Patent Description:
Massive Multiple-Input-Multiple-Output (MIMO) (which is also referred to as large scale MIMO) may simultaneously communicate with multiple users on the same time-frequency resource by configuring hundreds or thousands of antenna arrays at a base station side, thus greatly improving the spectrum efficiency, and the massive MIMO is a key technology for improving system capacity and Spectrum Efficiency (SE) in the 5th Generation Mobile Networks (<NUM>). Without an increase in system bandwidth, base stations or cells, massive MIMO cells can exhibit a traffic gain several times higher than that of conventional macro stations by virtue of beamforming and multi-user spatial division pairing capabilities of the massive MIMO.

However, some massive MIMO cells cannot well perform the beamforming and multi-user spatial division pairing capabilities of the massive MIMO, resulting in a limited improvement in traffic of the massive MIMO cells.

<CIT> relates to a load balancing method.

<CIT> discloses a method for carrying out load balancing.

Embodiments of the present application provide a load adjustment method, a server and a storage medium, providing a possibility to improve the traffic of a massive MIMO cell.

Embodiments of the present application are described in detail in conjunction with the drawings.

First embodiment of the present application relates to a load adjustment method. The load adjustment method may be applied to a device, for example, a base station. The flow is shown in <FIG> and includes steps described below.

In step <NUM>, an indicator value of a first performance indicator of a massive MIMO cell is acquired.

The device may automatically acquire the indicator value of the first performance indicator of the massive MIMO cell within the latest preset time period, and the preset time period may be set according to actual requirements. For example, the preset time period is <NUM> minutes. A triggering event may also be preset in the device. When the triggering event occurs, the indicator value of the first performance indicator of the massive MIMO cell is acquired. The first performance indicator may be one type of performance indicator. For example, the first performance indicator is a Physical Resource Block (PRB) utilization. The first performance indicator may also be multiple types of performance indicators, and then indicator values of the multiple types of performance indicators are acquired, respectively. For example, the first performance indicator includes the PRB utilization, Control Channel Element (CCE) power and a CCE position utilization, and then the indicator value of the PRB utilization, the indicator value of the CCE power and the indicator value of the CCE position utilization are acquired, respectively.

In step <NUM>, a load state of the massive MIMO cell is determined according to the indicator value of the first performance indicator.

In an example, different load states of the massive MIMO cell may be represented as a relatively idle state, a relatively busy state and a congestion state. In both the relatively idle state and the relatively busy state, no congestion situation occurs, and in the congestion state, a congestion situation occurs. In an example, different load states of the massive MIMO cell may also be represented numerically, different numerical values characterize different load states. It may be predefined that the larger the numerical value is, the busier the massive MIMO cell is. The largest numerical value characterizes that the congestion situation occurs, the smallest numerical value characterizes that no congestion situation occurs and the massive MIMO cell is relatively idle, and other numerical values characterize that no congestion situation occurs and the massive MIMO cell is relatively busy. For example, cases where s = <NUM>, <NUM>, <NUM>, and <NUM> refer to different load states, respectively, when s = <NUM>, no congestion situation occurs and the massive MIMO cell is relatively idle; when s = <NUM> or <NUM>, no congestion situation occurs and the massive MIMO cell is relatively busy; and when s = <NUM>, the congestion situation occurs.

The device may preset a rule for determining the load state of the massive MIMO cell according to the indicator value of the first performance indicator. In an example, a correspondence between load states of the massive MIMO cell and ranges where the indicator value of the first performance indicator is located may be set. For example, the load states are represented by the relatively idle state, the relatively busy state, and the congestion state. When <NUM>% ≤ the PRB utilization ≤ <NUM>%, the massive MIMO cell is in the relatively idle state; when <NUM>% < the PRB utilization ≤ <NUM>%, the massive MIMO cell is in the relatively busy state; and when <NUM>% < the PRB utilization ≤ <NUM>%, the massive MIMO cell is in the congestion state. For another example, the load states are represented numerically. When <NUM>% ≤ the PRB utilization ≤ <NUM>%, and <NUM>% ≤ the CCE power ≤ <NUM>% or <NUM>% ≤ the CCE position utilization ≤ <NUM>%, s = <NUM>; when <NUM>% < the PRB utilization ≤ <NUM>%, and <NUM>% ≤ the CCE power ≤ <NUM>% or <NUM>% ≤ the CCE position utilization ≤ <NUM>%, s = <NUM>; when <NUM>% < the PRB utilization ≤ <NUM>%, and <NUM>% < the CCE power ≤ <NUM>% or <NUM>% < the CCE position utilization ≤ <NUM>%, s = <NUM>; and when <NUM>% < the PRB utilization ≤ <NUM>%, and <NUM>% < the CCE power ≤ <NUM>% or <NUM>% < the CCE position utilization ≤ <NUM>%, s = <NUM>.

In an example, it may be set that the load state of the massive MIMO cell is determined according to the load state within the previous preset time period and a switching rule of the load state. For example, the load states are represented by the relatively idle state, the relatively busy state and the congestion state, and the switching rule of the load state is described below. In a case where the load state within the previous preset time period is the relatively idle state, when the current PRB utilization is greater than <NUM>%, the load state is switched to the relatively busy state. In a case where the load state within the previous preset time period is the relatively busy state, when the current PRB utilization is greater than <NUM>%, and the current CCE power is greater than <NUM>% or the current CCE position utilization is greater than <NUM>%, the load state is switched to the congestion state; and when the current PRB utilization is less than <NUM>%, the load state is switched to the relatively idle state. In a case where the load state within the previous preset time period is the congestion state, when the current PRB utilization is less than <NUM>%, or the current CCE power is less than <NUM>% and the current CCE position utilization is less than <NUM>%, the load state is switched to the relatively busy state.

In step <NUM>, a load adjustment strategy matching the load state of the massive MIMO cell is determined and performed, where the load adjustment strategy includes one of the following: migrating a first user of a neighboring cell of the massive MIMO cell into the massive MIMO cell, migrating a second user in the massive MIMO cell into a neighboring cell, migrating a first user of a neighboring cell into the massive MIMO cell and migrating a second user in the massive MIMO cell into the neighboring cell, or maintaining the status quo.

The first user and the second user are different users. When the load adjustment strategy is migrating the first user of the neighboring cell into the massive MIMO cell and migrating the second user in the massive MIMO cell into the neighboring cell, the first user of the neighboring cell may be migrated into the massive MIMO cell first, and then the second user in the massive MIMO cell is migrated into the neighboring cell; or the second user in the massive MIMO cell may be migrated into the neighboring cell first, and then the first user of the neighboring cell is migrated into the massive MIMO cell; or the first user of the neighboring cell may be migrated into the massive MIMO cell at the same time when the second user in the massive MIMO cell is migrated into the neighboring cell. The embodiment is not intended to be limiting.

In an example, the first user or the second user refers to any user. In an example, when migrating the first user of the neighboring cell into the massive MIMO cell, the neighboring cell is denoted as a present cell and the massive MIMO cell is denoted as a target cell; when migrating the second user in the massive MIMO cell into the neighboring cell, the massive MIMO cell is denoted as a present cell and the neighboring cell is denoted as a target cell. The first user or the second user is determined in the manner described below. The flowchart of determining the first user or the second user is shown in <FIG>.

In step <NUM>, N users are selected from the present cell, where N ≥ <NUM> and N is preset.

The value of N may be preset according to actual situations, which is not limited in the embodiment. If the number of users in the present cell is less than N, all users in the present cell are selected. For example, N is preset to be <NUM>; if there are <NUM> users in the present cell, any <NUM> users are selected; if there are <NUM> users in the present cell, the <NUM> users are selected.

In an example, when migrating the first user of the neighboring cell into the massive MIMO cell, the step in which the N users are selected from the present cell includes that N users are selected from users, in the present cell, having a downlink data volume greater than a preset data volume; when migrating the second user in the massive MIMO cell into the neighboring cell, the step in which the N users are selected from the present cell includes that users having the number of spatial division scheduling times greater than a preset number of times and a spatial division scheduling proportion greater than a first preset threshold in the present cell are ranked according to Spectrum Efficiency (SE) values from small to large, and the first N users are selected.

A user having a downlink data volume greater than the preset data volume is referred to as a large Buffer Status Report (BSR) user. If the number of large BSR users is less than N, all large BSR users are selected. For example, a user having the downlink data volume greater than <NUM> Kbits within <NUM> second is counted as a large BSR user. In a case where N is preset to be <NUM>, and if there are <NUM> large BSR users in the present cell, any <NUM> large BSR users are selected; and if there are <NUM> large BSR users in the present cell, the <NUM> large BSR users are selected. Users, in the present cell, having the number of spatial division scheduling times greater than the preset number of times and the spatial division scheduling proportion greater than the first preset threshold are ranked according to the SE values from small to large, and the first N users are selected. If the number of users satisfying the condition is less than N, all users are selected. The preset number of times and the first preset threshold may be set according to actual requirements, which are not limited in the embodiment. The spatial division scheduling proportion is equal to dividing the number of times that the user performs spatial division scheduling by the number of times that the user performs total scheduling. For example, N is preset to be <NUM>, the preset number of times is <NUM>, and the first present threshold is <NUM>%; if there are <NUM> users in the present cell, users having the number of spatial division scheduling times greater than <NUM> and the spatial division scheduling proportion greater than <NUM>% are selected first, then the users having the number of spatial division scheduling times greater than <NUM> and the spatial division scheduling proportion greater than <NUM>% are ranked according to the SE values from small to large, and the first <NUM> users are selected; if <NUM> users satisfy the condition, the <NUM> users are selected. In this manner, when migrating the first user of the neighboring cell into the massive MIMO cell, a condition is set for the selection process, that is, the selected N users are users having the downlink data volume greater than the preset data volume, so that the user quality of the first user migrated into the massive MIMO cell is improved, and thereby the possibility of improving the traffic of the neighboring cell is increased; when migrating the second user in the massive MIMO cell into the neighboring cell, a condition is set for the selection process, that is, the selected N users are selected from users having the number of spatial division scheduling times greater than the preset number of times and the spatial division scheduling proportion greater than the first preset threshold are ranked according to the SE values from small to large, so that the user quality of the second user migrated into the neighboring cell is improved, and thereby the possibility of improving the traffic of the neighboring cell is increased. Therefore, the possibility of an improvement in the total traffic of all cells in the area where the massive MIMO cell is located is increased.

In step <NUM>, a second performance indicator of each selected user in the target cell is measured so that an indicator value of the second performance indicator is obtained.

The device measures the second performance indicator of the selected user in the target cell to obtain the indicator value of the second performance indicator of the selected user in the target cell. The second performance indicator is preset. The second performance indicator may be one type of performance indicator or multiple types of performance indicators. In an example, the second performance indicator is Reference Signal Receiving Power (RSRP). The second performance indicator is described as the RSRP in the embodiment and following embodiments, but is not limited thereto.

In step <NUM>, if the indicator value of the second performance indicator is greater than a preset indicator value of the target cell, the selected user is used as the first user or the second user.

The preset indicator value of the target cell may be set according to actual situations, which is not limited in the embodiment. For example, if the preset indicator value of the RSRP of the target cell is -<NUM> dBm, RSRP values of selected users a, b, c, d, and e in the target cell are measured, and the RSRP values of -<NUM> dBm, -<NUM> dBm, -<NUM> dBm, -<NUM> dBm and -<NUM> dBm are obtained, respectively, so that users a, b, and e are the first user or the second user, and users a, b, and e of the present cell are migrated into the target cell.

In an example, the second performance indicator of a selected user in the target cell and the second performance indicator of the selected user in the present cell are measured respectively so that the indicator value of the second performance indicator of the user in the target cell and the indicator value of the second performance indicator of the user in the present cell are obtained. If the indicator value of the second performance indicator of the user in the target cell is greater than the preset indicator value of the target cell, and the difference between the indicator value of the second performance indicator of the user in the target cell and the indicator value of the second performance indicator of the user in the present cell is greater than or equal to a second preset threshold, the selected user is used as the first user or the second user. For example, if the preset indicator value of the RSRP of the target cell is -<NUM> dBm, the second preset threshold is -<NUM> dBm, the RSRP values of the selected users a, b, c, d and e in the target cell and the RSRP values of the selected users a, b, c, d and e in the present cell are measured, respectively, and the RSRP value of each selected user in the target cell and the RSRP value of the selected user in the present cell are -<NUM> dBm and -<NUM> dBm, -<NUM> dBm and -<NUM> dBm, -<NUM> dBm and -<NUM> dBm, -<NUM> dBm and -<NUM> dBm, and -<NUM> dBm and -<NUM> dBm, respectively, so that users a and e are the first user or the second user, and a and e of the present cell are migrated into the target cell.

In this manner, the user quality of the first user migrated into the massive MIMO cell is improved, thereby the possibility of the improvement in the traffic of the massive MIMO cell is increased, or the user quality of the second user migrated into the neighboring cell is improved, thereby the possibility of the improvement in the traffic of the neighboring cell is increased. Therefore, the possibility of the improvement in the total traffic of all cells in the area where the massive MIMO cell is located is increased.

In an example, after the load adjustment strategy matching the load state of the massive MIMO cell is determined and performed, the method further includes the following: an indicator value of a third performance indicator is acquired; and the preset indicator value of the target cell is updated according to the load state of the massive MIMO cell and the indicator value of the third performance indicator.

The device acquires the indicator value of the third performance indicator within a preset period time before the load adjustment strategy is performed and the indicator value of the third performance indicator within a preset period time after the load adjustment strategy is performed. The third performance indicator may be one type of performance indicator or multiple types of performance indicators. Updating the preset indicator value of the target cell refers to that for any load adjustment strategy, after the load adjustment strategy is performed, according to the load state and the indicator value of the third performance indicator, an adjustment amplitude is obtained according to a preset rule, and then the preset indicator value of the target cell is subjected to one of the following: kept unchanged, increased, or decreased. For example, the load state before the load adjustment strategy is performed and the load state after the load adjustment strategy is performed are a state before the adjustment and a state after the adjustment, respectively. The third performance indicator includes the traffic of the massive MIMO cell, the total traffic of the area where the massive MIMO cell is located and the number of Radio Resource Control (RRC) connection users of the massive MIMO cell, where the traffic of the massive MIMO cell within a preset time period before the load adjustment strategy is performed and the traffic of the massive MIMO cell within a preset time period after the load adjustment strategy is performed are denoted as MM traffic before the adjustment and MM traffic after the adjustment, respectively; the total traffic of the area within a preset time period before the load adjustment strategy is performed and the total traffic of the area within a preset time period after the load adjustment strategy is performed are denoted as area traffic before the adjustment and area traffic after the adjustment, respectively; and the number of RRC connection users of the massive MIMO cell within a preset time period before the load adjustment strategy is performed and the number of RRC connection users of the massive MIMO cell within a preset time period after the load adjustment strategy is performed are denoted as RRC before the adjustment and RRC after the adjustment, respectively. When the load adjustment strategy is migrating the first user of the neighboring cell into the massive MIMO cell, if the state before the adjustment is the same as the state after the adjustment, the RRC after the adjustment minus the RRC before the adjustment is less than or equal to <NUM>, the MM traffic before the adjustment is less than or equal to the MM traffic after the adjustment, the area traffic before the adjustment is less than or equal to the area traffic after the adjustment, and the preset indicator value, that is, Reference Signal Receiving Power (RSRP), of the massive MIMO cell is greater than -<NUM> dBm, the preset indicator value of the RSRP of the massive MIMO cell is decreased by <NUM> dB; if the state before the adjustment is the same as the state after the adjustment, the RRC after the adjustment minus the RRC before the adjustment is greater than or equal to <NUM>, and the preset indicator value of the RSRP of the massive MIMO cell is less than -<NUM> dBm, the preset indicator value of the RSRP of the massive MIMO cell is increased by <NUM> dB; if the state before the adjustment is the same as the state after the adjustment, the RRC after the adjustment minus the RRC before the adjustment is greater than <NUM>, the MM traffic before the adjustment is greater than the MM traffic after the adjustment or the area traffic before the adjustment is greater than the area traffic after the adjustment, and the preset indicator value of the RSRP of the massive MIMO cell is less than -<NUM> dBm, the preset indicator value of the RSRP of the massive MIMO cell is increased by <NUM> dB; and if the state before the adjustment is not same as the state after the adjustment, and the preset indicator value of the RSRP of the neighboring cell is not equal to -<NUM> dBm, the preset indicator value of the RSRP of the neighboring cell is adjusted to be -<NUM> dBm. The preset indicator value of the target cell is updated, so that the preset indicator value of the target cell is more reasonable, and when a user is subsequently determined and selected according to the updated preset indicator value of the target cell as the first user or the second user, the determined first user or the determined second user is more reasonable.

In the embodiment, the step in which the load adjustment strategy matching the load state of the massive MIMO cell is determined and performed includes the step described below. According to a preset correspondence between load states and load adjustment strategies, a load adjustment strategy corresponding to the load state of the massive MIMO cell is used as the load adjustment strategy matching the load state of the massive MIMO cell, and the load adjustment strategy matching the load state of the massive MIMO cell is performed. The correspondence between the load states and the load adjustment strategies is preset in the device, and the number of types of the load states is the same as the number of the load adjustment strategies. When the load state of the massive MIMO cell is determined, the correspondence is queried, the load adjustment strategy corresponding to the load state is used as the load adjustment strategy matching the load state, and the load adjustment strategy is performed. The correspondence between the load states and the load adjustment strategies is preset, so that after the load state is determined, the load adjustment strategy matching the load state can be determined relatively quickly and then performed, which is simple and feasible.

In an example, when the load state is that no congestion situation occurs in the massive MIMO cell, the corresponding load adjustment strategy is migrating the first user of the neighboring cell into the massive MIMO cell; and when the load state is that a congestion situation occurs in the massive MIMO cell, the corresponding load adjustment strategy is migrating the second user in the massive MIMO cell into the neighboring cell. For example, it is preset that the load state includes that no congestion situation occurs and the massive MIMO cell is relatively idle, no congestion situation occurs and the massive MIMO cell is relatively busy, and the congestion situation occurs. When no congestion situation occurs and the massive MIMO cell is relatively idle or no congestion situation occurs and the massive MIMO cell is relatively busy, the corresponding load adjustment strategy is migrating the first user of the neighboring cell into the massive MIMO cell; and when the congestion situation occurs, the corresponding load adjustment strategy is migrating the second user in the massive MIMO cell into the neighboring cell. The correspondence between the load states and the load adjustment strategies is shown in the table below.

When no congestion situation occurs in the massive MIMO cell, it represents that more users may access the massive MIMO cell, and then a user of the neighboring cell is migrated into the massive MIMO cell, so that it is possible to improve the traffic of the massive MIMO cell; when a congestion situation occurs in the massive MIMO cell, it represents that the massive MIMO cell cannot satisfy the requirements of users, and the second user in the massive MIMO cell is migrated into the neighboring cell, so that it is possible to improve the traffic of the neighboring cell. Therefore, it is possible to improve the total traffic of all cells in the area where the massive MIMO cell is located.

In an example, the step in which N users are selected from users, in the present cell, having the downlink data volume greater than the preset data volume includes the step described below. In a case where the load state is that no congestion situation occurs in the massive MIMO cell and the massive MIMO cell is relatively busy, the N users are selected from the users having the downlink data volume greater than the preset data volume in the present cell.

When the load state is that no congestion situation occurs in the massive MIMO cell and the massive MIMO cell is relatively idle, the N users selected from the present cell are not limited; the N users may be any N users, or may be N users having the downlink data volume greater than the preset data volume. When the load state is that no congestion situation occurs in the massive MIMO cell and the massive MIMO cell is relatively busy, N users are selected from users having the downlink data volume greater than the preset data volume in the present cell. When the load state is that a congestion situation occurs in the massive MIMO cell, users having the number of spatial division scheduling times greater than the preset number of times and the spatial division scheduling proportion greater than the first preset threshold in the present cell are ranked according to SE values from small to large, and the first N users are selected. In this manner, in a case where no congestion situation occurs in the massive MIMO cell and the massive MIMO cell is relatively busy, the selected users are N users having the downlink data volume greater than the preset data volume, so that the user quality of the first user migrated into the massive MIMO cell is improved, and thus the possibility of improving the traffic of the massive MIMO cell is increased.

In the embodiment, the indicator value of the first performance indicator of the massive MIMO cell is acquired first, and then the load state of the massive MIMO cell may be accurately determined according to the indicator value of the first performance indicator. The load state can reflect the busyness degree of the massive MIMO cell, and the load adjustment strategy includes one of the following: migrating the first user of the neighboring cell of the massive MIMO cell into the massive MIMO cell, migrating the second user in the massive MIMO cell into the neighboring cell, migrating the first user of the neighboring cell into the massive MIMO cell and migrating the second user in the massive MIMO cell into the neighboring cell, or maintaining the status quo. That is, the busyness degree of the massive MIMO cell can be adjusted through the load adjustment strategy, and the determined load adjustment strategy matching the load state matches the current busyness degree. Therefore, performing the load adjustment strategy matching the load state is conducive to adjusting the busyness degree of the massive MIMO cell to a better state, so that it is beneficial to exerting the advantages of the massive MIMO cell and it is possible to improve the traffic of the massive MIMO cell; further, it is possible to improve the total traffic of all cells in the area where the massive MIMO cell is located. Moreover, the correspondence between the load states and the load adjustment strategies is preset so that after the load state is determined, the load adjustment strategy matching the load state can be determined relatively quickly and then performed, which is simple and feasible.

The claimed invention comprises a load adjustment method, comprising:.

Second embodiment of the present application relates to a load adjustment method. The second embodiment is substantially the same as the first embodiment, and the main difference between the second embodiment and the first embodiment is that excellence levels of multiple candidate load adjustment strategies under the load state are preset, and the load adjustment strategy matching the load state for performing is determined according to the excellence levels. The flowchart is shown in <FIG> and includes steps described below.

Steps <NUM> to <NUM> are similar to steps <NUM> to <NUM> and are not repeated here.

In step <NUM>, excellence levels of multiple candidate load adjustment strategies under the load state of the Massive MIMO cell are queried, where an excellence level refers to how good and bad a load adjustment strategy is performed under the load state.

The load adjustment strategy here is similar to the load adjustment strategy in the first embodiment and is not repeated here. The excellence level may be expressed by numerical values, or may be expressed by various grades such as good and bad. In the present embodiment and the following embodiments, the excellence level is expressed by a numerical value; the larger the numerical value is, the more excellent the load adjustment strategy is, but not limited thereto. In an initial operation of the device, initial values of the excellence levels of the multiple candidate load adjustment strategies under different load states may all be <NUM>, or may be allocated different values according to practical experience; therefore, multiple candidate load adjustment strategies corresponding different load states may have different excellence levels, and it is necessary to query the excellence levels of the multiple candidate load adjustment strategies under a load state. For example, cases where s = <NUM>, s = <NUM>, s = <NUM>, and s = <NUM> refer to different load states, respectively, and cases where a = <NUM>, a = <NUM>, a = <NUM> and a = <NUM> refers to different load adjustment strategies, respectively. That is, the case where a = <NUM> refers to migrating the first user of the neighboring cell of the massive MIMO cell into the massive MIMO cell; the case where a = <NUM> refers to migrating the second user in the massive MIMO cell into the neighboring cell; the case where a = <NUM> refers to migrating the first user of the neighboring cell into the massive MIMO cell and migrating the second user in the massive MIMO cell into the neighboring cell; and the case where a = <NUM> refers to maintaining the status quo. Under different load states, the excellence levels of the multiple candidate load adjustment strategies are shown in the table below.

In step <NUM>, one candidate load adjustment strategy is selected according to the found excellence levels of the multiple candidate load adjustment strategies as the load adjustment strategy matching the load state of the massive MIMO cell, and the load adjustment strategy matching the load state of the massive MIMO cell is performed.

In an example, the step in which one candidate load adjustment strategy is selected according to the found excellence levels of the multiple candidate load adjustment strategies includes the step described below. A load adjustment strategy having the highest excellence level is directly selected from the found excellence levels of the multiple candidate load adjustment strategies, or the found excellence levels of the multiple candidate load adjustment strategies are ranked from high to low, and one load adjustment strategy is randomly selected from two load adjustment strategies having the top two excellence levels, etc. As described in the preceding examples, when the load state satisfies that s = <NUM>, the excellence levels of the multiple candidate load adjustment strategies are <NUM>, <NUM>, <NUM>, and <NUM>, respectively, and the load adjustment strategy a having the highest excellence level, that is, a = <NUM>, is directly selected.

In an example, the flowchart for the step in which the one candidate load adjustment strategy is selected according to the found excellence levels of the multiple candidate load adjustment strategies as the load adjustment strategy matching the load state of the massive MIMO cell and the load adjustment strategy matching the load state of the massive MIMO cell is performed is shown in <FIG> and includes steps described below.

In step <NUM>, a manner for selecting the one candidate load adjustment strategy is determined based on an ε greedy algorithm, where the manner includes random selection or selection according to an excellence level.

A random number x is generated first, where <NUM> ≤ x ≤ <NUM>. If x is less than ε, the manner for selecting the one candidate load adjustment strategy is determined as the random selection; if x is greater than or equal to ε, the manner for selecting the one candidate load adjustment strategy is determined as the selection according to the excellence level, where <MAT>. The load adjustment method is performed periodically, and T is the current number of times of performing. For example, T = <NUM>, and ε = <NUM>. If x is <NUM>, the manner for selecting is the random selection; and if x is <NUM>, the manner for selecting is the selection according to the excellence level.

In step <NUM>, according to the manner for selecting, the load adjustment strategy matching the load state of the massive MIMO cell is selected from the multiple candidate load adjustment strategies, and the load adjustment strategy matching the load state of the massive MIMO cell is performed.

If the manner for selecting is the selection according to the excellence level, a candidate value having the highest excellence level is selected from the candidate load adjustment strategies. For example, when the load state satisfies that s = <NUM>, the excellence levels of the multiple candidate load adjustment strategies are <NUM>, <NUM>, <NUM>, and <NUM>, respectively, and the load adjustment strategy a having the highest excellence level, that is, a = <NUM>, is selected. If the manner for selecting is the random selection, any candidate load adjustment strategy is selected.

The manner for selecting the one candidate load adjustment strategy can be accurately determined through the ε greedy algorithm, and the load adjustment strategy matching the load state is selected according to different selection manners. In this manner, the appropriate load adjustment strategy matching the load state can be selected accurately.

In the embodiment, in this manner, the determined load adjustment strategy matching the load state of the massive MIMO cell is an optimal load adjustment strategy under the load state, that is, a degree of matching between the load adjustment strategy selected in this manner and the current busyness degree of the massive MIMO cell is higher, so that the possibility of improving the traffic of the massive MIMO cell is increased.

Third embodiment of the present application relates to a load adjustment method. The third embodiment is substantially the same as the second embodiment, and the main difference between the third embodiment and the second embodiment is that an excellence level of the load adjustment strategy matching the load state, which is determined under the load state, is updated. The flowchart is shown in <FIG> and includes steps described below.

In step <NUM>, excellence levels of multiple candidate load adjustment strategies under the load state are found, where an excellence level refers to how good or bad a load adjustment strategy is performed under the load state.

In step <NUM>, an excellence level, determined under the load state of the massive MIMO cell, of the load adjustment strategy matching the load state of the massive MIMO cell is updated.

In an example, an adjustment value of the excellence level may be preset. The adjustment value of the excellence level plus an original excellence level is a new excellence level, and the new excellence level is updated as the excellence level, determined under the load state, of the load adjustment strategy matching the load state. For example, the preset adjustment value of the excellence level is <NUM>, the original excellence level is <NUM>, and thus the new excellence level is <NUM>; the new excellence level <NUM> is updated as the excellence level of the load adjustment strategy matching the load state, which is determined under the load state.

In an example, a new excellence level may be preset, and the new excellence level is directly updated as the excellence level of the load adjustment strategy matching the load state, which is determined under the load state. For example, the new excellence level is preset to be <NUM>, and the new excellence level <NUM> is directly updated as the excellence level, which is determined under the load state, of the load adjustment strategy matching the load state.

In an example, the flowchart for the step in which the excellence level, determined under the load state, of the load adjustment strategy matching the load state is updated is shown in <FIG> and includes steps described below.

In step <NUM>, an indicator value of a fourth performance indicator is acquired, where the fourth performance indicator includes a fourth performance indicator of the massive MIMO cell and a fourth performance indicator of a neighboring cell.

In step <NUM>, the excellence level, determined under the load state of the massive MIMO cell, of the load adjustment strategy matching the load state of the massive MIMO cell is updated according to the indicator value of the fourth performance indicator.

The fourth performance indicator may be one type of performance indicator or multiple types of performance indicators. According to the indicator value of the fourth performance indicator, the value of the fourth performance indicator is substituted into a preset formula to obtain an adjustment value of the excellence level through calculation, and the excellence level, determined under the load state, of the load adjustment strategy matching the load state is updated according to the adjustment value. When the excellence level of the load adjustment strategy matching the load state which is determined under the load state is updated, not only the fourth performance indicator of the massive MIMO cell but also the fourth performance indicator of the neighboring cell are taken into account, so that the accuracy of the updated excellence level is improved.

In an example, the fourth performance indicator includes the traffic Payloadpresent of the massive MIMO cell and the traffic Payloadneighb of the neighboring cell. The fourth indicator value is substituted into formula one and formula two. <MAT> <MAT> <MAT> represents the excellence level before updating, <MAT> represents the updated excellence level, <MAT> represents the traffic of the massive MIMO cell acquired within the latest preset time period, <MAT> represents the traffic of the massive MIMO cell acquired within the next preset time period, <MAT> represents the traffic, acquired within the latest preset time period, of a neighboring cell having an index value of n, and <MAT> represents the traffic, acquired with the next preset time period, of the neighboring cell having the index value of n. An evaluation weight βMM of the massive MIMO cell is equal to <NUM>, an evaluation weight βCluster of the area where the massive MIMO cell is located is equal to <NUM>, <MAT> represents the maximum value of excellence levels of multiple candidate values (that is, multiple candidate load adjustment strategies) of a target operation parameter of the device under the current state within the next preset time period, an initial learning rate a is equal to <NUM>, and a discount rate γ is equal to <NUM>.

In the embodiment, the excellence level of the load adjustment strategy matching the load state which is determined under different load states is continuously updated, so that the excellence level is more accurate; moreover, the load adjustment strategy matching the load state is determined every time according to the latest updated excellence level, so that the rationality of the determined load adjustment strategy matching the load state is improved.

Fourth embodiment of the present application relates to a server. As shown in <FIG>, the server includes at least one processor <NUM> and a memory <NUM> communicatively connected to the at least one processor <NUM>. The memory <NUM> is configured to store an instruction executable by the at least one processor <NUM> to enable the at least one processor <NUM> to perform the preceding embodiments of the load adjustment method.

The memory <NUM> and the at least one processor <NUM> are connected through a bus. The bus may include any number of interconnected buses and bridges. The bus connects together various circuits of one or more processors <NUM> and the memory <NUM>. The bus may also connect together various other circuits such as peripheral devices, voltage regulators, power management circuits, etc., which is well known in the art and therefore is not described here. A bus interface provides an interface between the bus and a transceiver. The transceiver may be one or more elements, for example, may be multiple senders and receivers, and provides a unit configured to communicate with various other devices over a transmission medium. Data processed by the at least one processor <NUM> is transmitted over a wireless medium through an antenna. The antenna also receives data and transmits the data to the at least one processor <NUM>.

The at least one processor <NUM> is responsible for managing the bus and general processing and may also provide various functions including timing, peripheral interfaces, voltage regulation, power management and other control functions. The memory <NUM> is configured to store data used by the at least one processor <NUM> in performing operations.

Fifth embodiment of the present application relates to a computer-readable storage medium configured to store a computer program. The computer program, when executed by a processor, implements the preceding method embodiments.

Claim 1:
A load adjustment method, comprising:
acquiring (<NUM>, <NUM>, <NUM>) an indicator value of a first performance indicator of a massive Multiple-Input-Multiple-Output, MIMO, cell;
determining (<NUM>, <NUM>, <NUM>) a load state of the massive MIMO cell according to the indicator value of the first performance indicator; and
determining and performing (<NUM>) a load adjustment strategy matching the load state of the massive MIMO cell, wherein the load adjustment strategy comprises one of the following: migrating a first user of a neighboring cell of the massive MIMO cell into the massive MIMO cell, migrating a second user in the massive MIMO cell into a neighboring cell of the massive MIMO cell, migrating a first user of a neighboring cell of the massive MIMO cell into the massive MIMO cell and migrating a second user in the massive MIMO cell into the neighboring cell, or maintaining a status quo;
wherein in migrating the first user of the neighboring cell into the massive MIMO cell, the neighboring cell is denoted as a present cell and the massive MIMO cell is denoted as a target cell; and in migrating the second user in the massive MIMO cell into the neighboring cell, the massive MIMO cell is denoted as a present cell and the neighboring cell is denoted as a target cell; and
the first user or the second user is determined in the following manner:
selecting (<NUM>) N users from the present cell, wherein N ≥ <NUM> and N is preset;
measuring (<NUM>) a second performance indicator of each of the selected N users in the target cell to obtain an indicator value of the second performance indicator; and
in response to the indicator value of the second performance indicator being greater than a preset indicator value of the target cell, using (<NUM>) a selected user having the indicator value of the second performance indicator greater than the preset indicator value as the first user or the second user.