JP2021077988A - Communication system, transmission device and receiving device - Google Patents

Abstract

To provide a communication system in which information transmission quality hardly lowers and efficiency of power supply hardly lowers regardless of the fact that information transmission and power supply can be performed in parallel, and provide a transmission device and a receiving device that can be used for the communication system.SOLUTION: An information wave spectral spreader 130 applies first spectral spread to an information wave generated by an information wave generator 110. A power wave spectral spreader 150 applies second spectral spread different from the first spectral spread to a power wave generated by a power wave generator 140. A first synthetic wave inverse spectral spreader 230 applies first inverse spectral spread being inverse spread of the first spectral spread to a first synthetic wave CW1 branched by a distributer 220. A second synthetic wave inverse spectral spreader 260 applies second inverse spectral spread being inverse spread of the second spectral spread to a second synthetic wave CW2 branched by the distributer 220.SELECTED DRAWING: Figure 5

Description

The present invention relates to communication systems, transmitters, and receivers.

As disclosed in Patent Document 1, there is known a communication system that wirelessly transmits information and supplies electric power. This communication system includes a transmitting device and a receiving device. The transmitting device transmits the information wave modulated by the baseband signal and the power wave having a larger effective value than the information wave to the receiving device. The receiving device reproduces the baseband signal by demodulating the information wave and obtains electric power by rectifying the power wave.

Japanese Unexamined Patent Publication No. 2011-62008

In the communication system according to Patent Document 1, information transmission and power supply are performed in a time-division manner. That is, the information wave and the power wave are alternately transmitted from the transmitting device to the receiving device. Therefore, information transmission and power supply cannot be performed in parallel.

On the other hand, when the information wave and the power wave are transmitted at the same time, the baseband signal contained in the information wave having a relatively small effective value is buried in the power wave having a relatively large effective value. It becomes difficult to reproduce the signal properly. As a result, the quality of information transmission from the transmitting device to the receiving device tends to deteriorate.

Further, as a result of adding the information wave to the electric power wave, the presence of the information wave component in the combined wave obtained by the addition may hinder the extraction of the electric power from the electric power wave component. In this case, the efficiency of supplying power from the transmitting device to the receiving device is reduced.

An object of the present invention is a communication system in which information transmission and power supply can be performed in parallel, but the quality of information transmission is not likely to be deteriorated, and the efficiency of power supply is not easily lowered. It is to provide a transmitting device and a receiving device that can be used in a communication system.

The communication system according to the first aspect of the present invention is
It is equipped with a transmitter and a receiver that are arranged across a space.
The transmitter
An information wave generator that generates an information wave modulated by a baseband signal,
A power wave generator that generates a power wave having a larger effective value than the information wave, and
A first spectrum diffuser that applies a first spectrum diffusion to the information wave generated by the information wave generator,
A second spectrum diffuser that applies a second spectrum diffusion different from the first spectrum diffusion to the power wave generated by the power wave generator.
A synthetic wave is generated by adding the information wave to which the first spectrum diffusion has been applied by the first spectrum diffuser and the power wave to which the second spectrum diffusion has been applied by the second spectrum diffuser. Synthesizer and
A transmitting antenna that transmits the combined wave generated by the synthesizer, and
Have,
The receiving device
A receiving antenna that receives the combined wave from the transmitting antenna, and
A distributor that branches the composite wave received by the receiving antenna into a first composite wave and a second composite wave having different intensities from each other.
A first inverse spectrum diffuser that applies the first inverse spectrum diffusion, which is the inverse diffusion of the first spectrum diffusion, to the first synthetic wave branched by the distributor.
A second inverse spectrum diffuser that applies a second inverse spectrum diffusion, which is the inverse diffusion of the second spectrum diffusion, to the second composite wave branched by the distributor.
Have.

The communication system according to the second aspect of the present invention is
It is equipped with a transmitter and a receiver that are arranged across a space.
The transmitter
An information wave generator that generates an information wave modulated by a baseband signal,
A power wave generator that generates a power wave having a larger effective value than the information wave, and
A spectrum diffuser that spreads a spectrum on one of the information wave generated by the information wave generator and the power wave generated by the power wave generator.
A synthesizer that generates a composite wave by adding the information wave and the power wave to which the spectrum spread is applied to one side by the spectrum diffuser.
A transmitting antenna that transmits the combined wave generated by the synthesizer, and
Have,
The receiving device
A receiving antenna that receives the combined wave from the transmitting antenna, and
A distributor that branches the composite wave received by the receiving antenna into a first composite wave and a second composite wave having different intensities from each other.
An inverse spectrum diffuser that applies reverse spectrum diffusion, which is the inverse diffusion of the spectral diffusion, to one of the first composite wave and the second composite wave branched by the distributor.
Have.

The transmitter according to the third aspect of the present invention is
An information wave generator that generates an information wave modulated by a baseband signal,
A power wave generator that generates a power wave having a larger effective value than the information wave, and
A first spectrum diffuser that applies a first spectrum diffusion to the information wave generated by the information wave generator,
A second spectrum diffuser that applies a second spectrum diffusion different from the first spectrum diffusion to the power wave generated by the power wave generator.
A synthetic wave is generated by adding the information wave to which the first spectrum diffusion has been applied by the first spectrum diffuser and the power wave to which the second spectrum diffusion has been applied by the second spectrum diffuser. Synthesizer and
A transmitting antenna that transmits the combined wave generated by the synthesizer, and
To be equipped.

The transmitter according to the fourth aspect of the present invention is
An information wave generator that generates an information wave modulated by a baseband signal,
A power wave generator that generates a power wave having a larger effective value than the information wave, and
A spectrum diffuser that spreads a spectrum on one of the information wave generated by the information wave generator and the power wave generated by the power wave generator.
A synthesizer that generates a composite wave by adding the information wave and the power wave to which the spectrum spread is applied to one side by the spectrum diffuser.
A transmitting antenna that transmits the combined wave generated by the synthesizer, and
To be equipped.

The receiving device according to the fifth aspect of the present invention is
An information wave modulated by a baseband signal and subjected to the first spectrum diffusion, and a power wave having a larger effective value than the information wave and having a second spectrum diffusion different from the first spectrum diffusion. A receiving antenna that receives the added composite wave, and
A distributor that branches the composite wave received by the receiving antenna into a first composite wave and a second composite wave having different intensities from each other.
A first inverse spectrum diffuser that applies the first inverse spectrum diffusion, which is the inverse diffusion of the first spectrum diffusion, to the first synthetic wave branched by the distributor.
A second inverse spectrum diffuser that applies a second inverse spectrum diffusion, which is the inverse diffusion of the second spectrum diffusion, to the second composite wave branched by the distributor.
To be equipped.

The receiving device according to the sixth aspect of the present invention is
It is a composite wave in which an information wave modulated by a baseband signal and a power wave having an effective value larger than that of the information wave are added, and one of the information wave and the power wave is spectrally diffused. The receiving antenna that receives the combined wave
A distributor that branches the composite wave received by the receiving antenna into a first composite wave and a second composite wave having different intensities from each other.
An inverse spectrum diffuser that applies reverse spectrum diffusion, which is the inverse diffusion of the spectral diffusion, to one of the first composite wave and the second composite wave branched by the distributor.
To be equipped.

According to the communication system according to the first aspect of the present invention, the following effects (i) and (ii) can be obtained.

(I) The composite wave transmitted from the transmitting antenna to the receiving antenna includes an information wave component and a power wave component. Therefore, information can be transmitted and power can be supplied in parallel from the transmitting device to the receiving device.

(Ii) Since the information wave is subjected to the first spectral diffusion and the electric power wave is subjected to the second spectral diffusion, both the spectral distributions of the information wave component and the electric power wave component in the synthetic wave are broadened. It becomes. Due to the first inverse spectral diffusion with respect to the first synthetic wave, the spectral distribution of the component of the information wave is sharpened while the spectral distribution of the component of the power wave is broadly spread. As a result, it is possible to prevent the information wave component from being buried in the power wave component, so that the quality of information transmission from the transmitting device to the receiving device is unlikely to deteriorate. Moreover, due to the second inverse spectral diffusion with respect to the second synthetic wave, the spectral distribution of the component of the power wave is sharpened while the spectral distribution of the component of the information wave is broadly spread. As a result, the presence of the component of the information wave is unlikely to interfere with the extraction of electric power, so that the efficiency of supplying electric power from the transmitting device to the receiving device is unlikely to decrease.

According to the communication system according to the second aspect of the present invention, the following effects (1) and (2), or effects (1) and (3) can be obtained.

(1) The composite wave transmitted from the transmitting antenna to the receiving antenna includes a component of an information wave and a component of a power wave. Therefore, information can be transmitted and power can be supplied in parallel from the transmitting device to the receiving device.

(2) When the information wave is spectrally diffused by the spectrum diffuser, the spectral distribution of the information wave component is sharpened by the inverse spectral diffusion of one of the first composite wave and the second composite wave, while the spectrum distribution is sharpened. The spectral distribution of the components of the power wave becomes broad. As a result, it is possible to prevent the information wave component from being buried in the power wave component, so that the quality of information transmission from the transmitting device to the receiving device is unlikely to deteriorate. Moreover, when the information wave is spectrally diffused by the spectrum diffuser, the spectral distribution of the information wave components is broadened in the composite wave, so that power is applied from the other side of the first composite wave and the second composite wave. At the time of extraction, the presence of the information wave component is unlikely to interfere with the extraction of power. Therefore, the efficiency of power supply from the transmitting device to the receiving device is unlikely to decrease.

(3) On the other hand, when the power wave is spectrally diffused, the spectral distribution of the power wave component is sharpened by the inverse spectral diffusion of one of the first composite wave and the second composite wave, while the spectrum distribution is sharpened. The spectral distribution of the information wave components becomes broad. Therefore, the presence of the component of the information wave is unlikely to hinder the extraction of electric power, so that the efficiency of supplying electric power from the transmitting device to the receiving device is unlikely to decrease. Moreover, when the power wave is spectrally diffused, the spectral distribution of the power wave component is broadened in the composite wave, so that the information wave component is unlikely to be buried in the power wave component. Therefore, the quality of information transmission from the transmitting device to the receiving device is unlikely to deteriorate.

The conceptual diagram which shows the structure of the communication system which concerns on Embodiment 1. FIG. (A): Conceptual diagram showing the spectral distribution of the first synthetic wave according to the first embodiment before backdiffusion, (B): Concept showing the spectral distribution of the first synthetic wave according to the first embodiment after backdiffusion. Figure. The conceptual diagram which shows the structure of the communication system which concerns on Embodiment 2. (A): Conceptual diagram showing the spectral distribution of the second synthetic wave according to the second embodiment before backdiffusion, (B): Concept showing the spectral distribution of the second synthetic wave according to the second embodiment after backdiffusion. Figure. The conceptual diagram which shows the structure of the communication system which concerns on Embodiment 3. (A): Conceptual diagram showing the spectral distribution of the synthetic wave according to the third embodiment, (B): Conceptual diagram showing the spectral distribution of the first synthetic wave according to the third embodiment after decentralization, (C): Implementation. The conceptual diagram which shows the spectral distribution of the 2nd synthetic wave which concerns on FIG. 3 after the back diffusion.

Hereinafter, the communication system according to the first to third embodiment will be described with reference to the drawings. In the figure, the same or corresponding parts are designated by the same reference numerals.

[Embodiment 1]
As shown in FIG. 1, the communication system 300A according to the present embodiment includes a transmitting device 100 and a receiving device 200 arranged so as to be spaced apart from each other in space. The transmitting device 100 transmits information and supplies electric power to the receiving device 200 in parallel using radio waves in the microwave band.

Hereinafter, the configuration of the transmission device 100 will be specifically described. The transmission device 100 includes an information wave generator 110 that generates an information wave modulated by a baseband signal. The baseband signal represents information to be transmitted from the transmitting device 100 to the receiving device 200. The information wave is a carrier modulated by a baseband signal.

Further, the transmission device 100 includes an upconverter 120 that raises the frequency of the information wave generated by the information wave generator 110 to the frequency of the microwave band.

The upconverter 120 has a local oscillator 121 and a mixer 122 that mixes the local oscillator wave generated by the local oscillator 121 with the information wave generated by the information wave generator 110.

Further, the transmission device 100 includes an information wave spectrum spreader 130 as a spectrum spreader that spreads the spectrum of the information wave whose frequency has been increased by the upconverter 120.

The information wave spectrum diffuser 130 upconverts the first diffusion signal generator 131 that generates the first diffusion signal, which is a pseudo-noise series, and the first diffusion signal generated by the first diffusion signal generator 131. It has a mixer 132 that multiplies an information wave whose frequency has been increased by 120.

That is, in the present embodiment, the direct diffusion method is adopted as the spectrum diffusion method, and “applying the spectrum diffusion to the information wave” is specifically an operation of multiplying the information wave by the first diffusion signal. Point to.

Further, the transmission device 100 includes a power wave generator 140 that generates a power wave having an effective value larger than that of the above-mentioned information wave. The power wave is responsible for the AC power supplied to the receiving device 200 and has a frequency in the microwave band.

Further, the transmitter 100 generates a composite wave by adding the information wave whose spectrum has been diffused by the information wave spectrum spreader 130 and the power wave generated by the power wave generator 140. And a transmitting antenna 170 that wirelessly transmits the synthesized wave generated by the synthesizer 160.

Next, the configuration of the receiving device 200 will be specifically described. The receiving device 200 wirelessly receives the combined wave from the transmitting antenna 170, and the combined wave received by the receiving antenna 210 is divided into a first combined wave CW1 and a second combined wave CW2 having different intensities from each other. It has a distributor 220 for branching.

The first combined wave CW1 is used for extracting the baseband signal, and the second combined wave CW2 is used for extracting the electric power. When the intensity of the first combined wave CW1 is P1 and the intensity of the second combined wave CW2 is P2, the distributor 220 branches the combined wave under the condition that P1 / P2 is 2/8 or less. In order to extract as much power as possible, P2 / P1 is preferably 1/9 or less.

Further, the receiving device 200 includes a reverse spectrum diffuser 230 for the first composite wave as a reverse spectrum diffuser that applies reverse spectrum diffusion to the first composite wave CW1 branched by the distributor 220. The inverse spectrum diffusion applied to the first composite wave CW1 by the first composite wave inverse spectrum diffuser 230 is the inverse spectrum diffusion applied to the information wave by the information wave spectrum diffuser 130 in the transmission device 100.

Specifically, the inverse spectrum diffuser 230 for the first synthetic wave is the same as the first diffusion signal generator 131 included in the transmitter 100, and the first diffusion signal generator 231 that generates the first diffusion signal described above. , The first synthetic wave CW1 is multiplied by a mixer 232 for multiplying the first diffusion signal generated by the first diffusion signal generator 231.

That is, in the present embodiment, "applying the inverse spectrum diffusion to the first composite wave CW1" specifically refers to an operation of multiplying the first composite wave CW1 by the first diffusion signal.

Further, the receiving device 200 includes a down converter 240 that lowers the frequency of the first synthetic wave CW1 in the microwave band, which has been subjected to reverse spectrum diffusion by the reverse spectrum diffuser 230 for the first synthetic wave.

The down converter 240 has a local oscillator 241 and a mixer 242 that mixes the local oscillator wave generated by the local oscillator 241 with the first synthetic wave CW1 to which the inverse spectrum is diffused.

Further, the receiving device 200 includes a baseband signal acquisition device 250 that acquires a baseband signal by demodulating the first composite wave CW1 whose frequency has been lowered by the down converter 240. The baseband signal acquisition device 250 includes a device that performs information processing according to the acquired baseband signal. For example, the baseband signal acquisition device 250 may be a display device that displays images such as moving images, still images, and character information, or a radio that outputs audio.

Further, the receiving device 200 includes a rectifier 270 that rectifies the second combined wave CW2 branched by the distributor 220. The rectifier 270 converts the second combined wave CW2 into DC power.

Further, the receiving device 200 includes a capacitor 280 that stores the DC power obtained by the rectifier 270. The electric power stored in the capacitor 280 is supplied to the baseband signal acquisition device 250. That is, the baseband signal acquisition device 250 operates by the electric power supplied from the capacitor 280.

Hereinafter, the effect of the communication system 300A according to the present embodiment will be described.

Conventionally, mainly, a time division method in which the period for transmitting information and the period for supplying electric power are different, or frequency division in which the frequency band used for transmitting information and the frequency band used for supplying electric power are different. The method was adopted.

On the other hand, in the communication system 300A according to the present embodiment, the composite wave transmitted from the transmitting antenna 170 to the receiving antenna 210 is a component of an information wave including a baseband signal representing information to be transmitted and a power wave carrying power. Including with the ingredients of.

Therefore, information can be transmitted and electric power can be supplied in parallel from the transmitting device 100 to the receiving device 200 by using a common synthetic wave. That is, according to the present embodiment, it is possible to achieve both information transmission and power supply at the same time while using the same frequency band.

Further, according to the present embodiment, since the information wave spectrum spreader 130 spreads the spectrum of the information wave, the quality of information transmission from the transmitting device 100 to the receiving device 200 is unlikely to deteriorate, and the power supply is supplied. Efficiency does not easily decrease. The reason for this will be described below.

FIG. 2A shows the spectral distribution of the first synthetic wave CW1 before the reverse spectrum diffusion by the reverse spectrum diffuser 230 for the first synthetic wave. Since the information wave spectrum diffuser 130 spreads the spectrum of the information wave, the spectral distribution S1 of the information wave component in the first synthetic wave CW1 is broader than the spectral distribution E1 of the power wave component in the first synthetic wave CW1. It is spreading to.

FIG. 2B shows the spectral distribution of the first synthetic wave CW1 after the reverse spectrum diffusion by the first synthetic wave reverse spectrum diffuser 230. Due to the inverse spectral diffusion, the spectral distribution S2 of the information wave component is sharpened more than the spectral distribution S1 of the information wave component before the inverse spectral diffusion.

Further, the inverse spectral diffusion exerts an effect equivalent to the spectral diffusion on the component of the power wave. Therefore, due to the inverse spectrum diffusion, the spectral distribution E2 of the power wave component is broader than the spectral distribution E1 of the power wave component before the inverse spectrum diffusion.

Then, as a result of the inverse spectrum diffusion, the spectral distribution S2 of the information wave component becomes sharper than the spectral distribution E2 of the power wave component. Therefore, it is possible to prevent the information wave component from being buried in the power wave component. Therefore, since the baseband signal can be appropriately extracted from the first composite wave CW1 by demodulation by the down converter 240, the quality of information transmission from the transmitting device 100 to the receiving device 200 is unlikely to deteriorate.

The intensity of the second composite wave CW2 is different from that of the first composite wave CW1, but the shape of the spectral distribution is the same as the shape of the spectral distribution shown in FIG. 2 (A). That is, since the spectrum spreader 130 for the information wave spreads the spectrum on the information wave, the spectral distribution of the component of the information wave is broader than the spectral distribution of the component of the power wave in the second composite wave CW2.

Therefore, when the electric power is extracted from the second combined wave CW2 by the rectifier 270, the presence of the component of the information wave is unlikely to hinder the extraction of the electric power. Therefore, the efficiency of power supply from the transmitting device 100 to the receiving device 200 is unlikely to decrease.

[Embodiment 2]
In the first embodiment, the transmitting device 100 spreads the spectrum of the information wave, and the receiving device 200 sharpens the component of the information wave and broadens the component of the power wave for the purpose of reproducing the baseband signal. Inverse spectrum diffusion was applied to the first composite wave CW1.

As a modification of the first embodiment, the transmitting device 100 spreads the spectrum of the power wave, and the receiving device 200 sharpens the component of the power wave and broadens the component of the information wave for the purpose of obtaining power. Inverse spectrum diffusion may be applied to the second composite wave CW2. Specific examples thereof will be described below.

As shown in FIG. 3, in the communication system 300B according to the present embodiment, the transmission device 100 is a power wave spectrum spreader 150 as a spectrum spreader that spreads the spectrum of the power wave generated by the power wave generator 140. To be equipped. On the other hand, in the present embodiment, the information wave generated by the information wave generator 110 is raised to the frequency of the microwave band by the upconverter 120 without being subjected to spectral diffusion, and then input to the synthesizer 160. To.

The power wave spectrum diffuser 150 includes a second diffusion signal generator 151 that generates a second diffusion signal that is a pseudo-noise series, and a second diffusion signal generator 151 for the power wave generated by the power wave generator 140. It has a mixer 152 for multiplying the second diffusion signal generated by.

That is, in the present embodiment, "applying spectral diffusion to a power wave" specifically refers to an operation of multiplying a power wave by a second diffusion signal.

The receiving device 200 includes a second composite wave reverse spectrum diffuser 260 as a reverse spectrum spreader that applies reverse spectrum diffusion to the second composite wave CW2 branched by the distributor 220. On the other hand, in the present embodiment, the first composite wave CW1 branched by the distributor 220 is input to the down converter 240 without being subjected to inverse spectrum diffusion.

The inverse spectrum diffusion applied to the second composite wave CW2 by the second composite wave inverse spectrum diffuser 260 is the inverse spectrum diffusion applied to the power wave by the power wave spectrum diffuser 150 in the transmission device 100.

Specifically, the reverse spectrum diffuser 260 for the second composite wave is the same as the second diffusion signal generator 151 included in the transmitter 100, and the second diffusion signal generator 261 that generates the second diffusion signal described above. , A mixer 262 that multiplies the second diffusion signal generated by the second diffusion signal generator 261 with the second composite wave CW2.

That is, in the present embodiment, "applying the inverse spectrum diffusion to the second composite wave CW2" specifically refers to an operation of multiplying the second composite wave CW2 by the second diffusion signal.

FIG. 4A shows the spectral distribution of the second composite wave CW2 before the reverse spectrum diffusion by the reverse spectrum diffuser 260 for the second composite wave. Since the power wave spectrum diffuser 150 spreads the spectrum of the power wave, the spectrum distribution E3 of the power wave component in the second composite wave CW2 is broader than the spectrum distribution S3 of the information wave component in the second composite wave CW2. It is spreading to.

FIG. 4B shows the spectral distribution of the second composite wave CW2 after the reverse spectrum diffusion by the second composite wave reverse spectrum diffuser 260. Due to the inverse spectral diffusion, the spectral distribution E4 of the power wave component is sharpened more than the spectral distribution E3 of the electric power wave component before the inverse spectral diffusion.

Further, the inverse spectrum diffusion by the inverse spectrum diffuser 260 for the second synthetic wave exerts an effect equivalent to the spectrum diffusion on the component of the information wave. Therefore, due to the inverse spectral diffusion, the spectral distribution S4 of the information wave component is broader than the spectral distribution S3 of the information wave component before the inverse spectral diffusion.

The spectral distribution E4 of the power wave component protrudes sharper than the spectral distribution S4 of the information wave component. Therefore, when the electric power is extracted from the second combined wave CW2 by the rectifier 270, the presence of the component of the information wave is unlikely to hinder the extraction of the electric power. Therefore, the efficiency of power supply from the transmitting device 100 to the receiving device 200 is unlikely to decrease.

The intensity of the first composite wave CW1 is different from that of the second composite wave CW2, but the shape of the spectral distribution is the same as the shape of the spectral distribution shown in FIG. 4 (A).

That is, since the power wave spectrum diffuser 150 spreads the spectrum of the power wave, the spectral distribution of the power wave component is broader than the spectral distribution of the information wave component in the first composite wave CW1. As a result, the spectral distribution of the information wave component is more prominent than the spectral distribution of the power wave component. That is, the peak value of the information wave component is higher than the peak value of the power wave component.

Therefore, it is possible to prevent the information wave component from being buried in the power wave component, so that the baseband signal can be appropriately extracted from the first composite wave CW1 by demodulation by the down converter 240. Therefore, the quality of information transmission from the transmitting device 100 to the receiving device 200 is unlikely to deteriorate. Other configurations and effects are the same as in the first embodiment.

[Embodiment 3]
In the first and second embodiments, the transmitting device 100 spreads the spectrum on one of the information wave and the power wave, and the receiving device 200 spreads the spectrum on one of the first composite wave CW1 and the second composite wave CW2. Was given.

As a modification of the first and second embodiments, the transmitting device 100 spreads the spectrum on both the information wave and the power wave, and the receiving device 200 applies both the first composite wave CW1 and the second composite wave CW2. Inverse spectrum diffusion may be applied. Specific examples thereof will be described below.

As shown in FIG. 5, in the communication system 300C according to the present embodiment, the transmission device 100 includes the above-mentioned spectrum spreader 130 for information waves as a first spectrum spreader that spreads the first spectrum on the information wave. The above-mentioned spectrum spreader 150 for power waves is provided as a second spectrum spreader that applies a second spectrum spread different from the first spectrum spread to the power wave.

Here, the "second spectrum diffusion different from the first spectrum diffusion" specifically means the first diffusion signal generated by the first diffusion signal generator 131 in the information wave spectrum diffuser 130 and the power wave. This means that the second diffusion signal generated by the second diffusion signal generator 151 in the spectrum diffuser 150 is pseudo noise different from each other.

The receiving device 200 includes the above-mentioned inverse spectrum diffuser 230 for the first composite wave as the first inverse spectrum diffuser that applies the first inverse spectrum diffusion, which is the inverse diffusion of the first spectrum diffusion, to the first composite wave CW1. It is provided with the above-mentioned inverse spectrum diffuser 260 for the second composite wave as the second inverse spectrum diffuser that applies the second inverse spectrum diffusion which is the inverse diffusion of the second spectrum diffusion to the second composite wave CW2.

FIG. 6A shows the spectral distribution SE of the synthetic wave obtained by the synthesizer 160. Since the information wave spectrum diffuser 130 applies the first spectrum diffusion to the information wave and the power wave spectrum diffuser 150 applies the second spectrum diffusion to the power wave, the information wave component and the power wave in the composite wave The spectral distribution SE of any of the components of is broadly spread.

FIG. 6B shows the spectral distribution of the first synthetic wave CW1 after the first reverse spectrum diffusion by the first synthetic wave reverse spectrum diffuser 230. Due to the first inverse spectral diffusion with respect to the first synthetic wave CW1, the spectral distribution S5 of the component of the information wave remains spread broadly as in the spectral distribution ES shown in FIG. 6 (A). It will be sharpened. As a result, the spectral distribution S5 of the component of the information wave is more prominent than the spectral distribution E5 of the component of the power wave. That is, the peak value of the information wave component is higher than the peak value of the power wave component.

Therefore, it is possible to prevent the information wave component from being buried in the power wave component, so that the baseband signal can be appropriately extracted from the first composite wave CW1 by demodulation by the down converter 240. Therefore, the quality of information transmission from the transmitting device 100 to the receiving device 200 is unlikely to deteriorate.

FIG. 6C shows the spectral distribution of the second composite wave CW2 after the second reverse spectrum diffusion by the second composite wave reverse spectrum diffuser 260. Due to the second inverse spectral diffusion with respect to the second synthetic wave CW2, the spectral distribution S6 of the component of the information wave remains broadly spread like the spectral distribution ES shown in FIG. 6 (A), and the spectral distribution E6 of the component of the power wave becomes. It will be sharpened. As a result, the spectral distribution E6 of the power wave component is more prominent than the spectral distribution S6 of the information wave component. That is, the peak value of the power wave component is higher than the peak value of the information wave component.

Therefore, when the electric power is extracted from the second combined wave CW2 by the rectifier 270, the presence of the component of the information wave is unlikely to hinder the extraction of the electric power. Therefore, the efficiency of power supply from the transmitting device 100 to the receiving device 200 is unlikely to decrease.

The first to third embodiments have been described above. The modifications described below are also possible.

In the configuration shown in FIG. 5, the first composite wave is subjected to the first inverse spectrum diffusion by the first composite wave reverse spectrum diffuser 230 between the first composite wave reverse spectrum diffuser 230 and the down converter 240. A bandpass filter that removes at least a part of the spectral distribution E5 of the power wave component may be arranged from the CW1 while leaving the spectral distribution S5 of the information wave component shown in FIG. 6 (B). The same applies to the configuration shown in FIG.

In the configuration shown in FIG. 5, the second composite wave CW2 in which the second inverse spectrum diffusion is performed by the second composite wave inverse spectrum diffuser 260 between the second composite wave inverse spectrum diffuser 260 and the rectifier 270. Therefore, a bandpass filter that removes at least a part of the spectral distribution S6 of the information wave component may be arranged while leaving the spectral distribution E6 of the power wave component shown in FIG. 6 (C). The same applies to the configuration shown in FIG.

In the above-described first to third embodiments, the direct spreading method is adopted as the spread spectrum method, but the frequency hopping method may be adopted as the spread spectrum method.

In the above embodiment 1-3, the modulation performed by the information wave generator 110 is not limited to the amplitude modulation including the amplitude shift keying, and is known modulation such as frequency modulation including frequency shift keying and phase modulation including phase shift keying. The method can be used. The baseband signal acquisition device 250 performs demodulation corresponding to the modulation performed by the information wave generator 110.

100 ... Transmitter,
110 ... Information wave generator,
120 ... Upconverter,
121 ... Local oscillator,
122 ... Mixer,
130 ... Spectral diffuser for information wave (spectral diffuser, first spectrum diffuser),
131 ... 1st diffusion signal generator,
132 ... Mixer,
140 ... Power wave generator,
150 ... Spectral diffuser for power wave (spectral diffuser, second spectrum diffuser),
151 ... Second diffusion signal generator,
152 ... Mixer,
160 ... synthesizer,
170 ... Transmit antenna,
200 ... Receiver,
210 ... Receiving antenna,
220 ... Distributor,
230 ... Inverse spectrum diffuser for the first synthetic wave (inverse spectrum diffuser, first inverse spectrum diffuser),
231 ... 1st diffusion signal generator,
232 ... Mixer,
240 ... Down converter,
241 ... Local oscillator,
242 ... Mixer,
250 ... Baseband signal acquisition device,
260 ... Inverse spectrum diffuser for second synthetic wave (inverse spectrum diffuser, second inverse spectrum diffuser),
261 ... Second diffusion signal generator,
262 ... Mixer,
270 ... Rectifier,
280 ... Capacitor,
300A, 300B, 300C ... Communication system,
CW1 ... 1st synthetic wave,
CW2 ... 2nd synthetic wave,
E1, E2, E3, E4, E5, E6 ... Spectral distribution of power wave components,
S1, S2, S3, S4, S5, S6 ... Spectral distribution of information wave components,
SE: Spectral distribution of synthetic waves.

Claims (6)

It is equipped with a transmitter and a receiver that are arranged across a space.
The transmitter
An information wave generator that generates an information wave modulated by a baseband signal,
A power wave generator that generates a power wave having a larger effective value than the information wave, and
A first spectrum diffuser that applies a first spectrum diffusion to the information wave generated by the information wave generator,
A second spectrum diffuser that applies a second spectrum diffusion different from the first spectrum diffusion to the power wave generated by the power wave generator.
A synthetic wave is generated by adding the information wave to which the first spectrum diffusion has been applied by the first spectrum diffuser and the power wave to which the second spectrum diffusion has been applied by the second spectrum diffuser. Synthesizer and
A transmitting antenna that transmits the combined wave generated by the synthesizer, and
Have,
The receiving device
A receiving antenna that receives the combined wave from the transmitting antenna, and
A distributor that branches the composite wave received by the receiving antenna into a first composite wave and a second composite wave having different intensities from each other.
A first inverse spectrum diffuser that applies the first inverse spectrum diffusion, which is the inverse diffusion of the first spectrum diffusion, to the first synthetic wave branched by the distributor.
A second inverse spectrum diffuser that applies a second inverse spectrum diffusion, which is the inverse diffusion of the second spectrum diffusion, to the second composite wave branched by the distributor.
A communication system. It is equipped with a transmitter and a receiver that are arranged across a space.
The transmitter
An information wave generator that generates an information wave modulated by a baseband signal,
A power wave generator that generates a power wave having a larger effective value than the information wave, and
A spectrum diffuser that spreads a spectrum on one of the information wave generated by the information wave generator and the power wave generated by the power wave generator.
A synthesizer that generates a composite wave by adding the information wave and the power wave to which the spectrum spread is applied to one side by the spectrum diffuser.
A transmitting antenna that transmits the combined wave generated by the synthesizer, and
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The receiving device
A receiving antenna that receives the combined wave from the transmitting antenna, and
A distributor that branches the composite wave received by the receiving antenna into a first composite wave and a second composite wave having different intensities from each other.
An inverse spectrum diffuser that applies reverse spectrum diffusion, which is the inverse diffusion of the spectral diffusion, to one of the first composite wave and the second composite wave branched by the distributor.
A communication system. An information wave generator that generates an information wave modulated by a baseband signal,
A power wave generator that generates a power wave having a larger effective value than the information wave, and
A first spectrum diffuser that applies a first spectrum diffusion to the information wave generated by the information wave generator,
A second spectrum diffuser that applies a second spectrum diffusion different from the first spectrum diffusion to the power wave generated by the power wave generator.
A synthetic wave is generated by adding the information wave to which the first spectrum diffusion has been applied by the first spectrum diffuser and the power wave to which the second spectrum diffusion has been applied by the second spectrum diffuser. Synthesizer and
A transmitting antenna that transmits the combined wave generated by the synthesizer, and
A transmitter. An information wave generator that generates an information wave modulated by a baseband signal,
A power wave generator that generates a power wave having a larger effective value than the information wave, and
A spectrum diffuser that spreads a spectrum on one of the information wave generated by the information wave generator and the power wave generated by the power wave generator.
A synthesizer that generates a composite wave by adding the information wave and the power wave to which the spectrum spread is applied to one side by the spectrum diffuser.
A transmitting antenna that transmits the combined wave generated by the synthesizer, and
A transmitter. An information wave modulated by a baseband signal and subjected to the first spectrum diffusion, and a power wave having a larger effective value than the information wave and having a second spectrum diffusion different from the first spectrum diffusion. A receiving antenna that receives the added composite wave, and
A distributor that branches the composite wave received by the receiving antenna into a first composite wave and a second composite wave having different intensities from each other.
A first inverse spectrum diffuser that applies the first inverse spectrum diffusion, which is the inverse diffusion of the first spectrum diffusion, to the first synthetic wave branched by the distributor.
A second inverse spectrum diffuser that applies a second inverse spectrum diffusion, which is the inverse diffusion of the second spectrum diffusion, to the second composite wave branched by the distributor.
A receiving device. It is a composite wave in which an information wave modulated by a baseband signal and a power wave having an effective value larger than that of the information wave are added, and one of the information wave and the power wave is spectrally diffused. The receiving antenna that receives the combined wave
A distributor that branches the composite wave received by the receiving antenna into a first composite wave and a second composite wave having different intensities from each other.
An inverse spectrum diffuser that applies reverse spectrum diffusion, which is the inverse diffusion of the spectral diffusion, to one of the first composite wave and the second composite wave branched by the distributor.
A receiving device.

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