There is described a method of controlling a basestation in a cellular wireless communications network, the method comprising, within the basestation, autonomously and dynamically adapting a maximum value for a total transmit power of the basestation, such that interference between the basestation a
There is described a method of controlling a basestation in a cellular wireless communications network, the method comprising, within the basestation, autonomously and dynamically adapting a maximum value for a total transmit power of the basestation, such that interference between the basestation and other access points in the vicinity is minimized.
대표청구항▼
1. A method of controlling a first basestation in a cellular wireless communications network comprising macrocell basestations and femtocell basestations, the method comprising: running a first set of algorithms at the first basestation at power up of the first basestation, said first set of algorit
1. A method of controlling a first basestation in a cellular wireless communications network comprising macrocell basestations and femtocell basestations, the method comprising: running a first set of algorithms at the first basestation at power up of the first basestation, said first set of algorithms selecting a carrier, a scrambling code, and maximum total downlink power for use by the first basestation in operation;and, in operation of the first basestation: obtaining measurements made by user equipment devices of signals from other basestations of said network;determining, from said measurements made by the user equipment devices, whether there has been a change in interference in a femtocell layer or a macrocell layer requiring a new carrier or scrambling code to be reselected;if there has been such a change in interference, rerunning, at the first basestation, the said first set of algorithms performed on power up for selection of a carrier, a scrambling code, and maximum total downlink power; andif there has not been such a change in interference, setting a maximum value for a total transmit power of the first basestation based on said measurements made by user equipment devices and based on knowledge of round trip delays for a communications path between said first basestation and a user terminal within a target coverage area, and based on a predetermined maximum permitted round-trip delay. 2. A method as claimed in claim 1, further comprising setting said maximum value for the total transmit power autonomously and dynamically within the first basestation. 3. A method as claimed in claim 1, further comprising setting said maximum value for the total transmit power based on: knowledge of the transmit power of, and path loss to, surrounding macrolayer basestations and other basestations, said knowledge being derived from information decoded from broadcast channel transmissions thereof and measured received signal strengths. 4. A method as claimed in claim 1, further comprising setting said maximum value for the total transmit power based on: knowledge of whether a measured dominant interferer is a macrolayer basestation or a nearby access point. 5. A method as claimed in claim 4, wherein said knowledge of whether a measured dominant interferer is a macrolayer basestation or a nearby access point is based on identity information conveyed in the received broadcast channel of said interferer and RF signal measurements therefrom. 6. A method as claimed in claim 1, further comprising setting said maximum value for the total transmit power based on: knowledge of historical statistics for the path loss between said first basestation and permitted User Equipments (UEs) in call therewith said first basestation, and based on a predetermined maximum permitted path loss figure. 7. A method as claimed in claim 1, further comprising setting said maximum value for the total transmit power based on: knowledge of historical statistics for a received signal/interference ratio as measured at UEs in call with the first basestation, and based on a predetermined minimum signal/interference ratio. 8. A method as claimed in claim 7, wherein measurements of said received signal/interference ratio are specifically requested by the first basestation. 9. A method as claimed in claim 1, further comprising setting said maximum value for the total transmit power based on: knowledge of historical statistics for a path loss between UEs in call with the first basestation and nearby nodeBs. 10. A method as claimed in claim 9, wherein measurements of said path loss are specifically requested by the first basestation. 11. A method as claimed in claim 1, further comprising setting said maximum value for the total transmit power based on: knowledge of access attempts by non-permitted users. 12. A method as claimed in claim 1, wherein, before the step of setting a maximum value for a total transmit power of the first basestation, there is the step of: determining whether or not a carrier that has been selected for communicating with UEs is unused by neighbouring macrolayer basestations or other basestations;wherein a carrier is unused if there are no detected macrolayer basestation or other basestation CPICH signals and the received signal strength indicator (RSSI) on the carrier is below a minimum interference threshold. 13. A method as claimed in claim 12, further comprising the step of: if the carrier is not unused by neighbouring macrolayer basestations or other basestations, determining whether the interference caused by neighbouring macrolayer basestations is greater than or less than the interference caused by neighbouring other basestations. 14. A method as claimed in claim 13, said setting step comprising: if said carrier is unused by neighbouring macrolayer basestations or other basestations, setting the total transmit power of the first basestation at a first level;if said carrier is not unused by neighbouring macrolayer basestations or other basestations, and the interference caused by neighbouring macrolayer basestations is greater than the interference caused by neighbouring other basestations, setting the total transmit power of the first basestation at a second level; andif said carrier is not unused by neighbouring macrolayer basestations or other basestations, and the interference caused by neighbouring macrolayer basestations is less than the interference caused by neighbouring other basestations, setting the total transmit power of the first basestation at a third level. 15. A method as claimed in claim 14, further comprising: determining whether said first, second or third levels are greater than a maximum permitted power threshold; andif said first, second or third levels are greater than a maximum permitted power threshold, resetting the total transmit power of the basestation to said maximum permitted power threshold; andif said first, second or third levels are not greater than a maximum permitted power threshold, maintaining the total transmit power of the basestation at its set level. 16. A basestation adapted to perform a method of controlling the basestation in a cellular wireless communications network comprising macrocell basestations and femtocell basestations, the method comprising: running a first set of algorithms at the basestation at power up of the first basestation, said first set of algorithms selecting a carrier, a scrambling code, and maximum total downlink power for use by the first basestation in operation;and, in operation of the first basestation: obtaining measurements made by user equipment devices of signals from other basestations of said network;determining, from said measurements made by the user equipment devices, whether there has been a change in interference in a femtocell layer or a macrocell layer requiring a new carrier or scrambling code to be reselected;if there has been such a change in interference, rerunning, at the basestation, the said first set of algorithms performed on power up for selection of a carrier, a scrambling code, and maximum total downlink power; andif there has not been such a change in interference, setting a maximum value for a total transmit power of the basestation based on said measurements made by user equipment devices and based on knowledge of access attempts by non-permitted users. 17. The basestation as claimed in claim 16, the method further comprising setting said maximum value for the total transmit power autonomously and dynamically within the basestation. 18. The basestation as claimed in claim 16, the method further comprising setting said maximum value for the total transmit power based on: knowledge of the transmit power of, and path loss to, surrounding macrolayer basestations and other basestations, said knowledge being derived from information decoded from broadcast channel transmissions thereof and measured received signal strengths. 19. The basestation as claimed in claim 16, the method further comprising setting said maximum value for the total transmit power based on: knowledge of whether a measured dominant interferer is a macrolayer basestation or a nearby access point. 20. The basestation as claimed in claim 19, wherein said knowledge of whether a measured dominant interferer is a macrolayer basestation or a nearby access point is based on identity information conveyed in the received broadcast channel of said interferer and RF signal measurements therefrom. 21. The basestation as claimed in claim 16, the method further comprising setting said maximum value for the total transmit power based on: knowledge of historical statistics for the path loss between said basestation and permitted User Equipments (UEs) in call therewith said basestation, and based on a predetermined maximum permitted path loss figure. 22. The basestation as claimed in claim 16, the method further comprising setting said maximum value for the total transmit power based on: knowledge of historical statistics for a received signal/interference ratio as measured at UEs in call with the basestation, and based on a predetermined minimum signal/interference ratio. 23. The basestation as claimed in claim 22, wherein measurements of said received signal/interference ratio are specifically requested by the basestation. 24. The basestation as claimed in claim 16, the method further comprising setting said maximum value for the total transmit power based on: knowledge of historical statistics for a path loss between UEs in call with the basestation and nearby nodeBs. 25. The basestation as claimed in claim 24, wherein measurements of said path loss are specifically requested by the basestation. 26. The basestation as claimed in claim 16, the method further comprising setting said maximum value for the total transmit power based on: knowledge of round trip delays for a communications path between said basestation and a user terminal within a target coverage area, and based on a predetermined maximum permitted round-trip delay. 27. The basestation as claimed in claim 16, wherein, before the step of setting a maximum value for a total transmit power of the basestation, there is the step of: determining whether or not a carrier that has been selected for communicating with UEs is unused by neighbouring macrolayer basestations or other basestations;wherein a carrier is unused if there are no detected macrolayer basestation or other basestation CPICH signals and the received signal strength indicator (RSSI) on the carrier is below a minimum interference threshold. 28. The basestation as claimed in claim 27, the method further comprising the step of: if the carrier is not unused by neighbouring macrolayer basestations or other basestations, determining whether the interference caused by neighbouring macrolayer basestations is greater than or less than the interference caused by neighbouring other basestations. 29. The basestation as claimed in claim 28, said setting step comprising: if said carrier is unused by neighbouring macrolayer basestations or other basestations, setting the total transmit power of the basestation at a first level;if said carrier is not unused by neighbouring macrolayer basestations or other basestations, and the interference caused by neighbouring macrolayer basestations is greater than the interference caused by neighbouring other basestations, setting the total transmit power of the basestation at a second level; andif said carrier is not unused by neighbouring macrolayer basestations or other basestations, and the interference caused by neighbouring macrolayer basestations is less than the interference caused by neighbouring other basestations, setting the total transmit power of the basestation at a third level. 30. The basestation as claimed in claim 29, the method further comprising: determining whether said first, second or third levels are greater than a maximum permitted power threshold; andif said first, second or third levels are greater than a maximum permitted power threshold, resetting the total transmit power of the basestation to said maximum permitted power threshold; andif said first, second or third levels are not greater than a maximum permitted power threshold, maintaining the total transmit power of the basestation at its set level. 31. A method of controlling a first basestation in a cellular wireless communications network comprising macrocell basestations and femtocell basestations, the method comprising: running a first set of algorithms at the first basestation at power up of the first basestation, said first set of algorithms selecting a carrier, a scrambling code, and maximum total downlink power for use by the first basestation in operation;and, in operation of the first basestation: obtaining measurements made by user equipment devices of signals from other basestations of said network;determining, from said measurements made by the user equipment devices, whether there has been a change in interference in a femtocell layer or a macrocell layer requiring a new carrier or scrambling code to be reselected;if there has been such a change in interference, rerunning, at the first basestation, the said first set of algorithms performed on power up for selection of a carrier, a scrambling code, and maximum total downlink power; andif there has not been such a change in interference, setting a maximum value for a total transmit power of the first basestation based on said measurements made by user equipment devices and based on knowledge of access attempts by non-permitted users. 32. A basestation adapted to perform a method of controlling the basestation in a cellular wireless communications network comprising macrocell basestations and femtocell basestations, the method comprising: running a first set of algorithms at the basestation at power up of the first basestation, said first set of algorithms selecting a carrier, a scrambling code, and maximum total downlink power for use by the first basestation in operation;and, in operation of the first basestation: obtaining measurements made by user equipment devices of signals from other basestations of said network;determining, from said measurements made by the user equipment devices, whether there has been a change in interference in a femtocell layer or a macrocell layer requiring a new carrier or scrambling code to be reselected;if there has been such a change in interference, rerunning, at the basestation, the said first set of algorithms performed on power up for selection of a carrier, a scrambling code, and maximum total downlink power; andif there has not been such a change in interference, setting a maximum value for a total transmit power of the basestation based on said measurements made by user equipment devices and based on knowledge of round trip delays for a communications path between said basestation and a user terminal within a target coverage area, and based on a predetermined maximum permitted round-trip delay.
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