BACKGROUND Data transmission 10 (FIG. 1) involves a transfer of information known as data between a sender 12 and a receiver 14. Often, data transmission 10 includes information transmitted as digital bits of ones and zeros, represented here by m,,-, to mo, and referred to as a message M.

In a perfect world, message M transmits free of errors.

Unfortunately, errors are often introduced though medium 16 by which message M travels from sender 12 to receiver 14 (e. g. , medium 16 may be any combination of wire, cable, fiber-optic, air, or link layer devices). One method for detecting the presence of errors in message M employs cyclic redundancy codes.

Cyclic redundancy codes treat groupings of digital bits like message M as a polynomial where each bit in the grouping represents a coefficient in the polynomial Xn-l + Xn- + X0. For example, a group of eight bits 11001101 may be represented by polynomial X7 + X6 + X3 + X2 + 1 (i. e., 1*X7 + i*x 6 + 0*xi + 0*X4 + 1*X3 + 1*X2 + 0*X1 + 1*X0).

These polynomials form an algebraic object known as a commutative ring with coefficients in Z/p where Z are the integers and p is a prime number, here 2, also known as {0, 1} modulo 2. A non empty set R together with two binary operations {+*} is called a ring if (R+) is an abelian

group, (R*) is a semi group and the distributive laws are obeyed, (i. e. a* (b+c) = a*b+a*b).

In polynomial rings, there are no carries or borrows from one coefficient to the next. In arithmetic modulo 2, addition and subtraction are identical and may be implemented with exclusive-or. For example: Division of polynomials represented as groups of bits is completed in a manner similar to binary division except subtraction is done in modulo2. A divisor will go into'a dividend if the dividend polynomial is of the same degree as the divisor polynomial (i. e. , the divisor and dividend share at least the same most significant bit).

A cyclic redundancy code may be obtained by calculating the remainder for message M divided by a generator polynomial P. This remainder is called a cyclic redundancy code ("CRC").

To obtain a CRC for a message M, the group of bits to be divided by generator polynomial P may include appended zero-bits 17. Zero-bits 17 are equal in number to the degree of generator polynomial P. Thus, the CRC of a message M = 10111000 having three appended zero-bits 17 based on a generator polynomial P = X3+1 = 1001 of degree three (i. e. , where X3 is the most significant bit of polynomial P) may be calculated as follows: 00010101 1001 10111000 ---M including 3 appended zero 1001 bits for Deg (P) =3 P 0101 0000 1010 r

1001 0110 0000 1100 remainder 1001 101 = M (modulo) P = MOD (M, P) = CRC.

The resulting remainder, shown as CRC 18, may be appended to message M, replacing zero bits 17, to create a message M'. Sender 12 transmits message M'via medium 16 to receiver 14 as data transmission 10.

Upon receipt, receiver 14 divides message M'by the same generator polynomial P to obtain a CRC for M'and check the validity of data transmission 10. If the resulting remainder is zero (i. e. , CRC = M' (modulo) P = 0), the integrity of data transmission 10 is confirmed. For example: 00010101 1001|10111101 M'with CRC = 101 appended/+ 1001 P 01011 0000 1011X r 1001 0100+ 0000 1001 remainder 1001 "000 = M' (modulo) P = 0 = valid data.

If the remainder of message M'divided by polynomial P is not zero (i. e. , CRC = M' (modulo) P + 0), data transmission 10 contains one or more errors. For example: 00010110 1001110101101-4 M'with error 0 introduce, dt + 1001 to message M' P 0111 0000 1111 1001 --- r

1100 1001 1011 remainder 1001 '010 = M' (modulo) P + O = error.

DESCRIPTION OF DRAWINGS FIG. 1 shows a prior art block diagram of a data transmission employing cyclic redundancy codes.

FIG. 2 shows a process for obtaining a CRC where a message M is separated into a plurality of segments.

FIG. 3 shows a CRC generator for obtaining a CRC of a message according to the process in FIG. 2.

FIG. 4 shows the CRC generator of FIG. 3 separated into four segments.

FIG. 5 shows a CRC generator for obtaining a CRC of a message M according to the process in FIG. 2.

FIG. 6 shows a modulo unit for obtaining a remainder of a message using a reciprocal approximation of a generator polynomial.

FIG. 7 shows the CRC generator in FIG. 3 using the modulo unit in FIG. 6.

FIG. 8 shows a CRC generator for updating a CRC of a message M where a portion of message M has been adjusted..

FIG. 9 shows the CRC generator in FIG. 8 operating on an adjusted segment of message M.

FIG. 10 is a view of computer hardware used to implement an embodiment of the invention.

Like reference symbols in the various drawings indicate like elements.

DETAILED DESCRIPTION Process 20 (FIG. 2) obtains a CRC for a message M based on a generator polynomial P.

Process 20 includes separating (201) a message M into a plurality of message segments Ms ; moduloing (defined below) (203) the message segments by a generator polynomial P, if needed, to obtain a remainder R for each segment; multiplying (205) the remainder R for each segment by an appropriate segment-constant C to obtain a segment-remainder SR for each segment Mg ; accumulating (207) the segment- remainders SR for each segment Ms to obtain an accumulated- remainder AR for message M; and moduloing (209) the accumulated-remainder by generator polynomial P, if needed, to obtain the CRC for message M.

Separating (201) message M into a plurality of message segments MS includes parsing message M so that: M = Ms-1*Xn*(s-1) + Ms-2*Xn*(s-20... + M1*Xn(1) + M'o*Xn (o) where s is the number of segments into which message M is separated, n is the number of bits in each segment, X is the position of each segment in message M, and MS are the individual segments of message M. If the number of bits is n, then X is of the form X= [1000... 0] where there are n zeroes, n+1 elements, and X is of degree n. Multiplying M by X will shift the message left by n bits. Multiplying M by x2 will shift the message by 2n bits (and so on).

Moduloing (203) includes obtaining a remainder R for each message segment MS by dividing segment MS by generator polynomial P if the degree of the most significant bit of segment MS is the same as or greater than the degree of the most significant bit of polynomial P. If the degree of segment MS is less than the degree of polynomial P (i. e., where the most significant bit of Ms is smaller than the most significant bit of polynomial P) moduloing (203) is not needed since the remainder for message segment Ms equals segment Mg itself. In alternate embodiments moduloing (203) may be accomplished by multiplying message segment MS by a

reciprocal approximation for polynomial P, rather than dividing segment MS by polynomial P, to obtain remainder R for message segment Mg. The operation of multiplication by reciprocal approximation to obtain a remainder R is discussed in connection with FIG. 6 below.

Multiplying (205) includes obtaining segment-constant C (defined below) for each message segment Ms and multiplying each segment-constant C by its remainder R to obtain a segment-remainder SR for each message segment. Segment- constants C may be obtained based on the position X of message segment Mg in message M modulo generator polynomial P or modulo a field extension of P.

Accumulation (207) includes adding the segment- remainders SR for each message segment MS to obtain an accumulated-remainder AR for message M.

Moduloing (209) includes dividing accumulated-remainder AR by generator polynomial P, or multiplying AR by a reciprocal approximation of generator polynomial P, to obtain a CRC for message M. However, if the degree of accumulated-remainder AR is less than the degree of polynomial P, moduloing (209) is not needed since the remainder (i. e. , the CRC) of message M is accumulated- remainder AR.

FIG. 3 shows an implementation of process 20 for calculating a CRC of message M based on generator polynomial P. For example: if M = 10111000, (Message 10111 with with 3 zero- bits appended) s = 2, n = 4, and P = 1001 = (Deg (P) =3) ; then M may be separated as

Ms-1 = M1 = 1011 = segment 33, Xn*(s-1) = X4 = 10000, MS-2 = Mo = 1000 = segment 35, xn* (s-2) = X0 = 00001; where M = 1011*10000 + 1000*00001 = 10111000.

CRC generator 30 obtains a CRC for message M based on generator polynomial P, where the CRC for message M is the remainder of message M divided by polynomial P (i. e., CRC = M (modulo) P = MOD (M, P).

Typically, generator polynomials P are selected because they are irreducible (i. e. , they have no factors). Several examples of well-known generator polynomials include: LRCC8 = X8 + 1 = 100000001 ; CRC16 = x16 + x15 + X2 + 1 = 11000000000000101; SDLC = X16 + x12 + X5 + 1 = 10001000000100001; LRCC = x16 + 1 = 10000000000000001; CRC12 12 = x12 + xll + X3 + X2 + X + 1 = 1100000001111; and ETHERNET = x32 + x26 + X23 + X22 + x16 + Xll + X + 1 X2 + X + 1 = 100000100110000010000110110110111 ; where LRCC stands for Last Registration Control Channel.

CRC generator 30 includes modulo unit 32, multiplier 34, accumulator 36, and modulo unit 38. Here, modulo unit 32 has modulo units 32a and 32b implemented in hardware.

Modulo unit 32a divides message segment 33 by generator polynomial P to obtain remainder Ri+l (i. e., Ri+i = Ms_ 1(modulo) P = MOD (Ms-1, P) ). Modulo unit 32b divides message segment 35 by generator polynomial P to obtain remainder Ri (i. e. , Ri = Mg-2 (modulo) P = MOD (Ms-2, P)). For example: if M = 10111000, M,-, = M1 = 1011 = segment 33, Ms-2 = M0 = 1000 = segment 35, and P = 1001 ; then Ri+l = R, = M,-, (modulo) P = MOD (Ms-1, P) = 1011 (modulo) 1001 = 010, and Ri = R0 = Ms-2 (modulo) P = MOD (Ms-2, P) = 1000 (modulo) 1001 = ; where P 0001 mus_1 \ 0001 Ms-a 1001 J1011 1001 tlOOO P 1001 1001 010 = Ri+l 001 = Ri.

Multiplier 34 multiplies remainders Ri+l and Ri by segment-constants Ci+i and Ci to obtain segment-remainders SRi+l and SRi. Here, segment-constants Ci+1 and Ci are obtained by moduloing the position X of segments 33 and 35 in message M by generator polynomial P (i. e., Ci+1 = Xn*(i+1) (modulo) P and Ci = Xn*i (modulo) P). For example: if M = 10111000, P = 1001, s = 2, and n = 4; then for SRi+1 = SRi Ci+1 = C1 = X4*1 (modulo) P = 10000 (modulo) 1001 = 010, and SRi = SR0 Ci = C0 = X4*0 (modulo) P

= 0001 (modulo) 1001 = 001 ; where P 00010 X4 1 \ oooo * v1001 ! ioooo 1001 ! oooi P 1001 0000 0010 001 = Ci. 0000 010 = Ci+l Segment-constants Ci+i and Ci may be obtained in advance, based on a known segmentation of message M and stored in memory unit 39, which is accessible to CRC generator 30. In other embodiments, segment-constants Ci+1 and Ci may be obtained on the fly'within CRC generator 30 upon receipt of message M.

Multiplier 34 includes multipliers 34a and 34b.

Multiplier 34a multiplies remainder Ri+l by segment-constant Ci+i to obtain segment-remainder SRi+,. Multiplier 34b multiplies remainder Ri by segment constant Ci to obtain segment-remainder SRi. For example: if Ri+1 = 010, Ci+1 = 010 and (from above) Ri = 001, Ci = 001 ; then SRi+1 = Ri+i*Ci+i = 010*010 = 00100, and SRi = Ri*Ci = 001*001 = 00001; where Accumulator 36 adds segment-remainders SRi+1 and SRi together to obtain accumulated-remainder AR. For example: if

SRi+1 = SRi = 00100, (from above) SRi = SR0 = 00001 ; then AR = 00100+00001 = 00101, where 00100 + 00001 00101 = AR.

Modulo unit 38 obtains the CRC for message M by moduloing accumulated-remainder AR by generator polynomial P (i. e. , CRC = AR (modulo) P = MOD (AR, P) ). For example: if AR = 00101, and (from above) P-1001 ; then CRC = AR (modulo) P = MOD (AR, P) = 00101 (modulo) 1001 = 101, where Hence, process 20 implemented on CRC generator 30 obtains the same CRC for message M, here 10111000. In this example, moduloing AR by polynomial P is not needed since the degree of AR was less than the degree of P.

CRC generator 30 may be expanded to include enough components for obtaining the CRC for message M separated into N segments. FIG. 4 shows CRC generator 40 capable of operating on message M separated into four (4) segments 43, 45,47 and 49. For example: if M = M'= 10111101, (e. g. , message M in the example for FIG. 3 above having the

obtained CRC appended to it) s = 4, n = 2, and p = 2; then M may be separated as Ms-i = M3 = 10 = segment 43, Xn* (s-l) = X6 = 1000000, Ms-2 = M2 = 11 = segment 45, Xn* (s-2) = X4 = 10000, Ms-3 = M1 = 11 = segment 47, Xn*(s-3) = X2 = 100, Ms-4 = Mo = 01 = segment 49, Xn* (s-4) = X0 = 001 ; where M = 10*1000000 + 11*10000 + 11*100 + 01*001 = 10111101.

CRC generator 40 includes modulo unit 42, multipliers 44, accumulator 46, and modulo unit 48. Modulo unit 42 includes modulo units 42a, 42b, 42c and 42d. Modulo units 42a, 42b, 42c and 42d each operate to divide message segment 43,45, 47 and 49 by generator polynomial P to obtain remainders R3, R2, R1 and Ro. For example: if M = 10111101 = M', (from above) MS-l = M3 = 10 = segment 43, MS-2 = M2 = 11 = segment 45, Ms-3 = Mi = 11 = segment 47, Ms-4 = Mo = 01 = segment 49, and P = 1001 ; then Ri+3 = R3 = Ms-1 (modulo) P = 10 (modulo) 1001 = 10, Ri+2 = R2 = Ms-2 (modulo) P = 11 (modulo) 1001 = 11,

Ri+1 = R1 = Ms-3 (modulo) P = 11 (modulo) 1001 = 11, and Ri = Ro = Ms 4 (modulo) P = 01 (modulo) 1001 = 01.

Multiplier 44 multiplies remainders R3 to Ro by segment- constants C3 to Co to obtain segment-remainders SR3 to SRo.

Segment-constants C3 to Co correspond to each particular segment 43,45, 47 and 49 and may be obtained by moduloing the position of segments in message M by polynomial P.

(i. e. , C3 = Xn*(3) (modulo) P, C2 = Xn*2 (modulo) P, C1 = Xnl (modulo) P, Co = Xn° (modulo) P). For example: if M = 10111101, (from above) P = 1001, s = 4, and n = 2 ; then SR3 = SRi+3 C3 = Ci+3 = X2*3 (modulo) P = 1000000 (modulo) 1001 = 001; SR2 = SR0 C2 = Ci+2 = X2*2 (modulo) P = 10000 (modulo) 1001 = 010; SR1 = SR1 C1 = Ci+1 = X2*1 (modulo) P = 100 (modulo) 1001 = 100; and SRo = SRi Co = Ci+o= X° (modulo) P = 001 (modulo) 1001 = 001.

Segment constants C3 to Co may be obtained in advance based on the segmentation of message M and stored in a memory unit 39 (FIG. 3) accessible to CRC generator 40. In other embodiments C3 to Co may be obtained on the fly'

(i. e. , in real-time) within CRC generator 40 as it receives message M.

Multiplier 44 multiplies R3 by C3, R2 by C2, Rl by Cl, and Ro by Co to obtain segment-remainders SR3 to SRo. For example: if Ri+3 = R3 = 10, Ci+3 = C3 = 001; (from above) Ri+2 = R2 2 = 11, Ci+@ = C2 = 010 ; Ri+1 = R1 = 11, Ci+1 = C1 = 100; and Ri = Ro= 01, Ci = Cio = 001 ; then SR3 = R3*C3 = 10*001 = 0010 ; SR2 = R2*C2 = 11*010 =0110 ; SRi = R1*C1 = 11*100 = 1100 ; and SR0 = R0*C0 = 01*001 = 0001.

Accumulator 46 adds segment-remainders SR3 to SRo together to obtain accumulated-remainder AR. Here, accumulator 46 includes accumulators 46a, 46b and 46c, where accumulators 46a and 46b compute temporary accumulations Tu and To and accumulator 46c combines temporary accumulations Ti and To to obtain accumulated-remainder AR. For example: if SRi+3 = SR3 = 0010, (from above) SRi+2 = SR2 = 0110, SRi+1 = SRi = = 1100, and SRi = SRo = 0001 ; then - 0010+0110 = 0100, To = 1100+0001 = 1101, and AR = 0100+1101 = 1001.

Finally, modulo unit 48 obtains the CRC for message M, here message M'having the CRC obtained as described in FIG.

3 above, by moduloing accumulated-remainder AR by polynomial P (i. e. , CRC = AR (modulo) P = MOD (AR, P). For example: if AR = 1001, and (from above)

P = 1001; then CRC = AR (modulo) P = 1001 (modulo) 1001 = 0 where Thus, CRC generator 40 verifies the integrity of message M from the example in FIG. 3 where the CRC of message M was appended to form M'and transmitted to a receiver 14 who confirmed the transmission using CRC generator 40 (FIG. 4).

According to process 20, CRC generators 30 and 40 may be further simplified where the degree of message segments Ms are less than the degree of generator polynomial P (i. e., Deg (Ms) < Deg (P) ). As shown in the example for FIG. 4 above, the remainder R of Ms (modulo) P equals Ms when the degree of Ms is less than the degree of P. Thus, CRC generator 50 (FIG. 5) does not need an initial modulo unit (e. g. , 32 or 42) for obtaining a remainder Ri of message segments Ms that are of a degree less than the degree of generator polynomial P. For segments of degree equal to P (i. e. , Deg (Ms) Deg (P) ) modulo units 32 or 42 may be replaced by an xor, as Ms (modulo) P equals Ms~P.

Here, CRC generator 50 includes multiplier 54, accumulator 56, and modulo unit 58, which operate to obtain a CRC for message M separated into four segments 53,55, 57 and 59 of a degree less than the degree of generator polynomial P (i. e. , Deg (Ms) < Deg (P)). For example: if

M = 10111000, (M including 3 appended zero bits as in FIG.

3 above) s = 4, n = 2, and P = 1001; then Ms-i = M3 = 10 = segment 53, Xn*(s-1) = X6 = 1000000, Ms-2 = M2 = 11 = segment 55, Xn* (s-2) = X = 10000, Ms-3 = 10-segment 57, Xn*(s-3) = X2 = 100, Ms-4 = M0 = 00 = segment 59, Xn*(s-4) = X0 = 001; and M = 10*1000000 + 11*10000 + 10*100 + 00*001 = 10111000.

Multiplier 54 multiplies segments 53 to 59 by segment- constants C3 to Co to obtain segment-remainders SR3 to SRo.

Segment-constants C3 to Co may be obtained in advance or calculated on the fly'as described above. For example: if M = 10111000, (from above) P = 1001, s = 4, and n = 2; then SR3 = SRi+3 C3 = Ci+3 = X2*3 (modulo) P = 1000000 (modulo) 1001 = 001 ; SR2 = SRi+2 C2 = Ci+@ = X2*2 (modulo) P = 10000 (modulo) 1001 = 010 ; SR1 = SRi+l C1 = Ci+1 = X2*1(modulo) P = 100 (modulo) 1001 = 100 ; and SR0 = SRi C0 = Ci+0 = X4*0 (modulo) P = 001 (modulo) 1001 = 001.

Multiplier 54 multiplies M3 by C3, M2 by C2, Ml by Cl, and Mo by Co to obtain segment-remainders SR3 to SRo, since each message segment Ms equals its remainder R. For example : if Ms-l = M3 = 10, Ci+3 = C3 = 001, Ms-2 = M2 = 11, Ci+2 = C2 = 010, Ms3 = M1 = 10, Ci+1 = C1 = 100, and Mg-4 = M0 = 00, Ci = Cio = 001 ; then SR3 = M3*C3 = 10*001 = 0010, SR2 = M2*C2 = 11*010 = 0110, SR1 = M1*C1 = 10*100 = 1000, and SRo = Mo*Co = 00*001 = 0000.

Accumulator 56 adds segment-remainders SR3 to SRo together to obtain accumulated-remainder AR. Here, accumulator 56 includes accumulators 56a, 56b and 56c, where accumulators 56a and 56b compute temporary accumulations T and To and accumulator 56c combines temporary accumulations T, and To to obtain accumulated-remainder AR. For example: if SRi+3 = SR3 = 0010, (from above) SRi+2 = SR2 = 0110, SRi+1 = SR1 = 1000, and SRi i = SR0 = 0000 ; then Ti = 0010+0110 = 0100 ; T0 = 1000+0000 = 1000 ; and AR = 0100+1000 = 1100.

Finally, modulo unit 58 obtains a CRC for message M by moduloing accumulated-remainder AR by polynomial P. For example: if AR = 1100, and (from above) P = 1001 ;

then CRC = AR (modulo) P = 1100 (modulo) 1001 = 101; where Thus, CRC generator 50 obtains the same CRC for message M as calculated in the example in FIG. 3 above without needing modulo units 32 or 42 of FIGS 3 and 4.

Moduloing (e. g. , (203) and (209) ) may also be accomplished by multiplying message M (or message segment Ms) by a reciprocal approximation D of generator polynomial P and subtracting that result from message M (or message segment Ms) to obtain a remainder R. Moduloing by multiplication by reciprocal approximator RA may be obtained based upon the following relationships: RA = XP+d/P ; M/P = M*RA*1/Xp+ra (for 0<=Deg (M) <= p+ra); M = (M/P) *P + M (modulo) P; R = M (modulo) P = M- (M/P) *P; R = M (modulo) P = M- (M*D/Xp+ra) *P where Xp+ra is a polynomial having a most significant bit of degree p+ra (i. e. Deg (Xp+ra) =p+ra) ; p is the degree of generator polynomial P (i. e. , Deg (P) =p); ra is the degree of reciprocal-approximator RA (i. e. , Deg (RA) =ra); and the degree of message M, for which remainder R is sought, is greater than zero and less than or equal to p+ra (i. e. , 0 < Deg (M) <= p+ra). For example: if M = 10111000 (i. e., Deg (M) = 7), and P = 1001 (i. e., Deg (P) = 3).

then reciprocal-approximator RA would have a degree of at least four (4) for p+ra to be greater than or equal to the degree of M, here seven (7). Thus: if M = 10111000 (i. e. , Deg (M) = 7), P = 1001 (i. e. , Deg (P) = 3) ; and ; ra = 4 ; then Xp+ra = 10000000 (i. e. , Deg (Xp+ra) = 7), and D = Xp+ra/P = X'/1001 = 10000000/1001 = 10010; where Modulo unit 60 may calculate reciprocal-approximator RA prior to receiving message M and store RA in memory 69 since both generator polynomial P and the degree of message M are known prior to receiving message M. In other embodiments, reciprocal-approximator RA may be built in or obtained on- the fly'by modulo unit 60 after receiving message M. Once the form of the polynomial is fixed, the implementation of the corresponding hardware may be simplified considerably.

To obtain remainder R for message M modulo unit 60 includes multiplication unit 62, truncation unit 64, multiplication unit 66 and subtraction unit 68 where : To = M*RA is performed by unit 62, Tl = To/XP+ra is performed by unit 64,

T2 = Tl*P is performed by unit 66, and R = M-T2 is performed by unit 68.

Multiplication unit 62 receives message M and multiplies M by reciprocal-approximator RA to obtain temporary result To. For example: if M = 10111000, (from FIG.

3 above) P = 1001, and RA = 10010 ; then To= M*RA = 10111000*10010 = 101011110000; where Multiplication unit 62 provides temporary result To to truncation unit 64, which divides To by Xp+ra, here 10000000, to obtain truncated result Tl. In other embodiments, truncation unit 64 may remove the p+ra least significant bits of temporary result To without dividing by XP+ra to obtain truncated result Ti. For example: if p-3, ra = 4, and To = 101011110000 ; then p+ra = 7, and Ti = 10101.

Thus for p+ra equaling seven (7), the seven (7) least significant bits, here 1110000, are removed from To to obtain Tl.

Truncation unit 64 provides truncated result T, to multiplication unit 66, which multiplies T, by generator polynomial P to obtain temporary result T2. For example; if P = 1001, and T1 = 10101 ; then T2 = T1*P = 10101*1001 = 10111101 where Multiplication unit 66 provides temporary result T2 to subtraction unit 68, which subtracts T2 from message M to obtain remainder R. For example: if M = 10111000, and (from above) T2 = 10111101; then R = M-T2 = 101 where Thus, modulo unit 60 obtains remainder R for message M using multiplication by reciprocal approximation. Hence, modulo unit 60 may calculate the CRC for the entire message

M on its own, or may be incorporated into CRC generators 30 and 40 to obtain remainders R for message segments Ms.

For example, FIG. 7 shows an implementation of the CRC generator in FIG. 3 employing modulo unit 60 in FIG. 6.

Here, modulo units 60 are show as MH (M, RA, P). For example: if M = 10111000, (Same as in FIG. 3 above) s = 2, n = 4, and P = 1001 ; then M may be separated as Ms-1 = M1 = 1011 = segment 73 xn* (s-l) = X4 = 10000, Ms-2 = M0 = 1000 = segment 75 xn* (s-2) = X0 = 00001 ; where M = 1011*10000 + 1000*00001 = 10111000.

CRC generator 70 obtains a CRC for message M based on generator polynomial P, where the CRC for message M is the remainder of message M divided by polynomial P.

CRC generator 70 includes modulo unit 72, multiplier 74, accumulator 76, and modulo unit 78. Here, modulo unit 72 includes modulo units 72a and 72b, which multiply message segments 73 and 75 by a reciprocal approximation of generator polynomial P to obtain remainders Ri, and Ri.

Modulo unit 72a multiplies message segment 73 by reciprocal-approximator RA of generator polynomial P to obtain a remainder R as shown in FIG. 6. For example: if M = 10111000, MS-1 = M1 = 1011 = segment 73, Ms-2 = Mo = 1000 = segment 75, Deg (Ms-1) = 3 Deg (Ms-2) = 3 P = 1001, and

RA Xp+ra/P = X3+1/P, so that p+ra is greater than or equal to the degree of each message segment M,-, and Ms- 2; then RA = X3+1/P = 10000/1001 = lOi where and To = Ms-i*RA = 1011 * 10 = 10110, To (i) = Ms_2*RA = 1000 * 10 = 10000, T1(i+1) = T0(i+1)/X3+1 = 10110/10000 = 1, T1(i) = T0(i)/X3+1 = 10000/10000 = 1, T2 (i+1) = T1(i+1)*P = 1*1001 = 1001, T2(i) = T1(i)*P = 1*1001 = 1001, Ri+l +1 = Ms-1 - T2(i+1)= 1011 - 1001 = 010 Ri = Ms-2 - T2(i) = 1000 - 1001 = 001.

Hence, modulo units 72a and 72b obtain the same remainders Ri+l and Ri as modulo units 32a and 32b in FIG. 3 above.

Multiplier 34 multiplies Ri+l and Ri by segment-constants Ci+i and Ci to obtain segment-remainders SRi+2 and SRi. Here, segment-constants Ci+1 and Ci are obtained @on the fly'by moduloing the position X of segments 33 and 35 in message M by generator polynomial P (i. e., Ci+i = Xn (i+l) (modulo) P and Ci = Xni (modulo) P) using modulo unit 60 described in FIG. 6.

For example: if Xn* (i+1) = X4*(1) = M1 = 10000,

Xn*i = X4*(0) = M0 = 00001, Deg (X4*(1)) = 4, Deg (X4*(0)) = 0, P = 1001, and RA Xp+ra/P = X3+1/P, so that p+ra is greater than or equal to the degree of each message segment X4* and x4* (0).

' then RA = 10000/1001 = 10 ; and To (i+1) = M1*RA = 10000 * 10 = 100000, T0(i) = M0*RA = 00001 * 10 = 000010, T1(i+1) = T0(i+1)/X3+1 = 100000/10000 = 10, Ti (i) = T0(i)/X3+1 = 000010/10000 = 0, T2 (i+1) = T1(i+1)*P = 10*1001 = 10010, T2 (i) = T1(i)*P = 0*1001 = 00000, Ci+i i+1 = M1 - T2(i+1) = 10000-10010 = 010, Ci = Mo-T2 (i) = 00001-00000 = 001.

In other embodiments segment-constants Ci+1 and Ci may be obtained in advance in stored in a memory unit (e. g. 39).

Multiplier 74 includes multipliers 74a and 74b.

Multiplier 74a multiplies remainder Ri+l by segment-constant Ci+1 to obtain segment-remainder SRi+1. Multiplier 74b multiplies Ri by segment constant Ci to obtain segment- remainder SRi. For example : if Ri+l = 010, Ci+1 = 010 and (from above) Ri = 001, Ci = 001 ; then SRi+1 = Ri+1*Ci+1 = 010*010 = 00100, and SRi = Ri*Ci = 001*001 = 00001 ;

Accumulator 76 adds segment-remainders SRi+1 and SRi together to obtain accumulated-remainder AR. For example: if SRi+1 = SR1 = 00100, SRi = SR0 = 00001 ; then AR = 00100+00001 = 00101.

Modulo unit 78 obtains a CRC for message M by moduloing accumulated-remainder AR by generator polynomial P. Here, modulo unit 78 obtains the CRC by using multiplication by reciprocal approximation shown in FIG. 6. For example: if AR = M = 00101, Deg (AR) = 2 P = 1001, and RA XP+ra/P = X3+1/P so that p+ra is greater than or equal to the degree of the message for which a remainder is desired, here AR; then RA = 10000/1001 = 10 ; and To = M*RA = 00101*10 = 1010, T1 = To/X3+l = 1010/10000 = 0, T2 = T1*P = 0*1001 = 0, R = CRC = M-T2 = 00101-0 = 101.

Thus CRC generator 70 obtains the same CRC the example for CRC generator 30. Likewise, CRC generator 70 may also be expanded to include enough components for obtaining the CRC for message M separated into N segments.

CRC generator 80 (FIG. 8) includes subtraction unit 82, modulo unit 84 and accumulator 86 for updating a CRC of a message M adjusted during transmission. Subtraction unit 82 subtracts old message 83 from new message 85 to obtain difference D. For example: i f/CRCold P = 1001,/ Mold = 10111 l 101 Mnew = 10001 ! 101 "*--CRC to be updated then D = Mnew - Mold = 00110000 wherein adjusted portion of M zu 101111011-Mnew - 4- Mold 001 0000 = D.

Modulo unit 84 modulos difference D by generator polynomial P to obtain a difference-remainder DR. For example: if P = 1001, and D = 00110000 ; then DR = D (modulo) P = MOD (D, P) = wherein

In other embodiments, difference-remainder DR may be obtained using multiplication by reciprocal-approximator RA (i. e. MH (D, RA, P) ).

Accumulator 86 adds difference-remainder DR and CRCold to obtain a CRCnew. For example: if CRCold = 101 and DR = 110 ; then CRCnew = CRcold + DR = 101+110 = 011 ; where 101 + 110 = CRCnew.

The accuracy of this CRCnew may be confirmed by replacing CRCold in the adjusted message Mnew with CRCnew and determining whether Mnew (modulo) CRCnew equals zero. For example: then MneW (modulo) CRCnew = 0 wherein

000 = CRC.

CRC generator 90 (FIG. 9) includes subtraction unit 92, modulo unit 94, multiplier 96, modulo unit 98 and accumulator 99 for updating a CRC of a message M adjusted during transmission. CRC generator 90 differs from generator 80 in that it adjusts the CRC of a message M based on the adjusted segment of the message.

Subtraction unit 92 subtracts old message segment 93 from new message segment 95 to obtain difference-segment DS.

For example: if <BR> <BR> P = 1001,<BR> <BR> <BR> n 2<BR> <BR> <BR> s 4 Mold = 10111l101 MS_1-10 CRCold Ms-2 = 11 = segment 93 Mus_3-11 Ms-4 = 01 Mnew = 10001 l 101 Ms-i = 10 Ms-2 = 00 = segment 95 Mus_3-11 Ms-4 = 01 then DS = Ms-2 (new)-Ms-2 (old) = 00- Modulo unit 94 modulos difference-segment DS by generator polynomial P to obtain a difference-segment- remainder DSR. For example: if P = 1001, and DS = 11 ; then DSR = DS (modulo) P = MOD (DS, P) = 11

wherein Here, as above, if the difference-segment DS is of a lesser degree than polynomial P, modulo unit 94 is not needed since the modulo of DS equals DS.

Multiplier 96 multiplies difference-segment-remainder DSR by an appropriate segment-constant Ci to obtain an expanded segment-remainder ESR. Segment-constants C3 to Co for this example may be obtained as described above. For example: if DSR = (M2new-M2old) (modulo) P = 11 and Ci = C2 = X2*2 (modulo) P - 10000 (modulo) 1001 = 010 ; then EDR = DSR * Ci = 11*010 = 110.

Modulo unit 98 obtains message difference-remainder DR by moduloing the extended difference-remainder by generator polynomial P. For example: if P = 1001 and EDR = 110 ; then DR = 110.

Again, for extended difference-remainders of a degree less than the degree of polynomial P the DR is the EDR.

Finally, accumulator 99 adds the message difference- remainder DR and CRCold to obtain a CRCnew For example:

CRCold = 101 and DR = 110 ; then CRC,,, = CRC, ld + DR = 101 + 110 = 011 ; wherein 101 + 110 Oil = CRCnew.

All of the above algorithms may be affected by embedding generator polynomial P in a larger ring. For example, let F = P*Q ; where F is a field extension of P, Q is an extender, and the greatest common denominator between P and Q is one (1). Segment-constants C may now be calculated using field extension F, instead of p, and message segments Ms increased in size (by bit) accordingly without requiring the additional modulos 42 and 42 in FIG. 3 and 4 above. Rather, only modulo by P, as shown in FIG. 5 may be needed.

FIG. 10 shows a general-purpose computer 100 for obtaining a CRC using process 20 or any of the operations of the CRC generator units 30,40, 50,60, 70,80 and 90 shown above. Computer 100 includes a processor 102 (e. g. a CPU), a storage medium 104 (e. g. , a random access memory) and communication interface 106 (e. g. , a network card) having one or more external connections 106a, 106b and 106c for sending and receiving data transmissions. Storage medium 104 stores computer instructions 108 for obtaining a CRC via process 20 or the operations of the CRC generator units described above. In one embodiment, computer 100 obtains a CRC for a message M based on multiplication by reciprocal approximation.

Process 20 and the operations of the CRC generators shown above, however, are not limited to use with any particular hardware or software configuration; they may find compatibility in any computing or processing environment.

Process 20 may be implemented in hardware, software, or any combination of the two. So too, may the operations of the CRC generator units 30,40, 50,60, 70,80 and 90.

Process 20 and the CRC generators described above may be implemented in computer programs executing on programmable computers that each include a processor, a storage medium readable by the processor (e. g. volatile memory, non-volatile memory, etc. ), one or more input devices, and one or more out devices. Program code may be applied to data entered using an input device to perform process 20 or any of the operations of the CRC generators described above. The output information may be applied to one or more output devices, such as screen 110.

Each such program may be implemented in a high level procedural or object-oriented programming language to communicate with a computer system. However, the programs can be implemented in assembly or machine language. The language may be a compiled or an interpreted language.

Each computer program may be stored on an article of manufacture, such as a CD-ROM, hard disk, or magnetic diskette, that is readable by computer 100 to obtain a CRC for message M in the manners described above. Process 20 and the operations for implementing the CRC generators above may also be implemented as a machine-readable storage medium, configured with one or more computer programs, where, upon execution, instructions in the computer program (s) cause the processor 102 to operate as described above.

A number of embodiments of the invention have been described. Nevertheless, it will be understood that various modifications may be made without departing from the spirit and scope of the invention. For example, message M may be divided into an odd number of segments or segment sizes or field extensions F may be substituted for generator polynomial P were appropriate. Accordingly, other embodiments are within the scope of the following claims.