JP5672083B2 - Wireless network control device and communication control method - Google Patents

Description

  The present invention relates to communication control in a radio access network including a base station and a radio network control device.

  In 3GPP (3rd Generation Partnership Project), the HSDPA (High Speed Downlink Packet Access) method is an extension method for realizing downlink high-speed wireless communication in a W-CDMA mobile communication system (hereinafter simply referred to as W-CDMA). Is stipulated. HSDPA is a communication method in which a plurality of mobile stations share one physical channel (HS-DSCH). In HSDPA, the transmission of downlink data from the base station (Node-B) to each mobile station (UE: User Equipment) is appropriately assigned to a specific unit (slot) delimited by a code and a fixed time interval (slot). HS-DSCH (High-Speed Downlink Shared Channel) is shared. Since HSDPA is an extension scheme in W-CDMA, some mobile stations do not support data transmission by HSDPA. For this reason, the radio network control apparatus selects application or non-application of data communication by HSDPA for each mobile station.

  In W-CDMA, when HSDPA is not used, the base station establishes a connection by a physical channel (hereinafter referred to as “individual channel”) individually assigned to each mobile station in downlink data communication. When performing data communication using dedicated channels in W-CDMA, the base station performs transmission power control for the purpose of ensuring a constant data communication speed through dedicated channels and maintaining signal reception quality at the mobile station. Do. Specifically, the mobile station measures, for example, SIR (Signal to Interference Ratio) based on the received signal from the base station, and compares the measured SIR with the target SIR. The mobile station transmits a TPC (Transmit Power Control) bit requesting the base station to increase or decrease the transmission power by a certain amount according to the comparison result.

  On the other hand, in HSDPA, HS-DSCH, which is a single physical channel, is shared by multiple mobile stations, so transmission power control is not performed, and the signal reception quality at each mobile station is the transmission when transmitting from the base station. This is ensured by changing the format (modulation method and error correction coding rate). Specifically, when the signal is received at the mobile station, the received signal quality is measured and reported to the base station. The base station receives the report, and when the received signal quality is poor, the transmission is slow. When the received signal quality is good, control is performed to select a high-speed transmission format and transmit the signal. For example, when the received signal quality is poor, choose a QPSK (Quadrature Phase Shift Keying) modulation method with high stability but low speed and a coding method with large error correction capability, and when the received signal quality is good, a faster 16QAM ( (Quadrature Amplitude Modulation) Modulation method and coding method with small error correction capability are selected.

  In HSDPA, since the transmission format is changed at high speed, more appropriate reception quality is obtained in each mobile station, and as a result, the communication capacity is improved as compared with communication using dedicated channels. In addition, since a physical channel is shared by a plurality of mobile stations and slots are allocated according to the communication state of the mobile station, the communication capacity is improved as compared with the communication using individual channels due to the statistical multiplexing effect. As a result, compared with conventional W-CDMA, the communication capacity (accommodation efficiency) per band or transmission power is improved.

  The base station transmits data with the maximum allowable power without performing transmission power control in HS-DSCH. Here, the allowable maximum power refers to a channel (hereinafter referred to as “common channel”) that is commonly used by all mobile stations based on an upper limit transmission power determined in consideration of the transmission capability of the base station and the like. This is the power excluding the transmission power used in the channel. In addition, since HS-DSCH is a channel shared by a plurality of mobile stations, even if there are few mobile stations that perform data communication using HS-DSCH, or even when the total data communication volume using HS-DSCH is small, The station transmits data at the maximum allowable power described above.

JP-A-2005-341170

  As described above, in data communication based on HSDPA, a communication capacity per transmission power is improved under the condition that a sufficient number of mobile stations perform data communication and the mobile stations are in different communication states. However, when the condition is not satisfied, that is, when a small number of mobile stations perform data communication by HSDPA (for example, when all slots of HS-DSCH are not allocated), the statistical multiplexing effect does not function sufficiently. Further, when the communication state of the small number of mobile stations is not good, high-speed modulation and high coding rate cannot be selected in data communication with respect to these mobile stations. On the other hand, in data communication using HSDPA, data is transmitted with the allowable maximum power regardless of the number of mobile stations that perform communication using HS-DSCH. Therefore, when a small number of mobile stations perform data communication using HSDPA, there is a high possibility that the communication capacity (accommodation efficiency) per transmission power will decrease.

  Here, when data communication is performed using HS-DSCH (shared channel), data communication is performed without using HS-DSCH (that is, data communication performed using HS-DSCH). Are switched to data communication using individual channels). In this case, it is clear that the transmission power of the base station is reduced by performing data communication without using HS-DSCH, but on the other hand, it is assumed that all mobile stations cannot be accommodated on the dedicated channel. For this reason, conventionally, when HS-DSCH (shared channel) is used for data transmission, it is possible to appropriately determine whether or not to switch from HS-DSCH (shared channel) to dedicated channel. could not.

  Therefore, in one aspect of the invention, a wireless network control device and a communication which can appropriately determine whether or not to switch from a shared channel to an individual channel while using a shared channel in data transmission An object is to provide a control method.

In a first aspect, a radio network control apparatus that prepares an individual channel assigned to each mobile station and a shared channel assigned shared to the mobile station as channels for transmitting user data addressed to the mobile station from the base station Is provided.
This wireless network control device
In the transmission of user data addressed to the mobile station from the base station, a control unit that selects a transmission mode between a first transmission mode that does not use a shared channel and a second transmission mode that uses a shared channel;
When the base station is transmitting in the second transmission mode, the first transmission power that is the transmission power required for transmitting the user data when transmitting the user data destined for the mobile station in the shared channel through the dedicated channel A first processing unit for acquiring the information of
A second processing unit that acquires information on a second transmission power that is a transmission power required for transmission of user data through the shared channel when the base station is transmitting in the second transmission mode;
With
The control unit selects either the first transmission mode or the second transmission mode based on a comparison result between the first transmission power and the second transmission power.

  In a second aspect, a communication control method in the wireless network control device is provided.

  According to the disclosed wireless network control device and communication control method, it is possible to appropriately determine whether or not to switch from the shared channel to the dedicated channel while using the shared channel in data transmission.

1 is a diagram showing a radio access network including a radio network control device according to a first embodiment. The figure which shows the transmission power of the state in which the base station of 1st Embodiment is performing data communication using HS-DSCH. The figure which shows notionally the comparison process of the transmission power in the radio network control apparatus of 1st Embodiment. The figure which shows notionally the comparison process of the transmission power in the radio network control apparatus of 1st Embodiment. The block diagram which shows the structure of the radio | wireless network control apparatus and base station of 1st Embodiment. The figure which shows the hardware constitutions of the radio | wireless network control apparatus and base station of 1st Embodiment. The figure which shows the processing flow of transfer from HS-DSCH to an individual channel about transmission of the downlink user data addressed to a mobile station. The figure which shows the processing flow of transfer to a HS-DSCH from a separate channel about transmission of the downlink user data addressed to a mobile station. The figure which shows an example of the transition on the time series of the power consumption accompanying the transition of a channel.

(1) First Embodiment Hereinafter, a first embodiment will be described.
In the following description of each embodiment, the transmission mode in which the base station does not use HS-DSCH for user data transmission is an example of the first transmission mode. The transmission mode in which the base station uses HS-DSCH for transmitting user data is an example of the second transmission mode.

(1-1) Communication Control Method in Radio Access Network FIG. 1 is a diagram illustrating a radio access network (UTRAN: Universal Terrestrial Radio Access Network) including the radio network control device of the present embodiment. The radio access network shown in FIG. 1 employs a W-CDMA mobile communication system and is connected to a core network CN. The radio access network is configured by a radio network controller RNC (Radio Network Controller), a base station Node-B, and a mobile station UE. The radio network controller RNC is connected to the core network CN via the lu interface, and performs radio resource management, control of the base station Node-B, and the like. The base station Node-B is connected to the radio network controller RNC via a lub interface. The mobile station UE is configured to be connected to the base station Node-B and the radio network controller RNC via a radio interface.

FIG. 2 is a diagram illustrating transmission power in a state where the base station Node-B of the present embodiment performs data communication using HS-DSCH (shared channel). In FIG. 2, P _C is the transmission power according to common channel used in common for all mobile stations may be considered to be substantially constant throughout the base station. P _DX is transmission power by a dedicated channel (DCH: Dedicated Channel) assigned to each mobile station as a channel for transmitting dedicated data addressed to the mobile station not supporting HSDPA from the base station. P _H is the transmission power by the HS-DSCH. Maximum transmit power P _MAX of the base station Node-B is predetermined, the transmission power P _H by HS-DSCH, as shown below formula (1), the allowable maximum power, i.e., P _C from P _MAX And P _DX are used as power.

_{P H = P MAX -P C -P} DX ... (1)

  The radio network controller RNC controls whether or not HS-DSCH is used for each base station Node-B to be managed. Further, the radio network controller RNC manages whether or not each mobile station UE that has established a connection with the own device is a mobile station that can support HSDPA.

(1-2) Communication Control Method when Using HS-DSCH First, a communication control method of the radio network controller RNC when using HS-DSCH according to the present embodiment will be described.
The radio network controller RNC according to the present embodiment, when the base station Node-B is performing downlink data transmission using HS-DSCH, and performing data transmission using the HS-DSCH on a dedicated channel. The required transmission power (hereinafter referred to as “first transmission power” as appropriate) is estimated. In addition, the radio network controller RNC according to the present embodiment, when the base station Node-B is performing downlink data transmission using HS-DSCH, transmits transmission power required for the transmission (hereinafter referred to as “second” as appropriate). "Transmission power"). Then, based on the comparison result between the first transmission power and the second transmission power, the radio network controller RNC maintains data transmission by HS-DSCH or transmits data without using HS-DSCH (that is, dedicated channel). Decide whether to switch to data transmission.

The radio network controller RNC of the present embodiment uses the first transmission power (transmission power when switching to the dedicated channel) when the base station Node-B is performing downlink data transmission using HS-DSCH. ) Can be estimated as follows.
[Estimation method 1]
Even when using the HS-DSCH, the base station Node-B may establish a downlink dedicated channel connection with the mobile station UE in order to transmit information other than user data such as control data. is there. In this case, since the base station Node-B applies transmission power control to transmission using the dedicated channel, the base station Node-B knows the transmission power required for the dedicated channel for each mobile station UE. Therefore, the radio network controller RNC can estimate this transmission power (power at the time of transmission of information other than user data using a dedicated channel) as the first transmission power.

[Estimation method 2]
When the base station Node-B has not established a connection with the mobile station UE via the downlink dedicated channel of control data and user data, the radio network controller RNC transmits the address from the mobile station UE to the base station Node-B. The first transmission power can be estimated from the transmission power of the uplink dedicated channel. Since the first transmission power is the downlink transmission power, it differs from the transmission power of the uplink dedicated channel. However, in W-CDMA, transmission power control is performed in both uplink and downlink in the dedicated channel, and the uplink and downlink The above estimation is established on the assumption that the propagation environments are substantially equal. Note that the above estimation can be performed even when the uplink dedicated channel uses EUL (Enhanced UpLink; E-DPDCH is used as a physical channel). Specifically, the base station Node-B instructs the mobile station UE to increase or decrease the transmission power based on the reception quality (for example, SIR) of the uplink signal at its own station, and performs transmission power control on the uplink dedicated channel. (TPC bit). Therefore, the base station Node-B always acquires the initial transmission power of the mobile station UE from the mobile station UE, and sequentially stores instructions for increasing or decreasing the transmission power thereafter, so that the mobile station UE always Manages the uplink transmission power from. The radio network controller RNC uses the uplink transmission power of the mobile station UE managed by the base station Node-B as the first transmission power.
In this estimation method 2, unlike the estimation method 1, the transmission power of the downlink dedicated channel cannot be directly calculated. Therefore, the radio network controller RNC uses the uplink transmission power and the downlink first transmission. It is preferable that data or a conversion formula (collectively referred to as reference data) to be referred to for power conversion is provided in advance. This reference data may be in either the base station Node-B or the radio network controller RNC.

[Estimation method 3]
When the base station Node-B is performing downlink data transmission using HS-DSCH, the base station Node-B is based on the CQI (Channel Quality Indicator) that is the reception quality at the mobile station UE of data transmission using the HS-DSCH. One transmission power may be estimated. The mobile station UE may measure, for example, a received SIR as CQI. The mobile station UE measures CQI, which is reception quality in downlink data transmission, and reports it to the base station Node-B sequentially. Based on the CQI reported from the mobile station UE, the base station Node-B determines a transmission format (modulation scheme and error correction coding rate) for data transmission to the mobile station UE. Therefore, the radio network controller RNC according to the present embodiment uses the CQI reported from the mobile station UE to the base station Node-B or the transmission format determined by the base station Node-B according to the CQI. The transmission power may be estimated. Since the first transmission power is the transmission power of the downlink dedicated channel to which transmission power control is applied, the first transmission power is set according to the downlink reception quality at the mobile station UE when using HS-DSCH. It can be estimated with high accuracy.
In this estimation method 3, as in the estimation method 2, the transmission power of the downlink dedicated channel cannot be directly calculated. Therefore, the radio network controller RNC converts the CQI or the transmission format and the first transmission power. It is preferable that data or a conversion formula (collectively referred to as reference data) to be referred to in advance is provided in advance. This reference data may be in either the base station Node-B or the radio network controller RNC.

The radio network controller RNC according to the present embodiment uses the estimation method described above, and the first transmission power (individual) when the base station Node-B performs downlink data transmission using the HS-DSCH. (Transmission power when switching to a channel) is estimated. Here, when the base station Node-B is performing downlink data transmission to a plurality of mobile stations UE ₁ , UE ₂ ,..., UE _n using HS-DSCH, estimate of the transmitted power required when performing communication in the dedicated channel Te respectively _{P D1, P D2, ...,} and _{P Dn.} The total of the estimated values P _D1 , P _D2 ,..., P _Dn is defined as P _D. The radio network controller RNC of the present embodiment compares the transmission power P _H (second transmission power) based on HS-DSCH and the estimated value P _D (first transmission power) of the first transmission power. This comparison is performed in consideration of a preset threshold P _T for shifting to an individual channel and a margin P _M for avoiding frequent switching of channels caused by an estimation error of the first transmission power. .
Specifically, the radio network controller RNC according to the present embodiment changes the data transmission addressed to the mobile station UE from the data transmission by the HS-DSCH to the data transmission by the dedicated channel when the following expression (2) is satisfied. Control to switch. In Equation (2), P _M + P _T is an example of a first threshold value.

P _H > P _D + P _M + P _T (2)

  FIG. 3 is a diagram conceptually showing the comparison processing of the above formula (2) in the radio network controller RNC, and shows a case where the formula (2) is satisfied as an example.

As shown in FIG. 2, in data transmission using HS-DSCH, the maximum power P _MAX predetermined by the base station Node-B is used. Therefore, data transmission without using HS-DSCH is used. As a result, the transmission power of the base station Node-B decreases. Further, in the communication control method of the present embodiment, the transmission power in the dedicated channel is estimated in advance (that is, before switching to the dedicated channel) in a state where data transmission by HS-DSCH is performed. Therefore, it is possible to determine in advance whether there is no problem in the data transmission of the base station Node-B when the channel is shifted to the dedicated channel. That is, when Expression (2) is satisfied, it can be determined that there is no problem in the capacity of the base station Node-B even if the channel is shifted to the dedicated channel. As a result, it is possible to avoid a situation in which all mobile stations cannot be accommodated in the dedicated channel after actually shifting from the HS-DSCH to the dedicated channel.

(1-3) Communication Control Method When Using Individual Channel Next, a communication control method of the radio network controller RNC when using the individual channel according to this embodiment will be described.
The radio network controller RNC according to the present embodiment periodically acquires the transmission power of the dedicated channel from the base station Node-B when the base station Node-B is performing downlink data transmission using the dedicated channel. . Here, the transmission power of the acquisition target dedicated channel is the transmission power required for data transmission from the base station Node-B to the mobile station UE that can support HSDPA. When the dedicated channel is used, the base station Node-B controls the transmission power for each destination mobile station UE by the transmission power control, and therefore manages the transmission power for each destination mobile station UE. The base station Node-B periodically reports the downlink transmission power for each mobile station UE to the radio network controller RNC when using the dedicated channel.
Even when the radio network controller RNC uses an individual channel without using HS-DSCH for data transmission to the mobile station UE, it uses the HS-DSCH for data transmission to the mobile station UE. The required transmission power (transmission power required only for HS-DSCH) can be calculated. That is, since the radio network controller RNC knows P _DX in the equation (1) from the downlink transmission power value for each mobile station UE that is periodically reported from the base station Node-B, the equation (1) based on, it is possible to calculate the transmission power P _H when using HS-DSCH.

Radio network controller RNC according to this embodiment, when the dedicated channel used, calculating the transmission power P _H when using HS-DSCH, among the transmission of user data addressed to the mobile station UE by dedicated channel currently in use comparing the transmission power P _D required for transmission of mobile stations that can be addressed UE corresponding to HSDPA. Then, based on the comparison result, the radio network controller RNC determines whether to maintain data transmission that does not use HS-DSCH or to switch to data transmission that uses HS-DSCH. In this communication control method, the transmission power P _H when using HS-DSCH is an example of a second transmission power, the transmission power P _D by dedicated channel currently in use is an example of a first transmission power .
Specifically, the radio network controller RNC according to the present embodiment performs control so that data transmission addressed to the mobile station UE is switched from the dedicated channel to the HS-DSCH when the following expression (3) is satisfied. In Equation (2), _PT is an example of the second threshold value.

P _H <P _D + P _T (3)

FIG. 4 is a diagram conceptually showing the comparison processing of the above formula (3) in the radio network controller RNC, and shows a case where the formula (3) is satisfied as an example.
Here, since the maximum power P _MAX of the base station Node-B are predetermined, it is not possible to transmit power P _D by dedicated channel moves from beyond the P _H to the HS-DSCH, P _D is some it is determined that the transition from approaching the P _H to the HS-DSCH. In order to prevent frequent channel transition between the dedicated channel and the HS-DSCH, the threshold P _M is set in the above-described equation (2) (determination when shifting from the HS-DSCH to the dedicated channel). Is provided.

By switching from data transmission not using HS-DSCH to data transmission using HS-DSCH, the transmission power of the entire base station Node-B becomes the maximum transmission power P _MAX , so that the power consumption of the base station Node-B This is disadvantageous. On the other hand, since data transmission using HS-DSCH has excellent accommodation efficiency, data transmission to a number of mobile stations UE that cannot be realized because data transmission using dedicated channels exceeds P _MAX. Can be realized by data transmission using HS-DSCH. Therefore, it is preferable that the threshold value _PT in the above equation (3) is determined in advance from the viewpoint of improving the accommodation efficiency of the mobile station UE in the base station Node-B.

Further, the threshold value _PT may be determined from another viewpoint.
In a situation where the number of mobile stations UE subject to data transmission by HS-DSCH increases with the passage of time, the transmission power is limited by the maximum value P _MAX so that the base station Node-B can A mobile station UE that cannot transmit data may occur. However, in order to increase the number of mobile stations UE accommodated, a certain transition time is required for switching from dedicated channels to HS-DSCH. Therefore, the threshold value _PT may be determined as a margin for preventing the generation of a mobile station UE in which the base station Node-B cannot transmit data using the dedicated channel during the transition time.

When data communication is performed using dedicated channels without using HS-DSCH, the total transmission power gradually increases due to factors such as an increase in the number of mobile stations UE performing data communication within a cell. A case where the transmission power approaches the maximum value P _MAX of B can be considered. In such a case, not all mobile stations can be accommodated on the dedicated channel in the near future, which may hinder the data transmission of the base station Node-B. Therefore, in the communication control method of the present embodiment, in a state where data transmission is performed on the dedicated channel, the remaining power of transmission power on the dedicated channel is set to the threshold value P in advance (that is, before switching to HS-DSCH). _{Since the} evaluation is performed based on _T , it is possible to appropriately determine switching to HS-DSCH.

(1-4) Configurations of Radio Network Control Device and Base Station Next, configurations of the radio network control device and the base station according to the present embodiment will be described with reference to FIG. FIG. 5 is a block diagram showing the configurations of the radio network control device and the base station of the present embodiment. In FIG. 5, the flow of the control signal is indicated by a thin line, and the flow of the downstream data signal (user data) is indicated by a thick line. In FIG. 5, the radio network controller RNC and the base station Node-B are connected by a lub interface.

[Base station configuration]
As shown in FIG. 5, the base station Node-B includes an antenna 10, a transmission / reception unit 11, an HS-DSCH baseband processing unit 12, and an individual channel baseband processing unit 13.

The transmission / reception unit 11 includes a band limiting filter, a low noise amplifier (LNA), a local frequency oscillator, a quadrature demodulator, an AGC (Automatic Gain Control) amplifier, an A / D (Analog to Digital) converter, and the like. At the time of reception, the transmission / reception unit 11 converts the uplink RF signal received by the antenna 10 into a digital baseband signal. The transceiver 11 further separates the baseband signal into a data signal, a control signal, and a reference signal (for example, a known series of pilot signals).
The transmission / reception unit 11 multiplexes a data signal, a control signal, and a reference signal as a baseband signal addressed to the mobile station UE at the time of transmission. The transmission / reception unit 11 includes a D / A (Digital to Analog) converter, a local frequency transmitter, a mixer, a power amplifier, a filter, and the like. And the transmission / reception part 11 radiates | emits a baseband signal from the antenna 10 to space, after carrying out up-conversion etc. from a baseband frequency to a radio frequency.

  The HS-DSCH baseband processing unit 12 transmits and receives control signals to and from the HS-DSCH processing unit 22 of the radio network control device RNC. Further, when transmitting HS-DSCH data signals, the HS-DSCH baseband processing unit 12 performs physical layer processing such as HS-DSCH channel coding, mapping to the physical channel HS-PDSCH, spreading processing, and modulation processing. Process. On the other hand, when receiving HS-DSCH user data, the HS-DSCH baseband processing unit 12 performs physical layer processing such as demodulation processing, despreading processing, demapping from the physical channel HS-PDSCH, and channel decoding. .

HS-DSCH baseband processing unit 12, when transmitting data signals HS-DSCH calculates the transmit power P _H by HS-DSCH (shared channel), successively, the radio network controller information for transmission power P _H Report to the resource management unit 20 through the HS-DSCH processing unit 22 of the RNC.
Calculation of the transmission power P _H is conducted as follows. That is, the dedicated channel baseband processing unit 13 collects transmission power P _DX (transmission power addressed to the mobile station UE not compatible with HSDPA) by the dedicated channel in the above formula (1). The HS-DSCH baseband processing unit 12 acquires the transmission power P _DX from the dedicated channel baseband processing unit 13. In the equation _{(1), P MAX} is known, the transmission power _{P C} by common channel may substantially considered constant. Accordingly, HS-DSCH baseband processing unit 12 can calculate a transmit power P _H by calculating the equation (1).

  The dedicated channel baseband processing unit 13 transmits and receives control signals to and from the dedicated channel processing unit 23 of the radio network controller RNC. Also, the dedicated channel baseband processing unit 13 performs physical layer processing for transmission / reception of the data signal of the dedicated channel, as with the HS-DSCH baseband processing unit 12. In this case, the dedicated channel baseband processing unit 13 performs a process of mapping the DCH signal to the physical channel DPCH when transmitting the dedicated channel data signal.

The dedicated channel baseband processing unit 13 performs uplink and downlink transmission power control in the dedicated channel with the mobile station UE. For example, when performing downlink transmission power control, the transmission / reception unit 11 transmits a reference signal to the mobile station UE. The mobile station UE measures the SIR as the reception quality based on the reference signal received from the base station Node-B, and reports the measured SIR to the base station Node-B using the uplink signal. The dedicated channel baseband processing unit 13 compares the SIR reported from the mobile station UE with the target SIR, and controls the amplification factor of the power amplifier of the transmission / reception unit 11 based on the comparison result. At this time, the dedicated channel processing unit 23 of the radio network controller RNC notifies the dedicated channel baseband processing unit 13 of the target SIR in advance. Also, the mobile station UE can notify the base station Node-B of a TPC (Transmit Power Control) bit for requesting an increase or decrease in downlink transmission power.
The dedicated channel baseband processing unit 13 manages the downlink transmission power in the dedicated channel for each mobile station UE, and sequentially reports to the resource management unit 20 through the dedicated channel processing unit 23 of the radio network controller RNC. .
The case where the transmission power control of the uplink signal from the mobile station UE is performed is similar to the case of the downlink. In this case, for example, the base station Node-B may notify the mobile station UE of a TPC bit for requesting increase or decrease in uplink transmission power. At this time, as described above, the history of the TPC bits notified to the mobile station UE is used to estimate the first transmission power when the base station Node-B is performing downlink data transmission using HS-DSCH. Can be used (see estimation method 2 above).

[Configuration of wireless network controller]
As shown in FIG. 5, the radio network controller RNC includes functional blocks of a resource management unit 20, a radio link control unit 21, an HS-DSCH processing unit 22, and a dedicated channel processing unit 23. The individual channel processing unit 23 is an example of a first processing unit. The HS-DSCH processing unit 22 is an example of a second processing unit. The resource management unit 20 is an example of a control unit.

When the mobile station UE is connected to the core network CN and data transmission / reception is performed between the core network CN and the mobile station UE, the resource management unit 20 secures resources of each unit for the data transmission / reception, Controls the flow of data signals (user data). Specifically, the resource management unit 20 transmits the downlink HS-DSCH data signal from the core network CN via the radio link control unit 21 and the HS-DSCH processing unit 22 to the base station Node-B. The flow of the data signal is controlled so as to be transmitted to the HS-DSCH baseband processing unit 12. In addition, the resource management unit 20 uses the dedicated channel baseband processing of the base station Node-B via the radio link control unit 21 and the dedicated channel processing unit 23 for the downlink dedicated channel data signal from the core network CN. The flow of the data signal is controlled so as to be sent to the unit 13. In transmitting these data signals, the resource management unit 20 reserves or releases resources of the radio link control unit 21, the HS-DSCH processing unit 22, and the dedicated channel processing unit 23 as necessary.
The resource management unit 20 also performs L2 / L3 protocol processing on the control plane.

Resource management unit 20, sequentially, HS-DSCH baseband processing unit 12 of the base station Node-B, individually from the channel base band processing unit 13, transmission power P _H by _HS-DSCH, transmission power P _D by the dedicated channel Receive a report. Then, the resource management unit 20 performs comparison processing according to the above-described equation (2) or (3) and channel selection processing (HS-DSCH or individual channel) based on the comparison processing. At this time, the threshold values P _M and P _T in each equation are values set in advance in the resource management unit 20.

The radio link control unit 21 includes a buffer that temporarily stores the downlink data signal from the core network CN. The resource management unit 20 manages whether or not HSDPA can be supported for each mobile station UE. Therefore, under the control of the resource management unit 20, the radio link control unit 21 stores data in the buffer at different data transmission rates depending on whether or not the data transmission destination mobile station UE is a mobile station capable of supporting HSDPA. Data is transmitted to the HS-DSCH processing unit 22 or the dedicated channel processing unit 23.
The radio link control unit 21 also performs L2 / L3 protocol processing on the user plane.

  The HS-DSCH processing unit 22 performs channel processing for HS-DSCH. For example, the HS-DSCH processing unit 22 includes a scheduler, and assigns a slot to each HS-DSCH mobile station UE and selects a transmission format. Note that, when assigning slots and selecting a transmission format, the HS-DSCH processing unit 22 uses the downlink SIR reported from the mobile station UE to the base station Node-B as the HS-DSCH baseband of the base station Node-B. Obtained from the processing unit 12.

  The dedicated channel processing unit 23 performs channel processing for the dedicated channel. The dedicated channel processing unit 23 sets a target SIR in transmission power control, and notifies the dedicated channel baseband processing unit 13 of the base station Node-B of the target SIR. In the configuration shown in FIG. 5, the dedicated channel processing unit 23 also performs processing on the common channel for the entire cell of the base station Node-B.

FIG. 6 is a diagram illustrating a hardware configuration example of the radio network control device and the base station according to the first embodiment. As shown in FIG. 6, the base station Node-B includes a transceiver 11, a DSP (Digital Signal Processor) 120, a CPU (Central Processing Unit) 130, and a memory 140. In the base station Node-B, the HS-DSCH baseband processing unit 12 and the dedicated channel baseband processing unit 13 can be realized by the DSP 120 and the CPU 130. The memory 140 is a volatile and / or non-volatile storage device, and can be appropriately used for the processing of the CPU 130.
As shown in FIG. 6, the radio network controller RNC includes a DSP 220, a CPU 230, and a memory 240. In the radio network controller RNC, the resource management unit 20, the radio link control unit 21, the HS-DSCH processing unit 22, and the dedicated channel processing unit 23 can be realized by the DSP 220 and the CPU 230. The memory 240 is a volatile and / or non-volatile storage device, and can be appropriately used for the processing of the CPU 230.

(1-5) Processing in Radio Access Network Next, with reference to FIG. 7 and FIG. 8, processing between the radio network controller RNC, the base station Node-B, and the mobile station UE in the radio access network of the present embodiment Will be described. FIG. 7 shows a processing flow of transition from HS-DSCH to dedicated channels for transmission of downlink user data addressed to mobile station UE. FIG. 8 shows a processing flow for shifting from the dedicated channel to the HS-DSCH for downlink user data transmission addressed to the mobile station UE.

[Transition processing from HS-DSCH to individual channels]
In FIG. 7, first, the base station Node-B uses the maximum transmission power P _MAX in the entire base station Node-B when transmitting user data using HS-DSCH. At this time, HS-DSCH baseband processing unit 12 of the base station Node-B is sequentially calculates the transmission power P _H required for data transmission of the HS-DSCH (step S10). Further HS-DSCH baseband processing unit 12, the information of the transmission power P _H, reported through HS-DSCH processing unit 22 of the radio network controller RNC to the resource management unit 20 (step S20). The calculation of the transmission power P _H has a transmission power P _C by a common channel used in common for all mobile stations, transmitted by the dedicated channel used for transmission of user data in the downlink addressed to the mobile station UE that does not correspond to the HSDPA power P _DX is required (see Equation (1)). Here, the transmission power P _C by a common channel can be considered a constant value throughout the base station Node-B. Further, the HS-DSCH baseband processing unit 12 acquires the transmission power P _DX for the dedicated channel from the dedicated channel baseband processing unit 13.

Next, the dedicated channel baseband processing unit 13 of the base station Node-B estimates the transmission power required when transmitting user data addressed to the mobile station UE through the dedicated channel for each mobile station UE to be transmitted. That is, the dedicated channel baseband processing unit 13 calculates estimated values P _D1 , P _D2 ,..., P _Dn for each mobile station UE that is the transmission target of the transmission power of the dedicated channel (step S30). The estimation method of the transmission power of the dedicated channel can employ any of the estimation methods 1 to 3 described above.
The dedicated channel baseband processing unit 13 reports the estimated values P _D1 , P _D2 ,..., P _Dn to the resource management unit 20 through the dedicated channel processing unit 23 of the radio network controller RNC (step S40).

The resource management unit 20 of the radio network controller RNC obtains a value P _D obtained by summing the P _D1 , P _D2 ,..., P _Dn . More resource management unit 20, and the P _D, the process of comparing the transmission power P _H required for the acquired data transmission HS-DSCH in step S20 (step S50). Specifically, the resource management unit 20 performs the determination process of the above equation (2). As a result, it is assumed here that P _H > P _D + P _M + P _T is established, and the resource management unit 20 shifts transmission of user data addressed to the mobile station UE by HS-DSCH to transmission by dedicated channels. Decide what to do.
Note that the reports in steps S20 and S40 are performed at a predetermined interval T, for example, and the resource management unit 20 may sequentially perform the comparison process in step S50 at an interval T (hereinafter referred to as a determination interval).

  Thereafter, the resource management unit 20 transmits a channel transition instruction message to the mobile station UE (step S60). This channel transition instruction message is transmitted to the mobile station UE via the resource management unit 20 → the radio link control unit 21 → the dedicated channel processing unit 23 → the base station Node-B (the dedicated channel baseband processing unit 13). . When receiving the channel transition instruction message, the mobile station UE returns a channel transition response message to the resource management unit 20 (step S70). When the resource management unit 20 receives the channel transition response message from the mobile station UE, the resource management unit 20 sends an HS-DSCH transmission stop instruction message to the base station Node-B (HS-DSCH baseband processing unit 12) through the HS-DSCH processing unit 22. (Step S80). In response to this transmission stop instruction message, the base station Node-B (HS-DSCH baseband processing unit 12) stops transmission of user data by HS-DSCH addressed to the mobile station UE (step S90).

In the process flow of FIG. 7, the transmission power P _H by HS-DSCH in the base station Node-B side, and calculates the estimated value P _D of the transmission power by the dedicated channel, a radio network controller RNC and P _H and configured to acquire information of P _D, but is not limited thereto. From the base station Node-B to the radio network controller destined RNC, it transmits information required for calculating the P _H and / or P _D, to perform a calculation of P _H and / or P _D at the radio network controller RNC side It may be.

[Transition from individual channel to HS-DSCH]
In FIG. 8, first, the base station Node-B performs transmission power control with the mobile station UE when transmitting user data using a dedicated channel, and transmits user data addressed to each mobile station UE. It manages the transmission power required for. Therefore, the dedicated channel baseband processing unit 13 of the base station Node-B transmits the transmission power required for transmitting the user data addressed to the mobile station UE that can support HSDPA among the transmission of user data addressed to the mobile station UE by the dedicated channel. P _D1 , P _D2 ,..., P _Dn are collected (step S100). Further, the dedicated channel baseband processing unit 13 reports the collected transmission powers P _D1 , P _D2 ,..., P _{Dn to} the resource management unit 20 through the dedicated channel processing unit 23 of the radio network controller RNC (step S110). ). Thereby, the resource management unit 20 obtains information on the transmission power P _D that is the sum of the transmission powers P _D1 , P _D2 ,..., P _Dn of the individual channels for each mobile station UE.

Next, of the transmission of user data addressed to the mobile station UE using the dedicated channel, the resource management unit 20 transmits the transmission power required when the user data addressed to the mobile station UE that can support HSDPA is transmitted using HS-DSCH. calculating the P _H (step S120). In calculating the transmission power P _H, the transmission power P _C by a common channel used in common for all mobile stations may be considered to be substantially constant, the transmission of user data by the dedicated channel addressed to the mobile station UE is non-corresponding to the HSDPA power P Information on _DX has been acquired in step S110. Therefore, the resource management unit 20, according to the above (1), it is possible to calculate the transmission power P _H required when performing in HS-DSCH.

Next, the resource management unit 20 performs a P _H calculated, the processing of comparing the P _D is the sum of the transmission power of the dedicated channels of mobile stations that can be addressed UE corresponding to HSDPA in Step S120 (Step S130) . Specifically, the resource management unit 20 performs the determination process of the above equation (3). As a result, it is assumed here that P _H <P _D + P _T is established, and the resource management unit 20 shifts the transmission of user data addressed to the mobile station UE by the dedicated channel to the transmission by HS-DSCH. To decide.
Note that the report in step S110 is performed at a predetermined interval T, for example, and the resource management unit 20 may similarly perform the comparison process in step S130 sequentially at the determination interval T.

Thereafter, the resource management unit 20 sends an HS-DSCH transmission start instruction message to the base station Node-B through the HS-DSCH processing unit 22 (step S140). When receiving the HS-DSCH transmission start instruction message, the base station Node-B starts transmission of user data by HS-DSCH by the HS-DSCH baseband processing unit 12 (step S150). By this stage, the HS-DSCH processing unit 22 completes slot assignment and transmission format selection for each HS-DSCH mobile station UE. When the HS-DSCH baseband processing unit 12 of the base station Node-B starts data transmission by HS-DSCH, the HS-DSCH transmission start response message is returned to the resource management unit 20 (step S160).
Next, the resource management unit 20 transmits a channel shift instruction message to the mobile station UE (step S170). This channel transition instruction message is transmitted to the mobile station UE via the resource management unit 20 → the radio link control unit 21 → the dedicated channel processing unit 23 → the base station Node-B (the dedicated channel baseband processing unit 13). . Upon receiving the channel transition instruction message, the mobile station UE performs channel transition processing (for example, setting for receiving processing in the assigned slot and the selected transmission format), and then performs resource management on the channel transition response message. Is transmitted to the unit 20 (step S180).

(2) Second Embodiment Hereinafter, a second embodiment of the present invention will be described.

(2-1) Communication control method when using HS-DSCH According to the communication control method when using (1-2) HS-DSCH described above, transmission of user data addressed to the mobile station UE is transmitted from the HS-DSCH to a dedicated channel. If this is done, the data transmission rate may drop rapidly. Therefore, the radio network controller RNC monitors the data transmission rate in order to avoid a sudden decrease in the data transmission rate addressed to the mobile station UE. Then, based on the determination result of the data transmission rate in addition to the determination condition according to the above equation (2), the transition of data transmission from the HS-DSCH to the dedicated channel may be determined.

  In this case, the radio link controller 21 of the radio network controller RNC calculates the data transmission rate of user data transmitted from the core network CN for each mobile station UE that is a transmission destination. At this time, the radio link control unit 21 calculates the data transmission rate based on the amount of data transmitted at a predetermined time, for example. At this time, the predetermined time serving as a reference for measuring the data amount can be arbitrarily set. For example, it may be the same as the determination interval in FIGS. 7 and 8 or an integral multiple of the determination interval. The radio link control unit 21 notifies the resource management unit 20 of the calculated data transmission rate, and the resource management unit 20 performs data transmission from the HS-DSCH to the dedicated channel based on the notified data transmission rate. Determine whether or not.

  Here, in the resource management unit 20, the data transmission rate by the dedicated channel corresponding to the selection of the CDMA code is known for each mobile station UE that is the transmission destination. That is, in W-CDMA, an OVSF (Orthogonal Variable Spreading Factor) code is used as a channelization code, but the resource management unit 20 has a predetermined condition (for example, the data retention amount in the radio link control unit 21 is equal to or less than a predetermined amount). The code of the spreading factor for obtaining the speed of the physical channel satisfying (1) is selected for each individual channel. As a result, in W-CDMA with a constant chip rate, the data transmission rate of the dedicated channel is automatically determined.

Hereinafter, the transmission rate for each individual channel of the transmission destination, which is known in the resource management unit 20, is referred to as _RD . Also obtained by the radio link control unit 21, the average value of the data transmission rate of a certain past period as the R _AVE, predetermined threshold (margin) and R _M. At this time, if the following equation (4) is satisfied, that is, if the average value of the data transmission rate in the past fixed period is lower than the data transmission rate of the dedicated channel even if the margin is taken into account, the base station Node- It can be determined that the transition from HS-DSCH to the dedicated channel is possible without any problem in the capacity of B.

R _AVE <R _D -R _M (4)

Even if the equation (4) is not satisfied, the resource management unit 20 can shift from the HS-DSCH to the dedicated channel when the following equation (5) is satisfied (when the margin is not considered). You may judge. For example, if R _AVE is a constant value for a certain period, the data transmission rate will not increase rapidly in the future, and the margin may not be considered. As shown in Equation (6), when the maximum data transmission rate in the past is R _MAX , if R _AVE does not exceed the R _MAX for a certain period, the data transmission rate will rapidly increase in the future. Considering that there is no increase, the transition from HS-DSCH to the dedicated channel may be permitted.

R _D −R _M <R _AVE <R _D (5)

R _MAX <R _D (6)

On the other hand, when the above formula (4) is not satisfied, it is preferable not to allow the transition from the HS-DSCH to the dedicated channel. In this case, the threshold value (margin) R _M in the formula (4) is, HS-DSCH according to the number of the destination mobile station UE to perform data transmission, the total data rate of the addressed all the mobile stations UE, the base station Node- You may adjust by parameters, such as the degree of tightness of the power supply power of B, or the magnitude of the power saving amount obtained by shifting to an individual channel.
For example, HS-DSCH by number of the destination mobile station UE to perform data transmission, as the sum of the data transmission rate of addressed all of the mobile station UE is large, a larger threshold R _M as hardly proceeds to an individual channel . The threshold _RM is reduced so that the more the power source power of the base station Node-B is tighter, the easier it is to shift to the dedicated channel. The threshold _RM is decreased so that the power saving amount obtained by shifting to the dedicated channel is larger, so that the shift to the dedicated channel is easier.

(2-2) Communication control method when using dedicated channel When the transmission of user data addressed to the mobile station UE is changed from HS-DSCH to dedicated channel and then returned to data transmission by HS-DSCH, the base station Node-B Since there is no advantage in the overall transmission power, the channel transition may be determined based on other conditions without performing the comparison of the transmission power shown in Expression (3). For example, among mobile station UEs that are transmission destinations of data transmission on dedicated channels, the number of mobile station UEs that can support HSDPA, the total data transmission rate for all mobile station UEs, mobile station UE units or all Based on parameters such as the data retention amount of data addressed to the mobile station UE, the channel may be returned from the dedicated channel to the HS-DSCH. In this case, when each parameter value is larger than a predetermined value, the resource management unit 20 decides to return to data transmission from the dedicated channel to the HS-DSCH from the viewpoint of increasing the capacity of the base station Node-B. To do.

  Although the embodiments of the present invention have been described in detail above, the wireless network control device and the communication control method of the present invention are not limited to the above embodiments, and various improvements and modifications can be made without departing from the spirit of the present invention. Of course, you may do.

For example, in the transition of the channel between the HS-DSCH and the dedicated channel when transmitting user data, the power consumption of the radio network controller RNC and the base station Node-B temporarily increases due to the process associated with the transition. . FIG. 9 shows an example of a transition in time series of power consumption accompanying this channel transition. In FIG. 9, PH _{→ D} indicates the power consumption associated with the transition from the HS-DSCH to the dedicated channel, and PD _{→ H} indicates the power consumption associated with the transition from the dedicated channel to the HS-DSCH. In FIG. 9, it is assumed that channel transition determination is performed at every predetermined determination interval T. Here, at the time of channel transition, power consumption of PH _{→ D} or PD _{→ H} is generated. Therefore, even if this power consumption is taken into account, the power consumption when transitioning from HS-DSCH to an individual channel is performed. It is preferable to set the determination interval T and / or the threshold value P _T so as to obtain a saving effect.

  In addition, when HS-DSCH is not used, power is consumed by cutting off power supply to the HS-DSCH processing unit 22 of the radio network controller RNC and the HS-DSCH baseband processing unit 12 of the base station Node-B. Electric power can be reduced. In this case, when HS-DSCH is used again, it takes a certain amount of time to restore the function by turning on the power again to the HS-DSCH processing unit 22 and the HS-DSCH baseband processing unit 12. It is preferable to set the determination interval T in consideration of time.

  Regarding the above embodiments, the following additional notes are disclosed.

(Appendix 1)
As a channel for transmitting user data addressed to a mobile station from a base station, a radio network control device that prepares an individual channel assigned to each mobile station and a shared channel assigned shared to the mobile station,
In the transmission of user data addressed to the mobile station from the base station, a control unit that selects a transmission mode between a first transmission mode that does not use a shared channel and a second transmission mode that uses a shared channel;
The first transmission power required for transmitting the user data when the base station is transmitting in the second transmission mode and transmitting the user data addressed to the mobile station in the shared channel through the dedicated channel. A first processing unit for acquiring transmission power information;
A second processing unit that acquires information on a second transmission power that is a transmission power required for transmitting the user data through a shared channel when the base station is transmitting in the second transmission mode;
With
The control unit selects either the first transmission mode or the second transmission mode based on a comparison result between the first transmission power and the second transmission power.
Wireless network control device.

(Appendix 2)
The controller is
When the base station is transmitting in the second transmission mode, the first transmission mode is changed on condition that the first transmission power is smaller than a value obtained by subtracting a predetermined first threshold from the second transmission power. Characterized by choosing,
The wireless network control device according to attachment 1.

(Appendix 3)
The controller is
When the base station is transmitting in the second transmission mode, the first transmission power is smaller than a value obtained by subtracting a predetermined first threshold from the second transmission power, and an average transmission rate in a past predetermined period. The first transmission mode is selected on the condition that is lower than a predetermined transmission rate,
The wireless network control device according to attachment 1.

(Appendix 4)
The controller is
When the base station is transmitting in the first transmission mode, the second transmission mode is selected when the first transmission power is larger than a value obtained by subtracting a predetermined second threshold from the second transmission power. It is characterized by
The wireless network control device according to appendix 1 or 2.

(Appendix 5)
The controller is
When a base station is transmitting in the first transmission mode, the number of mobile stations that can communicate on the shared channel among the mobile stations that communicate user data under the base station is greater than or equal to a predetermined threshold Or the sum of the transmission speeds of user data communications performed by mobile stations under the base station is equal to or greater than a predetermined threshold, or data retention of user data of mobile stations under the base station The second transmission mode is selected on condition that the amount is equal to or greater than a predetermined threshold.
The wireless network control device according to appendix 1 or 2.

(Appendix 6)
Use a shared channel in a radio network controller that prepares an individual channel assigned to each mobile station and a shared channel assigned shared to the mobile station as channels for transmitting user data addressed to the mobile station from the base station A communication control method for selecting a transmission mode between a first transmission mode that is not performed and a second transmission mode that uses a shared channel,
The first transmission power required for transmitting the user data when the base station is transmitting in the second transmission mode and transmitting the user data addressed to the mobile station in the shared channel through the dedicated channel. Get transmission power information,
When the base station is transmitting in the second transmission mode, obtain information on the second transmission power that is the transmission power required to transmit the user data through the shared channel;
Based on a comparison result between the first transmission power and the second transmission power, the first transmission mode or the second transmission mode is selected.
A communication control method.

(Appendix 7)
When the base station is transmitting in the second transmission mode, the first transmission mode is changed on condition that the first transmission power is smaller than a value obtained by subtracting a predetermined first threshold from the second transmission power. Selecting, including,
The communication control method according to attachment 6.

(Appendix 8)
When the base station is transmitting in the second transmission mode, the first transmission power is smaller than a value obtained by subtracting a predetermined first threshold from the second transmission power, and an average transmission rate in a past predetermined period. Selecting a first transmission mode on the condition that is lower than a predetermined transmission rate,
The communication control method according to attachment 6.

(Appendix 9)
When the base station is transmitting in the first transmission mode, the second transmission mode is selected when the first transmission power is larger than a value obtained by subtracting a predetermined second threshold from the second transmission power. Including,
The communication control method according to appendix 6 or 7.

(Appendix 10)
When a base station is transmitting in the first transmission mode, the number of mobile stations that can communicate on the shared channel among the mobile stations that communicate user data under the base station is greater than or equal to a predetermined threshold Or the sum of the transmission speeds of user data communications performed by mobile stations under the base station is equal to or greater than a predetermined threshold, or data retention of user data of mobile stations under the base station Selecting the second transmission mode on the condition that the amount is equal to or greater than a predetermined threshold,
The communication control method according to appendix 6 or 7.

(base station)
DESCRIPTION OF SYMBOLS 10 ... Antenna 11 ... Transmission / reception part 12 ... HS-DSCH baseband process part 13 ... Dedicated channel baseband process part (radio network control apparatus)
20 ... Resource management unit 21 ... Radio link control unit 22 ... HS-DSCH processing unit 23 ... Dedicated channel processing unit

Claims (5)

As a channel for transmitting user data addressed to a mobile station from a base station, a radio network control device that prepares an individual channel assigned to each mobile station and a shared channel assigned shared to the mobile station,
In the transmission of user data addressed to the mobile station from the base station, a control unit that selects a transmission mode between a first transmission mode that does not use a shared channel and a second transmission mode that uses a shared channel;
The first transmission power required for transmitting the user data when the base station is transmitting in the second transmission mode and transmitting the user data addressed to the mobile station in the shared channel through the dedicated channel. A first processing unit for acquiring transmission power information;
A second processing unit that acquires information on a second transmission power that is a transmission power required for transmitting the user data through a shared channel when the base station is transmitting in the second transmission mode;
With
When the base station is transmitting in the second transmission mode, the control unit is configured such that the first transmission power is smaller than a value obtained by subtracting a predetermined first threshold value from the second transmission power, and a predetermined value in the past. The first transmission mode is selected on condition that the average transmission rate in the period is lower than the predetermined transmission rate ,
Wireless network control device. As a channel for transmitting user data addressed to a mobile station from a base station, a radio network control device that prepares an individual channel assigned to each mobile station and a shared channel assigned shared to the mobile station,
In the transmission of user data addressed to the mobile station from the base station, a control unit that selects a transmission mode between a first transmission mode that does not use a shared channel and a second transmission mode that uses a shared channel;
The first transmission power required for transmitting the user data when the base station is transmitting in the second transmission mode and transmitting the user data addressed to the mobile station in the shared channel through the dedicated channel. A first processing unit for acquiring transmission power information;
A second processing unit that acquires information on a second transmission power that is a transmission power required for transmitting the user data through a shared channel when the base station is transmitting in the second transmission mode;
With
The controller is
When the base station is transmitting in the first transmission mode, the total transmission speed of user data communication performed by the mobile stations under the base station is equal to or greater than a predetermined threshold, or the base station The second transmission mode is selected on the condition that the data retention amount of the user data of the mobile station under the station is equal to or greater than a predetermined threshold,
Wireless network control device. The controller is
When the base station is transmitting in the second transmission mode, the first transmission mode is changed on condition that the first transmission power is smaller than a value obtained by subtracting a predetermined first threshold from the second transmission power. Characterized by choosing,
The radio network control device according to claim 1 or 2 . Use a shared channel in a radio network controller that prepares an individual channel assigned to each mobile station and a shared channel assigned shared to the mobile station as channels for transmitting user data addressed to the mobile station from the base station A communication control method for selecting a transmission mode between a first transmission mode that is not performed and a second transmission mode that uses a shared channel,
The first transmission power required for transmitting the user data when the base station is transmitting in the second transmission mode and transmitting the user data addressed to the mobile station in the shared channel through the dedicated channel. Get transmission power information,
When the base station is transmitting in the second transmission mode, obtain information on the second transmission power that is the transmission power required to transmit the user data through the shared channel;
When the base station is transmitting in the second transmission mode, the first transmission power is smaller than a value obtained by subtracting a predetermined first threshold from the second transmission power, and an average transmission rate in a past predetermined period. The first transmission mode is selected on the condition that is lower than a predetermined transmission rate .
A communication control method. Use a shared channel in a radio network controller that prepares an individual channel assigned to each mobile station and a shared channel assigned shared to the mobile station as channels for transmitting user data addressed to the mobile station from the base station A communication control method for selecting a transmission mode between a first transmission mode that is not performed and a second transmission mode that uses a shared channel,
The first transmission power required for transmitting the user data when the base station is transmitting in the second transmission mode and transmitting the user data addressed to the mobile station in the shared channel through the dedicated channel. Get transmission power information,
When the base station is transmitting in the second transmission mode, obtain information on the second transmission power that is the transmission power required to transmit the user data through the shared channel;
When the base station is transmitting in the first transmission mode, the total transmission speed of user data communication performed by the mobile stations under the base station is equal to or greater than a predetermined threshold, or the base station The second transmission mode is selected on condition that the data retention amount of the user data of the mobile station under the station is equal to or greater than a predetermined threshold.
A communication control method.

Images