KR101026623B1 - Methods and apparatus for controlling a base station's transmission power - Google Patents

Abstract

The base station receives loading information indicating the loading of other base stations to determine the downlink transmit power budget as a function of the received loading factor information. The base station may decrease / increase the current power budget assigned to downlink traffic channel segments in response to detecting an increase / decrease in loading at a neighboring base station. Thus, the base station operates in a cooperative manner that reduces power output in at least some cases where the loading at the neighboring base station increases, thus reducing interference to the base station with increased load. The base station may take into account possible optional transmit power levels, estimated interference levels and / or possible optional data rates when making trade-off decisions with respect to the downlink power budget.

Description

METHODS AND APPARATUS FOR CONTROLLING A BASE STATION'S TRANSMISSION POWER}

35 U.S.C. Claim of Priority in § 119

This application is a partial consecutive application of US Patent Application No. 11 / 251,069, filed October 14, 2005, a partial consecutive application of US Patent Application No. 11 / 302,729, filed December 14, 2005, on July 14, 2006. Filed U.S. Patent Application SN Part of the Serial Application of 11 / 486,714, filed on July 14, 2006, in US Patent Application S.N. Some consecutive applications of 11 / 487,017, each of which are incorporated by reference.

Technical field

The present invention relates to wireless communication systems, and more particularly to power control in a wireless communication system.

In a wireless communication system that includes at least some base stations that use the same radio resources, such as the frequency spectrum, with multiple base stations, downlink transmission from one base station may be performed by another base station, such as adjacent base stations using the same frequency spectrum. May interfere with downlink transmissions. Downlink traffic channel loading conditions at a particular base station attachment point generally include the number of users, the type of users, the type of applications in use, the amount of data to be communicated, error tolerance levels, latency requirements, channel conditions, error rates. And as a function of a number of factors including the positions of the wireless terminal. Changing the transmit power level of a traffic channel segment can affect the attainable information data rates for a particular wireless terminal, but attaches to different base station attachment points of other base stations using the same frequency spectrum, for example, adjacent base stations. The interference level from the perspective of other wireless terminals.

By using a fixed downlink transmit power budget for each base station attachment point, the overall downlink interference in the system can be controlled. The power associated with different sub-channels in the downlink traffic channel may be varied while keeping the overall downlink power budget at a fixed level. This approach tends to limit the overall interference in the system, but may fail to use different system loading conditions to optimize throughput. It would be advantageous if the base station could change the downlink transmit power budget in response to changing loading conditions at its own or in neighboring base stations without being limited to a single downlink power budget. It would be advantageous if neighboring base stations exchanged the loading information so that the base station could make timely decisions related to downlink transmit power levels. Also, since the base station has appropriate information readily available such as current loading conditions, current channel conditions, user profiles, detected changes, ongoing applications, if power budget decisions for a particular base station are made at the base station, It will be advantageous, and will eventually promote a promptly informed response to changing conditions.

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Various embodiments relate to methods and apparatus for communicating, collecting, measuring, reporting, and / or using information that can be used for interference control purposes, load management, and / or dynamic change of base station downlink power budget.

According to various embodiments, a base station receives loading information indicating the loading of other base stations, such as, for example, adjacent base stations, and the base station determines the downlink transmit power budget as a function of the received loading factor information. For example, the base station may decrease the current power budget assigned to downlink traffic channel segments in response to detecting an increase in loading at a neighboring base station. The base station may increase the current power budget assigned to the downlink traffic channel segments in response to detecting a decrease in loading at an adjacent base station. Thus, the base stations operate in a cooperative manner that reduces power output in at least some cases where the loading at the neighboring base station increases, thus reducing interference to base stations with increased load. This is in stark contrast to systems that attempt to increase power output in response to increasing load at a neighboring base station to overcome the increased interference generated by the neighboring base station with an increased communication load. The disclosed method and apparatus are particularly well suited for use in a communication system comprising a plurality of base stations which may interfere with each other. This is because in a wireless communication system including multiple base stations, downlink transmissions from one base station generate interference with respect to other base stations, for example, adjacent base stations using the same frequency spectrum. The base station may take into account possible optional transmit power levels, estimated interference levels and / or possible optional data rates, for example, when performing trade-off decisions related to downlink power budget for downlink traffic channels. .

An exemplary method of operating a first base station in accordance with various embodiments includes receiving second base station loading factor information indicating loading of a second base station attachment point corresponding to the second base station; And determining a downlink transmit power budget as a function of the received second base station loading factor information. An example base station in accordance with various embodiments includes an interface for receiving signals in communication with base station loading factor information indicating loading of at least one base station attachment point corresponding to at least one other base station; A loading factor information recovery module for recovering loading factor information corresponding to at least one other base station from the received signals; And a downlink transmit power budget determination module, wherein the downlink transmit power budget determination module determines a downlink transmit power budget for an attachment point of a base station as a function of the restored loading factor information corresponding to at least one other base station. Decide

While various embodiments are described above, it should be appreciated that not all embodiments need to include the same features, and that some of the features described above may be desirable, although not required in some embodiments. Various further features, embodiments and advantages of the invention are discussed in the following description.

1 is a diagram of an exemplary wireless communication system implemented in accordance with various embodiments.

2 is a diagram of an exemplary base station in accordance with various embodiments.

3 is a diagram of an exemplary wireless terminal in accordance with various embodiments.

4 is a flowchart of an exemplary method of operating a first base station in a multiple access wireless communication system including a plurality of base stations in accordance with various embodiments.

5 is a flowchart of an exemplary method of operating a first base station in a multiple access wireless communication system including a plurality of base stations in accordance with various embodiments.

6 is a flowchart 600 of an exemplary method of operating a first base station in a multiple access wireless communication system including a plurality of base stations in accordance with various embodiments.

7 is a feature of various embodiments in which a base station in a wireless communication system including multiple base stations receives loading factor information corresponding to another base station and determines a downlink transmission power budget as a function of the received base station loading factor information. It is a drawing used to explain them.

8 is a feature of various embodiments in which a base station in a wireless communication system including multiple base stations receives loading factor information corresponding to another base station and determines a downlink transmission power budget as a function of the received base station loading factor information. It is a drawing used to explain them.

9 is a feature of various embodiments in which a base station in a wireless communication system including multiple base stations receives loading factor information corresponding to another base station and determines a downlink transmission power budget as a function of the received base station loading factor information. It is a drawing used to explain them.

10, which includes a combination of FIGS. 10A and 10B, is a flowchart of an exemplary method of operating a base station in accordance with various embodiments.

1 is a diagram of an exemplary wireless communication system 100, such as a multiple access OFDM wireless communication system, in accordance with various embodiments. Exemplary wireless communication system 100 includes a number of base stations (base station 1 102,..., Base station M 104) and a network node 110. Each base station 102, ..., 104 includes at least one base station attachment point. Base stations 102, ..., 104 may include one or more sectors and may use one or more carriers. For example, a base station attachment point corresponds to a combination of cell and carrier in some embodiments for some base stations. In some embodiments, the base station attachment point for some base stations corresponds to a combination of cell, sector and carrier. Network node 110 is coupled to (base station 1 102,... Base station M 104) via network links 120, 122, respectively. Network node 110 is also coupled to other network nodes and / or the Internet via network link 124. Network links 120, 122, 124 are, for example, fiber optic links, wired links, and / or wireless links. Each base station (base station 1 102,..., Base station M 104) each has a corresponding radio coverage area (cell 1 106, cell M 108).

The communication system 100 includes a plurality of wireless terminals, such as mobile nodes, for example, which can pass through the system and can be attached to the base station at which the wireless terminal is currently located in the coverage area of the base station. have. The wireless terminals (WT 1 112, ..., WT N 114) currently located in cell 1 are coupled to base station 1 102 via wireless links 126, ..., 128, respectively. . Wireless terminals currently located within cell M 108 (WT 1 ′ 116,..., WT N ′ 118) are respectively connected to base station M via wireless links 130, ..., 132. 104).

At least some of the base stations in system 100 consider loading information from other base stations, such as neighboring base stations in addition to their own loading, and transmit their downlink as a function of the loading of other base stations, such as neighboring base stations. The power is adjusted dynamically, for example. In some embodiments, the base station makes an independent determination of the downlink power budget corresponding to one of its base station attachment points, but when performing the determination, it receives the received loading information of other base stations, such as neighboring base stations in the vicinity. use.

2 is a diagram of an exemplary base station 200 implemented in accordance with various embodiments. Exemplary base station 200 may be any base station of FIG. 1 or 4 or 5 or 6. Exemplary base station 200 includes a receiver module 202, a transmitter module 204, a processor 206, an I / O interface 208 and a memory over a bus 212 through which various elements may exchange data and information. And 210.

For example, a receiver module 202, such as an OFDM receiver, is coupled to receive antenna 216 where base station 200 receives uplink signals from wireless terminals. In some embodiments, the uplink signals include base station load factor information corresponding to other base stations in a communication system having a wireless terminal connected to another base station, such as base station 200 and an adjacent base station operating as a relay. .

Transmitter module 204, such as an OFDM transmitter, for example, is coupled to transmit antenna 218 where base station 200 transmits downlink signals to wireless terminals. The downlink signals include traffic channel signals and pilot channel signals, and the power budget for the traffic channel signals corresponds to base station 200 and load factor information corresponding to other base stations, for example, neighboring base stations. Is controlled as a function of load argument information.

I / O interface 208 couples base station 200 to the Internet and / or other network nodes, such as adjacent base stations. Load factor information is exchanged between the base station 200 and other base stations, such as adjacent base stations, via the I / O interface 208. Accordingly, I / O interface 208 receives signals that communicate base station loading factor information indicating loading of at least one base station attachment point corresponding to at least one other base station, such as a neighbor base station.

Memory 210 includes routines 220 and data / information 222. A processor 206, such as a CPU, executes the routines 220 of the base station 200, and uses the data / information 222 in the memory 210 to control operations and execute methods.

The routines 220 include a communication routine 224 and base station control routines 226. The communication routine 224 executes various communication protocols used by the base station 200. Base station control routines 226 include scheduler 228, pilot channel signaling module 230, traffic channel signaling module 232, loading factor information recovery module 234, downlink transmit power budget determination module 236, loading A factor determination module 238, a loading factor comparison module 240, and a loading factor tracking module 242. In some embodiments, at least one of the loading factor comparison module 240 and the loading factor tracking module 242 is included as part of the downlink transmit power budget determination module 236.

Scheduler 228 schedules wireless terminals in downlink and uplink traffic channel segments. Pilot channel signaling module 230 controls the generation and transmission of pilot channel signals such as modulation symbols known at predetermined power levels at predetermined locations within the cyclical timing and frequency structure. In the above exemplary embodiments, the pilot channel signals corresponding to the base station attachment point are transmitted at the same transmit power level per ton independent of downlink loading conditions at base station 200 or adjacent base stations. Traffic channel signaling module 232 controls the generation and transmission of traffic channel segment signals such as, for example, downlink traffic channel segment signals. The overall power budget associated with the base station 200 attachment point for downlink traffic channels is dynamically adjusted in response to decisions by the downlink transmit power budget determination module 236. Individual sub-channels in a downlink traffic channel may be transmitted at different power levels, and are sometimes transmitted.

The loading factor information recovery module 234 recovers loading factor information corresponding to base station attachment points of other base stations, such as, for example, neighboring base stations, from the received signals. For example, the loading factor information recovery module 234 may receive the received signals (received BS 2 signals (1) 244, received BS 2 signals (n) 246, received BS N signals (1)). 252, respectively, from the received BS N signal (n) 254 (restored BS 2 LF (t1) 248, reconstructed BS 2 LF (tn) 250, reconstructed BS N LF (t1) 256), the recovered BS N LF (tn) 258). In various embodiments the loading factor information includes downlink transmission loading of base station attachment points, such as, for example, downlink traffic channel loading at the base station attachment point.

The downlink transmit power budget determination module 236 is one or more attachment points of the base station 200 as a function of recovered loading factor information corresponding to at least one other base station, for example, one other neighboring base station. Determine the downlink transmit power budget for. In various embodiments, the determined power budget is a power budget for a set of downlink communication channels that includes at least a pilot channel and a data traffic channel. In some embodiments of the above, the portion of the power budget determined for the pilot channel is independent of the loading factor information, and the portion of the power budget corresponding to the data traffic channel is based on the base station loading factor information of another base station, such as, for example, a neighboring base station; It is determined according to the loading factor information of the base station 200. For example, the pilot channel signals may be transmitted at a power level per ton that does not change as a function of loading, but the traffic channel signal transmission power levels may be at a load factor determined for the base station 200 attachment point and at an attachment point of an adjacent base station. It can vary as a function of the corresponding received load factor. The results of the loading factor comparison module 240 are used as input by the determination module 236. The determined transmit power budget (time T1) 264 and the determined transmit power budget (time Tn) 270 are outputs from the determining module 236.

The loading factor determination module 238 determines a loading factor corresponding to the attachment point of the base station 200 for each attachment point of the base station 200. The determined base station loading factor (time t1) 260 and the determined base station loading factor (time tn) 262 indicate the outputs of the determination module 236 corresponding to the same base station 200 attachment point at different times.

The loading factor comparison module 240 compares the determined loading factor corresponding to the attachment point of the base station 200 with the restored loading factor corresponding to the attachment point of another base station, for example, the neighboring base station.

In some embodiments, the downlink transmit power budget determination module 236 is configured such that the loading of the attachment point of another base station, such as an adjacent base station, to which the loading factor comparison module 240 is involved in the comparison, is determined by the attachment point of the base station 200. Determining a power budget corresponding to a first value indicating the budget when determining greater than loading, and downlink transmit power budget determination module 236 determines that the loading factor comparison module 240 is associated with a neighboring base station involved in the comparison. When determining that the loading of the attachment point of the same other base station is smaller than the loading of the attachment point of the base station 200, the power budget is determined to correspond to a second value indicating a power budget that is greater than the power budget indicated by the first value. do.

In some embodiments, a heavily loaded base station sends the loading factor to a neighbor base station when it expects the base station receiving the loading factor has a lower loading and will reduce its transmit power budget. This in turn will eliminate interference experienced by the heavily loaded base station and allow the throughput rate at the heavily loaded base station to be increased.

The loading factor tracking module 242 tracks changes of loading factors at base station attachment points, for example attachment points corresponding to other base stations, such as adjacent base stations and attachment points corresponding to two base stations 200. do. The detected changes identified by the loading factor tracking module 242 are used by the downlink transmit power budget determination module 236 when determining the power budget for the base station attachment point of the base station 200. In some embodiments, downlink transmission power determination module 236 reduces the current power budget of the attachment point of base station 200 in response to an increase in loading detected at other base stations, such as, for example, neighboring base stations. The downlink transmit power determination module 236 increases the current power budget in response to a reduction in loading detected at another base station, for example, a neighbor base station. In some embodiments, the downlink transmission power determination module 236 increases the current power budget of the attachment point of the base station 200 in response to the increase in loading detected at the attachment point of the base station 200, and downlink transmissions. The power determination module 236 reduces the current power budget in response to the reduction in loading detected at the attachment point of the base station 200.

The data / information 222 is a set of received signals (received base station 2 signals (1) 244, ..., received base station 2 signals) that carry loading factor information corresponding to multiple base stations over time. n) 246), ..., (received base station N signal (1) 252, ..., received base station N signal (n) 254). Received signals carrying loading factor information are passed through a backhaul network in some embodiments via I / O interface 208. In some embodiments, the received signals are received via a receiver 202 having a wireless terminal coupled to, for example, two base stations relaying information. The data / information 210 may also contain restored base station 2 loading factor information (restored BS 2 loading factor (t1) 248,..., Restored base station 2 loading factor) indicating the base station 2 loading at different times. tn) 250), the recovered base station N loading factor information indicating the base station N loading at different times (restored BS N loading factor (t1) 256, ..., restored BS N loading factor (tn) 258), the determined BS 200 loading factor information indicating the BS 200 loading at different times (determined BS loading factor (t1) 260, ..., determined BS loading factor (tn) ( 262)).

The data / information 222 is determined based on the determined downlink transmit power budget information over time (determined downlink transmit power budget (T1) 264, ..., determined downlink transmit power budget (Tn)). 270). The determined downlink transmit power budget information 264 includes pilot channel budget information 266 and the determined downlink traffic channel budget information (T1) 268, while the determined downlink transmit power budget (Tn) 270 is a pilot. Channel power budget information 266 and the determined downlink traffic channel power budget (Tn) 272. In this exemplary embodiment, the pilot channel signal transmit power level does not change the channel as a function of the loading conditions, but the downlink traffic channel power budget does not change the loading conditions and / or as in adjacent base station and / or base station 200. Or may change as a function of loading condition changes and sometimes change.

Data / information 222 also includes comparison criteria for changing power budget 274, number of current users 276, amount of backlog downlink traffic information 278, and downlink channel condition information. The comparison criteria for the varying power budget 274 includes predetermined threshold limits at which the loading factor comparison module 1340, the loading factor tracking module 242, and / or the downlink transmit power budget determination module 236 are used. . The number of current users 276 includes information corresponding to, for example, the number of currently registered users, the number of active users, and / or the number of ON state users at the base station 200 capture point. The amount of backlog downlink traffic channel information 278 depends on, for example, the synthesis of registered users and information identifying the number of MAC frames of downlink traffic waiting to be transmitted corresponding to each of the current users of base station 200. Corresponding information identifying the number of MAC frames of the downlink traffic waiting to be transmitted. The downlink channel condition information 280 includes channel condition measurement information corresponding to current users of the base station 200, for example, signal to noise measurement information and / or signal to interference measurement information. At least some of the current number of users information 276, amount of backlog downlink traffic channel information 278, and downlink channel condition information 280 determine the loading factor when determining the loading factor corresponding to the base station 200 attachment point. Used by module 238.

3 is a diagram of an exemplary wireless terminal 300, such as a mobile node, in accordance with various embodiments. Exemplary wireless terminal 300 may be any of the exemplary wireless terminals of FIG. 1 or 4 or 5 or 6. Exemplary wireless terminal 300 includes a first receiver module 302, a first transmitter module 304, a processor 306, I coupled to each other via a bus 312 through which various elements can exchange data information. / O devices 308 and memory 310. In some embodiments, the wireless terminal 300 includes a second receiver module 318 and a second transmitter module 320 coupled to the bus 312.

A first receiver module 302, such as an OFDM receiver, is connected to a receive antenna 314 where the wireless terminal 300 receives downlink signals from a base station. The downlink signals are for example downlink traffic channel segment assignment signals, downlink traffic channel segment signals, requests for the wireless terminal to relay base station loading information, for the wireless terminal to relay base station loading information. Assignment signals such as instructions and / or base station attachment point loading information.

The first transmitter module 304, such as an OFDM transmitter, is connected to a transmit antenna 316 where the wireless terminal 300 transmits uplink signals to base stations. In some embodiments, the same antenna is used for the receiver module 302 and the transmitter module 304 in connection with the duplex module. Uplink signals include dedicated control channel reports such as SNR reports, uplink traffic channel segment signals, access signals, power control signals, timing control signals, and handoff signals. The uplink signals also include messages carrying loading factor information corresponding to a base station attachment point with a wireless terminal operating as a repeater between two adjacent base stations.

A second receiver module 318, such as an OFDM receiver, is connected to a receive antenna 322 where the wireless terminal 300 receives downlink signals from base stations. The downlink signals are for example downlink traffic channel segment assignment signals, downlink traffic channel segment signals, requests for the wireless terminal to relay base station loading information, for the wireless terminal to relay base station loading information. Assignment signals such as instructions and / or base station attachment point loading information.

A second transmitter module 320, such as an OFDM transmitter, is connected to a transmit antenna 324 where the wireless terminal 300 transmits uplink signals to base stations. In some embodiments, the same antenna is used for the receiver module 318 and the transmitter module 320 in connection with the duplex module. Uplink signals include dedicated control channel reports such as SNR reports, uplink traffic channel segment signals, access signals, power control signals, timing control signals, and handoff signals. The uplink signals also include messages carrying loading information such as downlink loading factor corresponding to a base station attachment point with a wireless terminal operating as a repeater between two adjacent base stations.

I / O devices 308, such as keypads, keyboards, microphones, switches, displays, speakers, and the like, allow a user of WT 300 to enter data / information and access output data / information. The input devices 308 also allow the user to control at least some of the functions of the wireless terminal, such as initiating a communication session with a peer node.

Memory 310 includes routines 326 and data / information 328. The processor 306, eg, the CPU, uses the data / information 328 in the memory 310 to execute the routines 326, to control the operation of the wireless terminal 300, and to execute the steps of the method. Routines 326 include communication routine 330 and base station control routines 332. The communication routine 330 executes various communication protocols used by the wireless terminal 300. Base station control routines 332 include a loading factor relay request / command monitor module 334, a loading factor recovery module 336 and a loading factor relay module 338.

The loading factor request / command monitor module 334 receives, to the wireless terminal 300, base station loading factor information such as downlink traffic channel base station loading information corresponding to one or more attachment points from the first base station. Monitor the received downlink signaling for the request and / or command directed to the wireless terminal 300 instructing the base station to relay the loading factor information to the two base stations. In some embodiments, the loading factor relay request / command monitor module 334 is used when the wireless terminal 300 is in a wireless terminal operating mode, the wireless terminal being two to two different base station attachment points. Support communication links simultaneously. For example, the WT 300 is in a multiple-access mode of operation and is currently coupled to a first base station via a receiver / transmitter module pair 302/304, and simultaneously via a receiver / transmitter module pair 318/320. It may be coupled to a second base station, and the monitor module 334 detects a signal instructing or requesting the wireless terminal 300 to transmit downlink loading information about the first base station attachment point to the second base station. In some embodiments, if the wireless terminal receives a request to send loading factor information and the wireless terminal is not in a multi-connection mode, the wireless terminal multiplexes in response to the received request / command to send loading factor information. Can transition to connected mode

The loading factor recovery module 336 is responsive to the request or command detected by the module 334 and recovers loading information, such as downlink base station attachment point loading information, from the received downlink signals. The loading factor relay module 338 responds to the loading factor recovery module 336 and generates messages that convey the recovered loading factor information to be communicated via uplink signaling to another base station, for example, an adjacent base station. . The loading factor relay module 338 controls the transmission of the generated relay messages.

The data / information 328 includes loading factor information 340, received base station loading factor information 342, generated base station loading factor message information 344, system base station information 346, and wireless terminal operating mode information 348. A received request / command for relaying the message. The received request / command for relaying the base station loading factor information 340 includes received requests and / or instructions for causing the wireless terminal 300 to serve as a relay between the base stations and to transmit the loading factor information. . In some embodiments, the request identifies a receiving base station. In some embodiments, stored system base station information 346 is used to determine associated receiving base stations, such as neighbor base stations that may be affected by downlink signaling from a source base station attachment point, for example, that may be interfering. Received base station loading factor information 342, e.g., base station attachment point loading factor corresponding to downlink traffic channel loading, is an output of reconstruction module 336 and is an input to loading factor relay module 338. The generated base station loading factor relay message is the output of the loading factor relay module 338 and is used as input to a wireless transmitter module, such as module 304 or module 320. System base station information 346 includes information (base station 1 information 350,..., Base station n information 352) corresponding to a plurality of base stations in the wireless communication system. The base station 1 information 350 may include, for example, downlink carrier information, downlink tone block information, uplink carrier information, channel structure information, tone hopping information, power level information, message structure information, cyclic timing structure information, and the like. Information corresponding to each of the attachment points. The WT operation mode information 348 includes information identifying whether the wireless terminal 300 is in a single connection operation mode or a multiple connection operation mode.

4 is a flow diagram 400 of an exemplary method of operating a first base station in a multiple access wireless communication system including a plurality of base stations in accordance with various embodiments. Each base station in the exemplary communication system includes at least one base station attachment point that wireless terminals, such as mobile nodes near the base station, may attach to the network. The base station may include one or more sectors. The base station attachment point corresponds to the base station sector, uplink carrier, uplink OFDM tone block, downlink carrier and downlink OFDM tone block in the above exemplary embodiment.

Operation begins in step 402, where the first base station is powered on and commences, and proceeds to step 404. In step 404, the first base station receives second base station loading factor information indicating loading of a second base station attachment point corresponding to the second base station. The second base station may be adjacent to, and sometimes adjacent to, the first base station. Exemplary loading information of a base station includes the number of active terminals connected, a Quality of Service (QoS) profile of the terminals (e.g., number of high QoS value terminals versus low QoS value terminals, QoS of traffic associated with the terminals). Profile (eg, amount of voice or video traffic versus amount of maximum-acting data traffic) and radio link resources (eg, power and bandwidth) required to support the traffic required by the connected active terminals. For example, the loading may increase when the base station provides increased voice traffic, and even if the base station services the same amount of traffic in terms of bits per second, the loading may be performed by most of the connected terminals. This may vary depending on the distance from the base station and the proximity of the base station, because the radio linker needed to support the traffic. This is because the circles, especially the power, are different from one another, and operation proceeds from step 404 to step 406.

In step 406, the first base station determines the downlink transmit power budget as a function of additional loading factor information corresponding to another base station attachment point, which another base station attachment point is the attachment point of the first base station. For example, another attachment point of the first base station and a second attachment point of the second base station may correspond to adjacent sectors using the same downlink carrier frequencies and the same downlink tone blocks, and the determined downlink transmission The power budget may correspond to another base station attachment point of the first base station. In some embodiments, the determined downlink transmit power budget is for a set of downlink communication channels including at least a pilot channel and a data traffic channel. In some embodiments the first portion of the determined power budget assigned for the pilot channel is independent of the first and second loading factor information, and the second portion of the determined power budget assigned to correspond to the data traffic channels is second. It is determined according to the base station loading factor information and additional loading factor information. For example, pilot channel signals corresponding to the additional attachment point of the first base station are broadcast at the first predetermined transmit power level regardless of the loading conditions of the second additional loading factor information, but additional attachment point of the first base station. Corresponding traffic channel signals are transmitted at a power level that is a function of the second additional loading factor information. Step 406 includes sub-steps 408, 410, 412, 414, 416, 418.

At sub-step 408, the first base station compares the additional loading factor information of the first base station with the second base station loading factor information. The loading factor information that is compared may refer to downlink loading of downlink, such as downlink traffic channel radio link resources. Operation proceeds from sub-step 408 to sub-step 410. At sub-step 410, the first base station determines whether the comparison of sub-step 408 indicates that the second base station loading is greater than the first base station loading. If the check in step 410 indicates that the second base station loading is greater than the first base station loading, operation proceeds to step 412 where the base station determines that the power budget corresponds to the first value indicative of the budget. Otherwise, operation proceeds from sub-step 410 to sub-step 414.

At sub-step 414, the first base station determines whether the comparison of sub-step 408 indicates that the second base station loading is less than the first base station loading. If the inspection of step 414 indicates that the second base station loading is less than the first base station loading, operation proceeds to sub-step 416, where the base station is less than the power budget indicated by the first value. Determine to correspond to a second value representing a large budget, otherwise operation proceeds from sub-step 414 to sub-step 418. In sub-step 418, the first base station determines that the power budget corresponds to a third value indicative of the budget. For example, the third value may indicate a power budget between the power budget represented by the first value and the power budget represented by the second value.

In some embodiments, the values of base station loading to be compared in steps 410 and 414 are quantized with indications of actual loading decisions, and progress to step 418 is performed with the first and second base station loading quantized levels. The values may indicate the same, and the first and second base station actual loading decisions may indicate nearly the same.

In some embodiments, step 410 checks whether the second base station loading is greater by a first predetermined amount than the first base station loading, and step 414 includes a second predetermined base station loading than the first base station loading. Check for greater than 2 quantities. Thus, if operation proceeds to step 418, it indicates that the first and second base station loadings are approximately the same.

5 is a flowchart 500 of an exemplary method of operating a first base station in a multiple access wireless communication system including a plurality of base stations in accordance with various embodiments. Each base station in the exemplary communication system includes at least one base station attachment point that wireless terminals, such as mobile nodes near the base station, may attach to the network. The base station may include one or more sectors. The base station attachment point corresponds to the base station sector, uplink carrier, uplink OFDM tone block, downlink carrier and downlink OFDM tone block in the above exemplary embodiment.

Operation begins in step 502, where the first base station is powered on and commences, and proceeds to step 504. In step 504, the first base station receives second base station loading factor information indicating loading of a second base station attachment point corresponding to the second base station. The second base station may be adjacent to, and sometimes adjacent to, the first base station. Operation proceeds from step 504 to step 506.

In step 506, the first base station determines the downlink transmit power budget as a function of additional loading factor information corresponding to another base station attachment point, which another base station attachment point is the attachment point of the first base station. For example, another attachment point of the first base station and a second attachment point of the second base station may correspond to adjacent sectors using the same downlink carrier frequencies and the same downlink tone blocks, and the determined downlink transmission The power budget may correspond to another base station attachment point of the first base station. In some embodiments, the determined downlink transmit power budget is for a set of downlink communication channels including at least a pilot channel and a data traffic channel. In some embodiments the first portion of the determined power budget assigned for the pilot channel is independent of the first and second loading factor information, and the second portion of the determined power budget assigned to correspond to the data traffic channels is second. It is determined according to the base station loading factor information and the additional loading factor information. For example, pilot channel signals corresponding to the additional attachment point of the first base station are broadcast at the first predetermined transmit power level regardless of the loading conditions of the second additional loading factor information, but additional attachment point of the first base station. Corresponding traffic channel signals are transmitted at a power level that is a function of the second additional loading factor information. Step 506 includes sub-steps 508, 510, 512, 514, 516.

At sub-step 508, the first base station compares the current second base station loading factor information with previously stored second base station loading factor information. The loading factor information that is compared may refer to downlink loading of downlink, such as downlink traffic channel radio link resources. Operation proceeds from sub-step 508 to sub-step 510. At sub-step 510, the first base station determines whether the comparison of sub-step 508 indicates that the loading is not increased, decreased or changed at the second base station. If the determination of step 510 is to increase the loading of the second attachment point at the second base station, operation proceeds to step 512 where the first base station reduces the downlink power budget. If the determination of step 510 does not change the loading at the second base station, operation proceeds from step 510 to step 516, where the first base station does not change the downlink transmit power budget. If the determination of step 510 reduces the loading at the second base station, operation proceeds to step 514, where the first base station increases the downlink power budget.

6 is a flowchart 600 of an exemplary method of operating a first base station in a multiple access wireless communication system including a plurality of base stations in accordance with various embodiments. Each base station in the exemplary communication system includes at least one base station attachment point that wireless terminals, such as mobile nodes near the base station, may attach to the network. The base station may include one or more sectors. The base station attachment point corresponds to the base station sector, uplink carrier, uplink OFDM tone block, downlink carrier and downlink OFDM tone block in the above exemplary embodiment.

Operation begins in step 602, where the first base station is powered on and commences, and proceeds to step 604. In step 604, the first base station receives second base station loading factor information indicating loading of a second base station attachment point corresponding to the second base station. The second base station may be adjacent to, and sometimes adjacent to, the first base station. Operation proceeds from step 604 to step 606.

In step 606, the first base station determines the downlink transmission power budget as a function of additional loading factor information corresponding to another base station attachment point, which another base station attachment point is the attachment point of the first base station. For example, another attachment point of the first base station and a second attachment point of the second base station may correspond to adjacent sectors using the same downlink carrier frequencies and the same downlink tone blocks, and the determined downlink transmission The power budget may correspond to another base station attachment point of the first base station. In some embodiments, the determined downlink transmit power budget is for a set of downlink communication channels including at least a pilot channel and a data traffic channel. In some embodiments the first portion of the determined power budget assigned for the pilot channel is independent of the first and second loading factor information, and the second portion of the determined power budget assigned to correspond to the data traffic channels is second. It is determined according to the base station loading factor information and additional loading factor information. For example, pilot channel signals corresponding to the additional attachment point of the first base station are broadcast at the first predetermined transmit power level regardless of the loading conditions of the second additional loading factor information, but additional attachment point of the first base station. Corresponding traffic channel signals are transmitted at a power level that is a function of the second additional loading factor information. Step 606 includes sub-steps 608, 610, 612, 614, 616.

In sub-step 608, the first base station compares the current first base station loading factor information with the previously stored first base station loading factor information. The loading factor information that is compared may refer to downlink loading of downlink, such as downlink traffic channel radio link resources. Operation proceeds from sub-step 608 to sub-step 610. In sub-step 610, the first base station determines whether the comparison of sub-step 608 indicates that the loading is not increased, decreased or changed at the first base station. If the determination of step 610 is to increase the loading of additional attachment points at the first base station, operation proceeds to step 612 where the first base station reduces the downlink power budget. If the determination of step 610 does not change the loading at the first base station, operation proceeds from step 610 to step 616, where the first base station does not change the downlink transmit power budget. If the determination of step 610 reduces the loading at the first base station, operation proceeds to step 614, where the first base station increases the downlink power budget.

7 is a diagram of various embodiments in which a base station in a wireless communication system including multiple base stations receives loading factor information corresponding to another base station and determines a downlink transmission power budget as a function of the received base station loading factor information. A diagram 1000 is used to describe the features. The diagram 1000 includes an example diagram 1002 that includes base station 1 1050 and base station 2 1052 connected together via a network link 1068. Base station 1 1050 is coupled to multiple wireless terminals WT 1 1054, WT 2 1056, WT 3 1058, and WT 4 1060 via wireless links. Base station 2 1052 is coupled to multiple wireless terminals (WT 1 '1062, WT 4' 1064) via wireless links. BS 1 1050 calculates a loading factor 1070 that corresponds to the current downlink traffic channel loading. BS 2 1052 has calculated a loading factor 1072 corresponding to its current downlink traffic channel loading. BS 2 sends a message 1074 over backhaul network link 1068 that conveys its loading factor 1072. BS 1 1050 receives the loading factor message 1074, restores the loading factor corresponding to BS 2 1052, and compares the loading factor 1072 with its loading factor 1070. BS 1 determines whether the loading factor 1072 for BS 2 is less than its loading factor 1070 and sets its downlink transmit power budget to the first level. Diagram 1006 of FIG. 1000 illustrates the downlink power budget for BS 1 corresponding to the example of FIG. 1002. In FIG. 1006, the height of arrow 1010 indicates the BS 1 downlink power budget for a predetermined condition where the loading factor of base station 2 is less than the loading factor of base station 1. The downlink power budget 1010 is divided into a first portion 1012 associated with the downlink pilot channel, a second portion associated with the downlink traffic channels 1016, and a third portion associated with the other downlink channels 1014. Can be.

FIG. 1000 includes an example diagram 1004 that includes base station 1 1050 and base station 2 1052 connected together via a network link 1068. Base station 1 1050 is coupled to multiple wireless terminals WT 1 1054, WT 2 1056, WT 3 1058, and WT 4 1060 via wireless links. Base station 2 1052 has multiple wireless terminals (WT 1 '1062, WT 4' 1064, WT 5 '1076, WT 2' 1078, WT 6 '1080) over wireless links. , WT 3 '1082, WT 7' 1084). BS 1 1050 calculates a loading factor 1086 corresponding to the current downlink traffic channel loading. BS 2 1052 calculates a loading factor 1088 corresponding to the current downlink traffic channel loading. BS 2 sends a message 1090 over the backhaul network link 1068 conveying its loading factor 1088. BS 1 1050 receives the loading factor message 1090, restores the loading factor corresponding to BS 2 1052, and compares the loading factor 1088 with its loading factor 1086. BS 1 determines if the loading factor 1088 for BS 2 is greater than its loading factor 1086 and sets its downlink transmit power budget to a second level 1018, where the second level is a first level. Less than 1010. Diagram 1008 of FIG. 1000 illustrates the downlink power budget for BS 1 corresponding to the example of FIG. 1004. In FIG. 1008, the height of arrow 1018 indicates BS 1 downlink power budget for a predetermined condition where the loading factor of base station 2 is less than the loading factor of base station 1. The downlink power budget 1018 is divided into a first portion 1020 associated with the downlink pilot channel, a second portion associated with the downlink traffic channels 1026, and a third portion associated with the other downlink channels 1024. Can be. In this example, the power levels associated with the pilot channels 1012, 1020 are the same regardless of the loading factor comparison decision, but the downlink traffic channel power budgets 1016, 1026 are in response to different results from the loading factor comparison. Change.

8 illustrates various embodiments in which a base station in a wireless communication system including multiple base stations receives loading factor information corresponding to another base station and determines a downlink transmission power budget as a function of the received base station loading factor information. A diagram 1100 is used to describe the features. The diagram 1100 includes an example diagram 1002 that includes base station 1 1150 and base station 2 1152 connected together via a network link 1170. Base station 1 1150 is coupled to multiple wireless terminals WT 1 1154, WT 2 1156, WT 3 1158, and WT 4 1160 via wireless links. Base station 2 1152 is coupled to multiple wireless terminals (WT 1 '1162, WT 2' 1164, WT 3 '1166, WT 4' 1168) via wireless links. BS 1 1150 calculates a loading factor 1172 corresponding to the current downlink traffic channel loading. BS 2 1152 has calculated a loading factor 1174 corresponding to its current downlink traffic channel loading. BS 2 sends a message 1176 over backhaul network link 1170 conveying its loading factor (LF _BS2 (t1)) 1174. BS 1 1150 receives the loading factor message 1176, restores the loading factor 1174 corresponding to BS 2, and compares the loading factor 1174 with its own factor 1172. In the above example, BS 1 determines that the loading factor 1174 for BS 2 is the same as its loading factor 1172 and assumes that both base stations are stable at these levels, for purposes of explanation. Base station 1 does not readjust the power budget set at level 1114. Diagram 1108 of FIG. 1100 illustrates the downlink power budget for BS 1 corresponding to the example of FIG. 1102. In FIG. 1108, the height of arrow 1114 indicates the base station 1 downlink power budget. The downlink power budget 1114 is divided into a first portion 1116 associated with the downlink pilot channel, a second portion 1120 associated with the downlink traffic channels, and a third portion 1118 associated with the other downlink channels. Can be.

FIG. 1100 includes an example diagram 1104 that includes base station 1 1150 and base station 2 1152 connected together via a network link 1170. Base station 1 1150 is coupled to multiple wireless terminals WT 1 1154, WT 2 1156, WT 3 1158, and WT 4 1160 via wireless links. Base station 2 1152 is coupled to a plurality of wireless terminals WT 1 '1162, WT 2' 1164, WT 3 '1166, WT 4' 1168 via wireless links at this point. . BS 1 1150 calculates a loading factor 1172 corresponding to the current downlink traffic channel loading. BS 2 1152 calculates a loading factor (LF _BS2 (t2)) 1184 corresponding to the current downlink traffic channel loading. BS 2 sends a message 1186 over the backhaul network link 1170 that conveys its loading factor 1184. BS 1 1150 receives the loading factor message 1176, restores the loading factor 1174 corresponding to BS 2, and compares the loading factor 1174 with its own factor 1172. BS 1 determines that the loading factor 1184 for BS 2 is greater than the previous loading factor 1174 for BS 2, thus reducing its downlink transmit power budget to level 1122. Diagram 1110 of FIG. 1100 illustrates the downlink power budget for BS 1 corresponding to the example of FIG. 1104. In FIG. 1110, the height of arrow 1122 indicates that BS 1 adjusted the downlink power budget for the determined condition that base station 2's current loading factor is greater than base station 2's previous loading factor. The downlink power budget 1122 is divided into a first portion 1124 associated with the downlink pilot channel, a second portion 1128 associated with the downlink traffic channels, and a third portion 1126 associated with the other downlink channels. Can be. In the above example, the power level associated with the pilot channels 1116, 1124 is the same regardless of the loading factor comparison decision, but the downlink traffic channel power budget 1120, 1128 responds to different results from the loading factor comparison tracking. Change should be observed.

FIG. 1100 includes an example diagram 1106 that includes base station 1 1150 and base station 2 1152 connected together via a network link 1170. Base station 1 1150 is coupled to multiple wireless terminals WT 1 1154, WT 2 1156, WT 3 1158, and WT 4 1160 via wireless links. Base station 2 1152 is coupled to a number of wireless terminals (WT 1 '1162, WT 4' 1164) via wireless links at this point. BS 1 1150 calculates a loading factor 1172 corresponding to the current downlink traffic channel loading. BS 2 1152 calculates a loading factor (LF _BS2 (t3)) 1188 corresponding to the current downlink traffic channel loading. BS 2 sends a message 1190 over the backhaul network link 1170 conveying its loading factor 1188. BS 1 1150 receives the loading factor message 1190, restores the loading factor 1188 corresponding to BS 2, and loads factor 1888 to the previously stored loading factor LF _BS2 (t2) corresponding to BS2. )) (1184). BS 1 determines that the current loading factor 1188 for BS 2 is less than the previous loading factor 1184 for BS2, thus increasing the downlink transmit power budget to level 1130. Diagram 1112 of FIG. 1100 illustrates the downlink power budget for BS 1 corresponding to the example of FIG. 1106. In FIG. 1112, the height of arrow 1130 indicates that BS 1 adjusted the downlink power budget for the determined condition that the current loading factor of base station 2 is less than the previous loading factor of base station 2. The downlink power budget 1130 is divided into a first portion 1132 associated with the downlink pilot channel, a second portion 1136 associated with the downlink traffic channels, and a third portion 1134 associated with the other downlink channels. Can be. In this example, the power levels associated with the pilot channels 1124, 1132 are the same regardless of the loading factor comparison decision, but the downlink traffic channel power budgets 1128, 1136 respond to different results from the loading factor comparison tracking. Change should be observed.

9 illustrates various embodiments in which a base station in a wireless communication system including multiple base stations receives loading factor information corresponding to another base station and determines a downlink transmission power budget as a function of the received base station loading factor information. A diagram 1200 is used to describe the features. The diagram 1200 includes an example diagram 1202 that includes base station 1 1250 and base station 2 1252 connected together via a network link 1270. Base station 1 1250 is coupled to multiple wireless terminals WT 1 1254, WT 2 1256, WT 3 1258, and WT 4 1260 via wireless links. Base station 2 1252 is coupled to a number of wireless terminals (WT 1 '1262, WT 2' 1264, WT 3 '1266, WT 4' 1268) via wireless links. BS 1 1250 calculates a loading factor (LF _BS1 (t1)) 1272 corresponding to the current downlink traffic channel loading. BS 2 1252 calculates a loading factor 1274 corresponding to the current downlink traffic channel loading. BS 2 sends a message 1276 over backhaul network link 1270 conveying its loading factor (LF _BS2 ) 1274. BS 1 1250 receives the loading factor message 1276, restores the loading factor 1274 corresponding to BS 2, and compares the loading factor 1274 with its own factor 1272. In the above example, BS 1 determines that the loading factor 1274 for BS 2 is equal to its loading factor 1272, and for purposes of explanation, assumes both base stations are stable at these levels, and thus Base station 1 does not readjust the power budget set at level 1214. Diagram 1208 of FIG. 1200 illustrates the downlink power budget for BS 1 corresponding to the example of FIG. 1202. In FIG. 1208, the height of arrow 1214 indicates the base station 1 downlink power budget. The downlink power budget 1214 is divided into a first portion 1216 associated with the downlink pilot channel, a second portion 1220 associated with the downlink traffic channels, and a third portion 1218 associated with the other downlink channels. Can be.

1200 includes an example diagram 1204 including base station 1 1250 and base station 2 1252 connected together via network link 1270. Base station 1 1250 is a number of wireless terminals (WT 1 (1254), WT 2 (1256), WT 3 (1258), WT 4 (1260), WT 5 (1278), WT 6 (1280) over wireless links. ), WT 7 (1282). Base station 2 1252 is coupled to multiple wireless terminals WT 1 '1262, WT 2' 1264, WT 3 '1266, WT 4' 1268 via wireless links at this point. . BS 1 1250 calculates a loading factor (LF _BS1 (t2)) 1284 corresponding to the current downlink traffic channel loading. BS 2 1252 calculates a loading factor (LF _BS2 ) 1274 corresponding to the current downlink traffic channel loading. BS 2 sends a message 1276 over backhaul network link 1270 that conveys its loading factor 1274. BS 1250 receives a loading factor message 1276, restores the loading factor 1274 corresponding to BS 2, and recognizes that the loading factor corresponding to BS 2 remains unchanged. BS 1 1250 compares current loading factor 1284 with a previously stored loading factor corresponding to BS 1 loading factor (LF _BS1 (t2)) 1272. BS 1 determines that the loading factor 1284 for BS 1 is greater than the previous loading factor 1272 for BS1, thus increasing its downlink transmit power budget to level 1222. Diagram 1210 of FIG. 1200 illustrates the downlink power budget for BS 1 corresponding to the example of FIG. 1204. In FIG. 1210, the height of arrow 1222 indicates that BS 1 adjusted the downlink power budget for the determined condition that the current loading factor of base station 1 is greater than the previous loading factor of base station 2. The downlink power budget 1222 is divided into a first portion 1224 associated with the downlink pilot channel, a second portion 1228 associated with the downlink traffic channels, and a third portion 1226 associated with the other downlink channels. Can be. In this example, the power levels associated with the pilot channels 1216 and 1224 are the same regardless of the loading factor comparison decision, but the downlink traffic channel power budgets 1220 and 1228 are in response to different results from the loading factor comparison. Change should be observed.

1200 includes an example diagram 1206 including base station 1 1250 and base station 2 1252 connected together via a network link 1270. Base station 1 1250 is coupled to multiple wireless terminals WT 3 1258 and WT 4 1260 via wireless links. Base station 2 1252 is coupled to multiple wireless terminals WT 1 '1262, WT 2' 1264, WT 3 '1266, WT 4' 1268 via wireless links at this point. . BS 1 1250 calculates a loading factor (LF _BS1 (t3)) 1286 corresponding to the current downlink traffic channel loading. BS 2 1252 calculates a loading factor (LF _BS2 ) 1274 corresponding to the current downlink traffic channel loading. BS 2 sends a message 1276 over backhaul network link 1270 that conveys its loading factor 1274. BS 1250 receives the loading factor message 1276, restores the loading factor 1274 corresponding to BS 2, and recognizes that the loading factor corresponding to BS2 remains unchanged. BS 1 compares its current loading factor 1286 with the loading factor 1284 previously stored corresponding to BS 1 (LF _BS1 (t2)). BS 1 determines that the current loading factor 1286 for BS 1 is less than the previous loading factor 1284 for BS 1, thus reducing its downlink transmit power budget to level 1230. Diagram 1212 of FIG. 1200 illustrates the downlink power budget for BS 1 corresponding to the example of FIG. 1206. In FIG. 1212, the height of arrow 1230 indicates that BS 1 adjusted the downlink power budget for the determined condition that base station 1's current loading factor is less than base station 1's previous loading factor. The downlink power budget 1230 is divided into a first portion 1232 associated with the downlink pilot channel, a second portion 1236 associated with the downlink traffic channels, and a third portion 1234 associated with the other downlink channels. Can be. In this example, the power levels associated with pilot channels 1224 and 1232 are the same regardless of the loading factor comparison decision, but the downlink traffic channel power budgets 1228 and 1236 respond to different results from the loading factor comparison tracking. Change should be observed.

10, which includes a combination of FIGS. 10A and 10B, is a flowchart 2000 of an exemplary method of operating a base station in accordance with various embodiments. An exemplary base station, such as base station 200 of FIG. 2, may be a base station in a multiple access wireless communication system including multiple base stations, each base station including at least one base station attachment point. Operation begins in step 2002 where the base station is powered on and started. Operation proceeds from start step 2002 to step 2034 through step 2004, step 2010, step 2020 and connecting node A 2032.

In step 2004, performed on a recursive basis, the base station determines the downlink loading for each base station attachment point. The outputs of step 2004 are base station 1 downlink loading factor 2006, ..., base station 1 attach point n downlink loading factor 2008. Information 2006,..., 2008 is input to steps 2020 and 2034.

In step 2010, the base station receives downlink loading factor information corresponding to attachment points of another base station, such as an adjacent base station. Reception may be performed via a wireless receiver having an interface to the backhaul network and / or a wireless terminal simultaneously connected to another base station, for example acting as a base station and a repeater. Receiving may be performed in response to a request and / or command to communicate its downlink loading information by another base station on a circular basis. The information corresponding to the various attachment points of one of the plurality of base stations is determined by the output of step 2010 (base station 2 attachment point 1 downlink loading factor 2012, ..., base station 2 attachment point m downlink loading factor) 2014), ..., base station N attach point 1 downlink loading factor 2016, ..., base station N attach point p downlink loading factor 2018). Information 2012, 2014, 2016, 2018 are inputs to step 2020.

Step 2020 is performed on an ongoing basis for each attachment point of the base station. In step 2020, the base station determines the downlink transmit power budget as a function of loading factor information corresponding to other base stations or base stations, such as neighboring base stations or base stations. In some embodiments, the determined downlink transmit power budget is a power budget for a set of downlink communication channels including at least a pilot channel and a data channel, wherein the pilot channel transmit power level, e.g., pilot channel power per tone, is determined by loading information. The portion of the determined downlink power budget that is independent while corresponding to the traffic channel is determined by the loading information of the corresponding base station attachment point and the loading information of the adjacent point or points of adjacent base stations or base stations. Step 2020 includes sub-steps 2022, 2024, 2026, 2028. In sub-step 2022, the base station compares the current loading at the base station attachment point under consideration with the loading of the attachment point or points of adjacent base stations or base stations that may interfere with the attachment point under consideration. In sub-step 2024, the base station compares the current loading at the base station attachment point under consideration to the previous loading at the base station attachment point under consideration. At sub-step 2026, the base station compares the current loading at the potentially interfering neighboring base station attachment point with the previous loading at the same potentially interfering neighboring base station attachment point. Sub-step 2026 may be performed for a number of different potentially interfering adjacent base station attachment points.

Operation proceeds from sub-steps 2022, 2024, 2026 to sub-step 2028. In sub-step 2028, the base station changes the base station attachment point loading over time, the changes in the neighbor base station attachment point over time, the loading at the base station attachment point under consideration and the attachment point or point of the neighbor base stations. As a result of the comparison in loading, the base station attach point downlink transmit power budget is adjusted as a function of the current downlink transmit power budget, the previous downlink transmit power budget, and optionally the possible downlink transmit power budget. Sub-step 2028 includes sub-step 2030. At sub-step 2030, the base station adjusts the base station attach point downlink traffic channel power budget.

In some embodiments, determining the power budget for a base station attachment point recalls the power budget when the comparison indicates that the loading of the attachment point of another base station, such as a neighboring base station, is greater than the loading of the base station attachment point to which the budget applies. Determine a power value corresponding to the first value indicating the budget, and when the comparison indicates that the loading of the attachment point of another base station, such as a neighboring base station, is less than the loading of the base station attachment point to which the budget applies, Determining to correspond to a second value indicative of a power budget that is greater than the power budget indicated by.

In various embodiments, determining the power budget for the base station attachment point includes reducing the current power budget in response to detecting an increase in loading at the attachment point of another base station, such as a neighbor base station. In some embodiments, determining the power budget for the base station attachment point includes increasing the current power budget in response to detecting a decrease in loading at the attachment point of another base station, such as a neighbor base station.

In various embodiments, determining the power budget for the base station attachment point includes increasing the current power budget in response to detecting an increase in loading at the attachment point. In some embodiments, determining the power budget for the base station attachment point includes reducing the current power budget in response to detecting a decrease in loading at the attachment point.

In some embodiments, the base station supports a plurality of predetermined downlink transmit power budget alternative levels for the attachment point, eg, 2, 3, or 4 or more, and the base station provides a possible selection level for a given time for the attachment point. Choose to use one of these. Thus, the base station can dynamically change power budgets between possible alternatives in response to loading changes, including loading changes at neighboring base stations. In some embodiments, base stations may communicate information to other base stations, such as neighbor base stations, that identify their selected downlink transmit power budget level.

In step 2034, the base station generates a message conveying the base station attachment point downlink loading information. The base station attach point loading information (BS 1 attach point 1 downlink loading factor 2006, ..., base station 1 attach point n downlink loading factor 2008) are inputs to step 2034. Operation proceeds from step 2034 to step 2036. In step 2036, the base station transmits the message generated in step 2034, which includes the determined base station attachment point loading factor directed to another, eg, adjacent, base station or base stations. Transmission to the neighbor base station may be performed through an interface to the backhaul network and / or a wireless terminal coupled to both the base station and the neighbor base station. The operations of steps 2034 and 2036 proceed on a response to a request from a neighbor base station, for example as part of a cyclical timing structure and / or where the base station communicates its loading information to one or more neighbor base stations. It is performed based on the decision. In some embodiments, the downlink loading factor of one of the base station attachment points is one in response to the base station determining that loading reaches a high level and / or in response to a detected change in a predetermined amount of loading. Or to more selected neighbor base stations.

Although the method and apparatus of various embodiments have been described in the context of an OFDM system, it is applicable to a wide variety of communication systems including a number of non-OFDM and / or non-cellular systems.

In various embodiments the nodes disclosed herein are one or more for performing steps corresponding to one or more methods, such as, for example, signal processing, beacon generation, beacon detection, beacon measurement, connection comparison, connection executions, or the like. It is implemented using more modules. In some embodiments various features are implemented using modules. The modules may be implemented using software, hardware or a combination of software and hardware. Many of the methods or method steps described above are for example used to execute all or part of the methods described above on one or more nodes, for example to control a machine such as a general purpose computer with or without additional hardware. Can be implemented using machine executable instructions, such as software, contained within a machine readable medium, such as a memory device such as RAM, floppy disk, and the like. Thus, among other things, various embodiments may be embodied in a machine-readable medium comprising machine-executable instructions for causing a machine, such as a processor and associated hardware, to perform one or more of the steps of the method (s) described above. It is about.

Various further variations in the methods and apparatus described above will be apparent to those skilled in the art in connection with the foregoing description. Such modifications should be considered within the scope. The method and apparatus of various embodiments can be or can be CDMA, orthogonal frequency division multiplexing (OFDM) and / or various other types of communication technologies that can be used to provide wireless communication links between access nodes and mobile nodes. Can be used. In some embodiments, access nodes are implemented with base stations that establish communication links with mobile nodes using OFDM and / or CDMA. In various embodiments mobile nodes are implemented in notebook computers, personal digital assistants (PDAs) or other portable devices that include receiver / transmitter circuits and logic and / or routines to implement the methods of the various embodiments. do.

Claims (35)

A method of operating a first base station in a multiple access wireless communication system comprising a plurality of base stations, each of the plurality of base stations including at least one base station attachment point. Receiving second base station loading factor information indicating loading of a second base station attachment point corresponding to the second base station; And Determining a downlink transmission power budget as a function of the received second base station loading factor information; Determining the downlink transmission power budget, Reducing a current power budget in response to detecting an increase in loading at the second base station, and Increasing a current power budget in response to detecting a decrease in loading at the second base station; A method of operating a first base station in a multiple access wireless communication system. The method of claim 1, Determining the downlink transmit power budget is further performed as a function of additional loading factor information corresponding to another base station attachment point that does not correspond to the second base station. A method of operating a first base station. 3. The method of claim 2, The another base station attachment point corresponds to the first base station, Determining the downlink transmit power budget comprises comparing the additional loading factor information with the second base station loading factor information. 3. The method of claim 2, The determined downlink transmit power budget is a power budget for a set of downlink communication channels including at least a pilot channel and a data traffic channel, A portion of the determined downlink transmit power budget for the pilot channel is independent of the additional loading factor information and the second base station loading factor information; And wherein a portion of the determined downlink transmit power budget corresponding to the data traffic channel is dependent on the second base station loading factor information and the additional loading factor information. 4. The method of claim 3, wherein determining the downlink transmit power budget comprises: Determining that the downlink transmit power budget corresponds to a first value indicating the downlink transmit power budget when the comparing step indicates that the second base station loading is greater than the first base station loading; And A second indicating the power budget greater than the downlink transmit power budget indicated by the first value when the comparing step indicates that the second base station loading is less than the first base station loading. And determining that the value corresponds to a value. delete delete The method of claim 2, wherein determining the power budget comprises: Increasing a current power budget in response to detecting an increase in loading at the first base station. The method of claim 2, wherein determining the power budget comprises: Reducing a current power budget in response to detecting a decrease in loading at the first base station. As a base station, Means for receiving other base station loading factor information indicating loading of a base station attachment point corresponding to the other base station; And Means for determining a downlink transmit power budget, Means for determining the downlink transmit power budget determines the downlink transmit power budget as a function of the received other base station loading factor information; Means for determining the downlink transmit power budget, Increase the current power budget in response to detecting a decrease in loading at the other base station, and Increasing the current power budget in response to detecting an increase in loading at the base station. The method of claim 10, Means for determining the downlink transmit power budget determines the downlink transmit power budget as a function of additional loading factor information corresponding to an additional base station attachment point. The method of claim 11, The additional base station attachment point corresponds to the base station, Means for determining the downlink transmit power budget comprises means for comparing the additional loading factor information with the other base station loading factor information. The method of claim 11, The determined downlink transmit power budget is a power budget for a set of downlink communication channels including at least a pilot channel and a data traffic channel, A portion of the determined downlink transmit power budget for the pilot channel is independent of the other base station loading factor information and the additional loading factor information; A portion of the determined downlink transmit power budget corresponding to the data traffic channel depends on the other base station loading factor information and the additional loading factor information. The method of claim 12, The means for determining the downlink transmit power budget corresponds to a first value indicating that the downlink transmit power budget indicates the downlink transmit power budget when the comparison indicates that the other base station loading is greater than the base station loading. Determined to be; And when the comparison indicates that the other base station loading is less than the base station loading, the downlink transmit power budget corresponds to a second value indicating a power budget that is greater than the downlink transmit power budget indicated by the first value. Base station. The method of claim 11, Means for determining the downlink transmit power budget reduces a current power budget in response to detecting an increase in loading at the other base station. delete The method of claim 11, Means for determining the downlink transmit power budget comprises means for tracking loading changes at the base station. The method of claim 11, The means for determining the downlink transmit power budget includes means for tracking loading changes at the base station, and the means for determining the downlink transmit power budget are responsive to detecting a decrease in loading at the base station. Thereby reducing the current power budget. As a base station, An interface for receiving signals carrying other base station loading factor information indicative of the loading of at least one base station attachment point corresponding to the at least one other base station; A loading factor information recovery module for recovering other base station loading factor information corresponding to at least one other base station from the received signals; And A downlink transmit power budget determination module, The downlink transmit power budget determination module determines a downlink transmit power budget for the attachment point of the base station as a function of the recovered loading factor information corresponding to at least one other base station, The downlink transmit power budget determination module reduces the current power budget in response to detecting an increase in loading at one of the other base stations, and reduces the current power budget in response to detecting a decrease in loading at one of the other base stations. To increase the base station. The method of claim 19, A loading factor determination module for determining a loading factor corresponding to the attachment point of the base station; And a loading factor comparison module for comparing the determined loading factor corresponding to the attachment point of the base station with a restored loading factor corresponding to the attachment point of the at least one other base station, The downlink transmit power budget determination module uses the results of the loading factor comparison module when determining the downlink power budget. The method of claim 19, The determined power budget is a power budget for a set of downlink communication channels including at least a pilot channel and a data traffic channel, A portion of the determined power budget for the pilot channel is independent of the other base station loading factor information and additional loading factor information, A portion of the power budget corresponding to the data traffic channel depends on the other base station loading factor information and the additional loading factor information. The method of claim 21, The downlink transmit power budget determination module determines that the downlink transmit power budget corresponds to a first value indicating the downlink transmit budget when the loading factor comparison module determines that the other base station loading is greater than the base station loading. and; And a second value indicating a power budget greater than the downlink transmit power budget indicated by the first value when the loading factor comparison module indicates that the other base station loading is less than the base station loading. Determining to correspond to a base station. The method of claim 21, And a loading factor tracking module for tracking changes in loading factors at base station attachment points. delete The method of claim 21, Further comprising a loading factor tracking module for tracking changes in loading factors at base station attachment points, The downlink transmit power budget determination module increases the current power budget in response to detecting an increase in loading at the attachment point of the base station. The method of claim 21, Further comprising a loading factor tracking module for tracking changes in loading factors at base station attachment points, The downlink transmit power budget determination module reduces a current power budget in response to detecting a decrease in loading at the attachment point of the base station. A computer readable medium comprising machine executable instructions for controlling a first base station in a multiple access wireless communication system comprising a plurality of base stations for executing the method. Receiving second base station loading factor information indicating loading of a second base station attachment point corresponding to the second base station; And Determining a downlink transmission power budget as a function of the received second base station loading factor information; Determining the downlink transmission power budget, Reducing a current power budget in response to detecting an increase in loading at the second base station, and Increasing a current power budget in response to detecting a decrease in loading at the second base station; Computer readable media. 28. The method of claim 27, And machine executable instructions for determining the downlink transmit power budget as a function of additional loading factor information corresponding to another base station attachment point that does not correspond to the second base station. The method of claim 28, And said another base station attachment point corresponds to said first base station. The method of claim 29, And machine executable instructions for comparing additional loading factor information with the second base station loading factor information as part of determining the downlink transmission power budget. 31. The method of claim 30, The determined downlink transmit power budget is a power budget for a set of downlink communication channels including at least a pilot channel and a data traffic channel, A portion of the determined downlink transmit power budget for the pilot channel is independent of the additional loading factor information and the second base station loading factor information; The portion of the determined downlink transmit power budget corresponding to the data traffic channel is dependent on the second base station loading factor information and the additional loading factor information. A base station operable in a communication system, Receive second base station loading factor information indicating loading of a second base station attachment point corresponding to the second base station; And A processor configured to determine a downlink transmit power budget as a function of the received second base station loading factor information; Determining the downlink transmission power budget, Reduce the current power budget in response to detecting an increase in loading at the second base station, and Increasing a current power budget in response to detecting a decrease in loading at the second base station; Base station. 33. The system of claim 32, wherein the processor is And determine the downlink transmit power budget as a function of additional loading factor information corresponding to another base station attachment point that does not correspond to the second base station. The method of claim 33, The another base station attachment point corresponds to the first base station, And the processor is further configured to determine the downlink transmit power budget by operations comprising comparing additional loading factor information with the second base station loading factor information. The method of claim 34, The determined downlink transmit power budget is a power budget for a set of downlink communication channels including at least a pilot channel and a data traffic channel, A portion of the determined downlink transmit power budget for the pilot channel is independent of the additional loading factor information and the second base station loading factor information; A portion of the determined downlink transmit power budget corresponding to the data traffic channel is dependent on the second base station loading factor information and the additional loading factor information.

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