A thesis on evaluation of the gilbert-varshamov bound for constrained systems
Obtaining nontrivial lower bounds on the rates of optimal codes in nonuniform spaces is gener- ally a difficult problem. This thesis is devoted to the study of the well-known Gilbert-Varshamov (GV) bound for constrained systems. Evaluation of this GV bound for specific constrained sys- tems poses...
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sg-ntu-dr.10356-1819442025-02-05T01:58:52Z A thesis on evaluation of the gilbert-varshamov bound for constrained systems Goyal, Keshav Kiah Han Mao School of Physical and Mathematical Sciences HMKiah@ntu.edu.sg Mathematical Sciences Analytic combinatorics GV bound discrete simplex Manhattan distance Constrained systems Obtaining nontrivial lower bounds on the rates of optimal codes in nonuniform spaces is gener- ally a difficult problem. This thesis is devoted to the study of the well-known Gilbert-Varshamov (GV) bound for constrained systems. Evaluation of this GV bound for specific constrained sys- tems poses a significant computation challenge. In 1991, Kolesnik and Krachkovsky showed that the GV bound can be determined via the solution of some optimization problems. Later, Mar- cus and Roth (1992) modified the optimization problem and improved the GV bound in many instances. This thesis aims to mitigate the computation challenges by introducing two different graph-theoretic and combinatorial approaches for the evaluation of the GV bound. We empha- size that the graph-theoretic approach is preferable for constrained systems for which graph pre- sentation is well known. On the other hand, a combinatorial approach is preferable when the generating function for total ball size is easy to find. In the graph-theoretic approach, we provide explicit numerical procedures to solve these two optimization problems and hence, compute the bounds for several constrained systems in Ham- ming metric including Run length constrained systems and Sliding Window constrained systems. We then show the procedures can be further simplified when we plot the respective curves. In the case where the graph presentation comprises a single state, we provide explicit formulas for both bounds. Analytic combinatorics in several variables refers to a suite of tools that provide sharp asymp- totic estimates for certain combinatorial quantities. In our combinatorial approach, we apply these tools to determine the Gilbert–Varshamov lower bound on the rate of optimal codes in the $L_1$ metric. Several different code spaces are analyzed, including the simplex and the hypercube in $Z^n$, all of which are inspired by concrete data storage and transmission models such as the permu- tation channel, the repetition channel, the adjacent transposition (bit-shift) channel, the multilevel flash memory channel, etc. Doctor of Philosophy 2025-01-06T00:01:17Z 2025-01-06T00:01:17Z 2025 Thesis-Doctor of Philosophy Goyal, K. (2025). A thesis on evaluation of the gilbert-varshamov bound for constrained systems. Doctoral thesis, Nanyang Technological University, Singapore. https://hdl.handle.net/10356/181944 https://hdl.handle.net/10356/181944 10.32657/10356/181944 en This work is licensed under a Creative Commons Attribution-NonCommercial 4.0 International License (CC BY-NC 4.0). application/pdf Nanyang Technological University |
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Mathematical Sciences Analytic combinatorics GV bound discrete simplex Manhattan distance Constrained systems |
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Mathematical Sciences Analytic combinatorics GV bound discrete simplex Manhattan distance Constrained systems Goyal, Keshav A thesis on evaluation of the gilbert-varshamov bound for constrained systems |
| description |
Obtaining nontrivial lower bounds on the rates of optimal codes in nonuniform spaces is gener-
ally a difficult problem. This thesis is devoted to the study of the well-known Gilbert-Varshamov
(GV) bound for constrained systems. Evaluation of this GV bound for specific constrained sys-
tems poses a significant computation challenge. In 1991, Kolesnik and Krachkovsky showed that
the GV bound can be determined via the solution of some optimization problems. Later, Mar-
cus and Roth (1992) modified the optimization problem and improved the GV bound in many
instances. This thesis aims to mitigate the computation challenges by introducing two different
graph-theoretic and combinatorial approaches for the evaluation of the GV bound. We empha-
size that the graph-theoretic approach is preferable for constrained systems for which graph pre-
sentation is well known. On the other hand, a combinatorial approach is preferable when the
generating function for total ball size is easy to find.
In the graph-theoretic approach, we provide explicit numerical procedures to solve these two
optimization problems and hence, compute the bounds for several constrained systems in Ham-
ming metric including Run length constrained systems and Sliding Window constrained systems.
We then show the procedures can be further simplified when we plot the respective curves. In
the case where the graph presentation comprises a single state, we provide explicit formulas for
both bounds.
Analytic combinatorics in several variables refers to a suite of tools that provide sharp asymp-
totic estimates for certain combinatorial quantities. In our combinatorial approach, we apply these
tools to determine the Gilbert–Varshamov lower bound on the rate of optimal codes in the $L_1$
metric. Several different code spaces are analyzed, including the simplex and the hypercube in $Z^n$,
all of which are inspired by concrete data storage and transmission models such as the permu-
tation channel, the repetition channel, the adjacent transposition (bit-shift) channel, the multilevel
flash memory channel, etc. |
| author2 |
Kiah Han Mao |
| author_facet |
Kiah Han Mao Goyal, Keshav |
| format |
Thesis-Doctor of Philosophy |
| author |
Goyal, Keshav |
| author_sort |
Goyal, Keshav |
| title |
A thesis on evaluation of the gilbert-varshamov bound for constrained systems |
| title_short |
A thesis on evaluation of the gilbert-varshamov bound for constrained systems |
| title_full |
A thesis on evaluation of the gilbert-varshamov bound for constrained systems |
| title_fullStr |
A thesis on evaluation of the gilbert-varshamov bound for constrained systems |
| title_full_unstemmed |
A thesis on evaluation of the gilbert-varshamov bound for constrained systems |
| title_sort |
thesis on evaluation of the gilbert-varshamov bound for constrained systems |
| publisher |
Nanyang Technological University |
| publishDate |
2025 |
| url |
https://hdl.handle.net/10356/181944 |
| _version_ |
1823807346946605056 |