Multiplexing of real time services and non-real time services for OFDM systems
원문보기
IPC분류정보
국가/구분
United States(US) Patent
등록
국제특허분류(IPC7판)
H04B-007/02
H04L-027/26
출원번호
US-0296081
(2014-06-04)
등록번호
US-RE47228
(2019-02-05)
발명자
/ 주소
Jalali, Ahmad
Walton, Jay R.
Wallace, Mark
출원인 / 주소
QUALCOMM Incorporated
대리인 / 주소
Do, Liem T.
인용정보
피인용 횟수 :
0인용 특허 :
75
초록▼
Transmitter and receiver units for use in an OFDM communications system and configurable to support multiple types of services. The transmitter unit includes one or more encoders, a symbol mapping element, and a modulator. Each encoder receives and codes a respective channel data stream to generate
Transmitter and receiver units for use in an OFDM communications system and configurable to support multiple types of services. The transmitter unit includes one or more encoders, a symbol mapping element, and a modulator. Each encoder receives and codes a respective channel data stream to generate a corresponding coded data stream. The symbol mapping element receives and maps data from the coded data streams to generate modulation symbol vectors, with each modulation symbol vector including a set of data values used to modulate a set of tones to generate an OFDM symbol. The modulator modulates the modulation symbol vectors to provide a modulated signal suitable for transmission. The data from each coded data stream is mapped to a respective set of one or more “circuits”. Each circuit can be defined to include a number of tones from a number of OFDM symbols, a number of tones from a single OFDM symbol, all tones from one or more OFDM symbols, or some other combination of tones. The circuits can have equal size or different sizes. Different circuits can be used for full rate data (e.g., active speech) and low rate data (e.g., silence periods).
대표청구항▼
1. A transmitter unit for use in a multi-carrier communication system, comprising: onetwo or more encoders, said onetwo or more encoders operative to receive and code a respective channel data stream to generate a corresponding coded data stream, thereby generating two or more coded data streams;a s
1. A transmitter unit for use in a multi-carrier communication system, comprising: onetwo or more encoders, said onetwo or more encoders operative to receive and code a respective channel data stream to generate a corresponding coded data stream, thereby generating two or more coded data streams;a symbol mapping element coupled to the onetwo or more encoders and operative to receive and map data from onethe two or more coded data streams to generate modulation symbol vectors, wherein each modulation symbol vector includes a plurality of data values used to modulate a plurality of tones to generate an OFDM symbol, wherein the data from each coded data stream is mapped to a respective set of onetwo or more circuits, and wherein each circuit includes a particular set of onetwo or more tones; anda modulator coupled to the symbol mapping element and operative to receive and modulate the modulation symbol vectors to provide a modulated signal. 2. The transmitter unit of claim 1, further comprising: onetwo or more scaling elements coupled to the onetwo or more encoders, each scaling element operative to receive and scale a respective coded data stream with a particular scaling factor to generate a corresponding scaled data stream that is then provided to the symbol mapping element. 3. The transmitter unit of claim 1, wherein the modulator includes an inverse Fourier transform unit operative to receive the modulation symbol vectors and generate a time-domain representation of each modulation symbol vector to provide a corresponding OFDM symbol,a cyclic prefix generator coupled to the inverse Fourier transform unit and operative to repeat a portion of each OFDM symbol to generate a corresponding transmission symbol, andan upconverter coupled to the cyclic prefix generator and operative to modulate transmission symbols to generate the modulated signal. 4. The transmitter unit of claim 1, wherein data for each channel data stream is transmitted in packets. 5. The transmitter unit of claim 4, wherein each packet includes a packet type identifier indicative of a change in circuit to be used to transmit a next packet, anda circuit identifier indicative of a particular circuit to be used to transmit the next packet. 6. The transmitter unit of claim 4, wherein transmissions for each channel data stream occur over slots, and wherein each slot includes a plurality of OFDM symbols. 7. The transmitter unit of claim 6, wherein a low rate transmission is achieved by transmitting a packet on a particular circuit every particular number of slots. 8. The transmitter unit of claim 6, wherein each slot is divided into two or more partitions, and wherein each partition includes one or more OFDM symbols and supports one or more types of service. 9. The transmitter unit of claim 8, wherein a first partition of each slot supports a first type of service having a first processing delays requirements and a second partition of each slot supports a second type of service having a second processing delays requirements. 10. The transmitter unit of claim 9, wherein the first type of service is full duplex real time services, and wherein the second type of service is half duplex real time services or non real time services, or both. 11. The transmitter unit of claim 6, wherein full rate data for a particular channel data stream is transmitted via a first circuit and lower rate data is transmitted via a second circuit. 12. The transmitter unit of claim 11, wherein the second circuit is transmitted once every particular number of slots. 13. The transmitter unit of claim 11, wherein the second circuit has a lower capacity than the first circuit. 14. The transmitter unit of claim 11, wherein an indication to use the second circuit is sent in a field of a packet transmitted on the first circuit. 15. The transmitter unit of claim 11, wherein an indication to use the first circuit is sendsent on a control channel. 16. The transmitter unit of claim 11, wherein a new circuit is utilized after receiving an acknowledgment of receipt of an indication to use the new circuit. 17. The transmitter unit of claim 4, wherein each packet includes a user identifier indicative of an intended recipient of the packet. 18. The transmitter unit of claim 1, wherein each circuit includes a plurality of tones from a plurality of OFDM symbols. 19. The transmitter unit of claim 1, wherein each circuit includes a plurality of tones from a single OFDM symbol. 20. The transmitter unit of claim 1, wherein each circuit includes all tones from one or more OFDM symbols. 21. The transmitter unit of claim 1, further comprising: onetwo or more cover elements coupled to the onetwo or more encoders, each cover element operative to receive and cover a respective coded data stream with a particular Walsh sequence to generate a corresponding covered data stream. 22. The transmitter unit of claim 21, further comprising: onetwo or more scaling elements coupled to the onetwo or more cover elements, each scaling element operative to receive and scale a respective covered data stream with a particular scaling factor to generate a corresponding scaled data stream. 23. The transmitter unit of claim 22, further comprising: a summer coupled to the onetwo or more scaling elements and operative to receive and sum onetwo or more scaled data streams. 24. The transmitter unit of claim 21, wherein each Walsh sequence is transmitted over multiple tones of each of the OFDM symbols used for the Walsh sequence. 25. The transmitter unit of claim 21, wherein the length of the Walsh sequence is matched to the number of tones in each OFDM symbol. 26. A transmitter unit for use in a multi-carrier communication system, comprising: onetwo or more encoders, said onetwo or more encoders operative to receive and code a respective channel data stream to generate a corresponding coded data stream, thereby generating two or more coded data streams;a symbol mapping element coupled to the onetwo or more encoders and operative to receive and map data from onethe two or more coded data streams to generate modulation symbol vectors, wherein each modulation symbol vector includes a plurality of data values used to modulate a plurality of tones to generate an OFDM symbol, wherein the data from each coded data stream is mapped to a respective set of onetwo or more circuits, and wherein each circuit includes a respective set of onetwo or more tones;an inverse Fourier transform unit coupled to the symbol mapping element and operative to receive the modulation symbol vectors and generate a time-domain representation of each modulation symbol vector to provide a corresponding OFDM symbol;a cyclic prefix generator coupled to the inverse Fourier transform unit and operative to repeat a portion of each OFDM symbol to generate a corresponding transmission symbol; andan upconverter coupled to the cyclic prefix generator and operative to modulate transmission symbols to generate a modulated signal, andwherein transmissions for eachthe two or more channel data stream occurstreams occurs over slots, wherein each slot includes a plurality of OFDM symbols, and wherein full rate data for a particular channel data stream is transmitted via a first circuit and lower rate data is transmitted via a second circuit. 27. A receiver unit comprising: an antenna operative to receive a modulated signal;a front end processor coupled to the antenna and operative to process the received signal to generate samples;a Fourier transform unit coupled to the front end processor and operative to receive the samples from the front end processor and generate transformed representations of the samples;a processor coupled to the Fourier transform unit and operative to process the transformed representations to generate at a symbol stream corresponding to a particular transmission being processed; anda decoder coupled to the processor and operative to receive and decode the symbol stream to generate decoded data,wherein the modulated signal is generated by coding onetwo or more channel data streams with a particular coding scheme to generate onetwo or more coded data streams, mapping data from the onetwo or more coded data streams to generate modulation symbol vectors, and modulating the modulation symbol vectors to provide thea modulated signal, and wherein each modulation symbol vector includes a plurality of data values used to modulate a plurality of tones to generate an OFDM symbol, wherein the data from each coded data stream is mapped to a respective set of onetwo or more circuits, and wherein each circuit includes a respective set of onetwo or more tones. 28. A transmitter unit for use in a multi-carrier communication system, comprising: means for receiving and coding a respective channel data stream to generate a corresponding coded data stream;means for mapping data from onetwo or more coded data streams to generate modulation symbol vectors, wherein each modulation symbol vector includes a plurality of data values used to modulate a plurality of tones to generate an OFDM symbol, wherein the data from each coded data stream is mapped to a respective set of onetwo or more circuits, and wherein each circuit includes a particular set of onetwo or more tones; andmeans for modulating the modulation symbol vectors to provide a modulated signal. 29. A method for transmitting in a multi-carrier communication system, comprising: receiving and coding a respective channel data stream to generate a corresponding coded data stream;mapping data from onetwo or more coded data streams to generate modulation symbol vectors, wherein each modulation symbol vector includes a plurality of data values used to modulate a plurality of tones to generate an OFDM symbol, wherein the data from each coded data stream is mapped to a respective set of onetwo or more circuits, and wherein each circuit includes a particular set of onetwo or more tones; andmodulating the modulation symbol vectors to provide a modulated signal. 30. The transmitter unit of claim 1, wherein the two or more circuits includes a first circuit and a second circuit different from the first circuit. 31. The transmitter unit of claim 30, wherein a first assignment for the first circuit and a second assignment for the second circuit are dynamically transmitted to a first user terminal and second user terminal, respectively, via a control channel. 32. The transmitter of claim 30, wherein the first circuit and the second circuit are different at least in size. 33. The transmitter of claim 30, wherein the first circuit and the second circuit are different at least in that the first circuit and the second circuit are dedicated for use in providing different types of services. 34. The transmitter of claim 30, wherein the first circuit and the second circuit are different at least in that the first circuit is dedicated for use in providing voice services during voice activity and the second circuit is dedicated for use in providing voice services by providing a comfort noise when a user changes state from voice activity to silence. 35. The transmitter unit of claim 26, wherein the two or more circuits includes a first circuit and a second circuit different from the first circuit. 36. The transmitter unit of claim 35, wherein a first assignment for the first circuit and a second assignment for the second circuit are dynamically transmitted to a first user terminal and second user terminal, respectively, via a control channel. 37. The receiver unit of claim 27, wherein an assignment for the two or more circuits is dynamically received via a control channel. 38. The transmitter unit of claim 28, wherein the two or more circuits includes a first circuit and a second circuit different from the first circuit. 39. The transmitter unit of claim 38, wherein a first assignment for the first circuit and a second assignment for the second circuit are dynamically transmitted to a first user terminal and second user terminal, respectively, via a control channel. 40. The method of claim 29, wherein the two or more circuits includes a first circuit and a second circuit different from the first circuit. 41. The method of claim 40, wherein a first assignment for the first circuit and a second assignment for the second circuit are dynamically transmitted to a first user terminal and second user terminal, respectively, via a control channel.
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