KR20200144224A - Communication modem, communication system comprising the communication modem, and construction method thereof - Google Patents

Abstract

The present invention relates to a communication modem for easy management and maintenance, a communication system including the same, and a construction method of the communication system. According to the present invention, the communication system comprises: a signal/power transmission device provided in the home, having a first LAN port and a second LAN port, and transmitting power and a communication signal inputted through the first LAN port through the second LAN port; and a communication modem provided in a terminal box in a building and operated using power supplied through the LAN port of the signal/power transmission device in the house. The communication modem includes a LAN port connected to the second LAN port of the signal/power transmission device, an optical port to which an optical cable is connected, a signal processing unit converting the communication signal received through the LAN port into an optical signal and transmitting the optical signal through the optical cable connected to the optical port, and a power processing unit contacting at least two pins of the LAN ports and receiving the power through the pins.

Description

Communication modem and communication system including the same, and construction method thereof {COMMUNICATION MODEM, COMMUNICATION SYSTEM COMPRISING THE COMMUNICATION MODEM, AND CONSTRUCTION METHOD THEREOF}

The present invention relates to a communication modem, a communication system including the same, and a method of constructing the same, and more particularly, a communication modem necessary for use of a service such as the Internet in each home of a building in which several households live, and a communication system including the same And its construction method.

Communication companies install communication modems to use Internet services in each home, and connect a home computer or router to the communication modem.

Here, the communication modem is for converting communication signals generated from a computer, etc. into a communication method provided to a communication company. For example, in the past, it was connected to a telephone line to transmit Internet data through a telephone line, and recently, it was connected to an optical cable to transmit optical signals It is also converted to and transmitted Internet data.

In order to use the Internet service in each home, it is essential to have such a communication modem. In the case of villas, apartments, and multi-family houses, installing such a communication modem in each house may be cumbersome or expensive. do.

For example, in the case of a communication modem that is directly connected to an optical cable and transmits the communication signal in the house as an optical signal, an optical cable must go into each house. In the case of a villa, apartment, and multi-family house that were built, optical cables to each house Since it does not contain this, it is costly and time-consuming to install an optical cable.

Publication Patent No. 10-2002-0033871

The present invention has been devised to solve the above-described problems in the related art, and an object thereof is to provide a communication modem that is easy to install, manage, and maintain, a communication system including the same, and a method of constructing the same.

In order to achieve the above object, the communication system according to the present invention is provided in a premises, includes a first LAN port and a second LAN port, and transmits power and a communication signal input through the first LAN port to the second A signal/power transmission device transmitted through a LAN port; A communication modem provided in a terminal box in a building and operating using power supplied through the LAN port of the signal/power transmission device in the house, wherein the communication modem includes a second LAN of the signal/power transmission device A LAN port connected to the port; An optical port to which an optical cable is connected; A signal processing unit converting the communication signal received through the LAN port into an optical signal and transmitting it through an optical cable connected to the optical port; And a power processing unit that contacts at least two pins of the LAN ports and receives power through the corresponding pins.

In addition, in order to achieve the above object, the method for building a communication system according to the present invention includes a first LAN port and a second LAN port, and transmits power and a communication signal input through the first LAN port to the second LAN port. Installing a signal/power transmission device for transmission through a communication cable connected to the premises; LAN port; An optical port to which an optical cable is connected; A signal processing unit converting the communication signal received through the LAN port into an optical signal and transmitting it through an optical cable connected to the optical port; Installing a communication modem including a power processing unit that contacts at least two pins of the LAN ports and receives power through the corresponding pins in a terminal box in a building premises; And connecting the second LAN port of the signal/power transmission device and the LAN port of the communication modem to each other.

In order to achieve the above object, a communication modem according to the present invention includes a LAN port to which a LAN cable is connected; An optical port to which an optical cable is connected; A signal processing unit converting the communication signal received through the LAN port into an optical signal and transmitting it through an optical cable connected to the optical port; And a power processing unit that contacts at least two pins of the LAN ports and receives power through the corresponding pins.

Here, a voltage conversion unit for supplying power to at least one element inside the communication modem by performing a voltage conversion operation after receiving power from the power processing unit; A power cut-off control unit configured to cut off power supply by controlling at least one of the voltage conversion unit and the power processing unit when determining a preset error occurrence situation may be further included.

Here, the power cut-off control unit may control the voltage converter to cut off the power supply, and then control the power processing unit to cut off the power supply second when the error occurrence condition is maintained for a preset time.

Here, the power cut-off control unit may determine that an error occurs when a magnitude of a current or voltage input from a pre-equipped temperature sensor or a current sensor exceeds a preset value.

As described above, according to the present invention, it is possible to install a communication modem in a terminal box in a building, even if a separate power source is not installed in the terminal box in a building premises, and without using common electricity.

Since the communication modem can be installed and operated in the terminal box in the building premises, there is no need to extend the optical cable to the premises, and furthermore, in the event of a communication modem replacement or malfunction, the repair technician does not visit each home, but at the terminal box in the building premises. Because it can be processed, costs associated with equipment installation, management and operation can be reduced.

1 is a schematic configuration diagram of an entire communication system including a communication modem according to an embodiment of the present invention,
2 is a functional block diagram of the communication modem of FIG. 1;
3 is a schematic configuration diagram of a conventional overall communication system compared to FIG. 1,
4 is an example of a specific configuration of a communication modem for detecting and processing an overcurrent,
5 is an example of a specific configuration of a communication modem for detecting and processing a temperature surge,
6 is a control flow diagram of the communication modem of FIG. 1.

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

Hereinafter, each embodiment according to the present invention is only one example for aiding understanding of the present invention, and the present invention is not limited to these embodiments. In particular, the present invention may be configured with a combination of at least one or more of individual configurations, individual functions, or individual steps included in each embodiment.

In particular, for convenience, some claims in the claims include alphabets such as'(a)', but these alphabets do not prescribe the order of each step.

In addition, each signal mentioned in each embodiment according to the present invention may mean one signal transmitted by one connection or the like, but may also mean a series of signal groups transmitted for the purpose of performing a specific function to be described later. . That is, in each embodiment, a plurality of signals transmitted at a predetermined time interval or transmitted after receiving a response signal from a counterpart device may be expressed as one signal name for convenience.

A schematic configuration of an entire communication system including a communication modem 100 according to an embodiment of the present invention is as shown in FIG. 1.

As shown in the figure, the entire communication system includes a communication modem 100, a signal/power transmission device 200, and furthermore, a router 300, a remote node 500, a computer device 400, It may be configured to include an optical path termination device 600.

Here, the optical line termination device (OLT) 600 is an optical subscriber network configuration device that is installed in the office and connects the backbone network and the subscriber network to each other, and serves to terminate the subscriber optical signal at the office side, and the router 300 Is to enable a plurality of communication equipment provided in the house to communicate with the outside through one line, the remote node 500 is an optical communication network unit (ONU) or an indoor optical termination device ( ONT, which corresponds to a device/node accommodating an optical splitter (splitter) at a point distributed to the communication modem 100 in the present embodiment, these devices are all known only, and thus a more detailed description thereof will be omitted.

In this embodiment, the remote node 500 and the communication modem 100 are installed in the terminal box in the building, and the signal/power transmission device 200 and the common land are installed in each individual premises, and a more detailed description thereof will be described later. Do it.

First, the signal/power transmission device 200 is provided in the house and performs a function of supplying power (current or voltage) through a predetermined LAN port 110.

For example, when the first LAN port 110 and the second LAN port 110 are provided in the signal/power transmission device 200, the signal/power transmission device 200 uses the first LAN port 110. The communication signal input through the second LAN port 110 is transmitted through the second LAN port 110 and a function of supplying predetermined power through the second LAN port 110 is also performed.

Supplying power using a predetermined cable itself corresponds to a known technology, so a more detailed description thereof will be omitted. However, in the case of the present invention, the signal/power transmission device 200 is different from a general power adapter in that power is supplied through a LAN cable connected to the LAN port 110.

On the other hand, the communication modem 100 converts a communication signal into a signal prescribed by a communication company and transmits it so that the in-house subscriber can use the Internet service, and a specific functional block of the communication modem 100 is shown in FIG. 2. As it is.

As shown in the figure, the communication modem 100 includes a LAN port 110, an optical port 120, a signal processing unit 130, a power processing unit 140, a voltage conversion unit 150, and a power cut-off control unit 160. It can be configured to include.

Here, the LAN port 110 is a LAN cable such as UTP (Unshielded Twist Pair: Unshielded Twisted Pair), FTP (Foil Screened Twist Pair Cable), STP (Shielded Twist Pair Cable: Shielded Twisted Pair), etc. are connected, for example, RJ -45, of course, may correspond to RJ-10, RJ-11, RJ-12, etc.

The optical port 120 is to which an optical cable is connected, and may be configured in a form corresponding to various types of optical cables such as an LC type, an SC type, and an ESCON type.

The signal processing unit 130 converts the communication signal received through the LAN port 110 into an optical signal and transmits it through an optical cable connected to the optical port 120. Can transmit signals.

Since converting a predetermined communication signal into an optical signal itself corresponds to a known technique, a more detailed description will be omitted.

The power processing unit 140 contacts at least two pins of the LAN port 110 to receive power through the corresponding pins.

That is, as described above, the signal/power transmission device 200 performs a function of supplying power as well as a communication signal through the second LAN port 110 provided to itself, and the power processing unit 140 / It performs a function of processing the power supplied by the power transmission device 200.

As described above, the communication modem 100 according to the present embodiment operates by using power supplied by the signal/power transmission device 200 through a LAN cable. By this configuration, the communication modem 100 is Unlike the conventional one, it is not provided in the house, but can be installed in the terminal box in the building.

Of course, there are cases where a separate power outlet is provided in the terminal box, but in this case, using the power outlet is the same as using common electricity, so it is not possible to use it at home.

In addition, when a separate power outlet is not provided in the building terminal box, the communication modem 100 cannot be installed in the building terminal box as in the present embodiment, but the communication modem 100 is used as a signal/power source as in the embodiment of the present invention. Since power supplied through the LAN port 110 and the LAN cable from the transmission device 200 can be used, it is possible to install the communication modem 100 in a terminal box in a building.

This can be more clearly distinguished when compared to the conventional system configuration.

Figure 3 corresponds to the system configuration for providing a conventional optical LAN service, the L3 switch is located in the office, only the CO (concentration) device accommodating the communication modem 100 in each premises is installed in the terminal box in the building, and the communication modem It can be seen that (100) is installed in the house to receive power through a power outlet in the house.

In this case, since the optical cable cannot be directly connected between the CO (concentrator) device and the communication modem 100 in the home, it is bound to be connected by a general telephone line. Therefore, an optical signal communication modem that directly transmits an optical signal through an optical cable cannot be installed in the house, and eventually, a proper communication speed cannot be provided.

On the other hand, in the communication system according to an embodiment of the present invention, as shown in FIG. 1, a communication modem 100 is installed in a terminal box in a building, and a signal/power transmission device 200 is installed in the house. Even if the optical cable is not connected, each subscriber can use the optical signal communication modem 100.

In particular, when the communication modem 100 is installed in a terminal box in a building instead of being provided in the house as in the present invention, there is an effect that service technicians can smoothly proceed with the work of checking or replacing the communication modem 100.

Meanwhile, the voltage converter 150 performs a function of supplying power to at least one element inside the communication modem 100 by performing a voltage conversion operation after receiving power from the power processing unit 140.

For example, when the voltage of the power supplied by the signal/power transmission device 200 is 12V, and the power processing unit 140 receives it and transmits it to the voltage converter 150 as it is, the voltage converter 150 Each element in the communication modem 100 can convert and supply the voltage of the power source.

The power cut-off control unit 160 controls at least one of the voltage conversion unit 150 and the power processing unit 140 to cut off power supply when determining a preset error occurrence situation.

For example, when the magnitude of the current or voltage input from the pre-equipped temperature sensor 170 or the current sensor 180 exceeds a preset value, it is determined that an error occurs, and the above-described power-off operation is performed.

In performing the power-off control, the power-off control unit 160 primarily controls the power supply by the voltage converter 150 to be cut off, and then the power processing unit 140 when an error occurs for a preset time period. By controlling the power supply can be cut off the second time.

An example of a circuit configuration for this processing is specifically shown in FIGS. 4 and 5.

In FIGS. 4 and 5, the MCU 160 corresponds to the power cut-off control unit 160, the PD IC (Power Delivery Integrated Chip) corresponds to the power processing unit 140, and the regulator corresponds to the voltage converter 150. .

The MCU 160 may receive temperature information or an analog signal through communication such as the temperature sensor 170 and I2C. When an I2C signal is received from the temperature sensor 170, the current The temperature is determined, and when an analog signal is received, ADC (Analog to Digital Conversion) processing is performed to determine the current temperature.

After determining the current temperature based on the signal received from the temperature sensor 170 as described above, the MCU 160 compares the current temperature with a preset temperature, and as a result of the comparison, an error occurs when the current temperature exceeds the preset temperature. It can be judged as.

When it is determined that an error occurs as described above, the MCU 160 controls the regulator 150 to cut off the power supply.

In this way, when the current temperature received from the temperature sensor 170 does not fall below the preset temperature even though a preset time has elapsed after the power supply by the regulator 150 is cut off, the MCU 160 additionally includes the PD IC 140 Is controlled so that the power supplied by the PD IC 140 is also cut off.

That is, the targets to which the PD IC 140 and the regulator 150 supply power may be different, but the MCU 160 does not cut off all power from the time it initially determines that an error occurs, but performs a primary cutoff. After proceeding, if the error occurrence situation is not resolved, the second blocking is performed.

5 shows a configuration for determining an overcurrent state through the current sensor 180.

The MCU 160 may determine the overcurrent state by measuring the voltage across both ends of the current sensor 180, and when it is initially determined that the overcurrent state is determined by determining the signal input from the first current sensor 181, the MCU 160 is a regulator Even though a preset time has elapsed since the first power cut off as a result of the determination based on the signal input from the second current sensor 182 after the control 150 so that the power supplied to the corresponding regulator 150 is first cut off. When it is determined that it is an overcurrent state, the PD IC 140 is controlled so that the power supplied by the corresponding PD IC 140 is cut off.

6 is a control flow diagram illustrating a process of turning off power through sequential control when the communication modem 100 according to an embodiment of the present invention has a high temperature.

The communication modem 100 receives a temperature sensing signal from the temperature sensor 170 provided therein (step S1), and determines the current temperature from the received temperature sensing signal (step S3).

As a result of the determination, when the current temperature is higher than the preset temperature (step S5), the communication modem 100 stops the operation of the regulator 150 (step S7).

Thereafter, after a predetermined time has elapsed (step S9), the communication modem 100 receives a temperature sensing signal from the temperature sensor 170 again (step S11) to determine the current temperature (step S13), and as a result of the determination, the current When the temperature is higher than the preset temperature (step S15), the operation of the PD IC 140 is secondarily stopped (step S17).

Meanwhile, it goes without saying that the process of performing each of the above-described embodiments may be performed by a program or application stored in a predetermined recording medium (eg, computer-readable). Here, the recording medium includes all of an electronic recording medium such as a random access memory (RAM), a magnetic recording medium such as a hard disk, and an optical recording medium such as a compact disk (CD).

At this time, the program stored in the recording medium may be executed on hardware such as a computer or a smart phone to perform each of the above-described embodiments. In particular, at least one of the functional blocks of the communication modem according to the present invention described above may be implemented by such a program or application.

In addition, the present invention is not limited to the specific embodiments described above, but can be implemented by various modifications and modifications without departing from the gist of the present invention. It will be apparent that such modifications and modifications are included in the present invention if they fall within the appended claims.

100: communication modem 200: signal/power transmission device
300: router 400: computer device
500: remote node 600: optical fiber termination device
110: LAN port 120: optical port
130: signal processing unit 140: power processing unit
150: voltage conversion unit 160: power cut-off control unit

Claims (6)

A signal/power transmission device provided in the home, having a first LAN port and a second LAN port, and transmitting power and a communication signal input through the first LAN port through the second LAN port;
A communication modem provided in a terminal box in a building and operating using power supplied through the LAN port of the signal/power transmission device in the house,
The communication modem includes: a LAN port connected to a second LAN port of the signal/power transmission device; An optical port to which an optical cable is connected; A signal processing unit converting the communication signal received through the LAN port into an optical signal and transmitting it through an optical cable connected to the optical port; And a power processing unit that contacts at least two pins of the LAN ports and receives power through the corresponding pins. A LAN port to which a LAN cable is connected;
An optical port to which an optical cable is connected;
A signal processing unit converting the communication signal received through the LAN port into an optical signal and transmitting it through an optical cable connected to the optical port;
And a power processor that contacts at least two pins of the LAN ports to receive power through corresponding pins. The method of claim 2,
A voltage converter for supplying power to at least one element inside the communication modem by performing a voltage conversion operation after receiving power from the power processor;
And a power cut-off control unit configured to cut off power supply by controlling at least one of the voltage conversion unit and the power processing unit when determining a preset error occurrence situation. The method of claim 3,
The power cut-off controller controls the power supply by the voltage converter to be cut off, and then controls the power processing unit to cut off the power supply second when the error occurrence condition is maintained for a preset time. . The method of claim 4,
And the power cut-off control unit determines that an error occurs when a current or voltage input from a pre-equipped temperature sensor or a current sensor exceeds a preset value. In the communication system construction method,
(a) A signal/power transmission device having a first LAN port and a second LAN port, and transmitting power and a communication signal input through the first LAN port through a communication cable connected to the second LAN port. Installing;
(b) a LAN port; An optical port to which an optical cable is connected; A signal processing unit converting the communication signal received through the LAN port into an optical signal and transmitting it through an optical cable connected to the optical port; Installing a communication modem including a power processing unit that contacts at least two pins of the LAN ports to receive power through the corresponding pins in a terminal box in a building;
(c) connecting the second LAN port of the signal/power transmission device and the LAN port of the communication modem to each other.

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