KR20100030569A - Frame generation apparatus and method for protecting protocol header information over wideband high frequency wireless system - Google Patents

Abstract

PURPOSE: A frame generation apparatus for protecting variable length header information in a broadband high frequency wireless system and a method thereof are provided to convert a variable length header of a frame into a fixed length header, thereby protecting variable length header information. CONSTITUTION: A frame basic header generator(1210) generates a frame basic header. A frame selection header generator(1220) generates a frame selection header. A MAC sub header generator(1222) of the frame selection header generator generates a fixed length MAC sub header.

Description

FRAME GENERATION APPARATUS AND METHOD FOR PROTECTING PROTOCOL HEADER INFORMATION OVER WIDEBAND HIGH FREQUENCY WIRELESS SYSTEM}

An embodiment of the present invention is a method for effectively protecting protocol header information in a system capable of high-speed transmission through the use of an ultra-wide frequency band, and relates to a frame generation method for protecting header information having a variable length.

Reed-Solomon (RS) code is a Forward Error Correction (FEC) technology that is widely used in a variety of applications including mobile communications, magnetics, optical storage media, wired and satellite communications. RS (255,239) or RS (224, 216) codes are also used in 60 GHz Millimeter Wave (mmWave) wireless communication systems.

The shortened RS code scheme, which is generally an RS code scheme, uses 255 information bytes or 224 information bytes as a mother code and adds 239 bytes or 216 bytes having a value of 0 after the information byte. Then, using the information bytes to which the byte of zero value is added, RS parity bits having a length of 16x8 or 8x8 bits are generated according to the RS FEC scheme and added after the information bytes. At this time, bytes of zero value added to the information bytes are removed.

A shortened Low Density Parity Check (LDPC) code scheme similar to the shortened RS code scheme is also used in 60 GHz Millimeter Wave (mmWave) wireless communication systems. The shortened LDPC code method uses 672 information bytes as the mother code and adds 336 bytes whose value is 0 to the end of the information byte. Then, the LDPC parity bit is generated according to the LDPC scheme by using the information bytes to which the byte of zero value is added and added after the information bytes. At this time, bytes of zero value added to the information bytes are removed.

In the conventional SC (Single Carrier) PHY standard, the PHY header, MAC header, and HCS (Header Check Sequence) field are encoded by the shortened RS code method. At this time, the HCS field for error detection of the PHY header, MAC header and MAC header is called a frame basic header. The MAC sub-header and the HCS field are encoded using the shortened RS code method. At this time, the HCS field for error detection of the MAC sub-header and the MAC sub-header is called a frame selection header.

However, the conventional frame selection header using the shortened RS code has a variable length. Therefore, a problem may occur that the RS cannot effectively perform RS decoding processing of a frame selection header having a variable length. That is, when the transmitting apparatus encodes the shortened RS code, RS decoding may be performed after adding bytes having a value of 0 to match the mother code length. However, if we receive a variable-length frame selection header, we do not know how many bytes of zero value must be added.

The conventional High Speed Internet (HSI) PHY standard encodes a frame basic header composed of a PHY header, a MAC header, and an HCS field in the same way as the above-described SC PHY standard using the shortened LDPC code method. The frame selection header consisting of the MAC sub-header and the HCS field is encoded by using the shortened LDPC code method.

As in the SC PHY specification described above, in the HSI PHY standard, the frame selection header has a variable length. Therefore, a problem may occur that the LDPC decoding process of the frame selection header having a variable length cannot be effectively performed by the receiving apparatus. That is, when the transmitting apparatus encodes the shortened LDPC code, the receiving apparatus may perform LDPC decoding after adding bytes having a value of 0 to match the mother code length. However, if we receive a variable-length frame selection header, we do not know how many bytes of zero value must be added.

In the conventional AV (Audio Video) PHY standard, a high rate protocol (HRP) header, an extended MAC header, and an HCS field are divided into two information byte blocks. Each divided information byte block is encoded using the shortened RS code method.

The extended MAC header is composed of variable length because the MAC extended header field, the security header field, and the video header fields may or may not exist. Nevertheless, in the prior art, information consisting of an HRP header, an extended MAC header, and an HCS is regarded as a fixed length of 92 bytes, divided into 48 bytes and 44 bytes, and then encoded separately in a shortened RS code method in the divided information blocks. It is prescribed. Therefore, in the encoder and the decoder, a malfunction may occur when the second information block having a variable length is encoded / decoded.

An embodiment of the present invention provides an apparatus and method for generating a frame for protecting variable length header information in a wideband high frequency wireless system.

An embodiment of the present invention provides a method for distinguishing variable length protocol header information and data information.

According to an embodiment of the present invention, even if a transmitting device performs shortened RS or shortened LDPC encoding on a variable length protocol header, the receiving device effectively distinguishes protocol header information and data information and decodes RS or LDPC information on a variable length protocol header. It provides a frame generation method that can perform.

An apparatus for generating a frame according to an embodiment of the present invention may include a frame basic header generator configured to generate a frame basic header including a physical layer protocol (PHY) header, a media access control (MAC) header, and a first header check sequence (HCS). And a frame selection header generator for generating a frame selection header including a fixed length MAC subheader and a second HCS.

An apparatus for generating a frame according to an embodiment of the present invention may include a variable header generation unit configured to receive protocol header information and generate a variable length protocol header, and add a padding bit having a value of 0 to the variable length protocol header to set a predetermined fixed length. The branch includes a fixed header converter that converts the fixed length protocol header into a frame and inserts the same into a frame.

A frame generation method according to an embodiment of the present invention may include generating a frame basic header including a physical layer protocol (PHY) header, a media access control (MAC) header, and a first header check sequence (HCS) and a fixed length. Generating a frame selection header comprising a MAC subheader and a second HCS.

According to an embodiment of the present invention, a frame generation method includes receiving a protocol header information to generate a variable length protocol header and adding a padding bit having a value of 0 to the variable length protocol header to have a fixed length which is preset. Converting to a protocol header and inserting it into a frame.

The frame generation apparatus according to an embodiment of the present invention signals a variable length header length of a frame. Therefore, the variable length header can be confirmed by the receiving device. Alternatively, the frame generation apparatus according to an embodiment of the present invention adds padding information to a variable length header of a frame and converts the predetermined length to a predetermined fixed length header. Therefore, the receiving apparatus may check the variable length header by receiving the preset fixed length header and removing the padding information.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings. However, the present invention is not limited or limited by the embodiments. Like reference numerals in the drawings denote like elements. If it is determined that the gist of the present invention may be unnecessarily obscured, detailed description thereof will be omitted.

Embodiments of the present invention may be applied to a communication standard for high speed data transmission. At this time, an example of a communication standard for high speed data transmission is IEEE 802.15.3c.

An embodiment of the present invention proposes methods for allowing a receiving apparatus to distinguish a variable length header from data information. As a first method, a method of signaling a header length of a variable length so that a reception apparatus can be known is proposed. Secondly, in order to match the mother code length, a method of adding a zero value bit, encoding a mother code added with zero value into an RS or LDPC code, and including the added zero value bits are proposed. Then, we propose a method using fixed length header, which is the most basic solution.

First, a method of signaling a header length of a variable length so that a receiving device is known will be described.

1 is a diagram illustrating an example of a frame configuration for protecting variable length header information according to an embodiment of the present invention. Referring to FIG. 1, the receiving device receiving the frame 100 of FIG. 1 may signal the length of the variable length protocol header 130 through the length field S_VLPH 120.

The transmitting apparatus distinguishes the fixed length protocol header 110 and the variable length protocol header 130 and individually shortens RS or shortened LDPC encoding. The frame 100 is configured by including the length field S_VLPH 120, which is length information of the variable length protocol header 130, in the fixed length protocol header 110.

Upon receiving the frame 100, the receiving apparatus first decodes the fixed length protocol header 110 through a shortened RS or a shortened LDPC decoding method. The receiver analyzes the fixed length protocol header 110 and extracts the length field S_VLPH 120 which is length information of the variable length protocol header. At this time, since the fixed length protocol header 110 has a fixed length, the receiving device can easily derive the number of zero bytes or zero bits to be added.

The receiving apparatus checks the length field S_VLPH 120 and decodes the variable length protocol header 130 through a shortened RS or a shortened LDPC decoding method.

2 is a diagram illustrating another example of a frame configuration for protecting variable length header information according to an embodiment of the present invention.

Referring to FIG. 2, the transmitting apparatus encodes a variable length protocol header 210 through a shortened RS or shortened LDPC encoding method, and then delimiter 220 as a physical signal to distinguish a boundary from the data 230. It is inserted into the frame 200. The delimiter 220 is composed of a signal having a predetermined specific pattern between the transmitting device and the receiving device. When the delimiter 220 is detected when the frame 200 is received, the receiving device may confirm that the fixed length RS parity or LDPC parity bit information and the variable length protocol header 210 have been received. Therefore, it is possible to extract the number of bits having a value 0 to be added for shortened RS decoding or shortened LDPC decoding.

3 is a diagram illustrating another example of a frame configuration for protecting variable length header information according to an embodiment of the present invention. Referring to FIG. 3, the transmitting apparatus generates a preset fixed length protocol header 340 by adding a padding bit 320 having a value of 0 to the variable length protocol header 310. Then, the predetermined fixed length protocol header 340 is encoded as a shortened RS or shortened LDPC code as a mother code.

That is, the transmitting device generates a frame 300 including the preset fixed length protocol header 340.

When the receiving device receives the RS / LDPC parity bit 330 of fixed length, the receiving device may know that the reception of the protocol header 340 is completed. Thereafter, RS or LDPC decoding is performed. Padding bits 320 with a value of zero become overhead. To reduce overhead, you can use a smaller length parent code.

The case in which the protocol header information may be variable in the SC (Single Carrier) PHY specification and the HSI (High Speed Internet) PHY specification is a case where the data payload part forms an aggregated frame. In other words, a frame is configured by encapsulating one or more subframes into one PHY / MAC header. In this case, the transmission apparatus may transmit different modulation and coding schemes (MCS) for each sub-frame, and the reception side may receive the MCS applied for each sub-frame. In order to apply MCS for each sub-frame, one subheader field is allocated per sub-frame, and the sub-headers are grouped into one to form a MAC sub-header. Therefore, the MAC sub-header has a variable length according to the number of clustered sub-frames.

Next, a method of encoding / decoding a MAC sub-header into a shortened RS code or a shortened LDPC code by forcibly configuring a variable length MAC sub-header with a fixed length will be described below with reference to FIGS. 4 and 5.

4 illustrates another example of a frame configuration for protecting variable length header information according to an embodiment of the present invention. Referring to FIG. 4, when the clustered frames 400 are transmitted according to the SC PHY standard, the MAC sub-header 402 is configured to have a fixed length regardless of the number of clustered sub-frames. That is, the MAC sub-header 402 has a fixed length so that the frame selection header 410 can be encoded / decoded with a shortened RS code.

The data payload 420 of the clustered frame 400 may consist of one or more sub-frames 421, 422, 423. In this case, the maximum number of sub-frames that can be clustered is limited in the specification, and the value thereof is referred to as N in the embodiment of the present invention. Therefore, the number n of sub-frames constituting the data payload 420 of the clustered frame 400 is actually greater than or equal to 1 and less than or equal to N.

The sub-headers 431, 432, 433 have sub-frame information of each of the sub-frames 421, 422, 423. MAC sub-header 402, which includes sub-headers 431, 432, 433, always has N sub-headers 431 regardless of the number of sub-frames n contained in clustered frame 400. , 432, 433, 434, 435. Sub-frame length field values of the (n + 1) th sub-headers 434 to the N th sub-headers 405 are set to zero. As a result of checking the sub-header, if the value of the sub-frame length field is 0, the reception device determines that the padding sub-frame does not exist in the clustered frame 400.

Therefore, the transmitting apparatus forcibly encodes the frame selection header 410 composed of the fixed length MAC sub-header 402 and the fixed length HCS 404 with the shortened RS code to insert the RS parity 460. When the receiving device receives the clustered frame 400, the receiving device may decode the shortened RS code because the predetermined length is known without additional information on the length of the MAC sub-header 402.

In FIG. 4, each field of the sub-header 421 is described as follows. The MCS information field 441 is a field indicating a modulation and coding scheme of the SC PHY and the HSI PHY used in each sub-frame. The FCS information 442 is a field indicating whether to use a frame check permutation. The retry field 443 is a field indicating whether to use retransmission of a sub-frame. Subframe length field 445 indicates the length of the sub-frame before encoding that does not include a frame check permutation. The resolution indication field 444 is a field indicating a unit of the subframe length field 445 described above. The subframe information field 446 is a field indicating the type of data included in the sub-frame. The skewed constellation mode field 447 is a field indicating whether a skewed constellation technique is used in a sub-frame. The MSDU Offset field 448 indicates a difference value between the number of MAC Service Data Units (MSDUs) in the MAC header and the number of MSDUs in the sub-frame. The last fragmentation field 449 is a field indicating whether the current sub-frame is the last fragmentation of the MSDU.

5 is a diagram illustrating another example of a frame configuration for protecting variable length header information according to an embodiment of the present invention. Referring to FIG. 5, the MAC sub-header has a fixed length so that the frame selection header 410 can be encoded / decoded with a shortened LDPC code. The clustered frame 400 of FIG. 5 is the same as the description of FIG. 4 except that the LDPC parity 560 encoded through the shortened LDPC code is inserted.

In order to force the length of the MAC sub-header 402 to a fixed length in Figs. 4 and 5, unnecessary sub-headers 434 and 435 have been inserted. However, this can increase overhead. In terms of reducing overhead, the variable header length signaling method described above with reference to FIG. 1 may be more effective.

 As described above, when the clustered frames are transmitted in the SC PHY and HSI PHY standards, the frame selection header including the MAC sub-header also has a variable length because the MAC sub-header is of variable length. In this case, in order to encode the shortened RS or the shortened LDPC, the length information of the MAC sub-header should be inserted into a frame basic header including a PHY header, a MAC header, and an HCS field. The length information of the MAC sub-header may be represented by the number of sub-headers since the sub-header constituting the MAC sub-header has a fixed length. In this case, the number of bits of the field for indicating the number of sub-headers is ceil (log2 (N + 1)) when N is the maximum number of sub-frames that can be included in the clustered frame. Here, ceil (a) operator means the smallest integer greater than or equal to a. For example, if N = 8, 4 bits of space are required.

In an embodiment of the present invention, a bit space for indicating MAC sub-header length information is called a sub-header number field. The length of the sub-header number field is ceil (log2 (N + 1)) bits, which is a fixed length. The sub-header count field may be included in the PHY header or the MAC header constituting the frame basic header. Since the existing PHY header and MAC header are also fixed lengths, the proposed frame base header length added with the sub-header count field has a fixed length. In the embodiment of the present invention, it will be described to add the sub-header count field to the PHY header.

An embodiment of the present invention applying a method of signaling a variable header length when transmitting a cluster frame in the SC PHY and HSI PHY standards will be described below with reference to FIGS. 6, 7, 8, and 9.

6 is a diagram illustrating an example of an SC PHY header configuration for protecting variable length header information according to an embodiment of the present invention. Referring to FIG. 6, in the SC PHY header 620 of the proposed SC PHY standard, a sub-header number field 640 is added to signal a variable length of a frame selection header. At this time, assuming that the maximum number of sub-frames to be clustered is 8, the length of the sub-header number field 640 is set to 4 bits. The reserved field 642 is also set to 6-bit space to make the length of the SC PHY header 620 in bytes.

Referring to the existing SC PHY header 610, the SC PHY header 610 does not include the sub-header count field 640 and includes a 2-bit reserved field 612.

Each field of the SC PHY header 620 is described as follows. Scrambler seed ID 621 is a field that stores the seed value of the scrambler. The aggregation field 622 is a field indicating whether to use a clustering technique. The UEP field 623 is a field indicating whether to use the inequality error protection scheme. The MCS field 624 is a field indicating modulation and coding scheme of the SC PHY. The frame length field 625 is a field indicating the length of the MAC frame in octets except the frame check permutation. The Preamble type field 626 is a field indicating the type of preamble to be used in the next frame. The beam tracking field 627 is a field indicating whether a training permutation exists for beam tracking. The low latency mode field 628 is a field indicating whether a low latency cluster mode of a frame is used. The pilot word length ID field 629 is a field indicating the length of the pilot word. The PCES field 630 is a field indicating whether a pilot channel prediction permutation is included in a frame.

When the cluster field 622 of the SC PHY header 620 as shown in FIG. 6 is 0, that is, when the frame selection header does not have a variable length because it is not a clustered frame, the number of sub-header fields 640 is added. Has no meaning. Thus, the sub-header count field 640 may act as an overhead.

Another SC PHY header structure for reducing the overhead of the sub-header count field 640 occurring in FIG. 6 according to an embodiment of the present invention will be described below with reference to FIG. 7.

7 is a diagram illustrating another example of an SC PHY header configuration for protecting variable length header information according to an embodiment of the present invention. Referring to FIG. 7, when the cluster field 622 of the SC PHY header 710 is set to 1, it means a clustered frame and means that a MAC sub-header of variable length is included. Each sub-header information constituting the MAC sub-header includes a subframe length field 445 indicating the length of the sub-frame as described with reference to FIG. 4. Therefore, when the MAC sub-header is included, frame length information of the SC PHY header 710 becomes unnecessary information. Therefore, in the embodiment of the present invention, the existing frame length field is used as the frame length or sub-header number field 715 by adding a sub-header number field. That is, if the cluster field 622 value is 0, the frame length or sub-header count field 715 is used as the frame length field. If the cluster field 622 value is 1, the frame length or sub-header count field 715 is used. Is used as the sub-header count field.

Each field of the SC PHY header 710 of FIG. 7 will not be described for the same field as that of FIG. 6.

8 and 9 apply the contents proposed in FIGS. 6 and 7 to the HSI PHY header structure, respectively.

8 is a diagram illustrating an example of an HSI PHY header configuration for protecting variable length header information according to an embodiment of the present invention. Referring to FIG. 8, the proposed HSI PHY header 820 uses 4 bits of the reserved field 812 of the existing HSI PHY header 810 as the sub-header count field 840.

In FIG. 8, each field of the HSI PHY header 820 is described as follows. The bit interleaver field 821 is a field indicating whether the bit interleaver is used in the payload of the frame. The skewed constellation field 822 is a field indicating whether to use an unequal error protection constellation mapping technique. For each field of the HSI PHY header 820, description of the same field as that of FIG. 6 will be omitted.

9 is a diagram illustrating another example of an HSI PHY header configuration for protecting variable length header information according to an embodiment of the present invention. FIG. 9 illustrates an embodiment in which the method of using the frame length or sub-header number field 915 proposed in FIG. 7 is applied to an HSI PHY header structure. Therefore, detailed description is omitted.

For each field of the HSI PHY header 910 of FIG. 9, the description of the same field as in the previous figure is omitted.

10 is a diagram illustrating an example of a protocol header configuration for protecting variable length header information according to an embodiment of the present invention. Referring to FIG. 10, a protocol header in an AV PHY includes an HRP header, an extended MAC header, and an HCS. The total length K is expressed by Equation 1 below.

K = L _{HRP _ header} + L _{MAC _ header} + L _{Extended _ control _ header} + I _{MAC _ extension _ header} × L _{MAC_extension_header} + I _{security _ header} × L _{security _ header} + I _{video _ header} × L _{video _ header} + L _reserved + L _HCS

Where L _{HRP _ header} is the HRP header length, L _{MAC _ header} is the MAC header length, L _{Extended_control_header} is the extended control header length, I _{MAC _ extension _ header} is the MAC extension header presence bit value of the extended control header, I _{security _ header} is the security header presence bit value of the extension control header, I _{video _ header} is the video header presence bit value of the extension control header, L _{MAC _ extension _ header} is the MAC extension header length, and L _{security _ header} is It is a security header length, L _{video _ header} is a video header length, L _reserved is a reserved field length, and L _HCS is an HCS length. At this time, _L. The field length, denoted by I, is fixed length _. The total length K becomes a variable length according to the bit value indicated by.

In an embodiment of the present invention, the AV PHY protocol header composed of K bytes is divided into fixed length k bytes and variable length K-k bytes, and the divided information blocks are individually encoded by a shortened RS code. In this case, the fixed length k-byte value satisfies Equation 2 below.

k ≥ L _{HRP _ header} + L _{MAC _ header} + L _{Extended _ control _ header}

In Equation 2, the condition of the value k must include the extended control header 1032 in the fixed length information block 1010. The extension control header 1032 includes length information of the K-k variable length information block 1020.

11 is a diagram illustrating a configuration of an apparatus for generating a frame including a variable length header according to an embodiment of the present invention. Referring to FIG. 11, a frame generating apparatus according to an embodiment of the present invention is a device for generating the frame of FIG. 3. The variable header generating unit 1110, the fixed header converting unit 1120, the FEC coder 1130, and the payload are shown in FIG. 3. Generation unit 1140 is included.

The variable header generator 1110 generates the variable length protocol header 310 by receiving the protocol header information. The fixed header converter 1120 converts the fixed length protocol header 310 into a fixed length protocol header 340 having a predetermined fixed length by adding a padding bit 320 having a value of 0 to the variable length protocol header 310. do.

The FEC coder 1130 encodes the fixed length protocol header 340 including the padding bit 320 to forward error correction (FEC) to generate the FEC parity bit 330, and generates the FEC parity bit 330. It is inserted into the frame 300. The payload generator 1140 generates a payload including the received data.

12 is a diagram illustrating a configuration of an apparatus for generating a frame including a variable length frame selection header according to an embodiment of the present invention.

Referring to FIG. 12, an apparatus for generating a frame according to an embodiment of the present invention is a device for generating the frame of FIG. 4 or 5, and includes a frame basic header generator 1210, a frame selection header generator 1220, and a payload generator. 1230, FEC coder 1242 and FEC coder 1244.

The frame base header generation unit 1210 generates a frame base header 1252 including a physical layer protocol (PHY) header, a media access control (MAC) header, and a header check sequence (HCS). The frame basic header generator 1210 includes a MAC header generator 1212, a PHY header generator 1214, an HCS generator 1216, and a scramble processor 1218.

The MAC header generation unit 1212 receives MAC information and generates a MAC header. The PHY header generation unit 1214 receives the PHY information and generates a PHY header. The HCS generator 1216 generates an HCS for error detection of the PHY header and the MAC header. The scramble processor 1218 scrambles the MAC header and the HCS. Frame base header 1252 is composed of a PHY header, a scrambled MAC header, and a scrambled HCS.

The frame selection header generator 1220 generates a frame selection header including a fixed length MAC subheader and an HCS. The frame selection header generator 1220 includes a MAC subheader generator 1222, an HCS generator 1224, and a scramble processor 1226.

When the MAC subheader generation unit 1222 receives the subheaders, the MAC subheader generation unit 1222 adds a padding subheader to the subheaders to generate a fixed length MAC subheader. In this case, the padding subheader indicates a subheader whose length information value of the corresponding sub-frame is zero. The HCS generator 1224 generates an HCS for error detection of the MAC subheader. The scramble processing unit 1226 scrambles the fixed length MAC subheader and the HCS to generate the frame selection header 1256.

The FEC coder 1242 FEC-codes the frame basic header 1252 to generate the FEC parity bits 1254 of the frame basic header. The FEC coder 1244 performs FEC encoding on the frame selection header 1256 to generate the FEC parity bit 1258 of the frame basic header.

The FEC coding applied by the FEC coder 1242 and the FEC coder 1244 may be applied by Reed-Solomon (RS) coding or Low Density Parity Check (LDPC) coding. The payload generator 1230 receives the sub-frames and generates a payload 1260 including the clustered sub-frames.

In the present invention as described above has been described by the specific embodiments, such as specific components and limited embodiments and drawings, but this is only provided to help a more general understanding of the present invention, the present invention is not limited to the above embodiments. For those skilled in the art, various modifications and variations are possible from these descriptions. Therefore, the spirit of the present invention should not be limited to the described embodiments, and all of the equivalents and equivalents of the claims as well as the claims to be described later belong to the scope of the present invention. .

1 is a diagram illustrating an example of a frame configuration for protecting variable length header information according to an embodiment of the present invention;

2 is a diagram illustrating another example of a frame configuration for protecting variable length header information according to an embodiment of the present invention;

3 is a diagram illustrating another example of a frame configuration for protecting variable length header information according to an embodiment of the present invention;

4 is a diagram illustrating another example of a frame configuration for protecting variable length header information according to an embodiment of the present invention;

5 illustrates another example of a frame configuration for protecting variable length header information according to an embodiment of the present invention;

6 is a diagram illustrating an example of configuration of an SC PHY header for protecting variable length header information according to an embodiment of the present invention;

7 illustrates another example of an SC PHY header configuration for protecting variable length header information according to an embodiment of the present invention;

8 illustrates an example of a configuration of an HSI PHY header for protecting variable length header information according to an embodiment of the present invention;

9 illustrates another example of an HSI PHY header configuration for protecting variable length header information according to an embodiment of the present invention;

10 illustrates an example of a protocol header configuration for protecting variable length header information according to an embodiment of the present invention;

11 is a view showing the configuration of an apparatus for generating a frame including a variable length header according to an embodiment of the present invention;

12 is a diagram illustrating a configuration of an apparatus for generating a frame including a variable length frame selection header according to an embodiment of the present invention.

Claims (20)

A frame basic header generation unit generating a frame basic header including a physical layer protocol (PHY) header, a media access control (MAC) header, and a first header check sequence (HCS); And A frame selection header generator for generating a frame selection header including a fixed length MAC subheader and a second HCS; The fixed length MAC subheader is generated using a padding subheader, Frame generation device. The method of claim 1, The frame selection header generation unit, A MAC subheader generation unit for generating the MAC subheader of fixed length by adding a padding subheader to the subheaders upon receiving the subheaders; And HCS generation unit for generating the second HCS for error detection of the MAC subheader; Frame generation device. The method of claim 2, And a scrambling processing unit configured to generate the frame selection header by scrambling the MAC subheader and the second HCS having a fixed length. Frame generation device. The method of claim 2, The padding subheader is Subheader whose length information value of the corresponding sub-frame is zero Frame generation device. The method of claim 1, The frame basic header generation unit, A PHY header generator configured to receive PHY information and to generate the PHY header; A MAC header generator which receives MAC information and generates the MAC header; An HCS generator configured to generate the first HCS for error detection of the PHY header and the MAC header; And And a scramble processor configured to scramble the MAC header and the first HCS. Frame generation device. The method of claim 1, The apparatus further includes an FEC coder configured to perform FEC encoding on each of the frame basic header and the frame selection header to generate respective FEC parity bits. Frame generation device. The method of claim 6, The FEC encoding is Reed-Solomon (RS) coding or Low Density Parity Check (LDPC) coding Frame generation device. The method of claim 1, The frame, And a payload including the frame basic header, the FEC parity bit of the frame basic header, the frame selection header, the FEC parity bit of the frame selection header, and a clustered sub-frame. Frame generation device. A variable header generation unit configured to receive protocol header information and generate a variable length protocol header; And And a fixed header converting unit for adding a padding bit having a value of 0 to the variable length protocol header, converting it into a fixed length protocol header having a predetermined fixed length, and inserting the same into a frame. Frame generation device. The method of claim 9, The apparatus may further include an FEC code unit configured to generate FEC parity bits by performing forward error correction (FEC) encoding on the fixed length protocol header including the padding bits, and inserting the FEC parity bits into the frame. Frame generation device. Generating a frame basic header including a physical layer protocol (PHY) header, a media access control (MAC) header, and a first header check sequence (HCS); And Generating a frame selection header comprising a fixed length MAC subheader and a second HCS How to create a frame. The method of claim 11, Generating the frame selection header, Generating a MAC header of fixed length by adding a padding subheader to the subheaders upon receiving subheaders; And Generating the second HCS for error detection of a MAC subheader; How to create a frame. The method of claim 12, Scrambling the MAC subheader of the fixed length and the second HCS to generate the frame selection header. How to create a frame. The method of claim 12, The padding subheader is Subheader whose length information value of the corresponding sub-frame is zero How to create a frame. The method of claim 11, Generating the frame basic header, Receiving PHY information to generate the PHY header; Receiving MAC information to generate the MAC header; Generating the first HCS for error detection of the PHY header and the MAC header; Scrambled the MAC header and the first HCS; And Generating the frame basic header including the PHY header, the scrambled MAC header, and the scrambled first HCS. How to create a frame. The method of claim 11, FEC encoding each of the frame basic header and the frame selection header to generate respective FEC parity bits. How to create a frame. The method of claim 16, The FEC encoding is Reed-Solomon (RS) coding or Low Density Parity Check (LDPC) coding How to create a frame. The method of claim 11, The frame, And a payload including the frame basic header, the FEC parity bit of the frame basic header, the frame selection header, the FEC parity bit of the frame selection header, and a clustered sub-frame. How to create a frame. Receiving protocol header information to generate a variable length protocol header; And Adding a padding bit having a value of 0 to the variable length protocol header, converting the same into a fixed length protocol header having a predetermined fixed length, and inserting the same into a frame; How to create a frame. The method of claim 19, Forward error correcting (FEC) encoding the fixed length protocol header including the padding bits to generate an FEC parity bit, and inserting the FEC parity bit into the frame. How to create a frame.

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