JP2005086276A - Cable modem system and modem management device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a cable MODEM system attaining a high communication speed by utilizing a CATV transmission line, and also to provide a MODEM management device. <P>SOLUTION: A plurality of cable MODEM termination apparatuses and a MODEM management device are connected to a CATV network. The MODEM management device is provided with: a speed entry means S300 for entering a communication speed V and a speed discrimination means S310 for discriminating whether a cable MODEM can process the entered communication speed; and a channel setting means S350 for registering a plurality of cable MODEMs for configuring pairs with the plurality of cable MODEM termination apparatuses to a registration means S340 when the means S310 discriminates that the single cable MODEM cannot process the entered communication speed and sets a channel used for data communication to a free channel transmitted through the CATV network. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

The present invention relates to a cable modem system and a modem management device used in a transmission line for a CATV line, and more particularly to a cable modem system and a modem management device for dealing with an increase in communication speed.

Conventionally, cable modem systems for CATV lines have been bi-directional, and bi-directional data transmission has been realized between the center device and the terminal device. (For example, see Patent Document 1)
Further, when data transmission is performed via a digital circuit switching network such as ISDN, bulk transmission is known as a technique for improving the data communication speed. In bulk transmission, a plurality of channels are bundled as one line, and data transmission is performed via this line. (For example, see Patent Document 2)

JP 2002-152709 A JP-A-6-152636

However, the technique of Patent Document 1 described above has a downlink signal transmission rate of up to 30 Mbps with 64 QAM modulation (Quadrature Amplitude Modulation) and an uplink signal communication rate of QPSK modulation (Quadrature Phase Shift Keying: Four-phase phase keying). Since the maximum is 4.6 Mbps in shift modulation, there is a problem that a transmission speed comparable to a high-speed service such as FTTH (Fiber To The Home) cannot be obtained. This is because DOCSIS (Data Over Cable Service Interface Specifications) defines transmission schemes such as modulation schemes and transmission bandwidths.
Therefore, in order to increase the communication speed, for example, as a unique system, a high-level multi-level modulation system such as 1024QAM modulation is adopted as the downstream signal modulation system, and the transmission bandwidth is increased to increase the modulation speed (modulation symbol rate). However, since both methods require high signal transmission quality, there is a problem of high cost due to the modification of the conventional CATV transmission line and the introduction of a new system.
In addition, the technique of Patent Document 2 discloses a technique for transmitting data across a plurality of channels between a center apparatus and a terminal apparatus via a digital circuit switching network such as ISDN, but using a CATV line. Bulk transmission could not be performed.
In view of these problems, the present invention has been made, and a first object of the present invention is to provide a cable modem system that enables a high communication speed by using a CATV transmission line.
A second object is to provide a cable modem system in which high speed communication and normal speed communication can coexist.
A third object is to provide a cable modem system that improves the frequency utilization efficiency of the CATV transmission line.
A fourth object is to provide a cable modem system that can be easily applied to an existing CATV system and can realize low cost.
A fifth object is to provide a modem management apparatus that enables a high communication speed using a CATV transmission line.

In order to solve the above problems, the invention of claim 1 is a cable modem in which a plurality of cable modem termination devices and a plurality of cable modems are connected to a CATV network to enable data communication between a center device and a plurality of terminals. In the system, the speed input means for inputting the data communication speed, the speed determination means for determining whether or not the input data communication speed can be processed by one cable modem, and at least input to the modem management device A plurality of modem registration means for registering a plurality of cable modems constituting a pair with a plurality of cable modem terminators when it is determined that the data communication speed cannot be processed by a single cable modem; and the cable modem terminator and the cable modem Channel setting method for setting a channel used for data communication to an empty channel for transmitting a CATV network And a data communication between the center device and the plurality of terminals via the plurality of cable modems that form a pair with the plurality of cable modem termination devices.

According to a second aspect of the present invention, the channel setting means is configured to be set to non-continuous empty channels.

The invention of claim 3 is a modem management device used in the cable modem system according to claim 1 or claim 2, wherein at least an input device for inputting a data communication speed, a storage device, and an input device are input. Based on the data communication speed, the number of modems required is calculated and registered in the storage device, and each cable modem termination device and a control device for setting a transmission channel corresponding to each cable modem are provided. Is done.

As described above in detail, according to the first aspect of the present invention, a cable that enables data communication between a center device and a plurality of terminals by connecting a plurality of cable modem termination devices and a plurality of cable modems to the CATV network. In a modem system, at least a speed input means for inputting a data communication speed and a speed determination means for determining whether or not the input data communication speed can be processed by one cable modem are input to the modem management device. A plurality of modem registration means for registering a plurality of cable modems forming a pair with a plurality of cable modem termination devices, the cable modem termination device and the cable Channel setting for setting the channel used by the modem for data communication to an empty channel for transmitting the CATV network And a stage, through a plurality of cable modems that make up the plurality of cable modem termination system paired, since to perform the data communication between the center apparatus and a plurality of terminals,
It is possible to provide a cable modem system that enables high-speed communication speed using a CATV transmission line and that allows high-speed communication and normal-speed communication to coexist.

According to the invention of claim 2, the channel setting means is set to a non-continuous empty channel.
It is possible to provide a cable modem system that can improve the frequency utilization efficiency of the CATV transmission line, can be easily applied to an existing CATV system, and can realize a low cost.

According to a third aspect of the present invention, there is provided a modem management device used in the cable modem system according to the first or second aspect, wherein at least an input device for inputting a data communication speed, a storage device, and an input Since the necessary number of modems is calculated based on the data communication speed and registered in the storage device, each cable modem terminator and a control device for setting a transmission channel corresponding to each cable modem are provided. ,
By using the CATV transmission line, a modem management device that enables a high communication speed can be provided.

Hereinafter, an example of an embodiment embodying the present invention will be described in detail with reference to the drawings.
FIG. 1 is a block diagram showing an example of an embodiment of a cable modem system according to the present invention. FIG. 2 is a block diagram showing details of the dividing / combining apparatus. FIG. 3 is a block diagram showing details of the modem management apparatus.
In FIG. 1, reference numeral 1 denotes a center device, which includes an input terminal 1b for connecting a VHF antenna 2, an input terminal 1c for connecting a UHF antenna 3, and an input terminal 1d for connecting an SHF antenna 4, and receiving by each antenna. The television signal and the television signal for independent broadcasting (not shown) are transmitted to the terminal terminal 12, and the terminal 11 such as a request signal from the personal computer 11 and a response signal to the request signal (that is, Internet information in other words) are transmitted to the terminal. Data is transmitted between the machine 11 and the WAN (wide area network). Note that 1a is a terminal for connecting the WAN, and 1e is an output terminal. An optical cable 5 is a transmission medium for connecting the center device 1 and the node type optical transceiver 6. A trunk line distribution amplifier 7, a trunk branching amplifier 8, and a branching unit 9 are connected between the node type optical transceiver 6 and the terminal 12 via a coaxial cable 10. 20 is a terminal device, 20a is an output terminal, and 20b is an input terminal. Reference numeral 30 denotes a cable modem.

The center device 1 includes a router 100 as a relay device for connecting WAN and CATV lines to each other, a request signal from the user 1 who desires high-speed transmission (request signal from the terminal device 11a), or high-speed transmission. Whether the request signal is from a general user 2 who does not wish to be received (request signal from the terminal device 11b) or the specific information (for example, MAC address) included in the request signal and the response signal, ) A known L2 switch (second layer (data link layer) of the OSI basic reference model) 110 for switching to the 130 side or the cable modem termination device (CMTS) 135 side is provided. Note that 110a to 110e represent port numbers. In addition, a request signal (request signal from the terminal device 11a) divided for each frame from the user 1 who desires high-speed transmission is combined, and a plurality of response signals corresponding to the request signal are provided for each frame. Data modem / divider 120 for distributing to cable modem terminators (CMTS) 130a, 130b, 130c, and a plurality of cable modem terminators (CMTS) for processing request signals and response signals of user 1 who desires high-speed transmission. ) 130.
On the other hand, a cable modem terminator (CMTS) 135 for processing a request signal from a general user 2 who does not desire high-speed transmission (request signal from the terminal device 11b), and the request signal and the response signal are mixed or distributed. A distribution / mixing device 140, a distribution / mixing device 145, a head end device (mixing device) 150 for mixing the television signal and the request signal and the response signal are provided.
The center apparatus 1 includes various servers 111 (WWW server, mail server, DNS server, etc.).
The center device 1 is provided with a modem management device 115.

Next, the data dividing / combining device 120 (200) will be described in detail with reference to FIG.
The data dividing / combining devices 120 and 200 include one input / output terminal 120a (200a) connected to the WAN or terminal, and a plurality of input / output terminals 120b to 120d (connected to the cable modem termination device or cable modem). 200b-200d). In addition, a switch 121 (201) for dividing and combining data for each frame, a buffer memory 122 (202) for storing data of one frame, and a bulk control device 123 (203) are provided. Yes. The bulk control device controls the transmission side and the reception side so that the order of frame data is the same by adjusting the transmission timing of each frame data.

As shown in FIG. 3, the modem management device 115 is formed by a personal computer, and includes an input device 118 for inputting a data communication speed and an output device 119 for confirming the input information, and the input data communication. A storage device 116 for calculating and registering the number of necessary modems based on the speed and a control device 117 for setting each cable modem terminator and a transmission channel corresponding to each cable modem are provided.

Further, the terminal device 20 divides the request signal output from the terminal 11a into each frame and outputs it to each of the cable modems 210a to 210c, and the center device 1 (more specifically, the data corresponding to the request signal). A data dividing / combining device 200 for returning the response signal divided by the dividing / combining device 120) to the original response signal, a plurality of cable modems 210a, 210b, 210c, and a distributor / mixer 220 are provided.
Here, cable modem terminators (CMTS) 130a, 130b, 130c, and 135 correspond to the cable modems 210a, 210b, 210c, and 30, respectively, and transmit in different frequency bands.

Next, the signal flow will be described. First, a terrestrial broadcast television signal received by the VHF antenna 2 and the UHF antenna 3, a satellite broadcast or satellite communication television signal received by the SHF antenna 4, and a self-broadcast television signal (not shown) Mixed by the end device 150. Further, the optical signal is converted into an optical signal by an optical transceiver built in the headend device 150 and output to the optical cable 5 through the output terminal 1e. The television signal converted into the optical signal is converted into an electrical signal of a high frequency signal by the node type optical transceiver 6 through the optical cable 5 and output to the coaxial cable 10. The television signal converted into the high frequency signal is transmitted to the terminal terminal 12 through the coaxial cable 10, the trunk distribution amplifier 7, the trunk branching amplifier 8, and the branching unit 9, and is received by a television receiver or the like (not shown). I can enjoy it.
The frequency band of the downstream signal flowing through the coaxial cable in this embodiment is, for example, 70 MHz to 602 MHz, and the frequency band of the upstream signal is 10 MHz to 55 MHz and 650 MHz to 770 MHz.

Next, data transmission will be described in detail.
First, when operating power is supplied to the cable modem termination device (CMTS) 130/135, the cable modem (CM) 210/30, the modem management device (MMS) 115, and the data division / combining device 120/200, the operation will be described later. The modem determination process is started, and the user 1 who desires high-speed transmission and the general user 2 who does not desire high-speed transmission perform data communication between the center apparatus 1 and the terminal 11 at the corresponding communication speeds. Can do.

Next, modem determination processing will be described. The modem determination process occurs when a new subscriber or a contract is changed, and is executed by the control device 117 of the modem management device 115. As shown in FIG. 4, when the modem determination process is started, in step 300 (hereinafter referred to as S300), the communication speed V is input according to the contract communication speed for each customer. Next, it is determined whether or not the communication speed input in S310 can be processed by one cable modem. In this embodiment, the standard for determining the communication speed that can be processed by one cable modem is 42.8 Mbps (256 QAM) for downlink and 10.24 Mbps (16 QAM) for downlink. If it is determined that the contracted communication speed input in S310 is higher than the communication speed that can be processed by one cable modem, it cannot be processed by one cable modem. Therefore, in S320, the optimum number of modems for bulk transmission is determined. It comes to calculate. For example, in the case of downlink 100 Mbps and uplink 30 Mbps, it is possible to use three cable modem pairs for both downlink and uplink. On the other hand, when it is determined that the contract communication speed input in S310 can be processed by one cable modem, 1 is set to the variable M in S330. When the number of modem pairs is determined, the modem pair is registered in the storage device in S340. In S350, empty channel data not transmitting television signals or communication signals to the modem pair via the CATV line is read from the storage device of the management device and assigned to the modem pair, and the empty channel data is updated and re-registered in the storage device. . Then, in S360, the variable M is decremented and the process proceeds to S370. In S370, it is checked whether or not the variable M is zero, and the processes from S340 to S360 are executed until the variable M becomes zero (in other words, until there is no modem pair not registered).
As described above, by executing the modem determination process, high-speed data communication can be realized using the CATV line, and a customer who wants high-speed data communication (a customer who places importance on speed rather than a charge) and a normal communication speed. A cable modem system that can be mixed with customers who want to (a customer whose speed is moderately balanced with the price) can be provided. Furthermore, since it is not always necessary to set transmission channels (transmission frequencies) continuously, transmission channels have already been determined as in existing CATV facilities, and continuous transmission channels cannot be secured. However, if the present invention is applied, the vacant channels that have been skipped can be bundled into one for high-speed transmission.

Next, the flow of the data signal will be described.
First, a user 1 who desires high-speed transmission uses a modem pair determined in the modem determination process (in this embodiment, three pairs of cable modem terminators 130a to 130c and cable modems 210a to 210c). When a request signal is output to the WAN from the personal computer 11a connected to the terminal terminal 12a used by the user 1 who desires high-speed transmission, the data is divided via the output terminal 20a of the terminal device 20. • Captured by the coupling device 200. The request signal fetched by the data division / combination device 200 is divided for each data frame by the data division / combination device, and the cable modem 210a, cable modem 210b, and cable modem 210c respectively use predetermined high-frequency signals (eg, 653 MHz and 671 MHz). , 713 MHz) and output to the terminal terminal 12a (input terminal 20b) via the distributor / mixer 220. The division request signal converted into the high-frequency signal output to the terminal 12a is taken into the node type optical transceiver 6 via the coaxial cable 10, the branching unit 9, the trunk branching amplifier 8, and the trunk distribution amplifier 7, and the optical signal. Then, the signal is transmitted to the center device 1 through the optical cable 5, taken into the optical transceiver in the head end device via the output terminal 1e, and converted into the original high-frequency electric signal. The division request signal converted into the high-frequency electrical signal taken into the head end device 1 is demodulated by the cable modem termination devices 130a to 130c, and is combined with the original request signal by the data division / combination device 120, and the L2 switch 110 Is taken in. The request signal captured by the L2 switch 110 detects the destination MAC address of the request signal, stores the detected MAC address and the port number (110b in this embodiment) in the L2 switch 110, and outputs it to the router 100. , The input terminal 1a is connected to the server (not shown) constituting the WAN (for example, the Internet) based on the request signal.

Next, a response signal from the server corresponding to the request signal is taken into the center apparatus 1 from the WAN via the input terminal 1a. The response signal captured by the center device 1 is captured by the L2 switch via the router 100, and the destination MAC address of the response signal is detected and matched with the destination MAC address stored in the L2 switch. The data is retrieved and output to the port number (110b in this embodiment), that is, to the data dividing / combining device 120. The response signal received by the data dividing / combining device 120 is divided into frames to generate divided response signals, which are output to the cable modem terminators 130a, 130b, 130c, respectively, and have different frequency bands (456 MHz in this embodiment, 468 MHz and 504 MHz), and is taken into the head end device 150 via the distributor / mixer 140 and the distributor / mixer 145. The division response signal converted into the high-frequency signal captured by the head end device 150 is converted into an optical signal by an optical transceiver provided in the head end device 150 and output to the optical cable 5 from the output terminal 1e. The split response signal of the high frequency signal converted into the optical signal is converted into an electrical signal of the high frequency signal by the node type optical transceiver 6 via the optical cable 5 and output to the coaxial cable 10. The divided response signal converted into the high frequency signal is transmitted to the terminal terminal 12a via the coaxial cable 10, the main line distribution amplifier 7, the main line branching amplifier 8, and the branching unit 9. The division response signal of the high frequency signal transmitted to the terminal terminal 12a is demodulated by the plurality of cable modems 210a, 210b, and 210c via the input terminal 20b of the terminal device 20 and the distributor / mixer 220, respectively, and the data dividing / combining device 200. The response signal is output to the personal computer 11a as a terminal through the output terminal 20a.
With this configuration, it is possible to achieve a high communication speed using the CATV transmission line, and to achieve excellent effects that high speed communication and normal speed communication can coexist. Further, since a continuous channel (frequency) is not required for data communication, the frequency utilization efficiency of the CATV transmission line is improved, and it can be easily applied to an existing CATV system, and can be applied to an existing CATV system at a low cost and at a high speed such as FTTH. It has excellent effects such as being able to obtain transmission speeds comparable to services.
In this embodiment, the downlink signal modulation method is 256 QAM (bandwidth 6 MHz), the uplink signal modulation method is 16 QAM (bandwidth 3 MHz), and parallel processing is performed using three existing cable modems. An upstream communication speed of 30 Mbps was achieved.

The general user 2 who does not desire high-speed transmission uses the modem pair determined in the modem determination process (in this embodiment, the pair of the cable modem terminator 135 and the cable modem 30). When a request signal is output to the WAN from the personal computer 11b connected to the terminal terminal 12b used by the general user 2 who does not desire high-speed transmission, the cable modem 30 causes a predetermined high-frequency signal (for example, , 665 MHz) and output to the terminal terminal 12b. The request signal converted into the high-frequency signal output to the terminal 12b is taken into the node type optical transceiver 6 via the coaxial cable 10, the branching device 9, the main branching amplifier 8, and the main distribution amplifier 7, and converted into an optical signal. After the conversion, the signal is transmitted to the center device 1 through the optical cable 5, taken into the optical transceiver in the head end device via the output terminal 1e, and converted into the original high-frequency electric signal. The request signal converted into the high-frequency electrical signal captured in the head end device 1 is demodulated by the cable modem termination device 135 and captured by the L2 switch 110. The request signal fetched into the L2 switch 110 detects the destination MAC address of the request signal, stores the detected MAC address and the port number (110c in this embodiment) in the L2 switch 110, and outputs it to the router 100. , The input terminal 1a is connected to the server (not shown) constituting the WAN (for example, the Internet) based on the request signal.

Next, a response signal from the server corresponding to the request signal is taken into the center apparatus 1 from the WAN via the input terminal 1a. The response signal captured by the center device 1 is captured by the L2 switch via the router 100, and the destination MAC address of the response signal is detected and matched with the destination MAC address stored in the L2 switch. It is retrieved and output to the port number (110c in the present embodiment), that is, output to the cable modem termination device 135, and converted to a signal in a frequency band (474 MHz in this embodiment) different from the output frequency band of the cable modem termination device 130. It is taken into the head end device 150 via the distributor / mixer 145. The response signal converted into the high-frequency signal captured by the head end device 150 is converted into an optical signal by an optical transceiver provided in the head end device 150 and output to the optical cable 5 from the output terminal 1e. The response signal of the high frequency signal converted into the optical signal is converted into the original electrical signal of the high frequency signal by the node type optical transceiver 6 via the optical cable 5 and output to the coaxial cable 10. The response signal converted into the high frequency signal is transmitted to the terminal terminal 12b through the coaxial cable 10, the main line distribution amplifier 7, the main line branching amplifier 8, and the branching unit 9. The response signal of the high frequency signal transmitted to the terminal terminal 12b is demodulated by the cable modem 30, and the response signal is output to the personal computer 11b as the terminal.

Here, S300 corresponds to the speed input means of the present invention, S310 corresponds to the speed determination means of the present invention, S340 corresponds to the multiple modem registration means of the present invention, and S350 corresponds to the channel setting means of the present invention. To do.

It should be noted that the present invention is not limited to the above embodiment, and can be implemented with appropriate modifications without departing from the spirit of the present invention. For example, in the first embodiment, the judgment criteria that can be processed by one cable modem are 42.8 Mbps for downlink and 10.24 Mbps for uplink. However, the determination criteria are not limited to this, and can be set according to the state of technological progress. Good. Further, in this embodiment, bidirectional data has been described. However, only one direction may be used if necessary. Also, in this embodiment, when registering cable modem terminators, it is divided into a group that performs bulk transmission (cable modem terminator 130) and a low-speed group that can be processed by one ordinary cable modem (cable modem terminator 135). However, it is not always necessary to separate them. For example, the same effect can be obtained by assigning one of the cable modem terminators 130a to 130c instead of the cable modem terminator 135.

1 is a block diagram showing an example of an embodiment of a cable modem system according to the present invention. It is a block diagram which shows the detail of a division | segmentation / coupling | bonding apparatus. It is a block diagram which shows the detail of a modem management apparatus. It is a flowchart of the modem determination process which a modem management apparatus performs.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 ... Center apparatus, 2 ... VHF antenna, 3 ... UHF antenna, 4 ... SHF antenna, 5 ... Optical cable, 6 ... Node type optical transceiver, 7 ... Trunk distribution amplifier, 8 ... Trunk branch amplifier, 9 ... Branch 10 ... Coaxial cable, 11 ... Terminal, 12 ... Terminal terminal, 20 ... Terminal device, 30 ... Cable modem, 100 ... Router, 110 ... L2 switch, 111 ... Various servers, 115 ... Modem management device, 116 ... Memory 117, control device, 118 ... input device, 119 ... output device, 120 ... data division / combination device, 121 ... switch, 122 ... buffer memory, 123 ... bulk control device, 130 ... cable modem termination device (CMTS), 140 ... Distributor / Mixer, 145 ... Distributor / Mixer, 150 ... Head-end device (Mixer), 200 ... Data division / combination Location, 201 ... switch, 202 ... buffer memory, 203 ... bulk controller, 210 ... cable modem, 220 ... distributor-mixer.

Claims (3)

In a cable modem system in which a plurality of cable modem terminators and a plurality of cable modems are connected to a CATV network to enable data communication between a center device and a plurality of terminals.
A speed input means for inputting the data communication speed to the modem management device;
Speed judging means for judging whether or not the input data communication speed can be processed by one cable modem;
A plurality of modem registration means for registering a plurality of cable modems forming a pair with a plurality of cable modem terminators when it is determined that at least the input data communication speed cannot be processed by a single cable modem;
A plurality of cable modems comprising a pair of the cable modem terminator and a channel setting means for setting a channel used by the cable modem for data communication as an empty channel for transmitting a CATV network; A cable modem system characterized by data communication between the center unit and multiple terminals via
2. The cable modem system according to claim 1, wherein the channel setting means is set to a discontinuous free channel.
A modem management device used in the cable modem system according to claim 1 or 2, wherein at least an input device for inputting a data communication speed,
A storage device;
Based on the input data communication speed, the number of necessary modems is calculated and registered in the storage device, and each cable modem termination device and a control device for setting a transmission channel corresponding to each cable modem are provided. A modem management device characterized by that.

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