KR101555976B1 - Method for comprising physical frame for giga bit passive optical network - Google Patents

Abstract

The method includes arranging a bit string of an even-numbered superframe after a first physical synchronization sequence bit string, arranging a bit string of an even-numbered hybrid error correction after a bit string of the even-numbered superframe, Arranging a bit string of an even-numbered superframe after a bit string, arranging a bit string of an identifier of a first passive optical network after a bit string of the even-numbered super frame, Arranging a bit stream of a second physical synchronization sequence after a bit stream of the physical frame payload, placing a bit stream of a second physical synchronization sequence after the bit stream of the second physical synchronization sequence, Arranging a bit stream of a superframe, arranging a bit stream of the odd superframe, The method comprising the steps of: arranging a bit string of a first passive optical network, placing a bit string of an identifier of a second passive optical network after a bit string of the odd hybrid error correction, And arranging parity bits after the bit string of the redundancy. The present invention also provides a method of constructing a physical frame for a gigabit passive optical network.

Description

[0001] METHOD FOR COMPRISING PHYSICAL FRAME FOR GIGABIT PASSIVE OPTICAL NETWORK [0002]

The present invention relates to a method of constructing a physical frame for a gigabit passive optical network, and more particularly, to a method of constructing a physical frame for a gigabit passive optical network by providing scrambled data (e.g., The present invention relates to a physical frame configuration method for a gigabit passive optical network capable of effectively improving the error correction probability of a super frame counter value used as a seed value.

In recent years, downlink data is broadcasted at a transmission rate of 10 Gbps using a single subscriber network optical cable, and upward data is transmitted at a transmission rate of 2.5 Gbps to a plurality of optical network terminals (ONTs) Gigabit passive optical networks are gaining popularity.

In the gigabit passive optical network described above, a super frame counter value is used as a seed value to decode scrambled data, and a BCH (63, 51, 2) code is used to correct an error of a super frame counter value. That is, the 51 bits among the 64 bits of the super frame counter block allocate the super frame counter value, place the redundancy value of 12 bits after the super frame counter value, and finally arrange the even parity value of 1 bit. In this way, only two bits of error correction can be performed.

On the other hand, in the patent document 10-2012-0089361, a visual field in the unit of seconds and a visual field in the unit of nanoseconds are disclosed in order to improve the reliability of the data frame. However, such a patent discloses a standard method of the gigabit passive optical network For example, ITU-T G.987).

SUMMARY OF THE INVENTION Accordingly, it is an object of the present invention to provide a method and apparatus for decoding a scrambled data while maintaining compatibility with a standard scheme of a gigabit passive optical network (for example, ITU-T G.987) The present invention provides a method for constructing a physical frame for a gigabit passive optical network capable of effectively improving the error correction probability of a physical layer.

It is to be understood that both the foregoing general description and the following detailed description are exemplary and explanatory and are not intended to limit the invention to the precise forms disclosed. Other objects, which will be apparent to those skilled in the art, It will be possible.

According to an aspect of the present invention, there is provided a method of configuring a physical frame for a gigabit passive optical network, the method comprising: providing a system capable of improving an error correction probability of a superframe counter value in a gigabit passive optical network Arranging a bit string of an even numbered superframe after a first physical synchronization sequence bit string; arranging a bit string of an even numbered hybrid error correction after a bit string of the even numbered superframe; Arranging a bit string of an identifier of a first passive optical network after a bit string of the even number superframe, arranging a bit string of an identifier of the first passive optical network after the bit string of the first passive optical network, Placing a bit stream of a physical frame payload thereafter, Arranging a bit stream of a second physical synchronization sequence after a bit stream of an im payload, arranging a bit stream of an odd superframe after a bit stream of the second physical synchronization sequence, Thereafter arranging the bit stream of the odd numbered hybrid error correction, arranging the bit stream of the identifier of the second passive optical network after the bit string of the odd hybrid error correction, setting the bit string of the identifier of the second passive optical network Placing a bit string of redundancy thereafter and placing a parity bit after the bit string of redundancy.

The method of constructing a physical frame for a gigabit passive optical network according to an embodiment of the present invention is characterized in that the bit string of the even superframe is 51 bits, the bit string of the identifier of the first passive optical network is 13 bits, The bit string of the identifier of the second passive optical network is 21 bits, and the bit string of the redundancy is preferably 42 bits.

The method of constructing a physical frame for a gigabit passive optical network according to an embodiment of the present invention is characterized in that the bit string of the even superframe is 51 bits, the bit string of the identifier of the first passive optical network is 13 bits, The bit string of the identifier of the second passive optical network is 35 bits, and the bit string of the redundancy is preferably 28 bits.

The method of constructing a physical frame for a gigabit passive optical network according to an embodiment of the present invention is characterized in that the bit string of the even superframe is 51 bits, the bit string of the identifier of the first passive optical network is 13 bits, It is preferable that the bit string of the identifier of the second passive optical network is 28 bits and the bit string of the redundancy is 35 bits.

The method of constructing a physical frame for a gigabit passive optical network according to an embodiment of the present invention is characterized in that the bit string of the even superframe is 51 bits, the bit string of the identifier of the first passive optical network is 13 bits, It is preferable that the bit string of the identifier of the second passive optical network is 14 bits and the bit string of the redundancy is 49 bits.

The method of constructing a physical frame for a gigabit passive optical network according to an embodiment of the present invention is characterized in that the bit string of the even superframe is 51 bits, the bit string of the identifier of the first passive optical network is 13 bits, It is preferable that the bit string of the identifier of the second passive optical network is 7 bits and the bit string of the redundancy is 56 bits.

According to another aspect of the present invention, there is provided a method of constructing a physical frame for a gigabit passive optical network, the method comprising: arranging a bit string of an even-numbered superframe after a first physical synchronization sequence bit string; Arranging a bit stream of even-numbered hybrid error correction after a bit string of a superframe, arranging a bit string of the even-numbered superframe after a bit string of the even-numbered hybrid error correction, Disposing a bit string of an identifier of a passive optical network; placing a bit string of a physical frame payload after a bit string of an identifier of the passive optical network; Arranging a bit stream of a sequence, the second physical synchronization sequence Numbered superframe; arranging a bit string of an odd numbered superframe after the bit string; arranging a bit string of odd hybrid error correction after a bit string of the odd numbered super frame; And arranging the parity bits after the bit string of the redundancy.

The physical frame configuration method for a gigabit passive optical network according to another embodiment of the present invention is characterized in that the bit string of the even-numbered superframe is 51 bits, the bit string of the identifier of the passive optical network is 13 bits, It is preferable that the bit string is 63 bits.

According to another aspect of the present invention, there is provided a method of configuring a physical frame for a gigabit passive optical network, the method comprising: arranging a bit string of an even numbered superframe after a first physical synchronization sequence bit string; The method comprising the steps of: arranging a bit string of even-numbered hybrid error correction after a bit string of an even-numbered superframe; arranging a bit string of the even-numbered superframe after a bit string of the even- Disposing a bit string of an identifier of a passive optical network in a passive optical network, placing a bit string of a first redundancy after a bit string of an identifier of the passive optical network, Arranging a bit stream, and after the bit stream of the physical frame payload, Arranging a bit string of a real synchronization sequence, arranging a bit string of an odd number superframe after a bit string of the second physical synchronization sequence, arranging a bit string of odd hybrid error correction after a bit string of the odd number superframe, Disposing a bit string of a second redundancy after the bit string of the odd hybrid error correction, and arranging a parity bit after the bit string of the second redundancy.

The method of constructing a physical frame for a gigabit passive optical network according to another embodiment of the present invention is characterized in that the bit string of the even-numbered superframe is 51 bits, the bit string of the identifier of the passive optical network is 6 bits, It is preferable that the bit string of one redundancy is 7 bits and the bit string of the second redundancy is 63 bits.

A method of constructing a physical frame for a gigabit passive optical network according to embodiments of the present invention includes: superframe bitstream, a bitstream of an identifier of a passive optical network, and a bitstream of a BCCH code in a frame block of an identifier of two passive optical networks It is possible to increase the redundancy bit string of the BCCH code by arranging the bit string of the redundancy so that the scrambled data can be stored in the main memory of the gigabit passive optical network while maintaining compatibility with the standard system of the gigabit passive optical network (for example, ITU-T G.987) It is possible to effectively improve the error correction probability of the superframe counter value used as the seed value for coating.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a schematic diagram of a downstream physical frame of a device-bit passive optical network to which a method for constructing a physical frame for a gigabit passive optical network according to a first embodiment of the present invention is applied; FIG.
FIG. 2 is a schematic diagram of a downstream physical frame of a device-bit passive optical network to which a physical frame configuration method for a gigabit passive optical network according to a second embodiment of the present invention is applied; FIG.
FIG. 3 is a schematic diagram of a downstream physical frame of a device bit passive optical network to which a physical frame configuration method for a gigabit passive optical network according to a third embodiment of the present invention is applied; FIG.
FIG. 4 is a schematic diagram of a downstream physical frame of a device-bit passive optical network to which a method of configuring a physical frame for a gigabit passive optical network according to a fourth embodiment of the present invention is applied; FIG.
FIG. 5 is a schematic diagram of a downstream physical frame of a device bit passive optical network to which a physical frame configuration method for a gigabit passive optical network according to a fifth embodiment of the present invention is applied; FIG.
FIG. 6 is a schematic diagram of a downstream physical frame of a device bit passive optical network to which a physical frame configuration method for a gigabit passive optical network according to a sixth embodiment of the present invention is applied; FIG.
FIG. 7 is a schematic diagram of a downstream physical frame of a device-bit passive optical network to which a physical frame configuration method for a gigabit passive optical network according to a seventh embodiment of the present invention is applied; FIG.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. The details of other embodiments are included in the detailed description and drawings. BRIEF DESCRIPTION OF THE DRAWINGS The advantages and features of the present invention, and how to accomplish them, will become apparent with reference to the embodiments described in detail below with reference to the accompanying drawings. Like reference numerals refer to like elements throughout the specification.

As shown in FIG. 1, a physical frame configuration method for a gigabit passive optical network according to the first embodiment of the present invention includes: first, a bit of an even-numbered super frame SFCE10 after a first physical synchronization sequence (PSync11) And the bit stream of the even-numbered super frame (SFCE10) can be composed of 51 bits.

Next, a bit string of 13-bit even hybrid error correction (HECE10) is arranged after the bit string of the even-numbered super frame (SFCE10).

Next, a bit string of the even-numbered superframe (SFCE10) is arranged after a bit string of the even-numbered hybrid error correction (HECE10), and the bit string of the even-numbered superframe (SFCE10) may be composed of 51 bits.

A bit string of an identifier (PON11) of a first passive optical network is arranged after a bit string of the even-numbered super frame (SFCE10), and a bit string of an identifier (PON11) of the first passive optical network is composed of 13 bits .

Next, a bit string of 155,496 bytes of physical frame payload (PHY frame payload) is arranged after the bit string of the identifier (PON11) of the first passive optical network.

Next, a bit string of the second physical synchronization sequence (PSync12) is arranged after the bit string of the physical frame payload (PHY frame payload).

Next, a bit string of the odd-numbered super frame (SFCO10) is arranged after the bit string of the second physical synchronization sequence (PSync12), and the bit string of the odd-numbered super frame (SFCO10) is composed of 51 bits.

Next, a bit string of a 13-bit odd-numbered hybrid error correction (HECO10) is arranged after the bit string of the odd-numbered super frame (SFCO10).

Next, a bit string of an identifier (PON12) of a second passive optical network is arranged after a bit string of the odd hybrid error correction (HECO10), and the bit string of the identifier (PON12) of the second passive optical network is 21 bits Lt; / RTI >

Next, a bit string of redundancy (RED10) is arranged after the bit string of the identifier (PON12) of the second passive optical network, and the bit string of the redundancy (RED10) may be composed of 42 bits.

Next, one bit of parity (PAR10) bits are arranged after the bit string of the redundancy RED10.

Thereafter, as shown in FIG. 1, a bit string of a 51-bit even-numbered super frame (SFCE10) arranged after a bit string of an even-numbered hybrid error correction (HECE10), a bit string of an identifier PON11 of a 13- (BCHs 127, 85, and 6) capable of performing 6-bit error recovery using a bit string, a bit string of the identifier PON12 of the second passive optical network of 21 bits, and a bit string of the redundancy RED10 of 42 bits. )).

A method of constructing a physical frame for a gigabit passive optical network according to a first embodiment of the present invention includes: superframe bitstreams in a frame block of identifiers of two passive optical networks; bitstreams of identifiers of passive optical networks; The redundancy bit string of the BCCH code can be increased by arranging the bit string of the redundancy of the Gigabit passive optical network so that the scrambled data can be maintained while maintaining compatibility with the standard system of the gigabit passive optical network (for example, ITU-T G.987) It is possible to effectively improve the error correction probability of the superframe counter value used as the seed value in the de-coating.

Hereinafter, a method of constructing a physical frame for a gigabit passive optical network according to a second embodiment of the present invention will be described with reference to a method and a method for constructing a physical frame for a gigabit passive optical network according to a first embodiment of the present invention Explain.

The method of constructing a physical frame for a gigabit passive optical network according to the second embodiment of the present invention is characterized in that the bit string (SFCE20) of the even-numbered superframe is 51 bits, and the bit string (PON21) Is 13 bits, the bit string of the identifier (PON22) of the second passive optical network is 35 bits, and the bit string of the redundancy (RED20) is 28 bits.

Accordingly, as shown in FIG. 2, the bit string of the 51-bit even-numbered super frame (SFCE10) disposed after the bit string of the even-numbered hybrid error correction (HECE20), the bit string of the identifier PON21 of the 13- (BCH 127, 99, 4) capable of 4-bit error recovery using a bit string, a 35-bit second passive optical network identifier PON22 and a 28-bit redundancy RED20 bit string. )).

Hereinafter, a method of constructing a physical frame for a gigabit passive optical network according to a third embodiment of the present invention will be described with reference to a method and a method for constructing a physical frame for a gigabit passive optical network according to the first embodiment of the present invention Explain.

A method of constructing a physical frame for a gigabit passive optical network according to a third embodiment of the present invention is characterized in that the bit string of the even superframe (SFCE30) is 51 bits, the bit string of the identifier PON31 of the first passive optical network Is 13 bits, the bit string of the identifier (PON32) of the second passive optical network is 28 bits, and the bit string of the redundancy (RED30) is 35 bits.

Therefore, as shown in FIG. 3, the bit string of the 51-bit even super frame (SFCE30) disposed after the bit string of the even-numbered hybrid error correction (HECE30), the bit string of the identifier PON31 of the 13-bit first passive optical network (BCHs 127, 92, and 5) capable of 5-bit error recovery using a bit string, a bit string of the identifier PON32 of the second passive optical network of 28 bits and a bit string of the redundancy RED30 of 35 bits )).

Hereinafter, a method of constructing a physical frame for a gigabit passive optical network according to a fourth embodiment of the present invention will be described with reference to a method and a method for constructing a physical frame for a gigabit passive optical network according to the first embodiment of the present invention Explain.

The method of constructing a physical frame for a gigabit passive optical network according to the fourth embodiment of the present invention is characterized in that the bit sequence of the even-numbered super frame (SFCE40) is 51 bits and the bit string of the identifier PON41 of the first passive optical network Is 13 bits, the bit string of the identifier (PON42) of the second passive optical network is 14 bits, and the bit string of the redundancy (RED40) is 49 bits.

Therefore, as shown in Fig. 4, the bit string of the 51-bit even-numbered super frame (SFCE40) disposed after the bit string of the even-numbered hybrid error correction (HECE40), the bit string of the identifier PON41 of the 13- (BCH 127, 78, 7, 7) capable of 7-bit error recovery using a bit string, a bit string of the identifier PON42 of the second passive optical network of 14 bits and a bit string of the redundancy RED40 of 49 bits )).

Hereinafter, a method of constructing a physical frame for a gigabit passive optical network according to a fifth embodiment of the present invention will be described with reference to a method and a method for constructing a physical frame for a gigabit passive optical network according to the first embodiment of the present invention Explain.

The method of constructing a physical frame for a gigabit passive optical network according to a fifth embodiment of the present invention is characterized in that the bit sequence of the even superframe (SFCE50) is 51 bits and the bit string of the identifier PON51 of the first passive optical network Is 13 bits, the bit string of the identifier (PON52) of the second passive optical network is 7 bits, and the bit string of the redundancy (RED50) is 56 bits.

Therefore, as shown in FIG. 5, the bit string of the 51-bit even-numbered super frame (SFCE50) disposed after the bit string of the even-numbered hybrid error correction (HECE50), the bit string of the identifier PON51 of the 13-bit first passive optical network (BCHs 127, 71, and 9) capable of 9-bit error recovery using a bit string, a 7-bit second passive optical network identifier PON52, and 56-bit redundancy RED50, )).

As shown in FIG. 6, a physical frame configuration method for a gigabit passive optical network according to a sixth embodiment of the present invention includes: first, a bit of an even-numbered super frame (SFCE60) after a first physical synchronization sequence (PSync61) And the bit stream of the even-numbered super frame (SFCE 60) may be composed of 51 bits.

Next, a bit string of 13-bit even hybrid error correction (HECE60) is arranged after the bit string of the even-numbered super frame (SFCE60).

Next, a bit string of the even-numbered superframe (SFCE60) is arranged after the bit string of the even-numbered hybrid error correction (HECE60), and the bit string of the even-numbered superframe (SFCE60) may be composed of 51 bits.

Next, a bit string of the passive optical network identifier (PON60) is arranged after the bit string of the even-numbered super frame (SFCE60), and the bit string of the identifier (PON60) of the passive optical network may be composed of 13 bits.

Next, a bit string of 155,496 bytes of physical frame payload (PHY frame payload) is placed after the bit string of the identifier (PON60) of the passive optical network.

Next, a bit string of the second physical synchronization sequence (PSync62) is arranged after the bit string of the physical frame payload (PHY frame payload).

Next, a bit string of the odd-numbered super frame (SFCO60) is arranged after the bit string of the second physical synchronization sequence (PSync62), and the bit string of the odd-numbered super frame (SFCO60)

Next, a bit string of a 13-bit odd hybrid error correction (HECO60) is arranged after the bit string of the odd-numbered super frame (SFCO 60).

Next, a bit string of redundancy (RED60) is arranged after the bit string of the odd hybrid error correction (HECO60), and the bit string of the redundancy (RED60) may be composed of 63 bits.

Next, a 1-bit parity (PAR60) bit is arranged after the bit string of the redundancy RED60.

Thereafter, as shown in FIG. 6, a bit string of the 51-bit even-numbered super frame (SFCE60) disposed after the bit string of the even-numbered hybrid error correction (HECE60), a bit string of the identifier PON60 of the 13- (BCHs 127, 64, and 10) capable of performing 10-bit error recovery using the bit string of the 64-bit redundancy (RED60) and the 63-bit redundancy (RED60)

As shown in FIG. 7, a physical frame configuration method for a gigabit passive optical network according to a seventh embodiment of the present invention includes: first, a bit of an even-numbered super frame SFCE70 after a first physical synchronization sequence (PSync71) Column, and the bit stream of the even-numbered super frame (SFCE 70) may be composed of 51 bits.

Next, a bit string of 13-bit even hybrid error correction (HECE 70) is arranged after the bit string of the even-numbered super frame (SFCE 70).

Next, a bit string of the even-numbered superframe (SFCE 70) is arranged after the bit string of the even-numbered hybrid error correction (HECE 70), and the bit string of the even-numbered superframe (SFCE 70) may be composed of 51 bits.

Next, a bit string of the passive optical network identifier (PON70) is arranged after the bit string of the even-numbered super frame (SFCE70), and the bit string of the identifier (PON60) of the passive optical network may be composed of 6 bits.

Next, a bit string of a first redundancy (RED71) is arranged after a bit string of an identifier (PON70) of the passive optical network, and the bit string of the first redundancy (RED71) may be composed of 7 bits.

Next, a bit string of 155,496 bytes of physical frame payload (PHY frame payload) is arranged after the bit string of the first redundancy RED71.

Next, a bit string of the second physical synchronization sequence (PSync72) is arranged after the bit string of the physical frame payload (PHY frame payload).

Next, a bit string of the odd-numbered super frame (SFCO) 70 is arranged after the bit string of the second physical synchronization sequence (PSync72), and the bit string of the odd-numbered super frame (SFCO) 60 may be composed of 51 bits.

Next, a bit stream of odd-numbered hybrid error correction (HECO 70) of 13 bits is arranged after the bit string of the odd-numbered super frame (SFCO 70).

Next, a bit string of the second redundancy RED72 is arranged after the bit string of the odd hybrid error correction (HECO70), and the bit string of the second redundancy RED72 may be composed of 63 bits.

Next, one bit of parity (PAR70) bits are arranged after the bit string of the second redundancy RED72.

Thereafter, as shown in Fig. 7, the bit string of the 51-bit even-numbered super frame (SFCE70) disposed after the bit string of the even-numbered hybrid error correction (HECE70), the bit string of the identifier PON60 of the 6- (BCH (127, 57, 11) capable of performing 11-bit error recovery using the bit string of the 7-bit first redundancy (RED71) and the 63-bit second redundancy (RED72) can do.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments.

On the contrary, those skilled in the art will appreciate that many modifications and variations of the present invention are possible without departing from the spirit and scope of the appended claims.

Accordingly, all such appropriate modifications and changes, and equivalents thereof, should be regarded as within the scope of the present invention.

PSync11: First physical synchronization sequence
PSync12: Second physical synchronization sequence
PON11: Identifier of the first passive optical network
PON12: Identifier of the second passive optical network
SFCE10: Can super frame
SFCO10: odd super frame
HECE10: Even-numbered hybrid error correction
HECO10: Odd hybrid error correction
PHY frame payload: Physical frame payload
RED10: Redundancy
PAR10: Parity

Claims (10)

A system for improving the error correction probability of a superframe counter value in a gigabit passive optical network,
Arranging a bit string of an even numbered superframe after the first physical synchronization sequence bit string;
Arranging a bit string of even-numbered hybrid error correction after the bit string of the even-numbered super frame;
Arranging a bit stream of the even superframe after the bit stream of the even-numbered hybrid error correction;
Arranging a bit string of an identifier of a first passive optical network after a bit string of the even superframe;
Arranging a bit string of a physical frame payload after a bit string of an identifier of the first passive optical network;
Placing a bit stream of a second physical synchronization sequence after a bit stream of the physical frame payload;
Arranging a bit string of an odd-numbered superframe after a bit string of the second physical synchronization sequence;
Arranging a bit string of odd hybrid error correction after a bit string of the odd superframe;
Disposing a bit string of an identifier of the second passive optical network after the bit string of the odd hybrid error correction;
Arranging a bit string of redundancy after a bit string of an identifier of the second passive optical network; And
And placing a parity bit after the bit string of the redundancy.
The method according to claim 1,
Wherein the bit string of the first passive optical network is 51 bits, the bit string of the identifier of the first passive optical network is 13 bits, the bit string of the identifier of the second passive optical network is 21 bits, Wherein the physical layer is a 42-bit physical layer.
The method according to claim 1,
Wherein the bit string of the first passive optical network is 51 bits, the bit string of the identifier of the first passive optical network is 13 bits, the bit string of the identifier of the second passive optical network is 35 bits, Wherein the physical frame configuration information is 28 bits.
The method according to claim 1,
Wherein the bit string of the first passive optical network is 51 bits, the bit string of the identifier of the first passive optical network is 13 bits, the bit string of the identifier of the second passive optical network is 28 bits, Wherein the physical frame is a 35-bit physical frame for a gigabit passive optical network.
The method according to claim 1,
Wherein the bit string of the first passive optical network is 51 bits, the bit string of the identifier of the first passive optical network is 13 bits, the bit string of the identifier of the second passive optical network is 14 bits, Wherein the physical frame is a 49-bit physical frame for a gigabit passive optical network.
The method according to claim 1,
Wherein the bit string of the first passive optical network is 51 bits, the bit string of the identifier of the first passive optical network is 13 bits, the bit string of the identifier of the second passive optical network is 7 bits, Wherein the physical frame structure is 56 bits.
Arranging a bit string of an even numbered superframe after the first physical synchronization sequence bit string;
Arranging a bit string of even-numbered hybrid error correction after the bit string of the even-numbered super frame;
Arranging a bit stream of the even superframe after the bit stream of the even-numbered hybrid error correction;
Arranging a bit string of an identifier of the passive optical network after the bit string of the even-numbered super frame;
Arranging a bit string of a physical frame payload after a bit string of an identifier of the passive optical network;
Placing a bit stream of a second physical synchronization sequence after a bit stream of the physical frame payload;
Arranging a bit string of an odd-numbered superframe after a bit string of the second physical synchronization sequence;
Arranging a bit string of odd hybrid error correction after a bit string of the odd superframe;
Arranging a bit string of redundancy after the bit string of the odd hybrid error correction; And
And placing a parity bit after the bit string of the redundancy.
8. The method of claim 7,
Wherein the bit string of the even-numbered superframe is 51 bits, the bit string of the identifier of the passive optical network is 13 bits, and the bit string of the redundancy is 63 bits. .
Arranging a bit string of an even numbered superframe after the first physical synchronization sequence bit string;
Arranging a bit string of even-numbered hybrid error correction after the bit string of the even-numbered super frame;
Arranging a bit stream of the even superframe after the bit stream of the even-numbered hybrid error correction;
Arranging a bit string of an identifier of the passive optical network after the bit string of the even-numbered super frame;
Disposing a bit string of a first redundancy after a bit string of an identifier of the passive optical network;
Arranging a bit string of a physical frame payload after a bit string of the first redundancy;
Placing a bit stream of a second physical synchronization sequence after a bit stream of the physical frame payload;
Arranging a bit string of an odd-numbered superframe after a bit string of the second physical synchronization sequence;
Arranging a bit string of odd hybrid error correction after a bit string of the odd superframe;
Disposing a bit string of a second redundancy after the bit string of the odd hybrid error correction; And
And placing a parity bit after the bit string of the second redundancy.
10. The method of claim 9,
Wherein the bit string of the even-numbered superframe is 51 bits, the bit string of the identifier of the passive optical network is 6 bits, the bit string of the first redundancy is 7 bits, and the bit string of the second redundancy is 63 bits A method for constructing a physical frame for a gigabit passive optical network.

Images