GB2481544A - Adapting a maximum total transmit power of one or more mobile devices based on interference with a macrolayer base station - Google Patents

Abstract

In a cellular wireless communications network, a maximum value for a total transmit power of one or more mobile devices 22 having wireless connections to a base station 18 is adapted based on interference with a macro-layer base station 16 of the cellular wireless communications network. The maximum value for total transmit power of the one or more mobile devices 22 may be adapted based on pathlosses between the macro-layer base station and the one or more mobile devices 22. The invention has particular application to access points, or femto-cell base stations (FBS) 18, for location within a home or office and for which costly site surveys or detailed radio network planning are not possible. The FBS 18 may also select a carrier frequency and/or scrambling code from lists of resources shared with other base stations 16.

Description

ACCESS POINT POWER CONTROL

This invention relates to an access point, acting as a basestation in a cellular wireless communications network, and in particular to such an access point, in which maximum transmit power levels of the access point are controlled in such a way as to avoid interference while ensuring acceptable coverage.

In conventional cellular networks, basestations are installed by the network operators, in order to provide coverage for the areas where the network operators expect there to be a demand for their services. The network planners are able to choose the locations of the basestations, and are able to set the maximum transmit powers, of the basestation itself and of the mobile devices that establish connections with the basestation, in order to ensure a certain coverage and Quality of Service (QoS). To achieve these aims, the process requires detailed site surveys and geographical planning. When a maximum transmit power has been set, this effectively sets the size of the cell served by the basestation, because it determines the range over which the transmissions from the basestation can successfully be received. The maximum transmit power is rarely changed after it has initially been set, but can be altered from the network if necessary, for example because of changes to the radio network.

When a maximum transmit power has been set for the basestation, and calls are in progress, power control is also applied to the transmissions within these calls. Firstly, an initial transmit power is set, for example based on the power of a received access request, and thereafter power control is applied to the transmissions, based on signal strength measurements made by the mobile device involved in the call and reported back to the basestation. Such power control can operate very quickly. For example, the power level used by a basestation for its transmissions can be adapted at a frequency in the kilohertz region. That is, the power level can in theory change many times per second if the signal strength measurements indicate this.

In the case of access points (also known as femtocell basestations), these are intended to be available for purchase by consumers themselves for location within a home or office, and are intended to provide cellular coverage over relatively small geographical areas, for example only within the building in which they are located. For such devices, costly site surveys and detailed radio network planning are not possible. It is therefore proposed that such devices should be able to configure themselves, based on the local radio environment.

US-6,314,294 relates to a basestation, in which RF transmit power levels are self calibrated, using data collected by the wireless system.

According to a first aspect of the present invention, there is provided method of controlling a basestation in a cellular wireless communications network, the method comprising: within the basestation, autonomously and dynamically adapting a maximum value for a total transmit power of the basestation.

According to a second aspect of the present invention, there is provided a basestation adapted to perform the method according to the first aspect of the invention.

This has the effect that the basestation can configure itself, based on the local radio environment, with reduced network involvement.

For a better understanding of the present invention, and to show how it may be put into effect, reference will now be made, by way of example, to the accompanying drawings, in which:-Figure 1 is a block schematic diagram of a part of a cellular wireless communications network.

Figure 2 is a flowchart of a carrier-selection algorithm.

Figure 3 is a flowchart of a scrambling code selection algorithm.

Figure 4 is a flowchart of an algorithm for selecting the initial downlink maximum transmit power.

Figure 5 is a flowchart of an algorithm for selecting the initial uplink maximum transmit power.

Figure 6 is a flowchart of an algorithm for adapting the uplink and downlink maximum transmit powers.

Figure 7 is a flowchart of an algorithm for adapting the uplink and downlink maximum transmit powers in the event that macrolayer interference is detected.

Figure 8 is a flowchart of an algorithm for adapting the uplink and downlink maximum transmit powers in the event that no interference is detected in the macrolayer or the femtocell basestation layer.

Figure 1 illustrates a part of a cellular wireless communications network in accordance with an aspect of the present invention. Specifically, Figure 1 shows a core network (CN) 10 and a radio network (RN) 12 of a cellular wireless communications network.

These are generally conventional, and are illustrated and described herein only to the limited extent necessary for an understanding of the present invention.

Thus, the core network 10 has connections into the Public Switched Telephone Network (PSTN) (not shown) and into a packet data network, for example the internet 14. The radio network 12 may include, for example, a GSM radio network and/or a UMTS radio network, which are then generally conventional. As shown in Figure 1, the radio network 12 has a basestation (BS) 16 connected thereto. As will be recognized by the person skilled in the art, a typical radio network 12 will have many such basestations connected thereto. These basestations provide coverage over respective geographic areas, or cells, such that a service is available to subscribers. Often, there is a group of basestations that together provide coverage to the whole of the intended service area, while other basestations provide additional coverage to smaller areas within that intended service area, in particular to smaller areas where there is expected to be more demand for the service. The cells served by the basestations of the first group are then referred to as macrocells, while the smaller areas served by the additional basestations are referred to as microcells.

Figure 1 also shows an additional basestation 18 that can be used to provide coverage over a very small area, for example within a single home or office building. This is referred to as a femtocell basestation (FBS). The femtocell basestation 18 is connected into the mobile network operator's core network 10 over the internet 14, by means of the customer's existing broadband internet connection 20. Thus, a user of a conventional mobile phone 22 can establish a connection through the femtocell basestation 18 with another device, in the same way that any other mobile phone can establish a connection through one of the other basestations of the mobile network operator's network, such as the basestation 16.

The core network 10 includes a management system (MS) 24 that provides information to the FBS 18, as described in more detail below.

As mentioned above, the macrocell basestations provide coverage to the whole of the intended service area including the location of the femtocell basestation 18 and the location of the mobile phone 22 while it is in the coverage area of the femtocell basestation 18. However, the network is configured such that, when a mobile device that is registered with the femtocell basestation 18 is within the coverage area of the femtocell basestation 18, then it will preferentially establish a connection with the femtocell basestation 18 rather than with the macrolayer basestation 16.

When the femtocell basestation 18 is first powered on, it selects a carrier frequency and a scrambling code, from lists provided to it from a management system that generally controls the operation of the femtocell basestations in the network. The carrier frequencies and the scrambling codes on the list are shared with other basestations in the network, including nodeBs of the macrolayer and other femtocell basestatioris, and so the carrier frequency and scrambling code are chosen such that they result in the lowest interference to neighbour nodeBs of the macrolayer and neighbour femtocell basestations.

Thereafter, the basestation can autonomously and dynamically select its carrier frequency from the permitted set of carrier frequencies, and can autonomously and dynamically select its scrambling code from a permitted set of codes, in order to produce the lowest interference (see Figures 2 and 3).

Also, the femtocell basestation 18 selects an initial value for the maximum total downlink power, and for total mobile transmit power levels (see Figures 4 and 5). This initial value can be preset in the femtocell basestation 18, based for example on an assumption about the type of location in which the device will be used. For example, it may be assumed that the device will generally be used in homes or small offices, up to a particular size (for example 90 to 250 m2), and further assumptions can then be made about the signal attenuation that will result, and this can be used to determine what value should be set for the maximum total downlink power, in order to ensure a reasonable coverage throughout that area, while avoiding interference with neighbour nodeBs of the macrolayer and neighbour femtocell basestations.

Again, the femtocell basestation 18 can autonomously and dynamically adapt both its total transmit power (including the transmit power of control channels as well as traffic channels) and the total transmit power of the mobiles attached to the basestation.

It is well known that power control should be applied in a cellular communications system, so that the transmission powers in the uplink (UL) and downlink (DL) directions can be adjusted quickly, in order to take account of rapid changes that affect each communication path from the basestation to the relevant mobile device. In the UMTS system, the group of functions used to achieve this are: open-loop power control, inner-loop (or fast) PC and outer-loop power control in both UL and DL directions. Slow power control is also applied to the DL common channels. Open-loop power control is responsible for setting the initial UL and DL transmission powers when a UE is accessing the network. There are two types of inner-loop power control algorithms both of which adjust the transmission dynamically on a 1500 Hz basis. The outer-loop power control estimates the received quality and adjusts the target SIR (signal-interference ratio) for the fast closed-loop power control so that the required quality is provided.

However, in accordance with aspects of the present invention, the total transmit power of the basestation (including the transmit power of control channels as well as traffic channels) and the total transmit power of the mobiles attached to the basestation are also adaptively controlled autonomously by the basestation itself.

This control can for example take place on the basis of measurements made by the basestation itself. That is, the basestation is able to detect signals transmitted by other basestations, including macrolayer basestations and other femtocell basestations. The basestation can identify whether a detected interferer is a macrolayer basestation or a femtocell basestation based on identity information conveyed in the received broadcast channel of said interferer and RF signal measurements therefrom. Preferably, the basestation suspends its own transmissions temporarily in order to make these measurements, both when it is initially powered on, and then intermittently during operation.

Thus, at power up the RSCP (Received Signal Code Power) values can be determined for the CPICHs (Common Pilot Channels) of all surrounding femtocell basestations and macrolayer nodeBs for all available carriers. The carrier exhibiting the lowest interference is selected, where the lowest interference is defined as follows.

Figure 2 is a flowchart showing the preferred algorithm by which the femtocell basestation may select the initial carrier.

In the first step 50, the interference is calculated for each of the allowed carriers on the macrolayer (ML) and each of the allowed carriers on the femtocell basestation layer (FBL). The macrolayer interference for each carrier is calculated by determining the macrolayer CPICH_RSCPs in milliwatts for each detected scrambling code in each carrier. These individual macrolayer CPICH_RSCPS are added together to calculate the total macrolayer interference power per carrier. This value is then converted back to dBm.

A similar method is used for determining the femtocell basestation layer interference for each carrier. The femtocell basestation layer CPICH_RSCPs are determined in milliwatts for each detected scrambling code in each carrier. These individual femtocell basestation CPICH_RSCPs are added together to calculate the total femtocell basestation interference power per carrier. This value is then converted back to dBm.

In the next step 52, it is determined whether there is more than one allowed carrier.

If there is only one allowed carrier, the process moves to step 54, that of determining whether the macrolayer interference for that carrier is below a maximum macrolayer interference threshold. If it is, the carrier is selected by the femtocell basestation. If the interference is above the threshold, an error is generated.

If there is more than one allowed carrier, the process moves to step 56, that of determining whether any of the allowed carriers on the macrolayer are currently unused. Hereinafter, a carrier is considered unused on the macrolayer if there are no detected nodeB CPICH signals and received signal strength indicator (RSSI) on the carrier is below a minimum macrolayer interference threshold.

If there are allowed carriers unused on the macrolayer, the process then determines in step 58 whether or not there are any allowed carriers on the femtocell basestation layer. Hereinafter, a carrier is considered unused on the femtocell basestation layer if there are no detected femtocell basestation CPICH signals and the RSSI on the carrier is below a minimum femtocell basestation layer interference threshold. If there are unused allowed carriers on the femtocell basestation layer, the femtocell basestation layer carrier with the lowest RSSI is chosen. If there are no unused allowed carriers on the femtocell basestation layer, the femtocell basestation layer carrier with the lowest interference (as calculated in step 50) is chosen.

In step 56, if it is determined that there are no unused carriers on the macrolayer, the process moves to step 60, where the carrier with the least macrolayer interference (as calculated in step 50) is chosen. In step 62, the macrolayer interference of this carrier is compared with a maximum macrolayer interference threshold. If the interference is below the threshold, that carrier is chosen. If the interference is above the threshold, an error is generated.

Once the carrier has been selected then, from the list of available scrambling codes, a code is selected. For example, the CPICH_RSCPs of all the available codes may be ranked, and the code with the lowest CPICH_RSCP value selected.

Figure 3 is a flowchart showing the preferred algorithm by which the scrambling code may be selected. This algorithm will typically be applied after the carrier selection algorithm described above with reference to Figure 2.

In step 70, the interference for each allowed scrambling code for the selected carrier is calculated. This step is performed by grouping and summing, by scrambling code, the detected femtocell basestation CPICH RSCPs for each basestation using the selected carrier.

In step 72, the process determines whether or not there are any scrambling codes that are not being used by the detected femtocell basestations. If there are any unused codes, one of these is chosen as the scrambling code. The selection of scrambling code from the list of unused codes is randomized to minimize the probability of two collocated access points selecting the same code.

If there are no unused codes the process moves to step 74, where the code with the least interference (as calculated in step 70) is selected. If the interference on this code is less than a maximum threshold, that code is chosen. If the interference is above the maximum threshold, an error is generated.

Further, the initial selection of carrier and scrambling code could be changed based on measurements from the UE. The UE may report measurements from an adjacent carrier that may indicate that the initial carrier or scrambling code were not optimal due to local shadowing of the femtocell basestation.

Following the carrier and code selection algorithms, the radio measurement data is reported back to the central management system, where it is checked against specified thresholds. If it is determined that the interference levels for the selected code/carriers exceed a predefined threshold set by the management system, and hence that the basestation is not in a location where it can perform acceptably, an error message is supplied to the user, suggesting a repositioning of the unit to a more optimal position within the home.

The initial maximum power values can then be set. If the macrolayer interference dominates, then the initial maximum Down Link transmit power is set based on the strongest macrolayer CPICH RSCP level and including a nominal in-door path loss of typically 60dB. Alternatively, if a carrier is selected which has little or no macrolayer interference, the maximum DL transmit power is set at the same level as the neighbour femtocell basestation exhibiting the strongest CPICH RSCP level (i.e. the largest femtocell basestation interferer). This is done to maintain the same QoS for collocated femtocell basestations. If there is neither macrolayer or femtocell basestation interference, then the initial maximum DL transmit power is set according to the expected UE sensitivity (for a mid range data service) including a nominal indoor path loss of 60dB. This is different to existing Radio Access Network (RAN) design practice, in which the maximum DL Transmit power is set by a RF planner to ensure the expected coverage.

The maximum Up Link femtocell basestation UE transmit power is firstly calculated by determining the smallest path loss to the neighbouring macrolayer nodeB, typically the closest. By summing the minimum macrolayer nodeB sensitivity with the smallest path loss, the maximum UL Tx power can be calculated. This method keeps the noise rise caused by the femtocell basestation UE below the noise caused by the macrolayer cell traffic. Likewise if no macrolayer interference is detected then the femtocell basestation sets its maximum DL transmit power at the same level as the neighbour femtocell basestation exhibiting the strongest CPICH RSCP level. If there is neither macrolayer or femtocell basestation interference then the initial UL transmit power is set according to the femtocell basestation sensitivity (for a mid range data service) and a nominal path loss of 60dB. Again, this is quite different to existing Radio Access Network (RAN) design, in which the maximum UL Transmit power is set by a RF planner to ensure the expected coverage and UE battery life.

Figure 4 is a flowchart showing the preferred algorithm by which the femtocell basestation may select the initial DL maximum transmit power.

In step 100, the interference is calculated for the selected carrier on the femtocell basestation layer and the macrolayer. This step will already have been performed during the carrier-selection algorithm (step 50 in Figure 2).

In step 102, it is determined whether the selected carrier is unused on the macrolayer and the femtocell basestation layer. Again, this step will already have been performed during the carrier-selection algorithm (steps 56 and 58 in Figure 2).

If the carrier is unused on the macrolayer and the femtocell basestation layer, the initial DL maximum transmit power is set at UEprx, mm, the average minimum signal power required by a femtocell basestation UE to support a particular data or speech service, plus the minimum indoor loss, a parameter corresponding to the allowed indoor path loss that will provide the required coverage (step 104). The minimum indoor loss is supplied by a central management system.

If the selected carrier is not unused by the macrolayer or the femtocell basestation layer, the process moves to step 106 where the macrolayer interference is compared with the femtocell basestation interference for the selected carrier. If the macrolayer interference is greater, in step 108 the initial DL maximum transmit power is set at the minimum indoor loss (as described above), plus the RSCP value of the nodeB with the largest detected RSCP, minus 1 Oxlog10(percentage of the total femtocell basestation power allocated to CPICH).

The percentage of the total downlink transmission power allocated to the CPICH is a parameter supplied by the central management system.

If, in step 106, it is determined that the femtocell basestation interference is greater than the macrolayer interference, the initial DL maximum transmit power is set in step 110 at the CPICH power of the neighbour femtocell basestation with the largest detected RSCP value, minus 1 Oxlog10(percentage of the total femtocell basestation power allocated to CPICH).

As before, the percentage of the total downlink transmission power allocated to the CPICH is a parameter supplied by the management system.

Once the initial DL maximum transmit power has been set in one of steps 104, 108 or 110, the process checks in step 112 whether the initial DL maximum transmit power is greater than or less than the maximum permitted femtocell basestation DL power (a parameter set by the management system). If it is less than the maximum permitted power, the initial DL maximum transmit power remains at its original value. However, if the initial DL maximum transmit power is greater than the maximum permitted power, the initial DL maximum transmit power is reset at the maximum permitted power, and a warning sent to the management system. For example, a flag may be set to indicate that the initial DL maximum transmit power is less than that required to run a particular speech or data service, or that the DL power is currently at its maximum permitted level.

Figure 5 is a flowchart showing the preferred algorithm by which the femtocell basestation may select the initial UL maximum transmit power.

Steps 150 and 152 are calculating the interference for the selected carrier on the femtocell basestation later and the macrolayer, and checking whether the selected carrier is in use on the femtocell basestation layer or the macrolayer, respectively.

Both of these steps will have been carried out earlier as part of the carrier selection algorithm, and are described in more detail with reference to Figure 2.

If the carrier is not in use on the macrolayer or the femtocell basestation layer, the initial UL maximum transmit power is set in step 154 at FB1 mm, the average minimum signal power required by a femtocell basestation to support a particular data or speech service, plus the minimum indoor loss, the allowed indoor path loss that will provide the required coverage.

If the carrier is in use on the femtocell basestation layer or the macrolayer, the process moves to step 156, where the macrolayer interference is compared with the femtocell basestation layer interference for the selected carrier. If the femtocell basestation interference is greater, the initial UL maximum transmit power is set in step 158 at the maximum UE transmit power of the femtocell basestation with the least path loss. This value is determined by first calculating the path losses from the femtocell basestation to the detected femtocell basestations using the following equation: LFBFB = CPICH -Tx -PowerFB -CPICH -RSCPFB where CPICH TxPowerFB is the CPICH transmitted power read from the broadcast channel of detected femtocell basestations. The maximum UE transmit power read from the broadcast channel of the neighbour femtocell basestation that has the least path loss to the femtocell basestation is then selected.

If the macrolayer interference is greater than the femtocell basestation interference for the selected carrier, the nodeB to femtocell basestation path losses are then calculated in step 160. The path losses are calculated using the following equation: LN0deBFB = CPICH -Tx -PowerNodeB -CPICH -RSCPN0deB where CPICH TxPowerNodeB is the CPICH transmitted power read from the broadcast channel of detected nodeBs.

The initial UL maximum transmit power is set in step 164 at MLprx, mm, the average minimum signal power required by a nodeB to support a particular data or speech service, plus the RSCP value that corresponds to the least nodeB to femtocell basestation path loss.

Once the initial UL maximum transmit power has been set in one of steps 154, 158 or 164, the process moves to step 166, where the initial UL maximum transmit power is compared with the maximum permitted femtocell basestation UL power. If the UL maximum transmit power is less than the maximum permitted power, the initial UL maximum transmit power is maintained at its original level. If the UL maximum transmit power is greater than the maximum permitted power, the initial UL maximum transmit power is reset at the maximum permitted power as defined by the management system. Also, a warning is sent to the management system, that the UL power may be insufficient for certain data or speech services, or that the UL power is currently at its maximum permitted level.

During operation, the maximum DL and UL transmit powers are adapted through the regular CPICH RSCP and CPICH Ec/lo measurements reported by the femtocell basestation UEs during idle mode or RRC connected mode (CELL_DCH state). The adaptation algorithm assumes that the femtocell basestation UEs remain for the majority of the time within the expected coverage area (i.e. the house or office). The adaptation algorithm slowly increases or decreases the allowed UL and DL maximum transmit power level to ensure that the CPICH Ec/lo (or Q0S) remains at a suitable level for both speech and data services. In the case that the femtocell basestation detects that there is local macrolayer interference then over a period of time it builds two sets of histograms from the femtocell basestation UE measurements of the active and neighbour cells. The first histogram is the path loss between the femtocell basestatiori UE and the neighbour macrolayer nodeB and the second set of histograms is the path loss between the femtocell basestation UE and the femtocell basestation and also the femtocell basestation UE CPICH Ec/lo measurements. The adaptation algorithm attempts to keep typically 90% of all femtocell basestation UE CPICH Ec/lo measurements above a particular level (e.g. -10 to -15dB) but will only allow 1% of femtocell basestation UE to femtocell basestation path loss measurements (i.e. largest path loss) to exceed the path loss between the femtocell basestation UE and macrolayer nodeB (i.e. smallest path loss). Furthermore the adaptation algorithm will allow a maximum path femtocell basestation to femtocell basestation UE path loss of typically <90dB for 95% of the time. By assuming that the UL and DL path loss is reciprocal, the same adaptation algorithms are used to set the maximum DL and UL transmit power levels.

The femtocell basestation may also gather UE measurements by sniffing' periodically (for example every 100 seconds) by stealing a down link frame.

Figure 6 is a flowchart showing the preferred algorithm by which the femtocell basestation may dynamically adapt the UL and DL maximum transmit powers.

As described above, the femtocell basestation regularly takes UE measurements of the active and neighbour cells, and these are used as the input for adapting the maximum transmit powers. By monitoring the UE measurements, in step 200, the process first determines whether there has been a significant change on either the macrolayer or the femtocell basestation layer's interference levels for the carrier and scrambling code already selected. A significant change in this context means any change that will require a new carrier and/or scrambling code to be reselected. Therefore, if a significant change is found, the process will rerun the carrier-selection algorithm, the scrambling-code-selection algorithm and the initial power setup algorithm described with reference to Figures 2, 3 and 4, respectively, in step 202.

Once these "power up" algorithms have been performed, the process moves to step 203, that of re-gathering samples of UE measurements so that step 200 can be performed again for the new carrier and/or scrambling code.

If there is no significant change in the macrolayer or the femtocell basestation layer, the process determines in step 204 whether or not the carrier is used on the macrolayer. If the carrier is used on the macrolayer (i.e. interference is detected on the macrolayer), the macrolayer interference algorithm is used to adapt the power (see Figure 7).

If the carrier is not used on the macrolayer, the process determines in step 206 whether the carrier is used on the femtocell basestation layer. If the carrier is not used on the femtocell basestation layer (i.e. there is no interference on the femtocell basestation layer) the "no interference" algorithm is used to adapt the power (see Figure 8).

If the carrier is used on the femtocell basestation layer, the UL and DL maximum transmit powers are set as follows.

The UL maximum transmit power is set at the maximum UE transmit power of the femtocell basestation with the least path loss. This value is determined by first calculating the path losses from the femtocell basestation to the surrounding detected femtocell basestations. The maximum UE transmit power read from the broadcast channel of the surrounding femtocell basestation that has the least path loss to the femtocell basestation is then selected.

The path losses are determined, as before, by the following equation: LFBFB CPICH -Tx -PowerFB -CPICH -RSCPFB.

The DL maximum transmit power is set at the CPICH Tx power of the femtocell basestation with the largest detected RSCP value, minus lOxlog1o(percentage of the total femtocell basestation power allocated to CPICH).

That is, if only interference from a neighbouring femtocell basestation is detected, the basestation uses the power of that neighbouring basestation to set its own UL and DL maximum transmit powers.

Figure 7 is a flowchart of the preferred algorithm that may be used to adapt the UL and DL maximum transmit powers in the event that macrolayer interference is detected.

As described above, histograms are produced from the UE measurements.

Specifically, these are the femtocell basestation UE to neighbouring nodeB path losses, the femtocell basestation to femtocell basestation UE path losses, and the femtocell basestation UE CPICH Ec/lo measurements. From these histograms, the following quantities can be calculated: Avg_Ec/lo = the average of the top 10% femtocell basestation UE CPICH Ec/lo values; Avg_ML_Pathloss = the average of the bottom 1% nodeB to femtocell basestation UE path losses; Avg_FBLPathloss = the average of the top 10% FB to FB UE path losses; Pathloss_adjustment = the absolute value of [1/2 x (Avg_FBL_Pathloss -Avg_M L_Path loss)] Further, a new parameter, Indoor loss, is set to the value of minimum indoor loss, initially provided by the central management system. However, minimum indoor loss is adapted as the process of DL and UL maximum power adaptation is repeated, as will be described in more detail below.

In step 250, Avg_Echo is compared with the desired femtocell basestation UE CPICH Echo. If Avg_Echo is larger, then the process moves to step 252, which compares Avg_ML_Pathloss with Avg_FBL_Pathloss. If Avg_ML_Pathloss is greater, the UL and DL maximum transmit powers are kept at the same level (step 254).

If Avg_ML_Pathloss is smaller than Avg_FBL_Pathloss, then the UL and DL maximum transmit powers are set as follows (step 256). Maximum DL power is set at the RSCP level of the largest detected nodeB RSCP value, minus 1 Oxlog10(percentage of the total femtocell basestation power allocated to CPICH), plus the indoor loss, minus Pathloss adjustment. Maximum UL power is set at ML1 mm, the minimum signal power required by the basestation to support a particular data or speech service, plus the Avg_ML_Pathloss. Further, minimum indoor loss is re-set at the value of Indoor loss minus Pathloss Adjustment.

If it is determined, in step 250, that Avg_Ec/Io is less than the desired femtocell basestation UE CPICH Ec/lo, the process moves to step 258, where Avg_ML_Pathloss is again compared with Avg_FBL_Pathloss.

If Avg_ML_Pathloss is smaller, the maximum DL power is set in step 260 at the RSCP value of the riodeB with the largest detected RSCP value, minus lOxIog1o(percentage of the total femtocell basestation power allocated to CPICH), plus the Avg ML Pathloss. The maximum UL power is set at ML1, mm, the minimum signal power required by the basestation to support a particular data or speech service, plus the Avg_ML_Pathloss.

If Avg_ML_Pathloss is greater than Avg_FBL_Pathloss, the maximum DL power is set in step 262 at the RSCP value of the nodeB with the largest RSCP value, minus 1 OxIog10(percentage of the total femtocell basestation power allocated to CPICH), plus the indoor loss and Pathloss_adjustment. The maximum UL power is set at ML mm, the minimum signal power required by a femtocell basestation to support a particular data or speech service, plus the Avg_ML_Pathloss. Further, minimum indoor loss is re-set at the value of Indoor loss plus Pathloss_Adjustment.

Once the maximum DL and UL powers have been set in one of steps 256, 260 or 262, the process moves in parallel to steps 263 and 264. In step 263 the process checks whether the maximum DL power is greater than or less than the maximum permitted femtocell basestation DL power (a parameter set by the management system). If it is less than the maximum permitted power, the maximum DL power remains at its re-set value. However, if the maximum DL power is greater than the maximum permitted power, the maximum DL power is changed to the maximum permitted power, and a warning sent to the management system. For example, a flag may be set to indicate that the maximum DL power is less than that required to run a particular speech or data service.

In step 264 the process checks whether the maximum UL power is greater than or less than the maximum permitted femtocell basestation UL power (a parameter set by the management system). If it is less than the maximum permitted power, the maximum UL power remains at its re-set value. However, if the maximum UL power is greater than the maximum permitted power, the maximum UL power is changed to the maximum permitted power, and a warning sent to the management system. For example, a flag may be set to indicate that the maximum UL power is less than that required to run a particular speech or data service.

The whole process as described by Figures 6 and 7 repeats, adapting the maximum UL and DL powers until either an error event occurs, the powers converge to an optimal value, or the host processor identifies that there has been a significant change in the local interference levels and the carrier, scrambling code and initial UL and DL powers need to be re-evaluated.

Further, the value of minimum indoor loss is adapted as the process repeats. For example, minimum indoor loss may be set at 60 dB initially. When the process is run, it may end up at step 262. If Pathloss Adjustment is found to be 10 dB, minimum indoor loss is reset at 70 dB, and for the next repeat of the process, indoor loss will begin at dB.

Figure 8 is a flowchart of the preferred algorithm that may be used to adapt the UL and DL maximum transmit powers in the event that no interference is detected from the macrolayer or the femtocell basestation layer.

As described above, histograms are produced from the UE measurements.

Specifically, these are the femtocell basestation to femtocell basestation UE path losses, and the femtocell basestation UE CPICH Ec/lo measurements. From these histograms, the following quantities can be calculated: Avg_Ec/lo = the average of the top 10% femtocell basestation UE CPICH Ec/lo values; Avg_FBL_Pathloss = the average of the top 10% FB to FB UE path losses; Pathloss_adjustment = the absolute value of [1/2 x (Avg_FBL_Pathloss -Maximum allowed FB Pathloss)] Maximum allowed femtocell basestation pathloss is supplied by the management system, and based on an assumed maximum indoor path loss (typically around 90dB).

Indoor loss is set at the value of minimum indoor loss, as described with reference to Figure 7.

In step 270, Avg_Ec/lo is compared with the desired femtocell basestation UE CPICH Ec/lo. If Avg_Ec/lo is larger, then the process moves to step 274, which compares Avg_FBL_Pathloss with the maximum allowed femtocell basestation path loss. If Avg_FBL_Pathloss is smaller, the UL and DL maximum transmit powers are kept at the same level (step 275).

If Avg_FBL_Pathloss is greater than the maximum allowed femtocell basestation path loss, then the UL and DL maximum transmit powers are set as follows (step 276).

Maximum DL power is set at UEprx, mm, plus the indoor loss, minus Pathloss adjustment. Maximum UL power is set at FBprx mm, plus the indoor loss, minus Pathloss_adjustment. Minimum indoor loss is reset at indoor loss minus Path loss_Adjustment If it is determined, in step 270, that Avg_Ec/lo is smaller than the desired femtocell basestation UE CPICH Ec/lo, the process moves to step 272, where Avg_FBL_Pathloss is again compared with the maximum allowed femtocell basestation path loss.

If Avg_FBL_Pathloss is smaller, the maximum DL power is set in step 277 at UEpN, mm, plus the indoor loss, plus Pathloss adjustment. Maximum UL power is set at FBprx, mm, plus the indoor loss, plus Pathloss adjustment. Minimum indoor loss is set at Indoor loss plus Pathloss_Adjustment.

If Avg_ML_Pathloss is greater than AvgfBL_Pathloss, then an error alert is sent to the management system (step 278).

Once the maximum DL and UL powers have been set in step 276 or 277, the process moves in parallel to steps 278 and 279. In step 279 the process checks whether the maximum DL power is greater than or less than the maximum permitted femtocell basestation DL power (a parameter set by the management system). If it is less than the maximum permitted power, the maximum DL power remains at its re-set value.

However, if the maximum DL power is greater than the maximum permitted power, the maximum DL power is changed to the maximum permitted power, and a warning sent to the management system. For example, a flag may be set to indicate that the maximum DL power is less than that required to run a particular speech or data service.

In step 279 the process checks whether the maximum UL power is greater than or less than the maximum permitted femtocell basestation UL power (a parameter set by the management system). If it is less than the maximum permitted power, the maximum UL power remains at its re-set value. However, if the maximum UL power is greater than the maximum permitted power, the maximum UL power is changed to the maximum permitted power, and a warning sent to the management system. For example, a flag may be set to indicate that the maximum UL power is less than that required to run a particular speech or data service.

The whole process as described by Figures 6 and 8 repeats, adapting the maximum UL and DL powers until either an error event occurs, the powers converge to an optimal value or the host processor identifies that there has been a significant change in the local interference levels and the carrier, scrambling code and initial UL and DL powers need to be re-evaluated. Again, the value of minimum indoor loss is also adapted as the process repeats.

The maximum DL transmit power will also be adapted based on reported round trip time (RTT) measurements available from the femtocell basestation and measured for each femtocell basestation UE. A histogram of the RTT measurements would be built up for all calls and the maximum DL transmit power adapted so that a predetermined number of RTT samples (typically 90%) are within the expected coverage area.

Furthermore, Random Access Channel (RACH) measurements can be used to determine at what distance from the access point a mobile is trying to set up a call. If the call set up is outside of the expected coverage area then the call can be rejected.

Error conditions such as multiple accesses from unregistered mobiles may indicate that the DL coverage is too large or that the user has positioned the femtocell basestation in a position that is causing unnecessary DL macrolayer interference (e.g. on a window overlooking the city). In this situation the maximum DL transmit power may be reduced until this error event falls below a predetermined threshold. Alternatively, the problem could be reported to the management system, which may send a message to the user requesting him to relocate the unit in a position that would cause less interference.

Thus the basestation can use knowledge of access attempts by unregistered mobiles to adapt the DL and UL maximum transmit powers.

As described above, there are several ways in which error conditions can be detected, and may be reported to the management system. For example, there may be a requirement to use a particular power level, or information about a number of access attempts from mobiles that are outside the intended coverage area. These may indicate that the configuration of the basestation would cause excessive interference, or otherwise be detrimental. In each of these situations, the problem may be resolved by repositioning of the basestation, for example away from a window or towards a position nearer the centre of the intended coverage area. In response to an error condition, therefore, a message may be sent from the management system to the user of the basestation, requesting that the basestation be repositioned. The message may be displayed on the basestation itself, or sent to a device that is connected to the basestation. This repositioning can be carried out until the error condition is resolved, and therefore acts as a pseudo-closed loop control.

There are thus described methods of operation of a basestation, and basestations adapted for such uses, that allow the basestations to configure themselves for operation within the cellular network without excessive interference with each other or with other basestations in the network.