JP3242098B2 - Communication base station device and communication terminal device - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

[0001] The present invention relates to a communication base station apparatus and a communication terminal apparatus for performing transmission power control in CDMA communication.

[0002]

2. Description of the Related Art CDMA (Code Division Multiple Acc)
The ess (code division multiple access) system is one of multiple access system technologies when a plurality of stations simultaneously communicate in the same frequency band in a wireless communication system using a car phone, a mobile phone, or the like. This CDMA system is another system, FDMA (Frequency Division Multiple Access: FDMA).
Frequency division multiple access (TDMA), Time Division
Multiple Access (Time Division Multiple Access) is a method that can achieve higher frequency use efficiency as compared with a method such as a method and can accommodate more users.

[0003] In the CDMA system, multiple access is performed by spread spectrum communication in which the spectrum of an information signal is spread and transmitted over a band sufficiently wider than the original information bandwidth. In the CDMA system, there are some of the above-mentioned spread spectrum systems. Among them, the direct spread system is a system in which an information signal is directly multiplied by a spread code in spreading. In this case, signals from a plurality of mobile stations are multiplexed in the same frequency domain and the same time domain.

[0004] The CDMA system using direct spreading has a problem of "far problem". This "perspective problem"
Desired transmitting station is far away, undesired transmitting station (interfering station)
Is closer, the received power of the signal from the interfering station is larger than the received signal from the desired transmitting station, and the processing gain (spreading gain) alone cannot suppress the cross-correlation between spreading codes. Communication is not possible. For this reason, in a cellular system using the direct spread CDMA system, transmission power control according to the state of each transmission path is essential in an uplink from a mobile station to a base station.

[0005] As a countermeasure against fading which is a cause of line quality degradation in land mobile communication, a method of compensating for instantaneous fluctuations in received power by controlling transmission power has been considered.

The operation of the closed loop transmission power control process using the conventional slot configuration will be described. FIG. 9 shows a slot configuration in a case where conventional transmission power control is performed.

[0007] A pilot data 901, transmission power control data (TPC) 902, and transmission data 903 are transmitted from a base station as signals multiplexed in time in slot units. Pilot data 901 is a signal having a fixed information pattern, and is used for transmission path estimation for demodulation and SIR (desired wave signal to interference wave signal power ratio) measurement at a mobile station, and transmission power control data 902 is used for transmission power control. Used as a command.

An uplink signal from the mobile station to the base station is also transmitted as a signal having a slot period in the same manner as a downlink signal from the base station to the mobile station, and the downlink signal is used to minimize transmission power control delay. , A timing offset (T _Shift ) of _{ス ロ ッ}ト slot is added.

First, transmission power control performed on the downlink will be described. The signal transmitted from the base station is received at the mobile station with a delay of propagation delay T _Delay (the distance from the base station to the mobile station). In the mobile station, reception S is determined by pilot data 904 at the beginning of the slot.
Perform IR measurement. Then, the SIR measurement result is compared with a reference SIR given in advance, and the received SIR is compared.
If the received SIR is low, a transmission power control bit for instructing to increase the transmission power of the base station is generated. If the reception SIR is high, a transmission power control bit is generated as a command for instructing to decrease the transmission power. This transmission power control bit is embedded and transmitted as uplink transmission power control data 905.

[0010] The signal transmitted from the mobile station is received at the base station with a _delay of T _Delay . The base station detects the transmission power control data 906, determines the downlink transmission power value from the result, and reflects the transmission power value on the transmission power at the head of the next downlink slot.

Next, the operation of transmission power control performed on the uplink will be described. The signal transmitted from the mobile station is
Received at the base station with a _delay of T _Delay . At the base station, pilot data 907 at the beginning of the slot is
SIR is measured, the received SIR is compared with the reference SIR as in the case of the mobile station, a transmission power control bit which is a command for instructing to increase or decrease the transmission power is generated, and the downlink transmission power control data 908 is generated. Embed in and send.

[0012] The signal transmitted from the base station is received by the mobile station with a _delay of T _Delay . The mobile station detects the transmission power control data 909, determines the transmission power value of the uplink from the result, and reflects the transmission power value on the head of the next downlink slot.

[0013] The up slot is 1/2 of the down slot.
Since the timing is offset only by the slot, the transmission power is controlled with one time slot control delay (the result of one slot before is reflected) in both the downlink and uplink.

Next, a case where the transmission rate is reduced will be described with reference to FIG. When the transmission rate decreases,
Since the absolute time of one bit (or symbol) increases, the ratio of the pilot data length and the transmission power control bit length to the slot length increases.

At this time, similarly to the above, the signal transmitted from the base station is received by the mobile station with a delay of propagation delay T _Delay (the distance from the base station to the mobile station), and the mobile station receives the signal. The reception SIR is measured based on pilot data 1004 at the head of the slot. The SIR measurement result is compared with the reference SIR, and the result is embedded as transmission power control data 1005 for uplink and transmitted.

[0016]

However, in the conventional apparatus, when the transmission rate is low, the ratio of the pilot data length and the transmission power control bit length to the slot length increases, and the transmission power control delay due to the closed loop increases. May be. If the transmission power control delay increases, the transmission power control is not reflected in the next slot, and it becomes impossible to perform appropriate transmission power control that follows a change in the communication environment.

Further, minimizing the control delay leads to shortening the measurement time of the SIR used for transmission power control, and there is a problem that sufficient measurement accuracy cannot be obtained.

The present invention has been made in view of the above points, and an object of the present invention is to provide a communication base station apparatus and a communication terminal apparatus capable of minimizing a control delay of closed loop transmission power control.

[0019]

Means for Solving the Problems In order to solve the above problems, the present invention has taken the following means. Communication base station of the present invention
The apparatus transmits an uplink transmission signal whose output power has been changed from the beginning of the first pilot data after receiving downlink transmission power control data, by providing a predetermined offset with respect to the downlink reception timing. A communication base station apparatus for communicating with a communication base station apparatus, comprising: a downlink propagation delay, a processing delay required for generating transmission power control data in the communication terminal apparatus, an uplink propagation delay, In consideration of the processing delay required for transmission power control data generation in the base station apparatus, in consideration of the slot configuration in which pilot data and transmission power control data are arranged separately, And a transmitting unit that changes the output power from the beginning of the first pilot data after receiving the transmission power control data included in the uplink transmission signal, and And a control unit that performs transmission power control on the terminal device with a delay of 1 slot, that it has a
Features. Further, the communication terminal device of the present invention is a communication terminal device for performing communication with the communication base station device, wherein the communication base station device has a delay of one slot in the transmission timing of the uplink with respect to the reception timing of the downlink. in the sending by providing viable offset the transmission power control, it
It is characterized by.

According to this configuration, the arrangement of the pilot data and the transmission power control data, and the switching between the uplink and the downlink.
By appropriately setting the lot positional relationship, it is possible to minimize the control delay of the closed-loop transmission power control and to suppress the deterioration of the measurement accuracy due to shortening the measurement time of the reception quality. Further, according to this configuration, the arrangement of pilot data and transmission power control data,
In addition, since the arrangement of the slot position relationship between the uplink and the downlink can be appropriately determined from the processing delay and the propagation delay, the control delay can be reliably minimized.

[0021]

DESCRIPTION OF THE PREFERRED EMBODIMENTS The present inventor pays attention to the slot configuration of data and appropriately changes the arrangement of the slot configuration so that transmission power control can be performed when the pilot data length and the transmission power control data length are relatively long. The present inventor has found that it is possible to prevent the user from being unable to keep up with the next slot. In this case, the arrangement of the slot configuration includes the propagation delay from the base station to the mobile station, the length of the pilot data for measuring the reception quality, and the transmission power control data by measuring the reception quality after the mobile station has received the last pilot data. Processing time until embedding, propagation delay from mobile station to base station,
The transmission power control data length and the time considered as a control delay including the processing time from when the base station finishes receiving the transmission power control data to when the transmission power control data is detected and the power is changed are considered.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings. Embodiment 1 FIG. 1 is a block diagram showing a configuration of a wireless communication apparatus according to Embodiment 1 of the present invention. This wireless communication device includes a base station side device and a mobile station side device.

In the base station-side apparatus, the data to be transmitted to the mobile station is input to the encoder 102, where transmission path coding and the like are performed.
The result is output to frame configuration section 104. Also,
Pilot signal generator 101 generates a pilot signal having a fixed data pattern and outputs it to frame forming section 104.

In the frame forming unit 104, the encoder 102
, The pilot signal from the pilot signal generator 101, and the arrangement of the transmission power control bits output from the transmission power control bit generation unit 103, perform a frame configuration in such a manner, and output to the spreader 105. This arrangement is determined in consideration of processing delay and propagation delay required for transmission power control. Also, the frame forming unit 104
Then, a slot offset is provided, that is, the slot is shifted by a predetermined time.

The spreader 105 performs a spreading process, and outputs the spread signal to the transmission signal amplitude controller 106.
The transmission signal amplitude control section 106 controls the amplitude of the input signal and outputs it to the adder 107. Adder 107 adds the output of transmission signal amplitude control section 106 and the signal from the transmission section for another mobile station, and outputs the result to transmission RF section 108.
The transmitting RF unit 108 modulates and converts the frequency of the input, and transmits the signal from the antenna 109.

The received signal from the mobile station received from antenna 109 is subjected to frequency conversion by reception RF section 110,
Demodulation is performed and output to the correlator 111 and other mobile station reception processing units. The correlator 111 performs despreading with the spreading code used for mobile station transmission to separate the desired signal, and outputs it to the decoder 112 and the received SIR measuring device 113. The decoder 112 decodes the input to obtain received data. The reception SIR measuring device 113 measures the reception SIR from the reception signal, and
Output to

The transmission power control bit generation section 103 compares the input reception SIR with the reference SIR to generate transmission power control data. The transmission power control data detected by decoder 112 is output to transmission power control section 114, where the transmission power value is determined. This transmission power value is sent to transmission signal amplitude control section 106 and transmission RF section 108, and the transmission power is controlled according to the transmission power value.

The mobile station side apparatus is the same as the base station side apparatus except for a portion for multiplexing and distributing signals of other mobile stations and a transmission signal amplitude control section 106 for controlling the amplitude of a transmission signal by multiplexing. It is a structure. That is, the pilot signal generator 101 to the spreader 105 and the adder 107 to the antenna 109 and the antenna 115 to the transmission power control unit 126 are the corresponding parts, and perform the same operation.

Next, an example of a slot configuration used for low-rate transmission performed in the wireless communication apparatus having the above configuration will be described with reference to FIG. The slot configuration of the downlink is the same as that of a normal slot, but the slot configuration of the uplink is that pilot data and transmission power control data are arranged separately in the slot, and the uplink slot offset with respect to the downlink. Is different from the usual one.

First, transmission power control performed on the downlink will be described. A signal transmitted from the base station (a signal composed of pilot data 201, transmission power control data 202, and data 203) is delayed at the mobile station by a propagation delay T _Delay (a distance from the base station to the mobile station). Received.

The mobile station measures the received SIR based on pilot data 204 at the beginning of the slot. By comparing this SIR measurement result with the reference SIR,
When the reception SIR is low, a transmission power control bit is generated as a command to instruct to increase the transmission power of the base station, and when the reception SIR is high, a transmission power control bit is generated as a command to instruct to decrease the transmission power. This transmission power control bit is used to transmit uplink transmission power control data 2
05 is embedded and transmitted.

At this time, the data arrangement in the slot is determined in consideration of the delay. Specifically, the pilot data 204 and the transmission power control data 205 are separated from each other, that is, the data is arranged between the pilot data and the transmission power control data. The slot is shifted by T _Shift . Thereby, the transmission power control bits obtained by the SIR measurement can be included in uplink transmission power control data 205 without delay. Therefore, the transmission power control data of the uplink can be reflected in the slot without delay.

The signal transmitted from the mobile station is received at the base station with a _delay of T _Delay . The base station detects the transmission power control data 206, determines the transmission power value of the downlink from the result, and reflects it on the transmission power at the head of the next downlink slot.

Next, the operation of transmission power control performed on the uplink will be described. The signal transmitted from the mobile station is
Received at the base station with a _delay of T _Delay . In the base station, pilot data 207 at the beginning of the slot is
SIR is measured, the received SIR is compared with the reference SIR as in the case of the mobile station, and a transmission power control bit which is a command for instructing the transmission power to be increased or decreased is generated. Embed in and send. In this case, since the slot transmitted from the mobile station has a configuration in which the pilot data and the transmission power control data are separated, the transmission power control bit based on the SIR measurement result of the pilot data 207 is changed to the transmission power control data 208 of the next slot. Can be included. Therefore, the transmission power control data of the downlink can be reflected in the slot without delay.

The signal transmitted from the base station is received by the mobile station with a _delay of T _Delay . The mobile station detects the transmission power control data 209, determines the transmission power value of the uplink from the result, and reflects it on the transmission power at the head of the next uplink slot.

As described above, according to the radio communication apparatus of this embodiment, even in low-rate transmission, uplink pilot data and transmission power control data are arranged apart from each other so that the slot offset in the uplink and downlink can be appropriately adjusted. By providing this, the control delay of the closed-loop transmission power control can be realized in one time slot for both the upper and lower lines without shortening the SIR measurement time.

(Embodiment 2) FIG. 3 is a diagram showing a slot configuration of signals transmitted and received in a radio communication apparatus according to Embodiment 2 of the present invention. In this embodiment, the slot configuration of the uplink is the same as that of the normal one, but the slot configuration of the downlink is such that pilot data and transmission power control data are arranged apart in the slot and The uplink slot offset is different from that of the first embodiment. Also in this case, transmission power control is performed by the same method as in the first embodiment.

That is, in the base station, the arrangement of data in the slot is determined in consideration of the delay. In particular,
The pilot data 301 and the transmission power control data 302 are separated from each other, that is, the data 303 is arranged between the pilot data 301 and the transmission power control data 302.

In this case, the mobile station performs SIR measurement using received pilot data 304, and includes the result in transmission power control data 305. Further, the slot is shifted by T _Shift . Thereby, transmission power control of the next slot can be performed without delay according to the transmission power control value of transmission power control data 308.
As a result, the transmission power control data of the uplink can be reflected in the slot without delay.

On the other hand, the base station measures the SIR based on pilot data 307 at the beginning of the slot, and generates a transmission power control bit based on the measurement result.
It is embedded in the transmission power control data 302 of the downlink and transmitted. In this case, since the slot transmitted to the mobile station has a configuration in which the pilot data and the transmission power control data are separated, the transmission power control bit based on the SIR measurement result of pilot data 307 is changed to the transmission power control data 302 of the next slot. Can be included. Therefore, the transmission power control data of the uplink can be reflected in the next slot without delay.

Further, the base station detects transmission power control data 306, determines the transmission power value of the downlink from the result, and reflects the transmission power value at the head of the next downlink slot.

As described above, according to the radio communication apparatus of the present embodiment, even in low-rate transmission, downlink pilot data and transmission power control data are arranged apart from each other so that slot offsets in the uplink and downlink can be appropriately adjusted. By providing this, the control delay of the closed-loop transmission power control can be realized in one time slot for both the upper and lower lines without shortening the SIR measurement time.

(Embodiment 3) FIG. 4 is a diagram showing a slot configuration of signals transmitted and received in a radio communication apparatus according to Embodiment 3 of the present invention. In the present embodiment, pilot data and transmission power control data are arranged separately in a slot for both uplink and downlink, and an uplink and downlink slot offset is appropriately provided. Also in this case, transmission power control is performed by the same method as in the first embodiment.

That is, in the base station and the mobile station, the data arrangement in the slot is determined in consideration of the delay. Specifically, pilot data 401 and transmission power control data 402 are separated from each other, that is, pilot data 4
01 and transmission power control data 402
Is arranged to sandwich.

In this case, the mobile station performs SIR measurement using received pilot data 404, and includes the result in transmission power control data 405. Further, the slot is shifted by T _Shift . Thus, transmission power control of the next slot can be performed without delay according to the transmission power control value of transmission power control data 406.
As a result, the transmission power control data of the uplink can be reflected in the slot without delay.

The base station measures the SIR based on pilot data 407 at the head of the slot, generates a transmission power control bit based on the result, and embeds it in transmission power control data 408 for the downlink to transmit.
In this case, since the slot transmitted to the mobile station has a configuration in which the pilot data and the transmission power control data are separated, the transmission power control bit of the transmission power control data 409 based on the SIR measurement result of the pilot data 407 is changed to the next. This can be reflected at the head of the uplink slot.

As described above, according to the radio communication apparatus of the present embodiment, even in low-rate transmission, pilot data and transmission power control data for the uplink and downlink are arranged apart from each other, and the slot offset for the uplink and downlink is appropriately adjusted. By providing this, the control delay of the closed-loop transmission power control can be realized in one time slot for both the upper and lower lines without shortening the SIR measurement time.

(Embodiment 4) FIG. 5 is a diagram showing a slot configuration of signals transmitted and received in a radio communication apparatus according to Embodiment 4 of the present invention. This is because data 501 is allocated to the uplink Ich and Q
pilot data 502 and transmission power control data 5 for channel
03 and a slot configuration to which control information such as rate information 504 is assigned. In this case, since the control information is configured only on the Qch, the ratio of the pilot data increases regardless of the transmission rate. Also in this case, similarly to the second embodiment, the downlink pilot data and the transmission power control data are arranged apart from each other, the slot offset for the uplink and the downlink is appropriately provided, and the transmission power control is performed by the same operation as in the first embodiment. I do.

As described above, according to the transmission / reception apparatus of the present embodiment, even in the case of a channel configuration in which the ratio of pilot data and transmission power control data in a slot is large, that is, in transmission / reception of I / Q multiplexed data. Also, by arranging the pilot data and the transmission power control data apart from each other and appropriately setting the slot offset for the uplink and downlink, without reducing the measurement time of the SIR,
The control delay of the closed loop transmission power control can be minimized for both the upper and lower lines.

(Embodiment 5) FIG.6 is a diagram showing a slot configuration of signals transmitted and received in a radio communication apparatus according to Embodiment 5 of the present invention.

In multi-rate transmission, when considering slot configurations of different rates, pilot data 601
And the absolute time of the transmission power control data 602 is different. Therefore, the ratio of the pilot data and the transmission power control data to the slot differs according to the respective transmission rates.

In this case, the slots are configured so that the positions of the pilot data and the transmission power control data of the slot configuration of another transmission rate are matched to the lowest transmission rate among the assumed transmission rates. . That is, as shown in FIG. 6, the slots are configured such that the lengths (data lengths) between pilot data 601 and transmission power control data are all the same at different transmission rates.
At this time, by performing the same processing as in the above-described embodiment for all assumed transmission rates,
Transmission power control can be performed in the same manner as in the above embodiment.

As described above, according to the transmission / reception apparatus of the present embodiment, even between different transmission rates, the SIR measurement time is not shortened while the slot offset of the uplink and downlink is kept constant, and the uplink and downlink are both used. The control delay of the closed loop transmission power control can be minimized.

In the present embodiment, a case is described in which slots are configured such that the lengths (data lengths) between pilot data 601 and transmission power control data are all the same at different transmission rates. However, if the data arrangement is determined so that pilot data and transmission power control data of another transmission rate are located within the pilot data length and transmission power control data width of the lowest transmission rate, the present embodiment can be implemented. The effect of is exhibited.

Here, the data arrangement of the pilot data and the transmission power control data having the slot configuration in the first to fifth embodiments will be described. FIG. 7 is a diagram showing the time required for processing of transmission power control on the downlink.

[0056] In FIG. 7, the time considered as a control delay, the propagation delay from the base station to the mobile station T _Delay 7
02, and the pilot data length for measuring SIR is T
And _PLMS 703, the processing time from the mobile station is finished receiving the last pilot data until it measures the SIR embed the transmission power control data and T _MS1 704, the propagation delay from the mobile station to the base station T _Delay 705 The transmission power control data length is T _TPCBS 706, and the processing time from when the base station _finishes receiving the transmission power control data to when the base station detects the transmission power control data and changes the power is T _BS1 707.
Then, it can be expressed by the following equation.

Transmission power control delay time (downlink) = T _Delay + T _PLMS + T _MS1 + T _Delay + T _TPCBS + T _BS1 FIG. 8 shows the processing time required for uplink transmission power control processing. In FIG. 8, the time considered as the control delay is the propagation delay from the mobile station to the base station as T.
_Delay 802, the pilot data length for measuring the SIR is T _PLBS 803, and the processing time from when the base station finishes receiving the end of the pilot data until the base station measures the SIR and embeds the transmission power control data is T _BS2 804, _Let T _Delay 805 be the propagation delay from the base station to the mobile station,
The transmission power control data length is _assumed to be T _TPCMS 806, and the processing time from when the mobile station has finished receiving the transmission power control data until when the mobile station detects the transmission power control data and changes the power is T _MS2.
If it is 807, it can be represented by the following equation.

Transmission power control delay time (uplink) = T _Delay + T _PLBS + T _BS2 + T _Delay + T _TPCMS + T _{MS2 where} the pilot data length is the data length for measuring SIR, and the SI is measured using data other than pilot data.
When measuring R, the value includes the length.

Therefore, the arrangement of the slot configuration in the first to fifth embodiments is performed in consideration of these processing times. Therefore, the positions where the pilot data and the transmission power control data can be arranged and the slot offset values of the uplink and downlink are determined from the above equation.

As described above, according to the slot configuration method of the present embodiment, it is possible to allocate an optimal slot configuration that minimizes the control delay of closed loop transmission power control.

The transmission and reception of data having the slot configuration shown in the first to fifth embodiments is suitably used between wireless communication devices in a wireless communication system, for example, between a base station device and a mobile station device.

In the above first to fifth embodiments, the case where SIR is used as the reception quality has been described.
The present invention can be similarly applied even when other parameters are used as the reception quality.

[0063]

As described above, according to the communication base station apparatus and the communication terminal apparatus of the present invention, in a transmitting / receiving apparatus for performing closed-loop transmission power control, pilot data and transmission power control data are arranged independently of each other. By arranging slots with an offset in the slot position relationship between the uplink and downlink, the control delay of closed-loop transmission power control can be minimized even at various transmission rates, and the SIR measurement can be performed. Deterioration of measurement accuracy due to shortening of the time can be avoided.

[Brief description of the drawings]

FIG. 1 is a block diagram showing a configuration of a wireless communication apparatus according to Embodiment 1 of the present invention.

FIG. 2 is a diagram showing a slot configuration of a signal transmitted / received in the wireless communication apparatus according to Embodiment 1 of the present invention.

FIG. 3 is a diagram showing a slot configuration of signals transmitted and received in a wireless communication apparatus according to Embodiment 2 of the present invention.

FIG. 4 is a diagram showing a slot configuration of signals transmitted and received in a wireless communication apparatus according to Embodiment 3 of the present invention.

FIG. 5 is a diagram showing a slot configuration of signals transmitted and received in a wireless communication apparatus according to Embodiment 4 of the present invention.

FIG. 6 is a diagram showing a slot configuration of a signal transmitted and received in a wireless communication apparatus according to Embodiment 5 of the present invention.

FIG. 7 is a diagram illustrating a time required for processing of downlink transmission power control in the embodiment of the present invention.

FIG. 8 is a diagram showing time required for processing of uplink transmission power control in the embodiment of the present invention.

FIG. 9 is a diagram showing a slot configuration of a signal transmitted and received at a high transmission rate in a conventional wireless communication device.

FIG. 10 is a diagram showing a slot configuration of a signal transmitted and received at a low transmission rate in a conventional wireless communication device.

[Explanation of symbols]

101, 119 Pilot signal generator 103, 121 Transmission power control bit generation unit 104, 118 Frame configuration unit 106 Transmission signal amplitude control unit 113, 122 Received SIR measurement unit 114, 126 Transmission power control unit 201, 204, 207 Pilot data 202 , 205, 206, 208, 209 Transmission power control data 203 data

────────────────────────────────────────────────── ─── Continuation of the front page (56) References JP-A-9-321699 (JP, A) JP-A-10-51354 (JP, A) Kiyo, et al., "SIR in Cofferent DS-CDMA mobile communication" Effect of Base Transmission Power Control ", IEICE Technical Report RC S96-169, The Institute of Electronics, Information and Communication Engineers, February 1997, Vol. 96, No. 530, p. 43-48 (58) Fields investigated (Int. Cl. ⁷ , DB name) H04B ^7/ 24-7/26 102 H04Q ^7/ 00-7/38

Claims (4)

(57) [Claims] An uplink transmission signal whose output power has been changed from the beginning of the first pilot data after receiving downlink transmission power control data is provided with a predetermined offset with respect to the downlink reception timing. A communication terminal device that communicates with a communication base station device, the communication terminal device comprising: a downlink propagation delay, a processing delay required for generating transmission power control data in the communication terminal device, and an uplink propagation delay. In consideration of the processing delay required for generation of transmission power control data in the communication base station apparatus, a slot configuration in which pilot data and transmission power control data are arranged apart from each other, A transmitting unit that performs transmission, and changes output power from the beginning of the first pilot data after receiving the transmission power control data included in the uplink transmission signal. Communication base station apparatus characterized by comprising a control unit for executing a transmit power control for the communication terminal apparatus with a delay of one slot. 2. A communication terminal apparatus for performing communication with a communication base station apparatus according to claim 1, wherein said communication base station apparatus has a delay of one slot at a transmission timing of an uplink with respect to a reception timing of a downlink. Transmission with transmission power control executable offset provided,
A communication terminal device characterized by the above-mentioned. 3. An uplink transmission power control data is determined based on an SIR measurement value of downlink pilot data, and an output power from the head of the first pilot data after receiving the downlink transmission power control data. A communication terminal apparatus for transmitting a transmission signal on the uplink with a predetermined offset with respect to the reception timing on the downlink, and a transmission base station apparatus for communicating with the communication terminal apparatus. The interval between the pilot data and the transmission power control data arranged after the pilot data in the next transmission slot, the offset time, processing delay required for transmission power control data generation in the communication terminal device, downlink The transmission slot is set to be equal to or longer than the sum of the propagation delay of Form, to perform transmission power control for the communication terminal apparatus with a delay of 1 slot, transmission power control method in a communication base station apparatus characterized by. 4. A transmission power control method in a communication terminal device used in the transmission power control method in a communication base station device according to claim 3, wherein the transmission timing of the uplink with respect to the reception timing of the downlink includes The base station apparatus transmits with an offset capable of executing transmission power control with a delay of one slot,
A transmission power control method in a communication terminal device characterized by the above-mentioned.