Abstract
Methods and apparatus disclosed maximize the capacity of serving cells and minimize inter-cell interferences due to power emission from serving cells in a multi-carrier multi-cell communication system. The control methods and apparatus take into account various factors such as cell configuration frequency reuse geometry and path-loss information transmission priority subchannel configuration feedback from other cells or any combination thereof and produce signals that control the transmission power levels and the modulation and coding of transmitted signals.
Technology | Declaration Information | Specification Information | Explicitly Disclosed | Patent Type | |||||
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4G | 13/11/2014 | ISLD-201411-006 | A2Z DEVELOPMENT CENTER INC |
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US8031686B2 | 4G | 13/11/2014 | ISLD-201411-006 | A2Z DEVELOPMENT CENTER INC |
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Claim
1. A method of controlling transmission power of signal transmitters and modulation and coding of transmitted signals in a multi-cell wireless communication system for increasing service capacity of a cell and decreasing inter-cell interference with nearby cells, the method comprising:
arranging a communication channel into multiple subchannels, wherein each subchannel consists of at least one subcarrier; and
adaptively controlling the modulation and coding of transmitted signals and signal transmission power, wherein the adaptive control is based on rules and constraints derived from system parameters and direct or indirect performance measurements, and wherein a selected transmission power level satisfies a Rise over Thermal (RoT) threshold requirement, and wherein the adaptive control comprises:
a first process wherein an achievable Channel Quality Information (QNew) at the receiver is updated by:
Qnew=Qcurrent+Pmax?Pcurrent, where Qcurrent denotes a recent measured CQI (Channel Quality Information) at a receiver, Pmax denotes a maximum transmission power available at a transmitter, and Pcurrent denotes a recent transmission power at the transmitter;
in a case where a primary criteria is to maximize throughput while controlling transmission power:
if Qnew exceeds CQI requirement for a highest MCS (modulation and coding scheme) in a protocol, the highest MCS is selected and Pnew is set as the transmission power level for that MCS with a certain margin;
if Qnew is lower than the CQI requirement for the highest MCS, the maximum transmission power (PNew) is selected to derive a corresponding MCS based on the value of Qnew; and
if Qnew is lower than the CQI requirement for the lowest MCS in the protocol, transmission may be denied and outage process may start;
in a case where the primary criteria is to minimize transmission power while meeting a data rate requirement:
if Qnew exceeds the CQI requirement for a given MCS in the protocol, a necessary transmission power level is set for the given MCS with a certain margin; and
if Qnew is lower than the CQI requirement for the given or lowest MCS, transmission is denied; and
a second process wherein an RoT check is performed and, if needed, the power is adjusted to meet the RoT threshold, the second process comprising:
Rnew=Rcurrent+Pnew?Pcurrent, where Rnew denotes a new RoT resulting from the first process computations, and Rcurrent denotes an RoT measurement before application of Pnew, and wherein:
if Rnew is less than the RoT threshold, decisions made during the first process concerning the transmission power level and MCS are maintained; and
if Rnew exceeds the RoT threshold, the transmission power level is reduced to meet the RoT threshold requirement; and
a new transmission power level is calculated as:
P new =P current +R threshold ?R current,
and a new achievable CQI is calculated as:
Q new =P current +R threshold ?R current,
where Rthreshold denotes the RoT threshold and an appropriate MCS is selected based on Qnew.
2. The method of claim 1, wherein service capacity is the capacity to communicate data, voice, video, or any combination thereof.
3. The method of claim 1, wherein at an initial stage of network entry, a mobile station can estimate an uplink CQI and RoT based on an observed path-loss from a downlink message and choose an appropriate transmission power and MCS, and a certain margin to account for the estimation error.
4. In a multi-carrier, multi-cell wireless communication system, a process of controlling transmission power of signal transmitters and modulation and coding scheme (MCS) of transmitted signals, the process comprising:
configuring a communication channel into multiple subchannels, wherein each subchannel consists of at least one subcarrier; and
adaptively controlling the MCS of the transmitted signals and signal transmission powers of the corresponding multiple subchannels to substantially achieve a balance between increasing a capacity of a serving cell and reducing interference with other cells, wherein the adaptive control is based on rules and constraints derived from system parameters and performance measurements, wherein the adaptive control uses the rules to determine the signal transmission powers of the corresponding multiple subchannels at a signal transmitter of the serving cell providing the transmitted signals to a receiver based on interference information received from one or more signal transmitters of other serving cells and representing interference experienced by the one or more signal transmitters of other serving cells providing signals to corresponding receivers in the other serving cells.
5. The process of claim 4, wherein:
the process is applicable to downlink, uplink, or both;
the multi-carrier system comprises Orthogonal Frequency Division Multiplexing (OFDM), or Multi-Carrier Code Division Multiple Access (MC-CDMA); and
a Time Division Duplexing (TDD) or a Frequency Division Duplexing (FDD) technique is employed.
6. The process of claim 4, wherein a total transmission power of a base station is controlled and a maximum allowable level is set relatively high for large cells, isolated cells, or cells with large frequency reuse factors, and wherein the total transmission power of the base station is set relatively low for small cells, congested cells, or cells with small frequency reuse factors, and wherein the total transmission power is adjusted either by changing a power density of each subcarrier/subchannel or changing a number of utilized subcarriers/subchannels.
7. The process of claim 4, wherein a performance measurement is SINR (signal-to-interference-plus-noise ratio), BER (bit error rate), PER (packet error rate), or any combination thereof, and wherein the performance measurement is a single number or a statistical indicator.
8. The process of claim 4, wherein modulation and coding requirements are pre-stored in a table based on system simulation or measurement, or the quality requirements are dynamically adjusted.
9. The process of claim 4, wherein a selected transmission power level requires to satisfy a Rise over Thermal (RoT) threshold, and wherein:
a central control method is adapted and:
a network-wide coordination among adaptive controllers globally optimizes the RoT threshold to achieve high overall performance; and
a central processor, based on information from base stations, determines the RoT threshold with which the network capacity on a particular subchannel is optimized; or
a distributed method is adapted and:
the RoT threshold is computed for each data link; and
an RoT threshold Calculator resides within or outside of a controller, wherein inputs to the Calculator include one or more of the following factors: cell configuration, frequency reuse factor, geometry/path loss information, transmission priority, subchannel configuration, and feedback from other cells or other users and an output of the Calculator is the RoT threshold value.
10. The process of claim 4, wherein the multiple subchannels includes a first subchannel, the signal transmitter of the serving cell providing a signal transmission power for the first subchannel that is higher than a signal transmission power for the first subchannel provided by the signal transmitters providing signals to corresponding receivers in the other serving cells.
11. In a multi-carrier, multi-cell communication system wherein a communication channel is configured into multiple subchannels and each subchannel includes multiple subcarriers, an apparatus for controlling transmission power and modulation and coding scheme (MCS) of transmitted signals, the apparatus comprising:
at least one controller configured to process input information and generate output signals for controlling transmission power and the MCS, wherein the controller uses a part or all of the inputs to generate the output signals, and wherein the output signals are sent to and employed by a transmitter in a next transmission, wherein the transmission powers of subchannels provided by the transmitter of a serving cell in the next transmission are based on interference information received from one or more transmitters of other serving cells and representing interference experienced by the one or more transmitters of other serving cells providing signals to corresponding receivers in the other serving cells; and
wherein the input information to the controller comprises:
performance measurements, wherein the performance measurements are frequently varying and repeatedly updated; and
system parameters and requirements, wherein the system parameters are stable and infrequently updated.
12. The apparatus of claim 11, wherein an Adaptive Modulation Coding and Power (AMCP) controller (a) selects a transmission power level that satisfies a Signal to Noise Ratio (SNR) or Rise over Thermal (RoT) threshold requirement and that achieves the highest modulation and coding scheme (MCS) for applications with adaptive MCS schemes, and (b) selects the corresponding MCS.
13. The apparatus of claim 11, wherein a SNR or RoT threshold is calculated using the cell configuration, frequency reuse factor, geometry and path-loss information, transmission priority, subchannel configuration, feedback from other cells, or any combination thereof; and wherein:
the SNR or RoT threshold is set relatively low if
the cell size is relatively small;
the configuration is relatively congested;
the frequency reuse factor is small;
the path-loss delta is relatively small; or
the transmission priority is low; and the SNR or RoT threshold is set relatively high if
the cell size is relatively large;
the configuration is relatively isolated;
the frequency reuse factor is large;
the path-loss delta is relatively large; or
the transmission priority is high.
14. The apparatus of claim 13, wherein a common SNR or RoT threshold is first set for all active links in one direction to control the interference with close-by cells, and wherein the common SNR or RoT threshold is used as a constraint in the calculation of individual SNR or RoT thresholds for each link.
15. The apparatus of claim 13, wherein information pertaining to interference occurrences within a network is used by a base station to compute the SNR or RoT threshold.
16. The apparatus of claim 11, wherein a path-loss for a mobile station to its serving and/or adjacent base stations is determined from strength of downlink or uplink signals from and to the base station, wherein:
each base station sends a unique downlink preamble signal or a pilot pattern and the mobile station scans through these preamble signals or pilot patterns using correlation or other signal processing methods, and wherein a result of a correlation indicates the path-loss to each base station, and wherein the path-loss information is fed back by the mobile station to its serving base station; or
the mobile station sends a unique ranging signal to a target base station and from the strength of such uplink signals the base station, and other close-by base stations that also detect such uplink signal, measure the corresponding path-loss.
17. The apparatus of claim 11, wherein the inputs and outputs of the controller correspond to an individual subchannel in case each subchannel uses a modulation and coding and a power control different from those of other subchannels or correspond to a set of subchannels in case the set of subchannels use the same modulation and coding and power control to reduce the control overhead.
18. The apparatus of claim 11, wherein the multiple subchannels includes a first subchannel, the signal transmitter of the serving cell providing a signal transmission power for the first subchannel that is higher than a signal transmission power for the first subchannel provided by the signal transmitters providing signals to corresponding receivers in the other serving cells.
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Explicitly disclosed patent:openly and comprehensibly describes all details of the invention in the patent document.
Implicitly disclosed patent:does not explicitly state certain aspects of the invention, but still allows for these to be inferred from the information provided.
Basis patent:The core patent in a family, outlining the fundamental invention from which related patents or applications originate.
Family member:related patents or applications that share a common priority or original filing.