JP2005080080A - Cdma wireless base station transmission electric power control method - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To enable transmission electric power control with a higher degree of accuracy while restraining a transmission electric power variation not systematically intended without further complicating an implement to a base station than before. <P>SOLUTION: There is provided a CDMA base station transmission electric power control method for controlling transmission electric power by a first transmission electric power control system using a first transmission electric power value calculated by using transmission electric power control bits received from a mobile station and a second transmission electric power control system using a second transmission electric power value set by a host apparatus. In the method, transmission electric power control reflection timing 110 by the first and second transmission electric power control systems is made to be identical. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

  The present invention relates to a transmission power control method in a CDMA wireless communication system.

  In the transmission power control in the conventional CDMA radio system, the control error in the open loop (outer loop) control is corrected, and in the closed loop (inner loop) transmission power control, the transmission power of the mobile station according to the traffic variation is corrected. For the purpose of realizing adaptive control in open loop control, a received signal power calculation circuit, an initial setting storage circuit that stores an initial relationship between received power and transmission power setting value, and a correction that corrects the relationship A circuit and a transmission power determination circuit, and the transmission power value is determined while correcting the relationship between the reception power and the transmission power setting value by a control signal periodically included in the reception signal (for example, , See Patent Document 1).

Japanese Patent Laid-Open No. 10-56421

  In the above conventional technique, the reflection timing of the control between the closed loop and the open loop is not particularly defined. Further, in a CDMA communication system configured by a mobile station, a base station, and a higher-level device of the base station, setting timing of transmission power upper limit value and lower-limit value from the higher-level device to the base station, closed loop and open loop in the base station The reflection timing of the control differs from this, and this timing lag has caused the problem of causing unintended transmission power fluctuations systematically.

  The present invention has been made to solve the above-described problems, and suppresses unintentional transmission power fluctuations systematically without making the implementation in the base station more complicated than in the past. An object of the present invention is to provide a transmission power control method for a CDMA radio base station that enables accurate transmission power control.

  In the CDMA radio base station transmission power control method according to the present invention, the first transmission power control system using the first transmission power value calculated using the transmission power control bit received from the mobile station, and the higher-level device set CDMA base station transmission power control method for controlling transmission power by a second transmission power control system using the second transmission power value, wherein the transmission power by the first and second transmission power control systems is The control reflection timing is the same.

  As described above, according to the present invention, the first transmission power control system using the first transmission power value calculated using the transmission power control bit received from the mobile station, and the second transmission power set by the higher-level device. CDMA base station transmission power control method for controlling transmission power by a second transmission power control system using a transmission power value of the transmission power, and a reflection timing of the transmission power control by the first and second transmission power control systems By making the same, it becomes possible to suppress unintended transmission power fluctuations systematically, and the number of reference timing signals necessary for transmission power control can be reduced. Implementation is easy.

Embodiment 1 FIG.
A CDMA radio base station transmission power control method according to Embodiment 1 of the present invention will be described below with reference to the drawings. FIG. 1 is a circuit block configuration diagram of a downlink transmission power control unit of a CDMA radio base station apparatus. The downlink transmission power control of the CDMA radio base station apparatus includes transmission power control by an inner loop (first transmission power control system) that calculates transmission power from a received TPC (Transmit Power Control) bit received from a mobile station, and CDMA radio. In the system, transmission power control by an outer loop (second transmission power control system) that reflects a transmission power value set from a host device of a base station apparatus, for example, RNC (Radio Network Control), as downlink transmission power in downlink transmission power. There are two types.

According to 3GPP (The 3rd Generation Partnership Project), transmission power control by the inner loop is represented by the following formula (1). However, P _bal (k) = 0 is not considered here.

P (k) = P (k−1) + P _TPC (k) + P _bal (k) (1)

P (k): Transmission power value reflecting the kth received TPC bit, P _TPC (k): Control power amount by the kth received TPC bit.

  The reception TPC demodulating circuit 1 demodulates the received TPC bits included in the received signal received from the input mobile station, and the control power amount obtained by the received TPC bits is input to the inner loop transmission power control processing circuit 2. Is done. In the inner loop transmission power control processing circuit 2, the calculation of the above formula (1) is performed, and the transmission power control value by the inner loop is output to the transmission power selection circuit 3.

  The transmission power control value by the inner loop and the transmission power control value by the outer loop are switched and output from the transmission power selection circuit 3 according to the output of the selection control circuit 4 and a predetermined condition. When the transmission power control value output from the transmission power selection circuit 3 is input to the transmission power limiting circuit 5 and is lower than the transmission power lower limit value set by the host device, or when it is higher than the transmission power upper limit value Are input to the transmission power setting circuit 6 after clip processing is performed on the lower limit value and the upper limit value.

  FIG. 2 is a flowchart showing a control process in the downlink transmission power control unit of the CDMA radio base station apparatus of FIG. 1, and a transmission power reflecting timing signal and an inner loop control signal are input to the selection control circuit 4, (201) In step (hereinafter, step is omitted), it is determined whether or not it is the transmission power reflection timing. At this time, if it is the transmission power reflection timing, in (202), it is determined whether or not the inner loop control signal is ON. If the inner loop control signal is ON (step 203), the inner loop transmission power processing circuit 2 obtains P (k) from the above equation (1) and outputs it to the transmission power selection circuit 3 as a transmission power value (204). This transmission power value is transmitted to the transmission power setting circuit 6 via the transmission power limiting circuit 5 (205). The transmission power value is reflected on the downlink transmission data and wirelessly transmitted as a transmission signal. Send to. The transmission power value output from the transmission power limiting circuit 5 is fed back to the inner loop transmission power control processing circuit 2 and used for transmission power calculation at the next inner loop reflection timing.

  If it is not the transmission power reflection timing in (201), the control processing is terminated without changing the transmission power (206). If the inner loop control signal is OFF at (202), the transmission power control circuit 3 at (207) substitutes the transmission power setting value by the outer loop for P (k) and outputs this value as the transmission power value. (204).

  FIG. 3 is a flowchart showing the transmission power limiting process (205) of the transmission power limiting circuit 5. The transmission power value obtained in (203) and the transmission power value set in (207) are set as the transmission power upper limit value and the transmission power. When the transmission power upper limit value is exceeded by comparison with the lower limit value, the transmission power upper limit value is set. When the transmission power lower limit value is exceeded, the transmission power lower limit value is set as the transmission power value at that time.

  There are two types of transmission power control: inner loop control and outer loop control. The reflection timing of each control is the same timing in the first embodiment, and this same timing is referred to as transmission power control reflection timing. I'm calling.

  FIG. 4 is a diagram showing a downlink transmission slot signal format in the CDMA radio base station apparatus, and the transmission power control reflection timing does not necessarily have to be at the beginning of the downlink transmission physical channel slot or frame, and also needs to have a constant cycle. However, considering the implementation of the CDMA radio base station apparatus, here, the transmission power control reflection timing is the slot period, and the change timing is the head (point A) of the pilot (PILOT) in the slot. The downlink transmission slot signal format may be changed so that the slot head matches the pilot head, and the transmission power control reflection timing may be set to the slot head.

  FIG. 5 is a diagram showing the correspondence between downlink transmission slots and transmission power during transmission power control by the inner loop in Embodiment 1, and transmission power control by the inner loop is obtained by demodulating the received TPC bits. This is performed using a reception TPC determination value ΔTPC that is a request change amount of the downlink transmission power from the mobile station, and is reflected in the downlink transmission power 501 at each transmission power control reflection timing 110.

  Transmission power control by the outer loop is performed using a transmission power upper limit value 101, an outer loop transmission power setting value 102, and a transmission power lower limit value (not shown in FIG. 5).

  Here, attention is paid to the change of the downlink transmission power 501 for each slot number. In slot (k−3), the reception TPC determination value is −ΔTPC, and therefore the downlink transmission power 501 changes by −ΔTPC at the transmission power reflection timing 110. In slot (k−2), since the reception TPC determination value is + ΔTPC, the downlink transmission power 501 changes by + ΔTPC at the transmission power reflection timing 110. In slot (k−1), since the reception TPC determination value is + ΔTPC, the downlink transmission power 501 changes by + ΔTPC at the transmission power reflection timing 110. Note that the outer loop transmission power setting 102 changes at the transmission power reflection timing 110, but is not reflected in the downlink transmission power 501 because the transmission power is being controlled by the inner loop. In slot (k), the reception TPC determination value is + ΔTPC, but the transmission power upper limit value 101 changes at the transmission power reflection timing 110 and (transmission power upper limit value 101) <(downlink transmission power 501). The downlink transmission power 501 becomes equal to the transmission power upper limit value 101. In slot (k + 1), since the reception TPC determination value is −ΔTPC, the downlink transmission power 501 changes by −ΔTPC at the transmission power reflection timing 110.

  FIG. 6 shows an example of correspondence between downlink transmission slots and transmission power when the transmission power control by the inner loop and the transmission power control by the outer loop in Embodiment 1 are switched by ON / OFF of the inner loop control signal. FIG. Here, the description of the same part as in FIG. 5 is omitted. The transmission power reflection timing 110 is the same as the reflection timing shown in FIG.

Here, when paying attention to the change in the downlink transmission power 601, the inner loop control signal is switched from ON to OFF at the transmission power reflection timing 110 of the slot number (k-1), so the slot number (k-1). + ΔTPC, which is the reception TPC determination value at, is not reflected in the downlink transmission power 601, and the downlink transmission power 601 is equal to the outer loop transmission power setting 102. Further, since the inner loop control signal is switched from OFF to ON at the transmission power reflection timing 110 of the slot number (k), the downlink transmission power 601 changes by + ΔTPC.

  Here, as a comparative example of the change in downlink transmission power with respect to each slot number, the inner loop reflection timing and the outer loop reflection timing are defined at different timings according to the conventional 3GPP, for example. Downlink transmission slot and transmission power during transmission power control by the inner loop when the loop reflection timing is the beginning of the pilot in the slot (point A in FIG. 4) and the outer loop reflection timing is the beginning of the slot (point B in FIG. 4) Is shown in FIG. In this case, the circuit block configuration diagram of the downlink transmission power control unit of the CDMA radio base station apparatus is the same as that in FIG. 1, but the selection control circuit 4 has an inner loop reflection timing and an outer loop as transmission power reflection timings. Two types of reflection timing signals are input.

  FIG. 7 is a diagram showing the correspondence between downlink transmission slots and transmission power during transmission power control by the inner loop in the above conventional case, and pays attention to the change in downlink transmission power 701. In slot (k−3), the reception TPC determination value is −ΔTPC, and therefore the downlink transmission power 701 changes by −ΔTPC at the inner loop reflection timing 111. In slot (k−2), since the reception TPC determination value is + ΔTPC, the downlink transmission power 701 changes by + ΔTPC at the inner loop reflection timing 111. In slot (k−1), since the reception TPC determination value is + ΔTPC, the downlink transmission power 701 changes by + ΔTPC at the inner loop reflection timing 111. In the slot (k), the outer loop transmission power setting 104 changes at the outer loop reflection timing 112, but is not reflected in the downlink transmission data 701 because the transmission power is being controlled by the inner loop. Since the reception TPC determination value 103 is + ΔTPC, the downlink transmission power 701 changes by + ΔTPC at the inner loop reflection timing 111. In slot (k + 1), transmission power upper limit 103 changes at outer loop reflection timing 112 and (transmission power upper limit 103) <(downlink transmission power 701), so downlink transmission power 701 is equal to transmission power upper limit 103. Is equal to Since the reception TPC determination value is −ΔTPC, the downlink transmission power 701 changes by −ΔTPC at the inner loop reflection timing 111.

  FIG. 8 is a diagram showing an example of correspondence between downlink transmission slots and transmission power when the transmission power control by the inner loop and the transmission power control by the outer loop in the conventional case are switched by ON / OFF of the inner loop control signal. is there. Here, the description of the same part as in FIG. 7 is omitted. Here, when paying attention to the change in the downlink transmission power 801, in the slot (k), the inner loop control signal is turned OFF at the outer loop reflection timing 112, and the downlink transmission power 801 becomes equal to the outer loop transmission power setting 104. . Although the reception TPC determination value is + ΔTPC, since the inner loop control signal is OFF, even if the inner loop reflection timing 111 comes, it is not reflected in the downlink transmission power 801. In the slot (k + 1), the inner loop control signal is turned ON at the outer loop reflection timing 112, but the downlink transmission power 102 does not change. Since the reception TPC determination value is −ΔTPC, the downlink transmission power 801 changes by −ΔTPC at the inner loop reflection timing 111.

  Here, when comparing FIG. 5 in the present Embodiment 1 and FIG. 7 in the conventional example showing the correspondence between the downlink transmission slot and the transmission power at the time of transmission power control by the inner loop, in slot (k), In FIG. 5, since the reflection timing of the transmission power control by the inner loop and the transmission power control by the outer loop are the same, there is no variation in the transmission power due to the difference in the reflection timing of the inner loop and the outer loop as seen in FIG. .

  Further, FIG. 6 in the first embodiment showing the correspondence between the downlink transmission slot and the transmission power when the transmission power control by the inner loop and the transmission power control by the outer loop are switched by ON / OFF of the inner loop control signal and the conventional example. When comparing FIG. 8 in the example of FIG. 8, in slot (k−1), the transmission power control by the inner loop and the transmission power control by the outer loop are the same in FIG. There is no change in transmission power due to the difference in reflection timing between the inner loop and the outer loop.

  Therefore, in the first embodiment, it is possible to suppress transmission power fluctuations that are not intended for the system. Conventionally, there are two types of timing signals, an inner loop control reflection timing signal and an outer loop control reflection timing signal. However, in the first embodiment, there is only one type of transmission power reflection timing signal. Therefore, the number of reference timing signals required for the wireless base station apparatus can be reduced.

Embodiment 2. FIG.
A CDMA radio base station transmission power control method according to Embodiment 2 of the present invention will be described below with reference to the drawings. FIG. 9 is a circuit block configuration diagram of the downlink transmission power control unit of the CDMA radio base station apparatus, and description of the same parts as those in FIG. FIG. 10 is a flowchart showing control processing in the downlink transmission power control unit of the CDMA radio base station apparatus of FIG.

  In the second embodiment, transmission power control by the inner loop is obtained by the following expressions (2) and (3).

P (k) = P1 + P ′ _TPC (k) (2)

P ′ _TPC (k) = P ′ _TPC (k−1) + P _TPC (k) (3)

P (k): transmission power value reflecting the kth received TPC bit, P1: transmission power value by the outer loop at the transmission power reflection timing, P ′ _TPC (k): control power by the received TPC bits up to the kth Integrated amount, P _TPC (k): Control power amount by the kth received TPC bit.

In the formula (1) in the first embodiment, the next transmission power value is obtained from the previous transmission power value. However, in the formulas (2) and (3), the amount of control power accumulated by the previous received TPC bit is used. The next control power integration amount is obtained, and the transmission power value by the outer loop is added to this, and the next transmission power value is obtained. From Expressions (2) and (3), the transmission power at the start of transmission power control by the inner loop is equal to the transmission power value by the outer loop, and the control power integration amount P ′ _TPC (k) = 0.

The selection control circuit 4 receives the inner loop reflection timing signal, the outer loop reflection timing signal, and the inner loop control signal, and determines whether it is the inner loop reflection timing in step (1001) (hereinafter, step is omitted). To do. At this time, if it is the inner loop reflection timing, it is next determined at (1002) whether or not the inner loop control signal is ON. If the inner loop control signal is ON (1003), the inner loop transmission power processing circuit 7 _obtains P ′ _TPC (k) from the above equation (3), and (1004) obtains P (k) from the above equation (2). Is output to the transmission power selection circuit 3 as a transmission power value (1005) and used for calculation of the control power integration amount by the received TPC bit at the next inner loop reflection timing. Feedback. In addition, when an upper limit or lower limit clip occurs in the transmission power limiting circuit 5, a clip information notification signal is added to notify the transmission power selection circuit 3 of the clip information.

If the inner loop control is OFF at (1006) and the inner loop control is OFF at (1007), P ′ _TPC (k) = 0 is set at (1008), and the transmission power value includes this outer loop reflection timing. Apply the outer loop transmission power setting value of the hour.

  If the inner loop control is not ON in (1002), the control process is terminated without changing the transmission power (1009). If it is not the outer loop reflection timing in (1006), and if the inner loop control is not OFF in (1007), the control process is terminated without changing the transmission power (1010).

  FIG. 11 is a diagram showing the correspondence between downlink transmission slots and transmission power during transmission power control by the inner loop in the second embodiment, and pays attention to changes in downlink transmission power 1101. In slot (k−3), the reception TPC determination value is −ΔTPC, so that the downlink transmission power 1101 changes by −ΔTPC at the inner loop reflection timing 111. In slot (k−2), since the reception TPC determination value is + ΔTPC, the downlink transmission power 1101 changes by + ΔTPC at the inner loop reflection timing 111. In slot (k−1), since the reception TPC determination value is + ΔTPC, the downlink transmission power 1101 changes by + ΔTPC at the inner loop reflection timing 111. In slot (k), the outer loop transmission power setting 104 changes at the outer loop reflection timing 104, and the outer loop transmission power is calculated according to the above equations (2) and (3), which are transmission power control arithmetic expressions based on the inner loop. The change in the setting 104 is reflected in the downlink transmission power 1101. Since the reception TPC determination value is + ΔTPC, it changes by + ΔTPC at the inner loop reflection timing.

  The correspondence between the downlink transmission slot and the transmission power when the transmission power control by the inner loop and the transmission power control by the outer loop in Embodiment 2 are switched by ON / OFF of the inner loop control signal is described in Embodiment 1. It becomes the same as FIG. 8 shown as a comparative example with the past.

As described above, in the second embodiment, the downlink transmission power can be corrected by the transmission power setting by the outer loop during the transmission power control by the inner loop, and more accurate transmission power control can be performed. . Further, since the inner loop transmission power control processing circuit has the calculation function of the formula (1) in the conventional and the first embodiment, the transmission power value is fed back and input, but in the second embodiment, Since the amount of control power accumulated by the received TPC bit corresponding to P ′ _TPC (k−1) is fed back, this feedback loop has become smaller, so that the wiring length can be shortened when configured with hardware. is there.

Embodiment 3 FIG.
A CDMA radio base station transmission power control method according to Embodiment 3 of the present invention will be described below with reference to the drawings. FIG. 12 is a circuit block configuration diagram of the downlink transmission power control unit of the CDMA radio base station apparatus, and FIG. 13 is a flowchart showing control processing in the downlink transmission power control unit of the CDMA radio base station apparatus of FIG.

  In the third embodiment, the reflection timing of the transmission power control by the inner loop and the reflection timing by the outer loop are made the same, and the expressions (2) and (3) described in the second embodiment are applied to the transmission power control by the inner loop. Apply.

The transmission power calculation circuit 8 receives the transmission power reflection timing signal, the inner loop control signal, and the outer loop transmission power value. In step (1301) (hereinafter, step is omitted), it is determined whether the transmission power reflection timing is reached. judge. At this time, if it is the transmission power reflection timing, P ′ _TPC (k) is obtained from the expression (3) in the inner loop transmission power processing circuit 7 in (1302), and it is determined whether or not the inner loop control signal is ON in (1303). . If the inner loop control signal is ON (1304), the inner loop transmission power processing circuit 7 obtains P (k) from equation (2) and outputs it as a transmission power value to the transmission power arithmetic circuit 8 (1305) and Is fed back to the inner loop transmission power processing circuit 7 so as to be used for calculating the control power integration amount by the received TPC bit at the inner loop reflection timing. In addition, when an upper limit or lower limit clip occurs in the transmission power limiting circuit 5, a clip information notification signal is added to notify the transmission power calculation circuit 8 of the clip information.

If the inner loop control is OFF in (1303), P ′ _TPC (k) = 0 is set in (1306), and P (k) is obtained from equation (2). If it is not the transmission power control reflection timing in (1301), the control processing is terminated without changing the transmission power (1307).

  FIG. 14 is a diagram showing the correspondence between downlink transmission slots and transmission power during transmission power control by the inner loop in the third embodiment, and attention is paid to changes in downlink transmission power 1401. In slot (k−3), the reception TPC determination value is −ΔTPC, and therefore, downlink transmission power 1401 changes by −ΔTPC at transmission power reflection timing 110. In slot (k−2), since the reception TPC determination value is + ΔTPC, the downlink transmission power 1401 changes by + ΔTPC at the transmission power reflection timing 110. In slot (k−1), the reception TPC determination value is + ΔTPC, the outer loop transmission power setting is changed by −ΔTPC, and the amount of change in the downlink transmission power 1401 at the transmission power reflection timing 110 is + ΔTPC + (− ΔTPC). ) = 0. In slot (k), at the transmission power reflection timing 110, the reception TPC determination value is + ΔTPC, and the downlink transmission power 1401 is about to increase by + ΔTPC, but the transmission power upper limit value 101 is changed, and this transmission power upper limit value 101 Therefore, it becomes equal to the transmission power upper limit value 101.

  The correspondence between the downlink transmission slot and the transmission power when the transmission power control by the inner loop and the transmission power control by the outer loop in the third embodiment are switched by ON / OFF of the inner loop control signal is described in the first embodiment. It becomes the same as FIG. 6 shown.

  Here, comparing FIG. 14 in the third embodiment showing the correspondence between the downlink transmission slot and the transmission power at the time of transmission power control by the inner loop, comparing FIG. 7 in the conventional example with slot (k−1). 14 and slot (k), since the reflection timing of the transmission power control by the inner loop and the transmission power control by the outer loop is the same in FIG. 14, the transmission by the difference in the reflection timing of the inner loop and the outer loop as seen in FIG. There are no fluctuations in power.

As described above, in Embodiment 3, it is possible to suppress transmission power fluctuations that are not intended in the system. In addition, during transmission power control by the inner loop, downlink transmission power can be corrected by transmission power setting by the outer loop, and more accurate transmission power control can be performed. Further, since the inner loop transmission power control processing circuit has the calculation function of the formula (1) in the conventional and the first embodiment, the transmission power value is fed back and input, but in the third embodiment, Since the amount of control power accumulated by the received TPC bit corresponding to P ′ _TPC (k−1) is fed back, this feedback loop has become smaller, so that the wiring length can be shortened when configured with hardware. is there.

Embodiment 4 FIG.
A CDMA radio base station transmission power control method according to Embodiment 4 of the present invention will be described below with reference to the drawings. FIG. 15 is a circuit block configuration diagram of the downlink transmission power control unit of the CDMA radio base station apparatus, and FIG. 16 is a flowchart showing control processing in the downlink transmission power control unit of the CDMA radio base station apparatus of FIG.

In the fourth embodiment, as in the third embodiment, the reflection timing of the transmission power control by the inner loop is made the same as the reflection timing by the outer loop, and the expression (2) described in the second embodiment for the transmission power control by the inner loop is given. ), Equation (3) is applied, and the transmission power upper limit value / lower limit value is applied not to the transmission power P (k) but to the control power integration amount P ′ _TPC (k) by the received TPC bits. Do.

The following formula (4) is applied to reflect the transmission power upper limit value / lower limit value to P ′ _TPC (k).

When P (k)> P _MAX : P ′ _TPC (k) = P _MAX −P1, When P (k) <P _MIN : P ′ _TPC (k) = P _MIN −P1 (4)

P (k): transmission power value reflecting the kth received TPC bit, P1: transmission power value by the outer loop at the transmission reflection timing, P ′ _TPC (k): control power integration by the kth received TPC bits Amount, P _MAX : upper limit of transmission power at transmission reflection timing, P _MIN : lower limit of transmission power at transmission reflection timing

The transmission power calculation circuit 8 receives the transmission power reflection timing signal, the inner loop control signal, and the outer loop transmission power value. In step (1601) (hereinafter, step is omitted), it is determined whether the transmission power reflection timing is reached. judge. At this time, if it is the transmission power reflection timing, P ′ _TPC (k) is obtained from the expression (3) in the inner loop transmission power processing circuit 7 in (1602), and then P ′ in the transmission power limiting circuit 9 in (1603). Expression (4) is applied to _TPC (k), and it is determined in (1604) whether the inner loop control signal is ON. If the inner loop control signal is ON (1605), the inner loop transmission power processing circuit 7 obtains P (k) from equation (2), and this P (k) is used as transmission power (1606).

If the inner loop control is OFF in (1604), P ′ _TPC (k) = 0 is set in (1607), and P (k) is obtained from equation (2). If it is not the transmission power control reflection timing in (1601), the control process is terminated without changing the transmission power (1608).

In the third embodiment, P ′ _TPC (k−1) before reflecting the transmission power limiting process is fed back to the inner loop transmission power processing circuit 7, but in the fourth embodiment, after the transmission power limiting process is reflected. P ′ _TPC (k−1) is fed back.

The clip information notification signal from the transmission power limiting circuit required in the third embodiment can be deleted, and when P ′ _TPC (k) is to be cleared, P1 = P _MAX = P _MAN can be set. Well, the downlink transmission power at this time is equal to P1.

  The correspondence between the downlink transmission slot and the transmission power during the transmission power control by the inner loop in the fourth embodiment is the same as in FIG. 14 shown in the third embodiment, and the transmission power control by the inner loop and the transmission by the outer loop. The correspondence between the downlink transmission slot and the transmission power when the power control is switched by ON / OFF of the inner loop control signal is the same as in FIG. 6 described in the first embodiment.

  As described above, in the fourth embodiment, in addition to the effects of the third embodiment, when the transmission power upper limit value and the lower limit value are reflected in the downlink transmission power, the calculation is performed simultaneously with the transmission power control value calculation by the inner loop. In addition, it is not necessary to perform transmission power restriction control separately, and the scale of the transmission power control processing unit can be reduced.

It is a circuit block block diagram of the downlink transmission power control part of the CDMA radio base station apparatus in Embodiment 1 of this invention. It is a flowchart which shows the control processing in the downlink transmission power control part of the CDMA radio base station apparatus in Embodiment 1 of this invention. It is a flowchart which shows the transmission power limiting process of the transmission power limiting circuit in Embodiment 1 of this invention. It is a figure which shows the downlink transmission slot signal format in a CDMA radio base station apparatus. It is a figure which shows matching of the downlink transmission slot and transmission power at the time of transmission power control by the inner loop in Embodiment 1 of this invention. 6 is a diagram illustrating an example of correspondence between downlink transmission slots and transmission power when transmission power control by an inner loop and transmission power control by an outer loop are switched by ON / OFF of an inner loop control signal in Embodiment 1. FIG. It is a figure which shows the example of matching of the downlink transmission slot and transmission power at the time of transmission power control by the conventional inner loop. It is a figure which shows the example of matching of the downlink transmission slot and transmission power at the time of switching the transmission power control by the conventional inner loop, and the transmission power control by an outer loop. It is a circuit block block diagram of the downlink transmission power control part of the CDMA radio base station apparatus in Embodiment 2 of this invention. It is a flowchart which shows the control processing in the downlink transmission power control part of the CDMA radio base station apparatus in Embodiment 2 of this invention. It is a figure which shows matching of the downlink transmission slot and transmission power at the time of transmission power control by the inner loop in Embodiment 2 of this invention. It is a circuit block block diagram of the downlink transmission power control part of the CDMA radio base station apparatus in Embodiment 3 of this invention. It is a flowchart which shows the control processing in the downlink transmission power control part of the CDMA radio base station apparatus in Embodiment 3 of this invention. It is a figure which shows the matching of the downlink transmission slot and transmission power at the time of transmission power control by the inner loop in Embodiment 3 of this invention. It is a circuit block block diagram of the downlink transmission power control part of the CDMA radio base station apparatus in Embodiment 4 of this invention. It is a flowchart which shows the control processing in the downlink transmission power control part of the CDMA radio base station apparatus in Embodiment 4 of this invention.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Reception TPC demodulation circuit 2 Inner loop transmission power control processing circuit 3 Transmission power selection circuit 4 Selection control circuit 5 Transmission power limiting circuit 6 Transmission power setting circuit 101 Transmission power upper limit value 102 Outer loop transmission power setting 110 Transmission power reflection timing 501 Downstream Transmit power

Claims (4)

A first transmission power control system that uses a first transmission power value calculated using a transmission power control bit received from a mobile station, and a second transmission power that uses a second transmission power value set by a higher-level device. A CDMA base station transmission power control method for controlling transmission power by a control system,
A CDMA radio base station transmission power control system characterized in that the transmission timing of the transmission power control by the first and second transmission power control systems is the same. A first transmission power control system that uses a first transmission power value calculated using a transmission power control bit received from a mobile station, and a second transmission power that uses a second transmission power value set by a higher-level device. A CDMA base station transmission power control method for controlling transmission power by a control system,
The first transmission power control system integrates the control power amount by the transmission power control bits in the current and past slots received from the mobile station to obtain a first transmission power value,
A CDMA base station transmission power control system characterized in that a transmission power value obtained by adding the first transmission power value and the second transmission power value is used as the transmission power. The first transmission power control system integrates the control power amount by the transmission power control bits in the current and past slots received from the mobile station to obtain a first transmission power value,
2. The CDMA base station transmission power control system according to claim 1, wherein a transmission power value obtained by adding the first transmission power value and the second transmission power value is used as transmission power. It is determined whether the transmission power value is greater than or equal to the transmission power upper limit value set by the higher-level device or less than the transmission power lower limit value, and the integrated power value obtained by integrating the control power amount by the transmission power control bit received from the mobile station. 4. The transmission power control method according to claim 3, wherein the transmission power control method is reflected on the transmission power.

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