초록 ▼

For soft handoff on the reverse link with restrictive reuse, a wireless terminal searches for pilots transmitted by sectors in a wireless system, measures the detected pilots, selects a serving sector (e.g., the strongest received sector), and identifies non-serving sectors that may receive high int

For soft handoff on the reverse link with restrictive reuse, a wireless terminal searches for pilots transmitted by sectors in a wireless system, measures the detected pilots, selects a serving sector (e.g., the strongest received sector), and identifies non-serving sectors that may receive high interference from the terminal. The serving sector assigns the terminal with subband(s) that are usable by the serving sector and unusable by the non-serving sectors. The terminal transmits data symbols on the assigned subbands to the serving and non-serving sectors. These sectors process the reverse link transmission from the terminal and obtain soft-decision symbols, which are estimates of the transmitted data symbols. The soft-decision symbols from co-located sectors may be combined and then decoded to obtain decoded packets. The sectors may also independently decode the soft-decision symbols, and the decoded packets from these sectors may be combined to obtain final decoded packets for the terminal.

대표청구항 ▼

What is claimed is: 1. A method of allocating frequency subbands to support soft handoff in a wireless communication system, comprising: ascertaining a serving sector and at least one non-serving sector for a wireless terminal, the serving sector being a sector with which the terminal communicates,

What is claimed is: 1. A method of allocating frequency subbands to support soft handoff in a wireless communication system, comprising: ascertaining a serving sector and at least one non-serving sector for a wireless terminal, the serving sector being a sector with which the terminal communicates, and each non-serving sector being a sector potentially receiving high interference from the terminal on a reverse link; determining a restricted set of frequency subbands based on the serving sector and the at least one non-serving sector, the frequency subbands in the restricted set being allocable to the terminal for data transmission; and assigning the terminal with at least one frequency subband selected from the restricted set for data transmission on the reverse link. 2. The method of claim 1, wherein the determining the restricted set of frequency subbands comprises forming the restricted set based on a usable set of frequency subbands for the serving sector and a forbidden set of frequency subbands for each of the at least one non-serving sector, the frequency subbands in the usable set being allocable to terminals in communication with the serving sector, and the frequency subbands in the forbidden set for each non-serving sector being unusable by terminals in communication with the non-serving sector. 3. The method of claim 2, wherein the restricted set is formed based on an intersection set operation between the usable set for the serving sector and the forbidden set for each of the at least one non-serving sector. 4. The method of claim 1, wherein the determining the restricted set of frequency subbands comprises forming the restricted set based on a usable set of frequency subbands for the serving sector and a limited use set of frequency subbands for each of the at least one non-serving sector, the frequency subbands in the usable set being allocable to terminals in communication with the serving sector, and the frequency subbands in the limited use set for each non-serving sector being usable by terminals in communication with the non-serving sector and having a lower transmit power limit. 5. The method of claim 1, wherein the serving sector and the at least one non-serving sector are ascertained based on pilot measurements for sectors received by the terminal. 6. An apparatus in a wireless communication system, comprising: a controller operable to ascertain a serving sector and at least one non-serving sector for a wireless terminal, the serving sector being a sector with which the terminal communicates, and each non-serving sector being a sector potentially receiving high interference from the terminal on a reverse link, determine a restricted set of frequency subbands based on the serving sector and the at least one non-serving sector, the frequency subbands in the restricted set being allocable to the terminal for data transmission, and assign the terminal with at least one frequency subband selected from the restricted set for data transmission on the reverse link. 7. The apparatus of claim 6, wherein the controller is operable to form the restricted set based on a usable set of frequency subbands for the serving sector and a forbidden set of frequency subbands for each of the at least one non-serving sector, the frequency subbands in the usable set being allocable to terminals in communication with the serving sector, and the frequency subbands in the forbidden set for each non-serving sector being unusable by terminals in communication with the non-serving sector. 8. The apparatus of claim 6, wherein the serving sector and the at least one non-serving sector are ascertained based on pilot measurements for sectors received by the terminal. 9. The apparatus of claim 6, wherein the wireless communication system utilizes orthogonal frequency division multiplexing (OFDM). 10. The apparatus of claim 6, wherein the wireless communication system is an orthogonal frequency division multiple access (OFDMA) system utilizing frequency hopping. 11. An apparatus in a wireless communication system, comprising: means for ascertaining a serving sector and at least one non-serving sector for a wireless terminal, the serving sector being a sector with which the terminal communicates, and each non-serving sector being a sector potentially receiving high interference from the terminal on a reverse link; means for determining a restricted set of frequency subbands based on the serving sector and the at least one non-serving sector, the frequency subbands in the restricted set being allocable to the terminal for data transmission; and means for assigning the terminal with at least one frequency subband selected from the restricted set for data transmission on the reverse link. 12. The apparatus of claim 11, wherein the means for determining the restricted set of frequency subbands comprises means for forming the restricted set based on a usable set of frequency subbands for the serving sector and a forbidden set of frequency subbands for each of the at least one non-serving sector, the frequency subbands in the usable set being allocable to terminals in communication with the serving sector, and the frequency subbands in the forbidden set for each non-serving sector being unusable by terminals in communication with the non-serving sector. 13. The apparatus of claim 11, wherein the serving sector and the at least one non-serving sector are ascertained based on pilot measurements for sectors received by the terminal. 14. A method of receiving a data transmission from a wireless terminal in a wireless communication system, comprising: obtaining a received signal having a reverse link signal transmitted by the terminal, the terminal being assigned at least one frequency subband selected from a restricted set of frequency subbands, wherein the restricted set of frequency subbands are determined based on a serving sector and at least one non-serving sector for the terminal, the serving sector being a sector with which the terminal communicates, and each non-serving sector being a sector potentially receiving high interference from the terminal; processing the received signal to obtain soft-decision symbols for the at least one frequency subband assigned to the terminal; and decoding the soft-decision symbols to obtain decoded data for the terminal. 15. The method of claim 14, wherein the restricted set is formed based on a usable set of frequency subbands for the serving sector and a forbidden set of frequency subbands for each of the at least one non-serving sector, the frequency subbands in the usable set being allocable to terminals in communication with the serving sector, and the frequency subbands in the forbidden set for each non-serving sector being unusable by terminals in communication with the non-serving sector. 16. The method of claim 14, further comprising: receiving soft-decision symbols obtained by the at least one non-serving sector for the terminal; and combining the soft-decision symbols obtained by the serving sector with the soft-decision symbols obtained by the at least one non-serving sector, and wherein the combined soft-decision symbols are decoded to obtain the decoded data for the terminal. 17. The method of claim 16, further comprising: estimating interference level for a group of frequency subbands containing the at least one subband assigned to the terminal; and determining whether to combine the soft-decision symbols obtained by the serving and non-serving sectors based on the estimated interference level. 18. The method of claim 14, further comprising: receiving decoded data obtained by the at least one non-serving sector for the terminal; and combining the decoded data obtained by the serving sector and the decoded data obtained by the at least one non-serving sector to obtain output decoded data for the terminal. 19. The method of claim 18, wherein the combining comprises for each data packet transmitted by the terminal, selecting a correctly decoded data packet for the transmitted data packet from either the serving sector or one of the at least one non-serving sector, if available. 20. The method of claim 14, further comprising: maintaining an instance of a Radio Link Protocol (RLP) for the terminal at the serving sector and at each of the at least one non-serving sector. 21. An apparatus in a wireless communication system, comprising: a receiver unit operable to process a received signal and provide data samples, the received signal including a reverse link signal transmitted by a wireless terminal assigned with at least one frequency subband selected from a restricted set of frequency subbands, wherein the restricted set of frequency subbands are determined based on a serving sector and at least one non-serving sector for the terminal, the serving sector being a sector with which the terminal communicates, and each non-serving sector being a sector potentially receiving high interference from the terminal; a demodulator operable to process the data samples to obtain soft-decision symbols for the at least one frequency subband assigned to the terminal; and a decoder operable to decode the soft-decision symbols to obtain decoded data for the terminal. 22. The apparatus of claim 21, wherein the decoder is further operable to receive soft-decision symbols obtained by the at least one non-serving sector for the terminal, combine the soft-decision symbols obtained by the serving sector with the soft-decision symbols obtained by the at least one non-serving sector, and decode the combined soft-decision symbols to obtain the decoded data for the terminal. 23. The apparatus of claim 21, wherein the decoder is further operable to receive decoded data obtained by the at least one non-serving sector for the terminal and to combine the decoded data obtained by the serving sector and the decoded data obtained by the at least one non-serving sector to obtain output decoded data for the terminal. 24. An apparatus in a wireless communication system, comprising: means for obtaining a received signal having a reverse link signal transmitted by a wireless terminal, the terminal being assigned at least one frequency subband selected from a restricted set of frequency subbands, wherein the restricted set of frequency subbands are determined based on a serving sector and at least one non-serving sector for the terminal, the serving sector being a sector with which the terminal communicates, and each non-serving sector being a sector potentially receiving high interference from the terminal; means for processing the received signal to obtain soft-decision symbols for the at least one frequency subband assigned to the terminal; and means for decoding the soft-decision symbols to obtain decoded data for the terminal. 25. The apparatus of claim 24, further comprising: means for receiving soft-decision symbols obtained by the at least one non-serving sector for the terminal; and means for combining the soft-decision symbols obtained by the serving sector with the soft-decision symbols obtained by the at least one non-serving sector, and wherein the combined soft-decision symbols are decoded to obtain the decoded data for the terminal. 26. The apparatus of claim 24, further comprising: means for receiving decoded data obtained by the at least one non-serving sector for the terminal; and means for combining the decoded data obtained by the serving sector and the decoded data obtained by the at least one non-serving sector to obtain output decoded data for the terminal. 27. A method of transmitting data from a wireless terminal in a wireless communication system, comprising: obtaining an assignment of at least one frequency subband to use for data transmission by the terminal on a reverse link, the at least one frequency subband being selected from a restricted set of frequency subbands, wherein the restricted set of frequency subbands are determined based on a serving sector and at least one non-serving sector for the terminal, the serving sector being a sector with which the terminal communicates, and each non-serving sector being a sector potentially receiving high interference from the terminal on the reverse link; processing data to generate data symbols; and multiplexing the data symbols onto the at least one frequency subband assigned to the terminal. 28. The method of claim 27, wherein the restricted set is formed based on a usable set of frequency subbands for the serving sector and a forbidden set of frequency subbands for each of the at least one non-serving sector, the frequency subbands in the usable set being allocable to terminals in communication with the serving sector, and the frequency subbands in the forbidden set for each non-serving sector being unusable by terminals in communication with the non-serving sector. 29. The method of claim 27, further comprising: generating a reverse link signal having the data symbols multiplexed onto the at least one frequency subband assigned to the terminal; and transmitting the reverse link signal to the serving sector and the at least one non-serving sector. 30. The method of claim 27, further comprising: detecting for pilots transmitted by sectors in the system; obtaining pilot measurements for detected pilots; and identifying the serving sector and the at least one non-serving sector based on the pilot measurements for the detected pilots. 31. The method of claim 30, further comprising: comparing the pilot measurements for the detected pilots against a threshold; and adding sectors having pilot measurements that exceed the threshold to a reuse set, and wherein the serving sector and the at least one non-serving sector are selected from the sectors in the reuse set. 32. The method of claim 31, wherein the serving sector is a sector with a strongest pilot measurement among the sectors in the reuse set, and wherein each of the at least one non-serving sector is a remaining sector in the reuse set. 33. The method of claim 27, wherein the serving sector and the at least one non-serving sector are ascertained based on pilot measurements made by the serving and non-serving sectors for the terminal. 34. The method of claim 27, wherein the serving sector and the at least one non-serving sector are ascertained based on a position estimate for the terminal. 35. The method of claim 27, further comprising: generating a pilot with an orthogonal sequence assigned to the serving sector; and transmitting the pilot on the reverse link. 36. The method of claim 35, wherein the serving sector and the at least one non-serving sector are assigned different orthogonal sequences. 37. The method of claim 27, further comprising: receiving a frequency hopping sequence assigned to the terminal; and determining the at least one frequency subband for each time interval with data transmission based on the frequency hopping sequence. 38. A wireless terminal in a wireless communication system, comprising: a controller operable to obtain an assignment of at least one frequency subband to use for data transmission by the terminal on a reverse link, the at least one frequency subband being selected from a restricted set of frequency subbands, wherein the restricted set of frequency subbands are determined based on a serving sector and at least one non-serving sector for the terminal, the serving sector being a sector with which the terminal communicates, and each non-serving sector being a sector potentially receiving high interference from the terminal on the reverse link; a transmit processor operable to process data to generate data symbols; and a multiplexer operable to multiplex the data symbols onto the at least one frequency subband assigned to the terminal. 39. The apparatus of claim 38, further comprising: a receive processor operable to detect for pilots transmitted by sectors in the system and obtain pilot measurements for detected pilots, and wherein the controller is further operable to ascertain the serving sector and the at least one non-serving sector based on the pilot measurements for the detected pilots. 40. The apparatus of claim 39, wherein the controller is further operable to compare the pilot measurements for the detected pilots against a threshold, add sectors having pilot measurements that exceed the threshold to a reuse set, and select the serving sector and the at least one non-serving sector from the sectors in the reuse set. 41. The apparatus of claim 38, wherein the controller is further operable to receive a frequency hopping sequence assigned to the terminal and to determine the at least one frequency subband for each time interval with data transmission based on the frequency hopping sequence. 42. A wireless terminal in a wireless communication system, comprising: means for obtaining an assignment of at least one frequency subband to use for data transmission by the terminal on a reverse link, the at least one frequency subband being selected from a restricted set of frequency subbands, wherein the restricted set of frequency subbands are determined based on a serving sector and at least one non-serving sector for the terminal, the serving sector being a sector with which the terminal communicates, and each non-serving sector being a sector potentially receiving high interference from the terminal on the reverse link; means for processing data to generate data symbols; and means for multiplexing the data symbols onto the at least one frequency subband assigned to the terminal. 43. The terminal of claim 42, further comprising: means for detecting for pilots transmitted by sectors in the system; means for obtaining pilot measurements for detected pilots; and means for identifying the serving sector and the at least one non-serving sector based on the pilot measurements for the detected pilots. 44. The terminal of claim 43, further comprising: means for comparing the pilot measurements for the detected pilots against a threshold; and means for adding sectors having pilot measurements that exceed the threshold to a reuse set, and wherein the serving sector and the at least one non-serving sector are selected from the sectors in the reuse set. 45. The terminal of claim 42, further comprising: means for receiving a frequency hopping sequence assigned to the terminal; and means for determining the at least one frequency subband for each time interval with data transmission based on the frequency hopping sequence. 46. A computer readable medium comprising executable codes, which, when executed by a processor, cause the processor: to ascertain a serving sector and at least one non-serving sector for a wireless terminal, the serving sector being a sector with which the terminal communicates, and each non-serving sector being a sector potentially receiving high interference from the terminal on a reverse link; to determine a restricted set of frequency subbands based on the serving sector and the at least one non-serving sector, the frequency subbands in the restricted set being allocable to the terminal for data transmission; and to assign the terminal with at least one frequency subband selected from the restricted set for data transmission on the reverse link. 47. The computer readable medium of claim 46, further comprising codes for causing the processor to form the restricted set based on a usable set of frequency subbands for the serving sector and a forbidden set of frequency subbands for each of the at least one non-serving sector, the frequency subbands in the usable set being allocable to terminals in communication with the serving sector, and the frequency subbands in the forbidden set for each non-serving sector being unusable by terminals in communication with the non-serving sector. 48. The computer readable medium of claim 46, further comprising codes for causing the processor to form the restricted set based on a usable set of frequency subbands for the serving sector and a limited use set of frequency subbands for each of the at least one non-serving sector, the frequency subbands in the usable set being allocable to terminals in communication with the serving sector, and the frequency subbands in the limited use set for each non-serving sector being usable by terminals in communication with the non-serving sector and having a lower transmit power limit. 49. The computer readable medium of claim 47, wherein the restricted set is formed based on an intersection set operation between the usable set for the serving sector and the forbidden set for each of the at least one non-serving sector. 50. The computer readable medium of claim 46, wherein the serving sector and the at least one non-serving sector are ascertained based on pilot measurements for sectors received by the terminal. 51. A computer readable medium comprising executable codes, which, when executed by a processor, cause the processor: to obtain a received signal having a reverse link signal transmitted by the terminal, the terminal being assigned at least one frequency subband selected from a restricted set of frequency subbands, wherein the restricted set of frequency subbands are determined based on a serving sector and at least one non-serving sector for the terminal, the serving sector being a sector with which the terminal communicates, and each non-serving sector being a sector potentially receiving high interference from the terminal; to process the received signal to obtain soft-decision symbols for the at least one frequency subband assigned to the terminal; and to decode the soft-decision symbols to obtain decoded data for the terminal. 52. The computer readable medium of claim 51, wherein the restricted set is formed based on a usable set of frequency subbands for the serving sector and a forbidden set of frequency subbands for each of the at least one non-serving sector, the frequency subbands in the usable set being allocable to terminals in communication with the serving sector, and the frequency subbands in the forbidden set for each non-serving sector being unusable by terminals in communication with the non-serving sector. 53. The computer readable medium of claim 51, further comprising: codes for causing the processor to receive soft-decision symbols obtained by the at least one non-serving sector for the terminal; and codes for causing the processor to combine the soft-decision symbols obtained by the serving sector with the soft-decision symbols obtained by the at least one non-serving sector, and wherein the combined soft-decision symbols are decoded to obtain the decoded data for the terminal. 54. The computer readable medium of claim 53, further comprising: codes for causing the processor to estimate interference level for a group of frequency subbands containing the at least one subband assigned to the terminal; and codes for causing the processor to determine whether to combine the soft-decision symbols obtained by the serving and non-serving sectors based on the estimated interference level. 55. The computer readable medium of claim 51, further comprising: codes for causing the processor to receive decoded data obtained by the at least one non-serving sector for the terminal; and codes for causing the processor to combine the decoded data obtained by the serving sector and the decoded data obtained by the at least one non-serving sector to obtain output decoded data for the terminal. 56. The computer readable medium of claim 55, further comprising: for each data packet transmitted by the terminal, codes for causing the processor to select a correctly decoded data packet for the transmitted data packet from either the serving sector or one of the at least one non-serving sector, if available. 57. The computer readable medium of claim 51, further comprising: codes for causing the processor to maintain an instance of a Radio Link Protocol (RLP) for the terminal at the serving sector and at each of the at least one non-serving sector. 58. A computer readable medium comprising executable codes, which, when executed by a processor, cause the processor: to obtain an assignment of at least one frequency subband to use for data transmission by the terminal on a reverse link, the at least one frequency subband being selected from a restricted set of frequency subbands, wherein the restricted set of frequency subbands are determined based on a serving sector and at least one non-serving sector for the terminal, the serving sector being a sector with which the terminal communicates, and each non-serving sector being a sector potentially receiving high interference from the terminal on the reverse link; to process data to generate data symbols; and to multiplex the data symbols onto the at least one frequency subband assigned to the terminal. 59. The computer readable medium of claim 58, wherein the restricted set is formed based on a usable set of frequency subbands for the serving sector and a forbidden set of frequency subbands for each of the at least one non-serving sector, the frequency subbands in the usable set being allocable to terminals in communication with the serving sector, and the frequency subbands in the forbidden set for each non-serving sector being unusable by terminals in communication with the non-serving sector. 60. The computer readable medium of claim 58, further comprising: codes for causing the processor to generate a reverse link signal having the data symbols multiplexed onto the at least one frequency subband assigned to the terminal; and codes for causing the processor to transmit the reverse link signal to the serving sector and the at least one non-serving sector. 61. The computer readable medium of claim 58, further comprising: codes for causing the processor to detect for pilots transmitted by sectors in the system; codes for causing the processor to obtain pilot measurements for detected pilots; and codes for causing the processor to identify the serving sector and the at least one non-serving sector based on the pilot measurements for the detected pilots. 62. The computer readable medium of claim 61, further comprising: codes for causing the processor to compare the pilot measurements for the detected pilots against a threshold; and codes for causing the processor to add sectors having pilot measurements that exceed the threshold to a reuse set, and wherein the serving sector and the at least one non-serving sector are selected from the sectors in the reuse set. 63. The computer readable medium of claim 62, wherein the serving sector is a sector with a strongest pilot measurement among the sectors in the reuse set, and wherein each of the at least one non-serving sector is a remaining sector in the reuse set. 64. The computer readable medium of claim 58, wherein the serving sector and the at least one non-serving sector are ascertained based on pilot measurements made by the serving and non-serving sectors for the terminal. 65. The computer readable medium of claim 58, wherein the serving sector and the at least one non-serving sector are ascertained based on a position estimate for the terminal. 66. The computer readable medium of claim 58, further comprising: codes for causing the processor to generate a pilot with an orthogonal sequence assigned to the serving sector; and codes for causing the processor to transmit the pilot on the reverse link. 67. The computer readable medium of claim 66, wherein the serving sector and the at least one non-serving sector are assigned different orthogonal sequences. 68. The computer readable medium of claim 58, further comprising: codes for causing the processor to receive a frequency hopping sequence assigned to the terminal; and codes for causing the processor to determine the at least one frequency subband for each time interval with data transmission based on the frequency hopping sequence.