Einzeltreffer — DigiBib

Provided is a method and wireless communication system that includes a HetNet, a serving cell with an associated coverage area and multiple additional low power nodes (LPNs) deployed in one or more clusters of cells in the coverage area. The LPNs transmit an associated discovery signal based on the timing of the associated small cell. The serving cell is configured to determine the timing of the cells and therefore the transmission pattern of the discovery signals and the serving cell configures measurement gaps such that the discovery signals are transmitted during the measurement gaps. The network is adapted to accomplish this for various degrees of granularity and timing measurement inaccuracies by placing the measurement gaps and/or adjusting the discovery signal (DS) transmission scheme accordingly.

Titel:	Method and system for signal transmission with network assistance
Autor/in / Beteiligte Person:	ZTE Wistron Telecom, AB
Link:	View record in USPTO Patent Grants (Volltext)
Veröffentlichung:	2019
Medientyp:	Patent
Sonstiges:	Nachgewiesen in: USPTO Patent Grants Sprachen: English Patent Number: 10397,856 Publication Date: August 27, 2019 Appl. No: 15/127370 Application Filed: March 16, 2015 Assignees: ZTE (TX) Inc. (Austin, TX, US) Claim: 1. A method for wireless communication, said method comprising: a cell transmitting discovery signals, said cell deployed in a cluster of cells deployed in a coverage area of a serving cell; said serving cell determining timing information of said cell and a discovery signal transmission pattern of said discovery signals of said cell; said serving cell configuring measurement gaps to match said discovery signal transmission pattern such that a user equipment (UE) can read said discovery signals in said measurement gaps; and said cell determining, based on granularity, timing information inaccuracy, lengths of measurement gaps, and durations of said discovery signals, that a certain discovery signal out of said discovery signals is not completely within a corresponding measurement gap out of said measurement gaps, and in response to the determining, said cell transmitting (2i+3) copies of said certain discovery signal, at least one copy being transmitted before said certain discovery signal, at least one copy being transmitted after said certain discovery signal when the timing information inaccuracy satisfies the condition Δ 2 ≤(T gap/ 2)−Δ 1 +(2i+1)T/2, wherein Δ 1 is granularity, Δ 2 is timing information accuracy, T is duration of said certain discovery signal, T gap is duration of a corresponding measurement gap, and i is a non-negative integer. Claim: 2. The method as in claim 1 , wherein said configuring said measurement gaps to match said discovery signal transmission pattern comprises configuring said measurement gaps such that said discovery signals are transmitted during said measurement gaps. Claim: 3. The method as in claim 1 , further comprising said UE detecting said discovery signals during said measurement gaps, and after said configuring. Claim: 4. The method as is claim 1 , wherein said UE is in communication with said serving cell and deployed within said coverage area. Claim: 5. The method as in claim 1 , wherein said cells of said cluster of cells each comprise low power nodes (LPN's). Claim: 6. The method as in claim 5 , wherein said serving cell determining timing information comprises said serving cell having some timing information of said cell and wherein said serving cell configuring measurement gaps includes said serving cell configuring said measurement gap taking into account timing information inaccuracies. Claim: 7. The method as in claim 1 , further comprising said UE performing a conventional cell search in initial inter-frequency measurement gaps, providing said timing information of said cell to said serving cell and wherein said serving cell configuring measurement gaps comprises said serving cell repositioning said initial inter-frequency measurement gaps. Claim: 8. The method as in claim 1 , wherein said cell transmitting discovery signals includes said cell transmitting different parts of at least one of said discovery signals at different times. Claim: 9. The method as in claim 8 , wherein said parts of said at least one of said discovery signals are transmitted before and after transmission of a full copy of the at least one of the discovery signals. Claim: 10. A wireless communication system comprising: a heterogeneous network (HetNet); a serving cell with an associated coverage area; cells in a cluster of cells deployed in said coverage area; each cell of said cluster of cells configured to transmit discovery signals; said serving cell configured to determine timing information of said cells and a discovery signal transmission pattern of said corresponding discovery signals; and said serving cell configured to configure measurement gaps such that said discovery signals are transmitted during said measurement gaps and such that a user equipment (UE) can read said discovery signals in said measurement gaps, wherein, based on granularity, timing information inaccuracy, lengths of measurement gaps, and durations of said discovery signals, when a certain discovery signal out of said discovery signals is not completely within a corresponding measurement gap out of said measurement gaps, the cell transmits (2i+3) copies of said certain discovery signal, at least one copy being transmitted before said certain discovery signal, at least one copy being transmitted after said certain discovery signal when the timing information inaccuracy satisfies the condition Δ 2 ≤(T gap /2)−Δ 1 +(2i+1)T/2, wherein Δ 1 is granularity, Δ 2 is timing information accuracy, T is duration of said certain discovery signal, T gap is duration of a corresponding measurement gap, and i is a non-negative integer. Claim: 11. The wireless communication system as in claim 10 , wherein said serving cell is configured to configure said measurement gaps based on said timing information, duration of said discovery signals, and granularity of said wireless communication system. Claim: 12. The wireless communication system as in claim 10 , wherein said cells comprise low power nodes (LPNs). Claim: 13. The wireless communication system as in claim 10 , wherein said UE is adapted for communication with said serving cell and is deployed within said coverage area. Claim: 14. The wireless communication system as in claim 10 , further comprising said UE further adapted to detect said discovery signals during said measurement gaps. Claim: 15. The wireless communication system as in claim 10 , wherein each said cell configured to transmit discovery signals includes each said cell configured to transmit different parts of said discovery signal at different times. Claim: 16. The wireless communication system as in claim 15 , wherein each said cell configured to transmit discovery signals includes each said cell adapted to transmit said different parts of said discovery signal before and after transmitting a full discovery signal of said discovery signals. Claim: 17. The wireless communication system as in claim 10 , wherein each said cell configured to transmit discovery signals includes each said cell adapted to transmit two spaced-apart copies of said discovery signal and wherein said serving cell configured to configure measurement gaps includes said serving cell adapted to target a center of said measurement gap between said two spaced-apart copies of said discovery signal. Claim: 18. The wireless communication system as in claim 10 , further comprising further cells in a further cluster of said further cells deployed in said coverage area and wherein said serving cell is further configured to determine which of said cluster and said further cluster is a more proximate cluster to said UE. Claim: 19. The wireless communication system as in claim 18 , wherein said UE is further configured to perform a conventional cell search in initial inter frequency measurement gaps and provide said timing information to said serving cell and wherein said serving cell configured to configure measurement gaps includes said serving cell configured to configure first measurement gaps of one of said cells and said further cells of said more proximate cluster. Claim: 20. The wireless communication system as in claim 10 , wherein each said cell configured to transmit discovery signals includes each said cell configured to transmit a plurality of successive copies of said discovery signals, and wherein said serving cell configured to configure measurement gaps includes said serving cell configured to configure at least one said measurement gap such that at least one said copy is received entirely with said measurement gap. Claim: 21. A wireless communication system, comprising: a heterogeneous network (HetNet); a serving cell with an associated coverage area; cells in a cluster of cells deployed in said coverage area; each cell of said cluster of cells configured to transmit discovery signals; said serving cell configured to determine timing information of said cells and a discovery signal transmission pattern of said corresponding discovery signals; and said serving cell configured to configure measurement gaps such that said discovery signals are transmitted during said measurement gaps and such that a user equipment (UE) can read said discovery signals in said measurement gaps, wherein each cell of said cluster of cells is a low power node (LPN) configured to transmit a plurality of adjacent copies of a discovery signal of said discovery signals, wherein, based on granularity, timing information inaccuracy, lengths of measurement gaps, and durations of said discovery signals, when a certain discovery signal out of said discovery signals is not completely within a corresponding measurement gap out of said measurement gaps, the cell transmits (2i+3) copies of said certain discovery signal, at least one copy being transmitted before said certain discovery signal, and at least one copy being transmitted after said certain discovery signal when the condition Δ 1 +Δ 2 −(2i+1)T/2≤[T gap /2]is satisfied, wherein Δ 1 is granularity, Δ 2 is timing information inaccuracy, T is duration of said discovery signal, T gap is duration of said measurement gap, and i is a non-negative integer. Claim: 22. The wireless communication system as in claim 21 , further comprising said wireless communication system adapted to determine a number of said copies necessary to insure that one said copy is transmitted within said measurement gap, based on granularity and timing information inaccuracy. Patent References Cited: 8712411 April 2014 Puliatti ; 2008/0274742 November 2008 Bi ; 2009/0318090 December 2009 Flordelis ; 2011/0305194 December 2011 Zheng ; 2012/0190373 July 2012 Tenny ; 2012/0263054 October 2012 Kazmi et al. ; 2015/0215799 July 2015 Kazmi ; 2016/0192332 June 2016 Koorapaty ; 2016/0234878 August 2016 Svedman ; 2016/0262100 September 2016 Larsson ; 2008/085952 July 2008 Other References: International Search Report/Written Opinion dated Jun. 16, 2015, in counterpart International Patent Application No. PCT/US2015/020675. cited by applicant Assistant Examiner: Van, Jenkey Primary Examiner: Sefcheck, Gregory B Attorney, Agent or Firm: Perkins Coie LLP

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Method and system for signal transmission with network assistance