JP7158310B2 - Optical communication device and control method - Google Patents

Description

The present invention relates to an optical communication device and control method.

A PON (Passive Optical Network) system, which is an optical communication system, is known. A PON system consists of an optical communication device (also referred to as a master station device) installed in a communication carrier office building and a plurality of optical communication devices (also referred to as slave station devices) on the subscriber side (also referred to as a slave station side). include. The parent station device is called an OLT (Optical Line Termination). A slave station device is called an ONU (Optical Network Unit).

In the PON system, control based on time division multiplexing of upstream signals is performed. Note that the upstream signal is an optical signal transmitted from the ONU to the OLT. The control is standardized by IEEE802.3. By performing control based on time division multiplexing, collision of optical signals can be prevented. A technology related to time-division multiplexing has also been proposed (see Patent Document 1).

Conventionally, an OLT has been realized with a single dedicated H/W (hardware) device. In order to enable the addition and deletion of functions flexibly and quickly, implementation of part of the functions of the OLT by general-purpose devices is under consideration. In other words, the OLT under consideration consists of a dedicated H/W device and a general-purpose device. A general-purpose device is also called a host device. The general-purpose device has high-layer functions among the functions of the OLT. A dedicated H/W device is also called a lower device. The dedicated H/W device has low-layer functions among the OLT functions. FASA (Flexible Access System Architecture) can be cited as an architecture of the OLT under consideration (see Non-Patent Document 1).

JP 2017-152773 A

NTT Access Service Systems Laboratories "New Access System Architecture (FASA) White Paper Ver. 2.0", Internet <URL: http://www. ansl. ntt. co. jp/j/FASA/index. html> Ｒｙｏ Ｋｏｍａ， Ｍａｓａｍｉｃｈｉ Ｆｕｊｉｗａｒａ， Ｊｕｎ－ｉｃｈｉ Ｋａｎｉ， Ｓａｎｇ－Ｙｕｅｐ Ｋｉｍ， Ｔａｋａｈｉｒｏ Ｓｕｚｕｋｉ， Ｋｅｎ－Ｉｃｈｉ Ｓｕｚｕｋｉ， ａｎｄ Ａｋｉｈｉｒｏ Ｏｔａｋａ、「Ｄｅｍｏｎｓｔｒａｔｉｏｎ ｏｆ Ｒｅａｌ－Ｔｉｍｅ Ｂｕｒｓｔ－Ｍｏｄｅ Ｄｉｇｉｔａｌ Ｃｏｈｅｒｅｎｔ Ｒｅｃｅｐｔｉｏｎ ｗｉｔｈ Ｗｉｄｅ Ｄｙｎａｍｉｃ Ｒａｎｇｅ ｉｎ ＤＳＰ－ｂａｓｅｄ ＰＯＮ Ｕｐｓｔｒｅａｍ ”, “Journal of Lightwave Technology”, 2016 IEEE

As described above, it is conceivable that the functions of the OLT are realized by a plurality of devices. It is desirable that many functions of the OLT be realized by general-purpose devices rather than by dedicated H/W devices. For example, the function of determining the reception timing of the optical signal is implemented by a general-purpose device. The function of receiving an optical signal is implemented by a dedicated H/W device. When such function allocation is performed, the general-purpose device calculates the reception timing of the optical signal. Based on the reception timing, the general-purpose device controls the dedicated H/W device so as to receive the optical signal. Here, for example, in a system such as a 10G-EPON system, time is managed with 16 ns as 1TQ (Time Quanta). Therefore, the general-purpose device controls the dedicated H/W device on a TQ basis. However, when the general-purpose device controls the dedicated H/W device in TQ units, the general-purpose device and the dedicated H/W device need to be provided with an IF (interface) that realizes high-speed communication. Equipping the general-purpose device and the dedicated H/W device with an IF that realizes high-speed communication increases the cost.

An object of the present invention is to contain costs.

An optical communication device according to one aspect of the present invention is provided. The optical communication device is a master station device. The optical communication device includes a transmission/reception control device that communicates with a slave station device, a first frame that is information for assigning an identifier to the slave station device, and a time for causing the slave station device to start transmitting an optical signal. and a frame generation device for generating a second frame that is information including a transmission start time. The first frame includes a first round-trip time, which is an information round-trip time in communication between the frame generation device and the slave station device via the transmission/reception control device. the transmission/reception control device receives the first frame and the second frame, and converts the transmission start time, the first round-trip time, and an optical signal transmitted by the slave station device into an electrical signal; the slave station device based on a delay time, which is a processing time for executing processing on the electrical signal , and a second round-trip time, which is an information round-trip time in communication between the frame generation device and the transmission/reception control device; calculates the reception time, which is the time at which the transmission/reception control device receives the optical signal transmitted by .

According to the present invention, costs can be suppressed.

1 is a diagram showing an optical communication system according to Embodiment 1; FIG. 2 is a diagram showing the main hardware configuration of the frame generation device according to Embodiment 1; FIG. 2 is a diagram showing an example (part 1) of a protocol stack of an OLT according to Embodiment 1; FIG. 2 is a diagram showing an example (part 2) of a protocol stack of an OLT according to Embodiment 1; FIG. 4 is a diagram for explaining the MPCP process of Embodiment 1; FIG. 1 is a functional block diagram showing the configuration of a frame generation device according to Embodiment 1; FIG. 4 is a diagram showing the format of a Register frame according to Embodiment 1; FIG. 2 is a functional block diagram showing the configuration of a transmission/reception control device according to Embodiment 1; FIG. 4 is a diagram showing an example of a management table according to Embodiment 1; FIG. FIG. 10 is a diagram showing RTT calculation processing according to the first embodiment; FIG. 10 is a diagram showing calculation processing of an RTT correction value according to Embodiment 1; 3 is a specific example (part 1) of optical signal transmission/reception processing according to the first embodiment; 2 is a specific example (part 2) of optical signal transmission/reception processing according to the first embodiment. FIG. 10 is a diagram showing the format of a Normal Gate frame according to Embodiment 2; FIG. FIG. 9 is a functional block diagram showing the configuration of a transmission/reception control device according to Embodiment 2;

Embodiments will be described below with reference to the drawings. The following embodiments are merely examples, and various modifications are possible within the scope of the present invention.

Embodiment 1.
FIG. 1 is a diagram showing an optical communication system according to Embodiment 1. FIG. The optical communication system includes OLT 10 and ONUs 21-24. FIG. 1 illustrates a case where the number of ONUs is four. However, the number of ONUs is not limited to four. The OLT 10 and the ONUs 21-24 are connected via an optical coupler 30. FIG.

The OLT 10 transmits optical signals to the ONUs. An optical signal that the OLT 10 transmits to the ONU is called a downstream signal. Also, the optical signal transmitted from the ONU to the OLT 10 is called an upstream signal.

ONUs 21 and 22 are optical communication devices that communicate at a communication speed of 10 Gbps. ONUs 23 and 24 are optical communication devices that communicate at a communication speed of 1 Gbps.

Thus, an optical communication system is a system that communicates at multiple different communication speeds. Therefore, for example, the optical communication system may be considered as a 10G-EPON (10 Gigabit Ethernet Passive Optical Network) system. In the optical communication system, time is managed with 16 ns as one TQ.
Also, the optical communication system may be a PON system in which one or more methods of wavelength, light receiving sensitivity, transmission power, communication speed, modulation, coding, FEC (Forward Error Correction), encryption, and filter are different for each ONU.

The OLT 10 has a frame generation device 100 and a transmission/reception control device 200 . For example, frame generation device 100 may be considered a general-purpose device. The transmission/reception control device 200 may be considered as a dedicated H/W device. Also, the OLT 10 may be expressed as a parent station control system including the frame generation device 100 and the transmission/reception control device 200 .

The frame generation device 100 and the transmission/reception control device 200 are devices that execute the control method. The frame generation device 100 has high layer functions among the functions of the OLT 10 . The transmission/reception control device 200 has low-layer functions among the functions of the OLT 10 . The frame generation device 100 and the transmission/reception control device 200 communicate using a general-purpose IF. For example, a general-purpose IF is an IF that is not a high-speed IF. That is, a general-purpose IF is a low-speed IF. For example, the slow IF is I2C (registered trademark). Equipping the frame generation device 100 and the transmission/reception control device 200 with a general-purpose IF can reduce costs.

Next, the main hardware configuration of the frame generation device 100 will be described.
FIG. 2 is a diagram showing the main hardware configuration of the frame generation device according to the first embodiment. The frame generation device 100 has a processor 101 , a volatile storage device 102 and a non-volatile storage device 103 .

A processor 101 controls the entire frame generation device 100 . For example, the processor 101 is a CPU (Central Processing Unit) or an FPGA (Field Programmable Gate Array). Processor 101 may be a multiprocessor. The frame generation device 100 may be implemented by processing circuitry, or may be implemented by software, firmware, or a combination thereof. It should be noted that the processing circuit may be a single circuit or multiple circuits.

The volatile memory device 102 is the main memory device of the frame generation device 100 . For example, the volatile memory device 102 is RAM (Random Access Memory). The nonvolatile storage device 103 is an auxiliary storage device for the frame generation device 100 . For example, the nonvolatile storage device 103 is a HDD (Hard Disk Drive) or SSD (Solid State Drive).
The transmission/reception control device 200 and the ONUs 21 to 24, like the frame generation device 100, have processors, volatile storage devices, and non-volatile storage devices.

FIG. 3 is a diagram illustrating an example (Part 1) of an OLT protocol stack according to the first embodiment. The functions in the frame 104 of the frame generation device 100 can be realized by the processor 101 executing a predetermined program.
The frame generation device 100 has an IF function section 110 . The transmission/reception control device 200 has an IF function section 210 . IF function unit 110 and IF function unit 210 can communicate.

FIG. 3 shows that the dividing point of the layer of the OLT function is between RS (Reconciliation Sublayer) and PCS (Physical Coding Sublayer). However, the dividing point of the layer of the OLT function may be other than between the RS and the PCS.
Here, the OLT 10 may have a conventional OLT and an adapter. Here, the conventional OLT is called a dedicated device.

FIG. 4 is a diagram illustrating an example (part 2) of an OLT protocol stack according to the first embodiment. The OLT 10 has a dedicated device 300 and an adapter 400 . Adapter 400 performs digital signal processing. For example, the adapter 400 uses an adaptive equalization algorithm as digital signal processing to compensate for waveform distortion due to effects such as polarization mode dispersion (PMD) and chromatic dispersion (CD). Further, for example, the adaptive equalization algorithm is a CMA (Constant Modulus Algorithm) used when digitally coherently receiving a phase-modulated signal modulated by QPSK (Quadrature Phase Shift Keying). For example, digital signal processing is described in Non-Patent Document 2.

Next, the MPCP (Multi-Point Control Protocol) process will be described.
FIG. 5 is a diagram for explaining the MPCP process of the first embodiment. FIG. 5 will be explained using the OLT 10 and the ONU 21 .

(Step S101) The OLT 10 transmits a Discovery Gate frame to establish a logical connection relationship.
(Step S102) The OLT 10 transmits a Discovery Gate frame.
Thus, the OLT 10 periodically transmits Discovery Gate frames.

(Step S<b>103 ) ONU 21 transmits a Register Request frame to OLT 10 when it receives a Discovery Gate frame.
(Step S104) The OLT 10 receives the Register Request frame. The OLT 10 detects the existence of the ONU 21 by receiving the Register Request frame. Also, the OLT 10 grasps the frame round-trip time between the OLT 10 and the ONU 21 . The frame round-trip time is also called RTT (Round Trip Time).

OLT 10 transmits a Register frame. The Register frame is information for allocating an LLID (Logical Link Identifier) to the ONU 21 . LLID is also called an identifier.
By allocating an LLID to the ONU 21, when the ONU 21 receives a frame including the allocated LLID, it can detect that the information is addressed to itself.

(Step S105) The OLT 10 transmits a Normal Gate frame. The Normal Gate frame includes the uplink signal transmission start time. The transmission start time is the time at which the ONU is caused to start transmitting upstream signals. Also, the transmission start time may be expressed as the time at which the start of uplink signal transmission is permitted.
(Step S106) ONU 21 transmits a Register ACK frame at the transmission start time included in the Normal Gate frame.

(Step S107) The OLT 10 receives the Register ACK frame. The OLT 10 completes LLID registration by receiving the Register ACK frame. Thereby, a logical connection relationship is established between the OLT 10 and the ONU 21 . Here, a logical connection relationship is also called a PON link.
OLT 10 transmits a Normal Gate frame.

(Step S108) ONU 21 registers the amount of data accumulated in its own device in the Report frame. Here, the data amount is also called a transmission request data amount. ONU 21 transmits a Report frame.
(Step S109) The OLT 10 registers the transmission start time and band of the upstream signal in the Normal Gate frame. OLT 10 transmits a Normal Gate frame.
(Step S110) The ONU 21 transmits an upstream signal including data at the transmission start time included in the Normal Gate frame.

Here, an overview of the first embodiment will be described. In the following explanation, the ONU 21 will be used, but the ONU may be any one of the ONUs 22-24.
The frame generation device 100 generates a Register frame and a Normal Gate frame. The Register frame is also called the first frame. The Normal Gate frame is also called a second frame or a third frame. The Register frame contains the RTT. RTT is also referred to as first round trip time. The first round-trip time is the information round-trip time in communication between the frame generation device 100 and the ONU 21 via the transmission/reception control device 200 .

The transmission/reception control device 200 communicates with the ONU 21 . The transmission/reception control device 200 receives the Register frame and the Normal Gate frame from the frame generation device 100 . The transmission/reception control device 200 calculates the reception time based on the transmission start time, RTT, delay time, and ΔRTT.

The delay time is the time from when the transmission/reception control device 200 receives the optical signal transmitted by the ONU 21 to when the transmission/reception control device 200 transmits an electrical signal based on the received optical signal to the frame generation device 100 . The delay time may be expressed as a processing time for converting an optical signal transmitted by the ONU 21 into an electrical signal and processing the electrical signal. Note that the delay time is ΔT, which will be described later.

ΔRTT is the information round-trip time in communication between the frame generation device 100 and the transmission/reception control device 200 . ΔRTT is also referred to as RTT correction value or second round trip time.
The reception time is the time at which the optical signal transmitted by the ONU 21 is received.

Thus, the transmission/reception control device 200 calculates the reception time. Since the transmission/reception control device 200 calculates the reception time, the frame generation device 100 does not need to calculate the reception time. That is, the frame generation device 100 does not need to calculate the reception timing of the optical signal. If the frame generation device 100 does not calculate the reception timing of the optical signal, the frame generation device 100 need not control the transmission/reception control device 200 so that the optical signal can be received based on the reception timing. If the frame generation device 100 does not execute the control, the frame generation device 100 and the transmission/reception control device 200 do not need to have an IF that realizes high-speed communication. That is, the frame generation device 100 and the transmission/reception control device 200 need only have a general-purpose IF. Equipping the frame generation device 100 and the transmission/reception control device 200 with a general-purpose IF can reduce costs.

Next, the frame generation device 100 and the transmission/reception control device 200 will be described in detail.
6 is a functional block diagram showing the configuration of the frame generation device according to Embodiment 1. FIG. The frame generation device 100 has an IF function section 110 and a frame generation section 120 .
A part or all of the IF function unit 110 and the frame generation unit 120 may be implemented by the processor 101 . A part or all of the IF function unit 110 and the frame generation unit 120 may be implemented as modules of a program executed by the processor 101 .

The IF function unit 110 transmits the MPCP frame generated by the frame generation unit 120 to the transmission/reception control device 200 . MPCP frames are Discovery Gate frames, Register frames, Normal Gate frames, Report frames, and the like. The IF function unit 110 also receives information from the transmission/reception control device 200 . It is assumed that IF function section 110 includes the function of RS.

The frame generator 120 controls the MPCP function, schedules transmission and reception of optical signals, and generates MPCP frames. Specifically, the frame generator 120 establishes the PON link, calculates the RTT, manages the ONU type and RTT corresponding to each LLID, and determines the transmission start time.

As described above, the frame generator 120 generates a Register frame among MPCP frames. Here, the LLID, the ONU type corresponding to the LLID, and the RTT are registered in the Register frame generated by the frame generation unit 120 . Here, the format of the Register frame will be explained.

7 is a diagram showing the format of a Register frame according to Embodiment 1. FIG. FIG. 7 shows that the LLID is registered in the Assigned port field. Also, FIG. 7 shows that the RTT and ONU type corresponding to the LLID are registered in the Padding field.
Also, the frame generator 120 calculates an RTT correction value. Calculation of the RTT correction value will be described later.

FIG. 8 is a functional block diagram showing the configuration of the transmission/reception control device according to the first embodiment. The transmission/reception control device 200 has an IF function section 210 , an optical transmission/reception section 220 , a signal processing section 230 , an information extraction section 240 , a control signal generation section 250 , a time management section 260 and a storage section 270 .
The storage unit 270 can be implemented as a storage area secured in a volatile storage device and a nonvolatile storage device of the transmission/reception control device 200 .

Some or all of the IF function unit 210, the optical transmission/reception unit 220, the signal processing unit 230, the information extraction unit 240, the control signal generation unit 250, and the time management unit 260 may be implemented by a processor included in the transmission/reception control device 200. good. Some or all of the IF function unit 210, the optical transmission/reception unit 220, the signal processing unit 230, the information extraction unit 240, the control signal generation unit 250, and the time management unit 260 are programs executed by the processor of the transmission/reception control device 200. It may be implemented as a module.

IF function unit 210 communicates with frame generation device 100 . The IF function unit 210 may have a loopback function. The Loopback function will be explained later.
The optical transmitter/receiver 220 receives upstream signals transmitted by the ONUs 21-24. The optical transmitter/receiver 220 converts the upstream signal into an electrical signal. The optical transceiver 220 transmits the converted electrical signal to the signal processor 230 .

Also, the communication speed of the ONUs 21 to 24 is 1 Gbps or 10 Gbps. Since the communication speeds are mixed in this manner, the optical transmitter/receiver 220 dynamically switches the band, the gain, and the like. That is, the optical transmitter/receiver 220 needs to identify the source of the upstream signal before receiving the upstream signal. Therefore, a timing control signal is transmitted to the optical transmitter/receiver 220 . The optical transmitter/receiver 220 is controlled based on the timing control signal. There are two timing control signals, a rate select signal and a reception reset signal. A rate select signal may be described as an Rx_SELECT signal. A received reset signal may be described as an Rx_RESET signal. The rate select signal is a signal for switching the receiving circuit of the optical transmitting/receiving section 220 according to the receiving band. The reception reset signal is a signal for resetting the reception circuit when switching the reception band. Note that the timing control signal is generated by the control signal generator 250 .

The optical transmitter/receiver 220 also converts the electrical signal received from the signal processor 230 into a downstream signal. The optical transceiver 220 transmits a downstream signal.
The signal processing unit 230 has PCS functions such as FEC, encryption, and encoding, and PMA (Physical Media Attachment) functions such as serial/parallel conversion, modulation, and demodulation. Thus, the signal processing unit 230 performs preprocessing for transmitting the electrical signal to the frame generation device 100 .

Information extractor 240 extracts information from the MPCP frame. Specifically, the information extractor 240 extracts the LLID, RTT, and ONU type from the Register frame. The information extractor 240 registers the LLID, RTT, and ONU type in the management table. A specific example of the management table is shown here.

9 is a diagram illustrating an example of a management table according to the first embodiment; FIG. A management table 271 is stored in the storage unit 270 . The management table 271 has items of item number, LLID, RTT, and ONU type.
The information extractor 240 also extracts the LLID described in the preamble of the Normal Gate frame and the transmission start time of the ONU. The ONU transmission start time is also called GST (Grant Start Time). The information extractor 240 notifies the control signal generator 250 of the LLID and the transmission start time of the ONU.

The information extractor 240 extracts the value of the TimeStamp field of the Discovery Gate frame. The information extraction unit 240 notifies the time management unit 260 of the extracted values. Thereby, the time of the frame generation device 100 and the transmission/reception control device 200 are synchronized. The information extractor 240 also extracts the value of the Start Time field of the Discovery Gate frame. Information extractor 240 notifies control signal generator 250 of the extracted value.

The information extractor 240 extracts an RTT correction value from a Loopback OFF frame, which will be described later. Information extraction section 240 stores the RTT correction value in storage section 270 .
The control signal generator 250 generates an Rx_SELECT signal and an Rx_RESET signal based on the Start Time and the ONU type so that the Register Request frame can be correctly received by the transmission/reception control device 200 . The control signal generator 250 outputs the Rx_SELECT signal and the Rx_RESET signal to the optical transceiver 220 .

The control signal generator 250 calculates the reception time. A method of calculating the reception time will be described later.
Also, the control signal generator 250 generates an Rx_SELECT signal and an Rx_RESET signal based on the ONU type so that the transmission/reception control device 200 can correctly receive the data transmitted by the ONU. The timing of generation is determined based on the reception time and the guard time. The control signal generator 250 outputs the Rx_SELECT signal and the Rx_RESET signal to the optical transceiver 220 .

The time management unit 260 increments the value of TimeStamp extracted by the information extraction unit 240 every 16 ns. Note that the value of TimeStamp is expressed in units of TQ. The time management unit 260 provides the counted value to the control signal generation unit 250 .

Next, RTT calculation processing will be described.
FIG. 10 is a diagram depicting RTT calculation processing according to the first embodiment. The horizontal axis of FIG. 10 is time.
Here, it is assumed that the ONU 22 is not assigned an LLID. It is also assumed that the ONU 22 has received the Discovery Gate frame from the OLT 10 . For example, the ONU 22 is in the state of step S102 in FIG. GST0 is registered in the Discovery Gate frame. GST is the transmission start time.

ONU 22 transmits a Register Request frame to GST0 as an upstream signal.
The optical transceiver 220 receives the Register Request frame. The time when the Register Request frame was received by the transmission/reception control device 200 is RX0_HW.

The signal processing unit 230 processes the Register Request frame. After completing the processing, IF function unit 210 transmits a Register Request frame to frame generation device 100 . The IF function unit 110 receives the Register Request frame. Note that the time when the Register Request frame was received by the frame generation device 100 is RX0_SERVER.
Here, the frame generation device 100 can calculate the RTT using Equation (1).

RTT#0=RX0_SERVER-GST0 (1)

There is a distance between the frame generation device 100 and the transmission/reception control device 200 . Therefore, it takes time for the frame generation device 100 to receive the Register Request frame. This time is expressed as an RTT correction value. Also, the RTT correction value is described as ΔRTT.
Here, RX0_HW can be expressed using Equation (2).

RX0_HW=GST0+RTT#0-(ΔT+ΔRTT) (2)

ΔT in equation (2) is the total time of the time taken by the optical transceiver 220 to convert an upstream signal into an electrical signal and the time taken by the signal processor 230 to process the electrical signal.
Note that ΔT and the RTT correction value are values that do not fluctuate. The time taken by the optical transmitter/receiver 220 and the signal processor 230 can be measured in advance. That is, ΔT can be measured in advance. Therefore, the ΔT measured in advance may be stored in the storage unit 270 .

Here, the processing for calculating the RTT correction value will be described.
FIG. 11 is a diagram illustrating calculation processing of an RTT correction value according to the first embodiment. The process of FIG. 11 is executed after the frame generation device 100 and the transmission/reception control device 200 become ready for communication.
Frame generator 120 generates a Loopback ON frame. IF function unit 110 transmits a Loopback ON frame. IF function unit 210 receives the Loopback ON frame. The IF function unit 210 turns on the Loopback function.

The frame generator 120 generates an RTT correction value measurement frame including Time Stamp. The IF function unit 110 transmits an RTT correction value measurement frame to the transmission/reception control device 200 at time t1. IF function section 210 transmits the RTT correction value measurement frame to frame generation device 100 . Thus, the RTT correction value measurement frame is looped back. IF function section 110 receives the RTT correction value measurement frame at time t2.
The frame generator 120 calculates the RTT correction value using Equation (3). Note that the RTT correction value is ΔRTT.

ΔRTT=t2−t1 (3)

Thus, the RTT correction value is calculated.
Frame generator 120 generates a Loopback OFF frame including ΔRTT. The IF function unit 110 transmits the Loopback OFF frame to the transmission/reception control device 200 . IF function unit 210 receives the Loopback OFF frame. The IF function unit 210 turns off the loopback function.

IF function section 210 transmits the Loopback OFF frame to information extraction section 240 . The information extractor 240 extracts ΔRTT from the Loopback OFF frame. Information extraction section 240 stores ΔRTT in storage section 270 .

ΔRTT may be stored in storage unit 270 by a method other than the above method. For example, ΔRTT is measured by an OTDR (Optical Time Domain Reflectometer) or the like. An external terminal (not shown) storing the measured ΔRTT stores ΔRTT in the storage unit 270 .

Next, optical signal transmission/reception processing will be described with reference to FIGS.
FIG. 12 is a specific example (part 1) of optical signal transmission/reception processing according to the first embodiment. FIG. 13 shows a specific example (part 2) of optical signal transmission/reception processing according to the first embodiment.
Here, it is assumed that the ONU 21 is not assigned an LLID. It is assumed that the ONU 23 is assigned an LLID.

Frame generator 120 generates a Discovery Gate frame at time T1. The IF function unit 110 transmits the Discovery Gate frame to the transmission/reception control device 200 .
The IF function unit 210 receives the Discovery Gate frame. The information extractor 240 extracts the value T1 registered in the Time Stamp field and the value T2 registered in the Start Time field of the Discovery Gate frame.

Information extractor 240 transmits value T1 to time manager 260 . The time manager 260 loads the value T1 into the time counter. Thereby, the time of the frame generation device 100 and the transmission/reception control device 200 are synchronized.
Also, the information extraction unit 240 extracts the ONU type from the value of the Discovery Information field. The ONU type is 1. That is, the ONU type indicates that it is a 10 Gbps ONU. The information extractor 240 transmits the value T2 and the ONU type to the control signal generator 250 .

The control signal generation unit 250 compares the value of the time counter managed by the time management unit 260 with the value T2. The control signal generator 250 generates the Rx_SELECT signal and the Rx_RESET signal before the guard time of the value T2. Here, the logic level of the Rx_SELECT signal is determined based on the ONU type. When the ONU type is 1, the logic level of the Rx_SELECT signal is High. If the ONU type is 0, the logic level of the Rx_SELECT signal is Low. Since the ONU type transmitted by the information extractor 240 is 1, the control signal generator 250 sets the logic level of the Rx_SELECT signal to High. The control signal generator 250 transmits the Rx_SELECT signal and the Rx_RESET signal to the optical transceiver 220 .

The signal processing unit 230 performs PCS and PMA processing on the Discovery Gate frame. After completing the processing, the optical transmitter/receiver 220 transmits a Discovery Gate frame.

ONU 21 receives the Discovery Gate frame. The ONU 21 extracts the value T1 registered in the Time Stamp field of the Discovery Gate frame. The ONU 21 synchronizes the local time managed within the ONU 21 with the value T1. The ONU 21 waits for a random delay time after the local time reaches the value T2 registered in the Start Time field of the Discovery Gate frame. After a random delay time, the ONU 21 transmits the Register Request frame as an upstream signal. The time when the Register Request frame is transmitted is assumed to be time T3. Also, the time T3 is registered in the Time Stamp field of the Register Request frame.

The optical transceiver 220 receives the Register Request frame. Since the logic level of the Rx_SELECT signal is High, the optical transceiver 220 can correctly receive the Register Request frame.
The signal processing unit 230 performs PCS and PMA processing on the Register Request frame. After completing the processing, IF function unit 210 transmits a Register Request frame to frame generation device 100 .

Assume that the frame generator 120 receives the Register Request frame at time T4.
Frame generation section 120 calculates RTT#1 using equation (4).

RTT#1=T4-T3 (4)

Note that the time T3 in Equation (4) is the time included in the Register Request frame.
The frame generator 120 assigns an LLID to the ONU 21 . LLID is assumed to be 0x0001. Frame generator 120 generates a Register frame. Also, RTT#1, ONU type, and LLID are registered in the Register frame. Note that the ONU type is 1. Also, the LLID is 0x0001. The IF function unit 110 transmits the Register frame to the transmission/reception control device 200 .

IF function unit 210 receives the Register frame. The information extractor 240 extracts the RTT#1, ONU type, and LLID from the Register frame. The information extraction unit 240 registers the RTT#1, ONU type, and LLID in the management table 271. FIG.
After the information extraction unit 240 extracts RTT#1 and the like from the Register frame, the signal processing unit 230 performs PCS and PMA processing on the Register frame. After the processing is finished, the optical transmitter/receiver 220 transmits the Register frame.

The frame generator 120 generates a Normal Gate frame addressed to the ONU 21 . LLID, GST1, and GL1 are registered in the Normal Gate frame. The LLID is 0x0001. GL1 is transmission band information. The IF function unit 110 transmits the Normal Gate frame to the transmission/reception control device 200 .

IF function unit 210 receives the Normal Gate frame. Information extractor 240 extracts LLID and GST1 from the Normal Gate frame. Information extractor 240 transmits LLID and GST1 to control signal generator 250 . The control signal generator 250 acquires the RTT and ONU type registered in the management table 271 using the LLID as a key. The acquired RTT and ONU type are RTT#1 and 1.
The control signal generator 250 calculates the reception time RX1_HW of the uplink signal transmitted by the ONU 21 using equation (5).

RX1_HW=GST1+RTT#1-(ΔT+ΔRTT) (5)

The control signal generation unit 250 compares the value of the time counter managed by the time management unit 260 with RX1_HW. The control signal generator 250 generates the Rx_SELECT signal and the Rx_RESET signal before RX1_HW by the guard time. Note that the logic level of the Rx_SELECT signal is High. The control signal generator 250 transmits the Rx_SELECT signal and the Rx_RESET signal to the optical transceiver 220 .
The signal processing unit 230 performs PCS and PMA processing on the Normal Gate frame. After completing the processing, the optical transmitter/receiver 220 transmits a Normal Gate frame.

ONU 21 receives the Normal Gate frame. When the Local Time reaches GST1, the ONU 21 transmits a Register Ack frame.
The optical transceiver 220 receives the Register Ack frame at time RX1_HW. Note that the optical transceiver 220 can receive the Register Ack frame because the logic level of the Rx_SELECT signal is High.

The signal processing unit 230 performs PCS and PMA processing on the Register Ack frame. After completing the processing, IF function section 210 transmits a Register Ack frame to frame generation apparatus 100 .
IF function unit 110 receives the Register Ack frame at time RX1_SERVER. Note that the time RX1_SERVER can be expressed using Equation (6).

RX1_SERVER=GST1+RTT#1 (6)

The frame generator 120 processes the Register Ack frame.
Frame generator 120 generates a Normal Gate frame addressed to ONU 23 . LLID, GST2, and GL2 are registered in the Normal Gate frame. The LLID is 0x0002. GL2 is transmission band information. The IF function unit 110 transmits the Normal Gate frame to the transmission/reception control device 200 .

Here, it is assumed that the management table 271 registers that the RTT corresponding to 0x0002 is RTT#2. It is also assumed that the ONU type corresponding to 0x0002 is 0 registered in the management table 271 .

IF function unit 210 receives the Normal Gate frame. Information extractor 240 extracts LLID and GST2 from the Normal Gate frame. Information extractor 240 transmits LLID and GST2 to control signal generator 250 . The control signal generator 250 acquires the RTT and ONU type registered in the management table 271 using the LLID as a key. The acquired RTT and ONU type are RTT#2 and 0.
The control signal generator 250 calculates the reception time RX2_HW of the uplink signal transmitted by the ONU 21 using equation (7).

RX2_HW=GST2+RTT#2-(ΔT+ΔRTT) (7)

The control signal generation unit 250 compares the value of the time counter managed by the time management unit 260 with RX2_HW. The control signal generator 250 generates the Rx_SELECT signal and the Rx_RESET signal before RX2_HW by the guard time. Note that the logic level of the Rx_SELECT signal is Low. The control signal generator 250 transmits the Rx_SELECT signal and the Rx_RESET signal to the optical transceiver 220 .

The signal processing unit 230 performs PCS and PMA processing on the Normal Gate frame. After completing the processing, the optical transmitter/receiver 220 transmits a Normal Gate frame.
ONU 23 receives the Normal Gate frame. When the Local Time reaches GST2, the ONU 21 transmits data.

The optical transceiver 220 receives data at time RX2_HW. Note that the optical transmitter/receiver 220 can receive the upstream signal because the logic level of the Rx_SELECT signal is Low.
The signal processing unit 230 performs PCS and PMA processing on the data. After completing the processing, the IF function unit 210 transmits the data to the frame generation device 100 .
IF function unit 110 receives data at time RX2_SERVER. Note that the time RX2_SERVER can be expressed using Equation (8).

RX2_SERVER=GST2+RTT#2 (8)

Thus, the transmission/reception control device 200 can receive the upstream signal at the calculated reception time.
According to Embodiment 1, the OLT 10 does not need to have a high-speed IF in the frame generation device 100 and the transmission/reception control device 200 . Therefore, the OLT 10 can keep costs down.

Moreover, in Embodiment 1, the case where the RTT is included in the Register frame has been described. However, the RTT may be included in the Padding field (padding area) of the Normal Gate frame. Also, when the RTT is included in the Normal Gate frame, the Padding field varies from 15 bytes to 39 bytes. However, when the RTT is included in the Register frame, the data length of the Padding field is fixed, so the Padding field does not change from 32 bytes.

After calculating the RTT corresponding to each ONU, the OLT 10 may perform the following processing. The OLT 10 disables FEC for downstream signals to ONUs with small RTT values. The reason is that when the distance between the OLT 10 and the ONU is short, the deterioration of the optical signal is small.

Embodiment 2.
Next, Embodiment 2 will be described. Items different from the first embodiment will be mainly described, and descriptions of items common to the first embodiment will be omitted. Embodiment 2 refers to FIGS. 1-6 and 8-13.
Embodiment 1 has described the case where the RTT is registered in the Padding field. Embodiment 2 describes a case where RTT is registered in MAC (Media Access Control)-SA (Source Address).

The frame generation device 100 will be explained.
Frame generator 120 generates a Normal Gate frame. Here, a specific example of the format of the Normal Gate frame will be shown.

FIG. 14 is a diagram showing the format of a Normal Gate frame according to the second embodiment. The frame generator 120 registers the RTT and ONU type in the MAC-SA field. Thus, the RTT is registered in the MAC-SA field, which is an area in which the MAC address of the frame generation device 100 is scheduled to be registered, among the fields of the Normal Gate frame. The MAC-SA field is also called the first area.

Here, the RTT registered in the MAC-SA field is RTT#2. It is also assumed that GST2 is registered in the Normal Gate frame.
The IF function unit 110 transmits the Normal Gate frame to the transmission/reception control device 200 .

FIG. 15 is a functional block diagram showing the configuration of the transmission/reception control device according to the second embodiment. The transmission/reception control device 200 further has an overwriting section 280 . 15 that are the same as or correspond to those shown in FIG. 8 are labeled with the same reference numerals as those shown in FIG.
When the IF function unit 210 receives the Discovery Gate frame, the information extraction unit 240 extracts the MAC-SA field value of the Discovery Gate frame. The MAC-SA field value is the MAC address of the frame generator 100 . Note that the MAC address is also called a physical address. Information extractor 240 stores the MAC address of frame generator 100 in memory 270 .

When the IF function unit 210 receives the Normal Gate frame, the information extraction unit 240 extracts the RTT#2, GST2, and ONU type from the Normal Gate frame. Information extractor 240 transmits RTT#2, GST2, and ONU type to control signal generator 250 .
Thereby, the control signal generator 250 can calculate the reception time. For example, the control signal generator 250 calculates the reception time RX2_HW using Equation (7).

Information extractor 240 transmits the Normal Gate frame to overwrite section 280 . The overwriting section 280 acquires the MAC address of the frame generation device 100 from the storage section 270 . The overwriting unit 280 overwrites the MAC address of the frame generation device 100 with the RTT and ONU type registered in the MAC-SA field of the Normal Gate frame. Thus, when the Normal Gate frame is received, the overwriting unit 280 registers the MAC address of the frame generation device 100 in the MAC-SA field of the Normal Gate frame.

The overwriting section 280 transmits the Normal Gate frame to the signal processing section 230 . The signal processing unit 230 performs PCS and PMA processing on the Normal Gate frame. After completing the processing, the optical transmitter/receiver 220 transmits a Normal Gate frame.

The above shows the case where the RTT is registered in the MAC-SA field of the Normal Gate frame. However, the RTT may be registered in fields other than the MAC-SA field. For example, when a multicast address is registered in the MAC-DA field, RTT is registered in the MAC-DA field.

According to the second embodiment, the OLT 10 generates a Normal Gate frame that deviates from IEEE802.3 regulations. However, when the OLT 10 transmits the Normal Gate frame, it modifies the Normal Gate frame to comply with the IEEE802.3 standard. Therefore, the OLT 10 can realize operations that conform to the IEEE802.3 standard.

The features of the embodiments described above can be combined as appropriate. Moreover, in the first and second embodiments, the case where the OLT function can be realized by two devices has been shown. However, the functions of the OLT may be realized by three or more devices.
Embodiments 1 and 2 exemplified the 10G-EPON system. However, Embodiments 1 and 2 can also be applied to optical communication systems other than the 10G-EPON system.

10 OLT 21, 22, 23, 24 ONU 30 Optical coupler 100 Frame generation device 101 Processor 102 Volatile storage device 103 Non-volatile storage device 104 Frame 110 IF function unit 120 Frame generation unit 200 Transmission/reception control device 210 IF function unit 220 optical transmission/reception unit 230 signal processing unit 240 information extraction unit 250 control signal generation unit 260 time management unit 270 storage unit 271 management table 280 overwriting unit 300 dedicated device , 400 adapter.

Claims (6)

An optical communication device that is a master station device,
a transmission/reception control device that communicates with the slave station device;
generating a first frame that is information for assigning an identifier to the slave station device and a second frame that is information including a transmission start time that is the time at which the slave station device starts transmitting an optical signal; a frame generator;
has
the first frame includes a first round-trip time that is an information round-trip time in communication between the frame generation device and the slave station device via the transmission/reception control device;
the transmission/reception control device receives the first frame and the second frame, and converts the transmission start time, the first round-trip time, and an optical signal transmitted by the slave station device into an electrical signal; the slave station device based on a delay time, which is a processing time for executing processing on the electrical signal , and a second round-trip time, which is an information round-trip time in communication between the frame generation device and the transmission/reception control device; calculating the reception time, which is the time at which the transmission/reception control device receives the optical signal transmitted by
Optical communication device. An optical communication device that is a master station device,
a transmission/reception control device that communicates with the slave station device;
a frame generation device that generates a third frame that is information including a transmission start time that is a time at which the slave station device starts transmission of an optical signal;
has
the third frame includes a first round-trip time that is an information round-trip time in communication between the frame generation device and the slave station device via the transmission/reception control device;
The transmission/reception control device receives the third frame, and includes the transmission start time, the first round-trip time, processing for converting an optical signal transmitted by the slave station device into an electrical signal, and processing for the electrical signal. and a second round-trip time, which is an information round-trip time in communication between the frame generation device and the transmission/reception control device, based on the optical signal transmitted by the slave station device calculating a reception time, which is the time at which the transmission/reception control device receives;
Optical communication device. The first round trip time is registered in the padding area of the third frame.
3. The optical communication device according to claim 2. the first round-trip time is registered in a first area, which is an area in which the physical address of the frame generation device is to be registered, among the areas of the third frame;
The transmission/reception control device is
storing the physical address of the frame generation device;
when receiving the third frame, extracting the first round trip time from the third frame and registering the physical address of the frame generation device in the first area;
3. The optical communication device according to claim 2. A control method executed by a transmission/reception control device that communicates with a slave station device and a frame generation device possessed by an optical communication device that is a master station device,
The frame generation device
A first information for assigning an identifier to the child station device, including a first round trip time that is an information round trip time in communication between the frame generation device and the child station device via the transmission/reception control device and a second frame that is information including a transmission start time that is the time at which the slave station device starts transmission of the optical signal,
The transmission/reception control device
receiving the first frame and the second frame;
the transmission start time, the first round-trip time, the delay time that is the processing time for converting the optical signal transmitted by the slave station device into an electrical signal and the processing for the electrical signal , and the frame generation device and the transmission/reception control device, based on a second round-trip time that is an information round-trip time in communication between the transmission/reception control device and the transmission /reception control device . ,
control method. A control method executed by a transmission/reception control device that communicates with a slave station device and a frame generation device possessed by an optical communication device that is a master station device,
The frame generation device
A first round-trip time, which is an information round-trip time in communication between the frame generation device and the slave station device via the transmission/reception control device, and transmission, which is a time at which the slave station device starts transmitting an optical signal. generating a third frame of information including the start time and
The transmission/reception control device
receiving the third frame;
the transmission start time, the first round-trip time, the delay time that is the processing time for converting the optical signal transmitted by the slave station device into an electrical signal and the processing for the electrical signal , and the frame generation device and the transmission/reception control device, based on a second round-trip time that is an information round-trip time in communication between the transmission/reception control device and the transmission /reception control device . ,
control method.

Images