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Update Phy Error Model Doc according to JIRA-202, missing codeblock size of 160
authorMarco Miozzo <marco.miozzo@cttc.es>
Tue, 14 Feb 2012 11:24:34 +0100
changeset 8637 5d8be68292c0
parent 8635 f72d4c3b630a
child 8638 5a6544286265
child 8639 3bad4dc4a43b
Update Phy Error Model Doc according to JIRA-202, missing codeblock size of 160
src/lte/doc/source/lte-design.rst file | annotate | diff | comparison | revisions 
--- a/src/lte/doc/source/lte-design.rst	Mon Feb 13 15:26:35 2012 +0100
+++ b/src/lte/doc/source/lte-design.rst	Tue Feb 14 11:24:34 2012 +0100
@@ -1168,7 +1168,7 @@
 
   CBLER_i = \frac{1}{2}\left[1-erf\left(\frac{x-b_{ECR}}{\sqrt{2}c_{ECR}} \right) \right]
 
-where :math:`x` is the MI of the TB, :math:`b_{ECR}` represents the "transition center" and :math:`c_{ECR}` is related to the "transition width" of the Gaussian cumulative distribution for each Effective Code Rate (ECR) which is the actual transmission rate according to the channel coding and MCS. For limiting the computational complexity of the model we considered only a subset of the possible ECRs in fact we would have potentially 5076 possible ECRs (i.e., 27 MCSs and 188 CB sizes). On this respect, we will limit the CB sizes to some representative values (i.e., 40, 140, 256, 512, 1024, 2048, 4032, 6144), while for the others the worst one approximating the real one will be used (i.e., the smaller CB size value available respect to the real one). This choice is aligned to the typical performance of turbo codes, where the CB size is not strongly impacting on the BLER. However, it is to be notes that for CB sizes lower than 1000 bits the effect might be relevant (i.e., till 2 dB); therefore, we adopt this unbalanced sampling interval for having more precision where it is necessary. This behaviour is confirmed by the figures presented in the Annes Section.
+where :math:`x` is the MI of the TB, :math:`b_{ECR}` represents the "transition center" and :math:`c_{ECR}` is related to the "transition width" of the Gaussian cumulative distribution for each Effective Code Rate (ECR) which is the actual transmission rate according to the channel coding and MCS. For limiting the computational complexity of the model we considered only a subset of the possible ECRs in fact we would have potentially 5076 possible ECRs (i.e., 27 MCSs and 188 CB sizes). On this respect, we will limit the CB sizes to some representative values (i.e., 40, 140, 160, 256, 512, 1024, 2048, 4032, 6144), while for the others the worst one approximating the real one will be used (i.e., the smaller CB size value available respect to the real one). This choice is aligned to the typical performance of turbo codes, where the CB size is not strongly impacting on the BLER. However, it is to be notes that for CB sizes lower than 1000 bits the effect might be relevant (i.e., till 2 dB); therefore, we adopt this unbalanced sampling interval for having more precision where it is necessary. This behaviour is confirmed by the figures presented in the Annes Section.
 
 
 Link Layer Performance
tomh/ns-3-dev-spectrum-wifi