Hybrid TDM/OFDM/CDM reverse link transmission
원문보기
IPC분류정보
국가/구분
United States(US) Patent
등록
국제특허분류(IPC7판)
H04B-007/204
H04W-004/00
출원번호
US-0984094
(2004-11-09)
등록번호
US-8179833
(2012-05-15)
발명자
/ 주소
Attar, Rashid A.
Bhushan, Naga
출원인 / 주소
QUALCOMM Incorporated
대리인 / 주소
Eggers, Charles E.
인용정보
피인용 횟수 :
12인용 특허 :
35
초록▼
A communication system includes a plurality of access terminals, and an access network. The access network schedules a transmission of data in a time interval from one of the access terminals. The access network selects a multiple access transmission mode from a plurality of multiple access transmis
A communication system includes a plurality of access terminals, and an access network. The access network schedules a transmission of data in a time interval from one of the access terminals. The access network selects a multiple access transmission mode from a plurality of multiple access transmission modes, and broadcasts the selected multiple access transmission mode to the access terminals. The selected mode may include a mode in which data is code-division-multiplexed during the time interval, and modes in which data is code-division-multiplexed during a first portion of the time interval, and data is either time-division-multiplexed or orthogonal-frequency-division-multiplexed during a second portion of the time interval.
대표청구항▼
1. A communication system comprising: an access network configured to select a multiple access transmission mode from a plurality of multiple access transmission modes, broadcast a signal indicating the selected multiple access transmission mode to at least one of a plurality of access terminals, an
1. A communication system comprising: an access network configured to select a multiple access transmission mode from a plurality of multiple access transmission modes, broadcast a signal indicating the selected multiple access transmission mode to at least one of a plurality of access terminals, and to schedule a transmission of data in one of a plurality of transmission time slots within a frame, from one of the access terminals in the selected multiple access transmission mode;wherein the plurality of multiple access transmission modes comprises a hybrid multiple access transmission mode in which data is code-division-multiplexed during a portion of a single transmission time slot, and data is either time-division-multiplexed or orthogonal-frequency-division-multiplexed during a remaining portion of the single transmission time slot,wherein the data comprises user data and overhead data,wherein transmission of the user data is prohibited during said portion of said single transmission time slot in which the data is code-division-multiplexed,wherein the data comprises user data to be transmitted through a traffic channel and overhead data to be transmitted through an overhead channel, andwherein the plurality of transmission modes comprises transmission modes that allow for a transmission of overhead data through the overhead channel only during a portion of a single transmission time slot in which code-division-multiplexing is implemented. 2. The communication system of claim 1, wherein the plurality of multiple access transmission modes comprise: a first multiple access transmission mode in which data is code-division-multiplexed during the transmission time slot; anda second multiple access transmission mode in which data is code-division-multiplexed during a first portion of the transmission time slot, and data is either time-division-multiplexed or orthogonal-frequency-division-multiplexed during a second portion of the transmission time slot. 3. The communication system of claim 1, wherein the plurality of multiple access transmission modes comprise: a first transmission mode in which data is code-division-multiplexed during the transmission time slot;a second transmission mode in which data is code-division-multiplexed during a first half of the transmission time slot, and data is either time-division-multiplexed or orthogonal-frequency-division-multiplexed during a second half of the transmission time slot; anda third transmission mode in which data is code-division-multiplexed during a first quarter of the transmission time slot and data is either time-division-multiplexed or orthogonal-frequency-division-multiplexed during the remaining three quarters of the transmission time slot. 4. The communication system of claim 3, wherein transmission of user data is prohibited during said first quarter of said transmission time slot in which the data is code-division-multiplexed. 5. The communication system of claim 1, wherein the access network is further configured to update the selected multiple access transmission mode after a number of transmission time slots. 6. The communication system of claim 5, wherein the transmission time slot comprises about 1.66 milliseconds, and the number comprises four. 7. The communication system of claim 1, wherein each of the access terminals is configured to transmit to the access network a request to transmit data in the transmission time slot, andwherein the access network is configured to schedule the transmission in response to the request to transmit data from each of the access terminals. 8. The communication system of claim 7, wherein each of the access terminals is further configured to determine an opportunity level for the transmission time slot, and to transmit the opportunity level to the access network. 9. The communication system of claim 8, wherein each of the access terminals is connected to the access network through a reverse link; andwherein each of the access terminals is configured to determine the opportunity level in accordance with an instantaneous quality metric of a channel in the reverse link in the transmission time slot, an average quality metric of the channel, and an impatience function. 10. The communication system of claim 9, wherein each access terminal is configured to transmit the opportunity level to the access network when the selected multiple access transmission mode is a multiple access transmission mode in which data is code-division-multiplexed during a first portion of the transmission time slot, and data is either time-division-multiplexed or orthogonal-frequency-division-multiplexed during a second portion of the transmission time slot. 11. The communication system of claim 7, wherein each of the access terminals is further configured to send to the access network an allocation request that asks for a resource to be allocated to a data flow within the access terminal during the transmission time slot. 12. The communication system of claim 11, wherein the access network is further configured to allocate the resource to the data flow within one of the access terminals during the transmission time slot, in response to the allocation request from said one of the access terminals. 13. The communication system of claim 12, wherein the access network is further configured to transmit to said one of the access terminals an allocation message indicating the allocation of the resource. 14. The communication system of claim 11, wherein each of the access terminals is configured to send the allocation request if at least two of the following are satisfied:data is available for transmission, a predetermined amount of data has already been transmitted since a previous allocation request was sent from the access terminal, and a predetermined time interval has elapsed since the previous allocation request. 15. The communication system of claim 12, wherein each of the access terminals is connected to the access network through a reverse link, andwherein the resource comprises a ratio between a transmit power of a traffic channel in the reverse link, and a transmit power of a pilot channel in the reverse link. 16. The communication system of claim 13, wherein the data flow within said one of the access terminals is characterized by a state variable and a parameter, andwherein the allocation message indicates a new value for the state variable and a new value for the parameter. 17. The communication system of claim 16, wherein said one of the access terminals is configured to replace the state variable and the parameter of the data flow with the new values, in response to the allocation message. 18. The communication system of claim 13, wherein the allocation message further indicates a maximum rate of data transmission for said one of the access terminals. 19. The communication system of claim 1, wherein each of the access terminals is configured to compensate for an energy loss during the transmission of the overhead data, by increasing a gain of the overhead channel. 20. An access network comprising a scheduler configured to select a multiple access transmission mode from a plurality of multiple access transmission modes, broadcast a signal indicating the selected multiple access transmission mode to at least one of a plurality of access terminals, and to schedule a transmission of data in one of a plurality of transmission time slots within a frame, from one of the access terminals in the selected multiple access transmission mode; wherein the plurality of multiple access transmission modes comprises a hybrid multiple access transmission mode in which data is code-division-multiplexed during a portion of a single transmission time slot, and data is either time-division-multiplexed or orthogonal-frequency-division-multiplexed during a remaining portion of the single transmission time slot,wherein the data comprises user data and overhead data,wherein transmission of the user data is prohibited during said portion of said single transmission time slot in which the data is code-division-multiplexed,wherein the data comprises user data to be transmitted through a traffic channel and overhead data to be transmitted through an overhead channel, andwherein the plurality of transmission modes comprises transmission modes that allow for a transmission of overhead data through the overhead channel only during a portion of a single transmission time slot in which code-division-multiplexing is implemented. 21. The access network of claim 20, wherein the plurality of multiple access transmission modes comprise: a first multiple access transmission mode in which data is code-division-multiplexed during the transmission time slot; anda second multiple access transmission mode in which data is code-division-multiplexed during a first portion of the transmission time slot, and the data is either time-division-multiplexed or orthogonal-frequency-division-multiplexed during a second portion of the transmission time slot. 22. An access terminal operable to transmit data in each of a plurality of multiple access transmission modes, the access terminal comprising a mode select unit, a receiver and a transmitter, wherein the access terminal is configured to receive a signal indicating a selection of one of the plurality of multiple access transmission modes for one of a plurality of transmission time slots within a frame, and to transmit data in the selected multiple access transmission mode during the transmission time slot;wherein the plurality of multiple access transmission modes comprises a hybrid multiple access transmission mode in which data is code-division-multiplexed during a portion of a single transmission time slot, and data is either time-division-multiplexed or orthogonal-frequency-division-multiplexed during a remaining portion of the single transmission time slot,wherein the data comprises user data and overhead data,wherein transmission of the user data is prohibited during said portion of said single transmission time slot in which the data is code-division-multiplexed,wherein the data comprises user data to be transmitted through a traffic channel and overhead data to be transmitted through an overhead channel, andwherein the plurality of transmission modes comprises transmission modes that allow for a transmission of overhead data through the overhead channel only during a portion of a single transmission time slot in which code-division-multiplexing is implemented. 23. The access terminal of claim 22, wherein the plurality of multiple access transmission modes comprise: a first multiple access transmission mode in which data is code-division-multiplexed during the transmission time slot; anda second multiple access transmission mode in which data is code-division-multiplexed during a first portion of the transmission time slot, and data is either time-division-multiplexed or orthogonal-frequency-division-multiplexed during a second portion of the transmission time slot. 24. The access terminal of claim 22, wherein the access terminal is further configured to send to an access network a request to transmit data in a transmission time slot, and receive from the access network a permission to transmit data in the transmission time slot in accordance with the request. 25. The access terminal of claim 22, wherein the access terminal is further configured to receive the signal from an access network. 26. A method of transmitting data, comprising: selecting a multiple access transmission mode from a plurality of multiple access transmission modes;broadcasting a signal indicating the selected multiple access transmission mode to at least one of a plurality of access terminals; andscheduling a transmission of data in one of a plurality of transmission time slots within a frame, from one of the plurality of access terminals, in the selected multiple access transmission mode;wherein the plurality of multiple access transmission modes comprises a hybrid multiple access transmission mode in which data is code-division-multiplexed during a portion of a single transmission time slot, and data is either time-division-multiplexed or orthogonal-frequency-division-multiplexed during a remaining portion of the single transmission time slot,wherein the data comprises user data and overhead data,wherein transmission of the user data is prohibited during said portion of said single transmission time slot in which the data is code-division-multiplexed,wherein the data comprises user data to be transmitted through a traffic channel and overhead data to be transmitted through an overhead channel, andwherein the plurality of transmission modes comprises transmission modes that allow for a transmission of overhead data through the overhead channel only during a portion of a single transmission time slot in which code-division-multiplexing is implemented. 27. The method of claim 26, wherein the plurality of multiple access transmission modes comprise: a first multiple access transmission mode in which the data is code-division-multiplexed during the transmission time slot; anda second multiple access transmission mode in which the data is code-division-multiplexed during a first portion of the transmission time slot, and the data is either time-division-multiplexed or orthogonal-frequency-division-multiplexed during a second portion of the transmission time slot. 28. A method of transmitting data, comprising: receiving a signal indicative of a multiple access transmission mode selected from a plurality of multiple access transmission modes; andtransmitting data in the selected multiple access transmission mode during one of a plurality of transmission time slots within a frame;wherein the plurality of multiple access transmission modes comprises a hybrid multiple access transmission mode in which data is code-division-multiplexed during a portion of a single transmission time slot, and data is either time-division-multiplexed or orthogonal-frequency-division-multiplexed during a remaining portion of the single transmission time slot,wherein the data comprises user data and overhead data,wherein transmission of the user data is prohibited during said portion of said single transmission time slot in which the data is code-division-multiplexed,wherein the data comprises user data to be transmitted through a traffic channel and overhead data to be transmitted through an overhead channel, andwherein the plurality of transmission modes comprises transmission modes that allow for a transmission of overhead data through the overhead channel only during a portion of a single transmission time slot in which code-division-multiplexing is implemented. 29. The method of claim 28, wherein the plurality of multiple access transmission modes comprise: a first multiple access transmission mode in which the data is code-division-multiplexed during the transmission time slot; anda second multiple access transmission mode in which the data is code-division-multiplexed during a first portion of the transmission time slot, and the data is either time-division-multiplexed or orthogonal-frequency-division-multiplexed during a second portion of the transmission time slot. 30. The method of claim 28, wherein receiving a signal comprises receiving a signal from an access network. 31. The method of claim 28, further comprising transmitting a request to transmit data in the transmission time slot to an access network, and receiving from the access network a permission to transmit data in the transmission time slot in accordance with the request. 32. The method of claim 31, wherein transmitting the request comprises determining at each access terminal an opportunity level for the transmission time slot, and transmitting the opportunity level. 33. The access terminal of claim 23, wherein the access terminal is operable to send delay-sensitive data during the first portion of the transmission time slot and send delay-tolerant data during the second portion of the transmission time slot. 34. The access terminal of claim 23, wherein the access terminal is operable to send code division multiplexed overhead channels in the first portion of the transmission time slot and send time division multiplexed data in the second portion of the transmission time slot. 35. The access network of claim 20, wherein the scheduler is operable to select and assign a different multiple access transmission mode for each subframe for at least one access terminal. 36. The access network of claim 20, wherein the scheduler is operable to select the selected multiple access transmission mode based on an application at an access terminal that produces data for reverse link transmission. 37. An access terminal operable to transmit data in each of a plurality of multiple access transmission modes, the access terminal comprising: means for receiving a signal indicating a selection of one of the plurality of multiple access transmission modes for one of a plurality of transmission time slots within a frame; andmeans for transmitting data in the selected one of the multiple access transmission mode during the transmission time slot;wherein said means for transmitting comprises:means for transmitting the data in a hybrid multiple access transmission mode in which data is code-division-multiplexed during a portion of a single transmission time slot, and data is either time-division-multiplexed or orthogonal-frequency-division-multiplexed during a remaining portion of the single transmission time slot,wherein the data comprises user data and overhead data,wherein transmission of the user data is prohibited during said portion of said single transmission time slot in which the data is code-division-multiplexed,wherein the data comprises user data to be transmitted through a traffic channel and overhead data to be transmitted through an overhead channel, andwherein the plurality of transmission modes comprises transmission modes that allow for a transmission of overhead data through the overhead channel only during a portion of a single transmission time slot in which code-division-multiplexing is implemented. 38. The access terminal of claim 37, wherein said means for transmitting comprises: means for transmitting the data in a first multiple access transmission mode in which the data is code-division-multiplexed during the transmission time slot; andmeans for transmitting the data in a second multiple access transmission mode in which the data is code-division-multiplexed during a first portion of the transmission time slot, and the data is either time-division-multiplexed or orthogonal-frequency-division-multiplexed during a second portion of the transmission time slot. 39. The access terminal of claim 38, further comprising: means for sending delay-sensitive data during the first portion of the transmission time slot; andmeans for sending delay-tolerant data during the second portion of the transmission time slot. 40. The access terminal of claim 38, further comprising: means for sending code division multiplexed overhead channels in the first portion of the transmission time slot; andmeans for sending time division multiplexed data in the second portion of the transmission time slot. 41. A non-transitory storage medium embodying executable instructions, the instructions comprising: code for causing an access terminal (AT) to receive a signal indicating a selection of one of the plurality of multiple access transmission modes for one of a plurality of transmission time slots within a frame; andcode for causing the AT to transmit data in the selected one of the multiple access transmission mode during the transmission time slot;wherein the plurality of multiple access transmission modes comprises a hybrid multiple access transmission mode in which data is code-division-multiplexed during a portion of a single transmission time slot, and data is either time-division-multiplexed or orthogonal-frequency-division-multiplexed during a remaining portion of the single transmission time slot, wherein the data comprises user data and overhead data, wherein transmission of the user data is prohibited during said portion of said single transmission time slot in which the data is code-division-multiplexed,wherein the data comprises user data to be transmitted through a traffic channel and overhead data to be transmitted through an overhead channel, andwherein the plurality of transmission modes comprises transmission modes that allow for a transmission of overhead data through the overhead channel only during a portion of a single transmission time slot in which code-division-multiplexing is implemented. 42. The storage medium of claim 41, further comprising: code for causing the AT to transmit the data in a first multiple access transmission mode in which the data is code-division-multiplexed during the transmission time slot; andcode for causing the AT to transmit the data in a second multiple access transmission mode in which the data is code-division-multiplexed during a first portion of the transmission time slot, and the data is either time-division-multiplexed or orthogonal-frequency-division-multiplexed during a second portion of the transmission time slot. 43. The storage medium of claim 42, further comprising: code for causing the AT to send delay-sensitive data during the first portion of the transmission time slot; andcode for causing the AT to send delay-tolerant data during the second portion of the transmission time slot. 44. The storage medium of claim 42, further comprising: code for causing the AT to send code division multiplexed overhead channels in the first portion of the transmission time slot; andcode for causing the AT to send time division multiplexed data in the second portion of the transmission time slot. 45. An access network comprising: a scheduler configured to select a multiple access transmission mode from a plurality of multiple access transmission modes, and to schedule a transmission of data from an access terminal to occur in one of a plurality of transmission time slots within a frame, and to use the selected multiple access transmission mode; anda transmitter configured to transmit a signal indicating the selected multiple access transmission mode to the access terminal;wherein the plurality of multiple access transmission modes comprises a hybrid multiple access transmission mode in which data is code-division-multiplexed during a portion of a single transmission time slot, and data is either time-division-multiplexed or orthogonal-frequency-division-multiplexed during a remaining portion of the single transmission time slot,wherein the data comprises user data and overhead data,wherein transmission of the user data is prohibited during said portion of said single transmission time slot in which the data is code-division-multiplexed,wherein the data comprises user data to be transmitted through a traffic channel and overhead data to be transmitted through an overhead channel, andwherein the plurality of transmission modes comprises transmission modes that allow for a transmission of overhead data through the overhead channel only during a portion of a single transmission time slot in which code-division-multiplexing is implemented. 46. The access network of claim 45, wherein the plurality of multiple access transmission modes comprise: a first multiple access transmission mode in which the data is code-division-multiplexed during the transmission time slot; anda second multiple access transmission mode in which the data is code-division-multiplexed during a first portion of the transmission time slot, and the data is either time-division-multiplexed or orthogonal-frequency-division-multiplexed during a second portion of the transmission time slot. 47. The access network of claim 45, wherein the scheduler is further configured to select the selected multiple access transmission mode based on transmission subframes. 48. The access network of claim 45, wherein the scheduler is further configured to select the selected multiple access transmission mode based on an application at the access terminal that produces the data for transmission. 49. A non-transitory storage medium embodying executable instructions, the instructions comprising: code for causing an access network (AN) to select a multiple access transmission mode from a plurality of multiple access transmission modes;code for causing the AN to schedule a transmission of data from an access terminal to occur in one of a plurality of transmission time slots within a frame and to use the selected multiple access transmission mode; andcode for causing the AN to transmit a signal indicating the selected multiple access transmission mode to the access terminal;wherein the plurality of multiple access transmission modes comprises a hybrid multiple access transmission mode in which data is code-division-multiplexed during a portion of a single transmission time slot, and data is either time-division-multiplexed or orthogonal-frequency-division-multiplexed during a remaining portion of the single transmission time slot, wherein the data comprises user data and overhead data, andwherein transmission of the user data is prohibited during said portion of said single transmission time slot in which the data is code-division-multiplexedwherein the data comprises user data to be transmitted through a traffic channel and overhead data to be transmitted through an overhead channel, andwherein the plurality of transmission modes comprises transmission modes that allow for a transmission of overhead data through the overhead channel only during a portion of a single transmission time slot in which code-division-multiplexing is implemented. 50. The storage medium of claim 49, wherein the plurality of multiple access transmission modes comprise: a first multiple access transmission mode in which the data is code-division-multiplexed during the transmission time slot; anda second multiple access transmission mode in which a first portion of data is code-division-multiplexed during a first portion of the transmission time slot, and a second portion of data is either time-division-multiplexed or orthogonal-frequency-division-multiplexed during a second portion of the transmission time slot. 51. The storage medium of claim 49, further comprising code for causing the AN to select the selected multiple access transmission mode based on transmission subframes. 52. The storage medium of claim 49, further comprising code for causing the AN to select the selected multiple access transmission mode based on an application at the access terminal that produces the data for transmission. 53. The method of claim 26, wherein the plurality of multiple access transmission modes comprise: a first transmission mode in which data is code-division-multiplexed during the transmission time slot;a second transmission mode in which data is code-division-multiplexed during a first half of the transmission time slot, and data is either time-division-multiplexed or orthogonal-frequency-division-multiplexed during a second half of the transmission time slot; anda third transmission mode in which data is code-division-multiplexed during a first quarter of the transmission time slot and data is either time-division-multiplexed or orthogonal-frequency-division-multiplexed during the remaining three quarters of the transmission time slot. 54. The method of claim 53, wherein scheduling of transmission of user data is prohibited during said first quarter of said transmission time slot in which the data is code-division-multiplexed. 55. The method of claim 26 further comprising updating the multiple access transmission mode after a number of transmission time slots. 56. The method of claim 55, wherein the transmission time slot comprises about 1.66 milliseconds, and the number comprises four. 57. The method of claim 26 further comprising transmitting a request to transmit data in the transmission time slot, and wherein scheduling the transmission is in response to the request to transmit data. 58. The method of claim 57 further comprising determining an opportunity level for the transmission time slot and transmitting the opportunity level. 59. The method of claim 57 further comprising sending an allocation request that asks for a resource to be allocated to a data flow within the access terminal during the transmission time slot. 60. The method of claim 59 further comprising allocating the resource to the data flow during the transmission time slot, in response to the allocation request. 61. The method of claim 60 further comprising transmitting an allocation message indicating the allocation of the resource. 62. The method of claim 59 further comprising sending the allocation request if at least two of the following are satisfied: data is available for transmission, a predetermined amount of data has already been transmitted since a previous allocation request was sent, and a predetermined time interval has elapsed since the previous allocation request. 63. The communication system of claim 2, wherein the overhead data is transmitted using the first multiple access transmission mode and the user data is transmitted using the second multiple access transmission mode. 64. The method of claim 53 further comprising transmitting the overhead data using the first multiple access transmission mode; and transmitting the user data using the second multiple access transmission mode. 65. The communication system of claim 1, wherein transmission of the user data is allowed during said remaining portion of the single transmission time slot. 66. The communication system of claim 1, wherein transmission of a reverse rate indication channel is prohibited during said portion of said single transmission time slot in which the data is code-division multiplexed. 67. The communication system of claim 1, wherein a transmission power of the user data and a transmission power of the overhead data are controlled separately.
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