KR200475491Y1 - Optical transmitting apparatus in Hybrid Fiber Coaxial and Optical transmitting module including the same - Google Patents

Abstract

The present invention discloses an optical receiving and distributing apparatus for a mixed optical network and a optical receiving and distributing expansion module for a mixed optical network including the same. The optical receiving and distributing apparatus of the present invention includes a photoelectric conversion unit, a branch signal unit, first RF output terminals, and an RF extension terminal. The photoelectric conversion unit is connected to the optical cable to convert the optical signal into an RF signal. The branch signal part receives the RF signal through the photoelectric conversion part to divide a plurality of first RF signals having the same signal loss and branches the second RF signal having a signal loss different from that of the first RF signal. The plurality of first RF output terminals output the first RF signal distributed through the branch signal unit. And the RF extension terminal outputs a second RF signal branched through the branch signal unit.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to an optical receiving and distributing apparatus for a hybrid optical network,

More particularly, the present invention relates to a light receiving and distributing apparatus for a photodetector and a light receiving and distributing apparatus for a photodetector of the same, which can be applied to a photodetector To a distribution extension module.

In recent years, the use of the Internet has increased exponentially in the information age, and the demand for multimedia data has increased, causing bottlenecks in the transmission network. ISDN (general information communication network), ADSL (asymmetric digital subscriber line), cable TV network, satellite and WLL (wireless subscriber network) are used as means for solving such a bottleneck and providing higher speed data service . Of these, cable TV networks have wider bidirectional bandwidths compared to other networks, and many cables are already installed at the subscriber terminals, which is considered to be one of the most feasible networks.

However, since cable networks are designed for broadcast-oriented purposes rather than for interactive multimedia services, it is necessary to improve existing transmission networks in order to provide high-speed data services using cable TV networks. A hybrid fiber coaxial (HFC) network has emerged in response to this demand.

A hybrid fiber coaxial (HFC) network is a fiber-optic cable from a broadcaster to a fiber node, and the remaining cable from the distribution point to a subscriber is a coaxial cable network.

The simplest form of HFC is to utilize fiber optic cable from a broadcasting station to a distribution point that provides service to 500 to 2,000 households. Thereafter, a coaxial line is provided from one light splitting point to the home, and is connected to a set-top box, cable modem, etc., depending on the service.

To this end, a signal passing through an optical core of an optical cable is conventionally received through an optical receiver. The optical receiver converts an optical signal into an RF signal. Thereafter, the RF signal is transmitted to the distributor through the coaxial line, and is connected to each household through the RF terminal of the distributor.

However, conventionally, the optical receiver and the distributor are disposed in separate places. Therefore, it is not easy to maintain and maintain the optical receiver and the distributor separately.

In addition, eight RF terminals are usually disposed in the distributor. However, as the number of terminals capable of viewing an image at home increases, there are cases where the RF terminal is insufficient.

Published Patent No. 10-2009-0025889

The present invention has been made to solve the above-mentioned problems and it is an object of the present invention to provide an optical receiving and distributing apparatus of a mixed optical network with a combined optical receiving function and a distributed function

It is another object of the present invention to provide an optical receiving and distributing device which can be combined with a separate distributor in addition to an integrated function and also function as an optical receiver and an optical receiving and distributing extension module having the same.

The optical receiving and distributing apparatus of the present invention includes a photoelectric conversion unit, a branch signal unit, first RF output terminals, and an RF extension terminal. The photoelectric conversion unit is connected to the optical cable to convert the optical signal into an RF signal. The branch signal part receives the RF signal through the photoelectric conversion part to divide a plurality of first RF signals having the same signal loss and branches the second RF signal having a signal loss different from that of the first RF signal. The plurality of first RF output terminals output the first RF signal distributed through the branch signal unit. And the RF extension terminal outputs a second RF signal branched through the branch signal unit.

The photoelectric conversion unit may include a photoelectric device unit connected to the optical cable and converting the optical signal into an electrical signal, and an RF modulator modulating an electrical signal through the photoelectric device unit into an RF signal. In this case, the RF modulator may include a first amplification unit for first amplifying the negative electrical signal to the photoelectric conversion unit, an attenuator for adjusting the electrical signal passing through the first amplification unit, an electric signal from the attenuator, And outputting an RF signal.

 The present invention may further comprise a light level comparator for determining whether the level of the optical signal input to the photoelectric conversion unit is proper, and a notification unit for informing whether the optical signal is appropriate according to the determination of the light level comparator.

In another aspect of the present invention, an optical receiving and distribution expansion module of a mixed optical network includes a optical receiving and distributing device of the optical attenuating network, a coaxial cable having one end connected to an RF extension terminal of the optical receiving and distributing device, An input terminal connected to the other end of the coaxial cable, a distributor circuit for distributing a plurality of RF signals received through the input terminal, and a plurality of second RF output terminals connected to the distributor circuit.

According to the present invention, photoelectric conversion, modulation with RF signals, signal distribution, and signal distribution functions can be achieved through a single optical receiver and distribution, simplifying installation and AS.

In addition, since the RF terminal is separately connected to the conventional distributor, it is applicable to a place where many RF terminals are required.

FIG. 1 is a block diagram illustrating an optical receiver and a distribution system of a mixed optical network according to a preferred embodiment of the present invention.
2 is a circuit diagram showing an example of a circuit diagram of the branch signal portion in Fig.
3 is a perspective view of the optical receiver and distribution apparatus of the present invention.
4 is a conceptual diagram of the optical receiver distribution extension module in another aspect of the present invention.

Hereinafter, the optical receiving and distributing apparatus of the present invention and the optical receiving and distributing module of the optical attenuating and distributing network including the same will be described in detail with reference to the drawings.

In this case, the optical coaxial mixing network is a system in which a broadcast station receives a broadcast program through an optical cable and supplies the broadcast program to a subscriber through a coaxial cable. The optical receiving and distributing device receives the optical signal from the optical cable, and performs photoelectric conversion, RF signal modulation and distribution, and is connected to the coaxial cable.

FIG. 1 is a block diagram of an optical receiving and distributing apparatus 10 of a mixed optical network according to a preferred embodiment of the present invention. 1, the optical receiving and distributing apparatus 10 of the optical cross-axis mixing network according to a preferred embodiment of the present invention includes a photoelectric conversion unit 20, a branch signal unit 40, RF output terminals 50 and an RF extension terminal 60.

The photoelectric conversion unit 20 is connected to the optical cable to convert the optical signal into an RF signal. In this case, the optical signal may have a wavelength of 1550 nm suitable for broadcasting, for example.

The photoelectric conversion unit 20 may include a photoelectric conversion unit 30 and an RF modulation unit 35. The photoelectric element section 30 includes a photodiode to convert the optical signal into an electrical signal. The present invention may further include a photoelectric conversion unit 30 and a power supply unit 90 for providing power to the RF modulation unit 35. The power supply unit 90 may be provided outside the optical receiving and distributing apparatus 10.

The RF modulator 35 modulates an electrical signal through the optoelectronic device 30 into an RF signal. An RF signal refers to a high frequency signal used for wireless communication or the like. Video refers to a signal such as an antenna-to-TV signal for a composite signal or an RGB signal, that is, a radio signal modulated with a composite signal and an audio signal.

 In this case, the RF modulating unit 35 may include a first amplifying unit 36, an attenuator 37, and a second amplifying unit 38.

The first amplification unit 36 primarily amplifies the negative electrical signal to the photoelectric element unit 30. [ For example, the electrical signal converted through the photodiode unit may have 60 decibels (dB), and the first amplifying unit 36 amplifies the electrical signal to about 70 decibels.

The attenuator 37 adjusts an electric signal passing through the first amplifying unit 36. The attenuation rate is kept constant in the frequency band while accurately holding the desired attenuation amount while holding the oscillation through the attenuator or reducing the reflection loss. The attenuator can change the amount of attenuation by a level controller 34 (see FIG. 3) such as a dial or the like and can directly read the attenuation ratio, so that the measurement of the attenuation ratio, gain, etc. and the voltage and current of the signal can be adjusted. Accordingly, for example, a signal of 70 decibels along the first amplification section 36 is reduced to about 65 decibels.

The second amplifying unit 38 second amplifies the electric signal from the attenuator and outputs an RF signal. Thus, for example, an electrical signal of about 65 decibels through the attenuator is amplified to 75 decibels.

The branching signal unit 40 receives the RF signal through the photoelectric conversion unit 20 and distributes a plurality of first RF signals having the same signal loss and outputs a signal having a signal loss different from that of the first RF signal. 2 branch the RF signal.

The branching signal unit 40 transmits signals having different signal losses. In this case, the first RF signal having the same signal loss is distributed and transmitted to a plurality of first RF output terminals described later. In addition, the second RF signal different from the first RF signal is transmitted to the RF extension terminal 60 located separately from the first RF output terminals. That is, the plurality of first RF output terminals 50 output the first RF signal distributed through the branch signal unit 40, and the RF extension terminal 60 outputs the first RF signal through the branch signal unit 40 And outputs the second RF signal. An example of the circuit diagram of the branch signal portion is shown in Fig.

Each of the first RF output terminals 50 is connected to a terminal of a broadcasting subscriber. Accordingly, each of the first RF output terminals 50 functions as an output terminal of the distributor.

Unlike the first RF output terminal 50, the RF extension terminal 60 may be connected to a separate splitter. If the number of terminals of the broadcast subscriber is 10 and the first RF output terminal of the optical receiver and distributor 10 is 8, an output terminal is further needed. In this case, when the RF output terminal is connected to the distributor having two or more RF output terminals through the RF extension terminal 60, the RF output terminal can be expanded to match the number of terminals of the subscriber. (95), which is not described, is a circuit protection element.

The present invention may further include a light level comparison unit 70 and a notification unit 75. The light level comparator 70 determines whether the optical signal level input to the photoelectric converter 20 is appropriate. Whether the RF signal is appropriate or not depends on whether the optical signal level is appropriate or not. Therefore, if the optical signal level is not appropriate, it is necessary to correct it. The notification unit 75 functions to notify whether the optical signal is appropriate or not according to the judgment of the suitability of the optical level comparator 70. The notification unit 75 may be a LED light source, for example, to turn on green light when it is normal, to change the light color at normal time and abnormal time so as to light red light when it is abnormal, So that they can be distinguished from each other. The notification unit 75 may be informed as a separate sound.

On the other hand, as shown in FIG. 3, the optical receiving and distributing apparatus 10 may further include a housing 11. The photoelectric conversion unit 20 and the branch signal unit 40 are housed in the housing 11. [ In this case, an optical connector 12 connected to the optical cable and a power connector 14 connected to the power supply unit 90 are disposed at one side of the housing 11.

An LED notification unit 75, first RF output terminals 50, a level controller 34, and an RF extension terminal 60 are disposed on the upper surface of the housing 11.

4, the optical receiving and distribution expansion module 100 including the optical receiving and distributing apparatus 10 of the optical axis-axis mixing network includes the above-mentioned optical receiving and distributing apparatus 10, the distributor 110 , And a coaxial cable (120).

One end of the coaxial cable 120 is connected to the RF extension terminal 60 of the optical receiver and distributor 10. The other end of the coaxial cable is connected to the input terminal 112 of the distributor 110. The distributor includes an input terminal 112, a distribution circuit 114 for distributing a plurality of RF signals received through the input terminal, and a plurality of second RF output terminals 116 connected to the distribution circuit.

 While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is evident that many alternatives, modifications and variations will be apparent to those skilled in the art. Accordingly, the true scope of protection of the present invention should be determined only by the scope of the appended utility model claims.

10: light receiving and distributing device 20: photoelectric conversion section
30: Photoelectric element section 35: RF modulation section
36: first amplifying unit 37: attenuator
38: second amplifying unit 40: branching signal unit
50: first RF output terminal 60: RF extension terminal
40: light level comparator 75:
100: optical receiver distribution expansion module 110: distributor

Claims (5)

A photoelectric conversion unit connected to the optical cable and converting the optical signal into an RF signal;
A branching signal unit for receiving a RF signal through the photoelectric conversion unit and distributing a plurality of first RF signals having the same signal loss and for branching a second RF signal having a signal loss different from that of the first RF signal;
A plurality of first RF output terminals for outputting a first RF signal distributed through the branch signal unit; And
An RF extension terminal for outputting a second RF signal branched through the branch signal unit;
And the optical receiving and distributing apparatus of the optical axis-axis mixed network. The method according to claim 1,
The photoelectric conversion unit includes:
A photoelectric element connected to the optical cable for converting the optical signal into an electrical signal; And
And an RF modulator for modulating an electrical signal through the photoelectric element to an RF signal. 3. The method of claim 2,
Wherein the RF modulator comprises:
A first amplifying unit for primarily amplifying an electric signal from the photoelectric conversion unit;
An attenuator for adjusting an electric signal passing through the first amplifying unit; And
A second amplifying unit for amplifying an electric signal from the attenuator to generate an RF signal;
And the optical receiving and distributing apparatus of the optical axis-axis mixed network. The method according to claim 1,
A light level comparator for determining whether an optical signal level input to the photoelectric conversion unit is appropriate; And
An informing unit informing whether an optical signal is appropriate or not according to whether the optical level comparing unit is correct;
Further comprising an optical receiver for receiving the optical signal. An optical receiving and distributing apparatus of a photovoltaic-core hybrid network having a structure according to any one of claims 1 to 4;
A coaxial cable having one end connected to the RF extension terminal of the light receiving and distributing device; And
A divider including an input terminal connected to the other end of the coaxial cable, a distribution circuit distributing a plurality of RF signals received through the input terminal, and a plurality of second RF output terminals connected to the distribution circuit;
And the optical receiving and distribution expansion module of the optical axis mixed network.

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