Investigation block error rate and bit error rate for linear block codes
Uncoded transmissions are suitable for a low-noise environment, but these ideal conditions are not usually available. While a multitude of options exists for reducing errors during transmission, it is challenging to estimate the volume of additional resources required for an improvement in its error...
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sg-ntu-dr.10356-678692023-07-07T16:48:52Z Investigation block error rate and bit error rate for linear block codes Han, Eugene Zhiwei Li Kwok Hung Teh Kah Chan School of Electrical and Electronic Engineering DRNTU::Engineering Uncoded transmissions are suitable for a low-noise environment, but these ideal conditions are not usually available. While a multitude of options exists for reducing errors during transmission, it is challenging to estimate the volume of additional resources required for an improvement in its error-reduction capability. As such, this report compares uncoded communication systems with some coding schemes, examining their resource efficiency and overall effectiveness. Extensive research has been conducted before and the literature of bit error rate (BER) and block error rate (BLER) relating to binary linear block code is widely available. This project strives to reinforce those findings by employing myriad simulative methods. Hamming-coded transmissions aid in reducing error caused by noise, but their performance varies across different orders of coding systems. Focussing on Hamming codes, a common platform where various types of Hamming codes can be normalized is built, allowing them to be compared based on BER and BLER. BER and BLER are examined in greater details as well, through both theoretical models and simulations. A relationship has been found between the two. It is observed that BLER is higher than BER in all cases. For Hamming codes, the relationship is BER = 3 � BLER, where � is the length of the code. This linearity applies to non-perfect linear block code too. This report also highlights the importance of supporting theory with applications. An investigation into the discrepancy in errors correction between degrees of error reveals that Hamming code performs unpredictably when an error of greater than 1 is introduced. As such, careful analysis shows that many factors like � �/ �0 and predicted errors must be considered for each type of communication system. Bachelor of Engineering 2016-05-23T05:00:04Z 2016-05-23T05:00:04Z 2016 Final Year Project (FYP) http://hdl.handle.net/10356/67869 en Nanyang Technological University 63 p. application/pdf |
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DRNTU::Engineering Han, Eugene Zhiwei Investigation block error rate and bit error rate for linear block codes |
| description |
Uncoded transmissions are suitable for a low-noise environment, but these ideal conditions are not usually available. While a multitude of options exists for reducing errors during transmission, it is challenging to estimate the volume of additional resources required for an improvement in its error-reduction capability. As such, this report compares uncoded communication systems with some coding schemes, examining their resource efficiency and overall effectiveness.
Extensive research has been conducted before and the literature of bit error rate (BER) and block error rate (BLER) relating to binary linear block code is widely available. This project strives to reinforce those findings by employing myriad simulative methods. Hamming-coded transmissions aid in reducing error caused by noise, but their performance varies across different orders of coding systems. Focussing on Hamming codes, a common platform where various types of Hamming codes can be normalized is built, allowing them to be compared based on BER and BLER.
BER and BLER are examined in greater details as well, through both theoretical models and simulations. A relationship has been found between the two. It is observed that BLER is higher than BER in all cases. For Hamming codes, the relationship is BER = 3 � BLER, where � is the length of the code. This linearity applies to non-perfect linear block code too. This report also highlights the importance of supporting theory with applications. An investigation into the discrepancy in errors correction between degrees of error reveals that Hamming code performs unpredictably when an error of greater than 1 is introduced. As such, careful analysis shows that many factors like � �/ �0 and predicted errors must be considered for each type of communication system. |
| author2 |
Li Kwok Hung |
| author_facet |
Li Kwok Hung Han, Eugene Zhiwei |
| format |
Final Year Project |
| author |
Han, Eugene Zhiwei |
| author_sort |
Han, Eugene Zhiwei |
| title |
Investigation block error rate and bit error rate for linear block codes |
| title_short |
Investigation block error rate and bit error rate for linear block codes |
| title_full |
Investigation block error rate and bit error rate for linear block codes |
| title_fullStr |
Investigation block error rate and bit error rate for linear block codes |
| title_full_unstemmed |
Investigation block error rate and bit error rate for linear block codes |
| title_sort |
investigation block error rate and bit error rate for linear block codes |
| publishDate |
2016 |
| url |
http://hdl.handle.net/10356/67869 |
| _version_ |
1772826831915843584 |