JPH10304000A - Quadrature amplitude modulating device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a frequency variable type quadrature amplitude modulation(QAM) device which can perform high-precision QAM as compared with conventional techniques and is simple in circuit constitution and low in manufacture cost. SOLUTION: A digital arithmetic control circuit 10 processes amplitude data and phase data for quadrature amplitude modulation according to two series of digital signals. Then D/A(digital-to-analog) converters 12 and 11 convert the amplitude data and phase data into an amplitude analog signal and a phase analog signal respectively and output them. A phase modulator 2 imposes phase modulation on the reference signal outputted from a reference signal generator 1 according to the phase analog signal from the D/A converter 11 and outputs the phase-modulated signal, and a multiplier 3 imposes amplitude modulation by multiplying the phase-modulated signal from the phase modulator 2 by the amplitude analog signal from the D/A converter 12 and outputs the modulated signal as a QAM signal.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

[0001] 1. Field of the Invention [0002] The present invention relates to a quadrature amplitude modulation (hereinafter, referred to as QAM) modulator.

[0002]

2. Description of the Related Art In recent mobile communication systems,
For modulation of voice signals and data signals, QAM capable of high-speed and large-capacity transmission is often used, and a configuration of a conventional quadrature amplitude modulator is shown in FIG.

In FIG. 3, a carrier signal of a radio frequency generated by a carrier signal generator 50 is in-phase distributed by an in-phase distributor 51, and one of the divided carrier signals is divided into two series by a multiplier 52. The digital signal is multiplied by the I signal, and the resulting signal is added to the adder 55.
Is output to Also, the other distributed carrier signal is
After being phase-shifted by 90 ° by the 90 ° phase shifter 53, the carrier signal after the phase shift is multiplied by the Q signal of the two-sequence digital signal by the multiplier 54, and the multiplied signal is added to the adder 55. Is output to Here, the two signals input to the adder 55 are orthogonal to each other, and the adder 55 adds the two input signals and outputs a signal of the addition result as Q
Output as an AM signal.

[0004]

The performance of the prior art quadrature amplitude modulator constructed as described above is determined by the multiplier 52,
54, a feedthrough indicating an offset value from the output value 0 when the magnitude of each of the I signal and the Q signal is 0, for example, and a phase shift accuracy of the 90 ° phase shifter 53. Is done. therefore,
In the case of the variable carrier frequency type, there is a problem that the modulation accuracy in the conventional quadrature amplitude modulator is relatively low.

Therefore, when the carrier frequency is made variable, a technique of changing the carrier frequency by changing the local oscillation frequency in the heterodyne system after QAM is performed at a predetermined carrier frequency is conventionally used. I have. However, there is a problem that the circuit configuration becomes relatively complicated.

SUMMARY OF THE INVENTION An object of the present invention is to provide a quadrature amplitude modulation device which can solve the above problems and can perform QAM with higher precision than the prior art, and has a simple circuit configuration and a low manufacturing cost. To provide.

Another object of the present invention is to provide a quadrature amplitude modulation device capable of easily changing a carrier frequency with a simple circuit configuration as compared with the prior art.

[0008]

A quadrature amplitude modulation apparatus according to the first aspect of the present invention comprises a calculation means for calculating amplitude data and phase data for quadrature amplitude modulation based on a two-sequence digital signal; Conversion means for D / A converting the amplitude data and the phase data calculated by the calculation means into amplitude analog signals and phase analog signals, respectively; and a signal for generating and outputting a carrier signal having a predetermined frequency Generating means, and phase-modulating the carrier signal according to a phase analog signal output from the conversion means,
Phase modulation means for outputting a modulated phase modulation signal, and amplitude modulation means for performing amplitude modulation by multiplying the carrier signal by an amplitude analog signal output from the conversion means and outputting a modulated amplitude modulation signal Wherein the phase modulating means and the amplitude modulating means are connected in cascade with each other, and output a signal outputted from a subsequent modulating means as a quadrature amplitude modulated signal.

According to a second aspect of the present invention, there is provided a quadrature amplitude modulation device, comprising: storage means for storing amplitude data and phase data for quadrature amplitude modulation of a predetermined two-sequence digital signal; Converting means for D / A converting the amplitude data and the phase data read from the means into an amplitude analog signal and a phase analog signal, respectively, and outputting;
Signal generation means for generating and outputting a carrier signal having a predetermined frequency; and phase modulation means for performing phase modulation on the carrier signal according to a phase analog signal output from the conversion means and outputting a modulated phase modulated signal And amplitude modulation means for multiplying the carrier signal by an amplitude analog signal output from the conversion means to output an amplitude-modulated signal after modulation. The phase modulation means, The modulation means is connected in cascade with each other, and outputs a signal output from the modulation means at the subsequent stage as a quadrature amplitude modulation signal.

Further, the quadrature amplitude modulator according to claim 3 is the quadrature amplitude modulator according to claim 1 or 2,
The phase modulation means includes a PLL circuit, the PLL circuit divides an input signal by an input frequency division ratio and outputs the frequency-divided signal, and a carrier signal output from the signal generation means. A phase comparator that compares the phase of the signal output from the frequency divider to output a phase error signal, a phase error signal output from the phase comparator, and a phase analog signal output from the conversion unit. And a low-pass filter that low-pass filters the signal output from the adding means with a predetermined loop filter coefficient and outputs the resultant signal. A voltage-controlled oscillator that generates a carrier signal so as to control the frequency of the carrier signal based on the signal output from the pass filter, outputs the carrier signal to the frequency divider, and outputs the signal as a phase modulation signal. And butterflies.

Further, the quadrature amplitude modulation device according to claim 4 is, in the quadrature amplitude modulation device according to claim 1, 2 or 3, inserted between the calculation means and the conversion means, Further, a differential means for time-differentiating the phase data output from the converter and outputting the differentiated data to the conversion means, wherein the phase modulation means operates as frequency modulation means.

Further, the quadrature amplitude modulation device according to the fifth aspect is the quadrature amplitude modulation device according to the first, second or third aspect, wherein the quadrature amplitude modulation device is inserted between the conversion means and the phase modulation means. The apparatus further comprises differentiating means for differentiating the phase analog signal output from the means with respect to time and outputting the resulting signal to the phase modulating means, wherein the phase modulating means operates as frequency modulating means.

[0013]

Embodiments of the present invention will be described below with reference to the drawings.

<First Embodiment> FIG. 1 is a block diagram showing a configuration of a quadrature amplitude modulation apparatus according to a first embodiment of the present invention. In the quadrature amplitude modulation device of the first embodiment, as shown in FIG. 1, (a) the phase data φ is a digital / analog converter (hereinafter, referred to as a D / A converter).
A phase modulator 2 for phase-modulating the reference signal generated by the reference signal generator 1 in accordance with the phase analog signal D / A-converted by 11 and outputting a phase-modulated phase-modulated signal; The data M is subjected to D / A conversion by the D / A converter 12, and is amplitude-modulated by multiplying the amplitude analog signal by the phase modulation signal output from the phase modulator 2 to obtain a QAM-modulated QAM signal. And a multiplier 3 that outputs The phase modulator 2 includes a phase locked loop (hereinafter, referred to as a PLL circuit) 2.
0, and the controller 30 changes the frequency division ratio 1 / N of the frequency divider 25 included in the PLL circuit 20, thereby changing the carrier frequency of the QAM signal.

In FIG. 1, an I signal and a Q signal of a two-sequence digital signal to be wirelessly transmitted are input to a digital operation control circuit 10 constituted by, for example, a microprocessor unit (MPU). The digital operation control circuit 10 calculates the amplitude data M and the phase data φ based on the I signal and the Q signal and calculates the amplitude data M and the phase data φ. Output to converters 12 and 11. Here, the phase data φ is preferably controlled by the digital operation control circuit 10 so as to be output, for example, in the range of -π <φ ≦ π. In the PLL circuit 20 of FIG. 1, the phase data φ is −2.
The output may be in the range of Nπ <φ ≦ 2Nπ.

## EQU1 ## M = √ (I ² + Q ² )

## EQU2 ## φ = tan ^-1 (Q / I)

The D / A converter 11 D / A converts the input phase data φ and outputs the converted phase analog signal to the adder 22 of the phase modulator 2. The D / A converter 12 D / A converts the input amplitude data M and outputs the converted analog signal to the multiplier 3.

Reference signal generator 1, for example a crystal oscillator
Generates a reference signal having a predetermined frequency and outputs it to a phase comparator 21 which is a multiplier of the phase modulator 2. The phase modulator 2 includes a phase comparator 21, an adder 22, a low-pass filter (hereinafter, referred to as LPF) 23 having a preset loop filter constant, and a voltage-controlled oscillator (hereinafter, referred to as VCO). ) 24 and a frequency divider 25 are provided with a PLL circuit 20 connected in a loop. The frequency division ratio 1 / N of the frequency divider 25 (where N is a natural number) uses a keyboard 31. And is set by the controller 30 constituted by, for example, an MPU. The phase comparator 21 performs a phase comparison by multiplying the reference signal output from the reference signal generator 1 by a signal output from the frequency divider 25 to obtain a phase indicating the cosine cos θ of the phase difference θ. The error signal is output to the adder 22. Adder 22
Is the phase error signal output from the phase comparator 21 and D
And the phase analog signal output from the A / A converter 11, and the signal of the addition result is output to the VCO 2 via the LPF 23.
4 is output. The VCO 24 generates a carrier signal so as to control the oscillation frequency based on the signal output from the LPF 23 and outputs the carrier signal to the multiplier 3 and the frequency divider 25. The divider 25 divides the frequency of the carrier signal from the VCO 24 so as to be 1 / N of the original frequency, and outputs the divided signal to the phase comparator 21.

[0018] In the PLL circuit 20 configured as described above is determined by the following equation frequency f _c of the carrier signal generated based on the frequency division ratio 1 / N of the frequency divider 25 by VCO 24.

F _c = N · f _c0

Here, f _c0 is the frequency of the reference signal generated by the reference signal generator 1. Thus, VCO 24 of the PLL circuit 20 has a natural number N times the carrier frequency of the frequency f _c0 of the reference signal generated by the reference signal generator 1, and the reference signal generated by the reference signal generator 1 to the phase A carrier signal having a phase synchronized with the phase analog signal from the D / A converter 11 and having a phase modulated in accordance with the phase analog signal is generated and output to the multiplier 3. The multiplier 3 is configured as, for example, a wideband multiplier having a pin diode, and includes a carrier signal from the VCO 24 and a D / A converter 12.
, The carrier signal is subjected to amplitude modulation according to the amplitude analog signal, and a phase-modulated and amplitude-modulated QAM signal is generated and output.

In the quadrature amplitude modulation device configured as described above, the phase-modulated carrier signal output from the phase modulator 2 is set to A ₀ cos (2πf _c + θ) and output from the D / A converter 12. Is given by m · M (where m is D
/ A conversion coefficient of the A converter 12, which corresponds to the modulation factor of amplitude modulation (0 <m ≦ 1) in the following equation. ), The QAM signal f (t) output from the multiplier 3 is expressed by the following equation.

In Equation 4] _{f (t) = A 0 (} 1 + m · M) cos (2πf c + θ) Equation 4, the carrier signal changes phase theta number 4 of the carrier signal by the phase data φ changes are The carrier signal is amplitude-modulated by the phase modulation and the change of the amplitude data M, and the QAM signal after the modulation is obtained. In order to change the carrier frequency, there are a method of changing the frequency of the reference signal generator 1 and a method of changing the frequency division ratio 1 / N of the frequency divider 25. When N is changed,
Since the phase sensitivity changes in proportion to N, the D / A converter 1
1 is changed according to N. On the other hand, when changing the frequency of the reference signal, the phase modulation sensitivity is kept constant.

In the quadrature amplitude modulation apparatus of the present embodiment configured as described above, the reference data generator 1 generates the phase data φ in accordance with the phase analog signal that has been D / A converted by the D / A converter 11. A phase modulator 2 that phase-modulates the obtained reference signal and outputs a phase-modulated signal after the phase modulation, and the D / A converter 12 converts the amplitude data M into a D / A signal.
/ A converted amplitude analog signal, and the phase modulator 2
And a multiplier 3 for amplitude-modulating by multiplying the phase-modulated signal output from the MPU to output a QAM signal, thereby forming a quadrature amplitude modulator. Since the carrier signal is amplitude-modulated and phase-modulated using the D / A-converted amplitude analog signal and phase analog signal, quadrature amplitude modulation is performed. Thus, quadrature amplitude modulation can be performed with higher accuracy, with a simple circuit configuration, and at a low manufacturing cost.

In the first embodiment, the PLL circuit 2
By providing the phase modulator 2 having 0 and the multiplier 3, there is an advantage that a variable frequency type quadrature amplitude modulator can be easily formed and the frequency characteristics are good. That is, the frequency characteristic of the multiplier 3 is based on the reference signal generator (SG).
Has very good frequency characteristics like the AM modulator, but the phase modulator 2 is also configured using the PLL circuit 20, so that phase modulation can be stably performed even when the carrier frequency changes. . In particular, in the digital circuit of the PLL circuit 20, phase modulation or frequency modulation (described in detail later) can be applied with very high accuracy.

By inputting the frequency division ratio 1 / N of the frequency divider 25 using the keyboard 31, a carrier signal having a carrier frequency higher than that of the reference signal generated by the reference signal generator 1 can be obtained. It can be easily generated regardless of the heterodyne method shown in the technology. Further, in the phase modulator 2 provided with the PLL circuit 20, the modulation index is determined irrespective of the reference frequency, and the wideband multiplier 3 can be constituted by using pin diodes. Compared with the quadrature amplitude modulator, a wide band quadrature amplitude modulator can be easily configured.

In the first embodiment, the frequency divider 2
Although the frequency division ratio of 5 is 1 / N, the present invention is not limited to this, and the frequency division ratio may be M / N (where M and N are natural numbers).

<Second Embodiment> FIG. 2 is a block diagram showing a configuration of a quadrature amplitude modulation apparatus according to a second embodiment of the present invention. In FIG. The same reference numerals are given. The quadrature amplitude modulation device of the second embodiment differs from the first embodiment of FIG. 1 in the following point. (A) For example, a read-only memory (hereinafter referred to as a ROM) for calculating and storing amplitude data M and phase data φ of a predetermined two-sequence digital signal to be generated, such as a pseudo-random pattern signal, in advance. 13 was provided. (B) ROM 1 instead of digital operation control circuit 10
3, the amplitude data M and the phase data φ of the two-sequence digital signal stored in the ROM 1 are synchronized with a predetermined clock signal.
And a digital operation control circuit 10a for sequentially reading data from D.3 and outputting to the D / A converters 12 and 11.

In the quadrature amplitude modulator of the second embodiment configured as described above, the digital operation control circuit 10a converts the amplitude data M and the phase data φ of the two-sequence digital signal stored in the ROM 13 into predetermined values. The data is sequentially read from the ROM 13 and output to the D / A converters 12 and 11 in synchronization with the clock signal. Next, the D / A converter 11
Converts the read phase data φ into a phase analog signal by D / A
The signal is converted and output to the phase modulator 2. On the other hand, the D / A converter 12 D / A converts the read amplitude data M into an analog analog signal and outputs the analog signal to the multiplier 3. Phase modulator 2
Performs phase modulation on the reference signal generated by the reference signal generator 1 in accordance with the phase analog signal, and outputs the phase-modulated phase-modulated signal to the multiplier 3. The amplitude modulation is performed by multiplying the phase modulation signal output from the modulator 2 to output a QAM signal.

In the second embodiment, there is no need for the digital operation control circuit 10 for performing the operations of the above equations (1) and (2), but merely reads out and outputs the amplitude data M and the phase data φ stored in the ROM 13. Since it is sufficient to provide the digital operation control circuit 10a, the quadrature amplitude modulation device can be configured with a simple circuit configuration and low manufacturing cost as compared with the first embodiment. Also in the second embodiment, the carrier signal is amplitude-modulated and phase-modulated using the amplitude analog signal and the phase analog signal obtained by D / A-converting the amplitude data and the phase data, which are digital data, respectively. Therefore, the quadrature amplitude modulation can be performed with higher accuracy than that of the prior art quadrature amplitude modulation apparatus shown in FIG. 3 with a simple circuit configuration and at a low manufacturing cost.

<Modification> In the above embodiment, the reference signal generated by the reference signal generator 1 is phase-modulated by the phase modulator 2 and then amplitude-modulated by the multiplier 3. Not limited to this, the order of the phase modulator 2 and the multiplier 3 may be switched, the amplitude modulation may be performed by the multiplier 3, and then the phase modulation may be performed by the phase modulator 2. That is, the phase modulator 2 and the multiplier 3 are connected in cascade, and the order is not limited and is not limited.

In the above embodiment, the phase modulator 2 is provided. However, the present invention is not limited to this, and a frequency modulator may be used instead of the phase modulator 2. That is, D /
The phase analog signal from the A converter 11 is time-differentiated by a differentiator and input to the adder 22, or the phase data φ output from the digital operation control circuit 10 is time-differentiated and then the D / A converter 11 By performing D / A conversion, the signal is converted into a frequency analog signal and input to the adder 22. Therefore, the present invention includes an angle modulator that is either the phase modulator 2 or the frequency modulator, and the angle modulator performs angle modulation according to an angle analog signal that is a phase analog signal or a frequency analog signal. Here, when configuring a frequency modulator, the maximum frequency shift f _max needs to be set to be equal to or less than the bandwidth of the PLL circuit 20. Further, when a frequency modulator is configured, the differential value of the phase data φ is used, so that the above-mentioned limitation of the phase data φ is eliminated.

In the first and second embodiments described above,
The phase modulator is composed of an analog circuit.
In a circuit using a circuit, frequency modulation is possible by changing the frequency division ratio. Therefore, if the digital data obtained by integrating the phase information is directly input to the frequency divider, the D / A converter 11 becomes unnecessary.

[0031]

As described in detail above, in the quadrature amplitude modulation apparatus according to the first aspect of the present invention, a calculation for calculating amplitude data and phase data for quadrature amplitude modulation based on a two-sequence digital signal. Means for converting the amplitude data and the phase data calculated by the calculating means into an analog analog signal and a phase analog signal, respectively, and outputting the analog and phase analog signals; and generating a carrier signal having a predetermined frequency. A signal generating means for outputting, a phase modulation means for performing phase modulation on the carrier signal in accordance with a phase analog signal output from the conversion means, and outputting a modulated phase modulation signal; and outputting the carrier signal from the conversion means. Amplitude modulation by multiplying by the amplitude analog signal
Amplitude modulating means for outputting a modulated amplitude modulated signal, wherein the phase modulating means and the amplitude modulating means are cascaded with each other, and a signal output from a subsequent modulating means is used as a quadrature amplitude modulated signal. Output. That is, quadrature amplitude modulation is performed by amplitude-modulating and phase-modulating a carrier signal using an amplitude analog signal and a phase analog signal obtained by D / A conversion of amplitude data and phase data, which are digital data, respectively. The quadrature amplitude modulation can be performed with higher accuracy than the prior art quadrature amplitude modulation device shown in FIG. 3, with a simple circuit configuration, and at low manufacturing cost.

According to a second aspect of the present invention, there is provided a quadrature amplitude modulation apparatus, comprising: storage means for storing amplitude data and phase data for quadrature amplitude modulation of a predetermined two-sequence digital signal; Converting means for D / A converting the amplitude data and the phase data read from the storage means into an amplitude analog signal and a phase analog signal, respectively; and a signal for generating and outputting a carrier signal having a predetermined frequency Generating means, phase-modulating the carrier signal in accordance with the phase analog signal output from the converting means, and outputting a modulated phase-modulated signal;
Amplitude modulation means for multiplying the carrier signal by an amplitude analog signal output from the conversion means to output an amplitude-modulated signal after modulation, the phase modulation means, and the amplitude modulation means Are connected in cascade with each other, and output the signal output from the modulation means at the subsequent stage as a quadrature amplitude modulation signal. Therefore, a quadrature amplitude modulator that generates a quadrature amplitude modulation signal of a predetermined two-sequence digital signal only by including the storage unit in place of the arithmetic unit is compared with the prior art quadrature amplitude modulator of FIG. Therefore, it can be realized with higher accuracy, with a simple circuit configuration, and at a low manufacturing cost.

Further, in the quadrature amplitude modulator according to claim 3, in the quadrature amplitude modulator according to claim 1 or 2, the phase modulation means includes a PLL circuit,
An LL circuit configured to divide the input signal by an input division ratio and output the divided signal; a carrier signal output from the signal generation unit; and a signal output from the frequency divider. A phase comparator that compares the phases and outputs a phase error signal, a phase error signal output from the phase comparator, and a phase analog signal output from the conversion unit are added, and a signal of the addition result is obtained. Adding means for outputting, a low-pass filter for low-pass filtering the signal output from the adding means with a predetermined loop filter coefficient, and outputting the carrier wave based on the signal output from the low-pass filter. A voltage-controlled oscillator that generates a carrier signal so as to control the frequency of the signal, outputs the signal to the frequency divider, and outputs the signal as a phase modulation signal. Therefore, by inputting the frequency division ratio of the frequency divider, a carrier signal having a carrier frequency higher than the carrier signal generated by the signal generating means, or a carrier signal having a changed carrier frequency, is used in the heterodyne method shown in the prior art. Regardless, it can be easily generated.

According to a fourth aspect of the present invention, there is provided the quadrature amplitude modulator according to the first, second, or third aspect, wherein the quadrature amplitude modulator is inserted between the arithmetic means and the conversion means, and The image processing apparatus further includes a differentiating unit that performs time differentiation on the phase data output from the unit and outputs the resultant to the conversion unit, and the phase modulation unit operates as a frequency modulation unit. Therefore, the quadrature amplitude modulation device provided with the frequency modulation means can be realized with a simple circuit configuration and at a low manufacturing cost only by further providing the differentiating means.

Further, in the quadrature amplitude modulation device according to the fifth aspect, the quadrature amplitude modulation device according to the first, second or third aspect is inserted between the conversion means and the phase modulation means, There is further provided differentiating means for differentiating the phase analog signal output from the converting means with respect to time and outputting the resultant signal to the phase modulating means, wherein the phase modulating means operates as frequency modulating means. Therefore, the quadrature amplitude modulation device provided with the frequency modulation means can be realized with a simple circuit configuration and at a low manufacturing cost only by further providing the differentiating means.

[Brief description of the drawings]

FIG. 1 is a block diagram illustrating a configuration of a quadrature amplitude modulation device according to a first embodiment of the present invention.

FIG. 2 is a block diagram illustrating a configuration of a quadrature amplitude modulation device according to a second embodiment of the present invention.

FIG. 3 is a block diagram illustrating a configuration of a conventional quadrature amplitude modulation device.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 ... Reference signal generator, 2 ... Phase modulator, 3 ... Multiplier, 10,10a ... Digital operation control circuit, 11,12 ... D / A converter, 13 ... Read only memory (ROM), 20 ... PLL circuit Reference numeral 21: phase comparator, 22: adder, 23: low-pass filter (LPF), 24: voltage-controlled oscillator (VCO), 25: frequency divider, 30: controller, 31: keyboard.

Claims (5)

[Claims] An arithmetic means for calculating amplitude data and phase data for quadrature amplitude modulation based on a two-sequence digital signal, and an amplitude analog signal and an amplitude analog signal respectively calculated by the arithmetic means. Conversion means for performing D / A conversion to a phase analog signal and outputting the signal; signal generation means for generating and outputting a carrier signal having a predetermined frequency; and converting the carrier signal according to the phase analog signal output from the conversion means. Phase modulating means for phase-modulating and outputting a phase-modulated signal after modulation; and amplitude-modulating the carrier signal by multiplying the carrier signal by an amplitude analog signal output from the conversion means, and modulating the amplitude-modulated signal after modulation. An amplitude modulating means for outputting a signal, wherein the phase modulating means and the amplitude modulating means are cascade-connected to each other and output from a succeeding modulating means. Quadrature amplitude modulation device and outputs a signal as a quadrature amplitude modulated signal. 2. A storage means for storing amplitude data and phase data for quadrature amplitude modulation of a predetermined two-sequence digital signal, and storing the amplitude data and the phase data read from the storage means in amplitude and Conversion means for performing D / A conversion to an analog signal and a phase analog signal and outputting the signal; signal generation means for generating and outputting a carrier signal having a predetermined frequency; and phase output from the conversion means for the carrier signal Phase modulation means for performing phase modulation according to an analog signal and outputting a modulated phase modulation signal; amplitude modulation by multiplying the carrier signal by an amplitude analog signal output from the conversion means; Amplitude modulation means for outputting a modulation signal, wherein the phase modulation means and the amplitude modulation means are connected in cascade with each other, and Quadrature amplitude modulation device and outputs a signal outputted as the quadrature amplitude modulation signal. 3. The phase modulation means includes a PLL circuit, wherein the PLL circuit divides an input signal by an input division ratio and outputs the divided signal, and an output from the signal generation means. A phase comparator that outputs a phase error signal by comparing the phase of the carrier signal with the signal output from the frequency divider, and a phase error signal output from the phase comparator. And the phase analog signal
Addition means for outputting a signal of the addition result; low-pass filter for low-pass filtering the signal output from the addition means with a predetermined loop filter coefficient; and output from the low-pass filter 2. A voltage-controlled oscillator for generating a carrier signal so as to control the frequency of the carrier signal based on the signal, outputting the carrier signal to the frequency divider, and outputting the carrier signal as a phase modulation signal. Or the quadrature amplitude modulator according to 2. 4. The phase modulating means further comprising a differentiating means inserted between the calculating means and the converting means for differentiating the phase data output from the calculating means with respect to time and outputting to the converting means. 4. The quadrature amplitude modulation device according to claim 1, wherein the device operates as frequency modulation means. 5. A differentiating means inserted between the converting means and the phase modulating means, and differentiating means for time-differentiating a phase analog signal output from the converting means and outputting the signal to the phase modulating means. The phase modulation means operates as a frequency modulation means.
A quadrature amplitude modulator according to any of the preceding claims.