JP2004186783A - Millimeter wave radio communication system and gateway unit - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To cheaply realize a radio communication system which transmits television broadcast signals with radio waves in a millimeter wave band to terminals and a radio communication in the millimeter wave band over a part of data communication routes between an external network and the terminals. <P>SOLUTION: When a satellite broadcast is selected, a millimeter wave TV communication BOX 40 sends a channel select signal to a millimeter wave communication apparatus 30, and to a gateway apparatus 10 over transmission lines La, L0. Based on the channel select signal, a first frequency converter 21 extracts only a signal of a selected channel from satellite broadcast signals, and converts it to a transmitting broadcast signal (chX signal) of a frequency f11. This chX signal is sent to the transmission line L0 from an internet 4, together with downlink data signals and wirelessly transmitted at a millimeter wave band from the millimeter wave communication apparatus 30. The millimeter wave TV communication BOX 40 receives the transmitted radio waves, down-converts them, and convert them to original broadcast signals, thereby viewing and hearing the selected broadcast. <P>COPYRIGHT: (C)2004,JPO&NCIPI

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to a millimeter-wave band in which a TV broadcast signal is up-converted into a millimeter wave band and wirelessly transmitted to a terminal side, and the transmission wave is received and down-converted by the terminal side to restore the original television broadcast signal. The present invention relates to a wireless communication system and a gateway device that forms the system.
[0002]
[Prior art]
2. Description of the Related Art Conventionally, wideband transmission using a millimeter wave band has been known as one method for transmitting a wideband signal with high quality. Radio waves in the millimeter wave band (for example, 60 GHz) have the physical characteristics that, because of their short wavelength, they can be downsized, and because of their large absorption attenuation by oxygen, they do not reach far and hardly cause interference. have. For this reason, a variety of large-capacity, low-cost utilization forms are expected.
[0003]
As a communication system using a millimeter wave band, for example, in a house, a television broadcast signal is up-converted to a millimeter wave band and wirelessly transmitted, a reception side receives the transmission radio wave and down-converts to an original television broadcast signal, There is known a system configured to directly output to a television receiver or various satellite broadcast tuners (for example, see Non-Patent Document 1).
[0004]
On the other hand, when bidirectional data communication is performed between an external wide area network (for example, the Internet) and a home communication terminal, at least a part of a transmission path connecting the home communication terminal and the wide area network is wirelessly communicated. It is also known that the realization is realized, and as one form thereof, wireless communication using the 2.4 GHz band of a wireless LAN, which is being standardized by IEEE 802.11b, is well known.
[0005]
In the wireless communication between such an external wide area network and a communication terminal, wireless communication using a millimeter wave band can be considered as in the case of the above-described television broadcast signal. It is expected that quality and transmission speed will be further improved.
[0006]
Therefore, for example, in a detached house, a television broadcast signal is transmitted in-house by a coaxial cable, and a television broadcast transmission device that converts a television broadcast signal into a millimeter wave band and wirelessly transmits the television broadcast signal is provided in a predetermined room. A cable for data communication (for example, a LAN cable typified by 10BASE-T defined by IEEE802.3) is wired in the house, and external communication data is converted into a millimeter wave band to the terminal in the predetermined room. By providing a data communication transmitting / receiving device that performs wireless transmission and converts communication data wirelessly transmitted from the terminal side in the millimeter wave band to original data and transmits the data to the outside, a television feeder line is provided in the predetermined room. Is wireless, so that the beauty of the house can be improved, and high-quality and high-speed data communication can be performed.
[0007]
The 2.4 GHz band wireless LAN exemplified above is a general LAN used for wirelessly connecting a plurality of terminal devices to each other and for each terminal device performing bidirectional data communication with an external wide area network. The prior art is not disclosed because it is a technology that is a well-known and official technology.
[0008]
[Non-patent document 1]
Eiji Suematsu, 3 others, “Digital / Analog Satellite Broadcasting / Millimeter Wave Radio Transmission
Transmission Characteristics in Japanese Houses in Japan, "Sharp Technical Report, Sharp Corporation,
In December 2000, No. 10 (Vol. 78), p. 18-19
[0009]
[Problems to be solved by the invention]
However, if the transmission of television broadcast signals is made wireless and the two-way data communication with the external wide area network is also made wireless, the beauty of the home can be improved as described above, and higher quality and higher speed data communication can be achieved. However, there is a problem that a device for realizing the above becomes large in size and conversely impairs the aesthetics of the house, or causes an increase in cost due to an increase in size of the device.
[0010]
That is, since the television broadcasting transmitter and the data communication transmitter / receiver are respectively provided in the predetermined room, it is naturally necessary to secure a large device installation space as compared with a case where only one of them is installed. The cost of the entire device also increases. In addition, since two types of cables, that is, a coaxial cable and a data communication cable, are routed out of the room from each device, the trouble of laying the cables increases, and the two types of cables are laid. Deterioration of aesthetics in the home is also expected.
[0011]
The present invention has been made in view of the above problems, and up-converts a television broadcast signal to a millimeter-wave band and wirelessly transmits the terminal to a terminal, and also forms a part of a data communication path between an external wide area network and the terminal. An object of the present invention is to realize a wireless communication system configured to be realized by millimeter-wave band wireless communication at low cost.
[0012]
Means for Solving the Problems and Effects of the Invention
The millimeter-wave band wireless communication system according to claim 1, which has been made to solve the above-mentioned problem, is characterized in that a gateway device having a function as a head-end device for distributing a television broadcast signal to one or a plurality of terminals is provided in an external wide area. The communication data transmitted from the network is converted into a first transmission signal in a higher frequency band than the television broadcast signal, and the first transmission signal and the television broadcast signal are mixed and transmitted over a transmission line. A second transmission signal in a frequency band higher than the television broadcast signal transmitted from the terminal side via the transmission line to perform data communication between the terminals is converted into original communication data and transmitted to the wide area network.
[0013]
Then, a gateway-side communication device provided for each terminal side up-converts the television broadcast signal and the first transmission signal transmitted from the gateway device via the transmission line to a millimeter wave band and transmits the up-converted signal from the first antenna. And a second transmission signal that is up-converted from the terminal side to the millimeter wave band and wirelessly transmitted is received by the first antenna, and the received second transmission signal is received before being up-converted by the terminal side. Downconvert to the original frequency band and output to the gateway device via the transmission line.
[0014]
That is, in the present invention, the transmission line for transmitting the television broadcast signal to the terminal side and the transmission line for transmitting the communication data transmitted and received between the terminal side and the wide area network are separated from each other as in the prior art. Instead of using a common transmission line.
[0015]
A gateway device is provided so that a television broadcast signal and communication data can be transmitted through this one transmission line. Communication data from an external wide area network is converted into a first transmission signal, and then mixed with the television broadcast signal to be transmitted on the transmission line. At the same time, the second transmission signal for data communication transmitted from the terminal side on the transmission line is converted back to the original communication data and output to the wide area network side.
[0016]
Then, the gateway-side communication device that up-converts the television broadcast signal to a millimeter wave band and wirelessly transmits the first transmission signal transmitted on the transmission line together with the television broadcast signal to the millimeter wave band as it is, Wirelessly transmitted to the terminal side, and conversely, the second transmission signal wirelessly transmitted from the terminal side in the radio wave of the millimeter wave band is down-converted to the original frequency band and transmitted onto the transmission line. The gateway-side communication device is configured to perform both millimeter-wave band transmission of a television broadcast signal and millimeter-wave band transmission and reception of data communication.
[0017]
Therefore, according to the millimeter wave band wireless communication system of the present invention, the television broadcast signal and the communication data (specifically, the first and second transmission signals) are mixed and transmitted on the same transmission line. The communication device also has a relatively simple configuration that simply performs up-conversion of the television broadcast signal and the first transmission signal to the millimeter wave band (and down-conversion of the second transmission signal received in the millimeter wave band). As a result, the millimeter-wave band wireless communication system can be realized at low cost.
[0018]
Here, if the frequency band occupied by the television broadcast signal and the frequency band occupied by the first and second transmission signals for data communication do not overlap each other, each signal is transmitted as it is on one transmission line. Can be. However, while taking into account the upper limit of the frequency band that can be transmitted favorably over a transmission line, the system determines how far the frequency band for a television broadcast signal or how far the frequency band of each transmission signal for data communication should be. It depends on the needs of the user who constructs and uses, for example, to be able to transmit a television broadcast signal of more channels, or to secure a wider data communication band to perform higher speed data communication. It is fully conceivable that the frequency band of the television broadcast signal and the frequency band of each of the above-mentioned transmission signals for data communication overlap as a result, for example.
[0019]
If there is an overlapping frequency band between the two, the television broadcast signal and the first or second transmission signal in that band cannot be transmitted to the transmission line as they are.
Therefore, when the band equal to or higher than the predetermined frequency in the entire band of the television broadcast signal overlaps with the frequency band of the first or second transmission signal, for example, as described in claim 2, the gateway device includes: Regarding the conversion target band including at least the overlapping frequency band (overlapping band) in the TV broadcast signal, the TV broadcast signal of the channel of the conversion target band is not entirely transmitted to the transmission line as it is, and the terminal is selected. Receiving a tuning signal corresponding to the selected channel, and converting only the television broadcasting signal of the selected channel into a predetermined frequency band within a conversion target band (excluding an overlapping band) preset for each terminal. It is preferable that the frequency is converted into a broadcast signal for transmission and transmitted on a transmission line.
[0020]
In this case, the gateway-side communication device further up-converts the transmission broadcast signal transmitted from the gateway device to the millimeter wave band and transmits the up-converted broadcast signal from the first antenna. Receiving a tuning signal transmitted by radio through the first antenna, down-converting the received tuning signal to the original frequency band before being up-converted on the terminal side, and performing gateway conversion via a transmission line. It may be configured to output to a device.
[0021]
That is, if the overlapping band of the entire band of the television broadcast signal is transmitted as it is onto the transmission line, it interferes with the first or second transmission signal. When the channel is selected on the terminal side, only the selected channel is frequency-converted into a broadcast signal for transmission and transmitted over a transmission line. The frequency band of the transmission broadcast signal is fixed and preset for each terminal.
[0022]
Therefore, in the communication device on the gateway side, the broadcast signal for transmission is up-converted to the millimeter wave band and transmitted wirelessly to the terminal side, and of the channels selected by the terminal side out of all the channels in the conversion target band. Only the television broadcast signal is transmitted to the terminal.
[0023]
Therefore, according to the millimeter-wave band wireless communication system of the second aspect, even if the frequency band of the television broadcast signal and the frequency band of the first or second transmission signal for data communication overlap, the overlapping band is included. As for the television broadcast signal in the conversion target band, only the channel selected on the terminal side is transmitted on the transmission line as the broadcast signal for transmission, so that the frequency band of the television broadcast signal to be transmitted to the terminal side (in other words, For example, the degree of freedom in setting the number of television broadcast channels that can be viewed on the terminal side and setting the frequency band for data communication is expanded.
[0024]
Note that the frequency band of the channel selection signal may be appropriately determined from unused bands. For example, if the frequency band is set to a frequency band adjacent to the frequency band of the second transmission signal, the frequency band transmitted from the terminal side to the gateway device in the system will be described. All the so-called upstream signals (second transmission signal and channel selection signal) fall within a predetermined frequency band, so that the gateway-side communication device can be more simply configured, which is preferable.
[0025]
Here, the terminal side in the millimeter wave band wireless communication system may be provided with, for example, a terminal side data communication device as described in claim 3. That is, the terminal side in the system according to claim 3 receives the transmission radio wave from the gateway side communication device by the second antenna, and converts the received signal to the original signal before being up-converted by the gateway side communication device. Down-converted to a frequency band, the first transmission signal after the down-conversion is further converted into communication data before being frequency-converted by the gateway device, output to the terminal device side, and output from the terminal device side. There is provided a terminal-side data communication device that converts communication data into a second transmission signal, up-converts the second transmission signal to a millimeter wave band, and transmits the data from a second antenna.
[0026]
If such a terminal-side data communication device is provided, the terminal device can acquire external communication data from the terminal-side data communication device, and transmit external communication data to the wide area network via the terminal-side data communication device. The terminal device can be moved freely within the range where millimeter-wave radio waves can be transmitted and received between the terminal-side data communication device and the gateway-side communication device. Communication can be performed.
[0027]
Further, the terminal side in the millimeter wave band wireless communication system according to the first aspect receives a transmission radio wave from the gateway side communication device by the second antenna as described in the fourth aspect, and transmits the received signal. A terminal-side television broadcast receiving device for down-converting to the original frequency band before up-conversion in the gateway-side communication device and outputting the down-converted television broadcast signal to the terminal device side; May be.
[0028]
If such a terminal-side television broadcast receiving device is provided, the terminal device (for example, a television receiver or a television set) is provided within a range where the terminal-side television broadcast receiving device can receive the millimeter-wave charged wave from the gateway-side communication device. The television program can be viewed by freely moving the personal computer with a tuner).
[0029]
Further, the terminal in the millimeter-wave band wireless communication system according to the second aspect is preferably provided with, for example, a terminal-side television signal communication device as described in the fifth aspect. That is, to the terminal side in the system according to claim 5, a tuning signal corresponding to the selected channel is up-converted into a millimeter wave band and transmitted from the second antenna, and is transmitted wirelessly from the gateway side communication device. In addition, a transmission broadcast signal and a non-converted broadcast signal that is a television broadcast signal in a frequency band excluding the conversion target band are received by the second antenna, and the received transmission broadcast signal and the non-converted broadcast signal are transmitted to the gateway side. The communication device down-converts to the original frequency band before the up-conversion, and outputs the non-converted broadcast signal after the down-conversion as it is to the terminal device side, and transmits the down-converted transmission broadcast signal. Returns to the TV broadcast signal of the original band to be converted before the frequency conversion by the gateway device, and outputs the signal to the terminal device side. Terminal TV signal communication device is provided.
[0030]
As described above, in the system according to claim 2, the non-converted broadcast signal transmitted as it is to the terminal side without frequency conversion as the television broadcast signal, and only the selected channel has the frequency as the broadcast signal for transmission. There is a TV broadcast signal of a conversion target frequency band which is converted and transmitted to the terminal side.
[0031]
Of these, the non-converted broadcast signal can be viewed on the terminal device side by directly outputting it to the terminal device side, but the transmission broadcast signal is different from the original frequency band of the selected channel. Therefore, it is difficult to view the contents even if they are directly output to the terminal device. Therefore, the broadcast signal for transmission is further returned to the television broadcast signal of the original band to be converted before the frequency conversion by the gateway device, and output to the terminal device side.
[0032]
Therefore, by providing the terminal-side television signal communication device configured as described above, the terminal device is provided within a range where millimeter-wave band radio waves can be transmitted and received between the terminal-side television signal communication device and the gateway-side communication device. Can be freely moved to view a program corresponding to the non-converted broadcast signal and a program corresponding to the conversion target frequency band.
[0033]
By the way, it goes without saying that a television broadcast signal can be obtained by receiving an external television broadcast wave with a television reception antenna, but this television reception antenna is not limited to only one, and is generally known. For example, there are various antennas according to the broadcast radio wave to be received, such as an antenna that receives a UHF band radio wave, a BS antenna that receives a BS broadcast, and a CS antenna that receives a CS broadcast.
[0034]
By providing the plurality of television receiving antennas, television broadcast signals of more channels can be transmitted to the terminal side (that is, more television programs can be viewed). However, when trying to transmit a television broadcast signal of such a large number of channels, a portion overlapping with the frequency band of the first or second transmission signal for data communication is likely to be generated, and in addition to each television reception antenna, It is also conceivable that the frequency bands of the television broadcast signals overlap each other.
[0035]
More specifically, for example, when a UHF band receiving antenna, a BS antenna, and a CS antenna are provided as described above, a frequency band of a television broadcast signal corresponding to a BS broadcast wave received by the BS antenna, and a CS antenna It is possible that the frequency band of the television broadcast signal corresponding to the received CS broadcast wave overlaps with each other and that each of the television broadcast signals overlaps with the frequency band of each of the transmission signals for data communication. .
[0036]
Therefore, in the millimeter wave band wireless communication system according to claim 2 or 5, as described above, a plurality of types of television receiving antennas for receiving an external television broadcast wave are provided, and at least two television receiving antennas (hereinafter, referred to as two or more). In the case where the frequency band of the television broadcast signal corresponding to the "signal overlapping antenna" overlaps with the frequency band of the first or second transmission signal for data communication, for example, as described in claim 6, The frequency band of the TV broadcast signal corresponding to each of the signal overlapping antennas is set as a conversion target band, and the gateway device determines, based on the channel selection signal, the TV broadcast signal corresponding to each of the signal overlapping antennas. Only one of the channels including the channel selected by the terminal is selected, and the television broadcast signal of the selected channel is transmitted. May is for frequency conversion to use broadcast signals.
[0037]
With such a configuration, a television broadcast signal corresponding to each signal overlapping antenna can be transmitted to the terminal without interference with the above-described transmission signals for data communication. Moreover, even if the frequency bands of the television broadcast signals corresponding to the respective signal overlapping antennas overlap, only the television broadcast signal including the channel corresponding to the channel selection signal from the terminal is taken in. A television program on a channel that can be received by the receiving antenna can be reliably viewed.
[0038]
Next, a seventh aspect of the present invention is a gateway device constituting the millimeter-wave band wireless communication system according to the first aspect, wherein the gateway device converts external communication data into a first transmission signal and receives a signal from a terminal. Data conversion means for converting the second transmission signal into the original communication data; mixing the television broadcast signal and the first transmission signal for transmission over the transmission line and outputting the second transmission signal from the terminal to the data conversion means; Mixing means. Therefore, if the gateway device according to the seventh aspect is used, the millimeter wave band wireless communication system according to the first aspect can be constructed.
[0039]
According to an eighth aspect of the present invention, there is provided a gateway device constituting the millimeter-wave band wireless communication system according to the second aspect, wherein the gateway device according to the seventh aspect is further tuned from a terminal side. Receiving a signal, and outputting a conversion control signal for frequency-converting the television broadcast signal into a transmission broadcast signal when the television broadcast signal of the channel selected by the terminal is within the conversion target band. A tuning control means, and a television broadcast frequency conversion means for frequency-converting a television broadcast signal of a channel selected on the terminal side into a broadcast signal for transmission based on the conversion control signal from the tuning control means. The mixing means mixes the broadcast signal for transmission and the first transmission signal and sends them out onto the transmission line. Therefore, if the gateway device according to the eighth aspect is used, the millimeter wave band wireless communication system according to the second aspect can be constructed.
[0040]
The television broadcast frequency conversion means can be specifically configured, for example, as described in claim 9. That is, the TV broadcast frequency converting means includes a local oscillator signal generating unit for generating a local oscillator signal used for frequency conversion, and a TV broadcast signal of a channel selected on the terminal side from TV broadcast signals in the conversion target band. A signal extraction unit for extracting only the signal, and a frequency conversion unit for frequency-converting the television broadcast signal extracted by the signal extraction unit into a transmission broadcast signal using a local oscillation signal.
[0041]
Then, the local oscillation signal generation unit adjusts the frequency of the generated local oscillation signal from the tuning control unit so that the television broadcast signal of the selected channel is frequency-converted into a broadcast signal for transmission by the frequency conversion unit. The signal extraction unit is configured to be able to set based on the conversion control signal, and the frequency band of the television broadcast signal to be extracted is selected from the channel selection control unit so that the television broadcast signal of the selected channel is extracted. Is configured to be able to be set based on the conversion control signal.
[0042]
That is, the frequency band of the television broadcast signal to be extracted by the signal extraction unit and the frequency of the local oscillation signal used for frequency conversion are both configured to be variable, and these are specifically selected. It is set based on the conversion control signal from the control means.
[0043]
Therefore, the television broadcast signal of the channel selected on the terminal side can be reliably extracted and frequency-converted into a broadcast signal for transmission, and the reliability of the millimeter wave band wireless communication system according to claim 2 is further improved. Becomes possible.
Next, a tenth aspect of the present invention is a gateway device constituting the millimeter-wave band wireless communication system according to the sixth aspect, further comprising a tuning control for the gateway device according to the eighth or ninth aspect. The means is configured to output a channel signal corresponding to the channel selected by the terminal. Then, only one of the television broadcast signals corresponding to at least two television receiving antennas including the channel selected on the terminal side is selected based on the channel signal from the channel selection control means, and the television broadcast signal is selected. A television broadcast signal selection unit for outputting to the frequency conversion unit; Therefore, if the gateway device according to the tenth aspect is used, the millimeter wave band wireless communication system according to the sixth aspect can be constructed.
[0044]
BEST MODE FOR CARRYING OUT THE INVENTION
Hereinafter, a preferred embodiment of the present invention will be described with reference to the drawings.
[First Embodiment]
FIG. 1 is an explanatory diagram illustrating a schematic configuration of a millimeter-wave band wireless communication system according to the present embodiment. As shown in FIG. 1, the millimeter-wave band wireless communication system according to the present embodiment includes a television antenna 1 for receiving a VHF or UHF television broadcast radio wave transmitted from a ground station, and a transmission radio wave from a broadcast satellite (BS). It comprises a BS antenna 2 for receiving and a CS antenna 3 for receiving a transmission radio wave from a communication satellite (CS), and broadcast signals from these antennas 1 to 3 are transmitted to each room (room A, It transmits to a television (hereinafter, referred to as “TV”) 48 as a terminal device provided in each of the rooms B, C, and D, and a personal computer (hereinafter, referred to as “PC”) as a terminal device provided in each room. ) 54 is connected to the Internet 4 which is a wide area network, and bidirectionally transmits communication data transmitted and received between each PC 54 and various servers on the Internet 4. It is intended.
[0045]
The broadcast signal from each of the antennas 1 to 3 is input to the millimeter wave band wireless communication system of the present embodiment, and only the broadcast signal of a predetermined frequency band (details will be described later) is transmitted to each room. In addition, a gateway device 10 for relaying data communication between the Internet 4 and the PC 54 in each room, and a gateway device 10 provided in each room and a transmission line L0 or the like (transmission lines L0 and La for room A). Millimeter-wave communication device 30 for wireless communication connected via a wireless communication device, and a millimeter-wave TV that is provided corresponding to the TV 48 in each room and performs wireless communication with the millimeter-wave communication device 30 using radio waves in the millimeter-wave band. A communication BOX 40 and a millimeter-wave PC card 50 provided corresponding to the PC 54 in each room and performing wireless communication with the millimeter-wave communication device 30 using radio waves in the millimeter-wave band are provided.
[0046]
The BS antenna 2 includes a converter that receives a radio wave transmitted from the BS and converts it into a BS-IF signal (1032 to 1336 MHz). On the other hand, the CS antenna 3 includes a low-noise converter that receives a transmission radio wave from the CS and converts it into a first CS-IF signal (1050 to 1550 MHz; vertical polarization, 1570 to 2070 MHz; horizontal polarization). The first CS-IF signal is further converted by the block converter 5 into a second CS-IF signal (1385 to 1625 MHz; vertical polarization, 1655 to 1895 MHz; horizontal polarization). In the following description, this second CS-IF signal is simply referred to as a CS-IF signal unless otherwise specified.
[0047]
Then, the BS-IF signal from the BS antenna 2 and the CS-IF signal from the CS antenna 3 are mixed in the mixer 6 and input to the gateway device 10 together with the VHF and UHF television broadcast signals from the television antenna 1. Is done. It should be noted that both the BS-IF signal and the CS-IF satellite broadcast signal and the VHF and UHF television broadcast signals input to the gateway device 10 correspond to the television broadcast signal of the present invention.
[0048]
Therefore, the frequency band of each broadcast signal input to the gateway device 10 is as shown in FIG. 7, and the CS-IF signal is obtained by converting the first CS-IF signal into the BS-IF signal by the block converter 5. It has been converted (rearranged) to a higher frequency band.
[0049]
The gateway device 10 having a function as a headend device includes a converter 11 for the room A, a converter 12 for the room B, a converter 13 for the room C, and a converter 14 for the room D provided respectively for the rooms A to D. Prepare. Each of the converters 11 to 14 extracts only the satellite broadcast signal of the channel selected in the corresponding room from both the satellite broadcast signals of the BS-IF signal and the CS-IF signal, and extracts the extracted signals. The satellite broadcast signal is frequency-converted into a broadcast signal for transmission in a preset frequency band (in the case of the room A, two channels of a chX signal having a center frequency f11 and a chY signal having a center frequency f12).
[0050]
Specifically, for example, when a desired BS broadcast channel is selected by operating the remote controller 56 in the room A, a tuning signal S1 including the selected channel data is generated by the millimeter wave TV communication BOX 40, It is transmitted to the gateway device 10. The tuning signal S1 is input from the mixer 20 to the tuning controller 23 in the converter 11 for the A room.
[0051]
Then, based on the channel selection signal S1, the channel selection controller 23 converts the broadcast signal of the channel selected by the first frequency converter 21 (or the second frequency converter 22) to the predetermined frequency f11 (or f12). The local oscillator setting data and the BPF band setting signal (details will be described later) that determine the respective setting values of the first frequency converter 21 (or the second frequency converter 22) so as to be converted into a chx signal (or a chY signal). Output.
[0052]
Thereby, the first frequency converter 21 (or the second frequency converter 22) extracts the broadcast signal of the channel selected by the remote controller 56, and outputs the chx signal (or chY signal) of the predetermined frequency f11 (or f12). And output.
The same is true for the converter 12 for the room B, the converter 13 for the room C, and the converter 14 for the room D. When a satellite broadcast channel is selected in each corresponding room and channel selection signals S2 to S4 are transmitted. Each of the converters 12 to 14 converts the frequency of the broadcast signal of the selected channel into a broadcast signal for transmission, and transmits the broadcast signal to the transmission line L0. However, the frequency of the transmission broadcast signal for each room (see FIG. 1) has a relationship of f11 <f12 <f21 <f22 <f31 <f32 <f41 <f42, and the frequency arrangement of each transmission broadcast signal is also shown in FIG. It becomes as shown in.
[0053]
In this embodiment, two transmission broadcast signals (chX signal and chY signal) are output for one room, but this is done, for example, by recording a BS broadcast program of a certain channel while video recording. This is because there is a viewing mode in which the user views the BS broadcast program of, for example, or divides the screen of the TV 48 into two and simultaneously displays two different BS broadcast programs (or CS broadcast programs).
[0054]
The gateway device 10 further includes a cable modem 15 generally used on the terminal side when connecting to the Internet 4 via a CATV line, and an ONU that provides a user / network interface when connecting to the Internet 4 via an optical line. (Optical Network Unit) 16 and a microcomputer including a CPU, a ROM, a RAM, etc., which control the exchange of communication data with the Internet 4 and the exchange of communication data with the terminal-side PC 54, and A data communication control unit 17 for performing protocol conversion of communication data in response thereto, and a hard disk drive (HDD) 18 for storing communication data exchanged between the data communication control unit 17 and the Internet 4 in response to an instruction from the PC 54. , Data from external internet 4 In order to transmit communication data input via the communication control unit 17 to each room via each transmission path (coaxial cable in the present embodiment) L0, La, Lb, Lc, Ld, a downlink of a predetermined frequency band is transmitted. The communication data for external output, which is converted to a PC data signal and output to the mixer 20 and output from the PC 54 and converted into an upstream data signal for transmission through each of the transmission paths, is transmitted to the original output data signal. An RF modulation / demodulation unit 19 (corresponding to the data conversion means of the present invention) for converting into communication data, a transmission broadcast signal (chX signal, chY signal) from each of the room converters 11 to 14, a VHF, UHF television broadcast signal, And the downlink PC data signal output from the RF modulation / demodulation unit 19 to the terminal side to be mixed and sent out onto the transmission line L0, and output from each room and transmitted over the transmission line L0. A PC data signal is output to the RF modulator / demodulator 19, and the tuning signals S1 to S4 output from the respective rooms and transmitted on the transmission line L0 are transmitted to the corresponding converters 11 to 14 for the respective rooms. And an output mixer 20 (corresponding to the mixing means of the present invention).
[0055]
In the present embodiment, the frequency bands of the upstream PC data signal and the downstream PC data signal when the PC 54 in each room performs data communication with the Internet 4 are generally higher than the frequency of each broadcast signal for television broadcasting. Although a band is set, a part of the band of the broadcast signal (specifically, a band of 1.75 GHz or more in the CS-IF signal) overlaps with the frequency band of the uplink PC data signal, as indicated by hatching in FIG. ing. Therefore, if the CS-IF signal and the uplink PC data signal are transmitted on the same transmission line as they are, interference occurs between the two and normal signal transmission is not performed. Note that this overlapping frequency band corresponds to the overlapping band of the present invention.
[0056]
Therefore, in the present embodiment, the CS-IF signal and the BS-IF signal are not directly mixed by the mixer 20 and sent out onto the transmission line L0, but the channel selected by the remote controller 56 for each room. , And is converted into a broadcast signal for transmission of a fixed frequency, transmitted over the transmission line L0, and transmitted to the corresponding room. In the present embodiment, as shown in FIG. 7, the frequency band in which the transmission broadcast signal can be set is, for example, a band of 1.0 to 1.7 GHz, and the band of the uplink PC data signal is 1.75 to 2.0 GHz. The band of the downlink PC data signal is 2.0 to 2.6 GHz, and 1.7 to 1.75 GHz is used as the transmission band for the channel selection signal.
[0057]
Here, a frequency band (for example, 1.0 to 2.0 GHz in this example) including a BS-IF signal and a CS-IF signal to be converted into a transmission broadcast signal corresponds to a conversion target band of the present invention. The UHF and VHF television broadcast signals transmitted as they are onto the transmission line L0 without performing frequency conversion correspond to the non-converted broadcast signal of the present invention, and the upstream PC data signal corresponds to the second transmission signal of the present invention. , The downlink PC data signal corresponds to the first transmission signal of the present invention.
[0058]
FIG. 2 shows a schematic configuration of the first frequency converter 21 as a television broadcast frequency conversion unit. As shown in FIG. 2, in the first frequency converter 21, first, a variable passband bandpass filter (hereinafter abbreviated as “BPF”) 61 as a signal extraction unit is transmitted from the BS antenna 2 and the CS antenna 3. From the BS-IF signal and the CS-IF signal, the broadcast signal of the channel selected by the remote controller 56 in the room A is extracted. The variable pass band BPF 61 is configured to be able to change its pass band based on a BPF band setting signal (DC voltage signal) from the channel selection controller 23 described later. A known configuration is conceivable in which the capacitance value is changed by changing the voltage between both ends, and as a result, the pass band is changed.
[0059]
The broadcast signal extracted by the variable pass band BPF 61 is amplified by an amplifier 62 and then input to a mixer 63 as a frequency converter, where a local oscillator 64 as a local oscillator generates a local oscillator. The frequency is converted by the signal. The local oscillator 64 can be composed of, for example, an injection-locked oscillator composed of a PLL circuit or the like, and the frequency division ratio of the frequency divider circuit constituting the PLL circuit is determined by local setting data (PLL frequency division) from the channel selection controller 23. Ratio data), it is possible to change the frequency of the local oscillation signal.
[0060]
The broadcast signal for transmission (chX signal of frequency f11) obtained by frequency-converting the broadcast signal by the mixer 63 is supplied to the mixer 20 via the BPF 65 and the amplifier 66 for selectively passing only the chX signal. Is output. The frequency converters included in the second frequency converter 22 and the other converters 12 to 14 (not shown) also have the same circuit configuration as that of FIG. 2, though the frequencies of the chX signal and the chY signal are different.
[0061]
FIG. 3 shows a schematic configuration of a tuning controller 23 as a tuning control means. As shown in FIG. 3, in the tuning controller 23, the BPF 71 first extracts a tuning signal S1 corresponding to the channel selected by the remote controller 56 in the room A from the signal input from the mixer 20. Then, the data indicating the selected channel is demodulated by the RF demodulation unit 72.
[0062]
Then, the demodulated data is processed by the data processing unit 73, and based on the processing result, the control output unit 74 is controlled by the control unit 74 so that the first frequency converter 21 can surely convert the frequency of the desired broadcast signal into a chX signal. , And outputs local setting data and a BPF band setting signal to the frequency converters 21 and 22, respectively. Both the local oscillation setting data and the BPF band setting signal correspond to the conversion control signal of the present invention. The channel selection controllers included in the other converters 12 to 14 also have different local oscillation setting data due to different frequencies of the chX signal and the chY signal, but the circuit configuration itself is exactly the same as that of FIG.
[0063]
On the other hand, a transmission line L0 from the gateway device 10 is connected to transmission lines La, Lb, Lc, and Ld to each of the rooms A to D via a four-way distributor. Among them, the transmission line La to the room A is connected to the millimeter wave communication device 30 installed near the ceiling in the room A, and the transmission line La between the millimeter wave communication device 30 and the gateway device 10. , And various signals are transmitted via the distributor and the transmission line L0.
[0064]
FIG. 4 shows a schematic configuration of the millimeter wave communication device 30. As shown in FIG. 4, the millimeter wave communication device 30 as the gateway-side communication device of the present invention includes a downlink indoor transmission signal (chX signal, chY signal, UHF and VHF television broadcast signal, downlink transmission signal) transmitted from the gateway device 10. PC data signal) is up-converted to a millimeter-wave band and wirelessly transmitted from an antenna 30a (a first antenna of the present invention), and channel selection transmitted from a millimeter-wave TV communication box 40 described later in a millimeter-wave radio wave. The signal and the upstream PC data signal transmitted from the millimeter wave PC card 50 to be described later in the millimeter wave band are received by the antenna 30a and down-converted to the original channel selection signal and the upstream PC data signal, respectively. This is sent to the gateway device 10 side.
[0065]
That is, of the downlink indoor transmission signals from the gateway device 10 input to the millimeter wave communication device 30, the chX signal, the chY signal, the UHF and VHF television broadcast signals (hereinafter simply referred to as “downstream broadcast signals”) are: The signal passes through a low-pass filter (hereinafter referred to as “LPF”) 81 that blocks signals in the band of 7 GHz or more, is amplified by an amplifier 82, and is input to a mixer 83. On the other hand, the downlink PC data signal among the downlink indoor transmission signals passes through a high-pass filter (hereinafter referred to as “HPF”) 91 that blocks signals in a band of 1.7 GHz or less, and further transmits a signal in a band of 2.0 GHz or less. The signal passes through the blocking HPF 92, is amplified by the amplifier 93, and is input to the mixer 94.
[0066]
Since a 60-GHz local signal is input from the local oscillator 84 to each of the mixers 83 and 94, both of the downstream broadcast signal and the downstream PC data signal are up-converted to a millimeter wave band by the mixers 83 and 94. You. Of these, the downstream broadcast signal up-converted to a millimeter wave band by the mixer 83 passes through the BPF 85 that extracts only the downstream broadcast signal (60 to 61.7 GHz), is amplified by the amplifier 86, and then mixed. The signal is mixed with a local signal of 60 GHz by the device 87. Then, both the downstream broadcast signal and the local oscillation signal pass through the LPF 88 that blocks signals in the band of 61.7 GHz or more, and are transmitted from the antenna 30a.
[0067]
The downstream PC data signal up-converted to a millimeter wave band by the mixer 94 also passes through the BPF 95 that extracts only the downstream PC data signal (62 to 62.6 GHz), and is amplified by the amplifier 96. The signal passes through the HPF 97 that blocks signals in the band of 62 GHz or less, and further passes through the HPF 98 that blocks signals in the band of 61.7 GHz or less, and is transmitted from the antenna 30a.
[0068]
On the other hand, the tuning signal (61.7 to 61.75 GHz) transmitted by being up-converted to the millimeter-wave band by the millimeter-wave TV communication box 40 and the up-converted signal by the millimeter-wave PC card 50 to the millimeter-wave band. All of the transmitted uplink PC data signals (61.75 to 62 GHz) are received by the antenna 30a, pass through the HPF 98 and the LPF 101 that blocks signals in the band of 62 GHz or more, and are amplified by the amplifier 102. After that, it is input to the mixer 103. A local signal from a local oscillator 84 is also input to the mixer 103. Therefore, both the upstream PC data signal and the channel selection signal are converted into the original frequency band, and the BPF 104 that extracts only the band (1.7 to 2 GHz), the amplifier 105, the LPF 106 that blocks signals in the band of 2 GHz or more, and The data is transmitted to the gateway device 10 via the HPF 91.
[0069]
Next, the millimeter wave TV communication box 40 provided corresponding to the TV 48 will be described. The millimeter-wave TV communication BOX 40 receives a transmission signal (infrared ray) when a TV channel is selected by the operation unit 58 of the remote controller 56 and data indicating the selected channel is transmitted from the transmission unit. The data is received by the unit 44 and demodulated by the data processing unit 45. The demodulated data (data indicating the selected channel) is modulated by the RF modulator 46 into a tuning signal of 1.7 to 1.75 GHz and output to the TV millimeter wave communication unit 41. Is up-converted to a millimeter wave band and transmitted from an antenna 40a (corresponding to a second antenna of claim 5).
[0070]
The millimeter-wave communication unit for TV 41 up-converts the tuning signal into a millimeter wave band and wirelessly transmits the same, and down-converts a broadcast signal transmitted from the millimeter wave communication device 30 in the millimeter wave band again to TV. The output is output to the output converter 42, and the specific configuration is shown in FIG.
[0071]
As shown in FIG. 5, in the millimeter-wave communication unit for TV 41, a broadcast signal in the millimeter wave band and a local oscillation signal (60 GHz) are received by the antenna 40a, and the received signal is converted into a signal in a band of 61.7 GHz or more. The signal is input to the mixer 113 via the LPF 111 and the amplifier 112 for blocking. Also, of the received signals, the 60 GHz local oscillator signal is extracted by the BPF 125 that allows only the local oscillator signal to pass, and is input as the local oscillator signals of the two mixers 113 and 119.
[0072]
Therefore, the received signal in the millimeter wave band is down-converted to the original broadcast signal (0 to 1.7 GHz) by the mixer 113, and the down-converted broadcast signal is passed through the BPF 114, the amplifier 115, and the BPF 114 that pass only the broadcast signal. The signal passes through the LPF 116 that blocks signals in a band of 1.7 GHz or more and is output to the TV output converter 42.
[0073]
On the other hand, the tuning signal from the RF modulator 46 passes through the HPF 117 that blocks signals in the band of 1.7 GHz or less, is amplified by the amplifier 118, and is then input to the mixer 119. Since the local oscillator signal of 60 GHz is input to the mixer 119 as described above, the channel selection signal is up-converted to a millimeter wave band. Then, the tuning signal (61.7 to 61.75 GHz) after the up-conversion is transmitted from the antenna 40a via the BPF 120, the amplifier 121, and the HPF 122, which blocks signals in the band of 61.7 GHz or less, which pass only the signal. Is done.
[0074]
Next, a schematic configuration of the TV output converter 42 is shown in FIG. As shown in FIG. 6, among the broadcast signals input from the millimeter-wave TV communication unit 41, the TV output converter 42 converts a UHF and VHF band television broadcast signal as a non-converted broadcast signal into a band of 1 GHz or more. After passing through the LPF 131 which blocks the signal of the above, the signal is output to the TV 48 as it is. On the other hand, the broadcast signal for transmission whose frequency has been converted by the A room converter 11 in the gateway device 10 cannot be viewed on the TV 48 as it is, and therefore needs to be returned to the original broadcast signal.
[0075]
Therefore, the broadcast signal for transmission (1 to 1.7 GHz) first passes through the HPF 132 that blocks signals in a band of 1 GHz or less. The chX signal is extracted by the BPF 133 that extracts only the frequency band of the chX signal, and is input to the mixer 135 after being amplified by the amplifier 134. As for the chY signal, the chY signal is extracted by the BPF 138 that extracts only the frequency band of the chY signal, amplified by the amplifier 139, and input to the mixer 140.
[0076]
Here, from the data processing unit 45, based on the selected channel data, local setting data and a BPF band setting signal similar to those of the tuning controller 23 in the gateway device 10 are generated, and a TV output converter is generated. Output to
The local oscillator 145 for frequency conversion by the mixer 135 and the local oscillator 146 for frequency conversion by the mixer 140 have exactly the same configuration as the local oscillator 64 shown in FIG. The frequency of the local oscillation signal can be set based on the local oscillation setting data from the data processing unit 45. FIG. 2 also shows a variable pass band BPF 136 for passing the original broadcast signal after frequency conversion by the mixer 135 and a variable pass band BPF 141 for passing the original broadcast signal after frequency conversion by the mixer 140. The configuration is exactly the same as that of the variable pass band BPF 61, and the pass band can be set based on the BPF band setting signal from the data processing unit 45.
[0077]
Therefore, the original broadcast signal before being converted into the chX signal and the original broadcast signal before being converted into the chY signal can be reliably restored, and the respective broadcast signals after the restoration are supplied to the amplifiers 137 and 142, respectively. After that, the signal is output to the TV 48. As a result, the television program of the selected channel can be viewed on the TV 48. The terminal millimeter-wave communication unit 41 and the TV output converter 42 constitute a terminal-side television signal communication device of the present invention.
[0078]
Next, the millimeter-wave PC card 50 (corresponding to the terminal-side data communication device of the present invention) modulates communication data from the PC 54 into an uplink PC data signal by the RF modulation / demodulation unit 52, and converts the uplink PC data signal to a PC signal. The millimeter-wave communication unit further up-converts the signal into a millimeter-wave band, transmits the up-converted signal from an antenna 50a (corresponding to a second antenna according to claim 3), and transmits the downlink PC transmitted from the millimeter-wave communication device 30 in the millimeter-wave band. The data signal is received by the antenna 50a, down-converted to the original downlink PC data signal by the millimeter-wave communication unit for PC, and the downlink PC data signal is further demodulated to communication data by the RF modulation / demodulation unit 52 to the PC 54. Output.
[0079]
The configuration of the millimeter-wave communication unit 51 for PC is exactly the same as the millimeter-wave communication unit 41 for TV configuring the millimeter-wave TV communication box 40, and the types of downlink and uplink signals to be transmitted are different (that is, the configuration is different). (The pass / stop bands of the various filters are different.) Therefore, detailed description thereof is omitted here.
[0080]
As described in detail above, in the millimeter-wave band wireless communication system of the present embodiment, the broadcast signal and the data signal are mixed by the gateway device so that the broadcast signal and the data signal can be transmitted to the terminal through a common transmission line. Is transmitted to the gateway device via the same transmission line. Since the frequency band of the data signal and the frequency band of the broadcast signal overlap, a signal of the overlapping band cannot be transmitted on a common transmission line as it is, but in this embodiment, the CS-IF signal Alternatively, when a channel of the BS-IF signal is selected, channel selection data indicating the selected channel is transmitted to the gateway device, and based on that, only the broadcast signal of the selected channel is transmitted to a predetermined frequency band. And transmits it to the terminal side.
[0081]
Therefore, according to the millimeter-wave band wireless communication system of the present invention, the broadcast signal and each PC data signal are mixed by the gateway device 10 and both are transmitted on the same transmission line. Since the broadcast signal and the downlink PC data signal can be realized with a relatively simple configuration that only performs up-conversion to the millimeter-wave band (and down-conversion of the uplink PC data signal received in the millimeter-wave band), It is possible to realize a band wireless communication system at low cost, and it is also possible to prevent the appearance of the house from being impaired by the construction of the system.
[0082]
Moreover, even if the frequency band of the broadcast signal and the frequency band of each PC data signal for data communication overlap, a television broadcast signal (BS-IF signal and CS-IF signal in this example) within a predetermined band including the overlap band. ), Only the channel selected on the terminal side is transmitted on the transmission line as a broadcast signal for transmission (chX signal or chY signal), so that the frequency band of the broadcast signal to be transmitted to the terminal side (in other words, Then, the degree of freedom in setting the number of television broadcast channels that can be viewed on the terminal side and setting the frequency band for data communication is expanded.
[0083]
Further, the PC 54 can acquire communication data from the external Internet 4 from the millimeter-wave PC card 50 and can output communication data to the external Internet 4 to the Internet 4 via the millimeter-wave PC card 50. The data communication with the Internet 4 can be performed by freely moving the PC 54 as long as the millimeter wave band radio wave can be transmitted and received between the millimeter wave PC card 50 and the millimeter wave communication device 30.
[0084]
Further, by providing the millimeter-wave TV communication box 40, the TV 48 can be freely moved within a range in which the millimeter-wave band radio waves can be transmitted and received between the millimeter-wave TV communication box 40 and the millimeter-wave communication device 30, so that the TV program can be transmitted. You can watch.
In this embodiment, the 60-GHz local oscillation signal used for frequency conversion by the millimeter-wave communication device 30 installed near the ceiling is transmitted together with a broadcast signal and the like to the TV millimeter-wave communication unit 41 and the PC millimeter-wave communication unit 51. To the TV millimeter-wave communication unit 41 and the PC millimeter-wave communication unit 51 for frequency conversion using the transmitted local oscillation signal. It is not necessary for each of the wave communication units 51 to include a local oscillator, and the cost of the entire system can be reduced.
[0085]
[Second embodiment]
Here, in the first embodiment, the case where the band of the broadcast signal overlaps with the band for data communication has been described. However, as described above, how far the frequency band for the broadcast signal should be, The range of the frequency band of each PC data signal varies depending on the needs of the user who constructs and uses the system, and depending on the user, there may be a case where not much band is required for data communication. In such a case, it may be assumed that the frequency of the broadcast signal and the signal frequency for data communication do not overlap.
[0086]
Therefore, a description will be given of a millimeter wave band wireless communication system in which a broadcast signal and a data signal do not overlap each other. FIG. 8 is an explanatory diagram showing a schematic configuration of a millimeter wave band wireless communication system of the present embodiment, and FIG. 10 is an explanatory diagram showing a frequency arrangement of various signals in the system.
[0087]
As shown in FIG. 10, in this embodiment, the frequency band of the broadcast signal is the same as that of the first embodiment, but the band for data communication, that is, the frequency band of the uplink PC data signal and the frequency band of the downlink PC data signal is , The band exceeds 1.9 GHz and extends to 2.6 GHz. That is, the frequency arrangement is such that the band of the broadcast signal and the band of each data signal do not overlap.
[0088]
Therefore, as shown in FIG. 8, the gateway device 150 configuring the system mixes the broadcast signals from the antennas 1 to 3 with the mixer 151 and further mixes the broadcast signals with the data communication signal with the mixer 152. It has a configuration. That is, unlike the gateway device 10 of the first embodiment, all the broadcast signals are sent out onto the transmission line L0 as they are.
[0089]
Therefore, the millimeter-wave receiver for TV 161 (corresponding to the terminal-side television broadcast receiver of claim 4) connected to the TV 48 is simply up-converted to a millimeter-wave band by the millimeter-wave communication device 160 and transmitted. This is a simple configuration that simply downconverts the broadcast signal to the original broadcast signal again.
[0090]
Specifically, as shown in FIG. 9, a broadcast signal transmitted in the millimeter wave band from the millimeter wave communication device 160 and received by the antenna 161a (corresponding to the second antenna of claim 4) has a frequency of 61.9 GHz. The signal passes through the LPF 171 that blocks signals in the above bands, is amplified by the amplifier 172, and is input to the mixer 174. The configuration of the millimeter wave communication device 160 is completely the same as that of the millimeter wave communication device 30 of the first embodiment (see FIG. 4), and transmits a 60 GHz local oscillation signal together with a broadcast signal. Therefore, in the TV millimeter wave receiver 161, the 60 GHz local signal is extracted by the BPF 173 that extracts only the 60 GHz signal, and is output to the mixer 174.
[0091]
As a result, the broadcast signal in the millimeter wave band is down-converted by the mixer 174 to the broadcast signal in the original frequency band. The down-converted broadcast signal is output to the TV 48 via the BPF 175 that passes only the push signal, the amplifier 176, and the LPF 177 that blocks signals in the band of 1.9 GHz or more.
[0092]
Therefore, even with the millimeter wave band wireless communication device of the present embodiment, the broadcast signal and each PC data signal are mixed by the gateway device 150 and both are transmitted on the same transmission path. Since the broadcast signal and the downlink PC data signal can be realized with a relatively simple configuration that only performs up-conversion to the millimeter-wave band (and down-conversion of the uplink PC data signal received in the millimeter-wave band), It is possible to realize a band wireless communication system at low cost, and it is also possible to prevent the appearance of the house from being impaired by the construction of the system.
[0093]
[Third embodiment]
Next, as shown in FIG. 11, the millimeter-wave band wireless communication system of the present embodiment includes a BS / CS antenna 7 that can receive both a BS broadcast and a 110 ° CS broadcast as an antenna for receiving a television broadcast. In addition, there is no block converter 5 (see FIG. 1) for frequency-converting the first CS-IF signal output from the CS antenna 3.
[0094]
Therefore, the frequency arrangement of each signal in the present embodiment is as shown in FIG. That is, as in the first embodiment, not only the band of the broadcast signal and the signal band for data communication overlap but also between the broadcast signals.
[0095]
Therefore, in the millimeter-wave band wireless communication system of the present embodiment, configuring the gateway device 180 as shown in FIG. Also correspond to the television receiving antenna of the present invention).
[0096]
That is, as shown in FIG. 11, the gateway device 180 of the present embodiment uses the broadcast signal from the BS / CS antenna 7 and the CS signal in the A room converter 181 (converters for other rooms are omitted here). A first changeover switch 182 for selecting any one of the broadcast signals from the antenna 3 and inputting the selected signal to the first frequency converter 21; and selecting one of the broadcast signal from the BS / CS antenna 7 and the broadcast signal from the CS antenna 3 And a second changeover switch 184 for selecting one of them and inputting it to the second frequency converter 22. Each of the changeover switches 182 and 184 corresponds to a television broadcast signal selection unit of the present invention.
[0097]
Switching between these switches 182 and 184 is controlled by a switch control signal (corresponding to a channel signal of the present invention) from the channel selection controller 186. That is, in addition to the functions provided by the channel selection controller 23 of the first embodiment, the channel selection controller 186 is a changeover switch that specifies which of the two antennas should receive the broadcast signal based on the channel selection signal. It also has the function of outputting control signals. Each of the changeover switches 182 and 184 selects one of the two antennas 3 and 7 according to the changeover switch control signal.
[0098]
The processing and flow of the selected broadcast signal are exactly the same as those in the first embodiment, and the broadcast signal of the selected channel is converted into a broadcast signal for transmission (chX signal or chY signal) and transmitted over a transmission line. Will be.
For this reason, according to the millimeter wave band wireless communication apparatus of the present embodiment, even if the broadcast signal bands from a plurality of antennas overlap each other, the changeover switches 182 and 184 receive the selected channel. Therefore, interference between broadcast signals can be prevented, and the selected broadcast signal can be reliably transmitted to the terminal.
[0099]
In addition, since the configuration is such that a plurality of antennas are selectively used by the changeover switch, it is possible to view television programs of more channels than in the first embodiment.
It should be noted that the embodiments of the present invention are not limited to the above embodiments at all, and it goes without saying that various embodiments can be adopted as long as they belong to the technical scope of the present invention.
[0100]
For example, in each of the above embodiments, in the gateway device, two broadcast signals for transmission (chX signal and chY signal) are set for each room. Of course, if you want more (for example, to display several other channels simultaneously while recording a video), it is of course possible to increase the number to three or more.
[0101]
Further, in the first embodiment, both the BS-IF signal and the CS-IF signal are subjected to frequency conversion into a broadcast signal for transmission. However, the present invention is not limited to this. Alternatively, the signal may be directly transmitted to the transmission line together with the UHF and the UHF, and the CS-IF signal may be frequency-converted and transmitted only for the selected channel.
[0102]
How to set the broadcast signal to be sent out on the transmission line as it is and the broadcast signal to be sent out on the transmission line after frequency conversion of the selected channel can be freely set while considering the band required for data communication. Can be set to
Further, in the first embodiment described above, a plurality of antennas (TV antenna 1, BS antenna 2, CS antenna 3) receive various broadcast radio waves to obtain a television broadcast signal corresponding to each antenna. The television broadcast signal input to the gateway device 10 is not necessarily limited to the signal directly input from the antenna as described above.
[0103]
In other words, in applying the present invention, it is irrelevant to what route the television broadcast signal is input to the gateway device 10. May be input from the server. More specifically, for example, a television broadcast signal of VHF and UHF may be taken in from a CATV line by pulling in a CATV line from the outside instead of the television antenna 1.
[0104]
Of course, if there is a means / line other than the CATV line that can take in the television broadcast signal, the television broadcast signal may be taken in. The same applies to the second and third embodiments.
[Brief description of the drawings]
FIG. 1 is an explanatory diagram illustrating a schematic configuration of a millimeter wave band wireless communication system according to a first embodiment.
FIG. 2 is a block diagram illustrating a schematic configuration of a first frequency converter included in the gateway device according to the first embodiment.
FIG. 3 is a block diagram illustrating a schematic configuration of a channel selection controller included in the gateway device according to the first embodiment.
FIG. 4 is a block diagram illustrating a schematic configuration of the millimeter wave communication device according to the first embodiment.
FIG. 5 is a block diagram illustrating a schematic configuration of a TV millimeter wave communication unit according to the first embodiment.
FIG. 6 is a block diagram illustrating a schematic configuration of a TV output converter according to the first embodiment.
FIG. 7 is an explanatory diagram showing a frequency arrangement of various signals in the millimeter wave band wireless communication system of the first embodiment.
FIG. 8 is an explanatory diagram illustrating a schematic configuration of a millimeter wave band wireless communication system according to a second embodiment.
FIG. 9 is a block diagram illustrating a schematic configuration of a millimeter wave receiver for TV according to a second embodiment.
FIG. 10 is an explanatory diagram showing a frequency arrangement of various signals in the millimeter wave band wireless communication system according to the second embodiment.
FIG. 11 is an explanatory diagram illustrating a schematic configuration of a millimeter wave band wireless communication system according to a third embodiment.
FIG. 12 is an explanatory diagram illustrating a frequency arrangement of various signals in the millimeter wave band wireless communication system according to the third embodiment.
[Explanation of symbols]
DESCRIPTION OF SYMBOLS 1 ... TV antenna, 2 ... BS antenna, 3 ... CS antenna, 4 ... Internet, 5 ... Block converter, 6,20 ... Mixer, 7 ... BS / CS antenna, 10,150,180 ... Gateway device, 11,181 ... A room converter, 12 ... B room converter, 13 ... C room converter, 14 ... D room converter, 15 ... Cable modem, 16 ... ONU, 17 ... Data communication control unit, 19,52 ... RF modulation / demodulation unit , 21: first frequency converter, 22: second frequency converter, 23, 186: tuning controller, 30: millimeter wave communication device, 30a, 40a, 50a, 160a, 161a: antenna, 40: millimeter wave TV Receiving BOX, 41 ... TV millimeter wave communication unit, 42 ... TV output converter, 44 ... Reception unit, 45 ... Data processing unit, 46 ... RF modulation unit, 5 ... Millimeter-wave PC card, 51 ... PC millimeter-wave communication unit, 56 ... Remote control, 57 ... Transmission unit, 58 ... Operation unit, 61,136,141 ... Variable passband BPF, 63 ... Mixer, 64 ... Local oscillator, 160 ... Millimeter wave communication device, 161 ... TV millimeter wave receiving device, 182 ... First changeover switch, 184 ... Second changeover switch

Claims (10)

It has a function as a head-end device for delivering a television broadcast signal to one or more terminals, and converts communication data transmitted from an external wide area network into a first transmission signal in a frequency band higher than the television broadcast signal. Then, the first transmission signal and the television broadcast signal are mixed and transmitted on a transmission line, and transmitted from the terminal side via the transmission line to perform data communication with the wide area network. A gateway device that converts a second transmission signal in a higher frequency band than the television broadcast signal into original communication data and transmits the communication data to the wide area network;
The television broadcast signal and the first transmission signal transmitted from the gateway device via the transmission line are provided for each terminal side, and are up-converted to a millimeter wave band and transmitted from a first antenna. The second antenna receives the second transmission signal which is radio-transmitted by up-converting from the terminal side to the millimeter wave band, and receiving the second transmission signal before the terminal side up-converts the second transmission signal. A gateway-side communication device for down-converting to the original frequency band and outputting to the gateway device via the transmission line,
A millimeter-wave band wireless communication system comprising: A band equal to or higher than a predetermined frequency in the entire band of the television broadcast signal is an overlap band overlapping the frequency band of the first or second transmission signal,
The gateway apparatus does not transmit all the television broadcast signals of the channels of the conversion target band on the transmission line as it is for the conversion target band including at least the overlapping band in the TV broadcast signal, and selects the channel on the terminal side. Receiving the channel selection signal corresponding to the selected channel, only the television broadcast signal of the selected channel, a predetermined frequency within the conversion target band excluding the overlap band, which is set in advance for each of the terminals. Frequency-converted to a broadcast signal for transmission of a band, and transmitted on the transmission line,
The gateway-side communication device further up-converts the transmission broadcast signal transmitted from the gateway device to a millimeter wave band and transmits the up-converted broadcast signal from the first antenna, and also performs up-conversion from the terminal side to a millimeter wave band. Receiving the tuning signal wirelessly transmitted by the first antenna, down-converting the received tuning signal to an original frequency band before being up-converted on the terminal side, and transmitting the selected tuning signal. 2. The millimeter-wave band wireless communication system according to claim 1, wherein the wireless communication system is configured to output to the gateway device via a line. It is provided on the terminal side of the system, receives the transmission radio wave from the gateway side communication device by the second antenna, and converts the received signal to the original frequency band before being up-converted by the gateway side communication device. Down-converting, further converting the first transmission signal after the down-conversion into communication data before being frequency-converted by the gateway device, and outputting the communication data to the terminal device side, and the communication output from the terminal device side A terminal-side data communication device for converting data into the second transmission signal, up-converting the second transmission signal to a millimeter wave band, and transmitting the data from the second antenna. 3. The millimeter-wave band wireless communication system according to 2. It is provided on the terminal side of the system, receives the transmission radio wave from the gateway side communication device by the second antenna, and converts the received signal to the original frequency band before being up-converted by the gateway side communication device. The millimeter-wave band wireless communication system according to claim 1, further comprising a terminal-side television broadcast receiving device that down-converts and outputs the down-converted television broadcast signal to a terminal device. Provided on the terminal side of the system, while up-converting the tuning signal corresponding to the selected channel to a millimeter wave band and transmitting it from the second antenna, wirelessly transmitted from the gateway side communication device, A broadcast signal for transmission, and a non-converted broadcast signal that is a television broadcast signal in a frequency band other than the conversion target band is received by the second antenna, and the received broadcast signal for transmission and the non-converted broadcast signal are transmitted to the gateway side. The communication device down-converts to the original frequency band before the up-conversion, and outputs the non-converted broadcast signal after the down-conversion as it is to the terminal device side, and transmits the down-converted transmission broadcast signal. Returns to the television broadcast signal of the original band to be converted before being frequency-converted by the gateway device, and Millimeter-wave band wireless communication system according to claim 2, characterized in that it comprises a terminal-side television signal communication device for outputting to the side. Equipped with a plurality of types of television receiving antennas for receiving television broadcasting radio waves from the outside, any of the frequency bands of the television broadcasting signals corresponding to at least two television receiving antennas are set as the conversion target band,
The gateway device, based on the tuning signal, selects only one of the television broadcasting signals corresponding to the at least two television receiving antennas, including only a channel selected on the terminal side, 6. The millimeter wave band wireless communication system according to claim 2, wherein a frequency of a television broadcast signal of a selected channel is converted into the transmission broadcast signal. It is a gateway apparatus which comprises the millimeter wave band radio | wireless communication system of Claim 1, Comprising:
Data conversion means for converting external communication data into the first transmission signal and converting the second transmission signal from the terminal into original communication data;
Mixing means for mixing the television broadcast signal and the first transmission signal and transmitting the mixed signal on the transmission line and outputting the second transmission signal from the terminal side to the data conversion means;
A gateway device comprising: It is a gateway apparatus which comprises the millimeter-wave band radio | wireless communication system of Claim 2, Comprising:
Receiving the tuning signal from the terminal side, and converting the television broadcast signal to the transmission broadcast signal when the television broadcast signal of the channel selected by the terminal side is in the conversion target band. Channel selection control means for outputting a conversion control signal for conversion,
TV broadcast frequency conversion means for frequency-converting the TV broadcast signal of the channel selected on the terminal side to the transmission broadcast signal based on the conversion control signal from the channel selection control means,
With
8. The gateway device according to claim 7, wherein the mixing unit mixes the broadcast signal for transmission and the first transmission signal and transmits the mixed signal to the transmission line. The television broadcast frequency conversion means,
A local oscillation signal generation unit that generates a local oscillation signal used for frequency conversion,
From among the TV broadcast signals in the conversion target band, a signal extraction unit that extracts only the TV broadcast signal of the channel selected on the terminal side,
A frequency conversion unit that frequency-converts the television broadcast signal extracted by the signal extraction unit into the transmission broadcast signal using the local oscillation signal,
With
The local oscillation signal generation unit controls the frequency of the local oscillation signal to be generated so that the frequency conversion unit converts the frequency of the television broadcast signal of the selected channel into the transmission broadcast signal. Is configured to be able to be set based on the conversion control signal from the means,
The signal extraction unit is configured to set a frequency band of a television broadcast signal to be extracted based on a conversion control signal from the channel selection control unit so that a television broadcast signal of the selected channel is extracted. 9. The gateway device according to claim 8, wherein It is a gateway apparatus which comprises the millimeter wave band radio | wireless communication system of Claim 6, Comprising:
The tuning control unit is further configured to output a channel signal corresponding to a channel selected by the terminal,
Of the respective television broadcast signals corresponding to the at least two television receiving antennas, only one including the channel selected on the terminal side is selected based on the channel signal from the channel selection control means. 10. The gateway device according to claim 8, further comprising a television broadcast signal selecting unit that outputs the broadcast signal to the television broadcast frequency conversion unit.

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