Abstract
Disclosed is a method and apparatus for providing uplink packet data services through an E-DCH in an asynchronous WCDMA system. A transport block size (TBS) for transmitting uplink transport channel data is determined. A combination of a spreading factor and a modulation scheme for uplink channel data transmission corresponding to the determined TBS is selected according to transmittable physical channel data bit sizes and puncturing limit values. The TBS is transmitted by incorporating it into control information of the uplink transport channel data. The modulation scheme and spreading factor combination is determined based on a physical channel data bit size that maximizes transmission efficiency and minimizes the number of punctured bits without requiring an additional physical channel in transmitting the uplink data having the TBS. This method maximizes uplink transmission efficiency to save transmission resources and reduces signaling overhead required to transmit E-DCH control information.
| Technology | Declaration Information | Specification Information | Explicitly Disclosed | Patent Type | |||||
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| Publication No | Technology | Declaration Information | Specification Information | Explicitly Disclosed | Patent Type | Status | National Phase Entries | |||||
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Technologies
Resource configuration Signal Processing
Product
Base Station (eNB/gNB)User Equipment (UE/Terminal)
Use Cases
Wireless communication
Services
Transmitting/receiving data in uplink
Claim
1. A method for providing an uplink packet data service in an asynchronous Wideband Code Division Multiple Access (WCDMA) system, the method comprising:
checking information related to a Transport Block Size (TBS) for transmission of uplink transport channel data;
determining a combination of a number of physical channels and a Spreading Factor (SF) based on transmittable physical channel data bit sizes and a plurality of Puncturing Limit (PL) values, the combination corresponding to the information related to the TBS; and
transmitting the unlink transport channel data corresponding to the combination of the number of physical channels and the spreading factor.', 'checking information related to a Transport Block Size (TBS) for transmission of uplink transport channel data;', 'determining a combination of a number of physical channels and a Spreading Factor (SF) based on transmittable physical channel data bit sizes and a plurality of Puncturing Limit (PL) values, the combination corresponding to the information related to the TBS; and', 'transmitting the unlink transport channel data corresponding to the combination of the number of physical channels and the spreading factor.
2. The method according to claim 1, wherein the combination of the number of the physical channels and the spreading factor is determined based on a physical channel data bit size for minimizing the number of bits to be punctured, and requires no additional physical channel in transmitting the uplink transport channel data.
3. The method according to claim 1, wherein the plurality of puncturing limit values are set for a plurality of modulation formats usable for transmission of the uplink transport channel data.
4. The method according to claim 3, wherein if a maximum physical channel data bit size for Binary Phase Shift Keying (BPSK) is greater than or equal to a transport channel data bit size punctured to the maximum extent according to a puncturing limit for the BPSK, the modulation format corresponding to the information related to the TBS is determined to be the BPSK, and the spreading factor corresponding to the information related to the TBS is determined to be a spreading factor corresponding to a minimum physical channel data bit size, which is greater than or equal to a non-punctured transport channel data bit size, of the transmittable physical channel data bit sizes.
5. The method according to claim 4, wherein if all of the transmittable physical channel data bit sizes are less than the non-punctured transport channel data bit size, the spreading factor corresponding to the information related to the TBS is determined to be a spreading factor corresponding to a minimum physical channel data bit size of the transmittable physical channel data bit sizes.
6. The method according to claim 4, wherein if the maximum physical channel data bit size for the BPSK is less than the transport channel data bit size punctured to the maximum extent according to the puncturing limit for the BPSK, and the maximum physical channel data bit size for Quadrature PSK (QPSK) is greater than or equal to a transport channel data bit size punctured to the maximum extent according to a puncturing limit for QPSK, the modulation format corresponding to the information related to the TBS is determined to be the QPSK, and the spreading factor corresponding to the transport block size is determined to be a spreading factor corresponding to a minimum physical channel data bit size of the transmittable physical channel data bit sizes.
7. The method according to claim 6, wherein if a maximum physical channel data bit size when the QPSK is used is less than the transport channel data bit size punctured to the maximum extent according to the puncturing limit for the QPSK, the modulation format corresponding to the information related to the TBS is determined to be 8-PSK, and the spreading factor corresponding to the information related to the TBS is determined to be a spreading factor corresponding to a minimum physical channel data bit size of the transmittable physical channel data bit sizes.
8. The method according to claim 1, wherein the plurality of Puncturing Limit (PL) values consist of a first puncturing limit (PL) and a second Puncturing Limit (PL), and the second Puncturing Limit (PL) punctures a greater number of bits than the first PL.
9. The method according to claim 1, wherein when a first set being a subset of an initial set, which is greater than or equal to a non-punctured transport channel data bit size and requires only one physical channel, is present, the combination of the number of physical channels and the Spreading Factor (SF) is determined to be a combination of the number of physical channels and the Spreading Factor (SF) corresponding to a minimum value of the first set
10. The method according to claim 9, wherein if the first set is not present, and if a second set being a subset of the initial set, which is greater than or equal to a transport channel data bit size punctured according to a first puncturing limit (PL), is present, the combination of the number of the physical channels and the Spreading Factor (SF) is determined to be a combination of a number of physical channels and a Spreading Factor (SF) corresponding to a largest value, which requires no additional physical channel, of the second set
11. The method according to claim 10, wherein if the second set is not present, and the combination of the number of the physical channels and the Spreading Factor (SF) is determined based on a second Puncturing Limit (PL) and a maximum value among the initial set
12. The method according to claim 1, wherein the combination of a number of physical channels and Spreading Factor (SF) includes a Modulation Format (MF)
13. An apparatus for providing an uplink packet data service in an asynchronous Wideband Code Division Multiple Access (WCDMA) system, the apparatus comprising:
a higher layer processor for checking information related to a Transport Block Size (TBS) for transmission of uplink transport channel data;
a determiner for determining a combination of a number of physical channels and a Spreading Factor (SF) based on transmittable physical channel data bit sizes and a plurality of Puncturing Limit (PL) values, the combination corresponding to the information related to the TBS; and
a transmitter for transmitting the unlink transport channel data corresponding to the combination of the number of physical channels and the spreading factor.', 'a higher layer processor for checking information related to a Transport Block Size (TBS) for transmission of uplink transport channel data;', 'a determiner for determining a combination of a number of physical channels and a Spreading Factor (SF) based on transmittable physical channel data bit sizes and a plurality of Puncturing Limit (PL) values, the combination corresponding to the information related to the TBS; and', 'a transmitter for transmitting the unlink transport channel data corresponding to the combination of the number of physical channels and the spreading factor
14. The apparatus according to claim 13, wherein the combination of the number of the physical channels and the spreading factor is determined based on a physical channel data bit size for minimizing the number of bits to be punctured, and requires no additional physical channel in transmitting the uplink transport channel data
15. The apparatus according to claim 13, wherein the plurality of puncturing limit values are set for a plurality of modulation formats usable for transmission of the uplink transport channel data
16. The apparatus according to claim 15, wherein if a maximum physical channel data bit size for Binary Phase Shift Keying (BPSK) is greater than or equal to a transport channel data bit size punctured to the maximum extent according to a puncturing limit for the BPSK, the modulation format corresponding to the information related to the TBS is determined to be the BPSK, and the spreading factor corresponding to the information related to the TBS is determined to be a spreading factor corresponding to a minimum physical channel data bit size, which is greater than or equal to a non-punctured transport channel data bit size, of the transmittable physical channel data bit sizes.17. The apparatus according to claim 16, wherein if all of the transmittable physical channel data bit sizes are less than the non-punctured transport channel data bit size, the spreading factor corresponding to the information related to the TBS is determined to be a spreading factor corresponding to a minimum physical channel data bit size of the transmittable physical channel data bit sizes.18. The apparatus according to claim 16, wherein if the maximum physical channel data bit size for the BPSK is less than the transport channel data bit size punctured to the maximum extent according to the puncturing limit for the BPSK, and the maximum physical channel data bit size for Quadrature PSK (QPSK) is greater than or equal to a transport channel data bit size punctured to the maximum extent according to a puncturing limit for QPSK, the modulation format corresponding to the information related to the TBS is determined to be the QPSK, and the spreading factor corresponding to the information related to the TBS is determined to be a spreading factor corresponding to a minimum physical channel data bit size of the transmittable physical channel data bit sizes.19. The apparatus according to claim 18, wherein if a maximum physical channel data bit size when the QPSK is used is less than the transport channel data bit size punctured to the maximum extent according to the puncturing limit for the QPSK, the modulation format corresponding to the information related to the TBS is determined to be 8-PSK, and the spreading factor corresponding to the information related to the TBS is determined to be a spreading factor corresponding to a minimum physical channel data bit size of the transmittable physical channel data bit sizes.
20. The apparatus according to claim 13, wherein the plurality of Puncturing Limit (PL) values consist of a first puncturing limit (PL) and a second Puncturing Limit (PL), and the second Puncturing Limit (PL) punctures a greater number of bits than the first PL.
21. The apparatus according to claim 13, wherein, when a first set being a subset of an initial set, which is greater than or equal to a non-punctured transport channel data bit size and requires only one physical channel, is present, the combination of the number of the physical channels and the Spreading Factor (SF) is determined to be a combination of a number of physical channels and a Spreading Factor (SF) corresponding to a minimum value of the first set.
22. The apparatus according to claim 21, wherein, if the first set is not present, and if a second set being a subset of the initial set, which is greater than or equal to a transport channel data bit size punctured according to a first puncturing limit (PL), is present, the combination of the number of the physical channels and the Spreading Factor (SF) is determined to be a combination of a number of physical channels and a Spreading Factor (SF) corresponding to a largest value, which requires no additional physical channel, of the second set.
23. The apparatus according to claim 22, wherein, if the second set is not present, the combination of the number of the physical channels and the Spreading Factor (SF) is determined based on a second Puncturing Limit (PL) and a maximum value among the initial set.
24. The apparatus according to claim 13, wherein the combination of a number of physical channels and Spreading Factor (SF) includes a Modulation Format (MF).
25. A method for providing an uplink packet data service in an asynchronous Wideband Code Division Multiple Access (WCDMA) system, the method comprising:
receiving control information including information related to a Transport Block Size (TBS) for receiving uplink transport channel data;
determining a combination of a number of physical channels and a Spreading Factor (SF) based on transmittable physical channel data bit sizes and a plurality of Puncturing Limit (PL) values, the combination corresponding to the information related to the TBS; and
receiving the uplink transport channel data using the number of the physical channels and the spreading factor.', 'receiving control information including information related to a Transport Block Size (TBS) for receiving uplink transport channel data;', 'determining a combination of a number of physical channels and a Spreading Factor (SF) based on transmittable physical channel data bit sizes and a plurality of Puncturing Limit (PL) values, the combination corresponding to the information related to the TBS; and', 'receiving the uplink transport channel data using the number of the physical channels and the spreading factor.
26. The method according to claim 25, wherein the combination of the number of the physical channels and the spreading factor is determined based on a physical channel data bit size for minimizing the number of bits to be punctured, and requires no additional physical channel in transmitting the uplink transport channel data.
27. The method according to claim 25, wherein the plurality of puncturing limit values are set for a plurality of modulation formats usable for transmission of the uplink transport channel data.
28. The method according to claim 27, wherein if a maximum physical channel data bit size for Binary Phase Shift Keying (BPSK) is greater than or equal to a transport channel data bit size punctured to the maximum extent according to a puncturing limit for the BPSK, the modulation format corresponding to the information related to the TBS is determined to be the BPSK, and the spreading factor corresponding to the information related to the TBS is determined to be a spreading factor corresponding to a minimum physical channel data bit size, which is greater than or equal to a non-punctured transport channel data bit size, of the transmittable physical channel data bit sizes.
29. The method according to claim 28, wherein if all of the transmittable physical channel data bit sizes are less than the non-punctured transport channel data bit size, the spreading factor corresponding to the information related to the TBS is determined to be a spreading factor corresponding to a minimum physical channel data bit size of the transmittable physical channel data bit sizes.
30. The method according to claim 28, wherein if the maximum physical channel data bit size for the BPSK is less than the transport channel data bit size punctured to the maximum extent according to the puncturing limit for the BPSK, and the maximum physical channel data bit size for Quadrature PSK (QPSK) is greater than or equal to a transport channel data bit size punctured to the maximum extent according to a puncturing limit for QPSK, the modulation format corresponding to the information related to the TBS is determined to be the QPSK, and the spreading factor corresponding to the information related to the TBS is determined to be a spreading factor corresponding to a minimum physical channel data bit size of the transmittable physical channel data bit sizes.
31. The method according to claim 30, wherein if a maximum physical channel data bit size when the QPSK is used is less than the transport channel data bit size punctured to the maximum extent according to the puncturing limit for the QPSK, the modulation format corresponding to the information related to the TBS is determined to be 8-PSK, and the spreading factor corresponding to the information related to the TBS is determined to be a spreading factor corresponding to a minimum physical channel data bit size of the transmittable physical channel data bit sizes.
32. The method according to claim 25, wherein the plurality of Puncturing Limit (PL) values consist of a first puncturing limit (PL) and a second Puncturing Limit (PL), and the second Puncturing Limit (PL) punctures a greater number of bits than the first PL.
33. The method according to claim 25, wherein, when a first set being a subset of an initial set, which is greater than or equal to a non-punctured transport channel data bit size and requires only one physical channel, is present, the combination of the number of the physical channels and the Spreading Factor (SF) is determined to be a combination of a number of physical channels and a Spreading Factor (SF) corresponding to a minimum value of the first set.
34. The method according to claim 33, wherein, if the first set is not present, and if a second set being a subset of the initial set, which is greater than or equal to a transport channel data bit size punctured according to a first puncturing limit (PL), is present, the combination of the number of the physical channels and the Spreading Factor (SF) is determined to be a combination of a number of physical channels and a Spreading Factor (SF) corresponding to a largest value, which requires no additional physical channel, of the second set.
35. The method according to claim 34, wherein, if the second set is not present, the combination of the number of the physical channels and the Spreading Factor (SF) is determined based on a second Puncturing Limit (PL) and a maximum value among the initial set.
36. The method according to claim 25, wherein the combination of a number of physical channels and Spreading Factor (SF) includes a Modulation Format (MF).
37. An apparatus for providing an uplink packet data service in an asynchronous Wideband Code Division Multiple Access (WCDMA) system, the apparatus comprising:
a control channel receiver for receiving control information including information related to a Transport Block Size (TBS) for receiving uplink transport channel data;
a determiner for determining a combination of a number of physical channels and a Spreading Factor (SF) based on transmittable physical channel data bit sizes and a plurality of Puncturing Limit (PL) values, the combination corresponding to the information related to the TBS; and
a receiver for receiving the uplink transport channel data using the number of the physical channels and the spreading factor.', 'a control channel receiver for receiving control information including information related to a Transport Block Size (TBS) for receiving uplink transport channel data;', 'a determiner for determining a combination of a number of physical channels and a Spreading Factor (SF) based on transmittable physical channel data bit sizes and a plurality of Puncturing Limit (PL) values, the combination corresponding to the information related to the TBS; and', 'a receiver for receiving the uplink transport channel data using the number of the physical channels and the spreading factor.
38. The apparatus according to claim 37, wherein the combination of the number of the physical channels and the spreading factor is determined based on a physical channel data bit size for minimizing the number of bits to be punctured, and requires no additional physical channel in transmitting the uplink transport channel data.
39. The apparatus according to claim 37, wherein the plurality of puncturing limit values are set for a plurality of modulation formats usable for transmission of the uplink transport channel data.
40. The apparatus according to claim 39, wherein if a maximum physical channel data bit size for Binary Phase Shift Keying (BPSK) is greater than or equal to a transport channel data bit size punctured to the maximum extent according to a puncturing limit for the BPSK, the modulation format corresponding to the information related to the TBS is determined to be the BPSK, and the spreading factor corresponding to the information related to the TBS is determined to be a spreading factor corresponding to a minimum physical channel data bit size, which is greater than or equal to a non-punctured transport channel data bit size, of the transmittable physical channel data bit sizes.
41. The apparatus according to claim 40, wherein if all of the transmittable physical channel data bit sizes are less than the non-punctured transport channel data bit size, the spreading factor corresponding to the information related to the TBS is determined to be a spreading factor corresponding to a minimum physical channel data bit size of the transmittable physical channel data bit sizes.
42. The apparatus according to claim 40, wherein if the maximum physical channel data bit size for the BPSK is less than the transport channel data bit size punctured to the maximum extent according to the puncturing limit for the BPSK, and the maximum physical channel data bit size for Quadrature PSK (QPSK) is greater than or equal to a transport channel data bit size punctured to the maximum extent according to a puncturing limit for QPSK, the modulation format corresponding to the information related to the TBS is determined to be the QPSK, and the spreading factor corresponding to information related to the TBS is determined to be a spreading factor corresponding to a minimum physical channel data bit size of the transmittable physical channel data bit sizes.
43. The apparatus according to claim 42, wherein if a maximum physical channel data bit size when the QPSK is used is less than the transport channel data bit size punctured to the maximum extent according to the puncturing limit for the QPSK, the modulation format corresponding to the information related to the TBS is determined to be 8-PSK, and the spreading factor corresponding to the information related to the TBS is determined to be a spreading factor corresponding to a minimum physical channel data bit size of the transmittable physical channel data bit sizes.
44. The apparatus according to claim 37, wherein the plurality of Puncturing Limit (PL) values consist of a first puncturing limit (PL) and a second Puncturing Limit (PL), and the second Puncturing Limit (PL) punctures a greater number of bits than the first PL.
45. The apparatus according to claim 37, wherein, when a first set being a subset of an initial set, which is greater than or equal to a non-punctured transport channel data bit size and requires only one physical channel, is present, the combination of the number of the physical channels and the Spreading Factor (SF) is determined to be a combination of a number of physical channels and a Spreading Factor (SF) corresponding to a minimum value of the first set.
46. The apparatus according to claim 45, wherein, if the first set is not present, and if a second set being a subset of the initial set, which is greater than or equal to a transport channel data bit size punctured according to a first puncturing limit (PL), is present, the combination of the number of the physical channels and the Spreading Factor (SF) is determined, to be a combination of a number of physical channels and a Spreading Factor (SF) corresponding to a largest value, which requires no additional physical channel, of the second set.
47. The apparatus according to claim 46, wherein, if the second set is not present, the combination of the number of the physical channels and the Spreading Factor (SF) is determined based on a second Puncturing Limit (PL) and a maximum value among the initial set.
48. The apparatus according to claim 37, wherein the combination of a number of physical channels and Spreading Factor (SF) includes a Modulation Format (MF).']
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ClaimChart-US7573854B2-STO
Patent number:US7573854B2
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