SE519739C2 - Controlling cell load in e.g. GSM networks supporting high speed circuit switched data (HSCSD) services, by determining signal strength for each mobile unit and neighbouring base stations - Google Patents

Abstract

The signal strength value (Gji) is determined for each mobile unit (i) and the base station (i) neighbouring the favourite base station (k) associated with the mobile unit. For each mobile unit a number (Ai) of base stations is calculated for which Gji is greater than a threshold value ~a, then a number (B) of base stations giving the highest increase in data throughput is selected from (Ai), and then the mobile-base station pair giving the highest total data throughput is selected from (B), and the mobile unit is transferred to the chosen base station in this pair.

Description

IQ '_11 30 35 519 739 2 gaps. This limits the number of time slots, forcing the operator to reuse its frequencies a number of times within the operator's coverage area. The technique in cell planning is to divide the drawing area into a number of cells, each cell having a base station that serves all the mobiles located in the cell's drawing cell (see Figure I). Each cell is assigned a number of frequencies. lirekvensernzi is reused in cells that are at a certain distance from each other so that the interference problem is minimized. The interference is a disturbance caused by other users by using the same frequency or medium. The closer to the source of interference, the lower the quality. an easy number of cells or base stations are controlled by a control unit called a "Base Station Controller" (BSC). The increase in the number of users in a mobile system and the limited number of frequencies available gives rise to a capacity problem. The capacity problem is exacerbated by the fact that the mobile users are mobile in the system, which makes the geographical problem of the problem unpredictable. The cell phones that arrive at a cell and find that: bad resources in the cell are occupied are blocked. The blocking situation in a mobile system varies from cell to cell and varies over time. Introducing HSCSD means an additional strain on the cells. lföreliggziiidc iippfiiiiiing deals specifically with capacitctsprobleinct which is tipped when llSCSl) is introduced. llppfiiiiiiiigeii not only solves the capacity problem titanium iiietlföi 'an increase in data speedlieteii or the data throughput (throughput) for llSCSD iiio cars and increases the load spread in the system. In the previous technology, attempts have been made to solve the capacity problem in various ways. some way is to refer iiiobileriia in a cell to the neighboring cells if these are of good enough quality. This method is used in today's GSM systems. Two functions that are used to reduce the barrier in the system and to spread the traffic load over a large area are so-called "Directetl Retry" and "Cell Load Sliariiig". Today, the functions are used only to handle mobiles that need only one time slot ("Single Slot"). "Cell Load Sharing" is used during an ongoing speech as part of the handlover algorithm.

In GSM systems, cell selection takes place with the help of a number of parameters set by the telecom operator. Cell selection in "Idle Mode" is called "Cell Selection" and is controlled by a number of criteria, called C1 and C2 criteria, which are controlled by a number of parameters set by the operator. ) is controlled in the same way by a number of parameters and determines when a mobile that is tipped (Connected Mode) should make eellbyte. the throughput of data because lörbiiitlelseriizi (base station - mobile pairs) uses several time slots, but this is only possible to a certain level. and reduce the blocking probability in the system by spreading the traticle load. iniiig (throughput) with reasonably low interference. In today's GSM system, load control is used to reduce the blocking probability in a loaded network. Previous studies on cell load control have focused on voice traffic and only taken into account the propagation conditions and the traffic load in the network. With the introduction of HSCSD, you will encounter more or less situations where different users need different resources and when consideration is given to what the resource situation in the network looks like.

The invention provides a method for taking into account the specific resource sittizititiiieii in the network. The invention solves the capacity problem by subdividing a cell into graob cells. In particular, the data level of llSCSD mobiles can be increased due to better channel utilization of the channels and reduced trunking loss.

SUMMARY OF THE INVENTION Thus, the present tip provides a method of load control in a cellular telecommunications and data communication system comprising a plurality of cells each served by a hash station and a plurality of mobile cars in each cell. The base stations are stiffened by a styrene line and each mobile i is tippktvjiplztd to or has a favorite list station k.

According to the invention, signal strength values Gji are collected for each mobile i and neighboring base station j to the base station k. > et. where ot is a threshold value. For each mobile 1 ', a hash station is selected from Ai which gives the highest increase in total data flow rate to form a nine-length B. From the inlet B the nine-car base station pair is selected which gives the highest increase in total data throughput. llandover is ordered by the selected mobile to the selected base station in the mobile base station pair. preferably, the increase in the total data throughput is calculated based on the handover available capacity of the potential base station in each mobile bus station pair plus the handover released capacity in base station 1r. (5) is defined in appended claims 1, while advantageous teachings are set forth in the dependent claims.

Brief description of the drawings can be described in detail below with reference to the accompanying drawings in which: Figure 1 is a diagram generally showing a telecommunication system and Figure 2 is a diagram showing an area around a base station where candidates are to be found. handover or eellval in accordance with the present ttppliiiiiing.

A detailed description of preferred embodiments of a generally mobile telecommunication system is shown in Figure 1. The telecommunication system may be a GSM system, but the invention is not in principle limited to this standard. A control unit BSC controls a number of base stations, each serving a cell. The mobile phones have a number of mobile phones (not shown), some of which are connected in ongoing calls, while others are only in contact with the system during calls.

The method according to tippliiiiiiiigen can be used when one or more cells are loaded and when there are free resources in neighboring cells that can take part of the load to which the cells are exposed. The method can be used both when connecting voice and data sanitals and during sanitaletis gangs. The method can be used in situations where one or more nine cars in the network have used more channels than are available in the base station.

The method can be used for both single slot and mttltis slot machines. Single slot mobiles are mobiles that request a time slot on arrival at the system and inultis slot machines are the mobiles that request more than one time slot on arrival on the system. The method can be applied when the number of available time slots in a cell is less than the total number of time slots that all the inobile in the cell requests.

The object of the invention is that in the event of traffic increase or blockage, the method shall be applied to reduce the blocking probability in the system and to increase the data speed and thus throughpttt in the system.

The method may be recurring at a certain interval set by the operator or may be dynamic when the need arises. The method is based on data on the cell environment of each cell and the radio environment of the inbound vehicles and their need for data rate.

In the GSM system, each mobile transmits its received signal strength from the neighboring base stations and its own cell and reports this on to the base station, which forwards it to the control unit BSC or higher units. Link quality received 1 () 35 \ C) 519 73 s from the cells can also be used. The term network means that which consists of base stations. the BSC control unit and other higher units in the GSM architecture. The network also provides information on all mobiles located in the network's scrvice area and in particular information on the mobiles' data rate needs. lltgåentle from this information, the network could refer or force certain inobilei 'to cells other than the so-called favorite cell. Normally, the favorite cell is the cell that is best suited to connect to, such as the cell that has the highest perceived signal strength. The situation may also be that the mobile is already connected to a cell.

The method should be used at the cellular level and applied to all mobiles in the cell.

The signal strength values of the mobiles to the network are used as signal strength values. Let (iii be the measured signal strength value (obtained according to any method) ntcllzlii base stationcnj and mobile i for all base stationcrj which are neighbors of the base station with index k.

We assume that the mobile is connected to base station k or has base station k as the favorite cell. zill the cell that the mobile connects to in normal cases. Gki represents the measured signal strength value at mobile in the favorite cell k belonging to the base station k.

The method uses a threshold value set by the operator. ot is the threshold value where all signal strength quiirtleti (iii> ot gcr a positive result. otherwise negative. (lpcratoren must be able to set ot at cell level.

The adjacent base station with index] to the base station k and whose Gii is greater than ot, constitutes a good candidate for mobile i and is part of a candidate-authorized Ai.

This assumes that (jki is greater than ot. / \ I is the amount of all neighbor orj to cell k that satisfies the condition that Gii is greater than ot for mobile i. Loan amount Ai is generated for each mobile i in the cell.

Neighbors or are the cells that are geometrically close to the considered cell k and that are defined according to a list that the network informs the mobile about.

The Gii> ot relationship will describe an area between the base stations. which in reality is highly irregular, where the method will search for mobiles that are suitable for eellbyte or handover. This is illustrated in Figure 2. where the shaded dial shows where the relation Gia> ot applies to certain base stations around the base station k. The parameter ot can also be used by the telecom operator to decide whether the method should be used or not. When ot is set infinitely large, no load control takes place by means of the method. When ot is set very low, all neighboring cells become "favorite cells" for connecting the mobile in.

The parameter ot is also a kind of protection in order not to impair the in-car's link quality and should be set to a reasonably high value so that the link quality and interference are not significantly affected. The quality of the link is that which can be measured with bit error ratio 10 l5 3 0 35 519 739 6 or similar dimensions.

For each mobile in the cell, you thus get the amount of Ai that contains the neighbor station that, together with the inobileii, fulfills the condition (iii> ot. the potentially new base stations belonging to the set Ai.

In addition, it is examined how many channels y, which can be assigned to other mobiles in the base station k to which the mobile in question is currently connected (serving cell), if the mobile makes an eel exchange or handover to the candidate base station under consideration. This is a measure of the released capacity in the cell k that can be used by other mobiles in the cell k in the event of an exchange of the mobile i to the new base station.

The free capacity and the released capacity are summed up (x + y) and: nan gets the total number of channels that can be allocated in the network given that the mobile is connected to the new base station, ie we study the increase in the total data throughput (throughput). (Ükniiigen of the total datagcnomströniiingen is studied lör all base stations in the candidateåiiiigden / \ i lör mobil i lör to then víiljzi out the base station that gives the largest increase of (latahzistiglictcii. This base station [MAX (Ai) | is the one that gives iiiaxii eellbyte of mobile i. This is done on all mobiles ii in the considered cell k.

Let B be inåiiigdeii of all base stations of [MAX (Ai)] which provide inaxiiiiztl datagenoiiiströnning lör each mobile in the cell being considered. If there is a mobile in linn llera candidate stzitioiiei 'which gives inaxiiiial increase of the data throughput, one chooses for each mobile the candidate base station which achieves the highest (iii, ie the one which has the highest niottzigeii signal strength.

From the set B, then select the base station / pair of cars that give the inaxiiiial (increase in data throughput [MAX (Ai)].) If there is more than one base station / pair of pairs in set B that have the same maximum data rate or throughput, it is necessary to pick out a final mobile from the set B. The selection can be made randomly or the pair that gives the highest signal strength Gji.

Finally, the network commands the selected mobile in the mobile base station pair to do cell reselection or handover to the designated base station in the pair.

The network commands the inobile to make a change to the designated cell by, for example, dynamically changing the parameters for "cell selection" when selecting a cell in "Old Mode" or by using the C1 or C2 criteria or by dynamically changing hands (iver- the parameters at "Connected Mode".

If the cell to which the mobile phone would actually like to be connected (original favorite cell) is again given time slots, the mobile phone which has been ordered to make a cell change or handover can again be switched to it after a certain period of time. .

In summary, the invention is a useful tool for radio resource management, especially for HSCSD. The invention can of course also be applied to other cellular systems which have similar conditions. The invention is also not limited to the GSM standard. The invention can be used to relieve small cells or large cells in a network with a hierarchical cell structure or to relieve a part of a dual band network or networks that use several frequency bands.

The scope of the invention is limited only by the following claims.

Claims (7)

10 15 20 25 30 35 519 739 8 PATENT REQUIREMENTS A method of load control in a cellular telecommunication and data communication system comprising a number of cells each served by a base station and a number of mobiles in each cell, the base stations being controlled by a control unit (BSC), and each mobile i being connected to or having a favorite base station k for communication on one or more channels, characterized by the steps: that signal strength values Gji for each mobile i and neighboring base station j to the base station k are collected; that for each mobile in a set Ai of base stations are formed for which Gji> ot, where ot is a threshold value; that available capacity is examined, expressed in the number of channels x mobile i can be assigned at a potential handover of mobile i to the respective base station in Ai; that released capacity is examined, expressed in the number of channels y that can be assigned to other mobiles in base station k at a potential handover of mobile i to the respective base station in Ai; that for each mobile in a base station is selected from A; giving the highest value of the sum of free capacity x and released capacity y, to form a quantity B; selecting from the set B the mobile base station pair which has the highest value of the sum of free capacity x and released capacity y, and thus gives the highest increase in total data throughput; and ordering handover of the selected mobile to the selected base station in said mobile base station pair. Method according to claim 1, characterized in that if in the selection of base station from the set Ai more than one base station gives the same increase of the total data throughput, the base station is selected which has the highest signal strength value Gji. Method according to Claim 1 or 2, characterized in that if in the selection of mobile base station pairs from the set B fl more than one mobile base station pair gives the same increase in the total data throughput, the pair having the highest signal strength value G1-, or a pairs are selected at random. Method according to one of the preceding claims, characterized in that the threshold value ot is variable and is set by a telecom operator. Method according to one of the preceding claims, characterized in that the load control is carried out at regular intervals set by a telecom operator. 519 759 ”i Method according to one of the preceding claims, characterized in that the load control is carried out dynamically when required, e.g. based on the traffic load of each cell, the radio environment of the mobiles and their need for data rate. Method according to one of the preceding claims, characterized in that handover is ordered by dynamically changing handover parameters.