JP4347411B1 - Transmitting apparatus and transmitting method - Google Patents

Abstract

An object of the present invention is to prevent a user from being aware of channel selection when using broadcast content in a portable device.
In a one-segment transmitter 1, a signal of, for example, 15Ch, which is one of channels 13 to 52Ch, is generated by a high-frequency signal transmitter and modulated based on a baseband signal of content to be transmitted. The Further, by performing frequency conversion processing on the modulated 15Ch signal, signals of each channel of 13, 14, 16 to 52Ch other than 15Ch are generated, and the intensity of 35 .mu.V / Transmitted using radio waves with intensity of m or less. The mobile device 2 can receive content regardless of which channel of the one-segment broadcasting is selected as long as the mobile device 2 is within the reach of radio waves. The present invention can be applied to a device that transmits radio waves of one-segment broadcasting.
[Selection] Figure 1

Description

  The present invention relates to a transmission device and a transmission method, and more particularly, to a transmission device and a transmission method that prevent a user from being aware of channel selection when content suitable for distribution in a broadcast format is received by a mobile device.

  In recent years, portable devices compatible with one-segment broadcasting have become widespread. In one-segment broadcasting, the UHF band of 470 to 710 MHz is divided into 40 channels of 13 to 52 Ch, and the frequency bandwidth of one channel, 6 MHz, is divided into 13 segments. This is a broadcast for mobile devices that is used.

  With the widespread use of one-segment broadcast compatible mobile devices, a system that provides services for users with such one-segment broadcast compatible mobile devices has been proposed or realized.

  Patent Document 1 describes a system that performs one-segment broadcasting limited to a region.

  Patent Document 2 discloses a system that divides a wide area into areas such as several kilometers and broadcasts contents specialized for each area.

  Patent Document 3 discloses a system for distributing odds information by forming a narrower area of several hundred meters in a public racetrack or the like.

  The regional broadcasting / information service using such one-segment broadcasting technology is a very useful new service, but in order to receive the service, the user first scans a receivable channel. For example, it is necessary to set a channel in the area.

  In addition, the user needs to perform an operation of selecting a channel on which the service is provided. When the user selects the channel, reception of radio waves of the selected channel is started in the mobile device, Get information carried by the received radio waves.

  Patent Document 4 discloses a technique that eliminates the need for scanning for channel setting by storing in a portable device a list in which information relating channel information and broadcast content is described.

JP 2006-279376 A JP 2007-295341 A JP 2008-97389 A JP 2008-153955 A

  Even if scanning for channel setting is unnecessary, depending on the technique described in Patent Document 4, in order to view and use the content provided by one-segment broadcasting, the user must select a channel. Need to do.

  The present invention has been made in view of such a situation, and prevents the user from being conscious of channel selection when the broadcast content is used in a portable device.

The transmission device of the present invention is a transmission device that transmits information by broadcasting in which a channel interval is defined at a constant frequency interval, and a high-frequency signal generation unit that generates a high-frequency signal having the same frequency as a predetermined channel ; The frequency corresponding to the interval between the channels is a fundamental frequency, and the harmonic generation means for generating a signal having the harmonic component thereof , the high frequency signal, and the signal having the harmonic component generated by the harmonic generation means And a transmission means for transmitting a signal resulting from the multiplication by the multiplication means as a new high-frequency signal.

  Filter means for removing or passing a signal of a predetermined frequency band included in the signal resulting from the multiplication by the multiplication means can be further provided.

  An amplitude adjusting means for adjusting the amplitude of the signal resulting from the multiplication by the multiplying means can be further provided.

The high-frequency signal generation means includes a first high-frequency signal generation means for generating a first high-frequency signal having the same frequency as a predetermined channel, and a first high-frequency signal generation of a baseband signal of content to be transmitted. First modulation means for modulating based on the first high-frequency signal generated by the means, and a second frequency difference between the first high-frequency signal and the center frequency by the same frequency as the frequency corresponding to the interval of each channel . Second high-frequency signal generating means for generating a high-frequency signal, and second baseband signal for modulating the baseband signal of the content to be transmitted based on the second high-frequency signal generated by the second high-frequency signal generating means modulating means, said first high-frequency modulated signal, adding the second high-frequency modulated signal, adding means for outputting a signal of addition result as the high-frequency signal It can be constructed from.

The transmission method of the present invention is a transmission method of a transmission apparatus that transmits information by broadcasting in which channel intervals are defined at constant frequency intervals, and generates a high-frequency signal having the same frequency as a predetermined one channel. A frequency corresponding to the interval is set as a fundamental frequency , a signal having the harmonic component is generated , the high-frequency signal and the signal having the harmonic component are multiplied, and the multiplication result signal is transmitted as a new high-frequency signal. Includes steps.

In the transmission apparatus or transmission method of the present invention, a high-frequency signal having the same frequency as that of a predetermined channel is generated, and a signal having a harmonic component having a frequency corresponding to the interval between the channels as a fundamental frequency is generated. The high-frequency signal and the signal having the harmonic component are multiplied, and the multiplication result signal is transmitted as a new high-frequency signal.

  “High frequency” refers to electromagnetic waves having a frequency of 3 million megahertz or less.

  “Harmonic” refers to a higher-order frequency component or frequency that is an integral multiple of a wave having a certain frequency component. “Fundamental wave” refers to the original wave or frequency that is the basis of a harmonic.

  According to the present invention, it is possible to prevent the user from being aware of channel selection when using broadcast content in a mobile device.

It is a figure which shows the example of the reach | attainment range of the electromagnetic wave which the one segment transmitter which concerns on one Embodiment of this invention transmits. It is a figure which shows the example of transmission of a content. It is a figure which shows the relationship between the frequency and intensity | strength of an electromagnetic wave. It is a figure which shows the relationship between the physical channel and frequency of terrestrial digital broadcasting. It is a figure which shows the concept of the transmission of the content by the one segment transmitter. It is a figure which shows the concept of transmission of a content. It is a block diagram which shows the structural example of a one segment transmitter. It is a block diagram which shows the structural example of the signal processing part of FIG. It is a block diagram which shows the structural example of the high frequency signal generation part of FIG. It is a figure which shows the example on the time-axis waveform and frequency spectrum of a high frequency signal. It is a figure which shows the example on the time-axis of a rectangular wave, and a frequency spectrum. It is a figure which shows the example on the time-axis waveform and frequency spectrum of another rectangular wave. It is a flowchart explaining the transmission process of a one segment transmitter. It is a block diagram which shows the other structural example of a signal processing part. It is a figure which shows the example of BPF. It is a figure which shows the example of the signal used as the object of filtering using BPF, and the signal after filtering. It is a figure which shows the example of BEF. It is a figure which shows the example of the signal used as the object of filtering using BEF, and the signal after filtering. It is a flowchart explaining the other transmission processing of a one segment transmitter. It is a block diagram which shows the further another example of a structure of a signal processing part. It is a figure which shows the example of a frequency spectrum. It is a flowchart explaining the further another transmission process of a one segment transmitter. It is a figure which shows the example of the center frequency of a high frequency signal. It is a figure which shows the example of the frequency spectrum of a weak radio wave. It is a figure explaining the example which uses the high frequency received signal from the outside as a function of a high frequency signal generation part.

<First Embodiment>
FIG. 1 is a diagram showing an example of the reach of radio waves transmitted by a one-segment transmitter 1 according to an embodiment of the present invention.

The one-segment transmitter 1 is a device that transmits content to the portable device 2 or the like in the area A ₁ that is the reach of radio waves using radio waves used in one-segment broadcasting.

  As shown in FIG. 2, for the one-segment transmitter 1, predetermined content (information) such as video content to be transmitted is transmitted via a recording medium such as a memory card or a LAN (Local Area Network). ) And other networks. The one segment transmitter 1 transmits the same content using the radio waves of all channels of the one segment broadcast. Content is played back on the mobile device 2, and the user can view and use it.

  The radio wave output from the one-segment transmitter 1 is not limited to a strong one that covers several hundreds of meters or several kilometers as shown in Patent Documents 2 and 3, and does not require a license to install a radio station. “Weak radio waves” may be used.

  The “weak radio wave” here is the range stipulated in “Radio stations with extremely weak radio waves (hereinafter referred to as weak radio stations)” that do not require a license, as stipulated in laws and regulations related to the Ministry of Internal Affairs and Communications. It is a radio wave output by the radio equipment. By providing and operating a weak radio station, it is not necessary to obtain a license for the radio station, and broadcasting / information services can be provided early.

  Hereinafter, radio waves having a strength that does not require a license for installation of radio stations are simply referred to as weak radio waves.

  FIG. 3 is a diagram showing the relationship between the frequency and intensity of radio waves.

  The horizontal axis in FIG. 3 represents frequency, and the vertical axis represents intensity. As shown in FIG. 3, the strength of radio waves that do not require a license is defined according to the frequency as the electric field strength at a position 3 m away from the radio station that outputs the radio waves.

  For example, in a frequency band of 0 kHz to 322 MHz or less, a license is not required if the electric field strength at a position 3 m away from the radio station is always 500 μV / m or less.

  In the frequency band exceeding 322 MHz and 10 GHz or less, a license is not required if the intensity of the radio wave at a position 3 m away from the wireless station is always 35 μV / m or less. The frequency of radio waves used for one-segment broadcasting based on the ISDB-T terrestrial digital broadcasting standard is 470 to 710 MHz in the UHF band, so when using radio waves of the same frequency, the intensity at a position 3 m away from the radio station If it is 35μV / m or less, no license is required.

  FIG. 4 is a diagram showing the relationship between physical channels and frequencies of terrestrial digital broadcasting.

  As shown in FIG. 4, terrestrial digital broadcasting is performed by dividing the UHF band of 470 to 710 MHz into 40 physical channels and setting each physical channel to 13 to 52 Ch. The interval between the center frequencies of the physical channels is 6 MHz, such as between the frequencies fu13 and fu14, between fu14 and fu15,..., Between fu51 and fu52.

  In one-segment broadcasting based on the ISDB-T terrestrial digital broadcasting standard, the relationship between the physical channel and the frequency is defined in this way. One-segment broadcasting is performed using one segment located in the center as viewed in the frequency direction among the 13 segments constituting each physical channel.

  The one segment transmitter 1 transmits the content to be transmitted by weak radio waves of all physical channels 13 to 52Ch.

  FIG. 5 is a diagram showing the concept of content transmission by the one-segment transmitter 1.

  As shown in FIG. 5, the one-segment transmitter 1 generates, for example, a 15Ch signal, which is one of channels 13 to 52Ch, using a high-frequency signal transmitter, and based on the baseband signal of the content to be transmitted. Modulate.

  The one-segment transmitter 1 performs frequency conversion processing on the modulated 15Ch signal to generate signals for channels 13, 14, 16 to 52Ch other than 15Ch, and is licensed to install a radio station. Transmit using radio waves with an intensity of 35 μV / m or less, which is unnecessary intensity.

  By transmitting the same content using all the channels, the mobile device 2 can transmit the content regardless of which channel of the one-segment broadcasting is selected as long as it is within the radio wave reachable range. It becomes possible to receive. The received content is reproduced on the portable device 2 and presented to the user.

  That is, the user of the portable device 2 can use the content not only by receiving 15Ch of the physical channel but also by receiving 13Ch, for example, and can also use the content by receiving 50Ch.

  Thereby, when using the content transmitted by the one-segment transmitter 1 using the portable device 2, the user does not need to perform channel setting by scanning a receivable channel.

  In addition, since the content can be used regardless of which channel is selected, the user does not need to be aware of the channel selection.

Since it is sufficient to mount one transmitter that generates one channel signal as a source signal for generating all channel signals, the configuration of the one-segment transmitter 1 can be simplified. . The 15Ch transmitter in FIG. 5 is a device that generates a signal with a predetermined bandwidth for one channel of one-segment broadcasting having a center frequency of 485.143 MHz.

  For example, as shown in FIG. 6, it is possible to generate a 40-channel signal by installing 40 transmitters. However, implementation with such a method is clearly uneconomical, Poor feasibility. On the other hand, in the method shown in FIG. 5 described in the embodiment of the present invention, only one transmitter is prepared, and signals for 40 channels are generated based on the signal generated by the transmitter. By doing so, the one-segment transmitter 1 can be reduced in size.

[Configuration of one-segment transmitter 1]
FIG. 7 is a block diagram illustrating a configuration example of the one-segment transmitter 1.

  As shown in FIG. 7, the one-segment transmitter 1 includes a content reproduction unit 11, a signal processing unit 12, a transmission unit 13, and an antenna 14.

  The content reproduction unit 11 acquires and reproduces content input via a recording medium or a network. The content reproduction unit 11 decodes the content encoded in a predetermined format, and outputs the content baseband signal to the signal processing unit 12.

  The signal processing unit 12 generates signals for 40 channels of one-segment broadcasting for transmitting the target content. The signal processing unit 12 outputs the generated signal to the transmission unit 13.

  The transmission unit 13 transmits the signal supplied from the signal processing unit 12 from the antenna 14 using weak radio waves.

  FIG. 8 is a block diagram illustrating a configuration example of the signal processing unit 12 of FIG.

  As shown in FIG. 8, the signal processing unit 12 includes a high frequency signal generation unit 21, a rectangular wave signal generation unit 22, and a mixer unit 23. The baseband signal output from the content reproduction unit 11 is input to the high frequency signal generation unit 21.

  The high frequency signal generation unit 21 generates a high frequency signal having the frequency of any physical channel among 13 to 52Ch, and modulates the baseband signal of the content to be transmitted based on the generated high frequency signal. The high frequency signal generation unit 21 outputs the modulated high frequency signal to the mixer unit 23. The high frequency signal generator 21 corresponds to one transmitter shown in FIG.

  The rectangular wave signal generator 22 generates a signal having a harmonic component of 6 MHz that is the interval between the center frequencies of the physical channels. The rectangular wave signal generation unit 22 generates a rectangular wave having a fundamental frequency of 6 MHz, for example, as such a signal and outputs the rectangular wave to the mixer unit 23.

  The mixer unit 23 performs analog multiplication (multiplication in the time domain) of the modulated high-frequency signal supplied from the high-frequency signal generation unit 21 and the rectangular wave generated by the rectangular wave signal generation unit 22, and the multiplication result signal Is output to the transmitter 13.

  If the frequency of the high-frequency signal generated by the high-frequency signal generator 21 is fMHz and the fundamental frequency of the rectangular wave generated by the rectangular wave signal generator 22 is sMHz, the output from the mixer unit 23 is the sum of the two input signals. This is a frequency series signal of f, f ± s, f ± 2s, f ± 3s,. The fundamental frequency s of the rectangular wave is 6 MHz, which is the interval between the center frequencies of the physical channels.

  FIG. 9 is a block diagram illustrating a configuration example of the high-frequency signal generation unit 21 of FIG.

  As shown in FIG. 9, the high frequency signal generator 21 includes a modulator 31 and a signal generator 32.

  The modulation unit 31 modulates the baseband signal supplied from the content reproduction unit 11 based on the high frequency signal supplied from the signal generation unit 32, and outputs the modulated high frequency signal to the mixer unit 23.

  The signal generation unit 32 generates a high-frequency signal having the frequency of any physical channel among 13 to 52 Ch, and outputs the high-frequency signal to the modulation unit 31.

  FIG. 10 is a diagram illustrating an example of a waveform and a frequency spectrum of a high-frequency signal generated by the signal generation unit 32.

As shown in FIG. 10A, a high-frequency signal represented as a sine wave on the time axis is generated by the signal generation unit 32. The high frequency signal e (t) is expressed by the following equation (1). ω ₀ is represented by ω ₀ = 2πs. s is 6 MHz which is the interval between the center frequencies of the physical channels.

The frequency spectrum of the high frequency signal is shown in FIG. 10B. As shown in FIG. 10B, the high frequency signal generated by the signal generating unit 32 does not include any frequency component other than ω ₀ . Such a high-frequency signal is modulated, and the modulated high-frequency signal is output to the mixer unit 32.

  FIG. 11 is a diagram illustrating an example of the waveform and frequency spectrum of a rectangular wave generated by the rectangular wave signal generation unit 22.

As shown in FIG. 11A, a rectangular wave having a predetermined ratio in which a duty ratio that is a ratio obtained by dividing a period of 1 by a period of one period of the rectangular wave is not 50% is a rectangular wave signal generator. 22 is generated. The duty ratio of the rectangular wave in FIG. 11A is 50% or less. The rectangular wave e (t) in FIG. 11A is expressed by the following equation (2).

An example of the frequency spectrum of a rectangular wave is shown in FIG. 11B. As shown in FIG. 11B, the rectangular wave generated by the rectangular wave signal generation unit 22 includes even-order harmonic components and odd-order harmonic components. The intensity of each frequency component included in the rectangular wave becomes weaker as the frequency becomes higher.

The Fourier series S (ω) of the rectangular wave is expressed by the following equation (3). n is an integer of 1 or more.

  Thus, by generating a rectangular wave having a predetermined duty ratio that is not 50% and performing analog multiplication with a high-frequency signal having a frequency of any physical channel of 13 to 52 Ch, each of 6 MHz intervals is obtained. It becomes possible to generate a signal having a frequency component. As the frequency band of the reference high-frequency signal becomes farther from the frequency, the intensity becomes weaker, but the signal resulting from the multiplication by the mixer unit 23 includes frequency components for 40 channels of 13 to 52 Ch.

  FIG. 12 is a diagram showing the waveform and frequency spectrum of a rectangular wave when τ = π and the duty ratio is 50%.

FIG. 12A shows a waveform of a rectangular wave having a fundamental frequency s and a duty ratio of 50%. This rectangular wave is expressed by the following expression (4).

A frequency spectrum of a rectangular wave having a duty ratio of 50% is shown in FIG. 12B. As shown in FIG. 12B, the rectangular wave having a duty ratio of 50% includes odd-order harmonic components but does not include even-order harmonic components. If such a rectangular wave is used for multiplication with the high-frequency signal generated by the high-frequency signal generation unit 21, the multiplication result signal includes only the physical channel components of every other channel among 13 to 52Ch. No signal. The Fourier series S (ω) of a rectangular wave with a duty ratio of 50% is shown in the following formula (5).

[Operation of one-segment transmitter 1]
Here, the processing of the one-segment transmitter 1 having the above configuration will be described with reference to the flowchart of FIG.

  This process is started, for example, when content to be transmitted is input to the one-segment transmitter 1 and an instruction to start content transmission is given.

  In step S1, the content playback unit 11 plays back the content to be transmitted.

  In step S2, the signal generation unit 32 (FIG. 9) of the signal processing unit 12 generates a high-frequency signal having the frequency of any physical channel among 13 to 52Ch.

  In step S3, the modulation unit 31 modulates the baseband signal of the content to be transmitted based on the high frequency signal.

  In step S4, the rectangular wave signal generator 22 generates a rectangular wave having a predetermined duty ratio that is not 50%.

  In step S5, the mixer unit 23 performs analog multiplication of the modulated high-frequency signal and the rectangular wave.

  In step S <b> 6, the transmission unit 13 transmits the multiplication result signal from the antenna 14 using weak radio waves. While the content is being transmitted, the above processing is repeatedly executed. When it is instructed to end the transmission of the content, the process ends.

  In the mobile device 2 that has received the weak radio wave, the RF signal of the channel that is being received at that time is demodulated, and a baseband signal is acquired. In addition, content video is displayed on a display unit such as an LCD (Liquid Crystal Display) based on a baseband signal, or content audio is output from a speaker.

  With the above processing, the user of the mobile device 2 can use the content transmitted from the one-segment transmitter 1 only by receiving any one-segment broadcast channel without being aware of the channel selection. can do.

  FIG. 13 is a flowchart for explaining the processing of the one-segment transmitter 1 step by step. In a service as an actual broadcasting / information distribution form, a series of processing after content reproduction is always performed. , The content is being sent.

  Since the intensity of the radio wave used for providing the service is an intensity that does not require a license for installing a radio station, the administrator of the one-segment transmitter 1 can easily realize a content providing service using one-segment broadcasting. It becomes possible.

  The content providing service using the one-segment transmitter 1 covers, for example, an entire restaurant such as a restaurant having a radius of several meters to several tens of meters, or a section of each table or product display corner. As done.

  The target service area may be performed for the entire space of movie theaters, trains, etc., or for each of those seats, or for the entire museum, museum floor, or around each exhibit. This may be performed for a limited area.

  The one-segment transmitter 1 can also be used for testing one-segment broadcasting compatible equipment. For example, when verifying whether the receiver of one-segment broadcasting is operating normally by making the receiver actually receive radio waves, it can be verified by using the one-segment transmitter 1 as the transmitter of one-segment broadcasting. It becomes possible to carry out easily.

Such services, by acquiring the radio station license uses unnecessary weak radio wave, the area A ₁ shown in FIG. 1 not only performed in such a limited area, in Patent Documents 2 and 3 It can also be applied to services in a wide area on the premise of obtaining a radio station license as shown.

<Second Embodiment>
[Configuration of one-segment transmitter 1]
FIG. 14 is a block diagram illustrating another configuration example of the signal processing unit 12.

  In FIG. 14, the same components as those shown in FIG. The overlapping description will be omitted as appropriate. The configuration of the signal processing unit 12 illustrated in FIG. 14 is different from the configuration illustrated in FIG. 8 in that a filter / amplitude adjustment unit 41 is additionally provided.

  The filter / amplitude adjustment unit 41 filters the signal resulting from the multiplication by the mixer unit 23.

  FIG. 15 is a diagram illustrating an example of a BPF (Band Pass Filter) used by the filter / amplitude adjustment unit 41.

  The BPF in FIG. 15 is a filter having a center frequency f and a bandwidth of 2 s, and allows a signal in a frequency band from fs to f + s to pass through. By filtering the signal represented by the frequency spectrum as shown in FIG. 16A using the BPF shown in FIG. 15, only the signal included in the frequency fs to f + s band as shown in FIG. 16B is obtained. It is possible to pass through.

  16A represents the frequency spectrum of the input signal to the filter / amplitude adjustment unit 41, and FIG. 16B represents the frequency spectrum of the output signal from the filter / amplitude adjustment unit 41. The solid arrow in FIG. 16B represents the frequency spectrum of the signal passing through the filter, and the dotted arrow represents the frequency spectrum of the signal whose passage is limited by the filter.

  FIG. 17 is a diagram showing an example of a BEF (Band Elimination Filter) used by the filter / amplitude adjustment unit 41.

  The BEF in FIG. 17 is a filter having a center frequency f and a bandwidth 2s, and removes a signal in a band of frequencies f−s to f + s. By filtering the signal represented by the frequency spectrum as shown in FIG. 18A using the BEF shown in FIG. 17, the signal in the band of frequency f−s is removed from the frequency f−s as shown in FIG. 18B. It is possible to pass other signals.

  18A shows the frequency spectrum of the input signal to the filter / amplitude adjustment unit 41, and FIG. 18B shows the frequency spectrum of the output signal from the filter / amplitude adjustment unit 41. The solid line arrow in FIG. 18B represents the frequency spectrum of the signal passing through the filter, and the dotted line arrow represents the frequency spectrum of the signal removed by the filter.

  The filter / amplitude adjustment unit 41 performs filtering using such BPF or BEF.

  By performing filtering using BPF, it is possible to use a frequency sequence of continuous channels as a carrier wave signal of content.

  Also, by filtering using BEF, it is possible not to use the frequency band used in the existing one-segment broadcasting, but to use a frequency sequence limited to only a vacant frequency band as a carrier signal for content. It becomes possible.

  Each physical channel of 13 to 52 Ch is assigned to a broadcasting station or the like. Even if the broadcast is intended for a narrow range such as a few meters in radius, it is also assumed that a broadcast station that does not allow the one-segment transmitter 1 to output the radio wave of the channel assigned to itself appears. It is necessary not to output radio waves of channels used by such broadcasting stations.

  Respond to broadcaster requests by restricting the passage of signals of channels assigned to broadcasting stations that are not allowed to output radio waves using BPF or removing the signals using BEF It becomes possible.

  Further, the filter / amplitude adjustment unit 41 adjusts the amplitude of the multiplication result signal appropriately subjected to filtering.

  As described above, when the intensity of the radio wave output from the one-segment transmitter 1 is set to the weak radio wave range that does not require a license for installation of the radio station, the filter / amplitude adjustment unit 41 uses the one-segment transmitter. The amplitude is adjusted so that the intensity of the output radio wave from 1 satisfies the restriction stipulated in related laws and regulations such as the Radio Law.

  In addition, when it is assumed that a radio station license is acquired instead of using weak radio waves, the amplitude is set so that the radio wave output specified there is obtained.

  Further, as described with reference to FIG. 11B, the intensity of each frequency component included in the rectangular wave generated by the rectangular wave signal generator 22 becomes weaker as the frequency becomes higher. The signal resulting from the multiplication of the rectangular wave and the high-frequency signal also becomes weaker and the amplitude becomes smaller as the frequency increases when the intensity of the component is seen for each frequency band.

  For example, the filter / amplitude adjustment unit 41 adjusts the amplitude so that the amplitude of the signal in the low frequency band and the amplitude of the signal in the high frequency band are substantially constant.

  The circuit constituting the filter / amplitude adjustment unit 41 may be constituted by an analog circuit that performs the above filtering and amplitude adjustment processing by an analog method, or may be constituted by a digital circuit that is performed by a digital method. It may be. Further, it may be configured by a circuit in which an analog circuit and a digital circuit are mixed.

  Further, the BPF and BEF of FIG. 15 and FIG. 17 constituting the filter / amplitude adjustment unit 41 show an example, and a plurality of LPFs are realized so as to realize a combination of a plurality of passbands and a plurality of stopbands. (Low Pass Filter) or a combination circuit of a plurality of HPFs (High Pass Filters) may be used.

[Operation of one-segment transmitter 1]
Processing of the one-segment transmitter 1 having the signal processing unit 12 having the configuration shown in FIG. 14 will be described with reference to the flowchart of FIG.

  The process of FIG. 19 is the same as the process described with reference to FIG. 13 except that filtering and amplitude adjustment processes are added.

  In step S11, the content reproduction unit 11 reproduces the content to be transmitted.

  In step S12, the signal generator 32 of the signal processor 12 generates a high frequency signal.

  In step S13, the modulation unit 31 modulates the baseband signal of the content to be transmitted based on the high frequency signal.

  In step S14, the rectangular wave signal generator 22 generates a rectangular wave having a predetermined duty ratio that is not 50%.

  In step S15, the mixer unit 23 performs analog multiplication of the modulated high-frequency signal and a rectangular wave.

  In step S <b> 16, the filter / amplitude adjustment unit 41 filters the signal resulting from the multiplication by the mixer unit 23 using BPF or BEF as described above.

  In step S <b> 17, the filter / amplitude adjustment unit 41 adjusts the amplitude of the signal obtained by performing the filtering.

  In step S18, the transmission unit 13 transmits the amplitude-adjusted signal from the antenna 14 using a weak radio wave, and ends the process.

<Third Embodiment>
[Configuration of one-segment transmitter 1]
FIG. 20 is a block diagram illustrating still another configuration example of the signal processing unit 12.

  The configuration of the signal processing unit 12 shown in FIG. 20 includes a high-frequency signal generating unit 51 as a first high-frequency signal generating unit and a high-frequency signal generating unit 52 as a second high-frequency signal generating unit. 14 is different from the configuration of the signal processing unit 12 shown in FIG. In terms of generating a high-frequency signal used for multiplication with a rectangular wave, a configuration in which the high-frequency signal generating unit 51, the high-frequency signal generating unit 52, and the mixing unit 53 are combined corresponds to the high-frequency signal generating unit 21 shown in FIG. To do.

  A baseband signal obtained by reproducing content to be transmitted is input to the high-frequency signal generator 51 and the high-frequency signal generator 52. The baseband signal input from the content reproducing unit 11 may be a signal obtained by reproducing the same content, or may be a content obtained by reproducing different content. Although the content is the same, content in different languages such as Japanese audio and English audio is played back. For example, baseband signals obtained by playing back Japanese audio content are high frequency A baseband signal that is input to the signal generator 51 and obtained by reproducing English audio content may be input to the high-frequency signal generator 52.

  The high-frequency signal generator 51 generates a high-frequency signal having a frequency of any physical channel among 13 to 52Ch, and modulates the input baseband signal based on the generated high-frequency signal. The high-frequency signal generator 51 also has the same configuration as that shown in FIG. The high frequency signal generation unit 51 outputs the modulated high frequency signal to the mixing unit 53.

  The high-frequency signal generator 52 generates a high-frequency signal having a difference between the center frequency of the high-frequency signal generated by the high-frequency signal generator 51 and the center frequency of 6 MHz, and an input baseband signal based on the generated high-frequency signal Modulate. The high-frequency signal generator 52 has the same configuration as that shown in FIG.

When the center frequency of the high-frequency signal generated by the high-frequency signal generator 51 is f ₁ and the center frequency of the high-frequency signal generated by the high-frequency signal generator 52 is f ₂ , f ₂ −f ₁ = s. As described above, s is 6 MHz, which is the interval between the center frequencies of the physical channels. In the high-frequency signal generation unit 51 and the high-frequency signal generation unit 52, high-frequency signals of channels having physical channel numbers adjacent to each other are generated.

  The mixing unit 53 adds the modulated high-frequency signal supplied from the high-frequency signal generating unit 51 and the modulated high-frequency signal supplied from the high-frequency signal generating unit 52, and outputs the addition high-frequency signal to the mixer unit 55. To do. An example of the frequency spectrum of the high-frequency signal output from the mixing unit 53 is shown in FIG. 21A. The solid line arrow shown in FIG. 21A represents a high frequency signal generated by the high frequency signal generation unit 51, and the dotted line arrow represents a high frequency signal generated by the high frequency signal generation unit 52.

  In this example, the center frequency of the high-frequency signal generated by the high-frequency signal generator 52 is higher by s MHz than the center frequency of the high-frequency signal generated by the high-frequency signal generator 51. If sMHz, the frequency of the high-frequency signal generated by the high-frequency signal generator 51 may be higher than the frequency of the high-frequency signal generated by the high-frequency signal generator 52.

  The rectangular wave signal generation unit 54 generates a rectangular wave having a 50% duty ratio and outputs the rectangular wave to the mixer unit 55. A rectangular wave having a duty ratio of 50% is shown in FIG. 21B. The fundamental frequency of the rectangular wave generated by the rectangular wave signal generator 54 is also s MHz (6 MHz).

  The mixer unit 55 performs analog multiplication of the high-frequency signal of the addition result supplied from the mixing unit 53 and the rectangular wave having a duty ratio of 50% generated by the rectangular wave signal generation unit 54.

  FIG. 21C is a diagram illustrating a frequency spectrum of a signal resulting from multiplication by the mixer unit 55.

As shown in FIG. 21C, the signal resulting from the multiplication by the mixer unit 55 is centered on the frequency f ₁ , f ₁ , f ₁ ± s, f ₂ ± s, f ₁ ± 3 s, f ₂ ± 3 s,. It becomes a frequency series signal of MHz.

  Thus, even when a rectangular wave having a duty ratio of 50% is used, by using a sum signal of two high-frequency signals having a center frequency interval of 6 MHz as a signal used for multiplication with the rectangular wave, It becomes possible to generate a signal including the components of all the channels 13 to 52Ch.

  Returning to the description of FIG. 20, the filter / amplitude adjustment unit 56 performs filtering and amplitude adjustment processing on the signal resulting from the multiplication by the mixer unit 55 in the same manner as the filter / amplitude adjustment unit 41 of FIG. The signal obtained by applying is output.

[Operation of one-segment transmitter 1]
With reference to the flowchart of FIG. 22, the process of the one segment transmitter 1 having the signal processing unit 12 having the configuration shown in FIG. 20 will be described.

  In step S21, the content reproduction unit 11 reproduces the content to be transmitted.

In step S22, the high-frequency signal generator 51 of the signal processor 12 center frequency to generate a high frequency signal f _1, the high-frequency signal generator 52 is the center frequency to generate a high frequency signal f _2.

In step S23, the high-frequency signal generator 51, the center frequency based on the frequency signal f _1, modulates the baseband signal content to be transmitted. The high frequency signal generator 52, the center frequency based on the frequency signal f _2, modulates the baseband signal content to be transmitted.

  In step S <b> 24, the mixing unit 53 adds the modulated high-frequency signal supplied from the high-frequency signal generating unit 51 and the modulated high-frequency signal supplied from the high-frequency signal generating unit 52.

  In step S25, the rectangular wave signal generation unit 54 generates a rectangular wave having a 50% duty ratio.

  In step S <b> 26, the mixer unit 55 performs analog multiplication of the high-frequency signal resulting from the addition by the mixing unit 53 and the rectangular wave.

  In step S27, the filter / amplitude adjustment unit 56 filters the signal resulting from the multiplication by the mixer unit 55 using BPF or BEF.

  In step S28, the filter / amplitude adjustment unit 56 adjusts the amplitude of the signal obtained by performing the filtering.

  In step S29, the transmission unit 13 transmits the amplitude-adjusted signal from the antenna 14 using a weak radio wave, and ends the process.

  With the above processing, the user who uses the content using the mobile device 2 does not have to be aware of channel selection.

  For example, when the baseband signal input to the high-frequency signal generator 51 and the baseband signal input to the high-frequency signal generator 52 are the same signal, the user can select the same content regardless of which channel is selected. It can be used.

  In addition, when the baseband signal input to the high-frequency signal generation unit 51 and the baseband signal input to the high-frequency signal generation unit 52 are signals obtained by reproducing contents having different audio languages, the user is odd The same content can be used every other channel, such that Japanese content can be used when selecting a channel, and English content can be used when an even channel is selected. Become.

In the above description, _two high-frequency signals having frequencies f ₁ and f ₂ are generated and mixed, and then multiplied by a rectangular wave. However, the generated high-frequency signals are limited to two signals. Absent. That is, three or more signals having a center frequency interval having a predetermined frequency may be generated and mixed, and then multiplied with a rectangular wave.

[Modification]
In the above, a transmission apparatus and a transmission method that do not make the user aware of channel selection have been shown for one-segment broadcasting based on the ISDB-T terrestrial digital broadcasting standard. In addition, a signal having the center frequency of any one of the 13-52 Ch of one-segment broadcasting is generated by the one-segment transmitter 1 as a high-frequency signal from which signals of a plurality of channels are generated. However, a signal having a frequency outside the frequency band of 13 to 52 Ch may be generated.

  For example, as shown in FIG. 23, by generating a 467.143 MHz signal that is 6 MHz lower than the center frequency of 13Ch, which is 473.143 MHz, one-segment broadcasting is also performed based on this signal. It is possible to generate signals of a plurality of channels. Similarly, a 713.143 MHz signal whose frequency is 6 MHz higher than 707.143 MHz, which is the center frequency of 52Ch, may be generated.

  That is, a signal having any frequency may be generated as long as the signal has a center frequency that is different from the center frequency of any physical channel of one-segment broadcasting by an integer multiple of 6 MHz. .

  In addition, with the center frequency of one physical channel of the one-segment broadcasting as a reference, for example, a signal having a center frequency that is different from an integer multiple of 428 kHz obtained by dividing 6 MHz by 14 may be generated. Good.

In the above, the center frequency f ₁ of the high frequency signal generated by the high-frequency signal generator 51 of FIG. 20, although the difference between the center frequency f ₂ of the high frequency signal generated by the high-frequency signal generator 52 has to be 6MHz The interval between the center frequencies f ₁ and f ₂ may be 428 kHz (one segment) obtained by dividing 6 MHz into 14 parts.

  In the first embodiment and the second embodiment, the rectangular wave has a duty ratio other than 50%, but a specific circuit configuration for generating a rectangular wave having a duty ratio other than 50% is described below. There are many. For example, it is possible to employ a circuit configuration that generates a rectangular wave having an arbitrary duty ratio by using an output of a comparator that compares the amplitude of a sine wave with guaranteed accuracy with a specified voltage value.

  Although a rectangular wave is generated as a signal used for multiplication with a high-frequency signal, a signal used for multiplication with a high-frequency signal is not limited to a rectangular wave in the time domain, for example, a triangular waveform in the time domain. It is possible to generate sufficient harmonic components in a desired frequency region, such as a triangular wave observed with a sawtooth waveform, a sawtooth wave observed with a sawtooth waveform, and a trapezoidal wave with a trapezoidal waveform, stable, and Any time domain waveform that can efficiently generate a signal may be generated by an appropriate method.

  There are various circuit configurations for realizing a mixer unit that performs analog multiplication. For example, a DBM using four diodes, an SBM realized with two diodes, or the like may be realized with a passive mixer circuit that does not provide conversion gain but has good linearity characteristics, or a transistor Alternatively, an active mixer circuit that can obtain a conversion gain using a FET, a dedicated IC, or the like may be used.

  Although the signals of a plurality of channels are transmitted by weak radio waves, the frequency spectrum of the weak radio waves has an intensity equal to or lower than the intensity required for a license for installing a radio station, as shown by an upward arrow in FIG. It will have.

  In the above, the radio wave of each physical channel of one-segment broadcasting based on the ISDB-T terrestrial digital broadcasting standard is output. However, the radio wave should not exceed the intensity required for installing a radio station. For example, radio waves having a frequency other than the band used in one-segment broadcasting may be output.

  For example, multiple channels having a frequency sequence of 9 kHz or 100 kHz corresponding to the channel interval determined in each communication broadcast media, such as 9 kHz intervals for AM radio broadcasts and 100 kHz intervals for FM radio broadcasts. A signal may be transmitted by radio waves, or in the case of analog television broadcasting, signals of a plurality of channels having a frequency sequence generated so as to have an interval of 6 MHz may be transmitted by radio waves. In other words, the present invention is applicable to various types of broadcasting in which channel intervals are defined at fixed frequency intervals and information is transmitted using the respective channels.

  When transmitting signals of multiple channels generated based on a signal having the center frequency of a certain channel of AM / FM radio broadcasting using radio waves, users of AM tuners or devices equipped with FM tuners select the channel. You can listen to the transmitted voice without being conscious of it.

  In addition, when a plurality of channel signals generated based on a signal having the center frequency of a channel of an analog television broadcast are transmitted by radio waves, the user of the device equipped with the analog television broadcast tuner selects a channel. The transmitted program can be viewed without being conscious of.

  In the embodiment of the present invention, an example in which content to be serviced is handled from a baseband signal and handled as a predetermined high-frequency signal by the high-frequency signal generation unit has been shown. However, as shown in FIG. It is also possible to input a signal to the mixer unit 23 after adjusting the frequency and amplitude to a desired frequency by the high frequency receiving unit 61.

  With the method shown in FIG. 25, it becomes possible to relay a specific channel on all channels, and a service that does not make the user aware of channel matching can be performed.

  In the embodiment of the present invention, the output by radio waves is presented, but even if the radio waves are not propagating through space, for example, high-frequency signals using twisted cables, coaxial cables, waveguides, leaky coaxial cables, surface wave transmission lines, etc. It can also be applied to transmission and propagation.

  In the embodiment of the present invention, a weak radio wave that does not require acquisition of a radio station license is described as an example, but whether the radio station license is acquired and the technology of the present invention are independent matters, the license acquisition Technically, the present invention can also be applied to a radio station that needs to be used.

  The embodiments of the present invention are not limited to the above-described embodiments, and various modifications can be made without departing from the scope of the present invention.

  DESCRIPTION OF SYMBOLS 1 One segment transmitter, 2 Portable apparatus, 11 Content reproduction part, 12 Signal processing part, 13 Transmission part, 14 Antenna, 21 High frequency signal generation part, 22 Rectangular wave signal generation part, 23 Mixer part, 31 Modulation part, 32 signal Generating unit, 41 filter / amplitude adjusting unit, 51, 52 high frequency signal generating unit, 53 mixing unit, 54 rectangular wave signal generating unit, 55 mixer unit, 56 filter / amplitude adjusting unit

Claims (5)

In a transmission apparatus that transmits information by broadcasting in which channel intervals are defined at fixed frequency intervals,
High-frequency signal generating means for generating a high-frequency signal having the same frequency as a predetermined one channel ;
Harmonic generation means for generating a signal having a harmonic component having a frequency corresponding to the interval of each channel as a fundamental frequency ;
Multiplication means for multiplying the high-frequency signal by a signal having the harmonic component generated by the harmonic generation means;
A transmission device comprising: transmission means for transmitting a signal resulting from multiplication by the multiplication means as a new high-frequency signal. The transmission apparatus according to claim 1 , further comprising a filter unit that removes or passes a signal in a predetermined frequency band included in a signal resulting from multiplication by the multiplication unit. The transmission device according to claim 1, further comprising amplitude adjusting means for adjusting an amplitude of a signal resulting from multiplication by the multiplying means. The high-frequency signal generating means includes
First high-frequency signal generating means for generating a first high-frequency signal having the same frequency as a predetermined one channel ;
First modulation means for modulating the baseband signal of the content to be transmitted based on the first high-frequency signal generated by the first high-frequency signal generation means;
A second high-frequency signal generating means for generating a second high-frequency signal having a difference in the high-frequency signal and the center frequency by the first of the same frequency as the frequency corresponding to the interval of each channel,
Second modulation means for modulating the baseband signal of the content to be transmitted based on the second high-frequency signal generated by the second high-frequency signal generation means;
Said first high-frequency modulated signal, adding the second high-frequency modulated signal, according to claim 1, 2 or 3, the signal of the addition result an adding means for outputting as said high-frequency signal Transmitter. In a transmission method of a transmission device that transmits information by broadcasting in which channel intervals are defined at fixed frequency intervals,
Generating a high frequency signal having the same frequency as a given channel ;
A frequency corresponding to the interval of each channel is set as a fundamental frequency, and a signal having the harmonic component is generated.
Multiplying the high frequency signal and the signal having the harmonic component,
A transmission method including a step of transmitting a signal resulting from multiplication as a new high-frequency signal.

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