DE4441925A1 - Method for determining call switching in a multicellular environment - Google Patents

Abstract

The decision to hand off from the serving cell to a neighbouring cell in a cellular communication's system including umbrella cells and microcells is taken by measuring the rate of change of a parameter of a signal from at least one neighbouring cell base station received at the mobile. According to the result, handoff to a microcell or to an umbrella cell may be appropriate.

Description

The present invention relates generally to a method for Determine a call switchover (handover, handoff) in a multicellular environment and particularly affects the Determination of call switches in a multicellular Environment, based on a rate of change of one parameter an incoming signal from at least one neighboring cell.

In a cellular environment is usually at any time exactly one cell for a mobile unit as a service cell determines which contains the base station from which the mobile unit is operated and calls received and transmitted can, and there are a number of neighboring cells. The operator Cell can also be called the cell opposite the mobile unit is on hold (camped on to). In a multicellular environment can cells with different Size so that a number of cells with the same size within a larger cell (umbrella cell) are located. The smaller cells inside the umbrella cell will be referred to as microcells. The microcells are in one Territory with high user population created to be larger Allow user capacity in the cellular system. The Microcells facilitate the reuse of frequencies at smaller intervals. Thus, a mobile unit can inside a micro cell and in an umbrella cell.

Typically, rural areas where there is only one small number of users exist, only in large cells can be divided since no large user capacity is required is. When the areas get bigger or the number of users increases in the cells, it is not possible with larger cells to cope with the increase in users. This is because there are not enough frequencies. Hence microcells created within the larger cells, and the larger cells len become umbrella cells. This allows reuse  of frequencies within the microcells. Such a micro cell technology improves spectral efficiency and increases it Cellular network capacity.

However, microcells have the following disadvantages. A disadvantage is that in microcell areas the number of Ge voice switching increases and thus the time available to make a call switching decision takes. For example, the presence of too many Mi Crocells in an area where fast-moving Mobile units are present, so that the mobile unit in a short time roams through a number of microcells and this to a number of call switches to be processed leads. An increasing number of call switches in a short time lowers the signal quality and leads to poor communication and, in extreme cases, aborted calls chen.

So there is a need for a fast and reliable procedures to determine when in a multicellular Environment a call switching must take place.

According to the present invention, a method for loading agree a call switch in a cellular commu nication system specified, in which at least one Mobilein communicates with a serving cell and at the the serving cell and the neighboring cells at least one Have umbrella cell and a variety of microcells. Each Cell has a base station. The procedure for determining whether the call switching from the serving cell to one Neighboring cell should take place, contains the steps of measuring a rate of change of a parameter on one at the mobile unit from at least one neighboring cell base station outgoing signal and determining a call switch depending on the measured rate of change.  

In a preferred embodiment of the invention, the Parameter a rate of change of a received signal level represents.

In an alternative embodiment, the parameter represents a rate of change of a power level control signal.

Preferred embodiments of the present invention will hereinafter with reference to the accompanying drawings explained in more detail. The drawings show in detail:

Fig. 1 a fast-moving mobile unit continues in a Multizellularumgebung;

FIG. 2 shows a mobile unit moving slowly in a multicellular environment; FIG.

Fig. 3 is a flow chart for a preferred method according to the present invention;

Figure 4 shows timing diagrams of signal levels for the mobile unit of Figure 1;

Fig. 5 shows time diagrams of signal levels for the mobile unit of FIG. 2.

In Fig. 1, a multicellular (or microcellular) environment is shown in which at least one umbrella cell (umbrella cell) 1 and a plurality of microcells 2 , 3 , 4 , 5 and 6 are present. Each cell contains a base station, which is typically located in the geographic center of the cell. Not all base stations are shown in FIG. 1. A base station typically determines the size and capacity of the cell. A communication system can have cells of different sizes as well as a mobile radio unit 20 , which is operated either by the base station 23 of the umbrella cell 1 or by a base station of one of the microcells 3 . Receiving service from a particular base station, meaning being able to receive and transmit calls, is also referred to as being on hold at the particular base station (being camped). When a mobile radio unit enters the multicellular environment, a decision must be made as to whether the service should continue to be of the current cell type or whether a call switching to a new cell type is necessary. The decision may depend on the speed of the mobile unit.

A distinction can be made between two cases when a mobile radio unit enters a multicellular environment or a transmission area. The mobile unit can move at high speed, as shown by the car 20 in FIG. 1, or it can move at low speed, as shown by the person 30 shown in FIG. 2. Both in Fig. 1 and in Fig. 2 it is assumed that the serving cell is the screen cell 1 and that a plurality of neighboring cells are micro cells 2 , 3 , 4 , 5 and 6 .

In Fig. 3, a flowchart is shown, based on which it can be decided whether a handover to another cell should take place with respect to the service or not. In a preferred embodiment, a parameter value received from at least one neighboring cell base station on the mobile unit is forwarded to the serving cell base station and measured for a period of time in step 51. A rate of change for the parameter of the neighboring cell is then calculated in step 53 at the serving cell base station.

In step 55, a maximum rate of change value is ge elects. The maximum value can simply be given by a given Value should be set, however it is more reliable if it is selectable and on variable parameters of the microcell system, such as capacity and cell size. The The maximum rate of the selected change in value is usually also depend on the number of call switches required,  when the mobile unit is passed on to a micro cell or is already in a microcell environment and stays there.

The rate of change for the parameter of the neighboring cell base station is compared with a selected maximum value of a change value in step 57. If the rate of change is greater than the maximum rate of the change value and if the serving cell is a micro cell, the service is switched to the screen cell in step 63, assuming that it has already been determined that the screen cell still has capacity available. If the rate of change is less than the predetermined maximum rate and the serving cell is a micro cell, then according to step 65 no further call switching is carried out. If the rate of change is greater than the maximum rate and the serving cell is an umbrella cell, no call switching is carried out and the service remains with the umbrella cell according to step 67. Finally, if the rate of change is less than the maximum rate and the service cell is an umbrella cell, the service is transferred to the micro cell according to step 69. Of course, Fig. 3 shows only a preferred embodiment of the process OF INVENTION to the invention so that the invention is not limited to this embodiment.

In a preferred embodiment of the present invention, a signal level received by the base unit of a neighboring cell from the mobile unit can be used as the parameter value (step 51). FIGS. 4 and 5 show ver resembling rates of change for the received signal level of the serving cell 1 and its neighboring microcells 2, 3 and 4 for a fast moving mobile unit 20 and a slow-moving mobile unit 30.

FIG. 4 shows signal levels from the serving umbrella cell 1 and the neighboring microcells 2 , 3 and 4 when the faster mobile unit 20 of FIG. 1 passes through the umbrella cell 1 from t0 to t1. FIG. 4a shows the signals received by the mobile unit 20 of the base station of umbrella cell signal level, when the mobile unit 20 drives through the umbrella cell in a period from t0 to t1. The received signal level of the serving cell 1 is kept approximately constant by power control commands. FIG. 4b shows the signal level received by the mobile unit 20 from the neighboring microcell 2 when the mobile unit 20 is moving from t0 to t1 for the same time as in FIG. 1. It should be noted that the mobile unit 20 does not move into the microcell 2 and thus receives a reasonably constant signal with a low rate of change. Similarly, FIG. 4d shows the signal level received by the mobile unit 20 from the neighboring microcell 4 when the mobile unit 20 is moving during the same time t0 to t1. Again, the mobile unit 20 does not move into the microcell 4 , and thus a reasonably constant signal with a low rate of change is obtained.

Fig. 4c shows the received at the mobile unit 20 of the microcell signal level 3, when the mobile unit for a time t0 moves to t1. In contrast to the neighboring microcells 2 and 4 , the received signal level changes considerably, which indicates a high rate of change. The mobile unit 20 has moved to the microcell 3, and in the short period from t0 to t1, the cell of the base station of the micro-3 received signal level has increased in a relatively high rate, indicating that the mobile unit at high speed in the microcell 3 moves. The serving cell base station 23 , which is located in the screen cell 1 in this case, can now decide that the call switch to the micro cell 3 should not take place since the mobile unit is moving at a relatively high speed and therefore presumably a number of call switches would have to take place in a short time if the microcells in the microcellular system operated the mobile unit. Therefore, it is more efficient to operate the rapidly moving mobile unit 20 from the base station 23 of the umbrella cell 1 .

FIG. 5 shows the signal levels received by the serving umbrella cell 1 and also shows the neighboring microcells 2 , 3 and 4 when the slower mobile unit 30 of FIG. 2 moves between t0 and t1. Fig. 5a shows the signals received from the serving cell signal level 1, the stungssteuerbefehle usually by Lei is kept constant. FIGS. 5b and d show the signals received by the mobile unit 30 from base stations of the adjacent micro-cells 2 and 4 signal level. Similarly, the rates of change are relatively low.

Fig. 5c shows the received signal level from the neighboring micro cell 3, when the mobile unit moves from t0 to t1. Since the Mo bileinheit 30 is actually moving into the microcell 3, it höht the signal received by the base station of the micro cell signal level 3, wherein the change in contrast to FIG. 4c is not made with a relatively high rate. Thus, the base station 23 of the operating umbrella cell 1 can decide to switch over to the microcell 3 for the slowly moving mobile unit 30 . Comparing FIGS. 4c and 5c, it can be seen that the rate of the received signal level for the faster mobile unit 20 is higher compared to the slower mobile unit 30 . Thus, according to the present invention, depending on the lower rate of change of a received signal level for a slow moving mobile unit, a call switching from an umbrella cell to a micro cell can be determined. Similar received signal levels are noticed when a call originates in a microcell (originates in a microcell). The majority of mobile units in a microcellular system are slowly moving mobile units and should therefore be operated by microcells.

A second embodiment of the present invention uses a rate of change of a power control level as a determination parameter. Similar to FIGS . 4 and 5, the rate of change of power control level signals received by a mobile unit from base stations of neighboring cells will change dramatically in a micro cell that the mobile unit passes quickly. Thus, a decision about a call switching from the base station of the serving cell depending on the rate of change of the power control signals, as received by the base stations of the neighboring cell at the mobile unit, can be made.

Although the process has been described as being for the Base station of the serving cell is suitable, the Ver drive also be implemented so that it is on the mobile unit is made, provided that these are intel has ligent building blocks. The procedure could also be at the Base station of the neighboring cell must be implemented, in advance sets the appropriate information to the base station of the night bar cell is forwarded. With the magnification taking place Modification of cellular systems can the present invention can also be implemented at control stations at higher levels.

In summary, the present invention provides a method for a microcellular communication system with microcells and Umbrella cells are available, with the slowly moving Mo units that use microcells and that move faster moving mobile units use the umbrella cells. In particular when a fast moving mobile unit has a microphone cell enters, it is necessary that the mobile unit knows the current cell type, namely an umbrella cell, is operated to the number of calls required to minimize circuits. Thus the number of conversations switching significantly reduced, so that the microcellular can be used efficiently. The present inven dung improves the reliability of call switching, which leads to lower call losses and less work for the Network.

Claims (5)

1. A method for determining a call switching of a mobile radio unit in a cellular communication system with a serving cell and a plurality of neighboring cells, wherein the serving cell and the neighboring cells have at least one umbrella cell and a plurality of micro cells and each cell has a base station, and the method determines whether the call should be switched from a serving cell to a neighboring cell and has the following steps:
Measuring a rate of change of a parameter from a signal received by the mobile unit from at least one neighboring cell base station ( 53 ); and
Determine a call switching depending on the measured rate of change. 2. The method according to claim 1 with the following further steps:
Selecting a maximum value for the rate of change of the parameter of the incoming signal ( 55 ); and
Switch to an umbrella cell if the rate of change of the measured parameter is greater than the maximum value and the serving cell is a micro cell ( 63 ). 3. The method according to claim 1 or 2, further comprising the following steps:
Selecting a maximum value for the rate of change of the parameter of the incoming signal ( 55 ); and
Switching to a microcell if the rate of change of the received signal level is less than the maximum value and the serving cell is an umbrella cell ( 69 ). 4. The method according to any one of the preceding claims, in which the parameter is a received signal level. 5. The method of claim 1, 2 or 3, wherein the parameter is a power level control signal.