Longitudinal Redundancy Check - meaning and definition. What is Longitudinal Redundancy Check
Diclib.com
ChatGPT AI Dictionary
Enter a word or phrase in any language 👆
Language:

Translation and analysis of words by ChatGPT artificial intelligence

On this page you can get a detailed analysis of a word or phrase, produced by the best artificial intelligence technology to date:

  • how the word is used
  • frequency of use
  • it is used more often in oral or written speech
  • word translation options
  • usage examples (several phrases with translation)
  • etymology

What (who) is Longitudinal Redundancy Check - definition


Longitudinal redundancy check         
ERROR DETECTION NUMBER CALCULATED OVER A SERIAL DATA STREAM
Horizontal redundancy check; ISO 1155; Optimal rectangular code; Optimal Rectangular Code; ORC (code)
In telecommunication, a longitudinal redundancy check (LRC), or horizontal redundancy check, is a form of redundancy check that is applied independently to each of a parallel group of bit streams. The data must be divided into transmission blocks, to which the additional check data is added.
Longitudinal Redundancy Check         
ERROR DETECTION NUMBER CALCULATED OVER A SERIAL DATA STREAM
Horizontal redundancy check; ISO 1155; Optimal rectangular code; Optimal Rectangular Code; ORC (code)
<storage, communications> (LRC, Block Redundancy Check) An error checking method that generates a longitudinal parity byte from a specified string or block of bytes on a longitudinal track. The longitudinal parity byte is created by placing individual bytes of a string in a two-dimensional array and performing a Vertical Redundancy Check vertically and horizontally on the array, creating an extra byte. This is an improvement over the VRC because it will catch two errors in the individual characters of the string, beyond the odd errors. (2004-01-26)
cyclic redundancy check         
TYPE OF HASH FUNCTION USED TO DETECT ERRORS IN DATA STORAGE OR TRANSMISSION
Cyclic Redundancy Check; FCS-32; Cyclic redundancy code; CRC16; Crc64; Crc32 mpeg2; Crc16; Cyclic redundancy checks; CRC-24; CRC-16; CRC-8; CRC-64; Cyclical redundancy checking; CRC-CCITT; CRC-12; Crc32c; CRC32c; CRC8; Cyclic redundancy; Cyclic redundancy checksum; CRC-32C; CRC-32K; CRC check; CRC Values; Polynomial representations of cyclic redundancy checks; Polynomial CRC representations; List of CRC polynomials
<algorithm> (CRC or "cyclic redundancy code") A number derived from, and stored or transmitted with, a block of data in order to detect corruption. By recalculating the CRC and comparing it to the value originally transmitted, the receiver can detect some types of transmission errors. A CRC is more complicated than a checksum. It is calculated using division either using shifts and exclusive ORs or table lookup (modulo 256 or 65536). The CRC is "redundant" in that it adds no information. A single corrupted bit in the data will result in a one bit change in the calculated CRC but multiple corrupted bits may cancel each other out. CRCs treat blocks of input bits as coefficient-sets for polynomials. E.g., binary 10100000 implies the polynomial: 1*x^7 + 0*x^6 + 1*x^5 + 0*x^4 + 0*x^3 + 0*x^2 + 0*x^1 + 0*x^0. This is the "message polynomial". A second polynomial, with constant coefficients, is called the "generator polynomial". This is divided into the message polynomial, giving a quotient and remainder. The coefficients of the remainder form the bits of the final CRC. So, an order-33 generator polynomial is necessary to generate a 32-bit CRC. The exact bit-set used for the generator polynomial will naturally affect the CRC that is computed. Most CRC implementations seem to operate 8 bits at a time by building a table of 256 entries, representing all 256 possible 8-bit byte combinations, and determining the effect that each byte will have. CRCs are then computed using an input byte to select a 16- or 32-bit value from the table. This value is then used to update the CRC. Ethernet packets have a 32-bit CRC. Many disk formats include a CRC at some level. (1997-08-02)