Parity bit is added to the transmitted strings of bits during transmission from transmitters to detect any error in the data when they are received at the receiver end. Basically a parity code is nothing but an extra bit added to the string of data. Now there are two types of parity these are even parity and odd parity. Now we get an even parity when the total numbers of 1's in the string of the data is even after adding that extra bit. Similarly we get an odd parity when after adding that extra bit into the data string the total number of 1's in the data is odd. We can understand it with an example, suppose we have an eight bit ASCII code – 01000001. Now if the added bit is 0 then the number will become 001000001. Here the total number of 1s in the number is even so we get an even parity. Again if we add 1 to the number the number will become 101000001. Here the number of 1s is 3 which is odd so, we have got an odd parity. Normally even parity is used and it has almost become a convention. Now parity checks are capable of detecting a single bit error but it fails if there are two changes in the data and it is the biggest drawback of this system. That’s why there are several other codes to detect and correct more than one bit errors.
In repetition code a single bit data is considered as a bit string of predetermined value and sent to the receiver, this is capable of detecting more than one data bit error. This can be illustrated with an example suppose the original number is 101. Now during transmission all the numbers are repeated say 3 times, so the final transmitted number is 111000111. So when the number is received 1 bit error and two bit errors can be easily identified like it will be 011, 110 or 101. So it is a better way to detect and correct data but it gets highly inefficient as the number of repeated bits increase.
Cyclic Redundancy Check Code
Cyclic redundancy check (CRC) codes provide a reasonably high level of protection at low redundancy
Level. The cycle code for a given data word is generated as follows. At first we have to add certain number zeroes (the numbers are determined by the desired number of bit checks. This new data bit sequence is then divided by a special binary word whose length equals n + 1, n being the number of check bits to be added. The remainder obtained as a result of modulo-2 division is then added to the dividend bit sequence to get the cyclic code. The code word generated after the operation is completely divisible by the divisor which was used in the generation of the code. Thus, when we divide the received code with the same divisor, an error-free reception should lead to an all ‘0’ remainder. A nonzero remainder is indicative of the presence of errors. The probability of error detection depends upon the number of check bits, n, used to construct the cyclic code. It is 100 % for single-bit and two-bit errors. It is also 100 % when an odd number of bits are in error and the error bursts have a length less than n + 1. The probability of detection reduces to 1 – (1/2)n−1 for an error burst length equal to n + 1, and to 1 – (1/2)n for an error burst length greater than n + 1.