WO2001063953A1

WO2001063953A1 - Method for implementing a hard handover process in a radio telephone system

Info

Publication number: WO2001063953A1
Application number: PCT/DE2001/000712
Authority: WO
Inventors: Bernhard Raaf; Christian Senninger
Original assignee: Siemens Aktiengesellschaft
Priority date: 2000-02-24
Filing date: 2001-02-23
Publication date: 2001-08-30
Also published as: EP1258164A1

Abstract

The invention relates to a radio telephone system, especially a UMTS radio telephone system, wherein the frame (m+1) transmitted during a hard-handover between a mobile station (MS) and a first base station (BS1) which is momentarily responsible for communication with the mobile station (MS) and/or between a base station (BS2) which will become responsible for communication with the mobilie station (MS) in the future is transmitted in compressed mode in order to use the transmission gaps occurring as a result of the compressed mode for implementation of a hard handover process .

Description

description

Method for carrying out a hard handover process in a mobile radio system

The present invention relates to a method for performing a hard handover process in a mobile radio system according to the preamble of claim 1.

If a mobile station moves out of the coverage area of its base station, the connection must be made via another base station. The handover from a base station to another base station is called a handover. The handover (HO) is a very time-critical process in mobile radio systems, since the continuity of the current connection must be guaranteed.

In Fig. 5 two base stations BS1 and BS2 are shown as an example, between which a handover process is to be carried out, it being assumed below that a subscriber with a mobile station MS is away from a radio cell for which the mobile station BSl is responsible, m a radio cell for which the mobile station BS2 is responsible moves. The switching of the connection between the base station BS1 and the mobile station MS to the base station BS2 is controlled by a switching center SC ('Switchmg Center'). Furthermore, the uplink transmission directions (from the mobile station to the corresponding base station) and the downlink transmission directions (from the corresponding base station to the mobile station) are shown in FIG. 5.

With regard to the implementation of handover processes, a distinction is made between different types of handover, which essentially differ in the mode of operation of the handover algorithm used in the respective mobile radio system. In the case of a so-called soft handover (SHO), a connection to the new base station is established at the same time as the existing connection with the currently responsible base station. For the example shown in FIG. 5, this means that the same information is sent to the mobile station MS during this period of time via the base stations BS1 and BS2. The mobile station MS again receives signals from both base stations BS1 and BS2 this time and can use both signals. If the signal of the new base station BS2 is completely received by the mobile station MS, the switching center SC can abandon the old base station BS1 and switch completely to the new base station BS2, as a result of which the soft handover process is completed.

With the help of a soft handover, data losses can thus be avoided during the handover process, but this requires a relatively high outlay, since the mobile station occupies two transmission channels simultaneously for a short time and therefore the possible subscriber capacity of the base stations is reduced ,

In the case of a so-called hard handover (HHO), on the other hand, there is a 'hard' switch from the currently responsible base station or radio cell to the new base station or radio cell. The effort required for this is significantly less than in a soft handover process, since the mobile station does not simultaneously occupy two transmission channels from different base stations.

A problem associated with a hard handover, however, is the fact that the hard switchover from the currently responsible base station to a new base station usually results in data losses during real-time data transmission, for example in the transmission of voice data result in a brief interruption in the received and sent voice information.

FIG. 7 shows a representation of a hard handover process from the base station BS1 shown in FIG. 5 to the base station BS2, in particular the time sequence of the respective uplink and downlink connections between the respectively active base station and frames m or m + 1 transmitted to the mobile station are shown at the time of the hard handover.

In the conventional hard handover process, a seamless transition from the base station BS1 to the base station BS2 is not possible.

Assuming a mobile station MS with only one frequency synthesizer, the frequency synthesizer would have to remain on the frequency pair of the uplink and downlink of the old base station BS1 until the entire frame no. M has been sent to the base station BS1 via the uplink. Only then can the frequency synthesizer switch to the corresponding uplink / downlink frequency pair of the new base station BS2. However, this has the consequence that the frame number m + 1 sent via the downlink of the new base station BS2 cannot be received from the beginning by the mobile station MS, so that the entire content of this frame may be lost. Should the mobile station receive the downlink of the new base station BS2 as shown in FIG. 7, the mobile station can completely receive the uplink frame no. M on the frequency of the base station BS1 and the downlink frame no. On the frequency of the base station BS2. Send m + 1 completely, but the data transmission is delayed by at least 1024 chips, whereby these considerations do not take into account the time required to switch over the frequency of the frequency synthesizer of the mobile station, which can be up to 1.2 ms. The present invention is therefore based on the object of proposing a method for carrying out a hard handover process in a mobile radio system, it being possible for data losses during the hard handover process to be avoided or at least significantly reduced.

This object is achieved according to the invention by a method having the features of claim 1. The subclaims define advantageous and preferred embodiments of the present invention.

According to the invention, at the time of a hard handover process between the mobile station and the old base station, which is responsible for communication with the mobile station before the hard handover, and / or between the mobile station and the new base station, which after the hard handover should be responsible for the communication with the mobile station, transmit a frame in the so-called 'compressed mode'. Preferably, both a frame between the mobile station and the old base station and a frame between the mobile station and the new base station are transmitted in the 'compressed mode' at the time of the hard handover process. The 'Compressed Mode', which is applied in particular to both the downlink and the uplink, creates a transmission gap in the respectively compressed frame, which can be used for the hard handover. In particular, the required frequency switching can be carried out during this transmission gap in the case of an intermediate frequency handover. Furthermore, the transmission / reception power can be set with respect to the new base station and the required chip synchronization can be carried out during the transmission gaps. Likewise, processing (for example decoding) of the received frame is already possible during the transmission gaps.

By using the 'Compressed Mode', the handover procedure is shortened and it can be especially with a best frame synchronism between the old base station and the new base station, data losses during the hard handover process can be avoided.

In order to bring about the synchronization required for the handover between the mobile station and the new base station, the mobile station can use a pilot bit sequence continuously transmitted by the new base station, in particular in the case of UMTS the CPICH channel ('Common Pilot Channel'), for synchronization to the downlink the new base station.

In order to synchronize the new base station with the uplink of the mobile station, it is proposed that the mobile station use a transmission gap specially provided for this purpose during the transmission gap caused by the compressed mode

Uplmk synchronization signal is sent, which can then be evaluated for Uplmk synchronization by the new base station. This uplmk synchronization signal can in particular be the PRACH preamble originally intended for the RACH channel ('Random Access Channel')

Act code ('Physical Random Access Channel'). Furthermore, it is also possible for a complete control channel ('Dedicated Physical Control Channel ¹ , DPCCH) to be transmitted during the transmission gap both from the mobile station and from the new base station during the transmission gap, which in particular contains power setting information (TPC bits,' Transmit Power Control ') for the respective receiver, so that not only the synchronization can be brought about, but also the transmission power of the mobile station and the new base station can be optimized before the actual data transmission between the mobile station and the new base station begins.

The invention is explained in more detail below with reference to the accompanying drawing on the basis of preferred exemplary embodiments. 1 shows an illustration to explain the principle on which the present invention is based,

2 shows an illustration to explain a first exemplary embodiment of the invention,

3 shows an illustration to explain a second exemplary embodiment of the invention,

4 shows an illustration to explain a third exemplary embodiment of the invention,

F g. 5 shows a simplified block diagram of a mobile radio system according to the invention,

6 shows a representation for explaining the frame structure in the 'compressed mode', and

FIG. 7 shows a representation to explain the implementation of a hard handover process according to the prior art

The present invention is explained below using a mobile radio system in accordance with the so-called UMTS mobile radio standard ('Universal Mobile Telecommunication System'). However, the invention is generally applicable to mobile radio systems in which a compression mode or 'compressed mode' described in more detail below is provided.

According to the current state of UMTS standardization, it is provided that the transmitter of the mobile radio system is occasionally operated in a mode referred to as 'slotted mode' or 'compressed mode', in which case the information to be transmitted is transmitted to a receiver within certain frames in a compressed form are transmitted in order to obtain a blanking interval with one or more so-called 'idle slots' in the corresponding compressed frame, the Blanking interval of information bits is free. For the compression, the information must be transmitted in a shortened time interval.

The principle of compression is shown schematically in FIG. 6, with several sequentially transmitted frames being shown, each of which has an identical frame duration. According to the UMTS standard, each frame comprises 15 time slots and has a frame duration of 10 ms. With regard to the second frame shown in FIG. 6, the 'compressed mode' is used, ie the information is transmitted in this frame in a compressed form, so that a transmission blanking interval ('idle period' or 'idle time') with several 'idle slots ^1' occurs where no information is transmitted. As is also shown in FIG. 6, the transmission power can be increased during this frame operated in the 'compressed mode' in order to achieve a transmission quality which is not impaired by the 'compressed mode'. The compressed frames can occur periodically or as a result of a command initiated by the mobile radio network.

So far, the 'Compressed Mode' has only been used to enable the mobile station to carry out measurements of radio cells of other frequencies.

According to the invention, on the other hand, it is provided to use the 'compressed mode' for carrying out a hard handover process.

With the 'Compressed Mode', the 15 tent slots of a frame can be compressed into up to eight time slots, while the mobile station neither transmits ('Uplink Compressed Mode') nor receives in the resulting blanking interval or 'Idle Time' of the remaining seven time slots (' Downlink Compressed Mode '). The 'Compressed Mode' allows time during a hard handover process for the frequency switching ('Frequency Switchmg') or deco dation of the received frame etc. can be obtained without losing the data transmitted in the uplink and downlink. In addition, the 'idle time' can be used for synchronization purposes or for power management, ie for setting the transmit and receive power.

The principle on which the invention is based will be explained below with the aid of the illustration in FIG. 1, it being assumed, analogously to FIGS. 5 and 7, that a hard handover from the base station BS1 to the base station

BS2 should be carried out. The illustration of FIG. 1 therefore corresponds fundamentally to that of FIG. 7, so that only the differences that are essential for the present invention are discussed below.

In the hard handover process shown in FIG. 1, it is assumed that the frames of the base stations BS1 and BS2 are received by the mobile station MS in synchronism with one another.

At the time of the hard handover, the base station BS1 responsible before the hard handover sends and receives the last frame no. M in the 'compressed mode'. The blocks shown in Fig. 1 each symbolize the compressed frames. As shown in FIG. 1, the first time slot of the transmission gap ('Transmission Gap', TG) should be the ninth time slot (ie time slot No. 8) and the length of the transmission gap ('Transmission Gap Length', TGL) comprise seven time slots. The base station BS2, which is to be switched to, also transmits and receives the first frame no. M + 1 in 'compressed mode' at the time of the hard handover, with the transmission gap being placed at the beginning of the compressed frame and ideally as in Fig 1 shown should start with the first timeslot (timeslot # 0) of the compressed frame # m + 1 and should comprise seven timeslots. If the 'Compressed Mode' shown in FIG. 1 and described above with TGL = 7 is used, 14 * 2560 -

1024 chips = 34816 chips in order to switch from the old base station BS1 to the new base station BS2, one chip corresponding to a time period of approximately 0.26 μs. The uplink is sent by the mobile station MS with a time delay of 1024 chips to the received downlink. The remaining time of 34816 chips will be a little shorter in reality if inaccuracies in the measurement of the difference in time ('Observed Time Difference Of Arπval', OTDOA) and the time discretization when transmitting to the respective base station are taken into account. For the following considerations, it is assumed that the inaccuracy in the measurement of the transit time difference comprises 20 chips, which corresponds to about 2 km, while with regard to time discretization it is assumed that only a maximum of 512 chips is used to quantize the spreading factor used for the channelization codes is to maintain the orthogonality of the channelization code ('Channelization Code'), so that there is a duration of 34816 Chιps-20 Chιps-256 Chιps = 34540 chips for the time remaining for switching from the base station BSl to the base station BS2.

The duration of the approximately 30,000 chips = 7.8 ms' idle time 'can be used as a frequency switchover time in the case of a handover between base stations operating at different frequencies (' Inter Frequency Handover). Furthermore, this idle time ^{1 can be used} for power settings, for chip synchronization and / or for processing, ms-specific decoding, the received frame, etc.

Of course, transmission gaps with different lengths can also be used for the individual frame, so that correspondingly different values result for the time available for the measures described above. Furthermore, it is sufficient if only either between a compressed frame is transmitted to the old base station BS1 and the mobile station MS or between the new base station BS2 and the mobile station.

To illustrate the principle on which the invention is based, two points in time t1 and t2 are shown in FIG. 1, the switchover or handover process at point in time tl (ie with the first time slot of the transmission gap from the mobile station MS to the old base station BS1. th compressed uplink frame no. m) begins and is completed at time t2 (ie with the last time slot of the transmission gap of the compressed downlink frame no. m + 1 sent from the new base station BS2 to the mobile station MS).

So that a synchronization of the mobile station MS with the downlink of the base station BS1 or BS2 currently communicating with the mobile station MS is possible, each base station continuously transmits the so-called 'Common Pilot Channel' (CPICH), which contains so-called pilot bits for synchronization purposes.

In addition, however, an up-k synchronization must also be carried out, which will be explained in more detail below with reference to two exemplary embodiments shown in FIG. 2 and FIG. 3.

For the synchronization of the base station BS2 to the uplink of the mobile station MS, the timing of the uplink received from the base station BS2 had to be known approximately. Through the

However, runtime differences result in additional inaccuracies. According to a first exemplary embodiment, it is therefore proposed to send an upmk synchronization signal during the transmission gap, ie during the idle time, which the base station can use for synchronization. To make the synchronization as effective as possible, this uplink synchronization signal should have good correlation properties.

The RACH preamble actually intended for the 'Random Access Channel' (RÄCH) could be sent by the mobile station MS as an uplink synchronization signal, for example (possibly repeated). The distribution of the time slots used for this by the mobile station MS is chosen only as an example in FIG. 2. In conventional mobile radio systems, RACH bursts are usually sent from a mobile station to a base station in order to establish a connection with it. These RACH bursts contain a predefined bit sequence which is very well suited for synchronization purposes and thus also for the required upmk synchronization.

Instead of the RACH signal, the mobile station MS can also send other suitable pilot signals as an upmk synchronization signal.

According to a second exemplary embodiment of the present invention shown in FIG. 3, as a further possibility for the uplink synchronization, a complete control channel ('dedicated physical control channel') is proposed between the mobile station MS and the new base station BS2 both via the uplink and via the downlink ', DPCCH). In this way, not only a synchronization between the base station BS2 and the mobile station MS, but also an optimization of the reception and transmission power can be achieved by means of a corresponding power control ('Open Loop Power Control'), the transmission power of the mobile station in particular via the control channel MS and base station BS2 is set to an optimal value before the actual data transmission begins.

The DPCCH control channel sent during the transmission gap from the mobile station MS or the base station BS2 should only contain so-called TPC bits and pilot bits. The TPC bits ('Transmit Power Control'), the value of which is determined by the respective transmitter of the TPC bits after an evaluation of a received signal, contain an instruction for the respective receiver of the TPC bits to adjust their transmission power to the respective TPC Value corresponding to bits. The TFCI bits ('Transport Format Combination Indicator') that are usually included with the DPCCH control channel in UMTS are not required. FBI bits ('Feedback Information') can be used to signal the necessary parameters when using different antennas with several adjustable operating modes ('Transmit Antenna Diversity').

The DPCCH control channel can, for example, be structured in the uplink in such a way that eight pilot bits and two TPC bits are transmitted per time slot. On the other hand, a format should be selected for the downlink in which as little data as possible (in particular no TFCI bits) is transmitted so that as many pilot bits as possible are available. The TPC

Fields of the first time slot or the first time slots of the uplink and downlmk DPCCH can be pre-assigned with a fixed known bit pattern in order to support the synchronization procedure at the beginning. These TPC fields are then not used for power control. Only the TPC bits received during the subsequent time slots are then evaluated as commands for an increase or decrease in the transmission power.

As shown in FIG. 3, the base station BS2 first transmits the DPCCH control channel during the transmission gap. After the mobile station MS has received the downlmk control channel, it sends 1024 chips later via the uplink also a DPCCH control channel, which then serves the base station BS2 for synchronization. The time slots of the downlink and uplink occupied by a DPCCH control channel are each shown in dotted lines in FIG. 3. The invention achieves the maximum advantage if both the old base station BS1 and the new base station BS2 transmit in such a time-related manner that - as shown in FIGS. 1 to 3 - the downlink of the old one from the mobile station MS

Base station BS1 is received frame-synchronously to the downlink of the new base station BS2, i.e. the compressed frame no. m + 1 of the base station BS2 from the mobile station MS immediately after the compressed frame NR. m is received at the base station BSl. However, this frame synchronization is not absolutely necessary.

4 shows two hard handover cases in which the downlink of the old base station BS1 and the downlink of the new base station BS2 are not received frame-synchronously by the mobile station MS, so that no seamless transition from the base station BS1 to the base station BS2 is guaranteed can be. Nevertheless, advantages are achieved over the previous method. The following can be seen in detail from the illustration in FIG. 4.

In the case of the frame relation shown as 'Case 1', the 'Compressed Mode' can be used to achieve a seamless transition between the communication information m sent to frame no. M and frame no. M + 1. On the other hand, even with the frame relation shown as 'Case 2', data loss will occur despite the use of 'Compressed Mode'. That if the frames are not synchronized with each other, the probability of data loss is reduced by using the 'Compressed Mode', although data loss cannot be completely avoided. With the UMTS mobile radio standard, however, it can be assumed that the signals of the two base stations BS1 and BS2, between which the handover is to be carried out, are adapted in such a way that the frame numbers m and m + 1 are at least approximately synchronized.

Claims

claims

1. Method for performing a hard handover process in a mobile radio system, the hard handover process leading to a specific one

Time is switched from a communication between a mobile station (MS) and a first base station (BSl) to a communication between the mobile station (MS) and a second base station (B2), and wherein the communication between the first and second base stations (BSl; BS2) and the mobile station (MS) m a frame structure is embedded, characterized in that the frame (m) transmitted at the time of the hard handover process between the mobile station (MS) and the first base station (BSl) and / or at the time of the hard handover process between the mobile station (MS) and the second base station (BS2) transmitted frames (m + 1) is transmitted in the form of a compressed frame, communication information being transmitted in a time-compressed manner within this compressed frame in such a way that within this compressed frame there is a transmission gap not occupied by communication information, and that the transmission gap occurring in the compressed frame (m, m + l) is used for measures for realizing the hard handover process.

2. The method according to claim 1, characterized in that both the downlmk frame (m) transmitted at the time of the hard handover process from the first base station (BSl) to the mobile station (MS) and the one at the time of the hard handover Upmk frames (m) transmitted from the mobile station (MS) to the first base station (BSl) are transmitted in the form of a compressed frame that both at the time of the hard handover process from the second base station (BS2 ^ to the Mobile station (MS) carried downlmk frames (m + 1) as well as the upmk frames (m + 1) m transmitted in the form of a compressed frame at the time of the hard handover process from the mobile station (MS) to the second base station (BS2), and that the transmission gaps occurring in the two compressed downmk frames and the transmission gaps occurring in the two compressed uplink frames are used for measures for realizing the hard handover process.

3. The method according to claim 2, characterized in that the downlmk frame (m) transmitted at the time of the hard handover process from the first base station (BSl) to the mobile station (MS) and that at the time of the hard handover process Downlmk frames (m + 1) transmitted from the second base station (BS2) to the mobile station (MS) are transmitted in frame-synchronous manner with respect to one another, and that at the time of the hard handover process from the mobile station (MS) to the first base station ( BSl) transmitted upmk frames (m) and the upmk frames (m + 1) transmitted from the mobile station (MS) to the second base station (BS2) at the time of the hard handover process are transmitted in synchronism with one another.

4. The method according to any one of the preceding claims, d a d u r c h g e k e n n z e i c h n e t that the transmission gap m between the mobile station (MS) and the first base station (BSl) transmitted at the time of the hard handover process compressed frame (m) comprises seven time slots.

5. The method according to any one of the preceding claims, characterized in that the transmission gap between the mobile station (MS) and the first base station (BSl) transmitted at the time of the hard handover process compressed frame (m) extends from a certain time slot of this frame to the end of this frame.

6. The method according to any one of the preceding claims, d a d u r c h g e k e n n z e i c h n t that the transmission gap between the mobile station (MS) and the second base station (BSl) transmitted at the time of the hard handover process compressed frame (m + 1) comprises seven time slots.

7. The method according to any one of the preceding claims, characterized in that the transmission gap m between the mobile station (MS) and the second base station (BS2) at the time of the hard handover process transmitted compressed frame (m + 1) from the beginning of this frame extends to a certain time slot of this frame.

8. The method according to any one of the preceding claims, characterized in that the communication between the mobile station (MS) and the first base station (BSl) takes place with a first transmission frequency, which at a second transmission frequency with which the communication between the mobile station ( MS) and the second base station (BS2) takes place, is different, and that the transmission gaps occurring in the compressed frame (m, m + l) are used to switch the transmission frequency of the mobile station (MS) from the first transmission frequency to the second transmission frequency.

9. The method according to any one of the preceding claims, characterized in that the transmission gaps occurring in the compressed frame (m, m + l) for synchronization of the mobile station (MS) m refer to a downl k- sent by the second base station (BS12) Signal and / or to synchronize the second Ba- sisstation (BS2) m are used in relation to an uplink signal sent by the mobile station (MS).

10. The method according to claim 9, so that the mobile station (MS) uses a bit sequence sent to the downlmk signal of the second base station (BS2) for synchronization with the downlmk signal sent by the second base station (BS2).

11. The method as claimed in claim 10, so that the bit sequence used by the mobile station (MS) for synchronization with the downlmk signal sent by the second base station (BS2) and containing the downlmk signal is a pilot bit sequence.

12. The method according to any one of claims 9-11, characterized in that a synchronization signal is sent from the mobile station (MS) during the transmission gap of the compressed transmitted frame (m, m + l), which m the second base station (BS2) to Synchronization to the uplink signal sent by the mobile station (MS) is used.

13. The method according to claim 12, d a d u r c h g e k e n n z e i c h n e t that the synchronization signal is sent repeatedly by the mobile station (MS) during the transmission gap.

14. The method according to claim 12 or 13, so that the synchronization signal sent by the mobile station (MS) during the transmission gap is a RÄCH preamble signal.

15. The method according to any one of claims 9-14, characterized in that a transmission channel corresponding to the mobile radio system (DPCCH) is sent from the mobile station (MS) during the transmission gap of the compressed transmitted frame (m, m + l), which control channel m for the second base station (BS2) for synchronization with that of the mobile station ( MS) sent upmk signal is used.

16. The method according to claim 15, so that the second base station (BS2) also transmits a control channel (DPCCH) corresponding to the mobile radio system during the transmission gap of the compressed transmitted frame (m, m + l).

17. The method according to claim 16, so that the control channel sent by the mobile station (MS) and by the second base station (BS2) during the transmission gap (DPCCH) only comprises pilot bits and / or power control bits.

18. The method according to claim 17, so that the control channel (DPCCH) sent by the mobile station (MS) during the transmission gap has eight pilot bits and two power control bits per time slot.

19. The method according to any one of claims 16-18, characterized in that the bits at the beginning of the control channel (DPCCH) sent by the mobile station (MS) or the second base station (BS2) during the transmission gap with an m of the second base station (BS2) or m the bit pattern known to the mobile station (MS) are occupied, and that m the second base station (BS2) or m the mobile station (MS) contains the bits of this bit pattern corresponding to the corresponding Control channel (DPCCH) can be used for synchronization to the upl signal sent by the mobile station (MS) or the downlmk signal sent by the second base station (BS2).

20. The method according to any one of the preceding claims, d a d u r c h g e k e n n z e i c h n e t that the transmission gap occurring in the compressed frame (m, m + l) is used to adjust the transmission power of the mobile station (MS) and / or the second base station (BS2).

21. The method according to claim 19 and claim 20, characterized in that the bits with the known bit pattern of the control channel (DPCCH) are power control bits which m the second base station (BS2) or the mobile station (MS) not for controlling the transmission power, but be used for synchronization.

22. The method according to any one of the preceding claims, d a d u r c h g e k e n n z e i c h n e t that the method is applied in a UMTS mobile radio system.