JP4105920B2 - Target SIR setting method for outer loop transmission power control - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a target SIR setting method for outer loop transmission power control.
[0002]
[Prior art]
In the field of wireless communication systems, HSDPA (High Speed Downlink Packet Access) has been proposed in which a plurality of communication terminals share a high-speed and large-capacity downlink channel and perform high-speed packet transmission on the downlink. Recently, a technique for increasing the packet transmission speed of the uplink (this technique is hereinafter referred to as Fast-UL (Fast-Uplink) in this specification) has been studied. In HSDPA, a plurality of channels such as HS-PDSCH (High Speed-Physical Downlink Shared Channel), A-DPCH (Associated-Dedicated Physical Channel), and HS-DPCCH (High Speed-Dedicated Physical Control Channel) are used. Similarly, in Fast-UL, a plurality of channels such as HS-PUSCH (High Speed-Physical Uplink Shared Channel), A-DPCH, and HS-DPCCH are considered to be used.
[0003]
The HS-PDSCH is a downlink shared channel used for packet transmission. HS-PUSCH is an uplink shared channel used for packet transmission. A-DPCH is an uplink or downlink dedicated associated channel associated with the shared channel, and transmits a pilot signal, a TPC (Transmission Power Control) command, a control signal for maintaining communication, and the like. HS-DPCCH is an uplink or downlink dedicated control channel, and a signal for controlling a shared channel such as an ACK signal, a NACK signal, or a CQI (Channel Quality Indicator) signal is transmitted. The ACK signal is a signal indicating that the high-speed packet transmitted from the base station or the communication terminal can be correctly demodulated at the communication terminal or the base station, and the NACK signal is transmitted from the base station or the communication terminal. The high-speed packet is a signal indicating that the communication terminal or the base station cannot correctly demodulate. The CQI is a signal created based on channel quality, for example, a signal indicating a combination of a packet modulation scheme, block size, transmission power adjustment value, and the like. In HSDPA, the communication terminal uses this CQI to notify the communication partner of the modulation scheme, block size, transmission power adjustment value, and the like desired by the communication terminal. The Fast-UL CQI is also a signal created based on the channel quality, but its specific content has not been determined.
[0004]
In Fast-UL, both A-DPCH and HS-DPCCH exist in both the uplink and downlink directions, and the CQI is transmitted via the HS-DPCCH in the uplink and via the HS-DPCCH in the downlink. An ACK signal / NACK signal is transmitted. In contrast, in HSDPA, A-DPCH has both an uplink direction and a downlink direction, but HS-DPCCH has only an uplink direction, and CQI and ACK signal / NACK signal are transmitted via HS-DPCCH in the uplink direction. Is transmitted. Soft handover (SHO) is applied to the A-DPCH. In contrast, hard handover (HHO) is applied to HS-PDSCH, HS-PUSCH, and HS-DPCCH, and HS-PDSCH, HS-PUSCH, and HS-DPCCH are always connected to only one base station. Moreover, the timing at which HS-PDSCH or HS-PUSCH is HHO is the same as the timing at which HS-DPCCH is HHO.
[0005]
Also, outer loop transmission power control may be used for transmission power control in HSDPA or Fast-UL. In the outer loop transmission power control, the target SIR is raised or lowered according to the reception quality in order to keep the reception quality at the required quality. Then, a TPC command is created based on the comparison result between the target SIR and the received SIR. As the reception quality, BLER (Block Error Rate) based on an error detection result (CRC result) by CRC (Cyclic Redundancy Check) is used. When CRC = OK, the target SIR is decreased by Dec, and when CRC = NG, the target SIR is increased by Inc. When the target BLER is BLER_T, the relationship between Dec and Inc is expressed by the following equation. However, Inc> 0.
Inc × BLER_T = Dec × (1−BLER_T) (1)
[0006]
[Problems to be solved by the invention]
In HSDPA and Fast-UL, outer-loop transmission power control of HS-DPCCH is performed using a target SIR set based on the CRC result of A-DPCH. Here, the target SIR of A-DPCH in the base station is set based on the CRC result of A-DPCH by the control station that controls the base station.
[0007]
Hereinafter, Fast-UL will be taken as an example, and outer loop transmission power control will be described with reference to FIGS. 12 and 13. FIG. 12 shows the case where the A-DPCH is not in the SHO state, and FIG. 13 shows the case where the A-DPCH is in the SHO state. Here, the case where the A-DPCH is not in the SHO state is a case where the communication terminal is in a state where the A-DPCH is connected to only one base station, and the A-DPCH is in the SHO state. The case is a case where the communication terminal is in a state where the A-DPCH is simultaneously connected to a plurality of base stations.
[0008]
As shown in FIG. 12, when the communication terminal is communicating with only the base station 1, the CRC result of A-DPCH is sent from the base station 1 to the control station. The control station sets a target SIR based on the CRC result of the A-DPCH and notifies the base station 1 of it. That is, when CRC = OK, the target SIR is decreased by Dec, and when CRC = NG, the target SIR is increased by Inc. Then, base station 1 creates a TPC command for A-DPCH based on the comparison result between the target SIR and the received SIR of A-DPCH, and transmits this TPC command to the communication terminal via A-DPCH. . Also, base station 1 creates a TPC command for HS-DPCCH based on the comparison result between the target SIR and the received SIR of HS-DPCCH, and transmits this TPC command to the communication terminal via HS-DPCCH. . The communication terminal controls the transmission power of A-DPCH according to the TPC command for A-DPCH, and controls the transmission power of HS-DPCCH according to the TPC command for HS-DPCCH. Note that the base station 1 may not create and transmit the HS-DPCCH TPC command, and the communication terminal may perform HS-DPCCH transmission power control according to the A-DPCH TPC command. In this way, when the A-DPCH is not in the SHO state, the base station 1 can satisfy the required quality of the reception quality of the A-DPCH and the reception quality of the HS-DPCCH.
[0009]
When the communication terminal moves from the base station 1 toward the base station 2, the communication terminal connects the A-DPCH both with the base station 1 and with the base station 2, and the A-DPCH enters the SHO state. . And if A-DPCH will be in a SHO state, both base station 1 and base station 2 will receive the A-DPCH signal transmitted from the communication terminal. Each of the base station 1 and the base station 2 sends the CRC result of the A-DPCH signal received by itself to the control station. The control station increases the target SIR by Inc if both CRC results are CRC = NG, and decreases the target SIR by Dec if at least one of the two CRC results is CRC = OK. Thus, for example, when CRC = NG at the base station 1 and CRC = OK at the base station 2, the target SIR is lowered by Dec. When such target SIR control is performed, the target SIR when the A-DPCH is in the SHO state is set to a value lower than the target SIR when the A-DPCH is not in the SHO state. Then, both the TPC command for A-DPCH and the TPC command for HS-DPCCH are created using the lowered target SIR.
[0010]
Here, for A-DPCH, when A-DPCH is in the SHO state, the A-DPCH signal received at base station 1 and the A-DPCH signal received at base station 2 are selectively combined at the control station. Is done. Therefore, as a result of the target SIR being lowered, as shown in FIG. 13, a TPC command instructing to lower the transmission power of the A-DPCH is transmitted from the base station 1 and the base station 2, and the A-DPCH is transmitted at the communication terminal. Even if the transmission power is reduced, the quality of the A-DPCH in the uplink direction satisfies the required quality at the control station, so there is no particular problem. The communication terminal increases the transmission power of the A-DPCH and transmits any one of the received TPC commands if all of the received TPC commands are TPC commands instructing to increase the transmission power. If it is a TPC command instructing power reduction, the transmission power of A-DPCH is reduced.
[0011]
On the other hand, HS-DPCCH to which HHO is applied is connected only to any one base station even when A-DPCH is in the SHO state. For this reason, as a result of the target SIR being lowered, as shown in FIG. 13, a TPC command instructing to lower the transmission power of HS-DPCCH is transmitted from base station 1, and the transmission power of HS-DPCCH is reduced in the communication terminal. If lowered, the HS-DPCCH in the uplink direction may not satisfy the required quality (BLER) even if the target SIR is satisfied.
[0012]
The present invention has been made in view of the above points, and in a wireless communication system in which A-DPCH to which SHO is applied and HS-DPCCH to which HHO is applied is mixed, a target SIR for outer loop transmission power control is appropriately set. It is an object of the present invention to provide a target SIR setting method which can be set to a proper value and keep the HS-DPCCH reception quality at a required quality.
[0013]
[Means for Solving the Problems]
In order to solve the above-described problems and achieve the object, the present invention provides a wireless communication system in which an A-DPCH to which SHO is applied and an HS-DPCCH to which HHO is applied are mixed. If not, the HS-DPCCH target SIR is set based on the A-DPCH error detection result, while if the A-DPCH is in the SHO state, the HS-DPCCH error detection result is set based on the HS-DPCCH error detection result. A target SIR is set.
[0014]
With this feature, in a wireless communication system in which A-DPCH to which SHO is applied and HS-DPCCH to which HHO is applied is mixed, even when A-DPCH is in the SHO state, an appropriate target SIR is set, Appropriate outer loop transmission power control can be performed on the HS-DPCCH.
[0015]
DETAILED DESCRIPTION OF THE INVENTION
(Embodiment 1)
FIG. 1 is a block diagram showing configurations of a base station apparatus and a control station apparatus according to Embodiment 1 of the present invention. The base station apparatus and the control station apparatus are used in a mobile communication system in which Fast-UL or HSDPA is performed. Moreover, this Embodiment demonstrates the case where both A-DPCH and HS-DPCCH are CRC-encoded.
[0016]
In the base station apparatus, the transmission unit 100 includes an encoding unit 12, a modulation unit 14, a spreading unit 16, and a transmission radio unit 18.
[0017]
The encoding unit 12 performs convolution encoding and CRC encoding on transmission data (bit string) of A-DPCH, and configures a transmission frame including a plurality of time slots. Further, the transmission data (bit string) of HS-DPCCH is convolutionally encoded and CRC encoded to form a transmission frame composed of a plurality of time slots. That is, both A-DPCH and HS-DPCCH are CRC-encoded. As error detection coding, a coding method other than CRC coding can be used. When configuring the transmission frame, the encoding unit 12 embeds the TPC command for the upstream A-DPCH in the A-DPCH time slot and the TPC command for the upstream HS-DPCCH in the HS-DPCCH time slot. Embed. These TPC commands are input from the TPC command creation unit 32. The TPC command for HS-DPCCH is substituted by the TPC command for A-DPCH when A-DPCH is not in the SHO state, and is embedded in the time slot of HS-DPCCH only when A-DPCH is in the SHO state. Sometimes. Moreover, it may be embedded in some time slots of A-DPCH instead of HS-DPCCH.
[0018]
The modulation unit 14 performs modulation processing such as QPSK on transmission data. The spreading unit 16 performs a spreading process on the modulated transmission signal with a spreading code assigned to each channel.
[0019]
The transmission radio unit 18 performs processing such as D / A conversion and up-conversion on the spread transmission signal, and then transmits the transmission signal via the antenna 20. The transmission radio unit 18 transmits an A-DPCH transmission signal via the A-DPCH, and transmits an HS-DPCCH transmission signal via the HS-DPCCH. A communication system in which HS-DPCCH exists only in the uplink direction is also conceivable. In this case, the base station does not perform HS-DPCCH transmission processing.
[0020]
The reception unit 200 includes a reception radio unit 22, a despreading unit 24, a demodulation unit 26, and a decoding unit 28.
[0021]
The reception radio unit 22 down-converts signals received via the antenna 20 (CRC-encoded A-DPCH signal, CRC-encoded HS-DPCCH signal), AGC (Auto Gain Control), A Processing such as / D conversion is performed. The despreading unit 24 performs a despreading process on the received signal with a spreading code assigned to each channel. The demodulator 26 demodulates the despread QPSK signal and the like. The demodulated signal is input to the decoding unit 28 and the SIR measurement unit 34.
[0022]
The decoding unit 28 performs error detection by error correction decoding and CRC determination on the A-DPCH reception signal and the HS-DPCCH reception signal. Thereby, the reception data (bit string) of A-DPCH and the reception data (bit string) of HS-DPCCH are obtained. In addition, CRC results of A-DPCH (hereinafter referred to as CRC) _A And HS-DPCCH CRC results (hereinafter referred to as CRC) _HS That is, CRC = OK (no error) or CRC = NG (error).
Input to the target SIR setting unit 30. CRC results from other base station devices are also input to the target SIR setting unit 30.
[0023]
When the A-DPCH is not in the SHO state, the target SIR setting unit 30 sets the target SIR of the A-DPCH (hereinafter, target SIR). _A HS-DPCCH target SIR (hereinafter referred to as target SIR) _HS Both) and CRC _A Set based on. On the other hand, if the A-DPCH is in the SHO state, the target SIR _A CRC _A Based on the target SIR _HS CRC _HS Set based on. That is, if the A-DPCH is in the SHO state, the target SIR _A And target SIR _HS And are controlled independently. Since the control station apparatus controls the HO, it can be understood what connection state each channel is currently in. The target SIR setting unit 30 sets the set target SIR. _A And target SIR _HS Is input to the TPC command creation unit 32 of the base station apparatus. Note that the target SIR is decreased by Dec when CRC = OK, and is increased by Inc when CRC = NG. The relationship between Dec and Inc is as shown in the above formula (1). The target SIR can be controlled by other methods. For example, BLER for a certain period may be measured, and if the BLER is equal to or higher than the target BLER, the target SIR may be decreased, and if the BLER is less than the target BLER, the target SIR may be increased.
[0024]
The SIR measurement unit 34 of the base station apparatus measures the SIR of a pilot sequence symbol in the received signal. That is, the SIR measurement unit 36 receives the A-DPCH reception SIR (hereinafter, reception SIR). _A And HS-DPCCH reception SIR (hereinafter referred to as reception SIR) _HS Measured). The measured SIR is input to the TPC command creation unit 32.
[0025]
The TPC command creation unit 32 receives the received SIR. _A And target SIR _A Based on the comparison result, a TPC command for uplink A-DPCH is created. Receive SIR _HS And target SIR _HS Based on the comparison result, a TPC command for the HS-DPCCH in the uplink direction is created. If the received SIR is equal to or higher than the target SIR, a TPC command for instructing to lower the transmission power (Down) is created. If the received SIR is less than the target SIR, a TPC command for instructing to increase the transmission power (Up) is created. Is done. The created TPC command is input to the encoding unit 12.
[0026]
Next, taking the Fast-UL as an example, outer loop transmission power control when the A-DPCH is in the SHO state will be described. FIG. 2 shows the case where A-DPCH is in the SHO state.
[0027]
When the communication terminal moves from the base station 1 toward the base station 2 and the A-DPCH enters the SHO state, the A-DPCH is connected to both the base station 1 and the base station 2. In FIG. 2, since HS-DPCCH indicates a state before HHO, HS-DPCCH is connected only to base station 1. Therefore, CRC from base station 1 _A And CRC _HS Is transmitted to the control station, and CRC is transmitted from the base station 2 _A Is transmitted to the control station.
[0028]
If the A-DPCH is in the SHO state, the control station _A Target SIR based on _A Set the CRC _HS Target SIR based on _HS Set. And target SIR _A To both base station 1 and base station 2, and the target SIR _HS Is transmitted only to the base station 1.
[0029]
In the base station 1, the reception SIR _A And target SIR _A Based on the comparison result, a TPC command for A-DPCH is created, and the TPC command is transmitted to the communication terminal via the downlink A-DPCH. Receive SIR _HS And target SIR _HS Based on the comparison result, a TPC command for HS-DPCCH is created, and the TPC command is transmitted to the communication terminal via the downlink HS-DPCCH.
[0030]
At base station 2, the received SIR _A And target SIR _A Based on the comparison result, a TPC command for A-DPCH is created, and the TPC command is transmitted to the communication terminal via the downlink A-DPCH.
[0031]
The communication terminal controls the uplink HS-DPCCH transmission power according to the HS-DPCCH TPC command. Further, the transmission power of uplink A-DPCH is controlled according to the TPC command for A-DPCH. For A-DPCH, if both of the two received TPC commands are TPC commands instructing to increase transmission power, the transmission power of A-DPCH is increased, and one of the two received TPC commands is If it is a TPC command instructing to reduce transmission power, the transmission power of A-DPCH is reduced.
[0032]
As described above, the outer loop transmission power control when the A-DPCH is in the SHO state is performed.
[0033]
Next, how the target SIR is set in each channel will be described with reference to FIG. In FIG. 3, one block corresponds to 1 TTI (Transmission Time Interval).
[0034]
If A-DPCH is not in SHO state (in case of Non-SHO), target SIR _HS And target SIR _A Both are CRCs at base station 1 _A Is set based on Thus, for example, as shown in FIG. ₁ CRC _A If t = OK, t ₂ Target SIR _HS And target SIR _A Both drop by Dec. T _Three CRC _A If t = NG, then t _Four Target SIR _HS And target SIR _A Both go up by Inc.
[0035]
And when A-DPCH enters the SHO state, the target SIR _HS Is CRC _HS Based on the target SIR _A Is CRC _A Is set based on In other words, target SIR _HS Is the target SIR _A And controlled independently. Target SIR _A For the CRC of base station 1 _A And base station 2 CRC _A When both of them become NG, Inc increases, and when any one of them becomes OK, Dec decreases. Thus, for example, as shown in FIG. ₆ In the base station 1 CRC _HS = NG, CRC _A = NG and the base station 2 performs CRC _A == t if OK ₇ And target SIR _HS Increased by Inc, target SIR _A Decreases by Dec. Thus t ₇ Target SIR _A Target SIR even if the price falls _HS As a result, t ₈ In CRC _HS = OK.
[0036]
Thus, according to the present embodiment, when the A-DPCH is in the SHO state, the target SIR _HS And target SIR _A Are controlled individually and target SIR _HS Target SIR _A Therefore, even when the A-DPCH is in the SHO state, the quality of the HS-DPCCH can satisfy the required quality.
[0037]
(Embodiment 2)
In the present embodiment, a case will be described in which A-DPCH is CRC-encoded but HS-DPCCH is not CRC-encoded. Therefore, in the base station apparatus shown in FIG. 1, encoding section 12 performs convolution encoding and CRC encoding on A-DPCH transmission data, but only convolution encoding on HS-DPCCH transmission data. The decoding unit 28 performs error correction decoding and CRC determination on the A-DPCH reception signal, but performs only error correction decoding on the HS-DPCCH reception signal. Therefore, the control station apparatus receives a CRC from each base station apparatus. _A Only entered, CRC _HS Is not entered.
[0038]
FIG. 4 is a block diagram showing a configuration of target SIR setting unit 30 of the control station apparatus according to Embodiment 2 of the present invention.
[0039]
Before the A-DPCH enters the SHO state, the target SIR control unit 302 receives the CRC from the base station 1 alone. _A Is entered. The target SIR control unit 302 receives the CRC input from the base station 1 _A Target SIR based on _A To control. Target SIR after control _A Is transmitted to the base station 1 and input to the offset adding unit 304. The offset adding unit 304 receives HO (handover) information. This HO information is information indicating whether or not the A-DPCH is in the SHO state. The HO information is created in the control station apparatus. If the A-DPCH is not in the SHO state, the offset adding unit 304 determines that the target SIR _A Directly to the target SIR _HS To the base station 1.
[0040]
When the A-DPCH enters the SHO state, the target SIR control unit 302 receives the CRC from both the base station 1 and the base station 2. _A Is entered. The target SIR control unit 302 uses the CRC of the base station 1 _A And base station 2 CRC _A Target SIR when both are NG _A Increasing by Inc. If any one is OK, target SIR _A Decrease by Dec. Target SIR after control _A Is transmitted to the base station 1 and input to the offset adding unit 304. When the A-DPCH is in the SHO state, the offset adding unit 304 determines that the target SIR _A The value obtained by adding the offset to the target SIR _HS To the base station 1.
[0041]
That is, in this embodiment, when the A-DPCH is not in the SHO state, the target SIR _HS Is the target SIR _A If the A-DPCH is in the SHO state, the target SIR _HS Is the target SIR _A It is set to a value obtained by adding an offset to.
[0042]
Next, how the target SIR is set in each channel will be described with reference to FIG. In FIG. 5, one block corresponds to 1 TTI. Further, the case where the A-DPCH is not in the SHO state (in the case of Non-SHO) is the same as that in the first embodiment, and thus the description thereof is omitted.
[0043]
When the A-DPCH enters the SHO state, as shown in FIG. _HS CRC _A Target SIR set based on _A It becomes the value which added offset to. For example, as shown in FIG. ₈ In the base station 1 CRC _A = NG and the base station 2 performs CRC _A == t if OK ₉ And target SIR _HS And target SIR _A Both drop by Dec. Thus t ₉ Target SIR _HS T is lower, the offset is large enough so t _Ten In the case of HS-DPCCH, there is no error. Thus, the target SIR _HS Is the target SIR _A Up and down by the same amount at the same time, but always when the A-DPCH is in the SHO state, the target SIR _A The value is larger by the offset.
[0044]
Thus, according to the present embodiment, when the A-DPCH is in the SHO state, the target SIR _A The target SIR is obtained by adding a sufficiently large offset to _HS Therefore, even when the A-DPCH is in the SHO state, the quality of the HS-DPCCH can satisfy the required quality. Further, even in a mobile communication system in which HS-DPCCH is not CRC-encoded, outer-loop transmission power control of HS-DPCCH is possible. Furthermore, target SIR _A Target SIR based on _HS If the A-DPCH is continuously transmitted, even if the HS-DPCCH is not continuously transmitted, an appropriate target SIR is set at the start of transmission of the HS-DPCCH. _HS Is set. That is, even when HS-DPCCH is transmitted intermittently, appropriate outer loop transmission power control can be performed on HS-DPCCH.
[0045]
(Embodiment 3)
In the present embodiment, a case will be described in which A-DPCH is CRC-encoded but HS-DPCCH is not CRC-encoded. Therefore, the configuration of the base station apparatus is the same as that of the second embodiment. The configuration of the control station apparatus is as shown in FIG. FIG. 6 is a block diagram showing a configuration of target SIR setting unit 30 of the control station apparatus according to Embodiment 3 of the present invention.
[0046]
Before A-DPCH enters the SHO state, both A and B of switch 1 are opened according to the HO information. Further, the A and C of the switch 2 are connected according to the HO information. Since the A-DPCH is before the SHO state, the target SIR setting unit 30 receives a CRC from the base station 1. _A Is input from the base station 2, but the CRC is _A Is not entered. The target SIR control unit 306 receives the CRC input from the base station 1 _A Target SIR based on _A To control. Target SIR after control _A Is transmitted to the base station 1 and input to the offset adding unit 310 via the switch 2. The offset adding unit 310 sets the target SIR _A The value obtained by adding the offset to the target SIR _HS To the base station 1. The offset adding unit 310 is omitted, and the target SIR output from the target SIR control unit 306 is obtained. _A Directly to the target SIR _HS May be transmitted to the base station 1.
[0047]
When A-DPCH enters the SHO state, A of switch 1 is opened and B is connected according to the HO information. Further, the A and C of the switch 2 are connected according to the HO information. Further, the target SIR setting unit 30 receives the CRC from both the base station 1 and the base station 2. _A Is entered. Therefore, the target SIR control unit 306 receives the CRC input from the base station 1 as before the A-DPCH enters the SHO state. _A Target SIR based on _A The offset adding unit 310 controls the target SIR. _A Directly to the target SIR _HS As or target SIR _A The value obtained by adding the offset to the target SIR _HS To the base station 1. The target SIR control unit 308 determines the CRC of the base station 1 _A And base station 2 CRC _A Target SIR when both are NG _A Increasing by Inc. If any one is OK, target SIR _A Decrease by Dec. Target SIR after control by target SIR control unit 308 _A Is transmitted to the base station 2.
[0048]
When HS-DPCCH HHOs (that is, HS-PUSCH HHOs), A of switch 1 is connected and B is released according to the HO information. Further, B-C of the switch 2 is connected according to the HO information. The HO information in the present embodiment includes information related to the timing at which the HS-DPCCH performs HHO. The target SIR control unit 306 determines the CRC of the base station 1 _A And base station 2 CRC _A Target SIR when both are NG _A Increasing by Inc. If any one is OK, target SIR _A Decrease by Dec. Target SIR after control _A Is transmitted to the base station 1. The target SIR control unit 308 receives the CRC input from the base station 2 _A Target SIR based on _A The offset adding unit 310 controls the target SIR. _A Directly to the target SIR _HS As or target SIR _A The value obtained by adding the offset to the target SIR _HS To the base station 2.
[0049]
That is, in the present embodiment, when the A-DPCH is in the SHO state, the CRC at the base station connected to both the A-DPCH and the HS-DPCCH _A Target SIR based only on _A Set. More specifically, when A-DPCH is in the SHO state and HS-DPCCH is in the state before HHO, the target SIR of base station 1 _A Is the CRC of base station 1 _A Only based on the target SIR of base station 2 _A Is the CRC of base station 1 _A And base station 2 CRC _A It is set based on both. Further, when the A-DPCH is in the SHO state and the HS-DPCCH is in the state after the HHO, the target SIR of the base station 1 _A Is the CRC of base station 1 _A And base station 2 CRC _A And the target SIR of the base station 2 _A Is the CRC of base station 2 _A Only based on.
[0050]
Here, when the A-DPCH is in the SHO state, _A If all of NG is NG, target SIR _A Multiple CRCs _A If any one of them is OK, the target SIR _A If the control is performed to decrease the target SIR when the A-DPCH is in the SHO state _A Is the target SIR when the A-DPCH is not in the SHO state _A Is set to a lower value. In other words, one base station CRC _A Target SIR set based on _A Is the CRC of multiple base stations _A Target SIR set based on _A It becomes a larger value.
[0051]
Therefore, according to the configuration of the present embodiment, when the A-DPCCH is in the SHO state, the target SIR of the base station to which the HS-DPCCH is connected is _A Is the target SIR of the base station to which the HS-DPCCH is not connected _A It becomes a larger value. Also, the target SIR of the base station to which the HS-DPCCH is connected _A Is the CRC of one base station _A Therefore, the target SIR satisfies the required quality. Target SIR _HS Is the target SIR of the base station to which the HS-DPCCH is connected _A Is set to a value equal to or an offset plus a target SIR _HS Is the target SIR that satisfies the required quality.
[0052]
Next, how the target SIR is set in each channel will be described with reference to FIG. In FIG. 7, one block corresponds to 1 TTI. In FIG. 7, the target SIR _HS Is the target SIR _A Is set equal to Further, the case where the A-DPCH is not in the SHO state (in the case of Non-SHO) is the same as that in the first embodiment, and thus the description thereof is omitted.
[0053]
When the A-DPCH enters the SHO state, as shown in FIG. 7, the target SIR of the base station 1 _A And base station 2 target SIR _A Are controlled independently. For example, as shown in FIG. ₆ In the base station 1 CRC _A = NG and the base station 2 performs CRC _A Suppose that = OK. CRC at base station 1 _A Is NG, so the target SIR of base station 1 _A Is t ₇ Then only Inc goes up. Also, the target SIR of the base station 1 _A To target SIR of base station 1 _HS Also t ₇ Then only Inc goes up. In contrast, the CRC at the base station 1 _A Is NG, CRC at base station 2 _A Is OK, so the target SIR of base station 2 _A Is t ₇ Then go down Dec.
[0054]
Thus, according to the present embodiment, when the A-DPCH is in the SHO state, in the base station connected to both the A-DPCH and the HS-DPCCH, the CRC in the base station _A Target SIR based only on _A And set the target SIR _A To target SIR _HS Therefore, even when the A-DPCH is in the SHO state, the quality of the HS-DPCCH can satisfy the required quality.
[0055]
(Embodiment 4)
In the present embodiment, the offset amount in the third embodiment is controlled. However, in the present embodiment, both A-DPCH and HS-DPCCH are CRC encoded. Therefore, the configuration of the base station apparatus is the same as that of the second embodiment. Further, the configuration of the control station apparatus is as shown in FIG. 8, and is a configuration in which an offset control unit 312 is further added to the third embodiment (FIG. 6). FIG. 8 is a block diagram showing a configuration of target SIR setting unit 30 of the control station apparatus according to Embodiment 4 of the present invention. In FIG. 8, the description of the same configuration as that of the third embodiment (FIG. 6) is omitted.
[0056]
When the A-DPCH enters the SHO state, the offset control unit 312 sends a CRC from the base station 1 _A And CRC _HS Both are input. The offset control unit 312 performs CRC _A And CRC _HS The offset amount set in the offset adding unit 310 is controlled based on the comparison result. Specifically, CRC _A = OK and CRC _HS When NG, the offset is increased by a predetermined amount. On the other hand, CRC _A = CRC with NG _HS If = OK, the offset is lowered by a predetermined amount. CRC _A And CRC _HS If both are OK, or CRC _A And CRC _HS If both are NG, the current offset amount is maintained.
[0057]
When HS-DPCCH is terminated at the base station, offset control section 312 and offset addition section 310 are provided in the base station apparatus, not the control station apparatus.
[0058]
Next, how the target SIR is set in each channel will be described with reference to FIG. In FIG. 9, one block corresponds to 1 TTI. Further, the case where the A-DPCH is not in the SHO state (in the case of Non-SHO) is the same as that in the first embodiment, and thus the description thereof is omitted.
[0059]
When the A-DPCH enters the SHO state, as shown in FIG. 9, the target SIR of the base station 1 _A And base station 2 target SIR _A Are controlled independently. Also, the target SIR of the base station 1 _HS Is the target SIR of base station 1 _A It is set to a value obtained by adding an offset to. This offset amount is the CRC of the base station 1 as described above. _A And base station 1 CRC _HS It is controlled based on the comparison result. For example, as shown in FIG. ₈ And the CRC of base station 1 _HS Is OK, base station 1 CRC _A = T if NG ₉ The offset amount at is t ₈ The offset amount is lowered by a predetermined amount.
[0060]
Thus, according to the present embodiment, the CRC _A And CRC _HS Since the offset amount is controlled on the basis of the comparison result, the HS-DPCCH is appropriate for the HS-DPCCH even when the error characteristic of the HS-DPCCH is different from the error characteristic of the A-DPCH due to a difference in encoding method or the like. Outer loop transmission power control can be performed.
[0061]
(Embodiment 5)
In the present embodiment, the target SIR set in the base station 1 _HS To the base station 2 at the timing when the HS-DPCCH performs HHO (that is, when the HS-PUSCH performs HHO).
[0062]
As shown in FIG. 10, when the handover source base station 1 performs HHO of the HS-DPCCH to the base station 2 (that is, when HS-PUSCH HHOs to the base station 2), the target SIR _HS To the handover destination base station 2 via the control station. FIG. 11 shows the target SIR. _HS Indicates timing notified from the handover source base station 1 to the handover destination base station 2. When the A-DPCH is in the SHO state, first, the target SIR is transmitted from the control station to the base station 1. _HS Is sent. In accordance with this instruction, the base station 1 sets the target SIR set for itself. _HS To the control station. The control station sends the target SIR transmitted from the base station 1 _HS Is transmitted to the base station 2. Thereafter, the control station issues an HS-DPCCH HHO instruction to the base station 1 and the base station 2. In accordance with this instruction, the base station 1 disconnects the HS-DPCCH, and the base station 2 connects the HS-DPCCH. After the HS-DPCCH connection, the base station 2 uses the target SIR transmitted from the control station. _HS Set to your station.
[0063]
Target SIR _HS Is managed by the control station, the control station, after the HHO instruction of the HS-DPCCH, manages the target SIR managed by the control station. _HS Is transmitted to the base station 2.
[0064]
Thus, according to the present embodiment, the target SIR _HS Is notified from the handover source base station to the handover destination base station at the timing when the HS-DPCCH is HHOed. _HS Can be set.
[0065]
In the present embodiment, Fast-UL has been described as an example. However, the present invention is not limited to this, and the present invention includes a mixture of dedicated channels to which SHO is applied and dedicated channels to which HHO is applied. All are applicable to wireless communication systems.
[0066]
【The invention's effect】
As described above, according to the present invention, in a wireless communication system in which A-DPCH to which SHO is applied and HS-DPCCH to which HHO is applied are mixed, the target SIR for outer loop transmission power control is set to an appropriate value. And the reception quality of the HS-DPCCH can be kept at the required quality.
[Brief description of the drawings]
FIG. 1 is a block diagram showing configurations of a base station apparatus and a control station apparatus according to Embodiment 1 of the present invention.
FIG. 2 is a diagram for explaining outer loop transmission power control according to Embodiment 1 of the present invention;
FIG. 3 is a diagram for explaining how a target SIR is set in each channel according to Embodiment 1 of the present invention;
FIG. 4 is a block diagram showing a configuration of a target SIR setting unit of a control station apparatus according to Embodiment 2 of the present invention.
FIG. 5 is a diagram for explaining how a target SIR is set in each channel according to Embodiment 2 of the present invention;
FIG. 6 is a block diagram showing a configuration of a target SIR setting unit of a control station apparatus according to Embodiment 3 of the present invention.
FIG. 7 is a diagram for explaining how a target SIR is set in each channel according to Embodiment 3 of the present invention;
FIG. 8 is a block diagram showing a configuration of a target SIR setting unit of a control station apparatus according to Embodiment 4 of the present invention.
FIG. 9 is a diagram for explaining how a target SIR is set in each channel according to Embodiment 4 of the present invention;
FIG. 10 is a target SIR according to the fifth embodiment of the present invention. _HS Schematic diagram of the notification operation
FIG. 11 shows a target SIR according to the fifth embodiment of the present invention. _HS Of notification timing
FIG. 12 is a diagram for explaining conventional outer loop transmission power control (when A-DPCH is not in the SHO state);
FIG. 13 is a diagram for explaining conventional outer loop transmission power control (when A-DPCH is in the SHO state);
[Explanation of symbols]
12 Encoding unit
14 Modulator
16 Diffusion part
18 Transmitting radio section
20 Antenna
22 Reception radio section
24 Despreading part
26 Demodulator
28 Decryption unit
30 Target SIR setting section
32 TPC command generator
34 SIR measurement section
100 Transmitter
200 Receiver
306, 308 Target SIR control unit
310 Offset addition part
312 Offset control unit

Claims (1)

A target SIR setting method for outer loop transmission power control used in a radio communication system in which a first dedicated channel to which soft handover is applied and a second dedicated channel to which hard handover is applied are mixed,
When the first dedicated channel is in the soft handover state, the target SIR of the second dedicated channel in the base station connected to both the first dedicated channel and the second dedicated channel is changed to the target SIR of the first dedicated channel, Setting an offset amount controlled based on the comparison result between the error detection result of the first dedicated channel and the error detection result of the second dedicated channel;
The target SIR setting method characterized by the above-mentioned.

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