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Performance bounds for uniformly interleaved serial concatenations with a general inner system

Performance bounds for uniformly interleaved serial concatenations with a general inner system

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Average performance bounds based on uniform interleaving are considered for a serial concatenation consisting of an outer code, an interleaver and an inner coded modulation system. The exact input–output weight spectrum is derived for the case when only the outer code has the uniform error property. Thereby, an upper bound to the bit error probability under maximum likelihood detection is obtained. However, numerous examples for serially concatenated continuous phase modulation show that neglecting the non-uniform error property of the inner system gives an accurate and less complex approximation. Other inner coded modulations may behave differently.

Inspec keywords: computational complexity; error statistics; maximum likelihood detection; concatenated codes; phase modulation; interleaved codes

Other keywords: bit error probability; non-uniform error property; input-output weight spectrum; general inner system; inner coded modulation system; interleaver coded modulation system; uniformly interleaved serial concatenations; maximum likelihood detection; serially continuous concatenated phase modulation; outer code; uniform error property

Subjects: Codes; Other topics in statistics

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