JP3473693B2 - Method and apparatus for adjusting transmission power of CDMA terminal - Google Patents

Abstract

PROBLEM TO BE SOLVED: To attain transmission power control for each code channel without increasing power consumption and a circuit scale in the case of multi-code transmission using a plurality of code channels in a CDMA(code division multiple access) terminal by frequency spread modulation. SOLUTION: Variable gain circuits 16A, 16B are provided respectively at outputs of spread circuits 15A, 15B provided in each code channel, adders 17, 18 sum outputs of the variable gain circuits 16A, 16B, a modulator 20 applies orthogonal modulation to the sum of obtain a transmission signal. Furthermore, a variable gain circuit 22 is provided to adjust a level of the transmission signal, the variable gain circuit 22 conducts adjustment of average transmission power by the code channel and the variable gain circuits 16A, 16B conduct individual adjustment.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a communication terminal device by CDMA (Code Division Multiple Access) using frequency spread modulation (spread spectrum modulation), and more particularly to one communication terminal device. The present invention relates to a method and apparatus for controlling transmission power in a communication terminal device when performing multi-code transmission in which a plurality of spread code channels are allocated to increase transmission capacity.

[0002]

2. Description of the Related Art In a mobile communication system having a base station and a plurality of mobile communication terminals, the number of terminals that can be accommodated in the system is increased and a spread spectrum technique is used as a connection method capable of flexibly responding to changes in transmission rate. CDMA, which is an application of, has attracted attention.

In the case of mobile communication by CDMA, in particular,
As a spread spectrum method, direct spread (DS: Direct
Sequence) is used, assuming that the transmission power from the mobile communication terminal is the same, the received electric field at the base station is approximately inversely proportional to the square of the distance between the base station and the mobile communication terminal. The strong radio wave from the terminal close to the base station causes strong interference with the weak radio wave from the terminal far from the base station, and the base station cannot normally receive the radio wave from the remote terminal. Therefore, for each terminal so that the strength of the radio waves received from each terminal at the position of the base station is about the same,
It is necessary to control the transmission power.

Conventionally, in a CDMA mobile communication system, one code channel is usually assigned to one terminal used by a user. Here, the code channel is a communication channel specified by a spread code (pseudo-random number sequence) used for spread modulation.

FIG. 7 is a block diagram showing a simplified conventional mobile terminal 101 based on the CDMA system from the viewpoint of transmission power control. Here, only one code channel is used from the mobile terminal 101 to the base station. It is assumed that data is transmitted to 102. The data to be transmitted is supplied to the mobile terminal 101 from the signal source 104 connected to the mobile terminal 101.

The data to be transmitted may be audio signals or sometimes high speed multimedia data output from a computer. In any case, the signal source 104 shall output the data stream at a bit rate of R bits / second.

The mobile terminal 101 includes a receiving antenna 111.
Is connected to the receiver 112, the transmitter 114 is connected to the transmitter 114, the spreading circuit 115 that receives the data stream from the signal source 104, and the digital signal output from the spreading circuit 115 is converted into an analog signal. D
/ A (digital / analog) converter 116, a modulator 117 for quadrature modulating a carrier signal based on the output of the D / A converter 116, and is inserted between the output of the modulator 117 and the input of the transmitter 114. The variable gain circuit 118 is provided. An oscillator circuit 119 for generating a high frequency signal that is a carrier signal is connected to the modulator 117.

The spreading circuit 115 performs processing such as error correction coding, interleaving, and encryption on the data stream from the signal source 104, and then uses a spreading code corresponding to the assigned code channel. Performs frequency spreading and outputs the baseband signal. Here, the spreading circuit 115 is configured as a digital signal processing circuit, and based on a multilevel digital signal that generates a signal by spreading-modulating the data stream from the signal source 104 and represents the instantaneous value of this signal momentarily. Output as a band signal. In the modulator 117, 4-phase PSK (Quadrature Phase Shift Keying) is also performed.
The quadrature modulation is performed by the
From 15, the in-phase component I and the quadrature component Q of the baseband signal are respectively output as multi-valued digital signals, and D / A
The converter 116 independently converts the in-phase component I and the quadrature component Q into analog signals, and the modulator 117 performs modulation by using the in-phase component I and the quadrature component Q as inputs.

Here, the structure of the spreading circuit 115 will be described with reference to FIG. The spreading circuit 115 performs direct spread (DS) modulation as frequency spread modulation on the input data stream. The values in parentheses in FIG. 8 indicate typical examples such as the data rate and the chip rate.

For example, a data rate of 128 kb from the signal source
A data stream of ps (bps is the number of bits per second) is input, and one input is used to divide the data stream into two data streams of half the data rate (64 kbps in this example) of the input data stream. 2 outputs (1
→ The serial / parallel conversion circuit 121 of 2) is provided. One data stream from the serial / parallel conversion circuit 121 corresponds to the in-phase component I in quadrature modulation, and the other data stream corresponds to the quadrature component Q. A PN sequence generator 122 for generating a pseudo random number sequence (PN sequence) as a spreading code sequence for the in-phase component I, and a pseudo random number sequence (P as a spreading code sequence for the in-phase component Q
A PN sequence generator 123 for generating (N sequence) is provided. The data stream on the in-phase component I side and the spreading code sequence are input to the adder 124, whereby the data stream corresponding to the in-phase component I is spread-modulated. Similarly, the data stream and the spreading code sequence on the quadrature component Q side are input to the adder 125, and the data stream corresponding to the quadrature component Q is spread and modulated. Adder 124,1
25 is for performing an exclusive OR operation between the input data stream and the spread code sequence. Each adder 12
The chip rate of the signal after spread modulation output from the 4,125 is, for example, 4.096 Mcps (cps is the number of chips per second). The spread-modulated signals from the adders 124 and 125 are input to FIR (finite impulse response) filters 126 and 127 functioning as low-pass filters, respectively, whereby the FIR filters 126 and 127 output A multi-valued digital signal (for example, an 8-bit value signal) representing the instantaneous values of the baseband signal of the in-phase component I and the quadrature component Q is output momentarily.

In this way, the data stream is frequency-spread modulated, and the output of the modulator 117 provides a transmission signal in a predetermined frequency band. The level of the transmission signal is adjusted by the variable gain circuit 118, and then the transmission signal is transmitted from the transmitter 114. The variable gain circuit 118 is composed of an amplifier capable of changing the gain or an attenuator capable of changing the amount of attenuation. As will be described later, the gain (or the amount of attenuation) in the variable gain circuit 118 is, for example, in steps of 1 dB, T from the receiver 112.
It is controlled by the PC signal.

Now, assuming that the bit rate of the data stream from the signal source 104 is R [bit / sec] and the bandwidth of the transmitted signal is W [Hz], G = W / R (1) Is called diffusion gain.

Upon receiving such a transmission signal from the mobile terminal 101, the base station 102 performs despreading, deciphering, deinterleaving and error correction on this signal. It is assumed that the signal power per bit necessary for the base station 102 to sufficiently receive this signal is E _b , the noise power per 1 Hz is N _0, and the ratio thereof is E _b / N ₀ .
Here, “sufficiently received” means that the bit error rate in the output data stream after error correction satisfies a predetermined level. Then, the carrier / noise ratio (C / N) required in the base station 102 is C / N = (R · E _b ) / (W · N ₀ ) = (1 / G) · (E _b / N ₀ ). (2) From this, the signal level required by the base station 102 is represented by C = N · (1 / G) · (E _b / N ₀ ) (3). Therefore, the base station 102 controls the mobile terminal 101 so that the signal reception level is always C.
Send a command to control the transmit power. Specifically, when the signal level of the code channel received from a certain mobile terminal 101 is smaller than the value C, the base station 102 sets the transmission power of the mobile terminal 101 by a fixed amount (for example, 1 dB).
The command to raise and, conversely, the command to lower if it is large are sent to the mobile terminal. This command is TPC
(Total Power Control) signal. This signal can be, for example, a command to increase the transmission power when the value is "1" and a command to decrease the transmission power when the value is "0".

The mobile terminal 101 receives the TPC signal from the receiver 1
Received at 12. The received TCP signal is output from the receiver 112 to the variable gain circuit 118, and the variable gain circuit 118 changes the gain according to the TCP signal by a certain amount (for example, 1).
Increase or decrease by dB). As a result, the transmission signal level is adjusted to the level required by the base station 102. The method of controlling the transmission power of the mobile terminal in this way is called closed loop control. This control method is very commonly used in the IS-95 CDMA system, which is a mobile communication system in the United States.

By the way, in recent years, in the field of mobile communication as well, transmission data has become multimedia, and it is not tired of low-speed data communication of only voice, and higher speed transmission such as connection to the Internet and image communication. A scheme is required. As one method for satisfying these demands, multi-code transmission is drawing attention.

The multi-code transmission differs from the conventional one in that
By allocating a plurality of (for example, two channels) code channels to one terminal, the transmission speed is increased. If the number of codes is N (where n ≧ 2) and the bit rate per code is R ₀ ,
The total transmission rate R _T is R _T = N · R ₀ (4) That is, it is possible to increase the transmission rate N times as compared with the case of using a single code channel.

However, when performing multi-code transmission, it is required to precisely control the transmission power for each code channel for the reasons described below. The present invention deals with how to control the transmission signal power of a terminal when performing multi-code transmission.

A major application of multi-code transmission is the simultaneous transmission of a voice signal and a data signal. Specifically, two code channels may be used, one of which is allocated for transmission of a voice signal such as a conversation and the other is allocated for transmission of a data signal for file exchange between computers. Considering such a situation, the permissible error rate differs between the voice signal and the data signal. For example, a bit error rate of about 10 ⁻³ is permitted for the voice signal, whereas the bit error rate of the data signal is The error rate may be required to be 10 ⁻⁶ or less. On the other hand,
In order to improve the capacity of the mobile communication system as a whole when frequency spread modulation is used, it is important to reduce the transmission power as a whole. Furthermore, in a certain area of the mobile communication system, although the number of mobile terminals performing voice communication is large at a certain moment, it is considered that the number of mobile terminals performing data communication is not so large. In consideration of the above, in a mobile terminal performing multi-code transmission, the transmission power of both code channels of a voice signal and a data signal is controlled based on the bit error rate required for the data signal while making both the same. not,
By making the transmission power of the code channel of the voice signal relatively small and making the transmission power of the code channel of the data communication relatively large, the mobile communication system while satisfying the bit error rate required for each signal It is possible to increase the total capacity, and
The callable time based on the battery capacity of the mobile terminal can be extended.

The reason why the transmission power control should be performed for each code channel in the case of performing multi-code transmission has been described above by exemplifying the case where the voice signal and the data signal are assigned to the respective code channels. The types of signals to be used are not limited to voice signals for conversation and data signals for file exchange. For example, moving image data and still image data may be transmitted. Further, even with regard to an audio signal, there are cases where relatively low sound quality such as conversation is permitted and cases where relatively high quality such as music is required. Even in the data communication between computers, the bit error rate required for the CDMA transmission layer differs depending on the upper protocol. Therefore, it is necessary to determine the bit error rate and the like according to the type and nature of the signal (data) to be transmitted, and to appropriately control the transmission power accordingly.

It is also possible to change the transfer rate of data to be transmitted for each code channel. Considering that the chip rate determines the bandwidth of the signal after spread modulation, the spreading gain is improved as the data rate is lower if the chip rate is the same, so that the transmission power can be correspondingly reduced. From this point as well, it is required to accurately control the transmission power for each code channel.

Among the methods for controlling the transmission power for each code channel, the easiest one to imagine is the circuit from the signal source 104 to the variable gain circuit 118 in the circuit shown in FIG. This is a method in which the number of code channels to be used is prepared, the outputs of these variable gain circuits are added in an analog manner by a high-frequency signal adder (combiner), and the added signals are input to the transmitter. .
FIG. 9 is a block diagram showing the configuration of a mobile terminal that controls transmission power by the method described here, where N = 2, that is, the mobile terminal uses two code channels. This mobile terminal 121 is the same as the mobile terminal 101 shown in FIG.
It is a matter of simply mounting two systems up to 8. Figure 9
Then, by adding one of the subscripts A and B to the code, it clearly indicates to which system each component belongs. That is, the circuit corresponding to the code channel A is a circuit from the signal source 104A to the variable gain circuit 118A, and the circuit corresponding to the code channel B is a circuit from the signal source 104B to the variable gain circuit 118B. The spreading codes used in the spreading circuits 115A and 115B are the spreading codes of the code channels A and B, respectively. Therefore, the spreading circuits 115A and 115B use different spreading codes from each other. Further, the oscillator circuit 119 for generating the carrier wave signal includes modulators 117A and 117B.
It is provided in common. Both variable gain circuits 118
The outputs of A and 118B are analogically added by a signal adder (combiner) 122, and the output of the signal adder 122 is input to the transmitter 114. As a result, the signal obtained by adding the transmission signals of the code channels A and B is the base station 102.
Sent to.

The base station 102 has code channels A and B.
TPCA signal and TPCB, which are TPC signals for each code channel, are regarded as individual channels.
The signal is transmitted to the mobile terminal 121. The mobile terminal 121
The signal from the base station 101 is received, and the variable gain circuit 11 is respectively received using the received TPCA signal and TPCB signal.
8A and 118B are controlled. As a result, closed loop power control is performed for each code channel.

[0023]

However, when the transmission power for each code channel is controlled by using a circuit as shown in FIG. 9 when performing multi-code transmission, this circuit is simply a signal source. From the transmitter to the variable gain circuit just before the transmitter, the circuit scale is not so different from the case where individual mobile terminals for each code channel are used. . Especially high frequency circuits such as modulators and D / A
Since the converters are provided in the same number as the code channels, the power consumption becomes larger than that of a normal terminal. In particular, providing a plurality of D / A converters directly leads to an increase in power consumption. After all, the configuration shown in FIG. 9 does not mean that the terminal is suitable for multi-code transmission. Further, in the case of multi-code transmission, since there are a plurality of code channels, the control of the transmission power becomes complicated. However, in the configuration shown in FIG. 9, this control is not rationalized.

An object of the present invention is a transmission power control method and apparatus for controlling transmission power during multicode transmission, which can further reduce the circuit scale and power consumption, and
It is an object of the present invention to provide a method and an apparatus capable of performing optimum power control.

[0025]

A method of adjusting transmission power of a CDMA terminal according to the present invention is a CDMA in which code division multiple access is performed by frequency spreading modulation and information is transmitted by multicode transmission using a plurality of code channels.
A method of adjusting the transmission power in a terminal, which involves performing spread spectrum modulation on data for each code channel ,
Code channel consisting of in-phase component and quadrature component of
A spread modulation signal for each code channel, a level difference between each code channel by adjusting the level of the spread modulation signal of the in- phase component and the quadrature component for each code channel, and the phase- adjusted in- phase component <br/> spread modulation signal and quadrature components over a plurality of code channels
Each time, the step of generating a high frequency signal by performing modulation based on the added signal and adjusting the level of the high frequency signal
And a step of performing.

[0026] In the transmission power adjusting method of the present invention further comprises the step of determining the adjustment amount of the level of the spread-modulated signal for each code channel, and adjust the process according to the determined adjustment amount is a level of diffusion modulation signal It may be adjusted. Further, in the present invention preferably further comprises a high-frequency signal level has been adjusted as factory for sending towards the other station. In the transmission power adjusting method of the present invention, it is preferable to determine the adjustment amount of the spread modulation signal level and the adjustment amount of the high frequency signal level for each code channel based on a control signal from a partner station such as a base station. . In this case, when the control signal raises or lowers the level in common to each code channel by a certain amount, the level of the spread modulation signal is not changed and only the level of the high frequency signal is changed. Well, the step of adjusting the level of the high frequency signal adjusts the average transmission signal level of the code channel, and the step of adjusting the level of the spread modulation signal for each code channel adjusts the level difference between the code channels. You may do it.

The transmission power adjusting apparatus for a CDMA terminal of the present invention performs code division multiple access by frequency spreading modulation and uses multiple code channels for multi-code.
A transmission power adjustment unit in a CDMA terminal for transmitting information through a transmission, data for each code channel
The data frequency spread modulation, from the in-phase and quadrature components of the signal
And <br/> spreading circuit for generating an output signal for each code channel configured, in-phase component provided for each code channel
And first level adjusting means for adjusting the level difference between the code channels by adjusting the level of the output signal of the quadrature component, and the output of the in-phase component and the quadrature component whose levels have been adjusted
Add signal component-wise over multiple code channels
High-frequency signal by performing modulation based on the signal after addition
A modulator that produces a
2 level adjusting means .

[0028] In the transmission power adjusting apparatus of the CDMA terminal of the present invention further comprises a control means for determining an adjustment amount of the level of diffusion modulation signal for each code channel, the first level adjusting means in accordance with tone Seiryou the it is preferably characterized in that for adjusting the level of the diffusion modulation signal. CD of the present invention
In the transmission power adjusting device for the MA terminal, it is particularly preferable to provide a transmitter for sending the output signal of the second level adjusting means to the partner station such as a base station. Further, it is preferable that each diffusion circuit and each first level adjusting means are provided in the digital signal processing circuit section, and the second level adjusting means is configured as a high frequency analog circuit.

In the transmission power adjusting device of the present invention,
It is common to adjust the transmission power based on a control signal from a partner station such as a base station. for that reason,
For example, based on the control signal from the partner station, each first record
You may make it provide the control means which determines the level adjustment amount in a bell adjustment means and a 2nd level adjustment means. As the control means, for example, a level control arithmetic circuit described in the embodiments described later is used. In this case, the average transmission signal level of the code channels is adjusted by the first level adjusting means, and the level difference between the code channels is adjusted by the second level.
It may be adjusted by the adjustment means.

Further, the level difference between the code channels may be preset so that only the level adjustment amount of the second level adjusting means is controlled by the level control signal from the partner station. In this case, a level setting circuit for setting the level adjustment amount in each first level adjusting means based on the required level difference between the code channels may be provided. Further, the level difference between code channels may be determined by using information about the property of transmission data in each code channel.

[0031]

BEST MODE FOR CARRYING OUT THE INVENTION Next, preferred embodiments of the present invention will be described with reference to the drawings.

<< First Embodiment >> FIG. 1 is a block diagram showing a configuration of a mobile terminal of a first embodiment including a transmission power control apparatus of the present invention. Here, it is assumed that the number of code channels of the multicode is 2. Here, these two code channels are distinguished by the subscripts A and B.

The mobile terminal 1 has code channels A and B.
Signal sources 4A, 4 for generating respective data streams
B is connected. Further, the mobile terminal 1 has a receiver 12 to which a receiving antenna 11 is connected, a transmitter 14 to which a transmitting antenna 13 is connected, and spread circuits 15A and 15B that receive data streams from signal sources 4A and 4B, respectively.
And variable gain circuits 16A and 16B provided on the output sides of the diffusion circuits 15A and 15B, respectively.

The spreading circuits 15A and 15B are composed of signal sources 4A and 4B.
For the data stream from B, error correction coding,
After performing processing such as interleaving and encryption, frequency spreading modulation by direct spreading is performed using a spreading code corresponding to the assigned code channel, and a baseband signal is output. Spreading circuit 15A is code channel A
, And the spreading circuit 15B uses the spreading code for code channel B. Here, the mobile terminal 1 transmits the transmission signal modulated by QPSK.
From the base station 2 to the base station 2, the spreading circuit 15A of the code channel A outputs the in-phase component IA and the quadrature component QA of the baseband signal, and similarly, the spreading circuit 15B of the code channel B outputs the baseband signal. The in-phase component IB and the quadrature component QB of the signal are output. The internal circuit configuration of the spreading circuits 15A and 15B is the same as the internal configuration of the spreading circuit described with reference to FIG.

The variable gain circuit 16A has an in-phase component IA and a quadrature component QA of the baseband signal of the code channel A.
And the variable gain circuit 16B adjusts the levels of the in-phase component IB and the quadrature component QA of the baseband signal of the code channel B.

Further, on the output side of the variable gain circuits 16A and 16B, an adder 17 for outputting the in-phase component I, which is a vector addition of the in-phase components IA and IB of the baseband signals of the respective code channels, and a quadrature. Ingredients QA, QB
There is provided an adder 18 for outputting a quadrature component Q obtained by vector-adding and combining. That is, the adder 1
In-phase component I and quadrature component Q output by 7 and 18 respectively
For, I = IA + IB (5) Q = QA + QB (6)

In the mobile terminal 1 of this embodiment, the spreading circuit 1
5A, 15B, variable gain circuits 16A, 16B and adder 1
Reference numerals 7 and 18 constitute a digital signal processing circuit unit 5 that performs digital signal processing. The diffusion circuits 15A and 15B are
A signal obtained by spreading-modulating the data streams from the signal sources 4A and 4B with a spreading code is generated, and a multilevel digital signal that represents the instantaneous value of this signal momentarily is output as a baseband signal. The variable gain circuits 16A and 16B can be configured as, for example, coefficient multipliers (multipliers), and the spreading circuit 15
The level is adjusted by multiplying the multivalued digital signal which is the output of A, 15B by the value corresponding to the level adjustment value, and the result is also output as a digital value. The adders 17 and 18 respectively output the in-phase component I and the quadrature component Q, which are momentarily synthesized, as digital values by digital calculation.

At the output side of the adders 17 and 18, a D / A (digital / digital) for converting a digital value signal into an analog signal is provided.
An (analog) converter 19 is provided. The D / A converter 19 converts the in-phase component I and the quadrature component Q of the baseband signal, which is a digital signal, respectively, and outputs the in-phase component I and the quadrature component Q of the analog signal. The quadrature component Q is input to the modulator 20. An oscillator circuit 21 that generates a high frequency signal that is a carrier signal is connected to the modulator 20, and the modulator 20 is
A carrier signal is quadrature-modulated by QPSK based on the in-phase component I and the quadrature component Q of the baseband signal from the A converter 19, and a transmission signal is output. This transmission signal is input to the transmitter 14 via the variable gain circuit 22, whereby
The transmission signal is transmitted to the base station 2 side. The variable gain circuit 22 is for adjusting the level of the transmission signal, and is composed of an amplifier capable of changing the gain or an attenuator capable of changing the amount of attenuation. .

Further, the mobile terminal 1 is provided with a level control arithmetic circuit 23 for controlling the level adjustment values in the variable gain circuits 16A, 16B and 22. The level control arithmetic circuit 23 includes a TP for each code channel.
The TPCA signal and the TPCB signal, which are C signals, are received by the receiver 1.
2 and the level control arithmetic circuit 23 inputs these TP
Variable gain circuit 1 based on the CA signal and the TPCB signal
Control signals A, B, and C for level adjustment are output to 6A, 16B, and 22, respectively.

After all, as compared with the mobile terminal 121 shown in FIG. 9, the mobile terminal 1 shown in FIG. 1 is configured to perform QPSK modulation after synthesizing the baseband signals of both code channels, and it is variable for each code channel. Gain circuit 16
A and 16B are provided in the digital signal processing circuit unit 5 and a variable gain circuit 22 that acts commonly on both code channels is provided in the high frequency analog circuit, and the variable gain circuits 16A, 16B and 22 are properly arranged. The difference is that a level control arithmetic circuit 23 for moving is provided. That is, the mobile terminal 1 has a total of three gain control circuits.

Next, the operation of the mobile terminal 1 will be described.

The data stream of each code channel is input from the signal sources 4A and 4B to the spreading circuits 15A and 15B, subjected to frequency spreading, and converted into in-phase component and quadrature component baseband signals. These baseband signals are
Variable gain circuits 16A and 16B for each code channel
After the level is adjusted by, the in-phase components and the quadrature components are added by the adders 17 and 18, and the combined in-phase component I and quadrature component Q are obtained. The signals of the in-phase component I and the quadrature component Q are converted into analog signals by the D / A converter 19, and then input to the modulator 20. As a result, a four-phase PSK-modulated high-frequency signal is obtained as a transmission signal, and this transmission signal is
It is transmitted to the base station 2 via the variable gain circuit 22 and the transmitter 14.

The base station 2 receives the signal of each code channel from the mobile terminal 1 and, for each code channel,
It is determined whether the reception level is an appropriate level, and the mobile terminal 1 receives the TPCA signal and the TPCB signal, which are power control signals for each code channel, according to the determination result.
Send to. In the mobile terminal 1, the receiver 12 uses these TPs.
Received CA signal and TPCB signal and received TPCA
The signal and the TPCB signal are sent to the level control arithmetic circuit 23. The level control arithmetic circuit 23 uses the TPCA signal and TP
Variable gain circuit 16A, 16B, 22A based on CB signal
To control.

Here, the control of the variable gain circuits 16A, 16B and 22 based on the TPCA signal and the TPCB signal will be described in detail. Here, the power control signals (TPCA signal and TPCB signal) for each code channel are
It indicates whether to increase or decrease the transmission power of the code channel, and is transmitted from the base station 2 periodically (for example, included in the pilot signal portion of each transmission slot). I shall.

Of the three variable gain circuits, the variable gain circuit 22 in the high frequency analog circuit section can obtain a wide dynamic range exceeding 80 dB, so that an average and large level fluctuation of the two code channels can be obtained. It is desirable to control with this variable gain circuit 22. On the other hand, the individual variable gain circuits 16A and 16B for each code channel are configured inside the digital signal processing circuit 5, and the D / A converter 19 is provided.
Due to the limitation of the word length, the dynamic range can be about 20 dB at most, and it is desirable to limit the use to setting the level difference between code channels. Therefore, the control procedure as shown in FIG. 2 is performed. In the figure, variables A, B, and C are gains of the variable gain circuits 16A, 16B, and 22 in dB units, respectively. The meanings of the conditions are as follows. TPCA = UP: Increase the transmission power of code channel A by 1 dB. TPCA = DOWN: Lower the transmission power of code channel A by 1 dB. TPCB = UP: Increase the transmission power of code channel B by 1 dB. TPCB = DOWN: Lower the transmission power of code channel B by 1 dB.

First, in step 51, the meanings of the TPCA signal and the TPCB signal are analyzed and conditional branching is performed.

When TPCA = UP and TPCB = UP, in step 52, the control signal C is output so as to increase the gain C of the variable control circuit 22 by 1 dB, and the process ends. Similarly, TPCA = DOWN and TPCB =
In the case of DOWN, in step 53, the control signal C is output so that the gain C of the variable control circuit 22 is lowered by 1 dB, and the process is ended. After all, TPCA signal and TPC
When both B signals are UP or both are DOWN,
Transmission power control is performed using only the variable gain circuit 22 in the high frequency analog circuit section.

On the other hand, when one of the TPCA signal and the TPCB signal is UP and the other is DOWN, if the variable gain circuits 16A and 16B are within the control range, they are controlled by them, and if they are out of the control range. , Variable gain circuit 22
Control is also included. That is, TPCA = UP and T
When PCB = DOWN, it is first determined whether or not the gain A of the variable gain circuit 16A is the maximum value (MAX) (step 54), and if it is the maximum value, the process directly proceeds to step 56, and if it is not the maximum value. , Gain A is 1 dB in step 55
After raising, the process proceeds to step 56. In step 56, it is determined whether or not the gain B of the variable gain circuit 16B is the minimum value (MIN), and if it is not the minimum value, step 57.
Then, the gain B is lowered by 1 dB, and the processing is terminated. If it is the minimum value, the gain C of the variable gain circuit 22 is set to 1 d in step 58.
After lowering B, the process ends.

Similarly, TPCA = DOWN and TPCB
= UP, it is first determined whether or not the gain B of the variable gain circuit 16B is the maximum value (MAX) (step 5
9) If it is the maximum value, the process directly proceeds to step 61. If it is not the maximum value, the gain B is increased by 1 dB in step 60 and then the process proceeds to step 61. In step 61, it is determined whether or not the gain A of the variable gain circuit 16A is the minimum value (MIN). If it is not the minimum value, the gain A is lowered by 1 dB in step 62, and the process is terminated. , In step 63, the gain C of the variable gain circuit 22 is lowered by 1 dB, and then the process ends.

Depending on the system design of the mobile communication system by CDMA, the power control signal (TPCA signal and TPCB signal) for each code channel may be increased by 1 dB (UP) or 1 dB for the transmission power of the code channel. In addition to instructing (DOWN), it may instruct not to change the transmission power (NOP). In such a case, the power control signal (TPCA signal and T
It may be that either one of the PCB signals does not change the transmission level. In such a case, as a general rule, the variable gain circuits 16A and 16B should be used. If the control range of the variable gain circuits 16A and 16B is not sufficient, control including the variable gain circuit 22 should be performed. Assumed to be performed.

FIG. 3 is a flow chart showing a control procedure in the case where the power control signal instructs three ways of increasing the transmission power (UP), decreasing the transmission power (DOWN) and keeping the transmission power unchanged (NOP). is there.

First, it is determined whether at least one of the TPCA signal and the TPCB signal is NOP (step 7).
0), if none of them are NOPs, the same processing as the processing shown in FIG. 2 is performed (A in the figure). If at least one is a NOP, then the TPCA signal and TPC
The meaning of the B signal is analyzed and conditional branching is performed (step 7).
1).

If TPCA = DOWN and TPCB = NOP as a result of the conditional branch, in step 72,
It is determined whether or not the gain A of the variable gain circuit A is the minimum value, and if it is not the minimum value, the gain A is lowered by 1 dB in step 73 and the processing is terminated. If it is the minimum value, the gain A cannot be lowered any further. Therefore, in step 74, the variable gain circuit B
And the gain C of the variable gain circuit C are increased by 1 dB.
Is decreased by 1 dB so that the gain of code channel A is decreased by 1 dB and the gain of code channel B remains unchanged. Similarly, TPCA = UP and TP
If CB = NOP, it is determined in step 75 whether or not the gain A is the maximum value. If it is not the maximum value, the gain A is increased by 1 dB in step 76, and the process is terminated. At 77, the gain B is lowered by 1 dB and the gain C is raised by 1 dB. If TPCA = NOP and TPCB = DOWN, in step 78, it is determined whether or not the gain B is the minimum value. If it is not the minimum value, the gain B is lowered by 1 dB in step 79, and the process is terminated. If so, the gain A is set to 1 in step 80.
As the dB is increased, the gain C is decreased by 1 dB. Also, TPC
If A = NOP and TPCB = UP, step 8
In step 1, it is determined whether or not the gain B is the maximum value. If it is not the maximum value, the gain B is increased by 1 dB in step 82, and the process is terminated. If it is the maximum value, the gain A is decreased by 1 dB in step 83 and the gain is increased. Increase C by 1 dB. TP
When CA = NOP and TPCB = NOP, the process is terminated without doing anything.

The procedure for adjusting the transmission power in mobile terminal 1 is not limited to that shown in FIG. 2 (or FIG. 3). The average transmission level of the code channels A and B may be adjusted by the variable gain circuit 22, and the level difference between the code channels A and B may be adjusted by the variable gain circuits 16A and 16B.

In the mobile terminal of the first embodiment described above, unlike the conventional mobile terminal shown in FIG. 9, the number of variable gain circuits provided in the D / A converter, the modulator and the high frequency analog circuit section is small. Since only one is required for each, increase in circuit scale and power consumption can be suppressed. Further, in the digital signal processing circuit section 5, individual variable gain circuits 16A and 16B for each code channel are provided, and by these, the level difference between the code channels at the time of multi-code transmission can be set.

<Second Embodiment> In the first embodiment described above, the number N of code channels is set to 2, but FIG. 4 shows a mobile terminal in which the number of code channels is set to M (M ≧ 3). 6 shows the configuration of No. 6. In this mobile terminal, M signal sources 4A to 4M are connected, and in the digital signal processing circuit unit 5, M systems of configurations from a spreading circuit to a variable gain circuit on the digital side are provided. That is, the digital signal processing circuit unit 5 includes M spread circuits 15A to 15A.
Equipped with M and M variable gain circuits 16A to 16M,
In-phase signals IA to I from the variable gain circuits 16A to 16M
M is added by the adder 17 to form the in-phase signal I, and similarly, the quadrature signal QA from each of the variable gain circuits 16A to 16M.
~ QM are added by the adder 18 to form the in-phase signal Q. The level control arithmetic circuit 23A is a variable gain circuit 16A.
-16M, 22 levels are controlled. Adder 17,18
The configuration on the output side of is the same as that of the first embodiment.

In this mobile terminal 6, based on the TPC signal for each code channel transmitted from the base station 2,
The level control arithmetic circuit 23A includes variable gain circuits 16A to 16A.
Determine the level adjustment amount for M and 22. Specifically, for example, the average transmission signal level of each code channel may be adjusted by the variable gain circuit 22, and the level difference between code channels may be adjusted by the variable gain circuits 16A to 16M.

It will be understood that even if the number of code channels used by the mobile terminal is three or more, it is sufficient to tamper with the configuration in the digital signal processing circuit section 5 in the mobile terminal of the first embodiment. Therefore, it is possible to suppress an increase in circuit scale and power consumption even if the number of code channels used increases.

<< Third Embodiment >> When a plurality of code channels are used in a single mobile terminal, the reception level required for each code channel on the base station side is the error correction method for each code channel. And the spreading factor G and the required error rate level (for example, about 10 ⁻³ for voice communication and about 10 ⁻⁶ for data communication), the difference between these reception levels is considered to be almost constant. Therefore, considering that these code channels were transmitted from the same mobile terminal,
Although the transmission power itself has to be controlled within a fairly wide range, it is considered that the difference in required transmission power between code channels is uniquely determined according to the difference in transmission method.

Therefore, in the mobile terminal 1 of the first embodiment, if the types of the signal sources 4A and 4B are known, it is considered that the required transmission level difference between code channels is uniquely determined. The mobile terminal 7 shown in FIG. 5 is different from the mobile terminal 1 shown in FIG. 1 in that instead of providing the level control arithmetic circuit 23, the signal types of the signal sources 4A and 4B are identified and the level difference between the code channels A and B is detected. Calculate and variable gain circuit 1
The configuration is such that a level setting circuit 24 for setting 6A and 16B is provided. The mobile terminal 7 has its own level setting circuit 24 to adjust the relative level difference to the variable gain circuit 1.
If 6A and 16B are set, by controlling the variable gain circuit 22 using the power control signal from the base station 2 (either the TPCA signal or the TPCB signal: hereinafter, it will be simply referred to as the TPC signal). , Power control can be realized.

Further, the relative level between the code channels is calculated in advance based on parameters such as the bit rate, the error correction method, the spreading rate, the required error rate and the like, which is stored in the ROM.
If it is stored in the (read only memory) and read from the level setting circuit 24, it is not necessary to perform the calculation, the circuit can be further simplified, and the power consumption can be reduced.

<Fourth Embodiment> In each of the above embodiments, assuming that the number of code channels is M, M in the digital signal processing circuit unit 5 and one in the output side of the modulator, M + 1 in total. Variable gain circuit. However, since the number of code channels to be controlled is M, originally, it suffices to have M variable gain circuits as a whole. Considering that the variable gain circuit provided in the digital signal processing circuit unit cannot have such a dynamic range, the variable gain circuit in the high frequency circuit unit is indispensable. Therefore, in the digital signal processing circuit unit, a configuration in which the variable gain circuit is omitted for one specific code channel can be considered.

FIG. 6 is a block diagram showing a configuration in which the variable gain circuit of one specific code channel is removed when M = 2. This mobile terminal 8 is the variable gain circuit 1 on the side of the code channel A in the mobile terminal 1 shown in FIG.
6A is removed, and the baseband signals of the in-phase component and the quadrature component from the spreading circuit 15A are respectively added by the adder 17,
I am directly inputting to 18. In addition, the level control arithmetic circuit 2
The 3B controls the variable gain circuits 16B and 22 based on the TPCA signal and the TPCB signal.

In the case of this mobile terminal 8, since the number of code channels is equal to the total number of variable gain circuits, when the level adjustment value for each code channel is given, the level adjustment amount in each variable gain circuit is increased. Is uniquely determined. For example, in the case of adjusting the level of only the code channel A, the level in the variable gain circuit 22 is adjusted by the amount corresponding to the adjustment amount, and the code channel B is adjusted by the amount obtained by inverting the sign of the adjustment amount. Variable gain circuit 16
Adjust the level with B. When adjusting the level of only the code channel B, the variable gain circuit 16B may adjust the level based on the adjustment amount. further,
If you want to adjust the level of both code channels,
A combination of the adjustment amounts when adjusting only code channel A and when adjusting only code channel B.
The level may be adjusted in each variable gain circuit 16B, 22.

Although the preferred embodiments of the present invention have been described above, the present invention is not limited to the above-mentioned embodiments.

In the above-mentioned embodiment, the transmission power control in the mobile terminal in the mobile communication system has been described, but the present invention is also applied to a CDMA system other than the mobile communication system, for example, a system assuming a terminal that does not move. It is possible. As such a system, there is a wireless local loop system used in place of a wired telephone network when constructing a telephone network in an area with a low population density or a developing country. Further, the type of spread spectrum modulation is not limited to direct spread (DS), and for example, frequency hopping (FH: frequency) may be used.
hopping and chirp diffusion can be used. Further, the modulation method in the modulator is not limited to the quadrature modulation by QPSK, but π / 4 shift QPSK
And DPSK (differential phase shift modulation)
shift keying) or BPSK (binary phase shift modulation: bin
A modulation method such as ary phase shift keying) can be adopted.

[0067]

As described above, according to the present invention, even when a plurality of code channels are used and the transmission power is controlled for each code channel, the high frequency circuit part is adjusted while adjusting the level difference between the code channels. Since only one variable gain circuit needs to be provided, there is an effect that an increase in circuit scale and power consumption can be suppressed.

[Brief description of drawings]

FIG. 1 is a block diagram showing a configuration of a mobile terminal according to a first embodiment of the present invention.

FIG. 2 is a flowchart showing an example of a processing procedure of transmission power control.

FIG. 3 is a flowchart showing an example of a processing procedure of transmission power control.

FIG. 4 is a block diagram showing a configuration of a mobile terminal according to a second embodiment of the present invention.

FIG. 5 is a block diagram showing a configuration of a mobile terminal according to a third embodiment of the present invention.

FIG. 6 is a block diagram showing a configuration of a mobile terminal according to a fourth embodiment of the present invention.

FIG. 7 is a block diagram showing a configuration of a conventional mobile terminal using CDMA.

FIG. 8 is a block diagram showing a general configuration of a spreading circuit.

[Fig. 9] Fig. 9 is a block diagram showing a configuration conceivable when transmission power is controlled for each code channel in a mobile terminal having two code channels.

[Explanation of symbols]

1,6-8 mobile terminals 2 base stations 4A, 4B, ..., 4M signal source 5 Digital signal processing circuit 11,13 antenna 12 receiver 14 transmitter 15A, 15B, ..., 15M Spreading circuit 16A, 16B, ..., 16M, 22 Variable gain circuit 17,18 adder 19 D / A converter 20 modulator 21 Oscillation circuit 23,23A, 23B level control arithmetic circuit 51-63, 70-83 steps

─────────────────────────────────────────────────── ─── Continuation of the front page (58) Fields surveyed (Int.Cl. ⁷ , DB name) H04B ^7/ 24-7/26 H04Q ⁷ /00-7/38 H04J 13/00

Claims (22)

(57) [Claims] 1. A method for adjusting transmission power in a CDMA terminal which performs code division multiple access by frequency spreading modulation and transmits information by multicode transmission using a plurality of code channels, the method comprising: the in-phase data and spread spectrum modulation, and generating a spread modulated signal for each code consisting channelization down Ne <br/> Le from the in-phase and quadrature components of the signal <br/> No. for each code channel An adjustment step of adjusting the level difference between the code channels by adjusting the levels of the spread modulation signals of the component and the quadrature component, and the level-adjusted spread modulation signal of the in-phase component and the quadrature component was added to each component over a plurality of code channels, generating a high-frequency signal by performing modulation based on the signal after addition, the high peripheral Transmission power adjusting method of the CDMA terminal including a step of adjusting the level of the signal. 2. The method further includes the step of determining an adjustment amount of the level of the spread modulation signal for each code channel, and the adjusting step adjusts the level of the spread modulation signal according to the determined adjustment amount. The method for adjusting the transmission power of a CDMA terminal according to claim 1 . Wherein the step of determining the adjustment amount of the level of the spread modulation signal, the phase based on the control signal from the manual station, the level adjustment amount of the level of the spread modulated signal of each code channel and the high-frequency signal The transmission power adjustment method for a CDMA terminal according to claim 2 , wherein the adjustment amount is determined. 4. When the control signal raises or lowers the level in common to each code channel by a certain amount, the level of the spread modulation signal is not changed and only the level of the high frequency signal is changed. The transmission power adjustment method for a CDMA terminal according to claim 3 , wherein the transmission power adjustment method is changed. 5. The method of adjusting the transmission power of a CDMA terminal according to claim 2 , wherein the step of adjusting the level of the high frequency signal adjusts the average transmission signal level of the spread modulation signal. 6. The at least one code channel, transmission power adjustment method of the CDMA terminal according to claim 1 or 2 does not perform the level adjustment of said spread modulated signal. 7. The method further comprises the step of determining the level difference between code channels based on data to be transmitted to each code channel, and the adjusting step adjusts the level of the spread modulation signal according to the determined level difference. The method of adjusting the transmission power of a CDMA terminal according to claim 1, wherein: 8. The transmission power adjustment method of the CDMA terminal according to any one of the high-frequency signal according to claim level further comprises a regulated high-frequency signal as engineering to be sent toward the other station of 1 to 7 . Wherein said CDMA terminal is a mobile station in a mobile communication system, CDMA transmission power adjustment method according to any one of claims 1 to 8 is a base station in the phase hand station the mobile communication system . Wherein said frequency spread modulation, CDMA according to any one of claims 1 to 9, which is a direct spread modulation
A method for adjusting the transmission power of a terminal. 11. A transmission power adjusting device in a CDMA terminal for performing code division multiple access by frequency spread modulation and transmitting information by multicode transmission using a plurality of code channels, wherein data is transmitted for each code channel. frequency spread modulation, the phase component and the spreading circuit, provided for each code channel to generate an output signal for each code consisting channelization down Ne <br/> Le from the in-phase and quadrature components of the signal <br/> No. And first level adjusting means for adjusting the level difference between the code channels by adjusting the level of the output signal of the quadrature component, and the level-adjusted output signals of the in-phase component and the quadrature component. was added to each component over a plurality of code channels, a modulator for generating a high-frequency signal by performing modulation based on the signal after addition, Second level adjustment hand for adjusting the level of the serial high-frequency signal
And a transmission power adjusting apparatus for a CDMA terminal including: 12. A control means for determining an adjustment amount of the level of the spread modulation signal for each code channel, wherein the first level adjusting means adjusts the level of the spread modulation signal according to the adjustment amount. The transmission power adjusting apparatus for a CDMA terminal according to claim 11 , wherein. Wherein said control means, based on a control signal from the phase hand station, according to claim 12 for determining the level adjustment amount of said each first adjusting means and the second adjustment means CDMA Terminal transmission power adjustment device. 14. When the control signal raises or lowers the level commonly by each code channel by a fixed amount, the control means changes the level of the spread modulation signal without changing the level of the high frequency signal. claim to set the level adjustment amount so as to vary the level only 13
5. A transmission power adjusting device for a CDMA terminal as described in 1. 15. The method according to claim 11, wherein a level difference between code channels is adjusted by the first adjusting means, and an average transmission signal level of the code channels is adjusted by the second adjusting means . 2. A transmission power adjustment device for a CDMA terminal according to item 1 . 16. A level setting circuit for determining a level difference of the output signal between the code channels based on data to be transmitted to each code channel, and the first level adjustment according to the determined level difference. The transmission power adjusting device for a CDMA terminal according to claim 11 , wherein the means adjusts the level difference. 17. The transmission power adjusting apparatus of a CDMA terminal according to claim 16 , wherein the level setting circuit determines the required level difference by using information about a property of transmission data in each code channel. 18. The method of claim 17, wherein the first adjustment means is not provided to a specific one code channel according to claim 11 or
12. The transmission power adjusting device for a CDMA terminal according to item 12 . 19. The spreading circuit and the first adjusting means are provided in a digital signal processing circuit section, and the second adjusting circuit is provided in the digital signal processing circuit section.
19. The transmission power adjusting device for a CDMA terminal according to claim 11, wherein the adjusting means is configured as a high frequency analog circuit. 20. A partner for a high-frequency signal whose level is adjusted
12. The method according to claim 11, further comprising a transmitter transmitting to the station.
20. Transmission power of CDMA terminal according to any one of 19
Adjustment device. 21. The CDMA terminal is a mobile station in a mobile communication system, one phase hand station of claims 11 to 20 is a base station in the mobile communication system 1
Item 7. A CDMA transmission power adjusting device according to the item. 22. The CD according to claim 11 , wherein the frequency spread modulation is direct spread modulation.
Transmitting power adjusting device for MA terminal.