Abstract:
A high-speed Galois Counter Mode-Advanced Encryption Standard (GCM-AES) block cipher apparatus and method is provided. The apparatus can operate at a low clock frequency of 125 MHz and provide a 2 Gbps link encryption function in an Optical Line Termination (OLT) and an Optical Network Unit (ONU) of an Ethernet Passive Optical Network (EPON). 11-round block cipher of 128-bit input data is implemented using an 8-round Counter-AES (CTR-AES) block cipher module and a 3-round CTR-AES block cipher module, so that it is possible to provide a 1 Gbps link security function for an input frequency of 62.5 MHz and a 2 Gbps link security function for an input frequency of 125 MHz.

Description:
RELATED APPLICATION  
       [0001]     The present application is based on, and claims priority from, Korean Application Number 2004-104925, filed Dec. 13, 2004, the disclosure of which is incorporated by reference herein in its entirety.  
       BACKGROUND OF THE INVENTION  
       [0002]     1. Field of the Invention  
         [0003]     The present invention relates to a high-speed Galois Counter Mode-Advanced Encryption Standard (GCM-AES) block cipher apparatus and method, which makes it possible to operate at a low clock frequency of 125 MHz and provide a 2 Gbps link security function in an Optical Line Termination (OLT) and an Optical Network Unit (ONU) of an Ethernet Passive Optical Network (EPON).  
         [0004]     2. Description of the Related Art  
         [0005]     The US NIST (National Institute of Standards and Technology) has selected a next-generation symmetric key block cipher algorithm “Rijndael” as an Advanced Encryption Standard (AES) algorithm. The AES is an encryption standard in which encryption is performed for a fixed block size of 128 bits during 11 rounds using respective round keys of 128 bits. Processing and computation of the AES is performed through 9 repetitive rounds and the final round after AddRound-Key. Each of the rounds other than the final round includes ByteSub, ShiftRow, MixColumn, and AddRound-key module. The AES block cipher algorithm supports the Electronic Codebook (ECB), Cipher Block Chaining (CBC), Cipher Feedback (CFB), Offset Feedback (OFB), or Counter (CTR) modes according to an operation mode. The CTR mode provides the fastest encryption function and provides the encryption function even for a variable-length data.  
         [0006]     IEEE802.3ah EFM complies with the MAC security standard proposed in the IEEE802.1AE working group to provide a link security function in an Ethernet Passive Optical Networks (EPON). The IEEE802.1AE working group has adopted the operation mode of a GCM-AES block cipher to provide both data encryption and frame authentication functions in the link layer.  
         [0007]     The adopted GCM-AES block cipher can provide either the authenticated encryption/decryption or authentication tag generation/verification function according to an operation. The GCM-AES block cipher provides a high-speed encryption function for a variable-length MAC frames using a 128-bit CTR-AES block cipher algorithm, and provides a frame authentication function using a universal hashing algorithm. Also, current the GCM-AES is free of intellectual property restrictions.  
         [0008]      FIG. 1  is a block diagram of a conventional GCM-AES block cipher apparatus.  
         [0009]     As shown in  FIG. 1 , the conventional GCM-AES block cipher apparatus B 100  comprises an 11-round key expansion module  101 , an 11-round CTR-AES block cipher module  102 , and an 8-round GF multiplication module  103 .  
         [0010]     In  FIG. 1 , a 32/128-bit converter  100  and a 128/32-bit converter  104  are data conversion interface modules for providing an interface between a MAC module and a MAC controller module.  
         [0011]     The key expansion module  101  generates 11 round keys of 128 bits (s 102 ) for use in CTR-AES block cipher using a 128-bit key that is received every MAC frame. The CTR-AES block cipher module  102  encrypts a 128-bit data block s 101  of a MAC frame received from the 32/128-bit converter  100  using the 128-bit round keys s 102  received from the key expansion module  101  (s 103 ). Here, the GF multiplication module  103  generates an authentication value of the MAC frame using a hash key calculated from the round keys.  
         [0012]     A clock frequency Fio of input/output data is used to pass data in an EPON OLT/ONU, and a clock frequency Fc, which is four times the clock frequency Fio, is used in the GCM-AES block cipher apparatus B 100 .  
         [0013]     32-bit data s 100  are input to the 32/128-bit converter  100  at the Fio clock frequency. The 32/128-bit converter  100  multiplexes the four input 32-bit data s 100  to convert them into a 128-bit data s 101  at the Fc clock frequency. Such 128-bit data s 101  are encrypted in the GCM-AES block encryption apparatus B 100  at the Fc clock frequency. The encrypted 128-bit data are input to the 128/32-bit converter  104 . The 128/32-bit converter  104  demultiplexes the input 128-bit data into 32-bit data s 104  at the Fio clock frequency.  
         [0014]     The GCM-AES block encryption apparatus B 100  performs its processing during 11 rounds in a pipeline manner. However, in order to encrypt consecutively input data blocks, the converters  100  and  104  requires an Fc clock frequency, which is four times the input/output data clock frequency Fio according to an inequality shown in Expression 1, since the converters  100  and  104  must maintain the relationship of multiples of 4 between Fio clock frequency and Fc clock frequency for clock synchronization.  
                   Fc   Fio     ×   cycle     ≥     11   ⁢           ⁢   rounds       ,           [     Expression   ⁢           ⁢   1     ]             
 
         [0015]     where  
         cycle   =     128   Wd       ,       
 
 Fio×Wd=EPON Data Rate, “Fc” is the clock frequency of the GCM-AES block cipher module, “Fio” is the input/output data clock frequency, “Wd” is an input/output data bus width, and “cycle” is the number of clock cycles required to input 128 bits. 
 
         [0016]     Accordingly, as shown in  FIG. 2 , if 62.5 MHz is used as the input/output data clock frequency in a 2 Gbps EPON OLT/ONU, a GCM-AES block cipher apparatus  201  uses a clock frequency of 250 MHz, which is four times the input/output data clock frequency.  
         [0017]     In the conventional GCM-AES block cipher apparatus, the relationship between the data bus width and the clock frequency in the 1 Gbps or 2 Gbps EPON OLT/ONU is shown in Table 1.  
                                                                         TABLE 1                       Data Rate   Fc   Fio   Wd   Fc/Fio(a)   Cycle(b)   Round(a)*(b)                                1 Gbps   125 MHz   31.25   MHz   32bits   4   4   16           125 MHz   62.5   MHz   16bits   2   8   16           125 MHz   125   MHz    8bits   1   16   16       2 Gbps   250 MHz   31.25   MHz   64bits   8   2   16           250 MHz   62.5   MHz   32bits   4   4   16           250 MHz   125   MHz   16bits   2   8   16           250 MHz   250   MHz    8bits   1   16   16           125 MHz   125   MHz   16bits   1   8   8           125 MHz   62.5   MHz   32bits   2   4   8           125 MHz   31.25   MHz   64bits   4   2   8                  
 
         [0018]     As shown in Table 1, the conventional GCM-AES block cipher structure must use a clock frequency of 250 MHz in the 2 Gbps EPON system environment in order to meet a requirement of more than 11 rounds under any circumstance. Using such a high clock frequency causes much difficulty in actual hardware implementation.  
         [0019]      FIG. 3  is a signal process diagram illustrating an encryption method in the conventional GCM-AES block cipher apparatus. In  FIG. 3 , a conventional GCM-AES block cipher module B 300  performs three main steps of processing (B 301 , B 302  and B 303 ) for a variable-length MAC frames.  
         [0020]     At the first step (B 301 ), the key expansion module  101  expands a 128-bit key s 300  received together with a MAC frame to produce 11 round keys for use s 301  in encryption of the MAC frame ( 300 ), and the 11-round CTR-AES encryption module  102  generates a hash key value s 307  from the generated round keys s 301  ( 301 ).  
         [0021]     The hash key value is calculated using an equation expressed in Expression 2. 
 
 H=E   11rounds ( K, 0 128 ),  [Expression 2]
 
         [0022]     Where “K” denotes the round key and “H” denotes the hash key value.  
         [0023]     While the first step (B 301 ) is performed, 32-bit input data of the MAC frame are multiplexed into a 128-bit data in the 32/128-bit converter  100 .  
         [0024]     Next, at the second step (B 302 ), 128-bit data blocks of the MAC frame are encrypted or decrypted, and an authentication value of the encrypted data blocks is also produced or an authentication value of the decrypted data blocks is compared with input authentication value.  
         [0025]     In order to generate the authentication value, the GE multiplication module  103  receives the first 128-bit data block of the MAC frame as an Additional Authenticated Data (AAD) value s 308 , and computes a product s 309  of the received ADD value and the hash key value s 307  produced at the first step (B 301 ) ( 305 ). The product s 309  is XORed with an encrypted value s 306  of the input data block ( 306 ), and the XOR result value is feedback to the GF multiplication module  103  to repeat the computation.  
         [0026]     In addition, in order to perform encryption, a 96-bit random Initial Vector (IV) value s 302  is combined with a 32-bit data block counter ( 302 ) to produce a 128-bit counter value s 303 . The 128-bit counter value s 303  is input to the 11-round CTR-AES block encryption module  102  and is then encrypted using the round key s 301  calculated at the first step (B 301 ) ( 303 ). The encrypted value s 304  is XORed with a 128-bit data block s 305  ( 304 ) to be output as an encrypted value s 306  of the input data blocks.  
         [0027]     This second step (B 302 ) is repeated for all 128-bit data blocks of the MAC frame as shown in Expression 3. 
 
 Y   o   =IV ∥0 31   ,Y   i   =INCR ( Y   i-1 ) for  i= 1 , . . . , n  
 
 C   i   =P   i   ⊕E   11rounds ( K,Y   i ) for  i= 1 , . . . , n− 1 
 
 C*   n   =P*   n   ⊕MSB ( E   11rounds ( K,Y   n ))  [Expression 3]
 
         [0028]     where “Y i ” denotes the 128-bit counter value, “P i ” denotes the 128-bit input data block, “C i ” denotes the encrypted value of the input data block P i , and “C* n ” denotes data encryption of a final bit string remaining after the MAC frame is divided into 128-bit data blocks.  
         [0029]     Finally, at the third step (B 303 ), the GF multiplication module  103  receives the authentication value s 310  repeatedly calculated for the data block s 306  encrypted at the second step (B 302 ), and performs two multiplications of the received authentication value s 310  and the hash key value to calculate a final authentication value s 316 .  
         [0030]     Specifically, the 11-round CTR-AES block cipher module  102  receives the 128-bit counter value s 311  obtained by combining a 96-bit IV value and a 32-bit zero value, and encrypts the received 128-bit counter value s 311  into a round key s 301  (s 312 ). Then, the GF multiplication module  103  computes a product of the hash key value s 307  and the authentication value s 310  calculated at the second step B 302  ( 308 ), and then performs an XOR operation between the product and a value s 314  obtained by combining the encrypted value of the last data block and the AAD value ( 309 ). The GF multiplication module  103  again computes a product of the XOR result value and the hash key value s 307  ( 310 ), and then performs an XOR operation ( 311 ) between the product and the encrypted value s 312  obtained at the third step (B 303 ) to calculate a final authentication value ICV (s 316 ).  
         [0031]     The calculated final authentication value ICV is expressed by an equation shown in Expression 4. 
 
 ICV=MSB ( GHASH ( H,A,C )⊕ MSB ( E   11rounds ( K,Y   0 ))  [Expression 4]
 
         [0032]     As described above, since the conventional GCM-AES cipher apparatus must operate at a frequency, which is four times the input/output data clock frequency, it must operate at a high clock frequency of 250 MHz in a 2 Gbps EPON environment. This makes it difficult to implement an EPON OLT/ONU through an FPGA. In addition, even if an EPON OLT/ONU is developed through an ASIC, a 0.13 μm process must be performed to guarantee the processing of data at a high clock frequency, which increases chip costs and makes it difficult to implement hardware.  
         [0033]     Thus, to easily implement the module in the hardware of an EPON OLT/ONU, it is necessary to provide a new structure of the GCM-AES block cipher module that can operate at a lower frequency.  
       SUMMARY OF THE INVENTION  
       [0034]     Therefore, the present invention has been made in view of the above problems, and it is an object of the present invention to provide a high-speed GCM-AES block cipher apparatus which is applied to an OLT/ONU in a 1 Gbps or 2 Gbps EPON and which can operate at a lower clock frequency to provide a 1 Gbps or 2 Gbps link security function.  
         [0035]     In accordance with one aspect of the present invention, the above and other objects can be accomplished by the provision of a high-speed GCM-AES block cipher apparatus for providing a data authenticated encryption/decryption or only a frame authentication tag generation/verification function in an EPON environment, the apparatus comprising: a key expansion module for generating 11 round keys of 128 bits for use in encryption using a 128-bit key that is input every MAC frame; an 8-round CTR-AES block encryption module for encrypting 128 bit data blocks of a MAC frame in a pipeline manner during 8 rounds using 0th to 7th round keys of the 11 round keys generated by the key expansion module; a 3-round CTR-AES block encryption module for encrypting the 128-bit data blocks encrypted in the 8-round CTR-AES block encryption module during 3 rounds using 8th to 10th round keys of the 11 round keys generated by the key expansion module; and a GF multiplication module for calculating an authentication parameter of the MAC frame from a hash key calculated using the round keys generated by the key expansion module.  
         [0036]     In accordance with another aspect of the present invention, there is provided a high-speed GCM-AES block cipher method comprising: expanding a 128-bit key, which is input every MAC frame, into round keys required for 11-round encryption; calculating a hash key value using the round keys; performing a first encryption step for encrypting 128-bit data blocks of a MAC frame using the 128-bit round keys during 8 rounds; performing a second encryption step for encrypting the encrypted data blocks using the expanded 128-bit round keys during 3 rounds; and calculating an authentication parameter of the MAC frame using the calculated hash key value and a result of the second encryption step.  
         [0037]     Preferably, the expansion of the 128-bit key comprises expanding a 128-bit key, which is input every MAC frame, into 0th to 10th round keys; and providing the expanded 0th to 7th round keys to the first encryption step and providing the expanded 8th to 10th round keys to the second encryption step.  
         [0038]     In this manner, the high-speed GCM-AES block cipher apparatus provides a frame authenticated encryption function and a frame authentication function for a 1 Gbps or 2 Gbps EPON. 
     
    
     BRIEF DESCRIPTION OF THE DRAWINGS  
       [0039]     The above and other objects, features and other advantages of the present invention will be more clearly understood from the following detailed description taken in conjunction with the accompanying drawings, in which:  
         [0040]      FIG. 1  is a block diagram of a conventional GCM-AES block cipher apparatus;  
         [0041]      FIG. 2  is a diagram illustrating an internal interface structure of a 2 Gbps EPON OLT/ONU when the conventional GCM-AES block cipher apparatus is applied to the 2 Gbps EPON OLT/ONU;  
         [0042]      FIG. 3  is a signal process diagram illustrating an encryption method in the conventional GCM-AES block cipher apparatus;  
         [0043]      FIG. 4  is a block diagram of a high-speed GCM-AES block cipher apparatus according to the present invention;  
         [0044]      FIG. 5  is a diagram illustrating an internal interface structure of a 2 Gbps EPON OLT/ONU when the high-speed GCM-AES block cipher apparatus according to the present invention is applied to the 2 Gbps EPON OLT/ONU; and  
         [0045]      FIG. 6  is a signal process diagram illustrating a high-speed GCM-AES block cipher method according to the present invention. 
     
    
     DESCRIPTION OF THE PREFERRED EMBODIMENTS  
       [0046]     Preferred embodiments of the present invention will now be described in detail with reference to the accompanying drawings.  
         [0047]      FIG. 4  is a block diagram of a high-speed GCM-AES block cipher apparatus according to the present invention.  
         [0048]     As shown in  FIG. 4 , the high-speed GCM-AES block cipher apparatus B 400  according to the present invention comprises an 11-round key expansion module  400 , an 8-round CTR AES block cipher module  401 , a 3-round CTR-AES block cipher module  402 , and an 8-round GF multiplication module  403 .  
         [0049]     The present invention is characterized in that 11-round CTR-AES block cipher is implemented using the 8-round CTR-AES block cipher module  401  and the 3-round CTR-AES block cipher module  402 , thereby reducing the maximum number of rounds and thus reducing the clock frequency.  
         [0050]     In the high-speed GCM-AES block cipher apparatus B 400 , the key expansion module  400  generates 11 round keys of 128 bits s 402  and s 404  for use in encryption in the two CTR-AES block cipher modules  401  and  402  using a 128-bit key that is input every MAC frame. In the 11 round keys, 0th to 7th round keys s 402  are transferred to the 8-round CTR-AES block cipher module  401 , the remaining 8th to 10th round keys s 404  are transferred to the 3-round CTR-AES block cipher module  402 .  
         [0051]     The 8-round CTR-AES block cipher module  401  encrypts a 128-bit data block using the 0th to 7th round keys s 402  generated by the key expansion module  400  during 8 rounds. Then, the 3-round CTR-AES block cipher module  402  again encrypts the 128-bit data blocks  405  encrypted in the 8-round CTR-AES block cipher module  401  using the 8th to 10th round keys s 404  generated by the key expansion module  400  during 3 rounds.  
         [0052]     The 8-round CTR-AES block cipher module  401  and the 3-round CTR-AES block cipher module  402  operate in parallel with each other. Here, the GF multiplication module  403  generates an authentication value of the MAC frame using a hash key.  
         [0053]     The high-speed GCM-AES block cipher apparatus B 400  configured as described above uses an Fc clock frequency s 408 , which is twice a Fio clock frequency s 400  and s 407  of the input MAC frame. Since the maximum number of rounds of the two CTR-AES block cipher modules  401  and  402  provided in the high-speed GCM-AES block cipher module B 400  is 8, it is possible to use an Fc clock frequency, which is twice the Fio clock frequency as expressed by an inequality shown in Expression 5 when sequentially encrypting data blocks through the high-speed GCM-AES block cipher module B 400 .  
                   Fc   Fio     ×   cycle     ≥     8   ⁢           ⁢   rounds       ,           [     Expression   ⁢           ⁢   5     ]             
 
         [0054]     Where “cycle” is the number of clock cycles required to input 128 bits,  
         cycle   =     128   Wd       ,       
 
 “Wd” is an input/output data bus width, Fio×Wd=EPON Data Rate(Wd=32), “Fc” is the clock frequency of the high-speed GCM-AES block cipher module, and “Fio” is the input/output data clock frequency. 
 
         [0055]      FIG. 5  is a diagram illustrating an internal interface structure of a 2 Gbps EPON OLT/ONU when the high-speed GCM-AES block cipher apparatus according to the present invention is applied to the 2 Gbps EPON OLT/ONU.  
         [0056]     As shown in  FIG. 5 , if 62.5 MHz is used as a clock frequency of input/output data in the 2 Gbps EPON OLT/ONU, the high-speed GCM-AES block cipher apparatus  501  uses a clock frequency of 125 MHz, which is twice the input/output data clock frequency.  
         [0057]     The relationship between the data bus width “Wd” and the clock frequency “Fc” in the high-speed GCM-AES block cipher apparatus according to the present invention in the 1 Gbps or 2 Gbps EPON OLT/ONU is shown in Table 2.  
                                                                             TABLE 2                       Data Rate   Fc   Fio   Wd   Fc/Fio(a)   Cycle(b)   Round(a)*(b)                                1 Gbps   62.5   MHz   31.25   MHz   32bit   2   4   8           62.5   MHz   62.5   MHz   16bit   1   8   8       2 Gbps   125   MHz   31.25   MHz   64bit   4   2   8           125   MHz   62.5   MHz   32bit   2   4   8           125   MHz   125   MHz   16bit   1   8   8                  
 
         [0058]     As shown in Table 2, the high-speed GCM-AES block cipher apparatus  501  according to the present invention, which is used to implement link security in the environment of the 2 Gbps EPON system, can operate at a clock frequency of 125 MHz in any case. If the clock frequency is reduced in this manner, it is easy to implement the block cipher apparatus through an FPGA and an ASIC, and it is also possible to guarantee the data that is transferred at the clock frequency.  
         [0059]     A high-speed GCM-AES block cipher method according to the present invention, which uses the above cipher apparatus, comprises expanding a 128-bit key, which is input every MAC frame, into round keys required for 11-round encryption; calculating a hash key value using the round keys; performing a first encryption step for encrypting 128-bit data blocks of a MAC frame using the 128-bit round keys during 8 rounds; performing a second encryption step for encrypting the encrypted data blocks using the expanded 128-bit round keys during 3 rounds; and calculating an authentication parameter of the MAC frame using the calculated hash key value and a result of the second encryption step.  
         [0060]     That is, according to the present invention, the 11-round encryption of input data blocks is performed through the first encryption step and the second encryption step.  
         [0061]      FIG. 6  is a signal process diagram illustrating a high-speed GCM-AES block cipher method according to the present invention. In  FIG. 6 , the high-speed GCM-AES block cipher method according to the present invention can be divided mainly into a first step (B 601 ), a second step (B 602 ), and a third step (B 603 ), listed in the order in which they are performed. The key expansion is implemented through the first step (B 601 ), the first and second encryption steps are implemented through the second step (B 602 ), and the authentication parameter calculation is implemented through the first to third steps (B 601  to B 603 ).  
         [0062]     The first step (B 601 ) is the step of generating a round key required for encryption, in which the key expansion module  400  generates 11 round keys s 601  and s 602  using a 128-bit key s 600  that is received every MAC frame from the 32/128-bit converter  100  ( 600 ), and the 8-round CTR-AES block cipher module  401  and the 3-round CTR-AES block cipher module  402  calculate a hash key value s 608  for use in frame authentication using the generated round keys s 601  and s 602  as shown in Expression 6 ( 602  and  603 ). 
 
 H=E   3rounds ( K′,E   8rounds ( K, 0 128 )),  [Expression 6]
 
         [0063]     Where “K′” denotes 8th to 10th round keys s 602 , and “K” denotes 0th to 7th round keys s 601 .  
         [0064]     If the round key and the hash key are generated as described above, the method proceeds to the second step (B 602 ) in which 128-bit data blocks of the MAC frame are encrypted using the two CTR-AES block cipher modules  401  and  402 , while an authentication value of the MAC frame is produced using the GF multiplication module  403 .  
         [0065]     The following is a more detailed description of how the second step (B 602 ) is performed. The GF multiplication module  403  receives the first 128-bit data block of the MAC frame as an Additional Authenticated Data (AAD) value s 609 , and computes a product s 610  of the received ADD value and the hash key value s 608  produced at the first step (B 601 ) ( 608 ). The product s 610  is XORed with an encrypted data block value s 607  ( 609 ), and the XOR result value s 611  is input back to the GF multiplication module  403  to repeat the computation.  
         [0066]     In the mean time, a 96-bit random Initial Vector (IV) value s 603  is combined with a 32-bit data block counter ( 604 ) to convert the 96-bit random IV value s 603  into a 128-bit counter value s 604 . The 128-bit counter value s 604  is input to the 8-round CTR-AES block cipher module  401 . The 8-round CTR-AES block cipher module  401  calculates an encrypted value of the 128-bit counter value s 604  using the 128-bit counter value s 604  and the round key s 601  calculated at the first step (B 601 ) ( 605 ). The encrypted value calculated in the 8-round CTR-AES block cipher module  401  is input back to the 3-round CTR-AES block cipher module  402  so that it is encrypted during the remaining 3 rounds of the 11 rounds of encryption ( 606 ).  
         [0067]     An encrypted value s 606  output from the 3-round CTR-AES block cipher module  402  is XORed with the 128-bit input data block s 605  ( 607 ) to be output as an encrypted value s 607  of the input data blocks.  
         [0068]     The second step (B 602 ) is repeated until all data blocks of the variable-length MAC frame are encrypted. This procedure is represented by Expression 7. 
 
 Y   o   =IV ∥0 31   , Y   i   =INCR ( Y   i-1 ) for  i= 1 , . . . , n  
 
 C   i   =P   i   ⊕E   3rounds ( K′,E   8rounds ( K,Y   i )for  i =1 , . . . , n− 1 
 
 C*   n   =P*   n   ⊕MSB ( E   3rounds ( K′,E   8rounds ( K, Y   n ))  [Expression 7]
 
         [0069]     where “Y i ” denotes the 128-bit counter value, “P i ” denotes the 128-bit input data block, “C i ” denotes the encrypted value of the input data block P i , and “C* n ” denotes data encryption of a final bit string remaining after the MAC frame is divided into 128-bit data blocks.  
         [0070]     If encryption is completed for all of the data blocks input at the second step (B 602 ), a final authentication parameter “ICV” is calculated for the encrypted MAC frame at the third step (B 603 ).  
         [0071]     More specifically, at the third step (B 603 ), the 8-round and 3-round CTR-AES block cipher modules  401  and  402  perform 11-round encryption of 128-bit input data s 612 , obtained by combining a 96-bit IV value and a 32-bit zero value, using the round keys s 601  and s 602  ( 610  and  611 ).  
         [0072]     Then, the GF multiplication module  403  computes a product s 614  of the hash key value s 608  calculated at the first step-(B 601 ) and the authentication value s 611  calculated at the second step (B 602 ) ( 612 ), and then performs an XOR operation between the product s 614  and a value s 615  obtained by combining the encrypted value of the last data block and the AAD value ( 613 ). The GF multiplication module  403  again computes a product of the XOR result value and the hash key value s 608  ( 614 ), and then performs an XOR operation ( 615 ) between the product and the encrypted value s 613  of the 3-round CTR-AES block cipher module  402 , which is obtained at the third step (B 603 ), to output a final authentication value ICV of 128 bits (s 617 ).  
         [0073]     The final authentication parameter ICV output at the third step (B 603 ) is expressed by an equation shown in Expression 8. 
 
 ICV=MSB ( GHASH ( H, A, C )⊕ MSB ( E   3rounds ( K′,E   8rounds ( K,Y   0 ))) [Expression 8]
 
         [0074]     As apparent from the above description, the present invention provides a high-speed GCM-AES block cipher module which implements 11-round CTR-AES cipher through an 8-round CTR-AES block cipher module and a 3-round CTR-AES block cipher module that are connected in parallel, thereby making it possible to implement a link security function at a speed of 2 Gbps using a lower clock frequency. The implementation using the lower clock frequency makes it easy to develop hardware of the high-speed GCM-AES block cipher module through an FPGA or ASIC.  
         [0075]     Although the preferred embodiments of the present invention have been disclosed for illustrative purposes, those skilled in the art will appreciate that various modifications, additions and substitutions are possible, without departing from the scope and spirit of the invention as disclosed in the accompanying claims.