JP3800176B2 - Communication apparatus and communication system using the same - Google Patents

Description

ここで、Ｇ１及びＧ２は増幅率であり、増幅率Ｇ１＞増幅率Ｇ２である。
（数１）に示すように、入力信号ｘが閾値ｓを超える場合は、閾値ｓを越える部分を増幅率Ｇ２で増幅するが、閾値ｓ以下の部分に対応する増幅率Ｇ１よりも増幅率Ｇ２は小さいため、閾値ｓを超える部分は閾値ｓ以下の部分よりも圧縮される。これにより、ピーク電力を確実に低減することができ、かつ平均電力の低下は小さいため、ピーク比が低減される。なお、全ての入力振幅を１以下の増幅率（一定）で増幅すれば、出力のピーク電力は低減できるが、平均電力も同一比率で低下するため、ピーク比は低減できない。つまり、本実施例のように振幅の比較的大きな部分のみを圧縮しなければピーク比を抑制することはできない。なお、伸長器１４２における閾値はｓ×Ｇ１とし、閾値を越える部分の増幅率はＧ２の逆数にすれば良い。第２図（ｃ）は、圧縮器１０４における増幅率の他の一例を示している。図示するように、閾値よりも小さな入力振幅に対してＧ１より低い増幅率であれば増幅率をＧ３のように連続的に変化させても同様の効果が得られる。
（実施例２）
次に、本発明の他の実施例である通信システムについて実施例１と異なる点を説明する。上述したようにＯＦＤＭ変調信号はキャリアの合成によりピーク比が高くなる。しかし、各キャリアの振幅、位相の組合せによってはピーク比が小さい場合もあり、その場合には圧縮が不要であるので圧縮を行わない。そして、送信信号に信号を圧縮したか否かの情報を付加して送信し、受信側ではその情報に従って、圧縮した信号であれば伸長器１４２に入力し、伸長後にＯＦＤＭ復調する。非圧縮の受信信号であれば、伸長器１４２を介さずにＯＦＤＭ復調する。圧縮した信号を伸長しても多少の歪みは残ってしまうため、本実施例のように圧縮が不要な場合には非圧縮とすることで、不必要な圧縮を避け、歪みの発生を抑制することができる。それにより、通信の信頼性を更に向上させることができる。
（実施例３）
続いて、本発明の他の実施例である通信システムについて、実施例１と異なる点を第６図を用いて説明する。第６図は、本実施例のＯＦＤＭ変調器１０′及びＯＦＤＭ復調器１４′の構成を示している。図示するように、本実施例のＯＦＤＭ変調器１０′は、２つの圧縮器１０４ａ，１０４ｂを備えており、また、圧縮器１０４ａ，１０４ｂの後段に直交変調器１０３が設けられている。ＩＦＦＴ１０２から出力された複素数信号は、実数信号及び虚数信号に分けられて、実数信号が圧縮器１０４ａに入力され、虚数信号が圧縮器１０４ｂに入力される。圧縮器１０４ａ，１０４ｂはそれぞれ実数信号及び虚数信号に対して実施例１と同様に圧縮を行う。圧縮器１０４ａ，１０４ｂにて圧縮された実数信号及び虚数信号は、直交変調器１０３に入力され、直交変調器１０３は入力された複素数信号（実数信号及び虚数信号）を実数信号に変換する。このように、圧縮器を実数信号及び虚数信号それぞれに対して設けることにより、例えば、実数信号のピーク電力が閾値よりも小さく、ピーク比も小さい場合には、実数信号について圧縮が行われないため、信号の歪みが生じない。一方、受信側となるＯＦＤＭ復調器１４′では、直交復調器１４３によって得られた複素数信号が実数信号及び虚数信号に分けられて、それぞれ伸長器１４２ａ，１４２ｂに入力される。伸長器１４２ａの増幅率は圧縮器１０４ａの逆変換を行うように設定されており、伸長器１４２ｂの増幅率は圧縮器１０４ｂの逆変換を行うように設定されている。
本実施例によれば、複素数信号を実数信号及び虚数信号に分けてピーク比の小さな信号については圧縮を行わないため、信号の歪みを低減することが可能となり、通信の信頼性を更に向上させることができる。
以上説明した各実施例では、電力線搬送によってデータ送受信を行う場合について説明したが、本発明は電力線搬送以外の通信方法にも適用可能である。また、各実施例では、マルチキャリア変調方式の例としてＯＦＤＭ方式について説明したが、本発明はＯＦＤＭ方式以外のマルチキャリア変調方式にも適用可能である。
産業上の利用可能性
本発明は、ＯＦＤＭ方式のようなマルチキャリア変調方式により通信を行う通信システムに適用できる。この適用により、通信速度を低下させることなく、ピーク比を低減することができる。
【図面の簡単な説明】
第１図は、本発明の好適な一実施例である通信システムの構成図、第２図は、圧縮器１０４及び伸長器１４２に設定された増幅率の特性図、第３図は、圧縮器１０４の入力信号（源信号）、出力信号（圧縮信号）及び源信号と圧縮信号のピーク比を示す図、第４図は、伸長を行わない場合と伸長を行った場合における信号点配置誤差を示す図、第５図は、入力振幅と出現頻度との関係及び入力振幅と累積頻度との関係を示す図、第６図は、本発明の他の実施例である通信システムの構成図である。TECHNICAL FIELD The present invention relates to a communication apparatus that performs communication using a multicarrier modulation method such as an orthogonal frequency division multiplexing method and a communication system using the communication device.
Background Art In a communication technique using a carrier wave, a method of transmitting data by modulating the amplitude, phase or frequency of one carrier is called a single carrier modulation method. On the other hand, a method of combining a plurality of carriers whose amplitudes or phases are modulated to form a transmission signal is called a multicarrier modulation method. When the transmission speed is the same, the multicarrier modulation method has a feature that the transmission time can be increased by several times the number of carriers, so that it is less affected by the reflected wave generated in the communication path.
The orthogonal frequency division multiplexing (hereinafter referred to as OFDM) scheme is one of multicarrier modulation schemes, and has a high frequency utilization efficiency because the frequency interval between carriers can be minimized. For this reason, it is adopted as an xDSL (Digital Subscriber Line) modulation method using power line carrier, digital television broadcasting, radio and telephone lines.
In the multi-carrier modulation system as well as the OFDM system, a plurality of carriers are combined to form a transmission signal, and therefore has a relatively high peak amplitude with respect to the effective value of the amplitude of the transmission signal. That is, the ratio of peak power to average power (hereinafter, peak power / average power is referred to as peak ratio) is high. In general, since a communication device has a restriction value for transmission output, the average power cannot be increased if the peak ratio is high as in the multicarrier modulation method. Although the transmission characteristics of the communication device are determined by the signal-to-noise ratio (S / N) of the transmission line including the communication device, as described above, since the average power cannot be increased in the multicarrier modulation method, the S / N is increased. As a result, transmission errors increase. In addition, since the peak ratio is high, an amplifier having a large maximum power must be used as the transmission amplifier, and the cost of the transmission amplifier increases. Furthermore, the dynamic range of the digital processing circuit used for transmission / reception signal processing must be increased.
As conventional techniques for reducing the peak ratio, there are JP-A-8-979797, JP-A-10-178411, JP-A-11-163826, and the like. Therefore, there is a problem that a complicated calculation for array conversion is required to reduce the peak power generated by, and that an effective transmission rate is lowered by adding redundant bits for limiting the data array.
DISCLOSURE OF THE INVENTION An object of the present invention is to provide a communication apparatus capable of reducing the peak ratio without reducing the transmission rate when performing communication using a multicarrier modulation method, and a communication system using the same. .
A feature of the present invention that achieves the above object is that a modulated signal obtained by synthesizing a plurality of carriers modulated by transmission data is input, a first amplification factor for a signal that is equal to or lower than a preset threshold value, A compressor that amplifies the modulation signal by a second amplification factor for a signal that exceeds the threshold value that is set to a value smaller than one amplification factor, and a transmission signal that is obtained based on the output signal of the compressor is transmitted And a transmission means.
By making the amplification factor of the signal exceeding the threshold value smaller than the amplification factor of the signal below the threshold value, the signal exceeding the threshold value is compressed compared to the signal below the threshold value, so that the peak power of the modulation signal is reduced, And since the fall of average power is suppressed smaller than the fall of peak power, a peak ratio is reduced. Further, since there is no need to add redundant bits for limiting the data arrangement as in the prior art, the transmission speed is not reduced.
BEST MODE FOR CARRYING OUT THE INVENTION Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.
Example 1
FIG. 1 shows the configuration of a communication system which is a preferred embodiment of the present invention. As shown in FIG. 1, in the communication system of the present embodiment, a plurality of communication devices 1a, 1b, 1c... Are connected via a power line 2, and each communication device 1a, 1b, 1c. Data is transmitted and received with each other by folding signals. That is, the communication device of the present embodiment is a power line carrier device that transmits and receives data by power line carrier. The communication devices 1a, 1b, 1c,... Have the same device configuration, and their operations are also the same.
Hereinafter, a case where data is transmitted from the communication device 1a to the communication device 1b will be described. First, transmission data to be transmitted to the communication device 1b is input to the OFDM modulator 10 of the communication device 1a. In the OFDM modulator 10, the input transmission data is input to the mapping 101, and the mapping 101 converts the input transmission data from 0, 1 pattern to complex data. This complex data becomes amplitude data of each carrier. The obtained complex number data is input to an inverse fast Fourier transformer (IFFT) 102 and subjected to inverse fast Fourier transform to generate a modulation signal in the time domain. In this embodiment, in order to synthesize a plurality of carriers having different amplitudes and frequencies, inverse fast Fourier transform is employed. A complex signal obtained by the inverse fast Fourier transform by IFFT 102 is input to quadrature modulator 103. The quadrature modulator 103 converts the input complex signal into a real signal and outputs it. Conventionally, the signal obtained by the quadrature modulator 103 is converted to an analog signal and then transmitted by being folded on the power line 2, but in this embodiment, the signal is compressed before being converted to an analog signal. .
The real signal output from the quadrature modulator 103 is input to the compressor 104, and the compressor 104 amplifies (compresses) the input signal at a preset amplification factor. FIG. 2A shows the amplification factor in the compressor 104, that is, the amplitude of the input signal (hereinafter referred to as input amplitude) and the amplitude of the output signal corresponding thereto (hereinafter referred to as output amplitude). As shown in FIG. 2 (c), the compressor 104 sets the amplification factor to 1 when the input amplitude is in the range of 0 to 0.03, and reduces the amplification factor to 1/8 (when the input amplitude is 0.03 or more. 0.125). That is, the amplification factor is changed using the input amplitude 0.03 as a threshold value. A method for determining the threshold and the amplification factor will be described later.
FIG. 3 (b) shows a signal after compression when the signal shown in FIG. 3 (a) is input to the compressor 104. FIG. When a multi-carrier modulation method such as the OFDM modulation method is used, an input signal (referred to as a source signal) of the compressor 104 is pulsed as shown in FIG. Due to the amplitude change, the waveform has a point with a large amplitude. When the source signal shown in FIG. 3 (a) is compressed by the compressor 104, as shown in FIG. 3 (b), the amplitude of 0.03 or more is greatly compressed and the protruding peak disappears. In the compressor 104 of the present embodiment, as described above, the peak power can be reduced by compressing the amplitude to 1/8 in the range of 0.03 or more which is the threshold, that is, by compressing a large amplitude. Since the amplitude below 03 is not compressed with an amplification factor of 1, the average power hardly decreases. Therefore, the peak ratio that is the ratio between the peak power and the average power is greatly reduced. FIG. 3 (c) shows a result obtained by simulating the relationship between the peak ratio of the source signal and the peak ratio of the compressed signal and the number of trials when random data is given as transmission data. As shown in the figure, the peak ratio of the source signal is close to 20 at the maximum, whereas the peak ratio of the compressed signal is reduced to 5 or less. As described above, according to the present embodiment, the maximum value of the peak ratio can be reduced to about 1/4 compared with the case where the signal compression is not performed, and thereby the maximum power of the amplifier described later can be reduced to about the conventional value. It can be reduced to a quarter. Conversely, when the same amplifier as the conventional one is used, the transmission power can be increased up to four times.
The signal output from the compressor 104 is input to a digital / analog converter (D / A) 105. The D / A 105 converts the input signal from a digital signal to an analog signal and outputs the analog signal. A signal output from the D / A 105 is input to the amplifier 11 as an OFDM modulated signal output from the OFDM modulator 10. The amplifier 11 amplifies the input OFDM modulated signal with a preset amplification factor, and the OFDM modulated signal amplified by the amplifier 11 is input to the coupler 12. The combiner 12 folds the input OFDM modulated signal on the power line 2.
The OFDM modulated signal folded on the power line 2 is received by the communication device 1b. The coupler 12 of the communication device 1b recognizes and takes in the signal output to the communication device 1b among the signals folded on the power line 2. Note that address information assigned to a transmission destination communication device is added to the signal to be folded on the power line 2, and the coupler 12 recognizes a signal to be captured based on the address information. The signal captured by the combiner 12 is input to a BPS (band pass filter) 13, and the BPS 13 outputs only a signal in a preset frequency range. Noise is removed by the BPS 13. The signal output from the BPS 13 is input to the OFDM demodulator 14.
The signal input to the OFDM demodulator 14 is input to an analog / digital converter (A / D) 141. The A / D 141 converts the input signal from an analog signal to a digital signal and outputs the signal. The signal output from the A / D 141 is input to the expander 142, and the expander 142 amplifies (expands) the signal at an amplification factor that is the inverse conversion of the compressor 104. FIG. 2B shows the amplification factor in the expander 142, that is, the input amplitude and the output amplitude corresponding thereto. As shown in FIG. 2 (b), the decompressor 142 sets the gain to 1 in the range of 0 to 0.03, and sets the gain to 1 in the compressor 104 in the range of 0.03 or more. The reciprocal of the amplification factor is 8. That is, the expander 142 also changes the amplification factor using the input amplitude 0.03 as a threshold value. Moreover, since the amplification factor for the input amplitude of 0.03 or more is the reciprocal of the amplification factor of the compressor 104, the same signal as the input signal (source signal) of the compressor 104 is obtained as the output signal of the expander 142. .
FIG. 4 (a) shows the signal point arrangement error when the expansion is not performed, and FIG. 4 (b) shows the signal point arrangement error when the expansion is performed as in the present embodiment. As shown in the figure, the signal point arrangement error when the extension of FIG. 4B is performed is very small as compared with the case where the extension of FIG. 4A is not performed. As described above, the signal transmitted after being compressed is expanded before the OFDM demodulation, so that the distortion of the transmission signal can be removed and the signal can be correctly demodulated.
The signal output from the decompressor 142 is input to the quadrature demodulator 143, and the orthogonal demodulator 143 converts the input signal from a real signal to a complex signal. The complex signal obtained by the quadrature demodulator 143 is input to a fast Fourier transformer (FFT) 144 and subjected to fast Fourier transform to generate a frequency domain signal. The signal obtained by the FFT 144 is input to the demapping 145, and the demapping 145 converts the input signal from complex data to data of 0, 1 pattern. This data is received data. In this way, data is transmitted from the communication device 1a to the communication device 1b.
Here, a method for determining a threshold value in the compressor 104 will be described. Although the peak power decreases as the threshold value decreases, the average power also decreases accordingly. Therefore, if the threshold value is too small, the effect of reducing the peak ratio decreases. For example, as an extreme example, when the threshold value is 0, the entire signal is compressed and the peak power is reduced, but the peak ratio is not changed. Since the frequency of large amplitude is low in an OFDM modulated signal, it is preferable to set a threshold value so that only the large amplitude is compressed. FIG. 5 (a) shows the result of counting the frequency of amplitude 100 times for 256 OFDM modulation signals in one period, and FIG. 5 (b) shows the relationship between the input amplitude and its accumulated frequency. In this counting result, the amplitude in terms of average power is 0.02, and the cumulative frequency of 0.02 or less is about 0.7. Further, at an amplitude of 0.04, the cumulative frequency is 0.95. It is known that the instantaneous power distribution of an OFDM modulated signal is a chi-square distribution, and the results in FIG. 5 are consistent with it. Therefore, setting the threshold to an average amplitude of 0.02 or less is not preferable because the average power decreases and the frequency of the signal to be compressed increases. On the other hand, setting the threshold to 3 times or more of the average amplitude is not preferable because the frequency of the signal to be compressed becomes too small, and the effect of reducing the peak power becomes small. Therefore, it is desirable to set the threshold within a range of 1 to 3 times the average power conversion amplitude. Furthermore, in consideration of reducing the distortion of the transmission signal, that is, minimizing the frequency of the signal to be compressed, the threshold is preferably about twice the amplitude of the average power.
Next, the amplification factor in the compressor 104 will be described. The peak ratio can be reduced as the amplification factor for the amplitude exceeding the threshold is smaller. However, if the value is too small, the quantization error in the digital value increases. Therefore, about 1/10 of the amplification factor below the threshold value may be set as the lower limit of the amplification factor above the threshold value.
The compressor 104 of the present embodiment described above will be described using mathematical expressions. When the input signal of the compressor 104 is x, the output signal is y, and the threshold is s, the relationship between the input signal x and the output signal y in the compressor 104 is (Equation 1).

Here, G1 and G2 are amplification factors, and amplification factor G1> amplification factor G2.
As shown in (Expression 1), when the input signal x exceeds the threshold s, the portion exceeding the threshold s is amplified by the amplification factor G2, but the amplification factor G2 is higher than the amplification factor G1 corresponding to the portion below the threshold s. Therefore, the portion exceeding the threshold s is compressed more than the portion below the threshold s. As a result, the peak power can be reliably reduced, and the decrease in average power is small, so the peak ratio is reduced. Note that if all input amplitudes are amplified with an amplification factor (constant) of 1 or less, the peak power of the output can be reduced, but the average power also decreases at the same ratio, so the peak ratio cannot be reduced. In other words, the peak ratio cannot be suppressed unless only a portion having a relatively large amplitude is compressed as in this embodiment. Note that the threshold value in the expander 142 may be s × G1, and the amplification factor of the portion exceeding the threshold value may be an inverse number of G2. FIG. 2 (c) shows another example of the amplification factor in the compressor 104. As shown in the figure, if the amplification factor is lower than G1 with respect to an input amplitude smaller than the threshold value, the same effect can be obtained even if the amplification factor is continuously changed like G3.
(Example 2)
Next, a communication system which is another embodiment of the present invention will be described while referring to differences from the first embodiment. As described above, the OFDM modulated signal has a high peak ratio due to carrier synthesis. However, the peak ratio may be small depending on the combination of the amplitude and phase of each carrier. In this case, compression is not performed because compression is unnecessary. Then, information indicating whether or not the signal is compressed is added to the transmission signal for transmission, and the reception side inputs the compressed signal to the decompressor 142 according to the information, and performs OFDM demodulation after decompression. If it is an uncompressed received signal, OFDM demodulation is performed without using the decompressor 142. Even if the compressed signal is expanded, some distortion remains. Therefore, if compression is not required as in this embodiment, non-compression is performed to avoid unnecessary compression and suppress the occurrence of distortion. be able to. Thereby, the reliability of communication can be further improved.
Example 3
Next, a communication system according to another embodiment of the present invention will be described with reference to FIG. FIG. 6 shows the configuration of the OFDM modulator 10 'and OFDM demodulator 14' of the present embodiment. As shown in the figure, the OFDM modulator 10 'of this embodiment includes two compressors 104a and 104b, and a quadrature modulator 103 is provided at the subsequent stage of the compressors 104a and 104b. The complex signal output from the IFFT 102 is divided into a real signal and an imaginary signal, and the real signal is input to the compressor 104a and the imaginary signal is input to the compressor 104b. The compressors 104a and 104b respectively compress the real signal and the imaginary signal in the same manner as in the first embodiment. The real number signal and the imaginary number signal compressed by the compressors 104a and 104b are input to the quadrature modulator 103, and the quadrature modulator 103 converts the input complex number signal (real number signal and imaginary number signal) into a real number signal. Thus, by providing a compressor for each of the real number signal and the imaginary number signal, for example, when the peak power of the real number signal is smaller than the threshold and the peak ratio is small, the real number signal is not compressed. , No signal distortion occurs. On the other hand, in the OFDM demodulator 14 ′ on the receiving side, the complex signal obtained by the orthogonal demodulator 143 is divided into a real signal and an imaginary signal and input to the decompressors 142 a and 142 b, respectively. The amplification factor of the decompressor 142a is set so as to perform the inverse transformation of the compressor 104a, and the amplification factor of the decompressor 142b is set so as to perform the inverse transformation of the compressor 104b.
According to this embodiment, a complex signal is divided into a real signal and an imaginary signal, and a signal with a small peak ratio is not compressed. Therefore, it is possible to reduce signal distortion and further improve communication reliability. be able to.
In each of the embodiments described above, the case where data transmission / reception is performed by power line conveyance has been described. However, the present invention can also be applied to communication methods other than power line conveyance. In each embodiment, the OFDM system has been described as an example of the multicarrier modulation system, but the present invention can also be applied to a multicarrier modulation system other than the OFDM system.
INDUSTRIAL APPLICABILITY The present invention can be applied to a communication system that performs communication using a multicarrier modulation method such as the OFDM method. By this application, the peak ratio can be reduced without reducing the communication speed.
[Brief description of the drawings]
FIG. 1 is a configuration diagram of a communication system according to a preferred embodiment of the present invention, FIG. 2 is a characteristic diagram of amplification factors set in the compressor 104 and the decompressor 142, and FIG. 3 is a compressor. 104 is a diagram showing the input signal (source signal), output signal (compressed signal) 104, and the peak ratio of the source signal and the compressed signal, and FIG. 4 shows signal point arrangement errors when the decompression is not performed and when the decompression is performed. FIG. 5 is a diagram illustrating the relationship between the input amplitude and the appearance frequency and the relationship between the input amplitude and the cumulative frequency. FIG. 6 is a configuration diagram of a communication system according to another embodiment of the present invention. .

Claims (6)

  A modulation signal obtained by synthesizing a plurality of carriers modulated by transmission data is input, and a first amplification factor for a signal equal to or lower than a preset threshold value and a value smaller than the first amplification factor are set. A first communication device comprising: a compressor that amplifies the modulation signal with a second amplification factor for a signal that exceeds a threshold; and a transmission unit that transmits a transmission signal obtained based on an output signal of the compressor; Second communication having receiving means for receiving a transmission signal transmitted by the transmitting means, and an expander for amplifying the signal received by the receiving means so as to be inversely transformed from amplification of the modulated signal in the compressor And a communication system.   The expander amplifies a signal equal to or less than a value obtained by multiplying the threshold value by the first amplification factor, and exceeds a value obtained by multiplying the threshold value by the first amplification factor. The communication system according to claim 1, wherein amplification is performed on a signal at a reciprocal of the second amplification factor.   The communication system according to claim 1, wherein the threshold value is set to a value within a range of 1 to 3 times the average value of the amplitude of the modulation signal.   The communication system according to claim 1, wherein the first amplification factor is a value equal to or less than 10 times the second amplification factor.   The communication system according to claim 1, wherein the modulation signal is a modulation signal obtained by an orthogonal frequency division division method.   2. The communication system according to claim 1, wherein the transmission unit transmits a transmission signal by folding the transmission signal on a power line, and the reception unit receives the transmission signal folded on the power line. .

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