JP6262452B2 - ELECTRIC-OPTICAL CONVERTER AND ELECTRO-OPTICAL CONVERSION METHOD - Google Patents

Description

  The present invention relates to an electro-optical conversion apparatus and an electro-optical conversion method for converting an electric packet signal into an optical packet signal.

  A typical communication system using optical packet switching technology is shown in FIG. 3A.

  Referring to FIG. 3A, this communication system is an external device 1 to n such as an information processing device (for example, a personal computer), and an ONU (abbreviation of “Optical_Network_Unit”) connected to the external devices 1 to n in a one-to-one correspondence. Generally translated as “optical subscriber unit”) 1 to n, OLT (abbreviation of “Optical_Line_Terminal”, generally translated as “optical termination unit”), and other information processing devices (for example, Server) and the like, and the Internet connecting the OLT and the opposite device. The ONUs 1 to n are a type of electro-optical conversion device.

  FIG. 3B is a diagram for explaining a configuration of an optical packet signal (upstream) from each ONU to the OLT in the communication system shown in FIG. 3A. Referring to FIG. 3B, the optical packet signal consists of a set of synchronization codes and corresponding packets from each ONU, respectively. In addition, there is no signal between the optical packet signals.

Next, the configuration and operation of each ONU will be described with reference to FIG. 4A. FIG. 4A is a block diagram for explaining a configuration of a general ONU.
Referring to FIG. 4A, each ONU 54 includes a data shaping unit 51 and an electro-optical conversion unit 53.

  The data shaping unit 51 in each ONU 54 transmits each packet 6 (a transmission unit in which a preamble, a transmission destination address, transmission data, and the like are collected into one according to a predetermined format) transmitted from the corresponding external device in the form of an electric signal. (Also referred to as “electric packet signal”), a synchronization code having a predetermined time length is added before the packet 6, a light source ON code is added before the synchronization code, and a light source OFF code is added after the packet 6. The packets added with the synchronization code, the light source ON code, and the light source OFF code are passed to the electro-optical conversion unit 53 as packets with synchronization codes.

  The electro-optical conversion unit 53 performs predetermined optical modulation on the synchronization-signed packet, and thus performs the predetermined optical modulation on the synchronization-signed packet as an optical packet signal 13 to be described later as an optical fiber. 32 to the OLT 14. Here, as in the signal example illustrated in FIG. 4B, the optical packet signal 13 includes the light emission stable state transition unit 20, the optical synchronization code 11 in which the synchronization code is optically modulated, and the optical packet 12 in which the packet 6 is optically modulated. And a light emission stop state transition unit 21. FIG. 4B is a diagram for explaining an optical packet signal in a general ONU.

  The length (time length) of the light emission stable state transition unit 20 described above is such that light is emitted from a light source (for example, a laser diode) provided in the electro-optical conversion unit 53 after power is supplied. The predetermined time length is set in consideration of the time until stabilization.

  Further, the length (time length) of the light emission stop state transition unit 21 described above is also a predetermined time length in consideration of the time from when the supply of power to the light source is stopped until the light emission of the light source is completely stopped. It is stipulated in.

  The optical synchronization code 11 is used by the OLT 14 that receives the optical packet signal 13 to establish synchronization.

  The length (time length) of the light emission stable state transition unit 20 and the light emission stop state transition unit 21 is, for example, a standard defined by the Institute of Electrical and Electronic Engineers (“Institut_Of_Electrical_and_Electronic_Engineers”, also abbreviated as “IEEE”). Standard 802.3 (see Non-Patent Document 1) defines 512 nanoseconds (ns), and the length (time length) of the optical synchronization code 11 is defined as 400 ns in the standard. It has been.

  In Patent Document 1, the monitoring information for monitoring the state of the optical repeater is used to fill a non-signal period between adjacent optical packet signals and convert it into an optical continuous signal. A technique for stabilizing the above is described.

JP 2009-021874 A

IEEE_Std. _802.3, "IEEE_Standard_for_Information_technology-Telecommunications_and_information_exchange_between_systems-Local_and_metropolitan_area_networks-Specific_requirements, Part_3: Carrier_Sense_Multiple_Access_with_Collision_Detection_ (CSMA_CD) _Access_Method_and_Physical_Layer_Specifications, Amendment: Media_Access_Control_Parameters, Phy ical_Layers, and_Management_Parameters_for_Subscriber_Access_Networks, page314-315,60.7.13.1_Laser_On_Off_timing_measurement, ", 24th_June, _2004

  However, as in the signal example shown in FIG. 4B, due to the improvement in the performance of the light source, the time from when power is supplied to the light source until the light emission of the light source is stabilized, and after the supply of power to the light source is stopped, In some cases, the time until the light emission completely stops is shorter than a predetermined time defined in the standard 802.3 or the like.

  For example, in the signal example shown in FIG. 4B, although the light emission of the light source is stabilized in a short time of 200 ns, only 312 ns (waiting time A) until 512 ns defined in the standard 802.3 has elapsed. The communication system shown in FIG. 4A has a problem that the transmission efficiency of the optical packet signal 13 is lowered due to wasteful waiting.

  Further, since the extra power is supplied to the light source for the period of the waiting time A, the communication system shown in FIG. 4A also has a problem that the power consumption increases accordingly.

  Further, as shown in FIGS. 5A and 5B, when the performance of the synchronization circuit 16 provided in the OLT 14 is high, the time until the synchronization is established is shorter than 400 ns defined in the standard 802.3. Become. FIG. 5A is a block diagram for explaining a configuration of a general OLT. FIG. 5B is a diagram for explaining an optical packet signal in a general OLT.

  For example, as in the signal example shown in FIG. 5B, the synchronization circuit 16 can establish synchronization in a short time of 100 ns, but the time until 400 ns defined in the standard 802.3 elapses. The communication system shown in FIG. 5A has a problem that reception efficiency is poor because reception of the optical packet 12 is waited wastefully for the remaining 300 ns (waiting time B).

  Further, since the power is supplied to the light source during the waiting time B, the communication system shown in FIG. 5A also has a problem that the power consumption of the ONU 54 increases accordingly.

  Note that Patent Document 1 uses a continuous light signal and does not disclose any use of a light source ON code or a light source OFF code.

  An object of the present invention is to provide an electro-optical conversion device and an electro-optical conversion method that solve the above-described problems.

The electro-optical conversion device of the present invention comprises:
A storage unit for storing a light source emission stabilization time length value indicating a time length of the light source ON code;
The light source ON code having a time length indicated by the light source light emission stabilization time length value or a synchronization code following the light source ON code is added before a packet received in the form of an electric signal from an external device. An additional process, an encoding process for encoding the packet by a predetermined encoding method and converting the packet into an encoded packet, and an optical conversion target packet including the light source ON code and the encoded packet in the form of an electrical signal A data shaping unit that performs output processing to output to,
An electric-light including a light source that receives the optical conversion target packet output in the form of an electric signal from the data shaping unit, converts the received optical conversion target packet into an optical signal, and outputs the optical packet signal to the outside as an optical packet signal A conversion unit;
With
The light source starts to emit light when it receives the leading end of the light source ON code of the light conversion target packet.

Another electro-optical conversion device of the present invention is
A storage unit for storing a synchronization time length value indicating a time length of the synchronization code;
A synchronization code addition process for adding the synchronization code having the time length value indicated by the synchronization time length value before a packet received in the form of an electrical signal from an external device, and a predetermined encoding method for the packet A data shaping unit that performs an encoding process for encoding and converting into an encoded packet, and an output process for outputting an optical conversion target packet including the synchronization code and the encoded packet to the outside in the form of an electrical signal;
An electrical-optical converter that receives the optical conversion target packet output in the form of an electrical signal from the data shaping unit, converts the received optical conversion target packet into an optical signal, and outputs the optical packet signal to the outside; Is provided.

Another electro-optical conversion device of the present invention is
A storage unit for storing a light source emission stabilization time length value indicating a time length of the light source ON code;
The light source ON code having a time length indicated by the light source light emission stabilization time length value or a synchronization code following the light source ON code is added before a packet received in the form of an electric signal from an external device. A data shaping unit that performs an additional process and an output process for outputting the light conversion target packet including the light source ON code and the packet in the form of an electrical signal;
An electric-light including a light source that receives the optical conversion target packet output in the form of an electric signal from the data shaping unit, converts the received optical conversion target packet into an optical signal, and outputs the optical packet signal to the outside as an optical packet signal A conversion unit and
The light source starts to emit light when it receives the leading end of the light source ON code of the light conversion target packet.

Another electro-optical conversion device of the present invention is
A storage unit for storing a synchronization time length value indicating a time length of the synchronization code;
A synchronization code adding process for adding the synchronization code having the time length value indicated by the synchronization time length value before a packet received in the form of an electrical signal from an external device, and optical conversion including the synchronization code and the packet A data shaping unit that performs output processing for outputting the target packet to the outside in the form of an electrical signal;
An electrical-optical converter that receives the optical conversion target packet output in the form of an electrical signal from the data shaping unit, converts the received optical conversion target packet into an optical signal, and outputs the optical packet signal to the outside; Is provided.

Another electro-optical conversion device of the present invention is
A light source information storage unit for storing a light source emission stabilization time length value;
An encoding process for converting a packet received in the form of an electric signal from an external device into an encoded packet by a predetermined encoding method, and an optical conversion target packet including the encoded packet in the form of an electric signal A data shaping unit that performs output processing to output to,
An electric-light including a light source that receives the optical conversion target packet output in the form of an electric signal from the data shaping unit, converts the received optical conversion target packet into an optical signal, and outputs the optical packet signal to the outside as an optical packet signal A conversion unit;
With
The light source starts light emission from a time point before the light source light emission stabilization time length value before the start time of conversion of the optical conversion target packet into the optical packet signal.

Another electro-optical conversion device of the present invention is
A light source information storage unit for storing a light source emission stabilization time length value;
A data shaping unit that performs output processing for outputting an optical conversion target packet including a packet received in the form of an electrical signal from an external device to the outside in the form of an electrical signal;
An electric-light including a light source that receives the optical conversion target packet output in the form of an electric signal from the data shaping unit, converts the received optical conversion target packet into an optical signal, and outputs the optical packet signal to the outside as an optical packet signal A conversion unit;
With
The light source starts light emission from a time point before the light source light emission stabilization time length value before the start time of conversion of the optical conversion target packet into the optical packet signal.

Moreover, the electro-optical conversion method of the present invention includes:
A time length value reading step of reading a light source emission stabilization time length value indicating a time length of the light source ON code from the storage unit;
Before a packet received in the form of an electrical signal from an external device, a light source ON code having a time length indicated by the light source light emission stabilization time length value read in the reading step, or following the light source ON code And an additional step of adding a synchronization code,
An encoding step of encoding the packet by a predetermined encoding method and converting the packet into an encoded packet;
An optical conversion step of converting an optical conversion target packet including the light source ON code and the encoded packet into an optical signal by an electro-optical conversion unit including a light source, and sending the optical packet signal to a transmission destination;
In the light conversion step, the light source starts to emit light when receiving the leading end of the light source ON code of the light conversion target packet.
Further, another electro-optical conversion method of the present invention is as follows.
A time length value reading step of reading a light source emission stabilization time length value indicating a time length of the light source ON code from the storage unit;
Before the packet received in the form of an electrical signal from an external device, the light source ON code having the time length indicated by the light source light emission stabilization time length value read in the reading step, or the light source ON code And an additional step of adding a synchronization code,
An optical conversion step of converting the light source ON code and an optical conversion target packet including the packet into an optical signal by an electro-optical conversion unit including a light source, and transmitting the optical signal to a transmission destination as an optical packet signal;
In the light conversion step, the light source starts to emit light when receiving the leading end of the light source ON code of the light conversion target packet.

  The present invention has an effect of improving the transmission efficiency of an optical packet signal and reducing the power consumption of a light source or the like.

It is a block diagram which shows the 1st Embodiment of this invention. It is a figure for demonstrating the optical packet signal which goes to OLT via the optical fiber from ONU in the 1st Embodiment of this invention. It is a block diagram which shows the 2nd Embodiment of this invention. It is a figure for demonstrating the optical packet signal which goes to OLT via an optical fiber from ONU in the 2nd Embodiment of this invention. It is a figure which shows the general communication system which uses an optical packet switching technique. It is a figure for demonstrating the structure of the optical packet signal which goes from each ONU to OLT in the general communication system using an optical packet switching technique. It is a block diagram for demonstrating the structure of a general ONU. It is a figure for demonstrating the optical packet signal in a general ONU. It is a block diagram for demonstrating the structure of a general OLT. It is a figure for demonstrating the optical packet signal in a general OLT.

  Next, embodiments of the present invention will be described in detail with reference to the drawings.

<First Embodiment>
FIG. 1A is a block diagram showing a first embodiment of the present invention.

  Referring to FIG. 1A, the communication system according to the present embodiment includes an ONU 4, an OLT 14, and a counter device 15.

  The ONU 4 includes a data shaping unit 1, an electro-optical conversion unit 3, and a storage unit 30. Further, the electro-optical conversion unit 3 includes a light source 35. The storage unit 30 stores in advance a synchronization time length value, a light source light emission stabilization time length value, and a light source light emission stop time length value, which will be described later.

  The OLT 14 includes a synchronization circuit 16.

  The opposing device 15 is an information processing device such as a server device, for example.

  FIG. 1B shows the configuration of the optical packet signal 13 from the ONU 4 to the OLT 14 via the optical fiber 32.

  The optical packet signal 13 includes a light emission stable state transition unit 20, an optical synchronization code 11, an optical packet 12, and a light emission stop state transition unit 21.

  As described above with reference to FIG. 4A, FIG. 4B, FIG. 5A, and FIG. 5B, for example, When receiving a packet 6 (also referred to as an “electric packet signal”) 6 transmitted in the form of an electric signal via a telecommunication line such as a synchronous code 9 having a predetermined time length before the received packet 6. , And the packet 6 is encoded by a predetermined encoding method to be converted into an encoded packet 10. Although the packet 6 is encoded in the present embodiment, it goes without saying that such encoding may not be performed depending on the communication standard. Further, although the synchronization code 9 is added in this embodiment, it goes without saying that such addition may not be performed depending on the communication standard.

  The synchronization code 9 and the packet 10 include a plurality of logic “1” (for example, a predetermined level with a voltage (or current) level of 0 or more) and a plurality of logic “0” (for example, voltage (or current) levels. Is a digital signal consisting of 0) signal.

  Further, the data shaping unit 1 generates the light conversion target packet 7 in which the light source ON code 18 is added before the synchronization code 9 and the light source OFF code 19 is added after the encoded packet 10, respectively. The data is sent to the conversion unit 3. Note that there are no significant signals 8 before and after the optical conversion target packet 7.

  The light source ON code 18 is a digital signal consisting of only one logic “1” signal, and the light source OFF code 19 is a digital signal consisting of only one logic “0” signal.

  Here, the time lengths of the synchronization code 9, the light source ON code 18, and the light source OFF code 19 in the light conversion target packet 7 are the synchronization time length value, the light source emission stabilization time length value, and the light source that are stored in advance in the storage unit 30. It is set to the same value as the light emission stop time length value. These values are the actual time required for synchronization in the synchronization circuit 16 in the OLT 14, the actual time from when the light source 35 in the electro-optical converter 3 starts to emit light until the light emission is stabilized, and the light source 35. This value is equal to the actual time from when the light emission starts to completely stop until the light emission stops.

  That is, the optimum synchronization time length value, light source light emission stabilization time length value, and light source light emission stop time length value are stored in the storage unit 30 according to the performance of the synchronization circuit 16 and the light source 35 to be used.

  The electro-optical conversion unit 3 has a function of converting the received electric signal directly into an optical signal by modulating it with a predetermined optical modulation method as necessary.

  That is, the electro-optical conversion unit 3 converts the light conversion target packet 7 received from the data shaping unit 1 in the form of an electric signal into the light emission stable state transition unit 20, the optical synchronization code 11, the optical packet 12, and the light emission stop state transition unit. 21 is converted into an optical packet signal 13 (see the signal example shown in FIG. 1B), and the optical packet signal 13 is transmitted to the OLT 14 via the optical fiber 32.

  Specifically, the light source 35 in the electro-optical conversion unit 3 receives the leading end of the light source ON code 18 at the head of the optical conversion target packet 7 sent from the data shaping unit 1 in the form of an electric signal. The light emission starts from the time point, and when the time length of the light source ON code 18 has elapsed from the light emission start time point, the light emission of the light source 35 reaches a stable state (the light emission stable state transition unit 20 of the signal example shown in FIG. reference.). Thereafter, the light source 35 receives the synchronization code 9 and the encoded packet 10 and optically converts them into the optical synchronization code 11 and the optical packet 12. Thereafter, the light emission of the light source 35 starts to stop when the front end of the light source OFF code 19 is received, and the light emission of the light source 35 stops at the moment when the time length of the light source OFF code 19 has elapsed from the light emission stop start time (FIG. (See the light emission stop state transition unit 21 in the signal example shown in 1B.)

  The level (voltage (or current) level) of the logic “1” signal and the logic “0” signal constituting the optical conversion target packet 7 sent in the form of an electrical signal from the data shaping unit 1 is supplied to the light source 35. Before being sent, it is converted to a level suitable for driving the light source 35 as necessary. Further, the light conversion target packet 7 sent from the data shaping unit 1 in the form of an electric signal is modulated by a predetermined light modulation method as needed before being sent to the light source 35.

  As described above, in the present embodiment, the optimum synchronization time length value, light source light emission stabilization time length value, and light source light emission stop, which are stored in advance in the storage unit 30 according to the performance of the synchronization circuit 16 and the light source 35 to be used. Since the time lengths of the synchronization code 9, the light source ON code 18, and the light source OFF code 19 are determined according to the time length value, the “waiting time A” described with reference to FIG. 4B and the “waiting time A” described with reference to FIG. The “waiting time B” disappears (see the signal example shown in FIG. 1B).

  When the synchronization circuit 16 or the light source 35 to be used is replaced, the synchronization time length value and the light source emission stabilization time length value stored in the storage unit 30 according to the performance of the replaced synchronization circuit 16 or light source 35. It goes without saying that the light source emission stop time length value may be changed to an optimum value.

  As described above, this embodiment has an effect that it is possible to improve the transmission efficiency of the optical packet signal and reduce the power consumption of the light source or the like.

  The reason is that it is possible to generate an optical packet signal using a synchronization code, a light source ON code, and a light source OFF code having a time length shorter than a time defined by a standard such as the IEEE 802.3 standard.

<Second Embodiment>
FIG. 2A is a block diagram showing a second embodiment of the present invention.

  Referring to FIG. 2A, the configuration of the present embodiment is almost the same as that of the first embodiment. In the first embodiment, the storage unit 30 in the data shaping unit 1 has a synchronization time value and light source emission stability. In the present embodiment, the synchronization time value is stored in the synchronization information storage unit 33 in the data forming unit 100, and the light source light source emission stop time length value is stored. The light emission stabilization time length value is stored in the light source information storage unit 34 in the electro-optical conversion unit 300.

  In the following, the characteristic part of the present embodiment will be mainly described, and the same reference numerals are given to the same components as those of the first embodiment described above, and the configurations thereof are described. A duplicate description of the elements is omitted. Further, the operation of each component of the present embodiment will be described with a focus on differences from the first embodiment.

  When the data shaping unit 100 receives the packet 6 transmitted from the external device in the form of an electric signal, the data shaping unit 100 adds a synchronization code 9 having a predetermined time length to the received packet 6 and also transmits the packet 6 to the predetermined value. Is encoded by the encoding method and converted into the encoded packet 10 to generate an optical conversion target packet 17 composed of the synchronous code 9 and the encoded packet 10, and sends it to the electro-optical conversion unit 3. Although the packet 6 is encoded in the present embodiment, it goes without saying that such encoding may not be performed depending on the communication standard. Further, although the synchronization code 9 is added in this embodiment, it goes without saying that such addition may not be performed depending on the communication standard.

  At this time, the time length of the synchronization code 9 in the optical conversion target packet 17 is set to the same value as the synchronization time length value stored in advance in the synchronization information storage unit 33. That is, an optimal synchronization time length value is stored in the synchronization information storage unit 33 according to the performance of the synchronization circuit 16 to be used.

  Upon receiving the light conversion target packet 17 received in the form of an electric signal from the data shaping unit 1, the electro-optical conversion unit 3 reads the light source emission stabilization time length value stored in advance in the light source information storage unit 34, A predetermined signal (for example, a signal of logic “1”) is supplied to 35 to start light emission.

  When the time corresponding to the light source light emission stabilization time length value has elapsed since the light emission of the light source 35 has started (that is, when the light emission of the light source 35 has stabilized), the electro-optical conversion unit 3 performs the light conversion target. The packet 17 is supplied to the light source 35 and optically converted.

  As a result, the optical packet signal 13 including the light emission stable state transition unit 20, the optical synchronization code 11, the optical packet 12, and the light emission stop state transition unit 21 is output from the light source 35 to the optical fiber 32. (See example signal shown in FIG. 2B). FIG. 2B is a diagram for explaining the optical packet signal 13 from the ONU 4 to the OLT 14 via the optical fiber 32 in the second embodiment.

  Here, in the signal example shown in FIG. 2B, the light emission stable state transition unit 20 shows a state from when the light source 35 emits light until the light emission is stabilized, and the time length is equal to the light source light emission stabilization time length value. Correspond. In addition, the light emission stop state transition unit 21 shows a state from when the output of the optical packet 12 is finished and when the light emission of the light source 35 is stopped until the light emission is completely stopped.

  As described above, the present embodiment has the effect of improving the transmission efficiency of the optical packet signal and reducing the power consumption of the light source and the like, similar to the effect of the first embodiment.

  The reason is that an optical packet signal can be generated using a synchronization code having a time length shorter than a time defined by a standard such as the IEEE 802.3 standard and a light source emission stabilization time.

Note that some or all of the above-described embodiments and modifications thereof may be described as in the following supplementary notes. However, the present invention described by way of example using the above-described embodiment and its examples is not limited to the following. That is,
(Appendix 1)
A storage unit for storing a light source emission stabilization time length value indicating a time length of the light source ON code;
The light source ON code having a time length indicated by the light source light emission stabilization time length value or a synchronization code following the light source ON code is added before a packet received in the form of an electric signal from an external device. An additional process, an encoding process for encoding the packet by a predetermined encoding method and converting the packet into an encoded packet, and an optical conversion target packet including the light source ON code and the encoded packet in the form of an electrical signal A data shaping unit that performs output processing to output to,
An electric-light including a light source that receives the optical conversion target packet output in the form of an electric signal from the data shaping unit, converts the received optical conversion target packet into an optical signal, and outputs the optical packet signal to the outside as an optical packet signal A conversion unit;
With
The light source starts light emission at the time when the leading end of the light source ON code of the light conversion target packet is received.
(Appendix 2)
A storage unit for storing a light source emission stabilization time length value indicating a time length of the light source ON code;
The light source ON code having a time length indicated by the light source light emission stabilization time length value or a synchronization code following the light source ON code is added before a packet received in the form of an electric signal from an external device. A data shaping unit that performs an additional process and an output process for outputting the light conversion target packet including the light source ON code and the packet in the form of an electrical signal;
An electric-light including a light source that receives the optical conversion target packet output in the form of an electric signal from the data shaping unit, converts the received optical conversion target packet into an optical signal, and outputs the optical packet signal to the outside as an optical packet signal A conversion unit and
The light source starts light emission at the time when the leading end of the light source ON code of the light conversion target packet is received.
(Appendix 3)
A light source information storage unit for storing a light source emission stabilization time length value;
An encoding process for converting a packet received in the form of an electric signal from an external device into an encoded packet by a predetermined encoding method, and an optical conversion target packet including the encoded packet in the form of an electric signal A data shaping unit that performs output processing to output to,
An electric-light including a light source that receives the optical conversion target packet output in the form of an electric signal from the data shaping unit, converts the received optical conversion target packet into an optical signal, and outputs the optical packet signal to the outside as an optical packet signal A conversion unit;
With
The light source starts light emission from a time point before the light source light emission stabilization time length value from a time point when the light conversion target packet is converted into the optical packet signal. .
(Appendix 4)
A light source information storage unit for storing a light source emission stabilization time length value;
A data shaping unit that performs output processing for outputting an optical conversion target packet including a packet received in the form of an electrical signal from an external device to the outside in the form of an electrical signal;
An electric-light including a light source that receives the optical conversion target packet output in the form of an electric signal from the data shaping unit, converts the received optical conversion target packet into an optical signal, and outputs the optical packet signal to the outside as an optical packet signal A conversion unit;
With
The light source starts light emission from a time point before the light source light emission stabilization time length value from a time point when the light conversion target packet is converted into the optical packet signal. .
(Appendix 5)
The light source emission stabilization time length value is a value equal to a time from when the actually used light source starts to emit light until the light emission is stabilized. Electro-optical conversion device.
(Appendix 6)
The storage unit stores a light source emission stop time length value indicating a time length of the light source OFF code,
The electro-optical converter performs a light source OFF code addition process for adding the light source OFF code having a time length indicated by the light source emission stop time length value after a packet received in the form of an electric signal from the external device. In the output process, the optical conversion target packet including the encoded packet and the light source OFF code is output to the outside in the form of an electrical signal,
The electro-optical conversion device according to appendix 1 or 2, wherein the light source starts to stop light emission from the time when the leading end of the light source OFF code of the light conversion target packet is received.
(Appendix 7)
The electro-optical conversion according to appendix 6, wherein the light source light emission stop time length value is equal to a time from when light emission of the light source actually used starts to stop until light emission stops completely. apparatus.
(Appendix 8)
A storage unit for storing a synchronization time length value indicating a time length of the synchronization code;
A synchronization code addition process for adding the synchronization code having the time length value indicated by the synchronization time length value before a packet received in the form of an electrical signal from an external device, and a predetermined encoding method for the packet A data shaping unit that performs an encoding process for encoding and converting into an encoded packet, and an output process for outputting an optical conversion target packet including the synchronization code and the encoded packet to the outside in the form of an electrical signal;
An electrical-optical converter that receives the optical conversion target packet output in the form of an electrical signal from the data shaping unit, converts the received optical conversion target packet into an optical signal, and outputs the optical packet signal to the outside; An electro-optical conversion device comprising:
(Appendix 9)
A storage unit for storing a synchronization time length value indicating a time length of the synchronization code;
A synchronization code adding process for adding the synchronization code having the time length value indicated by the synchronization time length value before a packet received in the form of an electrical signal from an external device, and optical conversion including the synchronization code and the packet A data shaping unit that performs output processing for outputting the target packet to the outside in the form of an electrical signal;
An electrical-optical converter that receives the optical conversion target packet output in the form of an electrical signal from the data shaping unit, converts the received optical conversion target packet into an optical signal, and outputs the optical packet signal to the outside; An electro-optical conversion device comprising:
(Appendix 10)
The electrical time according to appendix 8 or 9, wherein the synchronization time length value is equal to an actual time required to establish synchronization in a synchronization circuit that is actually used in a device that receives the optical packet. A light conversion device;
(Appendix 11)
A time length value reading step of reading a light source emission stabilization time length value indicating a time length of the light source ON code from the storage unit;
Before a packet received in the form of an electrical signal from an external device, a light source ON code having a time length indicated by the light source light emission stabilization time length value read in the reading step, or following the light source ON code And an additional step of adding a synchronization code,
An encoding step of encoding the packet by a predetermined encoding method and converting the packet into an encoded packet;
An optical conversion step of converting an optical conversion target packet including the light source ON code and the encoded packet into an optical signal by an electro-optical conversion unit including a light source, and sending the optical packet signal to a transmission destination;
In the light conversion step, the light source starts light emission from the time when the leading end of the light source ON code of the light conversion target packet is received.
(Appendix 12)
A time length value reading step of reading a light source emission stabilization time length value indicating a time length of the light source ON code from the storage unit;
Before the packet received in the form of an electrical signal from an external device, the light source ON code having the time length indicated by the light source light emission stabilization time length value read in the reading step, or the light source ON code And an additional step of adding a synchronization code,
An optical conversion step of converting the light source ON code and an optical conversion target packet including the packet into an optical signal by an electro-optical conversion unit including a light source, and transmitting the optical signal to a transmission destination as an optical packet signal;
In the light conversion step, the light source starts light emission from the time when the leading end of the light source ON code of the light conversion target packet is received.
(Appendix 13)
An encoding step of encoding a packet received in the form of an electric signal from an external device by a predetermined encoding method and converting the packet into an encoded packet;
An optical conversion step of converting an optical conversion target packet including the encoded packet into an optical signal by an electro-optical conversion unit including a light source, and transmitting the optical packet as an optical packet signal to a transmission destination;
In the light conversion step, a light source light emission stabilization time length value is read from a light source information storage unit, and the light source stabilizes the light source light emission from the start time of conversion of the light conversion target packet into the optical packet signal. An electro-optical conversion method characterized in that light emission is started from a time point before the time length value.
(Appendix 14)
An optical conversion step of converting an optical conversion target packet including a packet received in the form of an electric signal from an external device into an optical signal, and sending the optical packet signal to a transmission destination;
In the light conversion step, a light source light emission stabilization time length value is read from a light source information storage unit, and the light source stabilizes the light source light emission from the start time of conversion of the light conversion target packet into the optical packet signal. An electro-optical conversion method characterized in that light emission is started from a time point before the time length value.
(Appendix 15)
The light source light emission stabilization time length value is a value equal to a time from when the light source that is actually used starts to emit light until the light emission is stabilized. Electrical-optical conversion method.
(Appendix 16)
The storage unit stores a light source emission stop time length value indicating a time length of the light source OFF code,
A light source OFF code adding step of adding the light source OFF code having a time length indicated by the light source emission stop time length value after a packet received in the form of an electric signal from the external device;
In the light conversion step, the light conversion target packet including the light source ON code, the synchronization code, the encoded packet, and the light source OFF code is converted into an optical signal,
13. The electro-optical conversion method according to appendix 11 or 12, wherein the light source starts to stop light emission when the leading end of the light source OFF code of the light conversion target packet is received.
(Appendix 17)
The electro-optical conversion according to claim 16, wherein the light source light emission stop time length value is equal to a time from when light emission of the light source actually used starts to stop until light emission stops completely. Method.
(Appendix 18)
A time length value reading step of reading out a synchronization time length value indicating the time length of the synchronization code from the storage unit;
A synchronization code addition step of adding the synchronization code having a time length value indicated by the synchronization time length value before a packet received in the form of an electrical signal from an external device;
An encoding step of encoding the packet by a predetermined encoding method and converting the packet into an encoded packet;
An optical-optical conversion method comprising: an optical conversion step of converting an optical conversion target packet including the synchronization code and the encoded packet into an optical signal and transmitting the optical signal as an optical packet signal to a transmission destination.
(Appendix 19)
A time length value reading step for pre-reading the synchronization time length value indicating the time length of the synchronization code from the storage unit;
A synchronization code addition step of adding the synchronization code having a time length value indicated by the synchronization time length value before a packet received in the form of an electrical signal from an external device;
An optical-optical conversion method comprising: an optical conversion step of converting an optical conversion target packet including the synchronization code and the packet into an optical signal, and transmitting the optical packet to the transmission destination as an optical packet signal including the optical packet.
(Appendix 20)
The electrical time according to appendix 18 or 19, wherein the synchronization time length value is a value equal to an actual time required to establish synchronization in a synchronization circuit that is actually used in a device that receives the optical packet. -Light conversion method.

1 Data shaping part 3 Electric-light conversion part 4 ONU
6 packet 7 optical conversion target packet 8 no signal state 9 synchronization code 10 encoded packet 11 optical synchronization code 12 optical packet 13 optical packet signal 14 OLT
DESCRIPTION OF SYMBOLS 15 Opposite apparatus 16 Synchronization circuit 17 Light conversion object packet 18 Light source ON code 19 Light source OFF code 20 Light emission stable state transition part 21 Light emission stop state transition part 30 Storage part 32 Optical fiber 33 Synchronization information storage part 34 Light source information storage part 35 Light source information 51 Data shaping part 53 Electric-light conversion part 54 ONU
100 Data shaping part 300 Electric-light conversion part

Claims (2)

A storage unit for storing a light source light emission stabilization time length value indicating a time length from when the light source actually used by the light source ON code starts to emit light until the light emission is stabilized;
Before the packet received in the form of an electrical signal from an external device , the light source ON code having a time length indicated by the light source light emission stabilization time length value, and a synchronization code following the light source ON code are added. An additional process, an encoding process for encoding the packet by a predetermined encoding method and converting the packet into an encoded packet, and an optical conversion target packet including the light source ON code and the encoded packet in the form of an electrical signal A data shaping unit that performs output processing to output to,
Electrical comprising the light source, wherein the receiving the light converted packets output in the form of an electrical signal from the data forming unit converts the light converted packet received into an optical signal, and output as an optical packet signal - A light conversion unit;
With
The light source starts light emission at the time when the leading end of the light source ON code of the light conversion target packet is received. The actual time length value reading step of the light source is read out light emission stabilization time length value that indicates the length of time until the light-emitting is stabilized after the start of starting the light emission from the storage unit to be used for the light source ON code,
Before the packet received in the form of an electric signal from the external device , the light source ON code having the time length indicated by the light source emission stabilization time length value read in the reading step, and the light source ON code And an additional step of adding a synchronization code,
An encoding step of encoding the packet by a predetermined encoding method and converting the packet into an encoded packet;
Wherein the light source ON code and light converted packet including the encoded packet, electrical including the light source - is converted into an optical signal by the optical conversion unit, and a light conversion step of transmitting the optical packet signal to a destination,
In the light conversion step, the light source starts light emission from the time when the leading end of the light source ON code of the light conversion target packet is received.

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