A decoding system to achieve rates higher than 33.6 kbps in the analog modem to digital modem direction. The decoding system modifies the standard Tomlinson Harashima Precoding algorithm to adapt it for use in PCM modems. Instead of an arithmetic modulo operation that is implemented in the transmitt
A decoding system to achieve rates higher than 33.6 kbps in the analog modem to digital modem direction. The decoding system modifies the standard Tomlinson Harashima Precoding algorithm to adapt it for use in PCM modems. Instead of an arithmetic modulo operation that is implemented in the transmitter, the invention defines a Discrete Modulo Operation that performs the function of limiting the amplitude of the transmitted signal.
대표청구항▼
1. A decoder for generating a decoded signal from a received signal, the decoder comprising:a mapper that generates the decoded signal by mapping received signals in a plurality of distinct ranges onto a basic level, andwherein the mapping of the plurality of distinct ranges onto the basic level fol
1. A decoder for generating a decoded signal from a received signal, the decoder comprising:a mapper that generates the decoded signal by mapping received signals in a plurality of distinct ranges onto a basic level, andwherein the mapping of the plurality of distinct ranges onto the basic level follows different arithmetic rules for at least two of the plurality of distinct ranges. 2. The decoder according to claim 1, wherein the plurality of distinct ranges include a first distinct range and a second distinct range, the first distinct range forming part of a first constellation having a plurality of signal levels some of which are separated by a distance D 1 and the second distinct range forming part of a second constellation having a plurality of signal levels some of which are separated by a distance D 2 that differs from D 1 . 3. The decoder according to claim 2, wherein the first and second constellations form a subset of the levels in a standard mu-law or A-law PCM decoding table. 4. The decoder according to claim 2, wherein a first arithmetic rule of the mapper maps the first distinct range onto the basic level by partitioning the first constellation into a plurality of signal levels, some of the signal levels being separated by the distance D 1 . 5. The decoder according to claim 4, wherein the first arithmetic rule of the mapper also indexes the partitioned first constellation and maps the partitioned first constellation onto a basic constellation of levels as a function of the indexes. 6. The decoder according to claim 5, wherein the mapper maps the partitioned first constellation onto the basic constellation of levels by adding an offset J to the indexes. 7. The decoder according to claim 6, wherein the value of the offset J depends on whether the level of the received signal is inside or outside the basic constellation of levels. 8. The decoder according to claim 2, wherein a second arithmetic rule of the mapper maps the second distinct range onto the basic level by partitioning the second constellation into a plurality of signal levels, some of the signal levels being separated by the distance D 2 . 9. The decoder according to claim 1, wherein the basic level is one level within a basic constellation of levels and wherein the mapper maps each distinct range onto only one level inside the basic constellation of levels, such that a many-to-one mapping is created from each distinct range to a level inside the basic constellation of levels. 10. The decoder according to claim 1, further including a table identifying the mapping from the received signals in a plurality of distinct ranges to the basic level, wherein the basic level is one level in a basic constellation of levels. 11. The decoder according to claim 10, wherein the table has an index basic_const, where basic_const goes from 1 to k, associated with each of a plurality of levels inside the basic constellation, and having a constellation index positive_const, where positive_const goes from k+1 to 3k, associated with a plurality of levels outside the basic constellation of levels. 12. The decoder according to claim 11, wherein each of the plurality of levels outside the basic constellation of levels are mapped onto a level inside the basic constellation according to the equation: 13. The decoder according to claim 11, wherein the mapper further includes a comparator operably coupled to the table, the comparator generating an output signal identifying an index closest to the received signals. 14. The decoder according to claim 13, wherein the mapper further includes an output block operably coupled to the table and the comparator, the output block generating a decoded signal corresponding to the index closest to the received signal level, if the index is within the basic constellation of signal levels. 15. The decoder according to claim 13, wherein the mapper further includes an output block operably coupled to the table and the comparator, the output block generating a decoded signal corresponding to the index plus an offset J, if the index is outside the basic constellation of levels. 16. A method of decoding a received signal, the method comprising:mapping a received signal contained in a first distinct range onto a basic level according to a first arithmetic rule, andmapping a received signal contained in a second distinct range onto the basic level according to a second arithmetic rule. 17. The method of claim 16, wherein the first distinct range forms part of a first constellation having a plurality of signal levels some of which are separated by a distance D 1 and the second distinct range forms part of a second constellation having a plurality of signal levels some of which are separated by a distance D 2 that differs from D 1 . 18. The method according to claim 17, wherein the mapping step further includes mapping a received signal in the first distinct range onto the basic level by partitioning the first constellation into a plurality of signal levels, some of the signal levels being separated by the distance D 1 . 19. The method according to claim 18, further including the step of indexing the first constellation and mapping the partitioned first constellation onto a basic constellation of levels as a function of the indexes. 20. The method according to claim 19, further including the step of mapping the partitioned first constellation onto the basic constellation of levels by adding an offset J to the indexes. 21. The method according to claim 16, further including the step of identifying whether the received signal is contained in a first constellation of levels or a second constellation of levels. 22. The method of claim 21, further including the step of associating an index with the received signal, the index identifying a signal level in the identified constellation of signal levels that is equivalent to the received signal. 23. The method according to claim 22, further including the step of forming a mapped index signal, the mapped index signal being equal to the sum of an offset J and the associated index, such that the mapped index signal is associated with the basic level. 24. The method of claim 22, wherein the associating step further includes comparing the received signal with a table of received signal levels and their associated indexes. 25. The method according to claim 17, wherein the basic level is one level within a basic constellation of levels and wherein the mapping step maps each distinct range onto only one level inside the basic constellation of levels, such that a one-to-one mapping is created from each distinct range to a level inside the basic constellation of levels.
Ayanoglu Ender (Red Bank NJ) Golden Glenn D. (Tinton Falls NJ) Jones Raymond K. (Voorhees NJ) Mazo James E. (Fair Haven NJ) Shaw David G. (Middletown NJ), High speed quantization-level-sampling modem with equalization arrangement.
Ayanoglu Ender (Atlantic Highlands NJ) Dagdeviren Nuri R. (Red Bank NJ) Mazo James E. (Fair Haven NJ) Saltzberg Burton R. (Middletown NJ), High-speed modem synchronized to a remote CODEC.
Betts William L. (St. Petersburg FL) Zuranski Edward S. (Largo FL), Method and apparatus for adaptively providing precoding and preemphasis conditioning to signal data for transfer over a.
Karabed Razmik ; Nazari Nersi ; Popplewell Andrew,GBX ; Carew Isaiah A., System and method for generating many ones codes with hamming distance after precoding.
Olafsson Sverrir,ISX ; Zhou Zhenyu ; Zhang Xuming, System for controlling and shaping the spectrum and redundancy of signal-point limited transmission.
Turner Michael D. ; Schneider Kevin W. ; Burch Richard A. ; Goodson Richard L., Use of modified line encoding and low signal-to-noise ratio based signal processing to extend range of digital data tran.
※ AI-Helper는 부적절한 답변을 할 수 있습니다.