JP3525738B2 - Downlink handover control method in cellular system - Google Patents

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a downlink handover control method in a cellular system.

[0002]

2. Description of the Related Art First, the basic configuration of a cellular system will be described with reference to FIG. 5 showing the configuration of the cellular system.

As shown in FIG. 5, the cellular system comprises a mobile station 51, a radio base 52, a base station controller 53 and a backbone network 54. A wireless link is bidirectionally connected between the mobile station 51 and the wireless base station 52. Further, the link between the radio base station 52 and the base station controller 53 is also bidirectionally connected. Therefore, the mobile station 51 to the backbone network 54 are connected via the radio link between the mobile station 51 and the radio base station 52 and the radio base station 52-base station controller 53 link. Further, the backbone network 54
In the following, although not shown, the mobile station is connected to another mobile station via a base station control device and a radio base station, or is connected to another network (via the other terminal).

Next, the cell configuration will be described. Generally, the radio base stations of the cellular system are installed such that the coverage areas (cells) of the adjacent radio base stations are continuous in plane.

Also, the mobile station appropriately switches the connection destination radio base station so that the nearest radio base station having the smallest normal propagation loss becomes the connection destination. This is called handover.

In a CDMA cellular system using a CDMA (Code Division Multiple Access) system as a radio link system between a mobile station and a radio base station, generally, all mobile stations have the same frequency. Send a signal (uplink signal). All radio base stations also transmit signals (downstream signals) at the same frequency. However, the frequency of the upstream signal and the frequency of the downstream signal are different. That is, FDD (Frequency Division Duplex,
Time division duplex) method is used.

Now, how to control the transmission power in the up / down direction will be described. Since the same frequency is used in each of the up and down directions, transmission from a mobile station (or radio base station) is performed. The dropped signal becomes an interference with other signals. Since interference increases as the transmission power increases, transmission power control is performed in both the mobile station and the radio base station in the CDMA cellular system to reduce the transmission power to the necessary minimum and reduce the interference. The transmission power control of the mobile station is called uplink transmission power control, and the transmission power control of the radio base station is called downlink transmission power control.

In the CDMA system, the signal is spread by the spread code. Signals are simultaneously transmitted from one radio base station to a plurality of mobile stations. At this time, the transmission signals are spread by different spreading codes for each mobile station. On the other hand, the transmission timings of these multiple transmission signals can be synchronized in the radio base station. That is, it is possible to synchronize all the timing phases of different spreading codes of a plurality of transmission signals. There is a combination of spreading codes such that the cross-correlation becomes 0 when the timing phases are synchronized, and it is generally called an orthogonal code. One example is the Walsh code. By using such an orthogonal code for spreading the transmission signal from the radio base station, it is possible to eliminate the correlation between a plurality of signals transmitted from one radio base station. However, the number of codes that are orthogonal to each other is limited.

Next, the conventional soft handover (hereinafter,
(Abbreviated as SHO) will be described. As described above, in a CDMA cellular system in which the same frequency is used in all cells, interference must be suppressed as much as possible by always connecting to a radio base station that causes the minimum propagation loss and controlling transmission power. However, if the connection switching with the minimum propagation loss wireless base station is delayed due to the handover delay, both the wireless base station and the mobile station perform transmission with unnecessarily large transmission power, and the interference rather increases. On the other hand, if SHO in which one mobile station simultaneously connects radio links with a plurality of radio base stations at the time of handover is applied, the radio link with the minimum propagation loss radio base station candidate can always be established. Therefore, the minimum propagation loss due to the movement of the terminal can be prepared in advance for the replacement of the radio base station, and the increase in interference due to the handover delay is not caused. Moreover, the effect of site diversity and non-interruptive handover can be achieved by SHO.

Specifically, the mobile station selects a plurality of wireless base stations as connection destination candidates at the time of SHO. Here, the selected plurality of wireless base stations is referred to as a connection candidate base station group. As the connection candidate base station group, as a general rule, for example, the maximum N radio base stations are selected from the one having the smallest propagation loss from the mobile station. Since the propagation loss changes due to the movement of the mobile station or the fluctuation of fading, it is necessary to change the connection candidate base station group. At that time, a wireless base station is added to the connection candidate base station group and a wireless base station is deleted from the connection candidate base station group.

In the conventional method, SHO is performed by connecting a radio link between each radio base station of the connection candidate base station group thus selected and the mobile station. Therefore, according to the addition / deletion of connection candidate base stations, the mobile station-
The wireless links between the wireless base stations are also connected / released.

By the way, the signal flow of the downlink base station control device → radio base station → mobile station, that is, the flow of traffic information from the base station control device to the mobile station at the time of SHO is the conventional downlink flow at the time of SHO. From FIG. 6 showing First, in a state where the mobile station 61 is performing SHO over a plurality of wireless base stations (connection candidate base stations) 62-1 to 62-n, the base station control device 63 transmits the traffic information addressed to the mobile station 61 to the wireless station. It transmits to each of the base stations 62-1 to 62-n. Each of the radio base stations 62-1 to 62-n receives the mobile station 6 received from the base station control device 63.
The traffic information addressed to 1 is transmitted to the mobile station 61 on the wireless link. The mobile station 61 includes a plurality of radio base stations 62-
The same signals sent from 1 to 62-n are received, and if necessary, they are combined and selected to be demodulated.

As described above, in downlink SHO, interference increases due to a plurality of radio base stations transmitting to one mobile station. Also, by transmitting signals from different radio base stations to one mobile station, each radio base station consumes one downlink code spreading orthogonal code, which is more than in the case where SHO is not performed. The consumption of the orthogonal code for downlink signal spreading in the entire system will increase. As described above, since the number of orthogonal codes that can be used in one radio base station is limited, when the number of mobile stations in SHO in the system is large, there may be a situation where the orthogonal codes run short.

In order to deal with the problem of increased interference due to the downlink SHO, "base station selective transmission power control method in downlink of DS-CDMA cellular system" (Hiroshi Furukawa, Technical Report RCS97 of the Institute of Electronics, Information and Communication Engineers) -218, MW97-163 (1
998-02), a downlink transmission power control method from a plurality of wireless base stations included in a connection candidate base station group is shown for the purpose of reducing downlink interference. In this transmission power control method, the connection candidate base stations of N stations are transmitted by sending from the mobile station the number of the radio base station selected as the main base station from the group of connection candidate base stations of N stations and an instruction to increase or decrease the transmission power. It controls the transmission power of the group. That is, the mobile station constantly monitors the pilot channel from each radio base station, and selects the radio base station having the maximum pilot channel reception level as the main base station.

The mobile station also receives the SIR of the communication channel.
(Signal to Interference power Ratio) is measured and compared with the desired SIR. If the received SIR is lower than the desired SIR, the main base station number (1 to N) is set as the transmission power control signal in order to instruct the wireless base station to increase the transmission power.
Either) and set and send. Receive SIR is desired S
When it is higher than IR, the number (0) instructing the power reduction is transmitted. Each radio base station increases the transmission power when it receives the base station number of its own station as a control signal from the mobile station, and decreases it when it receives other numbers. In particular, when a base station number other than the base station number of the own station is received, the transmission power is set to the minimum value.

Then, each radio base station internally manages two transmission power values P1 and P2 so that when the main base station is replaced, the transmission power of the original radio base station becomes the transmission power of the new radio base station. It is taken over and the actual transmission power is controlled as described above. That is, P1
Reduces the control step size DP when the received number is the number (0) instructing the power reduction, and increases the DP only when the other number (base station number) is received. P2 is set to the value of P1 when the received number is the base station number of the own station, and is decreased by the control step size DP when the received number is the number (0) instructing the power reduction, When the other number (base station number) is received, the minimum transmission power Pmin is set. At this time, P2 is set as the actual transmission power. If the numbers transmitted from the mobile station can be received by each radio base station without error by performing such control, the transmission power values P1 managed inside the radio base stations are all equal. , P1 when the main base station changes
Since the value of is set to the actual transmission power P2, the transmission power of the replacement source wireless base station is inherited by the transmission power of the replacement destination wireless base station.

By the above method, the interference is reduced by suppressing the transmission power of the radio base stations other than the main base station.

[0018]

However, the general problems relating to the above-mentioned downlink SHO are summarized as follows.

(1) A plurality of radio base stations simultaneously transmit to one mobile station, which causes an increase in interference, resulting in a decrease in capacity.

(2) Since signals are transmitted from different radio base stations to one mobile station, each radio base station consumes one orthogonal code for downlink signal spreading and does not perform SHO. Compared with the case, consumption of the orthogonal code for downlink signal spreading in the entire system increases. As described above, since the number of orthogonal codes that can be used in one radio base station is limited, when the number of mobile stations in SHO in the system is large, there may be a situation where the orthogonal codes run short.

The method of the above-mentioned conventional document has the problems described above.
We are dealing with (1), but the following issues remain.

(3) From a radio base station other than the main base station,
Since signals are transmitted with the minimum power, interference is reduced, but the problem of increased interference due to multiple links remains.

(4) Due to a transmission error in the control information (number information) transmitted in the upstream direction, the value of the transmission power value P1 managed individually by a plurality of connection candidate base stations is different for each radio base station. Will be different. Further, if the wireless base station selected by the mobile station as the main base station receives the number by mistake, the transmission power from the main base station is set to the minimum power, which may cause communication interruption. Alternatively, if the number accidentally received by a wireless base station that the mobile station has not selected as the main base station coincides with the number of its own station, the wireless base station transmits at the same transmission power as the main base station. , Large interference may occur.

(5) The above-mentioned conventional literature does not describe a method of initializing the transmission power value P1 when a wireless base station is added to the connection candidate base station group, but P1 has an error. When set, the initial setting error is held as it is while the wireless base station is continuously included in the connection candidate base station group. That is, it affects transmission power when the transmission power is taken over when the wireless base station is changed, and if the error is large, interference increases or communication quality deteriorates when the wireless base station changes.

An object of the present invention is to provide a downlink handover control method in a cellular system that can deal with such a problem.

[0026]

In order to achieve this object, according to the present invention in a cellular system composed of a base station controller, a plurality of radio base stations, and a mobile station, data should be transmitted to a mobile station. When information is present in the base station controller, one or more connection candidate base stations for the mobile station are selected from a plurality of radio base stations, and one or more connection candidate base stations are selected from the base station controller. To the mobile station by selecting one or more of the connection candidate base stations as a main base station in real time, and transmitting the information from the selected main base station to the mobile station. The candidate base station transmits an uplink radio link transmission power control command to the mobile station. Therefore, the interference generated in the downlink can be significantly reduced as compared with the conventional method that uses a plurality of links at the same time, and the effect of reducing the interference generated in the downlink is higher than that of the method disclosed in the above document. Particularly, in the present invention, the uplink radio link transmission power control command is transmitted from all the connection candidate base stations, so the uplink radio link transmission power control is optimized. That is, since the uplink radio link and the downlink radio link use different frequencies, the optimum radio base station that minimizes the propagation loss may be different. The inconvenience that the transmission power from the mobile station is not optimized by the transmission of the radio link transmission power control command does not occur.

Further, according to another aspect of the present invention, when the transmission from the main base to be changed to the mobile station is started, a spread code using an orthogonal code, which is used for spreading a signal to be transmitted, is allocated, and the main base to be changed is assigned. The station is characterized in that after the transmission to the mobile station is stopped, the allocation of the spreading code used for spreading the signal being transmitted is released. Therefore, by assigning the orthogonal code to the spreading code in this way, it is possible to suppress the probability of falling into a situation where the orthogonal code is insufficient as compared with the conventional downlink SHO method.

Further, according to another aspect of the present invention, in response to the change of the main base station caused by the real-time selection of the main base station, the mobile station instructs the changed main base station to start transmission, The main base station to which the change is instructed to start transmission starts transmission to the mobile station when there is information to be transmitted to the mobile station or when there is information to be transmitted, and in parallel, the main base station to be changed from the mobile station. The transmission source main base station instructed to stop transmission to the base station, and instructed to stop transmission, stops transmission to the mobile station. Then, prior to the mobile station instructing the source main base station to stop the transmission, the mobile station confirms that the source main base station has started transmission, and the mobile station confirms that the source main base station has started the transmission. After instructing the base station to stop transmission, the mobile station confirms that the transmission from the change-source main base station has been stopped. Alternatively, when the mobile station gives an instruction to start transmission to the main base station to be changed, a transmission start command is continuously or repeatedly transmitted for a certain period of time, and the mobile station stops transmission to the main base station to be changed. In response to the instruction, the transmission stop command is continuously or repeatedly transmitted for a certain period of time. Therefore, the probability of erroneous transmission on / off at the wireless base station on the receiving side can be significantly reduced, and thereby the probability of line disconnection or duplicate transmission from a base station other than the main base station can be suppressed to a low level.

According to another aspect of the present invention, when the connection candidate base station selected as the main base station starts transmission to the mobile station, the pilot channel of the selected connection candidate base station is transmitted. The reception level to interference level ratio is measured at the mobile station, information indicating the measured reception level to interference level ratio is transmitted to the connection candidate base station, and the connection candidate base station is based on the transmitted information. It is characterized by setting the transmission power to the mobile station. When the connection candidate base station selected as the main base station starts transmission to the mobile station, from the reception level of the pilot channel transmitted by the selected connection candidate base station and the selected connection candidate base station The interference signal reception level for the signal when the signal addressed to the mobile station is transmitted is measured at the mobile station,
Information indicating both the measured pilot channel reception level and the interference signal reception level or the ratio between the pilot channel reception level and the interference signal reception level is transmitted to the connection candidate base station, and based on the transmitted information. It is also characterized in that the connection candidate base station sets transmission power for the mobile station. Therefore, when a certain wireless base station becomes the switching destination immediately after being added to the connection candidate,
Also, in any case where the wireless base station that is continuously the connection candidate becomes the switching destination, the downlink wireless link transmission power initial value can be correctly set.

[0030]

BEST MODE FOR CARRYING OUT THE INVENTION A downlink handover control method in a cellular system according to an embodiment of the present invention will be described below.

FIG. 1 is a diagram showing a signal flow of a cellular system according to an embodiment of the present invention.

First, the addition and deletion of connection candidate base stations will be described. The mobile station 11 selects a plurality of wireless base stations 12-1 to 12-n as connection destination candidates during SHO. As described above, the selected wireless base station is called a connection candidate base station. As a connection candidate base station group, for example, a maximum of N radio base stations are selected from the one with the smallest propagation loss from the mobile station 11. Since the propagation loss changes due to movement of the mobile station 11 or fluctuation of fading,
It is necessary to change the connection candidate base station group. At that time, the addition of the wireless base station to the connection candidate base station group and the deletion of the wireless base station from the connection candidate base station group are performed by the following method, for example.

From each of the radio base stations 12-1 to 12-n,
Generally, a common channel signal unique to each radio base station is transmitted with a constant transmission output. This common channel is called a pilot channel here. The mobile station 11 can identify the radio base stations existing in the vicinity by receiving the pilot channels from the radio base stations 12-1 to 12-n, and can measure the reception level of each pilot channel. . Each radio base station 12-1 to 12-
When the maximum of the pilot channel reception levels from n is Smax [dBm], the reception level S [dBm] of the pilot channels from the radio base stations not included in the connection candidate base station group is predetermined. For the threshold Tadd [dB]

Smax-S <Tadd [dB]

When, the radio base station is selected as a connection candidate base station and added to the connection candidate base station group. However, when the number of wireless base stations included in the connection candidate base station group exceeds N, N stations become the connection candidate base station group from the one having the highest pilot channel reception level. In addition, the reception level S [dBm] of the pilot channel from the wireless base stations included in the connection candidate base station group is a predetermined threshold Tde.
for l [dB]

Smax-S> Tdel [dB] (Generally, Tdel> Tadd)

When it becomes, the selection of the wireless base station as a connection candidate base station is stopped and the wireless base station is deleted from the connection candidate base station group. The difference between the values of Tadd and Tdel is provided in order to avoid frequent addition / deletion of radio base stations due to fluctuations in the pilot channel reception level among a plurality of radio base stations.

Next, the connection of the base station controller-radio base station and the operation of the base station controller at the time of SHO will be described.

In the embodiment of the present invention, the flow of traffic information from the base station controller to the mobile station at the time of SHO is such that the mobile station 11 has a plurality of radio base stations (connection candidate base stations) as shown in FIG. ) SH spanning 12-1 to 12-n
In the state of performing O, the base station control device 13
Traffic information addressed to the wireless base stations 12-1 to 12-
to each of the n. Radio base stations 12-1 to 12-
Among n, the radio base station instructed to turn on the radio link by the command from the mobile station 11 receives the traffic information addressed to the mobile station 11 from the base station control device 13,
It transmits on the wireless link towards the mobile station 11. Mobile station 1
1 receives the same signal sent from one or a plurality of radio base stations, and performs synthesis / selection and demodulation as necessary. In addition, in FIG. 1, the wireless base station 12-2
Only the transmission is turned on is shown in the example.

Connection / release in the case of a wired link in the embodiment of the present invention is performed as follows. The wired link from the base station control device to the connection candidate base station is connected when the wireless base station is added to the connection candidate base station group, and released when it is deleted from the connection candidate base station group. . The same information addressed to the target mobile station is transmitted in parallel from the base station control device to all the radio base stations included in the connection candidate base station group. However, in order to reduce the required line capacity of the wired link, etc., it prevents the adoption of a method in which the same information addressed to the mobile station is not necessarily transmitted to all the wireless base stations included in the connection candidate base station group. is not.

Connection / release in the case of the wireless link in the embodiment of the present invention is performed as follows. The radio link from each radio base station to the mobile station turns on / off the transmission at high speed in accordance with a command from the mobile station, for example. The mobile station monitors the reception level of the pilot channel from each radio base station, connects the radio link with the radio base station with the highest reception level (defined as the main base station), and connects the other radio links. Send a transmission on / off command to the radio base station to release. When the mobile station is receiving pilot channels from three connection candidate base stations (for example, BTS1, BTS2, BTS3), fluctuations in the reception level and transmission ON / OFF from each connection candidate base station corresponding to the fluctuation
An example of changes in the off state is shown in FIG.

As another method, it is conceivable that the connection candidate base station voluntarily determines whether transmission is on or off. That is, since each connection candidate base station is considered to be receiving the uplink signal transmitted from the mobile station for SHO of the uplink radio link, the transmission error quality (eg, bit error rate, frame error) of the received signal is received. Rate) is monitored at regular intervals, for example, and when the quality is deteriorated from a predetermined quality (for example, when the bit error rate / frame error rate exceeds a predetermined threshold), the connection candidate base station selects the target mobile station. Stop sending to. Conversely, when the transmission error quality of the received signal becomes better than a predetermined quality (for example, when the bit error rate / frame error rate falls below a predetermined threshold value).
Then, the connection candidate base station starts transmission to the target mobile station.

The details of the wireless link switching method will be described later.

As described above, the number of radio links used simultaneously for transmission from the radio base station to the mobile station can be limited to one with minimum propagation loss or a small number with near minimum propagation loss. Therefore, it is possible to greatly reduce the interference generated in the downlink as a whole, as compared with the conventional general method of simultaneously using a plurality of links. Further, in the present invention, basically, transmission is completely stopped from the base stations other than the main base station, so that the interference generated in the downlink can be reduced even when compared with the method shown in the above-mentioned conventional literature. Highly effective.

On the other hand, the connection / release of the link from the base station controller to the connection candidate base station can be made equivalent to the conventional general SHO system, and the radio link is frequently turned on / off.
The processing load on the base station controller does not increase due to the turning off.

Radio Base Station in Downlink Handover Control Method in Cellular System of the Present Invention
Although various methods can be adopted as the method of switching the downlink radio link between the mobile stations, three typical methods will be described below. In the following, a case where two wireless base stations BTS1 and BTS2 are included in the connection candidate base station group will be described as an example.

In the first downlink radio link switching method, a command is sent from the mobile station to the radio base station, the radio link of the switching destination is established first, the radio link of the switching source is released, and the radio link is established. By confirming the release / release on the mobile station side, the establishment / release can be performed without error.

Specifically, the following procedure shown in FIG.
Switching is performed by performing it at a speed high enough to follow fading. It should be noted that in the following procedure, stopping a transmission-on command for a certain BTS can be regarded as a transmission-off command for the BTS.

(1) The mobile station measures the reception levels of the pilot channels of BTS1 and BTS2 (step 301), and selects a radio base station with a high reception level (step 30).
2). The radio base station that has been selected so far (switching source BTS
) And the newly selected wireless base station (switch destination BTS) are different from each other, the next step is executed (step 303).
(The following description will be made assuming that BTS1 has been selected so far and BTS2 is newly selected and switched.)

(2) The mobile station sends a command to turn on transmission of the downlink radio link to the newly selected BTS2 (step 304).

(3) The BTS 2 starts transmission for the mobile station according to the transmission ON command from the mobile station (step 30).
5).

(4) The mobile station confirms the start of transmission from BTS2, establishes a radio link (step 306), and then sends a command to turn off transmission of the downlink radio link to BTS1 (step 307). (If the transmission start from BTS2 cannot be confirmed, send the transmission ON command again.)

(5) The BTS 2 stops the transmission for the mobile station (releases the radio link) according to the transmission off command from the mobile station (step 308).

(6) The mobile station confirms that transmission from BTS1 has stopped (step 309). (When the transmission stop from BTS1 cannot be confirmed, the transmission off command is sent again.)

As described above, when the wireless link is switched, since the wireless link of the switching destination is first established and then the wireless link of the switching source is released, the line disconnection does not occur due to the switching of the wireless link. . Also, the mobile station confirms the release of the wireless link of the switching source, and if it is not released, the release procedure is repeated again, so that there is no possibility that a signal is continuously transmitted from the wireless base station of the switching source by mistake.

The second downlink radio link switching method is to reduce command transmission error by repeatedly transmitting a command when the mobile station instructs the radio base station to turn on / off the transmission.

Specifically, the following procedure shown in FIG.
Switching is performed by performing it at a speed high enough to follow fading.

(1) The mobile station measures the reception levels of the pilot channels of BTS1 and BTS2 (step 401), and selects a radio base station having a high reception level (step 40).
2). The radio base station that has been selected so far (switching source BTS
) And the newly selected wireless base station (switch destination BTS) are different, the following step is executed (step 403).
(The following description will be made assuming that BTS1 has been selected so far and BTS2 is newly selected and switched.)

(2) The mobile station sends a command to turn on the downlink radio link to the newly selected BTS2 either continuously for a certain period of time or repeatedly at a certain period of a certain period of time (step 404). . At the same time or after a lapse of a predetermined time, a downlink radio link transmission OFF command is continuously sent to the BTS 1 for a fixed time or repeatedly at a fixed cycle for a fixed time (step 40).
7).

(3) The BTS 2 continuously receives the transmission ON command from the mobile station for a fixed time (or a fixed number of times), or when the BTS 2 receives a command for a predetermined number of times during a fixed time (step 40
5) Immediately start transmission for the mobile station (step 4)
06).

(4) The BTS 1 continuously receives the transmission off command from the mobile station for a fixed time (or a fixed number of times), or when the command is received a predetermined number of times or more during the fixed time (step 40).
8) Then, the transmission for the mobile station is stopped immediately or after a predetermined time (step 409).

In this method, since the transmission ON / OFF command is repeatedly transmitted, the probability of mistaken transmission ON / OFF at the receiving side radio base station can be significantly reduced, whereby the line disconnection or other than the main base station The probability of duplicate transmission from the base station can be suppressed to a low level.

In the third downlink radio link switching method, the connection candidate base station voluntarily determines on / off of transmission according to the transmission error quality of the uplink radio link received signal transmitted from the mobile station. is there.

Specifically, the transmission from the connection candidate base station is turned on / off by performing the following procedure. It is assumed that the mobile station is continuously transmitting an uplink radio link signal and that all connected base stations receive the signal.
Further, the transmission power is increased or decreased at regular time intervals by general closed loop control, and the reception quality at the connection candidate base station that minimizes the propagation loss from the mobile station is controlled to be almost constant. To do.

(1) In each connection candidate base station,
Bit error rate BE of the uplink radio link received signal at fixed time intervals
Calculate R or frame error rate FER.

(2) In the connection candidate base station which is transmitting the downlink radio link signal to the mobile station, with respect to the predetermined threshold BER0 (or FER0)

BER> BER0 (or FER> FER0)

When, the downlink wireless link signal transmission from the connection candidate base station is stopped.

(3) For a predetermined threshold BER1 (or FER1) in a connection candidate base station that has stopped transmitting downlink radio link signals to the mobile station

BER <BER1 (or FER <FER1)

When, the downlink wireless link signal transmission from the connection candidate base station is started.

In the above procedure, in order to suppress the switching frequency of transmission on / off,

BER1 <BER0 (or FER1 <FER0)

It may be set as follows. Also

BER1 = BER0 (or FER1 = FER0)

It is also possible to set as.

When the transmission on / off from each connection candidate base station is switched in this way, the condition of the above procedure (3) should be satisfied at least in the connection candidate base station where the propagation loss is minimum in the uplink radio link. To threshold BER1
(Or FER1) can be set, the downlink radio link signal is transmitted from the same connection candidate base station, and the conditions of the above procedure (2) are satisfied at the other connection candidate base stations due to the propagation loss of the uplink wireless link. Since the downlink radio link signal may not be transmitted in some cases, the downlink radio link signal is substantially turned on / off according to the propagation loss of the uplink radio link.

Next, a method of determining the initial value of the transmission power of the switching destination wireless base station at the time of switching the downlink wireless link will be described below.

The communication channel transmission power TT [dBm] from the wireless base station to which the wireless link is switched is

TT = I + SIRT + (TP −RP) = SIRT − (RP
−I) + TP ≈ SIRT − SIRP + TP I [dBm]: Interference power of communication channel received by mobile station SIRT [dB]: Required communication channel SIR TP [dBm]: Pilot channel transmission power RP [dBm]: Pilot Channel reception power SIRP [dB]: Pilot channel reception SIR

It may be set as follows. Therefore, when switching the wireless link, the mobile station switches to the switching target wireless base station
Is notified, and the switching destination radio base station may calculate TT. Alternatively, the TT can be calculated in the switching target wireless base station even when the mobile station notifies the switching target wireless base station of the value of (RP-I) or the values of RP and I.

In the above method, when a wireless base station is a switching destination immediately after a certain wireless base station is added to the connection candidates, and a wireless base station which is a continuous connection candidate is a switching destination. It can be applied to both cases.

A method of determining the initial value of the transmission power of the switching destination wireless base station at the time of switching another downlink wireless link will be described below. It should be noted that another method may be adopted as a method of determining the initial value of the transmission power when the wireless base station which is a connection candidate continuously becomes the switching destination.

In this case, it is assumed that the mobile station periodically transmits a command for increasing or decreasing the transmission power as a common transmission power control command to all the connection candidate base stations. At this time, each connection candidate base station internally manages the virtual transmission power value P1 regardless of transmission ON / OFF, and increases / decreases P1 according to a command from the mobile station. The initial value of P1 is set, for example, by the above-described method of calculating TT in the switching destination wireless base station.
At this time, the value of P1 is set as the actual transmission power in the radio base station selected as the switching destination (instructed to turn on the transmission). In other wireless base stations, the value of P1 is only held internally, and the actual transmission power is set to 0 (transmission off).

Next, the line switching command / initial power information transmission method will be described.

First, the command for switching the radio link does not need to be transmitted constantly or periodically, and may be transmitted from the mobile station as needed. Also, when the initial value of the transmission power of the switching target wireless base station is determined by the method of calculating TT in the switching target wireless base station described above, the information necessary for that (SIRP or (RP-I), etc.) is also wirelessly transmitted. It may be sent in the same way as the link switch command.

By doing so, the amount of control signals transmitted from the mobile station to the radio base station can be reduced.

It should be noted that, due to restrictions on the structure of the wireless interface, sending the above-mentioned wireless link switching command and transmission power initial value determination information constantly or periodically does not essentially hinder the present invention.

In addition to this, CRC or FEC is used for transmitting the radio link switching command and the information for determining the transmission power initial value.
Transmission error protection may be performed, for example. When this is done, transmission errors of those commands and information are reduced, so that the occurrence of wireless link switching errors, transmission power setting errors, etc. can be greatly suppressed.

In the present invention, it is possible to allocate and release the orthogonal code for spreading the downlink signal depending on whether the transmission of the connection candidate base station is on or off. That is, when transmission is started from the radio base station in the transmission off state, a new orthogonal code is newly allocated and used for signal spreading. Further, when the transmission of the wireless base station in the transmission on state is stopped, even if the wireless base station is still included in the connection candidate base station group, the orthogonal code used is released and another downlink is released. Allow it to be used for signal spreading.

Therefore, as described in the description of the prior art, since the number of orthogonal codes used for spreading downlink signals is limited, the above-mentioned orthogonal code allocation is used to perform conventional downlink transmission. The probability of falling into a situation where the orthogonal code is insufficient can be suppressed to a lower level than in the link SHO system.

Next, control for uplink transmission power control and command transmission will be described.

First, regarding the control for uplink transmission power control, the uplink radio link at the time of SHO is such that one signal transmitted from the mobile station is simultaneously received by a plurality of radio base stations, and these signals are transmitted to the base station controller. Selection / combination is performed. At this time, generally, in order to control the transmission power of the uplink radio link, a command for increasing or decreasing the transmission power is transmitted from all the radio base stations that have received the signal to the mobile station. In the mobile station, the transmission power control is performed such that the transmission power is reduced only when all the received power control commands instruct the reduction, and in other cases, the transmission power is increased. This means that the mobile station substantially follows the command from the optimum radio base station with the minimum propagation loss.

Next, regarding the command transmission, since the frequencies used in the uplink radio link and the downlink radio link are different, the optimum radio base station that minimizes the propagation loss may be different. That is, even if the uplink radio link transmission power control command is sent only from the optimal radio base station for the downlink radio link, the transmission power from the mobile station may not be optimal. Therefore, in order to optimize the uplink radio link transmission power control, it is possible to send the uplink radio link transmission power control command from all the connection candidate base stations. That is, in this case, the uplink radio link transmission power control command transmitted on the downlink radio link is excluded from the transmission on / off target and is always transmitted.

Therefore, the uplink transmission power at the time of SHO can be optimized.

Next, correspondence to different cell sizes will be described. It is assumed that the cell size varies depending on the traffic density. When the traffic density is low (when the cell size is large), it is considered that the influence on the other is small even if the transmission power is high compared to the place where the traffic density is high.

Regarding the transmission power S of the radio base station, the influence S'of the interference (or the influence on the capacity) S '

S ′ = a × S (the larger the cell size, the more a
Is small)

Considering that, when selecting a radio base station, the propagation loss itself from each radio base station to the mobile station is not compared, but the value of (propagation loss × a) is compared and the value is calculated. It is only necessary to select the smallest radio base station. (The larger the cell, the smaller a becomes, so (propagation loss x a) becomes smaller than the actual propagation loss, and it may happen that the base station of a cell with a large size is selected even at a distant location. When this is applied to the above-mentioned two downlink radio link switching methods, it is sufficient that the correction level a of the propagation loss is reflected in the reception level of the pilot channel measured in step (1). That is, the pilot channel transmission power of each radio base station may be increased or decreased by the propagation loss correction amount a depending on the cell size. That is, the pilot transmission power TP

TP = TP0 / a (however, TP0 is a constant)

It may be set as follows.

Therefore, even when cells of different sizes are mixed depending on the traffic bias, it is possible to optimize the interference (or maximize the total capacity) according to the traffic distribution.

Next, communication channel synchronization at the time of radio link switching will be described.

At the time of switching the downlink radio link, the mobile station needs to establish synchronization for receiving a signal from the switching destination radio base station. For example, a common channel such as a pilot channel is constantly transmitted from the radio base station. , If the mobile station has already established synchronization for the common channel,
Utilizing synchronization timing information for common channels,
It is possible to quickly establish synchronization with a communication channel signal whose transmission is newly started from the wireless base station.

As an example other than the embodiment described above, there is a case where a plurality of wireless links are simultaneously connected. In this case, the explanation is made assuming that the main base station that connects the downlink radio link is one station, but it is applicable to mobile stations in which the propagation losses from a plurality of connection candidate base stations are almost equal. Simultaneous connection of downlink radio links from multiple connection candidate base stations is not excluded. In that case, the mobile station sends a transmission-on command to all the base stations selected as the connection destinations.

Then, application to packet transmission can be considered. This is true both when the signal transmitted on the downlink radio link is continuous and when it is intermittent like packet transmission. However, in the case of packet transmission, the radio base station instructed to turn on transmission starts actual transmission only when there is a signal to be transmitted or when there is a signal to be transmitted.

Application to a cellular system by a radio system other than CDMA is also conceivable. The present invention in this case is particularly effective when applied to a CDMA cellular system, but is applied to a cellular system using a wireless system other than CDMA (including partial application).
Does not exclude.

The configurations of the above-described embodiments are merely examples, and combinations of the embodiments are possible, and the combinations can be arbitrarily configured.
Further, the above-described embodiments are merely examples of the present invention and are not intended to limit the present invention, and the present invention can be carried out in other modified modes and modified modes. Therefore, the scope of the present invention is defined only by the claims and their equivalents.

[0109]

As described above, according to the present invention,
Compared to the conventional method using a plurality of links at the same time, the interference generated in the downlink can be significantly reduced, and the effect of reducing the interference generated in the downlink is higher than that of the method disclosed in the above document. Further, by assigning the orthogonal code to the spreading code, it is possible to suppress the probability of falling into a situation where the orthogonal code is insufficient as compared with the conventional downlink SHO method.
Further, the probability that transmission on / off is erroneous at the wireless base station on the receiving side can be significantly reduced, and thus the probability of line disconnection or duplicate transmission from a base station other than the main base station can be suppressed to a low level. Also, when a wireless base station is the switching destination immediately after a certain wireless base station is added to the connection candidates,
Also, in any case where the wireless base station that is continuously the connection candidate becomes the switching destination, the downlink wireless link transmission power initial value can be correctly set.

[Brief description of drawings]

FIG. 1 is a diagram showing a signal flow of a cellular system downlink according to the present invention.

FIG. 2 is a diagram showing changes in transmission on / off state from each connection candidate base station according to the present invention.

FIG. 3 is a flowchart showing an operation of downlink radio link switching according to the present invention.

FIG. 4 is a flowchart showing another downlink radio link switching operation according to the present invention.

FIG. 5 is a block diagram showing a configuration of a cellular system.

FIG. 6 is a diagram showing a signal flow of a downlink of a conventional cellular system.

[Explanation of symbols]

11, 51, 61 Mobile stations 12-1 to 12-n, 52, 62-1 to 62-n Radio base stations 13, 53, 63 Base station controller 54 Backbone network

─────────────────────────────────────────────────── ─── Continuation of the front page (72) Inventor Fumio Watanabe International Telegraph and Telephone Corporation, 2-3-2 Nishishinjuku, Shinjuku-ku, Tokyo (56) Reference JP-A-11-69416 (JP, A) JP Japanese Unexamined Patent Publication No. 10-22975 (JP, A) Japanese Unexamined Patent Publication No. 3-242049 (JP, A) Japanese Unexamined Patent Publication No. 7-298333 (JP, A) Japanese Unexamined Patent Publication No. 1882042 (JP, A) Japanese Unexamined Patent Publication No. 9-224276 (JP , A) JP 10-13922 (JP, A) JP 9-312871 (JP, A) (58) Fields investigated (Int.Cl. ⁷ , DB name) H04B ⁷ /24-7/26 H04Q 7/00-7/38

Claims (19)

(57) [Claims] 1. A cellular system comprising a base station control device, a plurality of radio base stations, and a mobile station, wherein when the information to be transmitted to the mobile station exists in the base station control device, the mobile station , One or more connection candidate base stations are selected from the plurality of radio base stations, and the same information is provided from the base station control device to the one or more connection candidate base stations as necessary. , One or more of the connection candidate base stations is selected as a main base station, the information is transmitted from the selected main base station to the mobile station, while all the connection candidate base stations are transmitted. , A downlink handover control method in a cellular system, which transmits an uplink radio link transmission power control command to the mobile station. 2. The downlink handover control method in a cellular system according to claim 1, wherein the wireless base stations other than the selected main base station do not transmit the information to the mobile station. 3. Each of the radio base stations transmits a pilot channel signal with a fixed transmission power for each of the radio base stations, and the mobile station receives the pilot channel signal from each of the radio base stations and receives the pilot channel signal. The maximum reception level value is obtained based on the channel signal, and the value obtained by subtracting the reception level value of the pilot channel signal from each radio base station from the maximum reception level value is smaller than the first threshold value set in advance. Then, the radio base station is selected as the connection candidate base station, and the reception level value of the pilot channel signal from the radio base station already selected as the connection candidate base station is subtracted from the maximum reception level value. When the value becomes larger than a predetermined second threshold value, the wireless base station is selected as the connection candidate base station. The downlink handover control method in the cellular system according to claim 1 or 2, characterized in that it is canceled. 4. The connection candidate base station, wherein one or more of the connection candidate base stations having the smallest propagation loss to the mobile station are selected as a main base station. 4. A downlink handover control method in the cellular system according to any one of 3 to 3. 5. Each of the plurality of radio base stations transmits the pilot channel signal with a fixed transmission power for each radio base station, and the mobile station receives the pilot channel signal from each of the connection candidate base stations. Is received and one or more of the connection candidate base stations from the highest reception level are selected as a main base station, and the downlink in the cellular system according to claim 1. Circuit handover control method. 6. The mobile station instructs a change-destination main base station to transmit in response to a change of the main base station caused by real-time selection of the main base station, and the transmission instructed The change destination main base station transmits to the mobile station when there is information to be transmitted to the mobile station or when there is information, and in parallel, the mobile station instructs the change source main base station to transmit. The transmission source is stopped or the transmission is instructed, and the transmission source is stopped or the transmission source main base station is instructed to stop the transmission to stop the transmission to the mobile station. 6. The downlink handover control method in the cellular system according to any one of 5 above. 7. The mobile station, prior to the mobile station stopping the transmission instruction to the change source main base station or instructing the transmission stop, indicates that the transmission from the change destination main base station has started. After confirming at the station and stopping the transmission instruction from the mobile station to the change source main base station or instructing the transmission stop, the mobile station confirms that the transmission from the change source main base station is stopped. 7. The downlink handover control method in the cellular system according to claim 6, characterized in that 8. When the mobile station gives an instruction to start transmission to the change-destination main base station, a transmission start command is continuously or repeatedly transmitted for a fixed time, and the mobile station sends the change-source main base station. 7. The transmission stop command is continuously or repeatedly transmitted for a certain time when the station is instructed to stop transmission.
A downlink handover control method in the cellular system according to. 9. A quality indicated by a transmission error such as a bit error rate or a frame error rate of the received signal when an uplink radio link signal transmitted from the mobile station is received by each of the plurality of connection candidate base stations. When the connection candidate base station stops transmission addressed to the mobile station when the quality of the received signal deteriorates below a predetermined quality indicated by a predetermined transmission error, and the quality of the transmission error of the received signal becomes better than a predetermined quality. The connection candidate base station starts transmission to the mobile station as the main base station, whereby one or more of the plurality of connection candidate base stations are selected as the main base station. Claim 1
5. A downlink handover control method in the cellular system according to any one of 4 to 4. 10. The downlink handover control method according to claim 9, wherein the quality is indicated by a transmission error such as a bit error rate or a frame error rate. 11. When the connection candidate base station selected as the main base station starts transmission to the mobile station,
The mobile station measures the reception level-to-interference level ratio of the pilot channel transmitted by the selected connection candidate base station, and transmits information indicating the measured pilot channel reception level-to-interference level ratio to the connection candidate base station. The downlink in the cellular system according to any one of claims 1 to 5 and 9, wherein transmission power addressed to the mobile station is set in the connection candidate base station based on the transmitted information. Circuit handover control method. 12. When the connection candidate base station selected as the main base station starts transmission to the mobile station, the pilot channel reception level transmitted by the selected connection candidate base station and the selected The interference signal reception level for a signal when a signal addressed to the mobile station is transmitted from the connection candidate base station is measured at the mobile station, and both the measured pilot channel reception level and the interference signal reception level are measured, or Information indicating the ratio of the reception level of the pilot channel and the reception level of the interference signal is transmitted to the connection candidate base station, and the transmission power for the mobile station is set in the connection candidate base station based on the transmitted information. A downlink handover control method in a cellular system according to any one of claims 1 to 5 and 9, Law. 13. A common transmission power control command for holding a virtual transmission power value in each of the connection candidate base stations, and for instructing all the connection candidate base stations of the connection station to increase or decrease the transmission power. Each of the connection candidate base stations that have received the transmission power control command from the mobile station increase or decrease the virtual transmission power value according to the instruction of the command, and are selected as the main base station. 10. The connection candidate base station sets the virtual transmission power value as an actual transmission power addressed to the mobile station when starting transmission to the mobile station. 2. A downlink handover control method in the cellular system according to item 1. 14. A measurement for instructing transmission from the mobile station to the change destination main base station or a command to stop transmission to the change source main base station, or from the mobile station to the connection candidate base station, measurement Only when necessary, information indicating the reception level to interference level ratio, or both the measured pilot channel reception level and the interference signal reception level, or information indicating the ratio between the pilot channel reception level and the interference signal reception level 7. The transmission from the mobile station is performed.
13. A downlink handover control method in the cellular system according to any one of 1 and 12. 15. A command for instructing transmission from the mobile station to the change-destination main base station or a command to stop transmission to the change-source main base station, or from the mobile station to the connection candidate base station, measurement The information indicating the reception level-to-interference level ratio, the measured pilot channel reception level and the interference signal reception level together, or the information indicating the ratio between the pilot channel reception level and the interference signal reception level is error-corrected. The downlink handover control method in a cellular system according to any one of claims 6, 11 and 12, wherein the mobile station transmits the coded or error-detected coded data. 16. A transmission code used for spreading of a signal to be transmitted is allocated at the start of transmission from the change-destination main base station to the mobile station, and after the change-source main base station stops transmission to the mobile station,
The downlink handover control method in a cellular system according to claim 6 or 9, wherein the allocation of the spreading code used for spreading the signal being transmitted is released. 17. The downlink handover control method in a cellular system according to claim 16, wherein an orthogonal code is used as a spreading code assigned by the main base station to be changed. 18. The uplink radio link transmission power control command from each of the connection candidate base stations is transmitted constantly or periodically. Downlink handover control method in a cellular system. 19. The pilot channel transmission power of each of the radio base stations is set so as to have a positive correlation with a predetermined value of the cell size of each of the radio base stations. Downlink handover control method in the cellular system of the present invention.