KR20010112498A - Television receive, Internet conneting and inner area LAN system - Google Patents

Abstract

SUMMARY OF THE INVENTION The present invention aims to provide a television reception, an internet connection, and a local area network (LAN) system, and as a means for this purpose, a coaxial transmission line 6 and a television terminal arranged in series in the transmission line. The bidirectional amplifier 5 is provided upstream of the inside of the television common reception facility provided with (8). On the upstream side of the bidirectional amplifier, a router 15 which manages the MAC address of the center modem 14 for converting the RF signal flowing through the transmission line into a baseband signal and the personal computer 11 arranged in each generation, and owns an IP address. ) And the trunk line modem 16 for connecting the input / output between the upper provider (trunk line system) 12 in that order. By using the transmission line for data transmission in the same town, no separate wiring is necessary.

Description

TV reception, Internet access and local area LAN system {Television receive, Internet conneting and inner area LAN system}

The present invention utilizes an existing television joint reception facility such as a coaxial cable installed in a large structure such as an apartment house, a building, a hotel, and the like, in addition to TV reception, an Internet connection and a LAN in a building. By constructing three communication systems, in particular, in an empty frequency band not used for television broadcasting, by using one or more communication channels, two-way communication can be established at high speed and high quality and low cost. It's about the system.

In recent years, with the rapid spread of the Internet, various business models have been provided using the Internet as well as information disclosure collection using electronic mail and home pages, and convenience has been gradually improved.

On the other hand, the penetration rate of personal computers is increasing year by year, and now reaches about 40% of Japanese families. In the future, a plurality of personal computers (one to one to one household) will be distributed in one household. It is also expected. Then, a personal computer is used to access the Internet.

Therefore, the Internet population is also on the rise, and the maintenance of infrastructure becomes indispensable. In addition, since the data to be transmitted becomes a still image from the text data, and the amount of data to be transmitted at one time also increases over various fields such as a moving picture and audio, a high-speed internet network capable of transmitting a large amount of data can be established. Needs to be.

By the way, most of the households use a telephone line (twisted pair line) already introduced into each household except for a part using CATV or a dedicated line. If this twisted pair wire is used, there is a limit to high speed and large capacity.

When there is a request to cope with speed, etc., in the case of a single-family house, it is possible to respond relatively freely by contracting with CATV or drawing in a leased line by the intention of the resident. However, in the case of apartment houses such as mansions (apartments) made up of many lakes to which the present invention is concerned, and various buildings, individual residents and the like cannot enter CATV or leased lines at will by their own will. Therefore, in buildings, apartments, hotels, etc., where the CATV system is not introduced, it is inevitable to use a twisted pair wire to connect to the Internet.

On the other hand, according to the infrastructure of the trunk line, it is desirable to build a system that supports high-speed data and large-capacity data in buildings. As an example of the solution, a CATV system, an optical fiber cable, or the like may be installed in a building. However, in the case of already established buildings, it is practically difficult to reinstall wiring, optical fiber cables, and the like in the wall for constructing a CATV system because of various restrictions. Thus, for example, when wiring or the like is exposed outside the wall. Moreover, construction for him is done for all rooms, whether or not they wish to access the Internet. Then, in the generation which does not make such a hope, it is often forced to do unnecessary construction, and it may become difficult to obtain consent.

Moreover, when connecting to the Internet using a twisted pair wire | wire, there exists the following problem. That is, in many cases, the modular terminal for telephone lines is provided in a living room or the like, and in many cases, it is provided in two places including living. On the other hand, the installation place of a personal computer may be installed in a study room or each room. Then, the room where the personal computer is installed may not be provided with a modular terminal. If so, the telephone line can be connected by dragging a telephone line from a modular terminal such as a living room or using a wireless LAN or the like. Then, when the user drags around the telephone line, the telephone line is exposed in the room, which may not only look bad but also interfere with the telephone line. In addition, there is no such problem in the wireless system, but there is a problem in terms of safety of data transmission.

SUMMARY OF THE INVENTION The present invention has been made in view of the above problems, and its object is to solve the above problems, and to solve the above problems, in a building equipped with an in-house television common reception facility provided with a coaxial cable, a high-speed telephone line can be used without using a telephone line. It is possible to transmit a large amount of information, to connect to the Internet, and to use it as a local area network (LAN) system and a television reception facility as it is.

In order to achieve the above object, the present invention provides a coaxial cable installed in a large structure such as a multi-family house, a building, a hotel, an in-house amplifier for connecting the coaxial cable and an antenna, and the large structure connected to the coaxial cable. A television reception, Internet connection, and local area network (LAN) system were constructed by using an existing television common reception facility equipped with a television terminal installed in an interior room. Specifically, when the internal amplifier is in one direction, it is replaced by a bidirectional amplifier (therefore, if a bidirectional amplifier applicable to the present system is already used, it is used as it is). A mixer is connected to the bidirectional amplifier, and the mixer is connected to the antenna and connected to an Internet connection such as a center modem or a router and a device for LAN connection in the same area. A terminal such as a personal computer and the coaxial cable are connected to the television terminal, and a terminal modem for an interface for data transfer between them is connected. The downlink data communication signal directed to the terminal transmitting the coaxial cable uses an empty frequency band not used for television broadcasting, and the uplink data communication signal transmitting the coaxial cable transmitted from the terminal is the downlink. The frequency band is higher than the frequency band of the data communication signal.

Although the above-described invention is specifically aimed at existing large structures, the same technical idea can be applied to large-sized structures. That is, even in such a large structure, the television co-receiving includes a coaxial cable installed in the same housing, an in-house amplifier for connecting the coaxial cable and an antenna, and a television terminal provided in a room in the large structure connected to the coaxial cable. The equipment must be installed. Therefore, by using the bidirectional amplifier in the in-house amplifier in advance, it is possible to construct a television reception, an Internet connection, and a local area network (LAN) system by the above method.

In multi-unit houses such as mansions, office buildings, leasing buildings, and other buildings, in-house TV co-receiving facilities with coaxial cables are usually installed. Therefore, in the present invention, in the case of establishing a facility environment in which the Internet connection is possible in a building (large structure) in which the television common reception facility is installed and a LAN can be used in the same area, the coaxial already installed in the building Cables and in-house television common reception equipment using them, more specifically coaxial cables, were actively used as transmission lines. That is, the coaxial cable has a wide band and a short wiring distance of several 100 m or less in the copper band, so that the loss of the coaxial cable is almost negligible. Therefore, as a transmission path (transmission medium), it can use sufficiently by transmitting a high speed and a large amount of information.

Since it is transmitted as an RF signal on a transmission line, conversion is made from a center modem to a signal that can be communicated over an internet network such as a baseband signal. That is, data transmitted from the Internet network is converted into an RF signal by the center modem and transmitted to the television terminal through the transmission line. In addition, since information flowing through the transmission line is converted into a baseband signal by the center modem, it is then directly connected to the Internet network or through the contracted higher provider to the Internet network.

In addition, whether the device is directly connected to the Internet network or connected to a higher provider, the output of the center modem is physically directly connected to a predetermined communication line, or through an apparatus for converting to a predetermined communication protocol. Include any case where it is printed. In other words, "direct" includes not only the case of physically connecting directly to the line, but also the above concept.

In addition, since the data transmitted and received by a computer such as a personal computer does not normally use an RF signal, a user who connects to the Internet using the Internet connection or a local area network (LAN) system of the present invention does not use an RF signal. A terminal modem for converting a signal and a signal of a type handled by a computer (for example, an Ethernet-compatible signal) is provided.

Further, by using a router or the like, the LAN connection system can be easily constructed by configuring transmission and reception of information between a plurality of computers connected to the above-mentioned television common reception facility.

In addition, in the present invention, since the number of installations is higher than that of the terminal for general telephone lines, and the television terminals are installed in each room, even if a computer is installed in an arbitrary room, only the television terminal in that room is used. If you do, you can simply connect to the Internet without having to drag the cable out of the room.

In addition, since there is no need for separate wiring for Internet connection by using the transmission line as described above, in an already established building, for example, the Internet can be easily connected by performing the following method. The facility environment can be built.

That is, the amplifier which connects the said television common reception facility and a television antenna is replaced with the bidirectional amplifier. The upstream side of the bidirectional amplifier is provided with a center modem for converting a splitter or an RF signal flowing through the transmission line into a baseband signal, so that a computer connected to the television terminal can be constructed in an installation environment that can be connected to the Internet. Can be.

In addition, in the present invention, the frequency band used for the uplink signal (data communication signal) flowing through the coaxial cable is higher than the downlink signal band. Therefore, in the transmission cable (coaxial cable) in the same area, since the uplink signal also becomes a high frequency band, noise generated from the device or the like is hard to overlap, and high-quality transmission can be performed.

In addition, the communication channel to be used may be "one-to-one" having one uplink signal and one for downlink signal respectively, may be "one-to-n" having a plurality of ones, or may be "n-m" having a plurality of both. .

The control for establishing and adjusting the communication channel used in this way includes uplink channel designation information for replacing transmission information transmitted from the terminal on an uplink carrier and a downlink channel for determining a reception channel for receiving a downlink communication signal from the center modem. Control signals comprising channel designation information, uplink output level adjustment information for controlling the strength of the output level from the terminal modem, and terminal modem management information for the center modem to constantly monitor the identification and status of the respective terminals; The configuration may be performed. The terminal modem also oscillates a request signal for making a communication connection from the terminal modem to the center modem.

In other words, if the number of users (terminal computers) using the Internet connection and the LAN connection increases, for example, if the communication carrier is one wave, traffic jams will occur if these multiple users are used simultaneously. There is concern. Thus, by preparing and distributing a plurality of communication channels, it is possible to maintain a high transmission speed. In addition, by adjusting the output level, high quality data transmission is made possible.

1 is a conceptual diagram showing an example of a transmission system in a premises of a multi-family house which is a main part of the present invention.

2 shows an example of a frequency band used in the present invention.

(Explanation of symbols for the main parts of the drawing)

1: TV antenna 2: BS-U-V amplifier

3: mixer 4: splitter

5 bidirectional amplifier 6 transmission line

7: apartment house 8: TV terminal

10: TV 11: personal computer

12: parent provider 14: center modem

15 router 16: trunk line modem

18: terminal modem 19: server machine

Although FIG. 1 has shown the principal part of embodiment of this invention, in order to make it the structure of FIG. First, in the case where the in-house amplifier of the in-vehicle television receiving facility is in one direction, it is replaced by the bidirectional amplifier 5. If the bidirectional amplifier 5 is already provided, it is used as it is. Next, the mixer 3 is connected to the bidirectional amplifier 5, and the mixer 3 is connected to the antenna of the in-vehicle television receiving facility, and the Internet connection such as a center modem, a router, or a local area network (LAN) Connect equipment necessary for LAN) connection. In addition, the television terminal 8 which has been completed is provided with a terminal modem which also serves as a terminal interface such as a personal computer and a television receiver. This form shows the example applied to apartment houses, such as an apartment. Basically, the same applies to large structures such as rental buildings and hotels and other buildings.

The present invention uses the in-house television joint reception equipment from a plurality of television terminals installed in each generation, and constitutes a next generation communication system that is faster than the twisted pair lines used in telephone lines and the like in each generation so far.

As shown in the figure, in the television common reception facility in the neighborhood, the signal received by the television antenna 1 is amplified by the BS / UV amplifier 2, and the signal of the reception band is amplified. Is given to the bidirectional amplifier 5 which is a dynamic amplifier. The bidirectional amplifier 5 is connected in parallel via a divider 4 with a plurality of transmission lines 6 constituted by coaxial cables. This transmission line 6 is provided in each layer of the multi-family house 7 in this example. And the television terminal 8 arrange | positioned in each chamber of the same layer is connected to this transmission line 6 in series. Of course, as the installation pattern of this transmission line 6, it is not necessary to limit to providing the television terminal 8 in parallel in each layer as shown in the figure, and serial / parallel group division is arbitrary. In addition, all the television terminals 8 may be arranged in parallel.

In general, when a plurality of rooms exist in one generation, in many cases, a television terminal 8 is provided for each room. That is, a plurality of television terminals 8 are arranged in the first generation. Therefore, in each generation, the television can be viewed in any room by connecting the television terminal 8 and the television 10 provided in the room where the television is to be installed. This is a television joint reception system. In addition, a plurality of transmission line 6 and television terminal 8 described above are used to establish a television common reception facility in the town.

In the present invention, in-house television joint reception equipment is used for the data transmission path in particular, between the personal computer 11 installed in each generation and the Internet network (higher provider 12). That is, since the transmission line 6 is comprised by the coaxial cable, the transmission band which the transmission line 6 has is very wide. Thus, uplink and downlink signals are transmitted using a frequency band not used for retransmission channels of VHF and UHF television broadcasting.

Specifically, the downlink signal used in consideration of the broadcasting frequency band of the cable television is in the range of 70 to 770 MHz (usually 450 MHz or less) as shown in FIG. 2, and among the frequency bands of the downlink signal, 7 and 8 channels are shown. At least one frequency band of (bandwidth 4 MHz) is an empty channel. In addition, an empty channel is also provided between the frequency bands (222 to 470 MHz: super high band) between the VHF band and the UHF band.

Therefore, the frequency band of the downlink signal in the neighborhood for the Internet connection is to use the above super high band (for N channels). Of course, a channel corresponding to 7 or 8 channels (different depending on the region) may be used, or an unused frequency band such as a mid band may be used. In addition, instead of using a plurality of channels in this way, it is of course possible to use one predetermined channel.

In addition, between 1032 and 2150 MHz is a signal for BS and CS-IF. Therefore, although the uplink communication signal for data communication is to use an arbitrary channel of 800 to 1000 MHz, which is an empty frequency band on the high frequency side, the frequency band to be used is not limited to this. The lower limit of the upward signal of may be lowered. In addition, not all of these wide ranges are actually used, but predetermined frequency bands (for example, 6 channels of 821 to 866 MHz) or the like may be used.

In this way, in order to transmit an uplink signal, in a general public television common reception facility, it is a one-way amplifier which flows from the television antenna 1 toward each transmission line 6, but in the present invention, since it is necessary to perform bidirectional transmission, a bidirectional amplifier ( 5) is used. Therefore, in existing apartment houses and other large structures, when the television common reception facility is already installed and one-way amplifier is provided, it can respond by replacing it with the bidirectional amplifier 5. In addition, as described later, the upstream side of the bidirectional amplifier 5 includes a system connected to the television antenna 1 described above, and a system connected to an apparatus for Internet connection or LAN connection. The distributor 4 is provided on the upstream side of

The bidirectional amplifier 5 separates and transmits an upstream signal and a downlink signal in the inside thereof, and amplifies it in the middle so that each signal can be transmitted to the other side without attenuation. For this reason, a splitter is provided at the input / output terminal to separate it into a downward line and an upward line. In addition, the basic configuration of the bidirectional amplifier 5 is the same as that generally used.

Thus, in this embodiment, since any up-down signal flowing through the transmission line 6 in the apartment 7 becomes the high frequency band, it becomes strong against noise and suppresses transmission of noise overlapping the uplink signal as much as possible. .

In addition, the upstream side of the bidirectional amplifier 5 is branched into two systems by the mixer 3, and in parallel with the above-described television antenna 1, conversion of the RF signal and the baseband signal (e.g., Ethernet system correspondence). A center modem 14 for executing a network, a personal computer 11 arranged in each generation, a router 15, and a trunk line modem 16 for connecting input / output between the router 15 and an upper provider (trunk line system). Are connected in that order.

That is, as will be described later, the personal computer 11 of the subscriber's home performs data transmission via the transmission line 6 and communicates with the center modem 14 and the router 15 via the bidirectional amplifier 5. Data transmission and reception can be performed at.

As described later, a signal (for example, a baseband signal) output from the personal computer 11 is once converted into an RF signal, and the RF signal is transmitted in the same transmission line 6 in the same area as the RF modem. Since it reaches (14), the center modem 14 demodulates the RF signal into an Ethernet base band signal. Of course, the downlink signal (baseband signal) sent from the router 15 toward the personal computer 11 is converted into an RF signal by this center modem 14, and the predetermined terminal modem 18 is transmitted via the transmission line 6. Is sent).

On the other hand, in the subscriber's home which connects to the Internet using this system, the terminal modem 18 is connected to the television terminal 8 and the personal computer 11 is connected to the terminal modem 18. In addition, the terminal modem 18 is also provided with a terminal for connecting the television 10. Of course, the television 10 can also be directly connected to the television terminal 8.

In addition, the upstream signal transmitted from the personal computer 11 is converted into an RF signal transmitting in coaxial in the terminal modem 18, and is converted into a high frequency signal of 800 to 1000 MHz by a frequency converter provided on an upline in the apparatus. After that, it is supplied to the transmission line 6.

On the other hand, in the above-described embodiment, for example, six channels are prepared as channels for transmitting upstream signals in the same town, and N channels are prepared for the downlink signals. In other words, both are used for multiple channels. Then, the empty channel is automatically selected, and the uplink and downlink signals are all multi-carrier transmission methods, thereby transmitting information (data). As a result, the empty channel and the channel with little noise can be detected and used automatically, thereby enabling stable mass transfer. That is, even if the user has a large amount of data to be transmitted or transmitted, it is possible to cope without deteriorating transmission speed and quality in the city.

In addition, a channel actually used by any one terminal (personal computer) for internet access or the like is selected from one of the plurality of channels and an empty (light load) channel. Of course, you may use multiple channels.

The determination of the channel to be used and the adjustment at the time of communication are performed based on the control signal sent from the center modem 14 in this embodiment. That is, as a control signal, uplink channel designation information (determining a communication channel to be used as uplink signal in the building) for replacing transmission information transmitted from the terminal modem on the uplink carrier, and receiving downlink communication signal from the center modem 14 are received. Downlink channel designation information (determining a communication channel used as a downlink signal in the neighborhood), uplink output level adjustment information for controlling the strength of the output level from the terminal modem, or identification and status of each terminal In addition to the terminal modem management information for monitoring the center modem at all times, there is information necessary for connection establishment and adjustment.

The communication channel to be used is determined by the terminal modem 14 monitoring the status of the terminal modem management information or the assigned communication channel, and the determined contents are the above-mentioned uplink and downlink channel designation information and uplink output level adjustment information. It transmits toward a predetermined terminal modem, and the terminal modem transmits and receives information (data) in accordance with the received control information.

In addition, as a method of transmitting this control signal, the method of transmitting as an independent control signal and the method to include in a data carrier can be employ | adopted. In the former case, since the control signal is not included in the real data portion (data carrier) in the communication carrier, the transmission speed of the real data does not decrease. In addition, when performing transmission control in multi-carriers, it is necessary to consider the communication establishment procedure for each terminal, but the control system is simplified.

In addition, in the latter data carrier, either a tandem method for transmitting control signals to all channels or a parallel method for transmitting control signals to specific channels can be employed. That is, in the case of the tandem system, since the data signal and the control signal are conveyed in a mixed state (logically multiplexed and separated) in each channel, the modulation / demodulation circuits of the respective carriers can be commonized and the product price can be reduced. .

In addition, when the parallel method is used, determining the frequency through which the data carriers in which the data signal and the control signal are mixed is sent makes it unnecessary to search the control signal frequency and simplify the communication establishment procedure. . In addition, since there are no control signals in other channels, it is possible to maintain the transmission speed and quality of real data in these other channels.

In the above example, the trunk line modem 16, the router 15, and the center modem 14 are formed separately, but it is a matter of course that a plurality of devices may be formed as one.

In addition, the server machine 19 may be separately connected, and mail may be transmitted and received between subscriber homes (personal computer 11) in the multi-family house 7. In other words, it is possible to construct a LAN. In addition, the bulletin board can be managed to provide a service that residents of the multi-family house 7 can write down each other.

According to this aspect, by contracting with an upper provider, the connection cost per terminal can be made low. In addition, by managing the router 15, the trunk line modem 16, etc., it can function as a kind of subordinate provider and develop as a business such as collecting charges from each subscriber's home. In this case, the manager may be a management association of a multi-family house, or a general contractor or a real estate company that manages the construction sales of the building. Of course, various telecommunication operators may be used separately.

In general, any existing multi-unit house or lease building has a TV terminal that has been installed. Therefore, a new wiring construction is provided because the TV terminal is connected to the TV terminal and an Internet connection can be used using an existing public TV facility. It is unnecessary, and construction is only necessary to change the amplifier of one direction to the bidirectional amplifier 5, and to install each apparatus for Internet connection and LAN connection mentioned above between the bidirectional amplifier 5 and a higher provider. Therefore, the installation work can be easily performed. In addition, since construction is basically completed without being performed in each household, there is no unreasonability even for those who do not wish to have Internet access, and no temporary deterioration of the living environment accompanying construction is caused.

In addition, one or more television terminals are generally provided in each room, and the number of installations per unit is large compared to the modular terminals of telephone lines, and the restriction on the installation position of the personal computer is reduced as much as possible. In other words, although there may be a room without a modular terminal, there is no exaggeration to say that there is no room without a television terminal. An environment in which a personal computer is installed in a desired room and an internet connection can be established.

In addition, the LAN can be easily configured in the neighborhood, and the files shared for building the neighborhood can be accessed by using the LAN, which is advantageous for office buildings and leased buildings that do not have a local LAN facility. It becomes.

In addition, even in the case of architectural design of a new building, it is possible to provide a connection environment to the Internet and a LAN environment by using the in-house TV common facility, which is also a standard facility, without arranging an optical cable. As a result, the cost can be reduced.

The present invention enables the construction of three communication systems, namely, Internet connection and local area network (LAN), in addition to television reception by utilizing existing television joint reception facilities such as coaxial cables, but in particular, no telephone line is used. In addition, it is not necessary to newly install a coaxial cable, and to utilize three existing television joint reception facilities, and to establish three communication systems is an invention corresponding to an era in which renewal is required. Can be.

In addition, the present invention not only makes it possible to construct at a low cost by utilizing existing facilities, but also improves the speed of communication information to be transmitted and the quality of information by using the same configuration as that described in the claims. It is to have the effect that can be achieved.

Claims (3)

Coaxial cables installed in large structures such as apartment houses, buildings, hotels, in-house amplifiers connecting the coaxial cables and antennas, and installed in rooms in the large structures connected to the coaxial cables In a television reception, an internet connection, and a local area network (LAN) system, which is constructed by using an existing television common reception facility having a television terminal, If the dynamic amplifier is in one direction, replace it with a bidirectional amplifier. A mixer is connected to the bidirectional amplifier, the connection is made with the antenna through the mixer, and an Internet connection such as a center modem or a router and a device for LAN connection are simultaneously connected. A terminal such as a personal computer and the coaxial cable are connected to the television terminal, and a terminal modem for an interface for performing data transfer therebetween is connected. A downlink data communication signal directed to the terminal modem transmitting on the coaxial cable uses an empty frequency band not used for television broadcasting; An uplink data communication signal transmitting on the coaxial cable sent from the terminal modem is constructed to use a frequency band higher than a frequency band of the downlink data communication signal. system. A coaxial cable newly installed in a new large structure such as an apartment house, a building, a hotel, an in-house amplifier connecting the coaxial cable and an antenna, and a television terminal connected to the coaxial cable and installed in a room in the large structure In a television reception, internet access, and local area network (LAN) system built using a television common reception facility, Using a bidirectional amplifier as the dynamic amplifier, A mixer is connected to the bidirectional amplifier, the connection is made with the antenna through the mixer, and an Internet connection such as a center modem or a router and a device for LAN connection are simultaneously connected. A terminal such as a personal computer and the coaxial cable are connected to the television terminal, and a terminal modem for an interface for performing data transfer therebetween is connected. A downlink data communication signal directed to the terminal modem transmitting on the coaxial cable uses an empty frequency band not used for television broadcasting; The uplink data communication signal transmitted on the coaxial cable sent from the terminal is constructed to use a higher frequency band than the frequency band of the downlink data communication signal. . The method according to claim 1 or 2, The downlink data communication signal and the uplink data communication signal are each performed using a predetermined communication channel among a plurality of communication channels, The control for establishing and adjusting the communication channel to use is Uplink channel designation information for replacing transmission information transmitted from the terminal modem on an uplink carrier, Downlink channel designation information for determining a reception channel for receiving a downlink communication signal from the center modem; Uplink output level adjustment information for controlling the strength of the output level from the terminal modem, And a control signal including terminal modem management information for the center modem to constantly monitor the identification and status of the respective terminal modems.