초록

Methods and architectures for turbo decoding are presented. The methods are such that low energy consumption is obtained with reduced memory requirements. Moreover the methods show improved performance with respect to latency.

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1. A method of determining a decoded signal from an encoded signal, the method comprising:receiving the encoded signal;performing a first decoding so as to determine a first intermediate data element, wherein the first intermediate data element is stored in a memory, and wherein the first decoding i

1. A method of determining a decoded signal from an encoded signal, the method comprising:receiving the encoded signal;performing a first decoding so as to determine a first intermediate data element, wherein the first intermediate data element is stored in a memory, and wherein the first decoding is based on the encoded signal;performing a second decoding so as to determine a second intermediate data element, wherein determining the second intermediate data element is based on the encoded signal and an interleaved version of the first intermediate data element that is read from the memory, and wherein the second intermediate data element is stored in the memory;iteratively performing the first decoding and second decoding, wherein the first decoding exploits an interleaved version of the second intermediate data element, wherein the second intermediate data element is read from the memory and wherein the first intermediate data element is stored in the memory, wherein the second decoding exploits an interleaved version of the first intermediate data element that is read from the memory, and wherein the second intermediate data element is stored in the memory; anddetermining the decoded signal from either the first or the second intermediate data elements. 2. The method of claim 1, wherein the memory is a single port memory. 3. A method of determining a decoded signal from an encoded signal, the method comprising:receiving the encoded signal;performing substantially simultaneously a plurality of iterative decoding methods on parts of the encoded signal, wherein each of the iterative decoding methods comprises:performing a first decoding so as to determine, based on part of the encoded signal, a first intermediate data element, wherein the first intermediate data element is stored in a memory that is assigned to an iterative decoding method on part of the encoded signal;performing a second decoding so as to determine, based on part of the encoded signal and an interleaved version of the first intermediate data element, read from the memory, a second intermediate data element, wherein the second intermediate data element is stored in the memory;iteratively performing the first decoding and second decoding, wherein the first decoding exploits an interleaved version of the second intermediate data element that is read from the memory, wherein the first intermediate data element is stored in the memory, wherein the second decoding exploits an interleaved version of the first intermediate data element that is read from the memory, and wherein the second intermediate data element is stored in the memory; anddetermining part of the decoded signal from either the first or the second intermediate data elements; andassembling the determined parts of the decoded signal so as to provide the decoded signal. 4. The method of claim 2, wherein the memory is a single port memory. 5. A method of determining a decoded signal from an encoded signal, the method comprising:receiving the encoded signal;performing substantially simultaneously a plurality of iterative decoding methods on parts of the encoded signal, wherein each of the iterative decoding methods comprises:iteratively performing a sequence of decoding processes, wherein each of the decoding processes exploits an interleaved version of intermediate data elements, wherein the intermediate data elements are produced by a preceding decoding process, wherein the intermediate data elements are stored in and read from a memory that is assigned to the iterative decoding methods;determining part of the decoded signal from one of the intermediate data elements; andassembling the determined parts of the decoded signal so as to provide the decoded signal. 6. The method of claim 5, wherein the memory is a single port memory. 7. An apparatus for determining a decoded signal from an encoded signal, the apparatus being adapted for receiving the encoded signal and outpufling the decoded signal, the app aratus comprising a plurality of parallel modules, each of the modules being adapted for performing decoding, wherein each of the modules comprises:a decoder module having at least a first input, a second input, a first output and a second output;a memory, being assigned to the decoder module;a feedback connection between the second output and the second input; andwherein the memory is incorporated within the feedback connection. 8. The apparatus of claim 7, wherein the memory is a single port memory. 9. The apparatus of claim 7, wherein each of the modules is adapted to perform an iterative decoding method on parts of the encoded signal. 10. The apparatus of claim 7, wherein the memory is a single memory. 11. An apparatus for determining a decoded signal from an encoded signal, the apparatus being adapted for receiving the encoded signal and outputting the decoded signal, the apparatus comprising a plurality of parallel modules, each of the modules being adapted for performing decoding, wherein each of the modules is adapted for performing an iterative decoding method on parts of the encoded signal, wherein the iterative decoding method comprises iteratively decoding an interleaved version of the intermediate data elements, wherein the intermediate data elements are produced by a preceding decoding process, wherein the data elements are stored in and read from the memory, and wherein the memory is assigned to the iterative decoding method. 12. The apparatus of claim 11, wherein the memory is a single port memory.