SE512145C2 - Device for correction of burst and random errors - Google Patents

Abstract

The apparatus includes a circuit (2) for generating two n-bit syndromes corresponding to the received signal, a circuit (4) for converting the two n-bit syndromes to a 2n-bit syndrome, a random error correcting circuit (7), a burst error correcting circuit (5), two combining circuits (11a, 11b) and output selecting circuit (6). The circuit (7) inputs the two n-bit syndromes and outputs a random error correction signal to one of the combining circuits (11a) and the circuit (5) inputs the 2n-bit syndrome and outputs a burst error correction signal to the other of the combining circuits (11b). The combining circuits combine the correction signals to the received BCH code signal. The output selecting circuit (6) selectively outputs one of the combined signals in accordance with the decoding conditions of the error correcting circuits (5, 7) and the result of comparison between the decoded and error-corrected signals. <IMAGE>

Description

512 145 2 the code, but there is no definitive proposal as to how the condition of the communication path should be handled in a concrete way and furthermore there is no criterion on how such a condition should be assessed appropriately, so it is difficult to accurately control the selection circuit 6 A further problem is that it is necessary for the respective units to independently include syndrome generating circuits for extracting the fault condition since the burst error correcting unit and the random error correcting unit are arranged independently of each other.

The present invention aims to solve such problems as described above and to provide an apparatus for decoding a BCH-encoded signal and for correcting a complex or compound error in the BCH-encoded signal, which apparatus is capable of determining the state of the communication path, that concretely provide a criterion for assessing the condition of the communication path and for jointly using a syndrome generation circuit for a burst error correcting unit and a random error correcting unit.

This object is achieved by a device for decoding a BCH code used for correcting a complex signal, which device is capable of determining the state of the communication path by using the decoded result from a burst error correction unit with a burst lock function and the decoded result from the random error correction unit. , the device having a circuit for determining the result of an operation with a circuit for forming an operation of integers with modulo 2 "-1, whereby a criterion is provided for assessing the state of the communication path for controlling an output selecting circuit, and further a means for converting a syndrome is provided, whereby the common use of a syndrome generating circuit can be achieved.

In the accompanying drawing: 512 1.45 3 Fig. 1 shows a block diagram illustrating a conventional device for decoding a BCH code with a correction function for a complex error; Fig. 2 is a block diagram illustrating an apparatus for decoding a BCH code having a complex error correction function in accordance with this invention; Fig. 3 is a block diagram illustrating details of the random error correcting circuit of Fig. 2; Fig. 4 is a detailed diagram of the burst error correcting circuit of Fig. 2; Fig. 5 is a detailed diagram of the output selection circuit of Fig. 2; and Fig. 6 is a table showing the criterion for controlling the output selecting switch included in the output selecting control circuit of Fig. 5.

An embodiment of the present invention will now be described. Fig. 2 shows in block diagram form an error correcting unit. In the drawing, reference numeral 1 denotes an input terminal for inputting a received coded message, 2 a syndrome generating circuit for generating two syndromes of n bits to correct a random error, 3 a delay circuit for retaining the received message during the period for generating the syndrome and correction of an error, 4 a syndrome conversion circuit for performing a conversion from the two syndromes of n bits generated in the syndrome generation circuit 2 to a syndrome of two n bits of a burst error correction circuit for correcting a burst error correction, a burst error correction circuit for the position in which a burst error is generated and the pattern of the burst error, 6 an output signal selecting circuit having a criterion for determining and judging the state of a communication path using the decoded results from the burst error correcting circuit 5 and a random error correcting circuit mentioned below, 7. - ran the circuit for receiving the syndrome as an input signal, which is a vector expressed by the polynomial base in a finite field and obtained with the syndrome generating circuit 2, for converting the vector expressed as a vector into an exponential expression of a primitive element in the finite field, for obtaining of an error position polynomial by normalizing the converted exponential expression with an integer operation of modulo 2 "-1, to obtain the radical of the normalized error position polynomial by looking up in a table the normalized error position calculated in advance for the constant terms in the normalized error position polynomial, for calculating the true error position from the normalized error position and for correcting the random error, 8 a data ROM for storing data for converting the syndrome expressed as a vector in the polynomial base in the finite field and obtained from the syndrome generating circuit 2 to the exgonential expression of the primitive the element in the finite field and data for the normalized error position which is the radical of the normalized error position polynomial, 9 an output terminal for outputting the decoded results, 10 a terminal for outputting a signal when an uncorrectable error showing the final decoded state is detected, and 11-a and ll-b exclusive OR circuits for adding error correction pulses output from the burst error correcting circuit 5 and the random error correcting circuit 7 for the received message.

Fig. 3 shows the details of the random error correcting circuit 7 shown in Fig. 2, and in this figure the reference numeral 12 denotes an input terminal for inputting the syndrome expressed as a vector in the polynomial base in the finite field and obtained by the syndrome generating circuit 2 in Figs. 2, 13 registers for holding the input signal syndrome, 14 a adding circuit with modulo 2 "-1, 15 a complementary numerical circuit with modulo 2" -1, 16 a register for temporarily holding data, 17 a register with a function for checking the results of the calculation of the addition circuit 14 with modulo 2 ”-1 and the complementary numerical circuit 15 with modulo 512 2145 5 2” -1, 18 a counter circuit for calculating the true error position, 19 an OR circuit for mixing the correction pulses output from the counter circuits 18 and 18, 20 an address control circuit for outputting an address to the data ROM 8 which stores data for converting the syndrome expressed as a vector in the polynomial base in the finite field to the exponent the expression of the primitive element in the finite field and data for the normalized error position which is a radical of the normalized error position polynomial, 21 an address terminal for outputting an address to said data ROM 8, 22 a data input terminal to which data is input from said data ROOM 8, 23 an output terminal for 'outputting' the correction pulse, and 24 a terminal for outputting a detection signal for uncorrectable error in the event of an error which cannot be corrected at the random error correcting circuit 7.

Fig. 4 shows the details of the burst error correcting circuit 5 in Fig. 2, the reference numeral 25 being the input terminal for inputting the output signal from the syndrome conversion circuit 4 in Fig. 2, 26 being a 1-bit delay circuit, 27 being a switch for controlling a feedback circuit. of delay circuits 26 connected in loop through the switch, 28 is a selector switch for selecting either the output of the syndrome conversion circuit 4 or data from the feedback circuit, 29 is a latch (zero detection) for detecting the fact that the upper 2n-b the bits of the linear feedback shift register or feedback circuit having a length of 2n bits become zero, 30 is a terminal which outputs an uncorrectable burst error detection signal when an error is detected which can not be corrected at the burst error correcting circuit 5, and 31 is an error pattern. output of an error pattern to be corrected when the burst error is corrected.

Fig. 5 is a detailed block diagram of the output select circuit 6 of Fig. 2 containing the criterion for determining and judging the state of the communication path using the decoded results from the burst error correcting circuit 5 and the random error correcting circuit 7 of Fig. 2. In Fig. 5, the reference numeral 32 denotes an input terminal for data corrected using the output signal from the random error correcting circuit 7, 33, an input terminal for data corrected using the output signal from the burst error correcting circuit 5, 34 denotes an exclusive OR data comparison circuit. corrected by the random error correcting circuit 7 and data corrected by the burst error correcting circuit 5, 35 an input terminal for the detection signal for uncorrectable errors from the terminal 24 related to the random error correcting circuit 7, 36 an input terminal for the detection signal related to the error correcting terminal 31 the circuit selecting switch 5, 37 an output signal selecting switch for selecting either data corrected by the random error correcting circuit 7 or data corrected by the burst error correcting circuit 5, and 38 an output selecting control circuit for generating an uncorrectable signal to the terminal 10 (shown in Fig. 2). depending on the detection signals for uncorrectable errors input from the random error correcting circuit 7 and the burst error correcting circuit 5 to the input terminals 35 and 36, and for generating a control signal for controlling the output signal selecting switch 37 in accordance with the error detection signal output signals. 34 comparing data input to the terminal 32, which has been corrected by the random error correcting circuit 7, and data input to the terminal 33, which has been corrected by the burst error correcting circuit 5.

Fig. 6 is a table showing the criterion for controlling the output selection circuit 37 and which is included in the selector circuit 6 and the criterion for determining the uncorrectable error signal to the terminal 10.

The function will now be described. A message coded on the transmitter side and including errors added along the communication path is received at the input terminal. 1. Two n-bit syndromes, S1, S3 expressed by vectors i. The polynomial base: in the finite field generated by the syndrome-generating circuit 2. The two n-bit syndromes SU are then fed to the random error correcting circuit 7. and the syndrome conversion circuit 4. In the random error correcting circuit 7, the input syndromes S1, S3 are stored in the register 13 and are output as the address of the data ROM 8 via the address control circuit 20 to the address output terminal 21.

The syndromes S1, S3 are converted by the data ROM 8 from the vector expression in the polynomial base in the finite field to the exponential expression of the primitive element of the finite element, log Sloch log S3. The converted syndromes log S1 and log S, are stored in register 16 by means of the data entry terminal 22 and register 17. On the basis of the exponentially expressed syndromes log S, and log S3 stored in register 16, the constant term is calculated (log S3 - 3 x log S 1) of the normalized error position polynomial using the add circuit 14 and the complementary numeric circuit 15, and the constant term (log S3 - 3 x log S1) is then output as address to the data ROM 8 via the address control circuit 2Ö and the address output terminal 21. The constant term (log S3 - 3 x log S1) is then converted by the data ROM 8 into two radicals i = log a * and j = log ai of the normalized error position polynomial. Here a is a primitive element of the finite field and a * as well as a * radicals of the normalized error position polynomial, ie. they represent the normalized error position. The two radicals i = log ai and j = log ai of the error position polynomial normalized by the data ROM 8 are passed through the data input terminal 22 and the register 17 and added by the add circuit 14 to log S, and stored in the counter circuit 18 for calculating the true error position. At this time, the result of the addition of the register 17 is checked, and if it is an uncorrectable condition, a detection signal indicating uncorrectable error is output to the terminal 24. The true error position stored in the counter circuit 18 is counted down, and when the contents of the counter circuit 18 become zero, an error correction is given. pulse through the OR circuit 19 to the exclusive OR circuit ll- a fi On the other hand, the two-bit syndromes S1 and S3 input are converted as input to the syndrome conversion circuit 4 to 5'12 '1115 8 2n long syndromes which are then input to the burst error correcting circuit 5. For example (511, 493) BCH codes with the following generating polynomials: g (x) = x "+ x" + x "+" x1 ° + x "+ X7 + X6 + X3 + 1, the conversion is performed according to the following equations: S10 = S17 + S14 + S13 + S11 + S10 + S + S * S33 + S3! 37 34 S11 = S18 + S15 + S14 + S12 + S11 + S10 * S38 + S35 * S34 * 531 * S30 S12- = S16 + S15- + S13 + S12 + S11 + S10 _ * S36: + S35 + S33 + S31 + S30 S13 = S16 + S12 + S36 + S33 + S32 Sl¿ = §l7 + S13 + S37 + S34 + S33 sls = sig + s14 + S10 + S38 + S35 + S34 + S30 516 = 517 + 515 + S14 + S13 * S37 * S36 * S35 * S34 * S33 S17 = 518 + S17 + S16 + S15 + S13 + S11 + 538 + S36 * S35 + S33 + S31 s18 = sls + slö + sla + slz + sl, + slo + sas + S33 + saz + ss, + sso S19 = sl? + S14 + slg + slz + sl, + S37 + S34 + S33 + S32 + S3! 511 ° = S18 * S1? * 515 * S12 * S11 + S38 + S37 + S35 + S32 + Ssx + S + S12 + S + S s1,1 = s lo + S 36 33 32 3 ° S112 = 510 + S30 s1,3 = S11 * 531 512 145 S114 = S12 * S32 S115 = S17 + Slët-Sll + S10 + S + + S37 + S34 31 S146 = 518 + S15 + S12 + S11 + S38 + 535 * 532 + S31 S117 = 516 + S13 + 512 + S10 + S35 * S33 + S32 J 'S30 In the burst error correcting circuit 5, the switch 27 for controlling the feedback is closed and the selector switches 28 are rotated to the sides "a" connected to the input terminals 25, so that the two n bit long syndromes converted by the circuit are converted. 14 is input to the delay circuit 26: in the linear feedback shift register circuit with a length of 2n bits.

The selector switch 28 is then rotated to the linear feedback shift register circuit sides "b" and the scuff pattern is controlled by the latch 29 (zero detection) during the shift operation. If the error pattern is detected by the latch circuit 29 (zero detection), the switch 27 is opened and the error pattern is output serially from the error pattern output terminal 31 to the exclusive OR circuit ll-b. If at this time no error pattern is detected by the shift operation over the length of the code, the signal regarding an uncorrectable error detected by the latch circuit 129 (zero detection) is output to the terminal 30.

If an error pattern is detected in the random error correcting circuit 7 or the burst error correcting circuit 5, the received message is read out from the delay circuit 3 in which the received message is stored, the respective error pattern being son detected in the random error correcting circuit 7 and the combined burst through the exclusive OR circuits 11-a, ll-b, so that the random and burst errors are corrected to provide the respective decoded messages. Thereafter, the decoded messages corrected by the random error correcting circuit 7 and the burst error correcting circuit 5 as well as the outputs of the uncorrectable error detection terminals 24, 30 connected to the random error correcting circuit 7 and the burst error circuit are input. the output selecting circuit 6. In the output selecting circuit 6, the respective messages input from the random error correcting circuit 7 and the burst error correcting circuit 5 are compared by the exclusive OR circuit 34.

The result of the comparison through the exclusive OR circuit 34 and the uncorrectable error detection signals from the terminals 24, 30 are input to the output select control circuit 36, which in turn controls the output select switch 37 according to the output selection criterion shown in Fig. 6. Thus, both the uncorrectable error detection signals from the terminals 24, 30 show correction and the output signal from the exclusive OR gate 34, which compares the respective decoded messages, shows that the decoded messages are identical, then the output signal selecting switch 37 is turned to its "a" side to selecting the output signal from the random error correcting circuit 7 via the exclusive OR circuit 11a, if the uncorrectable error detection signal from the signal 24 shows correction and the uncorrectable error detection signal from the terminal 30 shows detection of an uncorrectable error, then the output signal 37 is rotated to "a" page to select same output as above, if the uncorrectable error detection signal from the terminal 30 shows correction and the uncorrectable error detection signal from the terminal 24 indicates the detection of an uncorrectable error, then the output signal selecting switch 37 is rotated to its "b" side to select the output from the burst error corrector circuit 5 via the exclusive OR circuit ll-b, and in other cases the signal representing the occurrence of uncorrectable error is output to the terminal 10. The final decoded message selected by the output signal selecting circuit 6 is output via the output terminal 9.

In the embodiment described above, the random error correcting circuit 7 is provided with a circuit for performing operations modulo 2 "-1, but the arranged random error correcting circuit can use a conventional shift register circuit with linear period.

Furthermore, the code length is not definitively limited, but a similar effect can also be produced with a shorter code.

As described above, in accordance with the present invention, a circuit with higher reliability for decoding a BCH code can be provided for correcting a complex or complex error by providing an output select circuit containing the output signal selection criterion from the random error correcting circuit. respectively the burst error correcting circuit.

Those skilled in the art further recognize that the above description relates to a preferred embodiment of the described device and that various changes and modifications may be made within the scope of the invention.

Claims (1)

A patent for simultaneous detection and correction of a combined complex error in a digital communication system, comprising - a first unit (2, 7, 11-a) for correcting random errors in the code signal, - a second unit (4 , 5, 11-b) for correcting burst errors, and - a third unit (6) connected to the first and the second unit, characterized in that the received signal is coded with a Bach code using a generating poiynem got) = x "+ X" + x "+ x '° + x * + X7 + X6 + X3 + xl, that a first and a second n-bit syndrome (S1, S3) are generated in a manner known per se in the first unit (2, 11-a), that the second unit (4, 5, 11-b) contains a syndrome conversion circuit (4) for calculating a Zn-bit syndrome (S) from the two n-bit syndromes generated in the first unit, and that the third unit (6) selects the output signal from the first or second unit in response to the decoding states of the first and second units, wherein a switch selector output selector selects the output signal from the unit indicating a correctable error and emits a signal for detecting a non-correctable error if both correction units (for random error or burst error) indicate a non-correctable error or if both correction units indicate correctable errors but the correction patterns given of the two correction units are not identical. Circuit according to Claim 1, characterized by means (8) for look-up in a table which stores pre-calculated radical data for fault position polynomials and for obtaining a normalized fault position.