RU96101998A

RU96101998A - METHOD AND DEVICE FOR DETERMINING AT THE RECEIVER OF THE SYSTEM OF COMMUNICATION OF THE SPEED OF TRANSMISSION OF DATA TRANSMITTED TO VARIABLE SPEED

Info

Publication number: RU96101998A
Application number: RU96101998/09A
Authority: RU
Inventors: К.Батлер Брейн; Падовани Роберто; Зихави Ифрейм
Original assignee: Квэлкомм Инкорпорейтед
Priority date: 1993-06-18
Filing date: 1994-06-20
Publication date: 1998-06-20

Claims

1. The method of determining in the receiver of a communication system with a variable data rate a data rate of a received signal, characterized in that it includes decoding and re-encoding operations with a first data rate of a received signal to generate a first predicted value of the received signal and to generate a first quality indication, comparing the first predicted value of the received signal with the received signal and counting the first number of errors when errors occur when The clear signal is incompatible with the first predicted value of the received signal, and when the first number of errors and the first quality indication determine the first error metric, reduce the received signal to form a second received signal representing the second data rate, decode and re-encode the second data rate of the second received signal for the formation of the second predicted value of the received signal and for the formation of the second quality indication, comparing the second prog the nosed value of the received signal with the second received signal and counting the second number of errors when an error occurs, when the second received signal is incompatible with the second predicted value of the received signal and the second number of errors and the second quality indication determine the second error metric, and predicting the data rate of the received signal based on comparing each error metric.

2. The method according to p. 1, characterized in that it includes the operation of reducing the received signal to generate a third received signal representing a third data rate, decoding and re-encoding with a third data rate of the third received signal to generate a third predicted value of the received signal and for generating a third quality indication and comparing the third predicted value of the received signal with the third received signal and counting a third number of errors, to yes incompatibility occurs when third received error signal with the predicted value of the third received signal and the third number of errors and the third quality indication define a third error metric.

3. The method according to p. 2, characterized in that it includes operations to reduce the received signal to generate a fourth received signal representing the fourth data rate, decode and re-encode the fourth data rate of the fourth received signal to generate the fourth predicted value of the received signal and for generating a fourth quality indication, and comparing the fourth predicted value of the received signal with the fourth received signal and counting the fourth The number of errors, when an error occurs incompatibility fourth received signal with the predicted value of the fourth received signal and a fourth number of errors and fourth quality indication define a fourth error metric.

4. The method according to claim 1, characterized in that the operation of reducing the received signal includes dividing the received signal in time to form a previously received signal and a later received signal and summing the previously received signal with a later received signal to generate a second received signal.

5. The method according to p. 1, characterized in that the received signal is divided in time into many segments, and the operation of reducing the received signal includes selecting a subset of the specified many segments of the received signal to form the second received signal.

6. The method according to claim 2, characterized in that the operation of reducing the received signal to generate the third signal includes dividing in time the second received signal to form the previously received second signal and the later received second signal and summing the previously received second signal and the later received second signal for the formation of the third received signal.

7. The method according to claim 2, characterized in that the second received signal is divided in time into many segments, and the operation of reducing the received signal to generate the third signal includes selecting a subset of the specified many segments of the second received signal to generate the third received signal.

8. The method according to claim 1, characterized in that the quality indication is the result of monitoring using a cyclic redundancy code.

9. The method according to claim 3, characterized in that the first data transfer rate corresponds to full speed communication, the second data transfer rate corresponds to 1/2 speed communication, the third speed corresponds to 1/4 speed communication and the fourth speed communication to 1 / 8 speeds.

10. The method according to claim 9, characterized in that the first to fourth quality indicators are a single bit binary quality indication each, the symbol "1" indicating a high probability that the data rate of the received signal is the data rate that corresponds to the indicated indication quality, and the symbol "0" indicates that the data rate of the received signal is not the data rate that corresponds to the specified quality indication.

11. The method according to claim 10, characterized in that the operation of predicting the data rate of the received signal includes predicting the first data rate if the state (first quality indication = 1 and second quality indication = 1) is true and the state (first number of errors ≤ a second number of errors + T ₁₎ is true, or if the status (first quality indication = 1 and a second quality indication = 1) is false and condition (first quality indication = 1 and the first number of errors ≤ T ₂₎ is true, n ognozirovanie indication half rate, if the state (first quality indication = 1 and a second quality indication = 1) is true and condition (the first number of errors ≤ second number of errors + _T1) is false, or if the status (first quality indication = 1 and the second quality indication = 1) is false and condition (first quality indication = 1 and the first number of errors ≤ _T2) is false and condition (second quality indication = 1 and a second number of errors ≤ T ₃₎ is true and condition (the fourth display achestva = 1 and the third quality indication = 0 or fourth number of errors ≤ third number of errors) is true and condition (the second number of errors ≤ fourth number of errors + T ₄₎ is true, or if the status (first quality indication = 1 and a second quality indication = 1) is false and the state (first quality indication = 1 and the first number of errors ≤ T ₂ ) is false and the state (second quality indication = 1 and the second number of errors ≤ T ₃ ) is true and the state (fourth quality indication = 1 and the third quality indication = 0 or the fourth number of errors ≤ the third number of errors) is false and the state (third quality indication = 1) is true and the state (second number of errors ≤ the third number of errors + T ₅ ) is true, or if the state (first indication quality = 1 and the second quality indication = 1) is false and the state (first quality indication = 1 and the first number of errors ≤ T ₂ ) is false and the state (second quality indication = 1 and the second number of errors ≤ T ₃ ) is true and with condition (fourth quality indication = 1 and third quality indication = 0 or fourth number of errors ≤ the third number of errors) is false and the state (third quality indication = 1) is false; forecasting the 1/4 speed indication if the state (first quality indication = 1 and second quality indication = 1) is false and the state (first quality indication = 1 and the first number of errors ≤ T ₂ ) is false and the state (second quality indication = 1 and a second number of errors ≤ T ₃₎ is true and condition (the fourth quality indication = 1 and the third indication = 0 or fourth number of errors ≤ third number of errors) is false and condition (the third quality indication = 1) is true and condition (second count honors errors ≤ third number of errors + T ₅₎ is false, or if the status (first quality indication = 1 and a second quality indication = 1) is false and condition (first quality indication = 1 and the first number of errors ≤ _T2) is false and the state (second quality indication = 1 and the second number of errors ≤ T ₃ ) is false and the state (third quality indication = 1 and the fourth quality indication = 1) is true and the state (fourth number of errors <third number of errors and fourth number of errors ≤ T ₆ ) is false and the state (the third number of errors <the fourth number of errors and the third number of errors ≤ T ₇ ) is true, or if the state (first quality indication = 1 and the second quality indication = 1) is false and the state (first quality indication = 1 and the first number of errors ≤ T ₂ ) is false and the state (second quality indication = 1 and the second number of errors ≤ T ₃ ) is false and the state (third quality indication = 1 and the fourth quality indication = 1) is false and the state (third indication qual = = 1 and the third number of errors ≤ T ₈ ) is true; and predicting the 1/8 speed indication if the state (first quality indication = 1 and second quality indication = 1) is false and the state (first quality indication = 1 and the first number of errors ≤ T ₂ ) is false and the state (second quality indication = 1 and the second number of errors ≤ T ₃ ) is true and the state (fourth quality indication = 1 and the third quality indication = 0 or the fourth number of errors to the third number of errors) is true and the state (second number of errors ≤ the fourth number of errors + T) false, or if the state (first quality indication = 1 and the second quality indication = 1) is false and the state (first quality indication = 1 and the first number of errors ≤ T ₂ ) is false and the state (second quality indication = 1 and the second number of errors <T _{3 is} false and the state (third quality indication = 1 and fourth quality indication = 1) is true and the state (fourth number of errors <third number of errors and fourth number of errors ≤ T ₆ ) is true or if the state (first quality indication = 1 and Thoraya quality indication = 1) is false and condition (the first display quality = 1 and the first number of errors ≤ _T2) is false and condition (second quality indication = 1 and a second number of errors ≤ T ₃₎ is false and condition (the third quality indication = 1 and the fourth quality indication = 1) is false and the state (third quality indication = 1 and the third number of errors ≤ T ₈ ) is false and the state (fourth quality indication = 1 and the fourth number of errors ≤ T ₉ ) is true, where T ₁ - T ₁₀ are fixed and constants.

12. The method according to claim 11, characterized in that it includes the operation of forming an indication of an unrecoverable error if the state (first quality indication = 1 and second quality indication = 1) is false and the state (first quality indication = 1 and the number of errors ≤ T ₂ ) is false and the state (second quality indication = 1 and the second number of errors ≤ T ₃ ) is false and the state (third quality indication = 1 and the fourth quality indication = 1) is true and the state (fourth number of errors <third number of errors and fourth the number of errors ≤ T ₆ ) is false and the state (the third number of errors <the fourth number of errors and the third number of errors ≤ T ₇ ) is false, or if the state (first quality indication = 1 and second quality indication = 1) is false and the state ( the first quality indication = 1 and the number of errors ≤ T ₂ ) is false and the state (second quality indication = 1 and the second number of errors ≤ T ₃ ) is false and the state (third quality indication = 1 and fourth quality indication = 1) is false and condition (third and quality indication = 1 and the third number of errors ≤T ₈ ) is false and the state (fourth quality indication = 1 and the fourth number of errors ≤ T ₉ ) is false and the state (number of errors ≤ T ₁₀ ) is false.

13. The method according to p. 12, characterized in that it includes the operation of generating full speed with bit errors if the state (first quality indication = 1 and second quality indication = 1) is false and the state (first quality indication = 1 and the number of errors ≤ T ₂ ) is false and the state (second quality indication = 1 and the second number of errors ≤ T ₃ ) is false and the state (third quality indication = 1 and the fourth quality indication = 1) is false and the state (third quality indication = 1 and third the number of errors ≤ T ₈ ) is is false and the state (fourth quality indication = 1 and the fourth number of errors ≤ T ₉ ) is false and the state (number of errors ≤ T ₁₀ ) is true.

14. The method according to claim 11, characterized in that the total speed during communication is 9,600 bps.

15. The method according to p. 13, characterized in that the total speed during communication is 9 600 b / s.

16. The method according to item 13, wherein T ₁ = 15, T ₂ = 77, T ₃ = 60, T ₄ = 10, T ₅ = 10, T ₆ = 64, T ₇ = 60, T ₈ = 60, T ₉ = 64, T ₁₀ = 71.

17. The method according to item 13, wherein T ₁ = 15, T ₂ = 110, T ₃ = 84, T ₄ = 10, T ₅ = 10, T ₆ = 96, T ₇ = 76, T ₈ = 76, T ₉ = 96, T ₁₀ = 78.

18. A method of decoding a received signal at an unknown data rate in a receiver of a communication system with a variable data rate, characterized in that it includes decoding operations with a first data rate of the received signal to generate a first decoded received signal and to generate a first quality indication, re-encoding with a first data rate of the first decoded received signal to generate a first predicted value of the received signal, s Aviation of the first predicted value of the received signal with the received signal and counting the first number of errors when an error occurs when the received signal is incompatible with the first predicted value of the received signal and when the first number of errors and the first quality indication determine the first metric of error, decoding with the second data rate of the received signal for generating a second decoded received signal and for generating a second quality indication, re-encoding from the second the data rate of the second decoded received signal to generate a second predicted value of the received signal, compare the second predicted value of the received signal with the specified received signal, and calculate the second number of errors when an error occurs when the received signal is incompatible with the second predicted value of the received signal and when the second number of errors and the second quality indication determines the second metric of errors, predicting the unknown data rate based on a comparison of each metric among the indicated error metrics and the use in the further data processing of a decoded received signal that corresponds to a predicted unknown data rate.

19. Device for estimating the data rate of a signal received from a transmitter for transmitting data with multiple data rates, characterized in that it contains a first Viterbi decoder having an input for receiving the specified signal and an output, a first quality indication generator having an input connected with the output of the first Viterbi decoder, and the output, the first coding device having an input connected to the output of the first Viterbi decoder, and the output, the first comparator having the first input connected to the output of the first a measuring device, a second input for receiving the specified signal and an output, a first counter having an input connected to the output of the first comparator, and an output, a second Viterbi decoder having an input for receiving the specified signal and an output, a second quality indication generator having an input associated with the output of the second Viterbi decoder, and the output, the second encoding device having an input connected to the output of the second Viterbi decoder, and the output, the second comparator having the first input connected to the output of the second Viterbi decoder, the second input for receiving and the specified signal and output, a second counter having an input connected to the output of the second comparator, and an output, and a processor having many inputs and an output, the first input of the processor being connected to the output of the first counter, the second input to the output of the second counter, the third input - with the output of the first generator of quality indicators and the fourth input with the output of the second generator of quality indicators, and the processor output is designed to provide estimates of the data rate of the specified signal.

20. The device according to claim 19, characterized in that it contains a first selector included between the input of the specified signal and the second Viterbi decoder.

21. The device according to claim 20, characterized in that it contains a first adder included between the input of the specified signal and the second Viterbi decoder.

22. The device according to claim 19, characterized in that it contains a third Vitterby decoder having a signal reception input and output, a third quality indication generator having an input connected to the output of the third Viterbi decoder, and an output, a third encoding device having an input connected with the output of the third Viterbi decoder, and the output, the third comparator having a first input connected to the output of the third encoder, a second input for receiving the specified signal and output, a third counter having an input connected to the output of the third comparator, and output, p Moreover, the processor has a fifth input connected to the output of the third counter, and a sixth input connected to the output of the third quality indication generator.

23. The device according to p. 22, characterized in that it contains a first selector included between the input of the specified signal and the second Viterbi decoder.

24. The device according to p. 22, characterized in that it contains a first adder connected between the input of the specified signal and the second Viterbi decoder.

25. The device according to item 23, wherein the second selector is included between the first selector and the third Viterbi decoder.

26. The device according to paragraph 24, characterized in that it contains a second adder included between the first adder and the third Viterbi decoder.

27. A method of decoding a received signal at an unknown data rate in a receiver of a communication system with a variable data rate, characterized in that it includes decoding operations with a first data rate of the received signal to generate a first decoded received signal and to generate a first quality indication, re-encoding with a first data rate of the first decoded received signal to generate a first predicted value of the received signal, s Aviation of the first predicted value of the received signal with the received signal and counting the first number of errors when an error occurs when the received signal is incompatible with the first predicted value of the received signal and when the first number of errors and the first quality indication determine the first metric of errors, decoding at the second data rate of the received signal for generating a second decoded received signal and for generating a second quality indication, re-encoding from the second the data rate of the second decoded received signal to generate a second predicted value of the received signal, compare the second predicted value of the received signal with the received signal, and calculate the second number of errors when an error occurs when the received signal is incompatible with the second predicted value of the received signal and when the second number of errors and the second quality indication determine the second metric of errors, decoding with a third data rate received with a needle to generate a third decoded received signal and to generate a third quality indication, re-encoding with a third data rate a third decoded received signal to generate a third predicted value of the received signal, compare the third predicted value of the received signal with the received signal, and calculate the third number of errors when an error occurs when the received signal is incompatible with the third predicted value of the received signal and where the third number of errors and the third quality indication determine the third error metric, and predicting the specified unknown data rate based on a comparison of each metric from among the specified error metrics.

28. The method according to p. 27, characterized in that the first and third quality indicators are single-bit quality indicators each, in which the symbol "1" indicates a high probability of successful decoding with the specified data rate corresponding to the specified quality indication, and the symbol "0" indicates the high probability of defective decoding with the specified data rate corresponding to the specified quality indication.

29. The method according to p. 28, wherein the prediction operation includes predicting the first predicted data rate if the first quality indication is “1” and the first number of errors is less than the threshold number.

30. The method according to p. 28, wherein the prediction operation includes predicting a first data rate if the first quality indication is “1” and the second quality indication is “1” and the first number of errors is less than or equal to the second number of errors plus a predetermined number .

31. The method according to p, characterized in that the data transfer rate is 14,400 bits / s.

32. A method of decoding a received signal with a known data rate at a receiver that decodes and re-encodes the specified signal with a plurality of data rates, generates a quality indication for each data rate from among the plurality, and compares each decoded and re-encoded signal with the specified signal and counts the number of errors during each comparison, characterized in that it includes the operation of selecting the first data rate, if the indication to the value corresponding to the first data rate indicates successful decoding with the first data rate, and if the number of errors corresponding to the first data rate is less than the first threshold value, and the second data rate is selected if the quality indication corresponding to the first data rate, indicates successful decoding and quality indication corresponding to the second data rate, indicates successful decoding, and if the number of errors corresponding to The data transfer rate exceeds the second threshold value.

33. The method according to p, characterized in that the first threshold value is a given constant.

34. The method according to p, characterized in that the first threshold value is a given constant plus the number of errors corresponding to the second data rate.

35. The method according to p, characterized in that the first and second threshold values are equal and are a given constant plus the number of errors corresponding to the second data rate.

36. The method according to p, characterized in that it includes the operation of selecting a second data rate if the quality indication corresponding to the first data rate indicates unsuccessful decoding with the first data rate, and if the quality indication corresponding to the second data rate indicates successful decoding with a second data rate, and if the quality indication corresponding to the third data rate indicates unsuccessful decoding with a third data rate and if and a quality indication corresponding to the fourth data rate indicates successful decoding with the fourth data rate, and the number of errors corresponding to the second data rate is less than or equal to the third threshold value.

37. The method according to clause 36, wherein the third threshold value is a given constant plus the number of errors corresponding to the fourth data rate.

38. The method according to p. 32, characterized in that it includes the operation of selecting a fourth data rate, if the quality indication corresponding to the first data rate indicates unsuccessful decoding with the first data rate and if the quality indication corresponding to the second data rate successful decoding with a second data rate, and if the quality indication corresponding to the third data rate indicates unsuccessful decoding with a third data rate and If quality indication corresponding to a fourth data rate indicates successful decoding of the fourth data rate and the number of errors corresponding to said second data rate exceeds a third threshold value.

39. The method according to § 38, wherein the third threshold value is a given constant plus the number of errors corresponding to the fourth data rate.

40. The method according to p, characterized in that it includes the operation of selecting a second data rate if the quality indication corresponding to the first data rate indicates unsuccessful decoding with the first data rate, and if the quality indication corresponding to the second data rate, indicates successful decoding with a second data rate, and if the quality indication corresponding to the third data rate indicates unsuccessful decoding with a third data rate, and ec quality indication corresponding to a fourth data rate indicates unsuccessful decoding of the fourth data rate.

41. The method according to p, characterized in that it includes the operation of selecting a second data rate, if the quality indication corresponding to the first data rate indicates unsuccessful decoding with the first data rate, and if the quality indication corresponding to the second data rate, indicates successful decoding with a second data rate, and if the quality indication corresponding to the third data rate indicates successful decoding with a third data rate, and if quality indication corresponding to a fourth data rate indicates successful decoding of the fourth data rate and the number of errors, corresponding to a second data rate less than or equal to the number of errors corresponding to the third data rate plus a fixed constant.

42. The method according to p. 32, characterized in that it includes the operation of selecting a third data rate if the quality indication corresponding to the first data rate indicates unsuccessful decoding with the first data rate, and if the quality indication corresponding to the second data rate, indicates successful decoding with a second data rate, and if the quality indication corresponding to the third data rate indicates successful decoding with a third data rate, and ec whether the quality indication corresponding to the fourth data rate indicates successful decoding with the fourth data rate, and the number of errors corresponding to the second data rate exceeds the number of errors corresponding to the third data rate plus a fixed constant.

43. The method according to p, characterized in that it includes operations to select the fourth speed, if the quality indication corresponding to the data rate indicates unsuccessful decoding with the first data rate, and if the quality indication corresponding to the second data rate indicates unsuccessful decoding with the second data rate, and if the quality indication corresponding to the third data rate indicates unsuccessful decoding with the third data rate, and if the quality indication and the corresponding fourth data rate indicates successful decoding of the fourth data rate and the number of errors, corresponding to a fourth data rate is less than or equal to the third predetermined threshold value.

44. A device for estimating the data rate of a signal received from a transmitter for transmitting data with multiple data rates, characterized in that it contains a first decoder having an input for receiving the specified signal, the output of the decoded signal and the output of the quality indication, the first encoding device, having an input connected to the output of the decoded signal of the first decoder, and an output, a first comparator having a first input connected to the output of the first encoder, a second input for receiving the indicated signal and output, the first counter having an input connected to the output of the first comparator, and the output, the second decoder having an input for receiving the specified signal, the output of the decoded signal and the output of the quality indication, the second encoding device having an input connected to the output of the decoded signal a second decoder, and an output, a second comparator having a first input connected to the output of the second encoder, a second input to receive the specified signal and an output, a second counter having an input connected to the output of the second com arator, and an output, and a processor having many inputs and an output, the first input connected to the output of the first counter, the second input to the output of the second counter, the third input to the output of the quality indication of the first decoder, the fourth input to the output of the quality indication of the second decoder , and the processor output is designed to provide estimates of the data rate of the specified signal.

45. A device for estimating the data rate of a signal received from a transmitting device for transmitting data with multiple data rates, characterized in that it comprises decoding means for sequentially decoding the specified signal with multiple data rates for sequentially generating an output decoded signal corresponding to each speed from among the many data transfer rates, and for sequentially issuing an output quality indication, respectively coding means for sequentially coding an output decoded signal corresponding to each speed from among a plurality of data rates, and for sequentially generating an estimate of a received signal corresponding to each speed from among a plurality of data rates, means for sequentially comparing the specified signal with an estimate of the received signal corresponding to each speed from among the set of speeds n data transmission, and for forming an indication, when the estimate of the received signal is erroneous with respect to the specified signal, means for sequentially generating samples of indications corresponding to each speed from among the plurality of data transmission speeds, data processing means for receiving said samples corresponding to each speed from the set of data rates and output quality indications, respectively, of each speed from among a plurality of data rates for estimating transmission rates said signal data.

46. The method according to item 13, wherein T ₁ is about 4% of the number of characters in the data group, T ₂ is about 20% of the number of characters in the data group, T ₃ is about 16% of the number of characters in the data group , T ₄ - about 3% of the number of characters in the data group, T ₅ - about 3% of the number of characters in the data group, T ₆ - about 17% of the number of characters in the data group, T ₇ - about 16% of the number of characters in group data T ₈ - about 16% of the number of characters in the data group T ₉ - about 17% of the number of characters in the data group T ₁₀ - about 19% of the sym s in the data group.

47. The method according to item 13, wherein T ₁ is about 4% of the number of characters in the data group, T ₂ is about 29% of the number of characters in the data group, T ₃ is about 22% of the number of characters in the data group , T ₄ - about 3% of the number of characters in the data group, T ₅ - about 3% of the number of characters in the data group, T ₆ - about 25% of the number of characters in the data group, T ₇ - about 20% of the number of characters in group data T ₈ - about 20% of the number of characters in the data group T ₉ - about 25% of the number of characters in the data group T ₁₀ - about 20% of the sym s in the data group.