JP2003273833A - Radio transmitter, radio receiver and radio transmission method - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a signal transmission method in the CDMA mobile communication system, which is capable of preventing the generation of a hearing aid, by providing a large spread rate for each radio frame as a transmission information amount of temporary transmission is smaller and occasionally transmitting the frame with a smaller transmission power. <P>SOLUTION: When regular transmission information and occasional transmission information, which form transmission data are inputted into a radio frame configuration section 3 and a transmission information amount detection section 1, the section 1 detects the information transmission amount of the occasional transmission information and supplies the detection result to a control section 2. The section 2 controls the section 3, a spread section 5 and an amplifier section 6 so that the number of bits in a radio frame becomes smaller, dis-persion rate becomes larger, and the amplification amount is increased for a prescribed period so that the information amount for the prescribed period is smaller, on the basis of the detection result of information transmission amount. <P>COPYRIGHT: (C)2003,JPO

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a radio transmitting apparatus, a radio receiving apparatus and a radio transmitting method in a code division multiple access (hereinafter abbreviated as CDMA) system.

[0002]

2. Description of the Related Art In the CDMA system, the transmission power must be suppressed as much as possible in order to increase the number of users that can be used. As a technique for suppressing the transmission power, VOX (voice Operated Trans) that cuts off the transmission power during silence
mission) Transmission control is known. By using VOX transmission control, transmission power can be suppressed. However, in the VOX transmission control, it is necessary to periodically transmit a part of the information in order to maintain the synchronization or control the transmission power even in the silent state. An example of transmission is shown in FIG.

The transmission signal is, as shown in FIG.
It is configured by repeating a wireless frame including constant transmission information and occasional transmission information. The constant transmission information is information necessary for maintaining synchronization or controlling transmission power. The occasional transmission information is information in which the amount of transmission information such as voice information changes with time. If the transmission information is voice information at any time, and there is voice information to be transmitted, FIG.
As shown in (b), the transmission signal is constantly transmitted. According to the VOX transmission control, when there is no voice information to be transmitted, as shown in FIG. 10C, only the transmission information is constantly transmitted, and the transmission information is not transmitted at any time. In this case, by constantly transmitting the transmission information,
It becomes a periodic intermittent transmission.

[0004]

When periodical intermittent transmission is performed, a nearby audio device (for example, a telephone handset) is used.
On the other hand, a phenomenon (hearing aid) of generating abnormal noise from the speaker due to electromagnetic induction may occur. In a time division multiple access (TDMA) method used worldwide as a second-generation mobile communication system, there is a problem that a hearing aid occurs because periodic intermittent transmission is performed. CDMA as previously mentioned
Also in the method, intermittent transmission is performed by using VOX control. Not only VOX control but also the occasional transmission information is the control information, the intermittent transmission is performed when the occasional transmission information is stopped when there is no control information. Therefore, the CD
In the case of the MA method as well, there is a problem that a hearing aid may similarly occur.

The present invention has been made in view of the above,
The purpose of the CDMA is to prevent the occurrence of hearing aids by increasing the spreading factor and decreasing the transmission power continuously as the transmission information amount of the transmission information becomes smaller for each radio frame. To provide a wireless transmission device, a wireless reception device, and a wireless transmission method in a mobile communication system.

[0006]

In order to achieve the above object, the first feature of the present invention is to repeatedly transmit a radio frame composed of a transmission signal containing transmission information whose transmission information amount changes with time. In a CDMA mobile communication system, a wireless transmission device that spreads and transmits the transmission signal using a spreading code, the transmission information amount detecting means detecting the transmission information amount of the transmission information at any time in the input transmission signal. And 1 of the radio frame in the predetermined period according to the transmission information amount detected in the predetermined period.
Control means for calculating the number of spreading code chips for bits and the transmission power of the radio frame in the predetermined period, and a spreading code corresponding to the calculated number of chips of the spreading code are used in the predetermined period. It is characterized in that it is provided with a spreading means for spreading one bit of a radio frame and a transmitting means for transmitting the radio frame in the predetermined period spread by the spreading means with the calculated transmission power.

According to the first feature of the present invention, for example, for each radio frame, as the transmission information amount of the occasional transmission information is smaller, the spreading factor is increased and the transmission power is reduced, whereby the occasional transmission information is transmitted. By continuously transmitting even if the amount of information to be transmitted is small, it is possible to prevent the occurrence of hearing aid as in the conventional case.

Further, in the first feature of the present invention, when the transmission information amount detected in the predetermined period is large, the control means outputs a spread code for one bit of the radio frame in the predetermined period. It is preferable to calculate so that the number of chips is reduced.

Further, in the first feature of the present invention, the control means transmits the radio frame in the predetermined period so as to be in inverse proportion to the number of chips of a spread code for 1 bit of the radio frame in the predetermined period. It is preferable to calculate the power.

A second feature of the present invention is that a signal in which the amount of transmission information changes with time is spread at a spreading factor selected from a plurality of preset spreading factors according to the amount of transmission information. And a despreading means for despreading the received signal with a plurality of spreading factors, and a reception of each of the signals despread with a plurality of spreading factors by the despreading means. The gist of the present invention is to provide a level measuring means for measuring a level and a selecting means for comparing a plurality of reception levels measured by the level measuring means and selecting and demodulating a signal having the maximum reception level.

A third feature of the present invention is a CDM for repeatedly transmitting a radio frame composed of a transmission signal including transmission information whose transmission information amount changes with time.
A mobile communication system, which is a wireless transmission device that spreads and transmits the transmission signal using a spreading code, the transmission information amount detecting means detecting the transmission information amount of the transmission information in the input transmission signal at any time. And a control means for calculating the number of chips of the spread code for 1 bit of the radio frame in the predetermined period and the transmission power of the radio frame in the predetermined period according to the transmission information amount detected in the predetermined period. And a radio frame composing means for dividing the transmission signal into two series of radio frames for output, and modulating the two series of radio frames outputted from the radio frame composing means with carrier waves of mutually orthogonal phases. Using the modulation means and the spreading code corresponding to the calculated number of chips of the spreading code, the wireless frames of the two sequences in the predetermined period are used. And a transmission means for transmitting each of the two series of radio frames in the predetermined period spread by the spreading means with the calculated transmission power. That is the summary.

According to the third aspect of the present invention, for example, 2
In at least one of the in-phase component and the quadrature component of the radio frames of one sequence, the smaller the transmission information amount of the transmission information at any time for each radio frame, the larger the spreading factor and the smaller the transmission power. By continuously transmitting even if the amount of information to be transmitted is small, it is possible to prevent the occurrence of hearing aid as in the conventional case.

A fourth feature of the present invention is that CDMA for repeatedly transmitting a radio frame composed of a transmission signal containing transmission information whose transmission information amount changes with time.
In a mobile communication system, a radio transmission method for spreading and transmitting the transmission signal using a spreading code, the step of detecting the transmission information amount of the transmission information at any time in the input transmission signal, and in a predetermined period Depending on the detected transmission information amount, 1 of the radio frame in the predetermined period
Calculating the number of spreading code chips for each bit and the transmission power of the radio frame in the predetermined period;
Using the spreading code corresponding to the calculated number of chips of the spreading code, 1 of the radio frame in the predetermined period is used.
With the step of spreading the bits and the calculated transmission power,
And transmitting the radio frame in the predetermined period spread by the spreading unit.

A fifth feature of the present invention is a CDM for repeatedly transmitting a radio frame composed of a transmission signal including transmission information whose transmission information amount changes with time.
A mobile communication method, which is a wireless transmission method for spreading and transmitting the transmission signal using a spreading code, the method comprising: detecting a transmission information amount of transmission information at any time in the input transmission signal; Calculating the number of chips of a spread code for 1 bit of the radio frame in the predetermined period and the transmission power of the radio frame in the predetermined period according to the amount of transmission information detected in Of the two series of wireless frames and outputting the divided two series of wireless frames, modulating the two series of wireless frames output from the wireless frame constructing means with carrier waves of mutually orthogonal phases, and calculating the spread Spreading one bit of each of the two series of radio frames in the predetermined period using a spreading code corresponding to the number of chips of the code; In the transmission power it issued, and summarized in that comprises the step of transmitting each radio frame of the two sequences in the predetermined period of time that is diffused by the diffusion means.

In the fifth aspect of the present invention, the transmission signal includes constant transmission information and the occasional transmission information, and the first radio frame of the two series of radio frames is constantly transmitted. It is preferable that a second wireless frame that includes information and that does not include the constant transmission information among the two series of wireless frames.

[0016]

BEST MODE FOR CARRYING OUT THE INVENTION Embodiments of the present invention will be described below with reference to the drawings.

1 and 2 are block diagrams showing the basic configurations of a radio transmitting apparatus (TX) and a radio receiving apparatus (RX) for implementing a signal transmission method in a CDMA mobile communication system according to an embodiment of the present invention. Is.

First, the configuration of the radio transmitter (TX) shown in FIG. 1 will be described. The wireless transmission device (T
In X), the transmission signal is input by being composed of the constant transmission information and the occasional transmission information, the constant transmission information is supplied to the radio frame configuration unit 3, and the constant transmission information is supplied to the transmission information amount detection unit 1. It The transmission information amount detection unit 1 detects the transmission information amount of the input transmission information at any time, and supplies the detection result (transmission information amount) to the control unit 2.

Based on the detection result of the transmission information amount of the occasional transmission information, the control unit 2 decreases the number of bits in the radio frame in the predetermined period as the transmission information amount of the occasional transmission information detected in the predetermined period decreases. Then, the number of bits in the wireless frame, the spreading factor, and the amplification factor are calculated so as to increase the spreading factor and reduce the amplification amount, and these pieces of information are sent to the wireless frame configuration unit 3, the spreading unit 5, and the amplification unit 6. The number of bits, the spreading factor, and the amplification factor are controlled respectively.

Further, the radio frame construction unit 3 includes a control unit 2
A radio frame is constructed based on the number of bits in the radio frame specified by. The radio frame configured as described above is first-modulated in the modulator 4 and then spread-modulated in the spreader 5. In this case, the spread-modulation in the spreader 5 is performed by the controller 2 every predetermined period. It is done with the diffusion rate specified in. In this way, the radio frame spread-modulated by the spreading unit 5 is controlled by the control unit 2 in the amplification unit 6.
The signal is amplified by the amplification factor designated by and is transmitted from the transmitting antenna 7. Note that the spreading factor is the ratio of the number of chips of the spreading code (spreading chip rate) to 1 bit (information bit rate) of the wireless frame, as described in FIG.

Next, the configuration of the radio receiving apparatus (RX) shown in FIG. 2 will be described. The radio receiver (R
In X), the signals received by the receiving antenna 8 are despread by the plurality of despreading units 9, and the despread signals are supplied to the plurality of level measuring units 10 and the selecting unit 12. . Each of the plurality of level measuring units 10 measures each signal level, and each measurement result is supplied to the level comparing unit 11. The level comparison unit 11 compares the measurement results of the level measurement units 10 and instructs the selection unit 12 to select the signal having the highest signal level. The selection unit 12 selects the specified signal from the plurality of despread signals, assuming that the specified signal is a signal spread by the correct spreading factor,
It is supplied to the demodulation unit 13. The demodulation unit 13 performs data demodulation for the primary modulation.

In the above embodiment, the spreading factor designated by the control unit 2 in FIG. 1 is set to, for example, 64, 128, 256.
As described above, a plurality of values may be determined in advance, and a suitable spreading factor may be selected and transmitted according to the amount of transmission information. in this case,
In the radio receiving apparatus (RX) shown in FIG. 2, the number of despreading units 9 and level measuring units 10 may be the same as the number of spreading factors. For example, when three kinds of diffusion rates are prepared,
The despreading unit 9 and the level measuring unit 10 may be provided three by three.

In the radio receiver (RX) shown in FIG. 2, a plurality of despreading units 9 and level measuring units 10 are used. However, the despreading units 9 and the level measuring units 10 are respectively provided as one. The method of processing each of the despreading unit 9 and the level measuring unit 10 in a time division manner can be similarly performed.

FIG. 3 shows the radio frame configuration output from the radio frame configuration unit 3, the spreading code in the spreading unit 5, and the transmission power after being amplified by the amplifying unit 6 in the radio transmitter (TX) of FIG. Is shown.

In FIG. 3, in the section (a), the radio frame is a combination of the continuous transmission information and the occasional transmission information A
In the section (b), the transmission information amount of the transmission information at any time is smaller than that in the section (a), and the radio frame is composed of B bits (B <A). It shows the case. In either case, the spreading code used in the spreading unit 5 has the same speed as shown in FIG. 3 (b).

As shown in section (a), when one radio frame is composed of A bits, the control unit 2 causes the spreading unit 5 to set one bit of the radio frame to the spreading factor of the spreading code X chip. , And the amplification unit 6 is caused to transmit with the transmission power P as shown in FIG.

The transmission information amount of the transmission information at any time changes with time, and as shown in section (b), one radio frame is
In the case of B bits, the control unit 2 controls the diffusion unit 5
In addition, 1 bit of the radio frame is spread at the spreading rate of the spread code X · A / B chip without changing the spread signal speed, and the amplification unit 6 is caused to transmit at the transmission power P · B / A.

That is, the control unit 2 instructs the amplification unit 6 on the transmission power of the radio frame in the predetermined period so as to be in inverse proportion to the number of chips of the spread code for 1 bit of the radio frame in the predetermined period.

In the above description, one radio frame is B
The reason why the transmission power can be set to P · B / A when configured with bits will be described below. The reception quality on the receiving side is determined by the transmission power and the spreading factor on the transmitting side. The spreading factor is also known as spreading gain, and the larger the value, the better the reception quality. One radio frame consists of A bits,
When 1 bit is spread by an X chip, the spreading factor, that is, the spreading gain is X. When the amount of transmission information of the transmission information decreases at any time, one radio frame is composed of B bits, and one bit is spread by the X · A / B chip, the spreading gain is X.
・ A / B. Therefore, when one radio frame is composed of B bits, the spreading gain can be increased A / B times as compared with the case where one radio frame is composed of A bits.
The reception quality can also be A / B times. The improvement of the reception quality due to this spreading gain gives a margin to the required reception quality. This allowance can be allocated to the reduction of transmission power. That is, the transmission power in the case where one radio frame is composed of B bits can be reduced to B / A times as compared with the case where one radio frame is composed of A bits. Even if the transmission power is reduced, the reception quality does not change due to the improvement of the spreading gain.

As described above, as shown in the section (b), continuous transmission can be performed even when the transmission information amount of the transmission information decreases, so that the occurrence of hearing aid can be prevented.

FIG. 4 and FIG. 5 are block diagrams showing the basic configurations of a radio transmitting apparatus (TX) and a radio receiving apparatus (RX) for implementing a signal transmission method according to another embodiment of the present invention.

First, the configuration of the radio transmitter (TX) shown in FIG. 4 will be described. The wireless transmission device (T
X), similar to the wireless transmitter (TX) shown in FIG.
The transmission signal is input by being constituted by the constant transmission information and the occasional transmission information, the constant transmission information is supplied to the radio frame composing unit 16, and the occasional transmission information is supplied to the transmission information amount detecting unit 14. The transmission information amount detection unit 14 detects the transmission information amount of the transmission information at any time, and supplies the detection result to the control unit 15.

Based on this detection result, the control unit 15 reduces the number of bits in the radio frame in the predetermined period, increases the spreading factor, and decreases the amplification amount as the transmission information amount in the predetermined period decreases. , The number of bits in the radio frame, the spreading factor, and the amplification factor are calculated, and these pieces of information are supplied to the radio frame configuring unit 16, the spreading units 21 and 23, and the amplifying units 22 and 24, respectively, and the number of bits and the spreading factor are spread. The rate and the amplification rate are controlled respectively.

The radio frame composing unit 16 composes two series of radio frames, that is, the in-phase component radio frame and the quadrature component radio frame, based on the number of bits in the radio frame designated by the control unit 15. To do. The in-phase component radio frame and the quadrature component radio frame are subjected to primary modulation by modulators 17 and 20. The carrier wave oscillating unit 18 generates a carrier wave required for modulation, supplies the same to the modulator 17 as a carrier wave for the in-phase component, and passes the carrier wave for the in-phase component through the phase converter 19 to change the phase by π / 2. Modulator 2 as carrier for quadrature component
Supply to 0.

The modulators 17 and 20 respectively modulate the in-phase component and the quadrature component, and then the spreading units 21 and 23 respectively perform spread modulation. The spreading factor in this case is a value designated by the control unit 15 every predetermined period, as described above. The components spread-modulated by the spreading units 21 and 23 are amplified by the amplification factors designated by the control unit 15 in the amplifiers 22 and 24, respectively, and the combining unit 25 combines the in-phase component and the quadrature component, and then the transmitting antenna 26. Sent from.

The spreading factors of the spreading units 21 and 23 and the amplification factors of the amplifying units 22 and 24 do not necessarily have to be the same, and a value suitable for each radio frame configuration can be used.

Next, the configuration of the radio receiving apparatus (RX) shown in FIG. 5 will be described. The wireless receiver (R
In X), the signal received by the receiving antenna 27 is divided into two components, and despread by the plurality of despreading units 28 and 32 for each component. In the despreading units 28 and 32, despreading is performed using the spreading codes used in the spreading units 21 and 23 of the wireless transmission device (TX), respectively. Each despread signal is supplied to the plurality of level measuring units 29 and 33 and the selecting units 31 and 35. Each of the plurality of level measuring units 29 and 33 measures the signal level of each component and supplies the measurement result to the level comparing units 30 and 34. The level comparison units 30 and 34 compare the measurement levels supplied from the plurality of level measurement units 29 and 33, respectively, and designate the selection units 31 and 35 so as to select the signal having the largest signal level. The selection units 31 and 35 are
The respective signals designated by the level comparing units 30 and 34 are selected, and the selected signals are respectively demodulated by the demodulating units 36 and 36.
It demodulates at 37, and thereby a radio frame for the in-phase component and a radio frame for the quadrature component are generated.

Also in the present embodiment, as in the embodiments of FIGS. 1 and 2, a plurality of spreading factors designated by the control unit 15 are determined in advance, and a suitable spreading factor is set according to the amount of transmission information. You may select and transmit. Further, also in the radio reception device (RX) of the present embodiment, a plurality of despreading units 28 and 32.
Although a plurality of level measuring units 29 and 33 are used, one despreading unit and one level measuring unit may be processed in a time division manner.

Further, the radio frame constructed by the radio frame construction unit 16 may always include transmission information in both the in-phase component and the quadrature component, or may include the transmission information in only one of them.

When the transmission information is always included in both components,
The radio frame of FIG. 3 is divided into two every two bits, and 2
Since it is S / P converted into one bit string, both components have the same configuration as in FIG. Further, the respective control methods for the diffusion units 21 and 23 and the amplification units 22 and 24 by the control unit 15 are the same as above.

Each control method for the spreading units 21 and 23 and the amplifying units 22 and 24 by the control unit 15 when the always transmitted information is included in only one component will be described.

A component that always contains transmission information is an in-phase component,
If the component not included is the quadrature component, the radio frame configuration for the in-phase component after output from the radio frame configuration unit 16, the spreading code in the spreading unit 21, and the transmission power after amplification in the amplification unit 22 are the same as those in FIG. . In addition, the radio frame configuration unit 16
FIG. 6 illustrates the orthogonal component radio frame configuration after output, the spreading code in the spreading unit 23, and the transmission power after amplification in the amplification unit 24.
Shown in. The control method is the same as that in FIG. 3 except that there is no constant transmission information.

The control method for each component of the control unit 15 for both the in-phase component and the quadrature component is basically the same as the above, but since the quadrature component is only the transmission information at any time, the bit string of the transmission information at any time is for a predetermined period. If none of them are in the
The control is performed so as to perform F.

Further, as the orthogonal component, which is only the transmission information at any time, a certain fixed spreading factor can be used without changing the spreading factor as shown in FIG. In this case, even if the number of bits in the predetermined period decreases as in the section (b) of FIG.
Since the number of chips of the spreading code for spreading the bits does not change, the transmission power is the same as in the case of section (a) in FIG.
Although the quadrature component is not transmitted continuously, the in-phase component is transmitted continuously, so that the influence of hearing aid can be reduced. Further, it is possible to perform the same operation even in a configuration in which a component that always includes transmission information is a quadrature component and a component that does not include transmission information is an in-phase component.

User information and control information can be considered as the transmission information at any time. The types of radio frame configurations after output from the radio frame configuration section 3 of FIG. 1 are three types of FIG. 8 and the radio frame configuration section 16 of FIG. There are four possible types of radio frame configurations after output as shown in FIG.

That is, when both the in-phase component and the quadrature component always include transmission information, as shown in FIG. 8, (a-1) occasional transmission information includes only user information.

(A-2) The transmission information at any time includes both user information and control information.

(A-3) The occasional transmission information includes only control information.

There are three ways. When the constant transmission information includes only one component, as shown in FIG. 9, (b-1) the component including the constant transmission information includes only the user information, and the component not including the constant transmission information is the control information. Including only.

(B-2) The component including the constant transmission information includes only the user information, and the component not including the constant transmission information includes both the user information and the control information.

(B-3) The component including the constant transmission information includes only the control information, and the component including no constant transmission information includes only the control information.

(B-4) The component including the constant transmission information includes only the user information, and the component including no constant transmission information includes only the user information.

There are four ways.

In particular, the above (a-1), (a-3), (b-
In 1), there is an advantage that the spreading factor and the transmission power can be determined for each component by the transmission information amount of either user information or control information. In addition, the above (b-2)
In general, since the maximum transmission information amount differs between the user information and the control information and the control information amount is smaller, at least the control information is transmitted by either the in-phase component or the quadrature component. This has the advantage that there is no control information and the spreading factor of the component containing the user information can be determined only by the amount of transmission information of the user information.

The always transmitted information may include a pilot symbol for synchronous detection, a unique word for synchronous detection, and a transmission power control bit. The pilot symbol for synchronous detection is described in detail in Japanese Patent Application No. 6-140569. The unique word for keeping synchronization is used in a digital car telephone system (PDC: Personal Digital Cellular) currently implemented in Japan and is an existing technology. Further, the transmission power control bit is described in detail in US Pat. No. 5,056,109.

[0056]

As described above, according to the present invention,
Since the spreading factor is increased and the transmission power is reduced as the transmission information amount of the transmission information for each radio frame is smaller, the periodic transmission is performed by continuously transmitting even when the transmission information amount of the transmission information is smaller. It is possible to prevent the occurrence of hearing aids, which is a problem when performing intermittent transmission.

Further, according to the present invention, the spreading factor is increased as the transmission information amount of the transmission information is reduced for each radio frame in at least one of the in-phase component and the quadrature component,
Since the transmission power of the component is reduced, continuous transmission is performed even when the transmission information amount of the transmission information becomes small, thereby preventing occurrence of hearing aid, which is a problem when performing periodic intermittent transmission. You can

Further, according to the present invention, the spreading factor of the component including the transmission information is constantly changed and the continuous transmission is performed.
Even if the component of only the transmission information is not continuously transmitted at any time, the influence of the hearing aid can be reduced.

According to the present invention, it is possible to determine the spreading factor and the transmission power for each component based on the transmission information amount of either user information or control information.

Further, according to the present invention, since the maximum transmission information amount is generally different between the user information and the control information, and the control information amount is smaller, at least the control information is transmitted by either the in-phase component or the quadrature component. By doing so, there is no control information, and it is possible to determine the spreading factor of the component included in the user information only by the transmission information amount of the user information.

[Brief description of drawings]

FIG. 1 is a block diagram showing a basic configuration of a radio transmission apparatus (TX) that implements a signal transmission method in a CDMA mobile communication system according to an embodiment of the present invention.

FIG. 2 is used with the wireless transmitter (TX) of FIG.
It is a block diagram which shows the basic composition of the radio | wireless receiver (RX) which implements the signal transmission method which concerns on one Embodiment of this invention.

3 is a diagram showing a radio frame configuration output from a radio frame configuration unit, a spreading code in a spreading unit, and transmission power after being amplified by an amplification unit in the wireless transmission device (TX) of FIG.

FIG. 4 is a block diagram showing a basic configuration of a wireless transmission device (TX) that implements a signal transmission method according to another embodiment of the present invention.

FIG. 5 is used with the wireless transmitter (TX) of FIG.
It is a block diagram which shows the basic composition of the radio | wireless receiver (RX) which implements the signal transmission method which concerns on other embodiment of this invention.

6 is a diagram showing a radio frame configuration output from a radio frame configuration unit, a spreading code in a spreading unit, and transmission power after being amplified by an amplification unit in the wireless transmission device (TX) of FIG. 4;

7 shows a radio frame configuration output from a radio frame configuration unit, a spreading code in a spreading unit, and an amplification unit in the wireless transmission device (TX) of FIG. 4 when the spreading factor of the orthogonal component of only transmission information is not changed at any time. It is a figure which shows the transmission power after being amplified.

FIG. 8 is a diagram showing a radio frame configuration in the case where both in-phase components and quadrature components always include transmission information.

FIG. 9 is a diagram showing a radio frame configuration in the case where only one component always includes transmission information.

FIG. 10 is a diagram showing a radio frame configuration and a transmission power (TX POWER) showing a conventional signal transmission method.

[Explanation of symbols]

1 Transmission information amount detector 2 control unit 3 Radio frame component 5 diffuser 6 amplification section 9 despreader 10 Level measurement section 11 Level comparison section 12 Selector 13 Demodulator

   ─────────────────────────────────────────────────── ─── Continued front page    (72) Inventor Kouji Ohno             2-11-1, Nagatacho, Chiyoda-ku, Tokyo Stock             Ceremony company NTT Docomo (72) Inventor Seizo Onoue             2-11-1, Nagatacho, Chiyoda-ku, Tokyo Stock             Ceremony company NTT Docomo F-term (reference) 5K022 EE02 EE14 EE21 EE35                 5K060 CC04 CC12 DD04 FF06 HH05                       HH06 LL01                 5K067 AA06 CC10 EE71 GG02 GG08                       HH21

Claims (8)

[Claims] 1. A CDMA mobile communication system for repeatedly transmitting a radio frame composed of a transmission signal including transmission information whose transmission information amount changes with time.
A wireless transmission device for spreading and transmitting the transmission signal using a spreading code, the transmission information amount detecting means for detecting the transmission information amount of the transmission information at any time in the input transmission signal, and detecting in a predetermined period. According to the transmitted information amount
Control means for calculating the number of spreading code chips for 1 bit of the wireless frame in the predetermined period and the transmission power of the wireless frame in the predetermined period; and a spreading code corresponding to the calculated number of chips of the spreading code. By using 1 of the radio frame in the predetermined period.
A wireless transmission device comprising: a spreading unit that spreads a bit; and a transmitting unit that transmits the wireless frame spread by the spreading unit with the calculated transmission power during the predetermined period. 2. The control means calculates such that, when the amount of transmission information detected during the predetermined period is large, the number of spreading code chips for one bit of the radio frame during the predetermined period is reduced. The wireless transmission device according to claim 1, wherein: 3. The control means calculates the transmission power of the radio frame in the predetermined period so as to be in inverse proportion to the number of chips of a spread code for 1 bit of the radio frame in the predetermined period. The wireless transmission device according to claim 1. 4. Radio reception in which a signal whose spread information amount changes with time is spread at a spread ratio selected according to the spread information amount from a plurality of preset spread ratios and is despread. A device, despreading means for despreading a received signal with a plurality of spreading factors, level measuring means for measuring the reception level of each of the signals despread with a plurality of spreading factors by the despreading means, A radio receiving apparatus comprising: a selection unit that compares a plurality of reception levels measured by the level measurement unit, selects a signal having the maximum reception level, and demodulates the selected signal. 5. In a CDMA mobile communication system for repeatedly transmitting a radio frame composed of a transmission signal containing transmission information whose transmission information amount changes with time, the transmission signal is spread and transmitted using a spreading code. A wireless transmission device, wherein the transmission information amount detecting means for detecting the transmission information amount of the transmission information at any time in the input transmission signal, and the transmission information amount detected in a predetermined period,
Control means for calculating the number of chips of a spread code for 1 bit of the radio frame in the predetermined period and transmission power of the radio frame in the predetermined period; Wireless frame composing means, modulating means for modulating the two series of wireless frames output from the wireless frame composing means with carrier waves of mutually orthogonal phases, and the calculated number of chips of the spreading code. Spreading means for spreading 1 bit of each of the two series of radio frames in the predetermined period using a spreading code; and 2 in the predetermined period spread by the spreading means with the calculated transmission power. And a transmitting means for transmitting each of the series of wireless frames. 6. A CDMA mobile communication system for repeatedly transmitting a radio frame composed of a transmission signal containing transmission information whose transmission information amount changes with time.
A wireless transmission method for spreading and transmitting the transmission signal using a spreading code, the step of detecting the transmission information amount of the transmission information at any time in the input transmission signal, and the transmission detected in a predetermined period. Depending on the amount of information,
A step of calculating the number of spreading code chips for 1 bit of the wireless frame in the predetermined period and the transmission power of the wireless frame in the predetermined period; and a spreading code corresponding to the calculated number of chips of the spreading code. Using one of the radio frames in the predetermined period
A radio transmission method comprising: a step of spreading a bit; and a step of transmitting the radio frame in the predetermined period spread by the spreading means with the calculated transmission power. 7. In a CDMA mobile communication system for repeatedly transmitting a radio frame composed of a transmission signal including transmission information whose transmission information amount changes with time, the transmission signal is spread and transmitted using a spreading code. A method of wireless transmission, the step of detecting the transmission information amount of the transmission information at any time in the input transmission signal, and according to the transmission information amount detected in a predetermined period,
Calculating the number of chips of the spread code for 1 bit of the radio frame in the predetermined period and the transmission power of the radio frame in the predetermined period; and outputting the transmission signal by dividing it into two series of radio frames. A step of modulating the two series of radio frames output from the radio frame constructing means with carrier waves of mutually orthogonal phases; and using a spreading code corresponding to the calculated number of chips of the spreading code. A step of spreading 1 bit of each of the two series of wireless frames in the predetermined period; and a step of spreading the one frame of each of the two series of wireless frames in the predetermined period with the calculated transmission power. And a step of transmitting each of them. 8. The transmission signal includes constant transmission information and the occasional transmission information, and a first radio frame of the two series of radio frames includes constant transmission information, and the first series of the two series of radio frames. The wireless transmission method according to claim 7, wherein a second wireless frame of the wireless frames does not include the constant transmission information.