control frame, or a maintenance monitoring frame.
[0063]
Since the PON control unit 22 manages the plurality of virtual ONUs 12-1 to 12-31, the PON control unit 22 holds a state for each virtual ONU. Due to the nature of PON, the arrival of frames from the OLT and the transmission of frames to the OLT are sequential, so even when managing multiple virtual ONUs, a pseudo ONU is basically constructed with one state machine. Is possible.
[0064]
The procedure for a virtual ONU to join a PON is to send a subscription request to the OLT during a period that the ONU randomly determines during a relatively long period during which the OLT makes a subscription inquiry. Therefore, the join request may fail due to collision of join requests from a plurality of ONUs. In order to simulate this state, when a plurality of virtual ONUs send out subscription requests during one subscription inquiry period, the PON control unit 22 determines whether or not the periods for sending out the subscription requests overlap. In the case of overlapping, a join request is not sent, or an invalid frame such as a CRC (Cyclic Redundancy Check) error is sent.
[0065]
FIG. 4 is a block diagram showing a configuration of the distribution processing unit 13 shown in FIG. This distribution processing unit 13 includes a distribution table 31 in which ONU identifiers are stored corresponding to the VIDs in the VLAN tags, and a VID extraction unit that extracts the VIDs in the VLAN tags included in the uplink user frame and outputs them to the distribution table 31 32.
[0066]
The contents of the distribution table 31 are managed by the control unit 15. However, since this VID is used for the sake of testing, it is possible to delete the distribution table 31 by determining a simple conversion formula so that the VID is the same as the ONU identifier. It is.
[0067]
The control unit 15 performs basic settings for operating the pseudo ONU 3 as an ONU, similarly to a normal ONU. The control unit 15 also provides a command line interface (CLI) corresponding to a setting inquiry or change to the control terminal 5 connected via the control line.
[0068]
FIG. 5 is a diagram for explaining the types of commands that the control unit 15 receives from the control terminal 5. The join command is a command for joining the virtual ONU to the PON, and a virtual ONU bitmap is added as a parameter. Upon receiving this join command, the PON control unit 22 joins the virtual ONU that is “1” in the bitmap to the PON. At this time, the power-on of the virtual ONU that joins the PON is simulated. When a plurality of virtual ONUs are powered on simultaneously, a plurality of bits in the bitmap are set to “1”.
[0069]
The leave command is a command for leaving the virtual ONU from the PON, and a virtual ONU bitmap is added as a parameter. Upon receiving this leave command, the PON control unit 22 causes the virtual ONU that is “1” in the bitmap to leave the PON. At this time, the power-off of the virtual ONU that leaves the PON is simulated. When powering off a plurality of virtual ONUs simultaneously, a plurality of bits of the bitmap are set to “1”.
[0070]
The subscription inquiry command is a command for notifying the virtual ONU that is subscribed to the PON, and no parameter is added thereto. Upon receiving this subscription inquiry command, the PON control unit 22 notifies the virtual ONU that is subscribed to the PON at that time in a bitmap format.
[0071]
The distribution table setting command is a command for setting the contents of the distribution table 31, and an entry number and a corresponding ONU identifier are added as parameters. Upon receiving this distribution table command, the PON control unit 22 causes the distribution processing unit 13 to set an ONU identifier corresponding to the entry number of the distribution table 31.
[0072]
The distribution table inquiry command is a command for notifying the contents of the entry number set in the distribution table 31, and the entry number is added as a parameter. Upon receiving this distribution table inquiry command, the PON control unit 22 inquires the distribution processing unit 13 about the contents of the entry number and notifies the result.
[0073]
The additional RTT setting command is a command for simulating the virtual ONU so that the round-trip propagation time is delayed by the additional RTT, and an ONU identifier and an additional RTT are added as parameters. Upon receiving this additional RTT command, the PON control unit 22 simulates that the round-trip propagation time of the virtual ONU specified by the ONU identifier is delayed by the additional RTT.
[0074]
The additional RTT inquiry command is a command for inquiring an additional RTT set in the virtual ONU, and an ONU identifier is added as a parameter. When receiving the additional RTT inquiry command, the PON control unit 22 notifies the additional RTT set in the virtual ONU specified by the ONU identifier.
[0075]
FIG. 6A is a diagram for explaining basic RTT measurement. When the OLT sends a PON control frame to the ONU at time T1, the time T1 is described in a time stamp in the PON control frame. When the ONU receives this PON control frame, it updates its clock using the time stamp described in the PON control frame. The transmission start time given to the ONU is based on the ONU clock, and the time is T4. The OLT receives the PON control frame from the ONU at time T5 (time according to the OLT clock). At this time, RTT = T5−T4.
[0076]
FIG. 6B is a diagram for explaining the RTT measurement in the pseudo ONU. When the OLT sends a PON control frame to the virtual ONU, it is assumed that the actual virtual ONU is at the position L0. In order to simulate the virtual ONU as if it were at the position of L1, the control unit 15 of the pseudo ONU 3 receives its PON control frame at the time when it receives the PON control frame, with its time stamp described in the PON control frame. Update. Then, the transmission start time given to the virtual ONU is delayed by the additional RTT. When the time of the pseudo ONU reaches that time, the PON control unit 22 starts transmitting a PON control frame. The time stamp described in the PON control frame is a time returned by the additional RTT from the current time. In this way, it is possible to simulate the pseudo ONU as if it were in the position of L1.
[0077]
Alternatively, each pseudo ONU may have an independent clock, and the clock may be updated at a time that goes back by an additional RTT from the time stamp.
[0078]
As described above, according to the inspection apparatus in the present embodiment, since one pseudo ONU 3 simulates the operation of a plurality of standard ONUs, the configuration of the passive optical network inspection apparatus is simplified. It has become possible to reduce the cost of passive optical network test equipment.
[0079]
Also, when the PON control unit 22 receives an additional RTT setting command from the control terminal 5, the round trip propagation time is delayed by the additional RTT, so that the virtual ONU is connected to a long optical fiber. It became possible to simulate the situation.
[0080]
In addition, the PON control unit 22 joins the virtual ONU to the PON or removes the virtual ONU from the PON in response to the join command or the leave command received from the control terminal 5, so that it is accommodated in the PON. The number of virtual ONUs to be performed can be made arbitrary, and tests in various situations can be realized.
[0081]
Furthermore, since the PON control unit 22 sets the VID to the virtual ONU in response to the distribution table setting command received from the control terminal 5, an arbitrary ONU identifier can be assigned to the virtual ONU. It became possible to increase the versatility of the test equipment.
[0082]
The embodiment disclosed this time should be considered as illustrative in all points and not restrictive. The scope of the present invention is defined by the terms of the claims, rather than the description above, and is intended to include any modifications within the scope and meaning equivalent to the terms of the claims.
[0083]
【The invention's effect】
According to the passive optical network test apparatus of the first aspect, the simulating means simulates the operation of the plurality of optical subscriber line terminating devices according to the control frame received from the optical subscriber line terminal equipment. The configuration of the apparatus can be simplified and the cost can be reduced.
[0084]
According to the passive optical network test apparatus of claim 2, the storing means stores the identifier cut out by the cutting out means and the identifier of the optical subscriber line terminating apparatus simulated by the simulating means in association with each other. Therefore, it is possible to change the association of identifiers by changing this content.
[0085]
According to the passive optical network testing apparatus of claim 3, the control means simulates a plurality of optical subscriber line terminations simulated according to the control frame received from the optical subscriber line terminal equipment via the receiving means. Since the control frame of the device is generated and transmitted to the optical subscriber line terminal equipment via the transmission means, the test is performed in the same state as when a plurality of optical subscriber line termination devices are connected to the passive optical network. It became possible to do.
[0086]
According to the passive optical network test apparatus of the fourth aspect, it is possible to set an arbitrary attribute to the simulated optical subscriber line terminating apparatus.
[0087]
According to the passive optical network test apparatus of the fifth aspect, it is possible to simulate a situation in which the optical subscriber line terminating device is connected to a long optical fiber.
[0088]
According to the passive optical network test apparatus of the sixth aspect, the frame test machine transmits the frame to the plurality of optical subscriber line terminating apparatuses and the optical subscriber line terminal station apparatuses simulated by the simulation means. It became possible to realize tests under various load conditions.
[0089]
According to the passive optical network test apparatus of the seventh aspect, it is possible for the frame tester to realize the test in various load conditions by transmitting the frame to the optical subscriber line terminating apparatus to be tested. It became.
[Brief description of the drawings]
FIG. 1 is a block diagram showing a schematic configuration of a test apparatus in an embodiment of the present invention.
FIG. 2 is a block diagram for explaining details of a pseudo ONU 3;
FIG. 3 is a block diagram illustrating an example of a configuration of virtual ONUs 12-1 to 12-31.
4 is a block diagram showing a configuration of a distribution processing unit 13 shown in FIG.
FIG. 5 is a diagram for explaining the types of commands that the control unit 15 receives from the control terminal 5;
FIG. 6A is a diagram for explaining basic RTT measurement; (B) is a figure for demonstrating the RTT measurement in pseudo | simulation ONU.
FIG. 7 is a block diagram showing a schematic configuration of a conventional PON system.
FIG. 8 is a sequence diagram for explaining an operation procedure of a conventional PON system.
FIG. 9 is a diagram illustrating an example of a distributed allocation method.
FIG. 10 is a diagram showing an example of a conventional test apparatus for testing an ONU connected to a PON system.
[Explanation of symbols]
1,101 Standard OLT, 2,150 ONU under test, 3 pseudo ONU, 4,151 Ethernet (R) frame generator / tester, 5 control terminal, 6 optical fiber, 7 Ethernet (R), 8,105 splitter, 11 PON -PHY unit, 12-1 to 12-31 Virtual ONU, 13 distribution processing unit, 14 LAN transmission / reception IF, 15 control unit, 16 OR circuit, 22 PON control unit, 23 buffer memory, 24 transmission unit, 31 distribution table, 32 VID Cutout unit, 102-1 to 102-n Standard ONU, 103-1 to 103-n buffer, 104 transmission path, 106 grant, 107 report, 108 uplink information frame, 109 upper network, 110 lower network, 111 user terminal.

Claims (7)

A passive optical network testing device for testing an optical subscriber line termination device or an optical subscriber line terminal device connected to a passive optical network,
Simulation means for simulating the operation of a plurality of optical subscriber line termination devices according to the control frame received from the optical subscriber line terminal device;
Passive light including distribution means for distributing the frame to one of optical subscriber line termination devices simulated by the simulation means in accordance with an identifier included in a frame for a test received from the outside Network test equipment. The distribution means includes a cutting means for cutting out an identifier included in the frame for the test received from the outside,
The passive optical network according to claim 1, further comprising storage means for associating and storing the identifier cut out by the cutting means and the identifier of the optical subscriber line terminating device simulated by the simulation means. Test equipment. The simulation means includes a receiving means for receiving a frame from the optical subscriber line terminal station device;
Transmitting means for transmitting a frame to the optical subscriber line terminal equipment;
In response to a control frame received from the optical subscriber line terminal station device via the receiving means, a control frame of a plurality of optical subscriber line terminating devices to be simulated is generated, and the optical subscriber is transmitted via the transmitting means. The passive optical network test apparatus according to claim 1, further comprising control means for transmitting to the line end station apparatus. 4. The passive optical network test apparatus according to claim 3, wherein the control means sets attributes of a plurality of optical subscriber line terminating devices to be simulated in accordance with an instruction from a control terminal. 5. The passive optical network test apparatus according to claim 3, wherein the control unit sets virtual propagation delays of a plurality of optical subscriber line terminating apparatuses to be simulated according to an instruction from a control terminal. The passive optical network test apparatus further includes a frame test machine that generates a test frame;
Interface means connected to the first port of the frame tester, transmitting and receiving frames to and from the frame tester, and outputting the received frames to the distribution means;
6. The passive optical network test apparatus according to claim 5, wherein the optical subscriber line terminal station apparatus is connected to a second port of the frame test machine. 7. The passive optical network test apparatus according to claim 6, wherein the optical subscriber line terminating apparatus to be tested is connected to a third port of the frame test machine.

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