DE102004043881A1 - Communications connection method for delivering a connection in a cellular radio communications system transmits broadcast signals in different frequency bands - Google Patents

Abstract

In a first radio cell (C3) on a network side, signals for a connection pass to a subscriber station (MS) in a first frequency band (DL1). In a second radio cell (C4) on the network side, a broadcast signal (S) is transmitted in the DL1 and received by the MS so as to deliver a connection for signals to be transmitted to the MS for a connection from the DL1 into a second frequency band (DL2). Independent claims are also included for the following: (A) A cellular radio communications system; (B) and for a method for assisting connection delivery in a cellular radio communications system; (C) and for a network station for a cellular radio communications system.

Description

The The invention relates to a method for handover in a cellular Radio communication system, a corresponding radio communication system, a method of assisting the handover in such a system and a corresponding network-side station.

In Radio communication systems is a communication between in usually mobile subscriber stations and the radio communication network via a Air interface. In cellular radio communication systems a plurality of network-side stations exist, often as Base station are called and the supply to each one Radio coverage area, the so-called radio cells serve. The known mobile standards, such as GSM (Global System of Mobile Communication) or UMTS (Universal Mobile Telecommunication System) are such cellular radio communication systems. Furthermore, cellular Radio communication systems also for example after a WLAN (wireless Local Area Network) standard.

In cellular radio communication systems raises the problem of Handover, when a mobile subscriber station from a radio cell in a moved adjacent radio cell. It is necessary that This cell change is detected and the subscriber station previously Radio resources are allocated in the first radio cell, according to the Change to the second radio cell resources of this second radio cell be assigned to. The subscriber station can then continue with the Wireless network communicate without an existing connection must be interrupted. In general, the decision is whether a subscriber station located in the coverage area of a new radio cell be based on measurements performed by the subscriber station from received broadcast signals of the new radio cell. Hangs further As a rule, this decision also depends on the reception quality with which the subscriber station is based receives the signals of the existing connection in the first radio cell. Determined for this purpose the subscriber station is a measure of the interference due to measurements Connection by other in the radio communication system emitted Signals.

One special problem arises when, as for the UMTS standard in its FDD variant (Frequency Division Duplex), in the future in addition to a first frequency band, the so-called core band, im Range 2 GHz also another frequency band, called extension band, in the range of 2.5 GHz. The extension band serves to provide additional transmission capacity, provided that the core band is already busy. Therefore, in many cases the Extension band not in the entire coverage area of the radio communication system be provided, but only in sub-areas, where with a high traffic is expected. In particular, this will be done during a Expansion phase of the radio communication system to be the case. Therefore, will the extension band usually not in all radio cells of the radio communication system used, but only in sub-areas, by individual groups each of adjacent radio cells are formed. On the edge of a such coverage area of the radio communication system in which in addition to the core band, the extension band is also available for communication, now creates a problem when a subscriber station in the extension band only the downlink (downlink) operates a connection while the associated uplink (Upward direction, from the subscriber station to a network-side station) in the core band is operated. Is this a subscriber station, at the same time only in a single frequency band can receive, so only has a high-frequency receiver, you would due to measurements made by this subscriber station in the extension band the reception quality in the edge area of the supply area, in which the extension band is available to conclude that no handover is necessary, because in this border area only a few Transmit signals in the extension band become. However, this does not take into account that the subscriber station, the more it moves into the edge area of the cover of the extension band, from the network-side station communicating with her more and more removed and thus has to increase their transmission power, for the communication for to maintain an existing connection. As the subscriber station but for their uplink uses the core band, it bothers itself other connections in the radio communication system, which also has its uplink in the core band operate, the more, the higher their Transmission power is. In the technical recommendation 3GPP TR 25.889 The UMTS FDD standard describes two solutions to this problem. One avoids the increase of uplink interferences by stricter ones Handover Thresholds for the Subscriber stations using the extension band for their downlink. This solution however, has the disadvantage of not having large parts of the extension band can be used and possibly one unnecessary number of handovers within the same frequency band take place in cells at the edge of the supply area of the extension band (especially if a soft handover area is in these cells near a base station is located).

The second solution described in TR 25.889, also described in US 2004/29532 A1, sees the implementation of measurements in different RRC states through the subscriber stations to possible areas increased Uplink interference to detect. This solution avoids the disadvantages of the first solution, in return, however the implementation Complex measurements by the subscriber station necessary and required about that addition, the implementation Interfrequency measurements, that is measurements in different frequency bands, for which the Subscriber station either have two receivers for different frequency bands must or in the so-called slotted- or compressed-mode of the UMTS FDD standard.

One further problem may be in the future occur when inside a larger radio cell, following a first radio communication standard is operated (for example UMTS-FDD) a smaller radio cell is arranged, which after a second radio standard (for example, WLAN) is operated. In this Case would be it desirable if it could be detected when a subscriber station, which is initially in the area of the large radio cell, however not located in the area of the small radio cell while one existing connection has moved to the area of the small radio cell, so that a handover from the big one can be done in the small radio cell.

Of the Invention is based on the object, a handover in the explained Cases too facilitate.

These Task is solved according to the independent claims. Embodiments and Further developments of the invention are the subject of dependent claims.

The inventive method for handover in a cellular radio communication system provides that in a first radio cell network side signals a connection to a subscriber station be sent in a first frequency band, that in a second Radio cell network side emitted a broadcast signal in the first frequency band and that due to the received by the subscriber station Broadcastsignals a connection transfer for the transmitted to the subscriber station Signals of the connection from the first frequency band of the first radio cell is caused in a second frequency band of the second radio cell.

Even though So the handover decision due to the by the subscriber station in the first frequency band received broadcast signal is hit, the handover takes place not within the first frequency band but from the first frequency band in the second frequency band.

The inventive method to support the handover in a cellular radio communication system provides that in one Radio cell in a first frequency band sent out a broadcast signal will that for the reception is provided by subscriber stations, wherein the Receiving the broadcast signal of a handover decision serves, and that in the radio cell traffic channels for the downlink only at least be supported in a second frequency band.

The the decision over a handover serving broadcast signal is thus transmitted in a different frequency band, as the traffic channels supported by the radio cell. Traffic channels are those channels in a radio communication system with which connections to subscriber stations supports that is called in which user information is transmitted.

The Method of handover and the procedure for support the handover have the advantage of having a subscriber station that already has a Connection in the downlink in the first frequency band maintains, despite a later one Handover the downlink to the second frequency band for preparation This handover must receive no signal in the second frequency band, but instead receive the broadcast signal in the first frequency band can. This means that in preparation for handover, "simple" subscriber stations can be used have only a single high-frequency receiver. Besides, they are no complex next to the reception of the broadcast signal in the first frequency band Measurements necessary to over a connection transfer to decide. Another advantage is that through the reduction the number of inter-frequency or inter-system measurements performed in other frequency bands, as the one in which currently has a connection to the relevant Subscriber station is operated, the battery operating time the subscriber station increases.

According to a development of the method for handover of the first radio cell to a first group of adjacent radio cells, at the edge it is located, and each support traffic channels in the first frequency band, while the second radio cell does not support traffic channels in the first frequency band. In one embodiment of the invention, the support the first and the second radio cell the UMTS FDD standard and the first frequency band is a so-called extension band and the second frequency band is a so-called core band for this standard.

To a development of the invention are before the handover signals transmitted by the subscriber station in the first radio cell receive the connection network side in a third frequency band and after the handover are transmitted in the second radio cell from the subscriber station Signals of the connection network side also received in the third frequency band. That means before and after the transfer of the connection the transfer takes place in the uplink in the same frequency band, for example in the core band of the UMTS standards.

To a second embodiment the invention supports the second radio cell has a different radio standard than the first radio cell, However, the broadcast signal of the second radio cell corresponds to the Radio standard of the first radio cell. Here, for example, the first radio cell a mobile standard (such as GSM or UMTS-FDD), while the second radio cell supports a WLAN standard. With the invention is it then possible a handover from the first radio cell of the first radio standard into the second radio cell of the second radio standard without that in preparing the handover another behavior the subscriber station is required, as in a handover between two radio cells, both of which support the first radio standard.

The second embodiment The invention is particularly advantageous if the second radio cell smaller than the first radio cell and is located within this is. Then it is during the movement of a subscriber station within the larger first Radio cell possible, due to the broadcast signal received from the subscriber station the second radio cell over a handover to decide.

Especially Cheap it is in both embodiments of the invention, when the broadcast signal has the same structure or has the same structure as other broadcast signals, as well serve the preparation of a handover and in the radio communication system be sent out by each one radio cell supplying the network side station. This leaves it matters that the preparation according to the invention the handover analogous to all other handovers within the radio communication system between two radio cells, so that to carry out the inventive method no adaptation of the subscriber stations is necessary.

If the first radio cell supports the UMTS FDD standard is It is therefore advantageous if the broadcast signal is on a common pilot channel (CPICH) according to the UMTS standard is in the first frequency band in the second radio cell network side about that In addition, only signals on a synchronization channel (synchronization channel SCH) according to this standard. These signals become with UMTS also for conventional Handovers used.

To a development of the invention, the broadcast signal with almost same range as the traffic channels of the second radio cell. This means that by the broadcast signal a "mark" of the second radio cell in its entire extent.

Should the broadcast signal only as a trigger for inter frequency or intersystem measurements Serve, it may be advantageous in several cells of the mentioned To emit markers for broadcasting of certain cells, which at least partially agree (e.g., in terms of a pilot signal). This will reduce the implementation effort reduced in the subscriber station. It may then u.U. Not already from the fact that a marking broadcast signal was received, to be closed to which marked Radio cell is. But as soon as a marking broadcast signal is recognized by the subscriber station, she is able to the marked cell targeted measurements in another frequency band as the one in which it is communicating (inter-frequency measurements) or even in another radio communication system, too using another frequency band (intersystem measurements).

are the cell mark serving broadcast signals per to be marked On the other hand, if different, can already by identification of the corresponding, received from the subscriber station broadcast signal be concluded in which marked cell the Subscriber station is currently located. This evaluation of the of Subscriber station received broadcast signals can either by the subscriber station itself or by network facilities (e.g. Radio network controller), to the corresponding information of the subscriber station via the be received from her received broadcast signal. Have several Such broadcast signals of different Zel len to be marked e.g. different scrambling codes, their distinction can be, for example based on these codes.

Alternatively, however, it may also be provided that the broadcast signal is only in the edge region the second radio cell is emitted, which faces the first radio cell. As a result, a "marking" only of the edge region of the second radio cell by the broadcast signal, but this can be targeted in the transition region between the first and the second radio cell, in which a handover is applicable, and thus emitted with lower transmission power.

By the broadcast signal is thus to a certain extent a "mark" of the second radio cell, which can be received by the subscriber station without much effort. It could For example, the subscriber station based on the received broadcast signal independently over one Handover decide from the first to the second radio cell. For most Mobile radio systems, however, the handover is based on a decision in the web. Therefore, according to an alternative embodiment of the invention, it is provided that the subscriber station informs the radio communication network that she has received the Broadcaast signal. If applicable, transmitted the subscriber station readings over the received broadcast signal and / or received via the broadcast signal Information to the network. Due to the message of the subscriber station is then the network will be able to recognize that the subscriber station is located in the supply area of the second radio cell and can therefore via a handover decide in the second radio cell.

The cellular according to the invention Radio communication system has means for carrying out the method according to the invention for handover on. In embodiments and further developments of the invention, it also has further means for execution the embodiments and Further developments of the method according to the invention. The inventive network-side Station for a cellular radio communication system has means for performing the inventive method to support the handover as well as its embodiments and further education.

The Invention will be described below with reference to FIGS Embodiments described in more detail. Show it:

1 frequency bands available for communication in a first radio communication system according to a first embodiment of the invention,

2A several radio cells of this first radio communication system,

2 B an alternative embodiment of the invention for the radio communication system 2A .

3 a plurality of radio cells of a second radio communication system, wherein the principle of 2A is applied,

4 three radio cells of a third radio communication system and

5 Frequency bands available for communication in the third radio communication system.

1 shows for a first exemplary radio communication system available for the communication between network-side base stations and subscriber stations frequency bands. The considered radio communication system is one according to the UMTS FDD standard. This has a core band in the region of 2 GHz, in which an uplink band UL and a downlink band DL2 separated from it by a band gap are arranged. The two frequency bands UL and DL2 are available in this embodiment in all radio cells of the radio communication system for communication. Furthermore, the radio communication system in some of its radio cells on another downlink band DL1, which is arranged in the planned so-called extension band according to the UMTS FDD standard in the range of 2.5 GHz.

2A shows in a first variant of the first radio communication system in a schematic diagram four adjacent radio cells C1 to C4, which are supplied by a respective base station BS1 to BS4. In other embodiments of the invention, each radio cell can also be supplied by a plurality of base stations, each supplying a sector of the radio cell. Above the reference numerals for the radio cells C1 to C4 in 2A Information about which frequency bands are supported in the respective radio cell can be found. For the first three radio cells C1 to C3, these are in each case the frequency bands UL and DL2 of the core band and the downlink band DL1 of the extension band. In contrast, only the two frequency bands UL, DL2 of the core band are supported in the fourth radio cell C4. In this case, "supported" means that traffic channels can be operated in the radio cells only in these frequency bands, via which user data are exchangeable with subscriber stations.

2A also shows a subscriber status on MS in the form of a mobile station to which a connection is already maintained within the third radio cell C3. Namely, the subscriber station MS communicates with the third base station BS3 in the uplink using the core band UL and in the downlink using the extension band DL1. During the existing connection, the subscriber station MS now moves in the direction of the fourth radio cell C4 (indicated by the arrow in FIG 2A ) and finally reaches the area in which it can receive both transmissions of the third base station BS3 and the fourth base station BS4.

This is the overlap area the two radio cells C3, C4.

The fourth base station BS4 supported Although no traffic channels in the extension band DL1, in which the subscriber station MS with the third Base station BS3 communicates, but it sends a broadcast signal S in the extension band DL1 off. This happens with a range, that with the extension of the radio coverage area of the fourth radio cell C4 corresponds. At the broadcast signal S, that is the fourth base station BS4 sends out a Common Pilot Channel (CPICH) the UMTS FDD standard. Furthermore sends the fourth base station BS4 with the same range another Broadcast signal S 'off that is a synchronization channel (SCH) according to the UMTS FDD standard. Both broadcast signals S, S 'are transmitted in the extension band DL1. These are the two signals that a subscriber station to prepare a cell change in a UMTS FDD system for Preparation of a handover receives. It allows Receiving the Synchronization Channel S 'of the subscriber station MS the subsequent reception of the common pilot channel S. The synchronization channel S 'according to the UMTS FDD standard serves the subscriber stations the scrambling code of the CPICH S signal. In other embodiments, too a third broadcast signal in the fourth radio cell to mark it be broadcast on the format of a BCCH (Broadcast Control Channel) according to the UMTS FDD standard and the subscriber station MS can also take the downlink frequency DL2 of the core band.

at shares an alternative embodiment the net over the third base station BS3 of the subscriber station the scrambling code of the cell mark CPICH S with. Then eliminates the need the charisma of the SCH S 'to Marking of the fourth radio cell C4 in the extension band.

A again sees alternative embodiment before that in the for the radio communication system applies a special broadcast signal S is defined, which only for marking according to the invention of radio cells in frequency bands not supported in these radio cells. This broadcast signal can then use a specific pilot signal a specific scrambling code. The same broadcast signal S would then transmitted in all radio cells to be marked C4. Once the subscriber station MS receives this signal, Lead it then inter-frequency or inter-system measurements, so that a Interfrequency or intersystem handover is possible.

The Subscriber station MS receives after reaching the overlap area between the two radio cells C3, C4, the two broadcast signals S, S 'in the same Extension band DL1, in which they already have the signals of their existing Connection from the third base station BS3 receives. The subscriber station MS evaluates the signals S, S 'received by it.

The subscriber station MS reports results of the evaluation of the received signals S, S 'to the third base station BS3, with which it currently communicates and goes into the so-called "compressed mode" of the UMTS FDD standard to inter-frequency measurements in the downlink band DL2 However, the performance of the inter-frequency measurements at this time can be omitted in other embodiments as well 2A was exemplified only for two of the base stations. The third base station BS3 transmits the information reported by the subscriber station MS about the broadcast signals S, S 'received by it and additionally the results of the inter-frequency measurements in the core band DL2 to the radio network controller BSC. The radio network controller BSC evaluates this information and recognizes that the subscriber station MS is now located at the edge between the fourth radio cell C4 and the third radio cell C3 and thus in the edge region of the group of radio cells C1 to C3 in which the extension band DL1 for traffic connections is available. Thus, the radio access controller BSC is able to decide on a connection transfer of the connection of the subscriber station MS from the extension band DL1 in the third radio cell C3 in the downlink band DL2 of the core band in the fourth radio cell C4.

2 B shows a part of the 2A according to a modification of the previously considered embodiment. In this modification, the broadcast signals S, S 'are not from the fourth base station BS4 itself, but from another network-side station B within the fourth radio cell C4. The further network-side station B is located near the edge of the fourth radio cell C4, on the side facing the third radio cell C3. The broadcast signals S, S 'emitted by the further network-side station B have only a range such that they are just reaching the edge of the third radio cell C3. In particular, the further network-side station B can broadcast the broadcast signals S, S 'only in the overlapping area with the third radio cell C3. It is thereby achieved that the broadcast signals S, S ', which merely serve to mark the edge of the coverage area formed by the three radio cells C1 to C3, are also broadcast only where they are responsible for a decision about a handover or recognition of the said connection Randes are necessary. Therefore, their transmission power can be compared with that in 2A be reduced illustrated case. The further network-side station lowers the two broadcast signals S, S 'like a bark (beacon). Other signals are not sent or received by her. It therefore serves only the "marking" of said edge region

3 shows for a second radio communication system according to the UMTS FDD standard, in which the in 2A illustrated principle is applied, a plurality of adjacent radio cells C, which are each supplied by a base station shown point BS. The principle of the invention is in the right part of 3 while in the left part of the 3 the state is shown without application of the invention.

In both parts of the 3 Four adjacent radio cells are graphically highlighted approximately in the middle, in which traffic channels can be operated both in the two frequency bands UL, DL2 of the core band and in the frequency band DL1 of the extension band. In all other illustrated radio cells, however, only the two frequency bands UL, DL2 of the core band are available. In the 3 The overlapping areas of the four radio cells which also support the extension band DL1 are shown hatched with the neighboring radio cells which do not support this frequency band. If a subscriber station MS now moves out of one of the four radio cells supporting the extension band DL1 in the direction of a neighboring cell which does not support this frequency band, the extension band DL1 in the downlink is used for the communication of this subscriber station, while the uplink is used in the uplink Band UL of the core band is used, it comes to the already described in the introduction of the description that actually due to increasing interference from this subscriber station MS in the uplink frequency band UL desirable connection handover fails.

In the right part of the 3 is now shown how according to the invention in each neighboring cell of the four extension band DL1 supporting radio cells that do not support the extension band DL1 (shown in plaid) by the respective base station BS corresponding to the fourth radio cell C4 in 2A in each case the two broadcast signals S, S ', namely a radio-cell-specific CPICH and a radio-cell-specific SCH are transmitted. In this way, it does not matter in which direction a subscriber station MS located within the four radio cells in which the extension band DL1 is supported moves away from the latter into one of the checkered neighboring cells. Regardless of this direction, this can be determined by 2A explained procedures are performed.

In the right part of the 3 It can be seen that the broadcast signals S, S 'transmitted according to the invention cause the actual extent of the radio cells in which the extension band DL1 is available to be reduced to the same range as that for their core band frequency bands UL , DL2 is the case. This ensures that the cell boundaries of the individual radio cells (as usual in the case of cellular systems) are also hexagonal (instead of round) at the edge of the coverage area of the extension band. The handover from the extension band DL1 of the radio cell C3 in the downlink band DL2 of the core band of the radio cell C4 is then carried out in the ideal case in the middle between the two base stations BS3, BS4 (s. 2A ).

4 In a further embodiment, a third radio communication system shows three radio cells C10, C11, C12. In this third radio communication system, the two larger radio cells C10, C11 support the UMTS FDD standard with respect to traffic channels, while the smaller radio cell C12 supports any WLAN standard with respect to traffic channels. The WLAN radio cell C12 has smaller dimensions than the UMTS radio cell C11 and is arranged within this.

5 shows for the third radio communication system 4 Frequency bands provided by their radio cells. The UMTS radio cells C10, C11 provide an uplink band UL3 and a downlink band DL3, while in the WLAN radio cell C12 an uplink band UL4 and a downlink band DL4 are provided.

In 4 are the reference numerals for the frequency bands from 5 entered next to the reference numerals of the respective radio cell C10 to C12. The UMTS radio cell C11 is powered by a base station on BS11 and the WLAN radio cell C12 supplied by a radio access point BS12. A subscriber station MS moves in the direction of the arrow from the UMTS radio cell C12 in the direction of the WLAN radio cell C12. In this case, the subscriber station MS already has a connection to the base station BS11, the two frequency bands UL3, DL3 of the UMTS radio cell C11 being used. Although the radio access point BS12 of the WLAN radio cell C12 does not support traffic channels in the downlink band DL3 of the UMTS radio cell C12. However, it transmits in this frequency band DL3, according to the 2A and 2 B , two broadcast signals S, S ', which in turn are a CPICH and a SCH according to the UMTS FDD standard. This again takes place with the same range as the extent of the WLAN radio cell C12.

The inventive method can in other embodiments for every Combination of a cellular system (here UMTS) and a system for one HotSpot supply (here WLAN) are used (for example WLAN Hot Spot in a GSM network). Hot spots are places with increased traffic, within a cellular communication system by additional network-side stations or base stations are supplied. there For example, the hot-spot system can also use the same standard belong to like the cellular system, but use different frequency bands. Thus, e.g. the hotspot use the extension band of UMTS-FDD, while outside Of hot spots only the core band is used.

If the subscriber station MS now moves into the coverage area of the WLAN radio cell C12, where it can receive both broadcasts of the base station BS11 and the radio access point BS12, it also receives the two broadcast signals S, S 'of the radio access point BS12 in the downlink band DL3 of the UMTS radio cell C12. According to the in 2A As already explained, the subscriber station MS evaluates the received broadcast signals S, S 'during the connection with the base station BS11 and reports information to the base station BS11 in this regard.

The base station BS11 and the radio access point BS12 in 4 are connected to a radio access controller BSC, to which the base station BS11 forwards the information of the subscriber station MS via the received broadcast signals S, S '. Like the radio access controller BSC in 2A this is then able to recognize on the basis of the communicated information that the subscriber station MS is now in the radio coverage area of the radio access point BS12 or in the WLAN radio cell C12. The radio access controller BSC can then decide on a connection transfer of the connection of the subscriber station MS of the two frequency bands UL3, DL3 of the UMTS radio cell in the frequency bands UL4, DL4 of the WLAN cell C12 and corresponding instructions to the base station BS11, the radio access point BS12 and the subscriber station Transmit MS.

A Variant of the embodiment sees in that the subscriber station MS after recognizing the broadcast signals S, S '(of which in other embodiments even one is broadcast) automatically records inter-system measurements, i.e. in the downlink band DL4 of the WLAN cell C12 performs measurements, and independently establishes a connection to the WLAN cell or a handover there performs.

In the exemplary embodiments considered here, the broadcast signals S, S 'each serve to "mark" a specific coverage area of the communication systems 2A . 2 B and 3 they serve to "mark" the edge of the group of radio cells of the system in which the extension band DL1 is supported 4 the broadcast signals S, S 'serve to "mark" the extent of the WLAN radio cell and enable a subscriber station MS already communicating according to the UMTS standard to transmit a connection to a radio cell of another on the basis of broadcast signals S, S' broadcast according to the same UMTS standard Radio standards.

In further education in the 1 to 3 illustrated embodiments, it is possible to automatically adjust the transmission power of the broadcast signals S, S ', depending on the load distribution between the core band and extension band of the own cell and the neighboring cell. It can thus be achieved that the fluctuating range in the core band, which results in different interference situations, can be compensated automatically in the extension band. For example, if radio resource management provides a strategy to achieve even distribution of downlink traffic in the core band and extension band within the extension band cells, then the neighbor cells would make the transmission power of their broadcast signals S, S 'proportional to the total transmit power adjust in the core band. The "marking" would thus be adapted to fluctuating expansions of the radio cells.

Claims (15)

Method for handover in a cellular radio communication system, in which - in a first radio cell (C3; C11), on the network side, signals of a connection to a subscriber station (MS) are transmitted in a first frequency band (DL1; DL3), - in a second radio cell (C4; C12) a broadcast signal (S) in the first frequency band (DL1; DL3) is transmitted on the network side and due to the subscriber station (MS a received signal to be transmitted to the subscriber station of the connection from the first frequency band (DL1; DL3) of the first radio cell (C3; C11) to a second frequency band (DL2; DL4) of the second radio cell (C4; C12) is initiated. The method of claim 1, wherein the second radio cell (C4; C12) in the first frequency band (DL1; DL3) does not support traffic channels. Method according to Claim 2, in which the first radio cell (C3) to a first group of adjacent radio cells (C1, C2, C3) belongs, at the edge it lies, and the respective traffic channels in the first Support frequency band (DL1). Method according to one of the preceding claims, in before the handover in the first radio cell (C3) emitted by the subscriber station (MS) Signals of the connection network side in a third frequency band (UL) are received - and after the handover in the second radio cell (C4) emitted by the subscriber station (MS) Signals of the connection on the network side also in the third frequency band (UL) are received. The method of claim 3 or 4, wherein the first Radio cell (C3) and the second radio cell (C4) the UMTS FDD standard support - and the first frequency band (DL1) a so-called extension band and the second frequency band (DL2) is a so-called core band of this standard. Method according to one of the preceding claims, in the second radio cell (C12) supports a different radio standard than the first radio cell (C11), but the broadcast signal (S) of the second Radio cell (C12) corresponds to the radio standard of the first radio cell (C11). Method according to Claim 6, in which the first radio cell (C11) a mobile radio standard and the second radio cell (C12) a Wi-Fi standard supported. The method of claim 6 or 7, wherein the second Radio cell (C12) smaller than the first radio cell (C11) and inside this is arranged. Method according to one of the preceding claims, in the broadcast signal (S) has the same structure as broadcast signals, which also serve the preparation of handovers and by any Network-side station of the radio communication system, each a radio cell according to a certain radio standard, be sent out. Method according to one of the preceding claims, in the first radio cell supports the UMTS FDD standard - and the Broadcast signal (S) is transmitted on a common pilot channel according to the UMTS standard and in the first frequency band (DL1, DL3) in the second radio cell (C4, C12) on the mains side In addition, only signals on a synchronization channel after this Standard transfer become. Method according to one of the preceding claims, in the broadcast signal (S) with almost the same range broadcast will, like the traffic channels the second radio cell (C4, C12). Method according to one of claims 1 to 10, wherein the broadcast signal (S) is emitted only in an edge region of the second radio cell (C4), which faces the first radio cell (C3). Cellular radio communication system - with funds a first radio cell (C3; C11) for transmitting signals of a connection to a subscriber station (MS) in a first frequency band (DL1; DL3) - With Means of a second radio cell (C4; C12) for transmitting a broadcast signal (S) in the first frequency band (DL1; DL3) - and with means to induce a handover for the to the subscriber station (MS) to be transmitted Signals of the connection from the first frequency band (DL1, DL3) of the first one Radio cell (C3; C11) into a second frequency band (DL2; DL4) of the second Radio cell (C4; C12) depending on from the broadcast signal (S) received by the subscriber station. Method for supporting handover in a cellular radio communication system, in which - in a Radio cell (C4; C12) in a first frequency band (DL1; DL3) Broadcasting signal (S) is sent out for the reception by subscriber stations (MS) is provided, wherein the reception of the broadcast signal (S) a decision about a handover serves, - and in the radio cell (C4; C12) traffic channels for the downlink direction only in at least a second frequency band (DL2; DL4). Network-side station (BS4; BS12) for a cellu A radio communication system - comprising means for transmitting a broadcast signal (S) in a first frequency band (DL1; DL3) intended for reception by subscriber stations (MS), which makes a decision on a handover, - which only means for supporting traffic channels for the downlink in at least a second frequency band (DL2; DL4).