WO2004019511A1 - Radio transmitter - Google Patents

Abstract

For the direct spectrum spread modulation, a radio transmitter comprises a mapping unit for performing spread modulation of a transmission data array by a spread symbol, a waveform shaping unit for shaping the waveform of the output of the mapping unit to limit the band, and a variable amplifier capable of amplifying the nature of the component regarding the output of the waveform shaping unit and varying the gain. The radio transmitter further comprises a control unit. Before the gain of the variable amplifier is modified, the control unit processes the output of the mapping unit so that the amplitude of the component regarding the output of the waveform shaping units on the analog wave becomes zero. after the gain of the variable amplifier is modified, the original output of the mapping unit is waveform-shaped by the waveform-shaping unit.

Description

 Description Wireless transmitter Technical field

 The present invention relates to a wireless transmission device of a mobile communication system using CDMA and the like. Background art

 FIG. 9 is a block diagram showing a baseband modulation device in a portable handset wireless transmission device in a CDMA mobile communication system according to the prior art. In the figure, 1 is a mapping unit, 18 to 21 are waveform shaping units, 7 to 10 are gain multipliers, and 11 and 12 are adders.

In this prior art, for example, in order to transmit audio and moving images in multiple directions, the mapping unit 1 has a plurality of spreading units 1 _CH1 and 1 _CH2 . The spreading section 1 _CH1 is supplied with, for example, an audio data string _CH1 , and the spreading section 1 _CH2 is supplied with, for example, a moving picture data string CH2. Spreading section 1 _CH1 performs QPSK modulation using spreading code C 0 de 1 on data stream CH 1 and spreads, and spreading section 1 _CH2 performs QP SK modulation using spreading code Code 2 on data stream CH 2. To spread. Therefore, each of spreading sections 1 _CH1 and 1 _CH2 can handle 2-bit information per symbol time, and data strings CH 1 and CH 2 spread by QP SK modulation are I Component (in-phase component) and Q component (quadrature component) '. The I and Q components obtained by decomposing the data string CH 1 by the diffusing unit 1 _CH1 are I _CH1 and Q _CH1, and the I and Q components obtained by decomposing the data string CH 2 by the diffusing unit 1 _CH2 are I _CH2 , Q _CH2 . The components I CHI, Qcm, I GH2, and Q _CH2 of the decomposition result are each 1 symbol per symbol time. It is a line of de night.

The spreading codes C ode 1 and C ode 2 used by the spreading units 1 _CH1 and 1 CH2 are signals which change at a period equal to or shorter than that of the evening CH 1 and CH 2, and the spreading units 1 _CH1 and 1 _CH2 As a result, the spectra of the data trains CH 1 and CH 2 are diffused. The data CH I and CH 2 before spreading are signals that change in symbol units, but the components after spreading I CH1 W CH1 CH2 W CH2 change in chip units determined by the speed of the spreading code. Signal.

The component I _CH1 spread by the spreading section 1 _CH1 is input to the waveform shaping section 18 and the component Q _CH1 is input to the waveform shaping section 20. The component I _CH2 spread by the spreading unit 1 _CH2 is input to the waveform shaping unit 19, and the component Q _CH2 is input to the waveform shaping unit ₂₁ . These waveform shaping sections 18 to 21 are Nyquist filters, and when the data stream is converted from digital to analog, the components I _CH1 and I _CH1 are used to have an appropriate band-limited waveform. Process I _CH2 , Q CHI, Q _CH2 and output the components I ' _CH1 , I, _CH2 , Q, _CH Q, _CH2 respectively. The components I _CH1 , I _CH2 , Q cHi, and Q _CH2 before waveform shaping are 1-bit data sequences per time, whereas the waveform shaping section 18

2 Components after waveform shaping by 1 I 'CHI -L CH2 y GH1 ^ CH2 each have multiple bits (for example, 8 bits) per time, corresponding to the required amplitude accuracy, and change every moment. It is a data string.

The components I, _CH1 , G, _CH2 , Q'CHI, Q, and _CH2 output by the waveform shaping units 18 to ₂₁ are _gain- gained in order to provide an amplitude difference between channels (for example, audio and video). Input to multipliers 7-10. Component this prior art, the components I, _CH1, Q ⁵ _CH1 associated with the data string CH 1, while the gain multiplier 7, 9 are multiplied by the gain /? _D, associated with Isseki de column CH 2 I _,, Q ⁵ _Gain multipliers 8 and 10 are gain /? On _CH2. Multiply by These gains? _D ,?. Is variable. In addition, gain multiplier 7, 8-phase component /? _D · I _'CH1 you and ^ · I' _CH2 output from are added by an adder 1, output from the gain multiplier 9, 1 0 The quadrature component /? _D · Q ⁵ _CH1 and; 5 · Q ' _CH2 are added by the adder 12.

These added data strings are converted into analog signals by a digital-to-analog converter (D / A converter) (not shown), and the in-phase channel and quadrature are expressed by the following equations (1) and (2). Output of each band baseband modulator (baseband signal) I _md , Q _m . _d is obtained.

^{mod = 6 d · CH1 + 5} c · I CH2,丄)

Q mod ⁼ d * Q CHI ⁺ ? C "Q GH2 V

 The D / A converter is connected to a transmitter (not shown), and the transmitter performs radio frequency modulation and power amplification on the in-phase channel and the quadrature channel and the baseband signal, and then transmits the signals.

 In the wireless transmission device of the conventional CDMA mobile communication system configured as described above, the waveform shaping unit can adjust the amplitude ratio of each channel appropriately by multiplying the gain by one time. Since it is only necessary to be able to accept a 1-bit input, a waveform shaping unit having a simple configuration can be used, which is effective in reducing the circuit size of the wireless transmission device.

FIG. 11 shows a radio transmitting apparatus in a CDMA mobile communication system according to another related art. This radio transmitting apparatus is used in a CDMA mobile communication system requiring transmission power control that changes transmission power as needed. In the figure, 29 is a mapping section, 3 and 5 are waveform shaping sections, 2 22 3 is a digital-to-analog converter, 24 is a radio frequency modulator, 25 is a second selection section, and 26 is a first power supply. An amplifier, 27 indicates a second power amplifier, and 28 indicates a first selector. The moving section 29 has a diffusion section 29a, and the diffusion section 29a is supplied with the data CH1. Spreading section 29a spreads data sequence CH1 by performing QPSK modulation using spreading code Code1. Therefore, spreading section 29a can handle 2-bit information per symbol time, and the data sequence CH 1 spread by QPSK modulation is divided into I component I _CH1 and Q component Q _CH1 . Decomposed. The components I _CH1 and Q _CH1 of the decomposition result are each a 1-bit data sequence per symbol time.

The component I _CH1 and the component Q _CH1 are input to the waveform shaping units 3 and 5, respectively. These waveform shaping units 3 and 5 are composed of, for example, a root Nyquist filter, and when the data sequence is converted from digital to analog, a waveform is limited so as to have an appropriate band-limited waveform. Process the components I _CH1 and Q _CH1 and output the components I ' _CH1 and Q' CH! Respectively. Components before waveform shaping _ICH1 , Q

_{While CH1} is a sequence of 1 bit per symbol time each time, the components I ⁵ _CH1 and Q ⁵ oHi after the waveform shaping processing by the waveform shaping units 3 and 5 are necessary. It has multi-bits (for example, 8 bits) per time corresponding to the amplitude accuracy, and is a data sequence that changes every moment.

 The waveforms of the in-phase channel and the quadrature channel whose waveforms are shaped are converted into analog waveforms by digital analog converters 22 and 23, and the radio frequency modulator 24 modulates the radio frequency.

The output of the radio frequency modulator 24 is supplied to a second selector 25. The first selection unit and the second selection unit select such that the output of the radio frequency modulator 24 is power-amplified by either the first power amplifier 26 or the second power amplifier 27. The first power amplifier 26 and the second power amplifier 27 are variable power amplifiers. The first power amplifier 26 is a high-amplification power amplifier capable of outputting the maximum power required in the system, while the second power amplifier 27 cannot output the maximum power. , Working In this case, the power that needs to be supplied is smaller than that of the first power amplifier 26.

 The first power amplifier 26 and the second power amplifier 27 are selectively used depending on the power value output by the wireless transmission device. The power value that determines which power amplifier is used is set as a threshold, and if the output power value is greater than the threshold, the first selection unit 28 and the second selection unit 25 Select and use the first power amplifier 26. If the output power value is smaller than the threshold value, the first selector 28 and the second selector 25 select and use the second power amplifier 27, and Cut off the power supply.

 In this prior art, by operating as described above, if the maximum power that can be transmitted is satisfied by the first power amplifier 26 and power smaller than the threshold is required, Since the second power amplifier 27 with low power can be used, a wireless transmission device with lower power consumption can be provided.

 Since the conventional wireless transmission device is configured as described above, it is possible to change the gain for amplifying the amplitude or power during transmission, but the signal transmitted immediately after changing the gain There were issues such as instability.

For example, in the prior art transmitting apparatus shown in FIG. 9, it may be necessary to change the gain of the gain multipliers 7 to 10 during transmission. FIG. 10 shows the output power of each component when the gain /? _D is changed in the prior art of FIG. As shown in the first 0 Figure, the gain b down 5 _d associated with Isseki de column CH 1, Kara ^ _{d2,? D3,} when switched stepwise to? _D4, multipliers 7, 9 The output changes, and the outputs of the adders 11 and 12 and thus the output power of the baseband modulator also change stepwise. Related to data string CH 2 Gay /? The same applies to the case where is changed.

However, usually, the output signals of the waveform shaping section (components _I'CH1 , _Q'CHI ,

I ⁵ _CH2, Q, _CH2) is a superposition of impulse response of the waveform shaping unit at each sample point has the transient response characteristics. Therefore, gain /? _D or gain /? During the impulse response. If is changed with a large step, the waveform of the transient response multiplied by the multiplier will be distorted, and the band of the transmitted signal will be widened. In this case, there arise problems such as an increase in leakage power to adjacent frequencies.

 Further, in the transmitting apparatus of the prior art shown in FIG. 11, when the power to be transmitted passes a threshold value, switching from the first power amplifier 26 to the second power amplifier 27 or the second power amplifier 27 is performed. Switching from the power amplifier 27 to the first power amplifier 26 is performed, but before and after the switching, a discontinuous point occurs in the output signal of the transmission device, and the band of the signal to be transmitted is widened. Also in this case, problems such as an increase in leakage power for adjacent frequencies occur.

 SUMMARY OF THE INVENTION The present invention has been made to solve the above-described problem. Even if a gain for amplifying a property such as amplitude or power is changed during data transmission, an output transmitted immediately after the change is obtained. It is an object of the present invention to obtain a wireless transmission device capable of suppressing the spread of signal bands. Disclosure of the invention

According to the present invention, there is provided a radio transmission apparatus comprising: a muting unit for spreading and modulating a transmission data sequence by a spreading code for direct spectrum spreading modulation; and a waveform shaping of an output of the muting unit for band limitation. It has a waveform shaping unit and a variable amplifier that can amplify the nature of the component related to the output of the waveform shaping unit and has a variable gain. Further, the wireless transmission device includes a control unit. Before changing the gain of the variable amplifier, process the output of the muving section so that the amplitude of the component related to the output of the waveform shaping section on the analog wave is nullified.After changing the gain of the variable amplifier, The original output of the section is shaped by the waveform shaping section.

 As a result, the amplitude of the component related to the output of the waveform shaping unit on the analog wave can be nullified before and after the gain change of the variable amplifier. In other words, the gain of the variable amplifier can be changed while avoiding the transient response of the output of the waveform shaping unit. Therefore, it is possible to suppress the spread of the band of the output signal transmitted immediately after the gain change. BRIEF DESCRIPTION OF THE FIGURES

 FIG. 1 is a block diagram showing a configuration of a wireless transmission device of a portable handset in a CDMA mobile communication system according to Embodiment 1 of the present invention.

 FIG. 2 is a timing chart showing the output of each component of the wireless transmission device shown in FIG. FIG. 3 is a timing chart showing an output of each component of the wireless transmission device according to an alternative form of the first embodiment.

 FIG. 4 is a timing chart showing details of gating by the gate unit of the wireless transmission device shown in FIG.

 FIG. 5 is a timing chart showing the relationship between the output of the waveform shaping unit of the wireless transmission device shown in FIG. 1 and the timing of switching the gain of the gain multiplier.

FIG. 6 is a block diagram showing a configuration of a wireless transmission device of a portable handset in a CDMA mobile communication system according to Embodiment 2 of the present invention. FIG. 7 is a block diagram showing a configuration of a wireless transmission device of a portable handset in a CDMA mobile communication system according to Embodiment 3 of the present invention.

 FIG. 8 is a timing chart showing the output of each component of the wireless transmission device shown in FIG. ·

 FIG. 9 is a block diagram showing a baseband modulation device in a portable handset wireless transmission device in a CDMA mobile communication system according to the related art.

 FIG. 10 is a timing chart showing the output of each component of the wireless transmission device shown in FIG.

 FIG. 11 is a block diagram showing a wireless handset wireless transmission device in a CDMA mobile communication system according to another related art. BEST MODE FOR CARRYING OUT THE INVENTION

 Hereinafter, in order to explain this invention in greater detail, the preferred embodiments of the present invention will be described with reference to the accompanying drawings.

Embodiment 1

 FIG. 1 shows a configuration of a wireless transmission device of a portable handset in a CDMA mobile communication system according to Embodiment 1 of the present invention. This configuration may be applied to the base station of the same system. In the figure, 1 is a mapping section, 2 is a gate section, 3 to 6 are waveform shaping sections, 7 to 10 are gain multipliers (variable amplifiers), 11 and 12 are adders, and 13 is control signal generation. , 31 indicates a gain control unit.

For example, in order to transmit audio and video in multiple directions, the matching unit 1 has a plurality of spreading units 1 _CH1 and 1. For example, an audio data stream CH 1 is supplied to the spreading section 1 _CH1, and a moving picture data stream CH 2 is sent to the spreading section 1 _CH2 , for example. Supplied. The data sequence CH 1, C 2 is a data sequence of one bit per symbol time.

For direct spectrum spreading modulation, spreading section 1 _CH1 performs QP SK modulation using spreading code C 0 de 1 on data stream CH 1 and spreads, and spreading section 1 _CH2 generates spreading code C code. QPSK modulation using 2 is performed on the data sequence CH 2 and spread. Therefore, each of the spreading sections 1 _CH1 and 1 _CH2 can handle 2-bit information per symbol time, and the data strings CH 1 and CH 2 spread by QP SK modulation are I Decomposed into components and Q components. The I and Q components are each a sequence of 1 bit per symbol time. .

The spreading units 1 _CH1 and 1 _CH2 convert the levels of the I component and Q component to obtain a data sequence of 1 bit per symbol time represented by +1 and 1 1 . The I component and the Q component obtained by processing the data string CH 1 as described above by the spreading unit 1 _CH1 are I _CH1 and Q _CH1 , and the I component obtained by processing the data string CH 2 by the spreading unit 1 _CH2 as described above. The Q components are I _CH2 and Q _CH2 . In this way, the components I _CH , QCHI, I _CH2 , and Q _CH2 , each of which is one bit (+1 or 11) per symbol time, are obtained.

The spreading codes C ode 1 and C ode 2 used by the spreading units 1 _{CH 1} and 1 are signals that change at a period equal to or shorter than that of the de-consecutive sequences CH I and CH 2 and are applied to the spreading units 1 _{CH 1} and 1 _{CH 2} . Thus, the spectra of the data strings CH 1 and CH 2 are spread. The data CH 1 and CH 2 before spreading are signals that change in symbol units, but the components I _CH1 , QCHI, I _CH2 , and Q _CH2 after spreading are in chip units determined by the speed of the spreading code. Is a signal that changes.

The gate section 2 has gating circuits 2a to 2d. Spreader ₁ Component I output from _CH1 I _CH1 is input to gating circuit 2a, and component Q _CH1 is input to the gating circuit 2c. The component I _CH2 output from the diffusion unit 1 _CH2 is input to the gating circuit 2b, and the component Q _CH2 is input to the gating circuit 2d.

The gating circuits 2 a and 2 c (related to the data train CH I) of the gate unit 2 process the components I _CH1 and QCHI according to the control signal GS i generated by the control signal generator 13. On the other hand, the gating circuits 2 b and 2 d (related to the data train CH 2) process the components I _CH2 and Q _{CH2 according} to the control signal GS ₂ generated by the control signal generator 13. More specifically, the gating circuits 2 a to 2 d use the components I _CH1 , I _CH2 , Q _CH1 , or Q _CH2 as their input values when the corresponding control signal GS or GS ₂ is at a high level. Regardless, it is output as “0”. Otherwise, the gating circuits 2a-2d pass the component I _CH1 , I _CH2 , Q CHI, or Q _CH2 at the value as entered.

In this way, the gating circuits 2a to 2d convert the binary (+1, 11) components I _CH1 , I _CH2 , Q _CH1 , and Q _CH2 into three values (+1, 0, -1). Convert to “0” output from the gating circuits 2 a to 2 d is used as non-amplitude information. For example, when the component I _CH1 is “0”, the subsequent processing is performed so that the amplitude of the I component of the data string CH 1 becomes zero on the analog wave.

The control signal generator 13 receives the trigger for switching the variable gain /? _D used in the gain multipliers 7 and 9 described later, and outputs a high-level control signal to the gating circuit 2. a, 2 c. The control signal generator 13 is a variable gain /? Used in the gain multipliers 8 and 10. The When Switching Operation Order trigger is input, and supplies a control signal GS ₂ at a high level to the gated ring circuit 2 b, 2 d. Such a trigger is generated by the gain control unit 31. Thus, the gain control unit 31 and the control signal generation unit 1 3, and the gate unit 2 constitute a control unit that appropriately times the output of the mapping unit 1.

The component I _CH1 after the gating in the gating circuit 2a is input to the waveform shaping unit 3, and the component Q _CH1 after the gating in the gating circuit 2c is input to the waveform shaping unit 5. Is entered. The component I _CH2 after the gating in the gating circuit 2 b is input to the waveform shaping unit 4, and the component Q _CH2 after the gating in the gating circuit 2 d is the waveform shaping unit 5. Is input to These waveform shaping units 3 to 6 are composed of, for example, a root Nyquist filter. When the data sequence is converted from digital to analog, the component I is adjusted so that it has an appropriate band-limited waveform. _CH have to process the _{I CH2, Q CH1, Q CH2} , component _{I, CH1, I, CH2,} Q 'CHI, the Q ⁵ _CH2 it to its output.

In the conventional technique shown in FIG. 9, the waveform shaping units 18 to 21 accept a one-bit data stream per time, but the waveform shaping units 3 to 6 in this embodiment use two bits per time. Accept the de-que Before the waveform shaping process The components I _{CH and} I _CH2 , Q _CH1 , and Q _CH2 are each a 2-bit data stream per time, but after the waveform shaping process by the waveform shaping units 3 to 6 component _{I, CHI, I, CH2,} Q 'CHI, Q' CH2 it it, corresponding to the amplitude accuracy required, have one time per multibit preparative (e.g. 8 bits), the data that changes from moment to moment in Column.

Component _{I, CH1, I, CH2,} Q 5 CH1, Q 3 CH2 output the waveform shaping unit 3-6 in order to provide the amplitude difference of the channel phase 5 (e.g., voice and moving images), it it gain multiplier 7 to 10 are input. In this embodiment, the components I ′ _CH1 , Q, and _CH1 related to the data sequence CH 1 are multiplied by the gain multipliers 7 and 9 by the gain /? _D , while the components related to the data sequence CH 2 are multiplied. Components I, CH2, Q 'Gain multipliers 8, 10 are gain ^ for _CH2 . Multiply by These gays, β β?. Is variable and is controlled by the gain control unit 31. Also, the common mode components /? _D 'I ⁵ _CH1 and /? Output from the gain multipliers 7 and 8. · _I'CH2 is added by the adder 11 and the quadrature component /? _D output from the gain multipliers 9 and 10 _d · _Q'CH1 and. · Q and _CH2 are added by adder 12.

These added data strings are converted into analog signals by a digital-to-analog converter (D / A converter) (not shown), and an in-phase channel represented by the following equations (1) and (2) is used. and quadrature channels it its base - the output of Subang de modulator (baseband signal) I _{m. d} , Q _m . _d is obtained.

I mod ⁼ 6 d 'I CHI ⁺ o "I CH2,

Q mod ⁼ 5 d "Q CHI + ^cW CH2 ( ^ώ /

 The D / A converter is connected to a transmitter (not shown), and the transmitter applies radio frequency modulation and power amplification to the in-phase channel and the quadrature channel and the respective paceband signals, and then transmits the signals.

 Next, the operation will be described. In the following description of the operation, the evening timing chart in FIG. 2 will be referred to.

As shown in FIG. 2, symbol Isseki de column CH 1 at a predetermined interval, transitions from S _n-1, S _n, to S _{n +} have S _{n + 2.} When the CH1 changes from the symbol S _n to the symbol S _{n + 1} , the gain? It is assumed that a trigger for switching the mode is input to the control signal generator 13.

The control signal generator 13 generates a control signal G Si of a required length according to the trigger. That is, the control signal GS is supplied to the gating circuits 2 a and 2 c of the gate unit 2 so that some chips of the symbol _{Sn + 1} are set to “0”. According to the control signal G Si, the gating circuits 2 a and 2 c set the components I _{CH and} Q _CH1 of the required number of chips to “0”. Therefore, the waveform shaping units 3 and 5, which shape the components I _CH1 and Q _CH1 after gating, temporarily Amplitude output component I _'CH1, Q ⁵ _CH1 becomes "0".

Gain /? _D to switch is controlled by the signal GS i is high, the period the amplitude of the component I _'CH1, Q' _CH1 is "0" is changed from? _Dn /? To _{dn + 1.} Therefore, the multiplication results of the gain multipliers 7 and 8, /? _D ? _I'CH1 and /? _D · _Q'CH1 , change as shown.

After changing the gain /? _D, the control signal G Si is at a low level, the output of the waveform shaping section 3, 5 (component I _'CH have Q' _CH1) is resumed. Waveform immediately after resumption, because it is very bandwidth limited by the waveform shaping section 3, 5, gain /? _D is multiplied result of the component /? _D · I ⁵ _CH1 and 5 _d · Q, waveform CHI No distortion occurs. As described above, the gain can be switched without causing distortion in the output waveform. The switching of gain ^ _d has been described above, but the situation is the same in gain ^.

In this embodiment, even if the waveform shaping units 3 to 6 perform waveform shaping with a general finite-length impulse response, the gating circuit 2a to 2d starts gating (no The time from the regulation of the amplitude) to the end of the last impulse response can be known, for example, by experiment or simulation. Therefore, after the impulse response, gain _d , 3. It is very easy to set the operation timing of the gain control unit 31 so as to switch the operation. As described above, the period of the control signal GSGS ₂ is a high level, gain ^ _d,. This switching is preferably performed after the predicted end time of the last impulse response.

In this embodiment, as shown in FIG. 2, when the data row CH 1 is changed from the symbol s _n in the symbol s _{n + 1,} Bi beta _a to toggle its trigger control signal generating unit 1 3 The control signal generation unit 13 which is input generates a control signal G Si of a required length. Therefore, the symbol S _{n + 1} The amplitude of some leading chips is set to zero. However, as in the alternative form shown in FIG. 3, before the sequence CH 1 changes from the symbol S _{n to the} symbol S _{n + 1} , the trigger that switches between gay and no β _c is controlled by the control signal. The control signal generator 13 may be input to the generator 13 and generate a control signal GS i of a required length. In this case, the amplitude of the portion of the chip at the end of the symbol S _n is made zero. Furthermore, the amplitude of each part beginning of the part and the symbol S _{n + 1} at the end of the symbol S _n so as to ◦, control signal GS! May be generated.

FIG. 4 shows the details of the gating by the gate unit 2. As shown in Figure 4, I _{CH 1} which is spread-modulated by the spreading section 1 _{CH 1} of Mabbingu unit 1 varies Chi Uz flop cycle. During the period when the control signal GS is at the high level, the gating circuit 2a of the gate unit 2 outputs the chip as `` 0 '' so that there is no amplitude, and otherwise, the value of the chip remains as it is input. Let it pass. Thus, in this embodiment, since a part of the symbol is deleted, the autocorrelation of the entire symbol is degraded. However, if the number of chips in the entire symbol is sufficiently large with respect to the number of deleted chips, the autocorrelation value becomes sufficiently large, and the receiving apparatus can correctly estimate the transmitted data sequence. Also, as shown in FIG. 4, in this embodiment, the gating period (the period when the control signal GS is at a high level) is a 6-chip period. It may be changed appropriately according to the length of the impulse response which is a finite length.

In Figure 5 the method of the second view of this embodiment is the Thailand Mi ring chart showing output of the waveform shaping section 3 (component E, CHI) and the gain /? Switch tie Mi ranging relationship _d . As shown, after the gain /? _D change, the control signal

GS i becomes low level, and the output (component I, _CH1 ) of waveform shaping section 3 is restarted. Waveform shaping with finite length impulse response as shown Since the output of the waveform shaping unit 3 does not have a waveform after the impulse response of the last chip due to the regulation of no amplitude, the timing for changing the gain /? _D can be easily determined. it can.

As described above, according to the first embodiment, the gains 5 _d ,? Of the gain multipliers 7 to 10 are variable amplifiers whose gains? _D ,? _E are variable. Of before the change, by the this to the gate unit 2 a control signal generating unit 1 3 is the control signal GS ₁₅ GS _2, the gate unit 2 on the component analog wave related to the output of the waveform shaping section 3-6 The output of the matting unit 1 is processed so that the amplitude of the signal becomes zero. Also, gate fin? ₍₁ gain multiplier 7-1 0, after the change of the beta _c, by the supply of the control signal generating unit 1 3 to the gate section 2 of the control signal GS _l3 GS ₂ and halting The gate unit 2 is configured to operate so that the original output of the mapping unit 1 is supplied to the waveform shaping units 3 to 6.

Therefore, during the period before and after the change of the gain β of the gain multipliers 7 to 10, the amplitude of the components related to the outputs of the waveform shaping units 3 to 6 on the analog wave can be eliminated. In other words, to avoid the transient response of the output of the waveform shaping section 3-6, gain /? _D of the gain multiplier 7 to 1 0,?. Can be changed. Thus, the waveform distortion is suppressed, and the spread of the band of the output signal transmitted immediately after the gain change can be suppressed.

 The control unit that performs such a gating control operation includes a gain control unit 31, a control signal generation unit 13, and a gate unit 2. The control unit for gating control has a simple structure, and it is possible to avoid increasing the size of the device. Embodiment 2.

FIG. 6 shows a configuration of a wireless handset wireless transmitting apparatus in a CDMA mobile communication system according to Embodiment 2 of the present invention. This configuration , May be applied to the base station of the same system. In the figure, 1 is a mapping section, 14 to 17 are waveform shaping sections, 7 to: L0 is a gain multiplier (variable amplifier), 11 and 12 are adders, 13 is a control signal generator, 3 1 indicates a gain control unit.

 For example, in order to transmit audio and video in multiple ways, the mapping unit 1 has a plurality of spreading units 1 GH1 1 CH2. Details of diffusion unit 1 CH1 1 CH2

Same as 1 and its description is omitted.

The component I _CH1 output from the spreading section 1 _CH1 is input to the waveform shaping section 14, and the component Q _CH1 is input to the waveform shaping section 16. The component I _CH2 output from the spreading section 1 _CH2 is input to the waveform shaping section 15 and the component Q _CH2 is input to the waveform shaping section 17. These waveform shaping units 14 to 17 are composed of, for example, a root-next-fill filter. When a data string is subjected to digital-analog conversion, components are formed so as to have an appropriate band-limited waveform. Process I CH1 1 CH2 Q cHi, Q _CH2 to obtain component I 'CH1 ^x CH2 ^ ¾ CH1

, Output Q ⁵ CH2 each time. Therefore, the waveform shaping units 14 to 17 have functions equivalent to those of the waveform shaping units 3 to 6 of the first embodiment.

Further, the waveform shaping units 14 to 17 of this embodiment have an input signal deleting function. The waveform shaping sections 14 and 16 (related to the data string _CH1 ) process the components I _CH1 and QCHI according to the control signal G generated by the control signal generating section 13. On the other hand, the waveform shaping units 15 and 17 (related to the data train CH 2) process the components I _CH2 and QCH ₂ according to the control signal GS ₂ generated by the control signal generating unit 13. More specifically, when the corresponding control signal G Si or GS ₂ is at a high level, the waveform shaping units 14 to 17 determine the components I cm, I _CH2 , QCHI, or Q _CH2 that are actually input. _{Regardless of the} value (+1 or 1 1), the value of the component I _CH1 , I _GH23 QCHI, or Q _CH2 is regarded as 0, and the amplitude of the component of the corresponding data column on the analog wave is zero. So that Min _{I 'cm, I' CH2,} Q 'CHI, and outputs a Q ⁵ _CH2. Otherwise, the waveform shaping unit 1. 4 to: L 7, the components I _CH1 input, I _CH2, QCHI, was or based on the value of Q _CH2 (+ 1 Matawa 1), component I ' _CH I, _CH2 ,

Outputs Q'CHI, Q'CH2.

In short, the waveform shaping units 14 to 17 in the present embodiment use the corresponding control signal GS! Or when GS ₂ is at high level, except having a function to regard the value of the input signal as "0", having an equivalent waveform shaping function and the waveform shaping section 3-6 of the first embodiment. From another viewpoint, such waveform shaping units 14 to 17 have the functions of the gate unit 2 and the waveform shaping units 3 to 6 of the first embodiment. Therefore, the waveform shaping units 14 to 17 output components I cm, d CH2, and Q CHI Q CH2 equivalent to those in the first embodiment.

Operations after the waveform shaping units 14 to 17 are almost the same as those in the first embodiment. Control signal generating unit 1 3, when the gain multiplier 7, a variable used in 9 gain? Preparative switching the _d trigger is supplied from the gain control unit 3 1, the control signal GS _X of Nono I levels Supplied to waveform shaping units 14 and 16. Further, the control signal generator 13 includes a variable gain used in the gain multipliers 8 and 10. When the switch trigger is supplied from the gain control unit 3 1, supplies a control signal GS ₂ at a high level to the waveform shaping unit 1 5, 1 7. As described above, the gain control unit 31, the control signal generation unit 13, and the waveform shaping units 14 to 17 constitute a control unit that appropriately times the output of the matching unit 1.

As described above, according to the second embodiment, the gain /? _D , 3. Is a variable amplifier whose variable is the gain of 7-10 gain /? _D ,?. Before the change, the control signal generator 13 supplies the control signal GS or GS ₂ to the waveform shaping units 14 to 17, so that the waveform shaping units 14 to 17 can change the waveform shaping units 14 to 17. The component related to its own output is adjusted so that the amplitude on the analog wave is null. Process the output of the subbing unit 1. Also, the gain β of the gain multiplier 7 to 10. After the change, the control signal generating unit 1 3 is the control signal GS _{1 3} GS by stopping the supply to the waveform shaping section 1 4 to 1 7 _2, original output waveform shaping unit 1 4 mapping unit 1 The waveform shaping sections 14 to 17 themselves are configured to operate so that the waveforms are shaped to 117.

Therefore, the gain of the gain multipliers 7 to 10 /? _D , 5. During the period before and after the change, the amplitude of the components related to the outputs of the waveform shaping units 14 to 17 on the analog wave can be nullified. In other words, the waveform shaping sections 14 to 17 avoid the transient response of the output of their own, and gains 5 _d and ^ of the gain multipliers 7 to 10. Can be changed. Therefore, waveform distortion is suppressed, and the spread of the band of the output signal transmitted immediately after the gain change can be suppressed.

 A control unit that performs such a gating control operation includes a gain control unit 31, a control signal generation unit 13, and waveform shaping units 14 to 17. The control unit for gating control has a simple structure, and it is possible to avoid increasing the size of the device. Further, since the waveform shaping sections 14 to 17 have a gating function, there is no need to provide a gate section 2 (see FIG. 1) dedicated to gating.

 In Embodiments 1 and 2 described above, the multi-channel data sequence CHI, CH2 is transmitted for multimedia transmission. However, Embodiments 1 and 2 may be modified for single channel transmission, and such modified forms are also within the scope of the present invention. Embodiment 3.

FIG. 7 shows a configuration of a wireless transmission device of a portable handset in a CDMA mobile communication system according to Embodiment 3 of the present invention. This configuration may be applied to the base station of the same system. This wireless transmitter transmits It is used in CDMA mobile communication systems that require transmission power control to change power as needed. In the figure, 29 is a mapping section, 30 is a gate section, 3 is a waveform shaping section, 5 is a waveform shaping section, 22 and 23 are digital-to-analog converters, 24 is a radio frequency modulator, 2 Reference numeral 5 denotes a second selection unit, 26 denotes a first power amplifier, 27 denotes a second power amplifier, 28 denotes a first selection unit, and 33 denotes a power determination unit.

 The mapping section 29 has a diffusion section 29a, and the diffusion section 29a is supplied with the data train CH1. For direct spectrum spread modulation, spreading section 29a spreads data sequence CH1 by performing QPSK modulation using spreading code Codel. Therefore, the spreading section 29a can handle 2 bits of information per symbol time, and the data sequence CH1 spread by QPSK modulation is decomposed into an I component and a Q component. . Each of the I and Q components is a sequence of 1 bit per symbol time.

The spreading section 29a converts the levels of the I component and the Q component to obtain a 1-bit data sequence per symbol time represented by +1 and 1-1. The I component and the Q component obtained by processing the data string CH 1 as described above by the diffusion unit ₂₉ a are I _CH1 and Q _CH1 . In this way, it it 1 Shimpo Le time per Ri 1 bit (+ 1 or - 1) component E _CH1, Q _CH1 de Isseki a column is obtained.

The spreading code Code 1 used by the spreading section 29a is a signal that changes with a period equal to or shorter than that of the data string CH1, and the spreading section 29a causes the spectrum of the data string CH1 to be changed. Spread. Also, the data CH 1 before spreading is a signal that changes in symbol units, but the components I _CH1 and Q _CH1 after spreading are signals that change in chip units determined by the speed of the spreading code.

The gate section 30 has gating circuits 2a and 2c. The component I _CH1 and component Q _CH1 output from the diffusion unit 2 9a are the gating circuits 2 respectively. Input to a, 2 c. The gating circuits 2 a and 2 c of the gate unit 30 process the components I _CH1 and Q CHI according to the control signal GS generated by the control signal generation unit 13. More specifically, when the control signal GS is at a high level, the gating circuits 2 a and 2 c output the components I _CH1 and Q _CH1 as “0” regardless of their input values. Otherwise, the gating circuit 2 a, 2 <3 is the component 1 _(¾1 , which passes Q _CH1 as input ο

In this way, the gating circuits 2a and 2c convert the binary (+1, 11) components I _CH1 and Q _CH1 into the ternary (+1, 0, -1). “0” output from the gating circuits 2 a and 2 c is used as non-amplitude information. For example, when the component I _CH1 is “0”, the subsequent processing is performed so that the amplitude of the I component of the data train CH 1 on the analog wave becomes zero. When a trigger for switching between a first power amplifier 26 and a second power amplifier 27, which will be described later, is input, the control signal generator 13 outputs a high-level control signal GS to the gating circuit 2a. , 2c. This trigger is supplied by the power determination unit 33.

The component I _CH1 after gating in the gating circuit 2a is input to the waveform shaping unit 3, and the component Q _CH1 after gating in the gating circuit 2c is input to the waveform shaping unit 5. You. These waveform shaping units 3 and 5 are composed of, for example, a root Nyquist filter, and when a data string is converted from digital to analog, components I cm, Q processing the _CH1, the components I _'CH1, Q ⁵ _CH1 it to its output. In the conventional technique shown in FIG. 11, the waveform shaping units 3 and 5 accept a one-bit data stream per time, but the waveform shaping units 3 and 5 in this embodiment have two bits per time. Accept the data string of the default. The components I _CH1 and Q _CH1 before the waveform shaping process are each a 2-bit data stream per time On the other hand, the components I ' _CH1 and Q ⁵ _CH1 after the waveform shaping processing by the waveform shaping units 3 and 5 each have multiple bits (for example, 8 bits) per time corresponding to the required amplitude accuracy. The in-phase channel and quadrature channel, each of which is a data sequence that changes every moment, are converted into analog waveforms by the digital-to-analog converters 22 and 23, and are converted into radio frequency modulators. Radio frequency modulation is performed at 24.

 The output of the radio frequency modulator 24 is supplied to a second selector 25. The first selector and the second selector select so that the output of the radio frequency modulator 24 is power-amplified by either the first power amplifier 26 or the second power amplifier 27. . The first power amplifier 26 is a power amplifier having a large amplification (gain) capable of outputting the maximum power required in the system, whereas the second power amplifier 27 has a small gain and a maximum gain. A power amplifier that cannot output power but has to supply less power for operation than the first power amplifier 26. As an alternative to the illustrated form, the second power amplifier 27 may be eliminated and the second selector 25 and the first selector 28 may be directly connected.

The first power amplifier 26 and the second power amplifier 27 are selectively used depending on the power value output by the wireless transmission device. The power value for determining which power amplifier to use is set as a threshold value in the power determination unit 33.If the power determination unit 33 determines that the output power value is greater than the threshold value, the first The selecting section 28 and the second selecting section 25 select and use the first power amplifier 26. If the power determination unit 33 determines that the output power value is smaller than the threshold, the first selection unit 28 and the second selection unit 25 select and use the second power amplifier 27, The power supplied to the first power amplifier 26 is cut off. Therefore, the second selector 25, the first selector 28, the first power amplifier 26 and the second power amplifier 27 can be considered as constituting one variable amplifier.

 Next, the operation will be described. In the following description of the operation, the evening timing chart in FIG. 8 will be referred to.

When the power value of the signal to be output exceeds the threshold value and it is necessary to switch between the first power amplifier 26 and the second power amplifier 27, the control signal generator 13 controls the required length. A signal GS is generated and supplied to the gating circuits 2a and 2c of the gate section 30. The gating circuits 2a and 2c follow the control signal GS, that is, perform the gating while the control signal GS is at a high level, and set the components I _CH1 and Q _CH1 for the required number of chips to “0”. To Therefore, the waveform shaping units 3 and 5 for shaping the components I _CH1 and Q _CH1 after the gating output the components I ′ CH1 ヽ W CH1 whose amplitude temporarily becomes “0”. In the control signal GS is at a high level, the amplitude of the component I, _CH1, Q ⁵ _CH1 within the period is "0", and operates the selection section 2 5, 2 8, switching the power amplifier 2 6, 2 7. After switching, the control signal G Si goes low, and the outputs (components I, _GH1 Q 'CHl) of the waveform shaping units 3 and 5 are restarted. Since the waveform immediately after the restart is extremely band-limited by the waveform shaping units 3 and 5, no waveform distortion occurs. Therefore, by switching the amplifier, even if the output of the first selection unit 28 and, consequently, the amplitude of the output of the transmitting device changes, the output of the transmitting device without any discontinuity can be obtained.

In this embodiment, even when the waveform shaping units 3 and 5 perform waveform shaping with a general finite-length impulse response, the gating by the gating circuits 2a and 2c is started (to zero amplitude). The time from the regulation to the end of the last impulse response can be known, for example, by experiment or simulation. Therefore, the selection units 28, 25 are switched so that the power amplifiers 26, 27 are switched after the impulse response is completed. It is very easy to set the operation timing of the. As described above, while the control signal GS is at the high level, the power amplifiers 26 and 27 are switched, and this switching is preferably performed after the predicted end time of the impulse response.

 As described above, according to the third embodiment, before changing the gain of the variable amplifier (switching between the power amplifiers 26 and 27), the control signal generating unit 13 applies the control signal GS to the gate unit 3. By supplying the signal to 0, the gate unit 30 processes the output of the mapping unit 29 so that the amplitude of the component related to the output of the waveform shaping units 3 and 5 on the analog wave becomes null. Further, after the gain of the variable amplifier is changed (switching of the power amplifiers 26 and 27), the control signal generator 13 stops supplying the control signal GS to the gate 30 so that the control signal generator GS is turned off. The gate section 30 is configured to operate so that the original output of the scaling section 29 is supplied to the waveform shaping sections 3 and 5.

 Therefore, during the period before and after the change of the gain of the variable amplifier (switching of the power amplifiers 26 and 27), the amplitude of the components related to the outputs of the waveform shaping units 3 and 5 on the analog wave can be eliminated. In other words, the gain of the variable amplifier can be changed (switching between the power amplifiers 26 and 27) while avoiding the transient response of the output of the waveform shaping units 3 and 5. Therefore, the discontinuity of the waveform is eliminated, and the spread of the band of the output signal transmitted immediately after the gain change can be suppressed. ,

 The control unit that performs such a gating control operation includes a power determination unit 33, a control signal generation unit 13, and a gate unit 30. The control unit for gating control has a simple structure, and it is possible to avoid increasing the size of the device.

Further, in the third embodiment, the gate unit 30 performs a gating operation. However, the gate section 30 can be eliminated by providing a waveform shaping section capable of performing waveform shaping and gating as in the second embodiment. It is possible.

 Although the present invention has been illustrated and described in detail with reference to the preferred embodiments, various modifications in form and detail are possible within the spirit and scope of the invention described in the claims. Some will be understood by those skilled in the art. Such alterations, substitutions, and amendments are also within the scope of the claims. Industrial applicability

 As described above, according to the wireless transmission apparatus of the present invention, even if the gain for amplifying the amplitude or power of the data string during transmission is changed, the output signal transmitted immediately after the change is changed. Band expansion can be suppressed.

Claims

The scope of the claims

1. A muting section for spreading and modulating a transmission data sequence with a spreading code for direct spectrum spreading modulation;

 A waveform shaping unit that shapes the waveform of the output of the mapping unit and limits the band, a variable amplifier that can amplify the property of a component related to the output of the waveform shaping unit, and that has a variable gain.

 Before changing the gain of the variable amplifier, processing the output of the mapping unit so that the amplitude of the component related to the output of the waveform shaping unit on the analog wave is nullified, and after changing the gain of the variable amplifier, A wireless transmission device comprising: a control unit that causes the waveform shaping unit to perform a waveform shaping on an original output of the matting unit.

2. The wireless transmission device according to claim 1, wherein the variable amplifier amplifies the amplitude of the output of the waveform shaping unit.

3. The wireless transmission device according to claim 1, wherein the variable amplifier amplifies the power for transmitting the analog wave processed by the output of the waveform shaping unit.

4. The control unit includes a gate unit to which an output of the mapping unit is supplied, and a control signal generation unit that controls the gate unit,

Before the gain of the variable amplifier is changed, the control signal generation unit supplies a control signal to the gate unit, so that the gate unit adjusts the amplitude of the component related to the output of the waveform shaping unit on the analog wave. Processing the output of the mapping section so that After the gain of the variable amplifier is changed, the control signal generating unit stops supplying the control signal to the gate unit, so that the actual output of the mapping unit is supplied to the waveform shaping unit. 2. The wireless transmission device according to claim 1, wherein the gate unit is configured to operate.

5. The control unit includes: a waveform shaping unit to which an output of the mapping unit is supplied; and a control signal generating unit that controls the waveform shaping unit.

 Before the gain of the variable amplifier is changed, the control signal generating unit supplies a control signal to the waveform shaping unit, so that the waveform shaping unit reduces the amplitude of the component related to the output of the waveform shaping unit on the analog wave. Process the output of the mubbing section so that

 After the gain of the variable amplifier is changed, the control signal generation unit stops supplying the control signal to the waveform shaping unit, so that the original output of the matching unit is shaped by the waveform shaping unit. The wireless transmission device according to claim 1, wherein the waveform shaping section is configured to operate.