FIXED NULL-STEERING BEAMFORMING METHOD

Abstract

The invention relates to a frequency reuse method in a base station of a Frequency Division Multiplexing Access wireless communication system, the wireless communication system comprising at least the base station adapted for covering a cell, at least one wireless terminal coupled to the base station, the method comprising the steps of: calculating a maximum number of beams per cell by obtaining a number of antennas of the base station; initiating a fixed null-steering beamforming by setting a number of orthogonal fixed beams to a first constant on a portion of the cell, if a traffic of the base station is bigger than a first threshold; obtaining an absolute or an approximate location of the wireless terminal within the cell; scheduling the wireless terminal to fixed null-steering resources, if the absolute or approximate location of the wireless terminal is within the beam zone of the cell; setting the number of orthogonal fixed beams to a second constant of the fixed null-steering beamforming, if the traffic is bigger than a second threshold.

Description

BACKGROUND OF THE INVENTION

The invention is based on a priority application EP08290276.8 which is hereby incorporated by reference.

The invention relates to a method of fixed null-steering beamforming in a base station and to a computer program product.

In wireless communication systems, the frequencies resources allocated to the service may be re-used in a regular pattern of areas, called cells, each covered by one base station. In mobile wireless communication systems these cells are usually hexagonal. To ensure that the mutual interference between wireless terminals remains low, adjacent cells use different frequencies. In fact, a set of N different frequencies are used for each cluster of N adjacent cells. Cluster patterns and the corresponding frequencies are re-used in a regular pattern over the entire service area.

The closest distance between the centres of two cells using the same frequency in different clusters is determined by the cluster size N and the layout of the cell cluster. This distance is called the frequency re-use distance.

The signal processing technique of beamforming may be used with arrays of transmitting or receiving transducers that control the directionality of a radiation pattern. When receiving a signal, beamforming can increase the receiver sensitivity in the direction of wanted signals and decrease the sensitivity in the direction of interference and noise. When transmitting a signal, beamforming can increase the power in the direction the signal is to be sent. The change compared with an omnidirectional transmission is known as the transmission gain. These changes are done by creating beams and nulls in the radiation pattern.

Therefore, there is a need of a new frequency reuse method in a base station, of a base station and of a computer program product.

SUMMARY OF THE INVENTION

The invention provides to a frequency reuse method in a base station of a Frequency Division Multiplexing Access wireless communication system, the wireless communication system comprising at least the base station adapted for covering a cell, at least one wireless terminal coupled to the base station, the wireless communication system dividing a frequency band into three frequency sub-bands, wherein one of the frequency sub-band is assigned to the base station, the method comprising the steps of:

• • calculating a maximum number of beams per cell by obtaining a number of antennas of the base station;
  • initiating a fixed null-steering beamforming by setting a number of orthogonal fixed beams to a first constant on a portion of the cell, if a traffic of the base station is bigger than a first threshold;
  • obtaining an absolute or an approximate location of the wireless terminal within the cell;
  • scheduling the wireless terminal to fixed null-steering resources, if the absolute or approximate location of the wireless terminal is within the beam zone of the cell;
  • setting the number of orthogonal fixed beams to a second constant of the fixed null-steering beamforming, if the traffic is bigger than a second threshold,
  • wherein the first constant is smaller than the second constant and the second constant is smaller or equal to the maximum number of beams.

The Frequency Division Multiplexing Access wireless communication system can be a GSM system, or an OFDMA system such as WiMAX or LTE. If the fixed null-steering beamforming is initiated, the wireless terminals can be scheduled either to fixed null-steering resources or to reuse-3 resources. If the reuse-3 system is activated, then the wireless terminals can be scheduled only to reuse-3 resources. In the reuse-3 system, the sub-band assigned to the cell is shared by all users. In the fixed null-steering beamforming, a portion of the sub-band may be assigned exclusively to the wireless terminals located within the beam part of the cell, and the other portion of the sub-band is assigned for the reuse-3 resources.

One of the advantages of the embodiments is that the throughput of the system improves the classic reuse-3 system, without using the typically complicated interference suppression or cancellation algorithm of the reuse 1. Inside the cell, the wireless terminals are scheduled to occupy the resources according to the location information. The wireless terminals within the fixed null-steering beam zones may share the same spectral temporal resources between all the wireless terminals. The complicated interference suppression on cancellation algorithm is avoided by using the predefined fixed null-steering beamforming weights. The new method and the new base station become an alternative that nearly obtains the throughput of the reuse 1 system with the advantages of a low co-channel interference of reuse 3 systems.

In one of the embodiments, the wireless terminal comprises a positioning system (GPS, Galileo), the wireless terminal obtains the absolute location, and otherwise the base station obtains the approximate location by calculating a Direction of Arrival of an uplink signal from the wireless terminal and an uplink feedback CINR. The advantage is that if the wireless terminal is not able to obtain its location, the base station can calculate an approximated location.

In an embodiment, the first threshold describes an upper bound of a traffic of a reuse-3 system of the wireless communication system, wherein the second threshold describes an upper bound of a traffic of a fixed null-steering beamforming with a first constant number of beams. The second threshold determines the switch between the fixed null-steering beamforming with a first constant of fixed beams to a second constant.

In an embodiment, the method further comprises the steps of: switching to said reuse-3 system and scheduling the wireless terminal to reuse-3 resources, if the absolute or approximate location of the wireless terminal is outside the beam zone. The advantage of the embodiments is that the switching between the fixed null-steering beamforming and the reuse-3 system can be done according to the conditions of the traffic of the base station, and if the fixed null-steering beamforming is used, the scheduling is done according the location of the wireless terminals.

In a further embodiment, the method further comprises the steps of: switching to the reuse-3 resources for all wireless terminals located within the cell, if the traffic is smaller than the first threshold. The switching between the fixed null-steering beamforming and the reuse-3

In another aspect, the invention relates to a base station in an FDMA digital cellular mobile communication system being operable to perform in accordance with any one of the preceding claims.

In another aspect, the invention relates to a computer program product stored on a computer usable medium, comprising computer readable program means for causing a computer to perform a method according to any of the preceding claims 1 to 5 when the program is run on the computer.

BRIEF DESCRIPTION OF THE DRAWINGS

In the following preferred embodiments of the invention will be described in greater detail by way of example only making reference to the drawings in which:

FIG. 1 shows an embodiment of a method of fixed null-steering beamforming,

FIG. 2 shows a second embodiment of fixed null-steering beamforming,

FIG. 3 shows an example of a fixed M-null-steering beam pattern under three cells,

FIG. 4 shows an embodiment of a base station and wireless terminal,

FIG. 5 shows an embodiment of resource assignment in a cell of fixed null-steering beamforming.

DETAILED DESCRIPTION

FIG. 1 shows a method 100 of fixed null-steering beamforming in a base station, comprising a first step 101 where the maximum number M_max of beams in a cell is calculated. This calculation depends mainly on the number of antennas that the base station uses to transmit to the wireless terminals within the cell and to the sector angular coverage within the cell. The maximum number M_max of beams denotes an upper bound of the possible beams that may be allocated within a cell. On a second step 102, the traffic of the base station is measured and compared with a first threshold E1. The traffic represents all the communications between the base station and all the wireless terminals within the cell covered by the base station. If the traffic is smaller than the first threshold E1, the standard reuse-3 system is used and no fixed orthogonal beams will be formed within the cell. Otherwise, if the traffic is bigger than the first threshold, in a third step 103 a first two beams are set within the cell, so that a fixed null-steering zone covered by both beams is formed within the cell.

After this third step 103, the location of the wireless terminal A is obtained. The fourth step 104 obtains the absolute location information for that wireless terminal A if the wireless terminal is equipped with a Global Positioning System as a GPS or Galileo. If that is not the case and the wireless terminal does not include any means to obtain the absolute location information, a fifth step 105 within the base station calculates an approximate location of the wireless terminal A within the cell. This location is obtained by calculating the direction of arrival information from the uplink received signals from the wireless terminal and with the uplink feedback CINR measurements. After any of these two ways of obtaining the location is completed, either by obtaining the absolute location information on the forth step 104 or by obtaining the approximate location of the fifth step 105, the result is used on the sixth step 106, where it is defined if the location of the wireless terminal A is within the fixed null-steering zone.

If the wireless terminal A is outside the fixed null-steering zone, the wireless terminal is scheduled to use the standard reuse-3 radio resource system within the reuse 3 radio resource zone. If the wireless terminal is within the zone, then the terminal is scheduled to use the corresponding resources of the fixed null-steering radio. The steps from 104-108 are repeated for all the wireless terminals located within the cell covered by the base station.

The maximum number of M_max orthogonal spatial beams may be calculated as:

$\begin{array}{cc}M\le M_{\max }=\lfloor \frac{\Omega \left(N-1\right)}{\frac{\pi }{2}}\rfloor & \left(1\right)\end{array}$

where Ω denotes the sector angular coverage, N denotes the number of antenna at base station. As an example if

$\Omega =\frac{2}{3}\pi ,$

and base station equips 4 antennas, thus, the

$M\le M_{\max }=\lfloor \frac{\frac{2\pi }{3}\left(4-1\right)}{\frac{\pi }{2}}\rfloor =4.$

Consequently, the number of beams: M=4 and M=2 may be taken into consideration in the configuration of the fixed null-steering resources.

The spatial separation of the beams θ has to satisfy the relation,

$\begin{array}{cc}\theta \ge \frac{\Omega }{M_{\max }}.& \left(2\right)\end{array}$

In the example the result is

$\theta \ge \frac{\pi }{6}.$

FIG. 2 shows an embodiment of the fixed null-steering beamforming method 200 that may be applied after the eighth step 108 described in FIG. 1. In a first step 201, the traffic of the base station is compared to a second threshold E2, which is typically bigger than the first threshold E1. If the traffic within the cell that communicates with the base station is bigger than the threshold E2, the number of fixed beams is increased in a second step 202 and set to, e.g. M=4. The M=4 indicates using four beams within the area covered by the base station. Otherwise, if the traffic is smaller than the second threshold, on a third step 203 the current traffic is compared to the first threshold E1. If the amount of traffic is smaller than the first threshold E1, in a forth step 204 the normal reuse 3 system is applied for the whole cell and for all the wireless terminals that communicate with the base station. Otherwise, if the traffic is bigger than the first threshold, on a fifth step 205 the steps 104-108 described on FIG. 1 are repeated, where the location information for the wireless terminals within the cell is obtained and the scheduling is decided as whether using the fixed null-steering resources or the standard reuse 3 radio resources.

FIG. 3 shows two groups of cells 301 and 302 using the fixed null-steering beamforming method. The first group of cells 301 further comprises the first cell 303 and a second 304 and third cell 305, each including two beams per cell. The second group of cells 302 further comprises a first cell 306 and the second 307 and third 308. Each one of the second group of cells includes four beams corresponding to the fixed null-steering method with M=4. The first group of cells 301 with the two beams per cell corresponds to the configuration obtained when the traffic of the cell is bigger than a first threshold. All wireless terminals within the beams zones 309 and 310 are scheduled to use the resources of the fixed null-steering. The beam zone corresponds to an angle aperture of the cell, as represented by the zones 309 and 310.

The second group of cells 302 corresponds to the configuration obtained when the traffic of the cell is bigger than a second threshold E2. This can occur after a switch from an initial configuration of two beams, as represented in the group of cells 301. The switch of the configurations between the two beams or the four beams occurs adaptively during the operation and maintenance of the network and during the scheduling of all the wireless terminals within the cells covered by the base stations. In general, the coverage of the cell area is bigger for the two beams than the four beams, and the effective reuse factor is then smaller for the two beams than the four beams.

In wireless communication systems with frequency division multiple access, a frequency planning is necessary in order to use the complete spectrum of available frequency resources and avoid a high co-channel interference level. In a frequency reuse layout of three sub-bands, each sub-band is allocated in an adjacent cell, the three adjacent cell forming a so-called cluster. The reuse factor is denoted by one third (⅓). In general, by using a larger cluster size, the co-channel interference is smaller, as the cells using the same frequency band are farther away to each other, but the frequency sub-band is smaller for each individual cell, limiting the traffic into the cell. By displaying a small cluster size of three, the maximal system capacity may be approached, obtaining a balance between the co-channel interference and the cell throughput.

The use of fixed null-steering beamforming schemes enables the complete frequency reuse of the corresponding sub-band in a number M of spatial and geographical regions. For these types of schemes, the reuse factor may become M/3, because the frequency band allocated to the wireless terminals are M times reused. After obtaining the absolute or relative location information of the wireless terminals, the base station is able to decide if the wireless terminal or the wireless terminal is scheduled and allocated using the resources of the fixed null-steering zone or of the normal reuse-3 zone.

The null-steering beamforming is an art of adaptive beamforming for the suppression of interference and is associated with the concept of spatial domain multiple access (SDMA). For the fixed null-steering beamforming, the beamforming weights are not necessary calculated, because the beam patterns are fixed in a database within the base station and the specific number of beams is determined by the traffic of the cell.

FIG. 4 shows a wireless communication system 400 comprising a base station 401 and wireless terminal 402. The base station 401 comprises:

• • means for 403 calculating a maximum number M_max of beams per cell by obtaining a number of antennas of the base station;
  • means for 404 initiating a fixed null-steering beamforming by setting a number of fixed beams to M=2 on a beam zone of the cell, if a traffic of the base station is bigger than a first threshold;
  • means for 405 obtaining an absolute or an approximate location of the wireless terminal within the cell;
  • means for 406 scheduling the wireless terminal to fixed null-steering resource, if the absolute or approximate location of the wireless terminal is within the beam zone of the cell;
  • means for 407 setting the number of fixed beams to M=4 of the fixed null-steering beamforming, if the traffic is bigger than a second threshold.
  • a computer program product 408 stored on a computer usable medium, comprising computer readable program means.

The wireless terminal 402 comprises:

• • means for 409 obtaining the absolute location of the wireless terminal 402
  • means for 410 sending said absolute location of the wireless terminal 402 to the base station 401.

FIG. 5 shows a cell 501 and a frame 502. The cell 501 represents a cell with a fixed null-steering method including a first null-steering zone 503, a second null-steering zone 504, two wireless terminals U1 and U2 within the first null-steering zone 503 and wireless terminals U3 and U4 on the second null-steering zone 504. Further, the cell comprises a first reuse 3 system zone 505 including two wireless terminals V1 and V2 and a second reuse 3 zone 506 including a wireless terminal V3 for wireless terminal.

According to the method of fixed null-steering beamforming, two beams within the cell 501 are created when the traffic of the cell is bigger than a first threshold. Then, the location of all the wireless terminals within the cell, including U1 to U4 and V1 to V3, which according to the wireless terminal characteristics can be absolute location information or approximate location information. Further, it is determined that the wireless terminals U1 and U2 are within the fixed null-steering zone and wireless terminals U3 and U4 are within the second null-steering zone 504. Therefore, these terminals are allocated and scheduled within the fixed null-steering zone 507 of the sub-band 1 of the frame 502. The fixed null-steering zone 507 corresponds to a first sub-zone of the frame 502 and a second sub-zone 508 of the frame 502 is used for the reuse 3 zone, that is for all the wireless terminals outside the fixed null-steering zones.

On a first time domain 509 within the fixed null-steering zone 507, the resource allocation is shared between the wireless terminals U1 and U3 for the whole fixed null-steering zone 507 within a portion of the time frame. On the second sub-frame 510, the wireless terminals U1 and U4 share a partial amount of resources in the frequency domain, and the wireless terminals U2 and U4 share the rest of the frequency resources for the fixed null-steering zone 507. On the reuse-3 zone, the frame 502 shows the resource allocation for the three wireless terminals V1, V2 and V3 located outside the beams, assigned to the second sub-band 508. The sub-zone 508 describes a separated frequency resource allocation for each one of the wireless terminals.

List of Reference Numerals
101 first step
102 second step
103 third step
104 fourth step
105 fifth step
106 sixth step
107 seventh step
108 eighth step
200 second flowchart
201 first step
202 second step
203 third step
301 first group of cells
302 second group of cells
303 first cell
304 second cell
305 third cell
306 first cell
307 second cell
308 third cell
309 first null-steering zone
310 second null-steering zone
400 wireless communication system
401 base station
402 wireless terminal
403 means for calculating
404 means for initiating
405 means for obtaining
406 means for scheduling
407 means for setting
408 CPP
409 means for obtaining
410 means for sending
501 cell
502 frame
503 first null-steering zone
504 second null-steering zone
505 normal reuse 3 zone
506 second reuse 3 zone
507 fixed null-steering zone
508 reuse 3 zone
509 first sub-frame
510 second sub-frame
511 third sub-frame

Claims

1. A frequency reuse method in a base station of a Frequency Division Multiplexing Access wireless communication system, said wireless communication system comprising at least said base station adapted for covering a cell, at least one wireless terminal coupled to said base station, said wireless communication system dividing a frequency band into three frequency sub-bands, wherein one of said frequency sub-band is assigned to said base station, said method comprising the steps of: calculating a maximum number of beams per cell by obtaining a number of antennas of said base station;initiating a fixed null-steering beamforming by setting a number of orthogonal fixed beams to a first constant on a beam zone of said cell, if a traffic of said base station is bigger than a first threshold;obtaining an absolute or an approximate location of said wireless terminal within said cell;scheduling said wireless terminal to fixed null-steering radio resources, if said absolute or approximate location of said wireless terminal is within said beam zone of said cell;setting said number of fixed beams to a second constant of said fixed null-steering beamforming, if said traffic is bigger than a second threshold, wherein said first constant is smaller than said second constant and said second constant is smaller or equal to said maximum number of beams.

2. The method as in claim 1, wherein if said wireless terminal comprises a positioning system, said wireless terminal obtains said absolute location, otherwise said base station obtains said approximate location by calculating a Direction of Arrival of an uplink signal from said wireless terminal and an uplink feedback CINR.

3. The method as in claim 1, wherein said first threshold describes an upper bound of a traffic of a reuse 3-system of said wireless communication system, wherein said second threshold describes an upper bound of a traffic of fixed null-steering beamforming with a first constant of fixed beams.

4. The method as in claim 1, wherein said method further comprises the steps of: scheduling said wireless terminal to a reuse-3 resource, if said absolute or approximate location of said wireless terminal is outside said beam zone.

5. The method as in claim 1, wherein said method further comprises the steps of: switching to said reuse-3 resources for all wireless terminals located within said cell, if said traffic is smaller than said first threshold.

6. The method as in claim 1, wherein said first constant is an M=2 and said second constant is an M=4.

7. The method as in claim 1, wherein said base station generates a frame for at least said wireless terminal, said frame comprising a first frequency portion of said fixed null-steering resources and a second frequency portion of said reuse-3 resources, if said traffic of said base station is bigger than said first threshold.

8. The method as in claim 1, wherein the method is performed by a base station for an FDMA digital cellular mobile communication system.

9. The method as in claim 1, wherein the method is performed by a computer program product stored on a computer usable medium, comprising computer readable program means for causing a computer to perform the method when said program is run on said computer.