KR20160010922A - Power supply network modem apparatus and system - Google Patents

Abstract

The present invention relates to power supply network modem apparatus and system. The power supply network modem apparatus according to the present invention comprises: a coaxial connector to which a coaxial cable can be connected; a data conversion unit for converting digital data to an analog signal, and outputting the converted analog signal; a DC voltage generation unit for generating a DC voltage equal to or greater than a predetermined DC voltage necessary for a voltage conversion unit by receiving a commercial voltage, and outputting the DC voltage; and a voltage conversion unit for receiving the DC voltage outputted from the DC voltage generation unit, and converting the DC voltage into a plurality of rated voltages necessary for a power supply network modem apparatus. The analog signal outputted from the data conversion unit and the DC voltage outputted from the DC voltage generation unit are supplied to the coaxial connector at the same time, thereby extending a communications distance.

Description

[0001] POWER SUPPLY NETWORK MODEM APPARATUS AND SYSTEM [0002]

The present invention relates to a power supply network modem apparatus and system, and more particularly, it relates to a power supply network modem apparatus and system capable of using a conventional coaxial cable as it is, And more particularly, to a power supply network modem apparatus and a system capable of performing power supply.

Conventionally, analog cameras have been widely used, and video images taken by analog cameras have been transferred to the management apparatus through coaxial cables. However, in recent years, analog cameras have gradually been replaced by digital cameras in response to the demands of users who demand high image quality.

When replacing an analog camera with a digital camera, instead of just replacing the analog camera, you need to install a new cable suitable for digital transmission instead of the analogue coaxial cable that was already installed. In this case, upgrading is not easy due to the increase in new installation and construction costs.

On the other hand, Power Line Communication (PLC) is used to transmit and receive data. Power line communication refers to a communication system that transmits and receives data through a power line wired for power supply to a home or office. That is, the power line communication can be realized by modulating the data information into the high-frequency signal on the power line and transmitting the high-frequency signal by separating and receiving the high-frequency signal using the filter having the cutoff frequency of 50 Hz or 60 Hz.

A method of transmitting an analog signal and a digital signal using such power line communication is disclosed in Korean Patent Laid-Open Publication No. 2013-0042086. However, such a power line communication scheme is not suitable for a coaxial cable, and another cost increase is required for applying a power line communication scheme.

In addition, although a new network modem system can be constructed by using an optical cable between new network modem apparatuses, there arises a problem that power can not be supplied to another network modem apparatus through the optical cable.

Patent Document 1: Korean Patent Publication No. 2013-0042086

In order to solve the above-described problems, the present invention can be applied to a digital camera in which a coaxial cable can be used as it is even if it is replaced with a digital camera instead of an analog camera, Supply network modem apparatus and system.

According to an aspect of the present invention, there is provided a power supply network modem apparatus including a coaxial connector to which a coaxial cable can be connected, a data conversion unit for converting digital data into an analog signal and outputting the analog signal, A DC voltage generation unit that receives the DC voltage generated by the DC voltage generation unit and generates and outputs a DC voltage equal to or higher than a predetermined DC voltage required for the voltage conversion unit and outputs a plurality of rated voltages The analog signal output from the data conversion unit and the DC voltage output from the DC voltage generating unit may be supplied together with the coaxial connector.

The DC voltage generating unit may include a voltage selecting unit capable of selecting a plurality of DC voltages based on a predetermined DC voltage required for the voltage converting unit.

The voltage selector may select the desired DC voltage automatically by receiving the DC voltage information detected by the other network modem apparatus.

The DC voltage generating unit may include a voltage regulator that converts a DC voltage of a predetermined DC voltage or higher to a predetermined DC voltage required for the voltage converting unit and outputs the DC voltage.

The data conversion unit may receive Ethernet packet data as digital data and output an OFDM signal as an analog signal.

The data conversion unit may include a data conversion chip for converting the Ethernet packet data into an OFDM signal for a coaxial cable, and an analog front end chip for amplifying and outputting an OFDM signal for a coaxial cable output from the data conversion chip.

A first network modem device and a second network modem device, each of which includes a coaxial connector to which a coaxial cable can be connected and a data conversion unit that converts digital data into an analog signal and outputs the converted analog signal, according to another embodiment of the present invention, Wherein the first network modem device receives a DC voltage supplied through the coaxial cable from the second network modem device and transmits the DC voltage to the first network modem device through a plurality of rated voltages required for the first network modem device And an external power supply unit for supplying the DC voltage to an external terminal device via an external LAN, wherein the second network modem device receives a commercial voltage and supplies the DC voltage to the voltage conversion unit Generates a DC voltage equal to or higher than a predetermined DC voltage The above-described object can be achieved by including the DC voltage generating unit that outputs the DC voltage.

The external power supply unit may include a terminal power source detection unit for detecting whether commercial power is being supplied to the external terminal device.

The external power supply unit includes a switching unit for supplying the DC voltage to the external terminal device, a switching driver for turning the switching unit on or off, And a microcomputer for outputting a turn-on signal to the switching driver when it is determined that the commercial power is not supplied.

According to the above-described configuration, even when the digital camera is replaced with a digital camera instead of the analog camera, not only the existing coaxial cable can be used as it is, but also the power supply problem that occurs when the optical cable is used can be solved.

Also, the present invention can select the output voltage according to the communication distance between the network modem devices, thereby extending the communication distance.

In addition, the present invention can be installed in a region where the commercial power is not supplied, so that communication can be performed.

In addition, the present invention can adjust the output intensity of an analog signal, thereby increasing the coaxial cable length between network modem devices.

1 is a schematic diagram illustrating a network modem system according to an embodiment of the present invention.
2 is a block diagram of the first network modem apparatus shown in FIG.
3 is a circuit diagram of the external power supply unit shown in FIG.
4 is a block diagram of the second network modem apparatus shown in FIG.
5 is a block diagram of the DC voltage generating unit shown in Fig.

DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, preferred embodiments of a power supply network modem apparatus and system according to the present invention will be described with reference to the accompanying drawings. In the following description of the present invention, it is to be understood that the terminology used herein is for the purpose of describing particular embodiments only and is not intended to be limiting of the technical scope of the present invention. Will be.

1 is a schematic diagram illustrating a network modem system according to an embodiment of the present invention.

1, the network modem system includes an IP camera device 110, a first network modem device 120, a second network modem device 130, and a computer 140. The first network modem device 120 and the second network modem device 130 are connected to the coaxial cable 160 (160), and the first network modem device 120 and the first network modem device 120 are connected to the LAN 150, And the second network modem device 130 and the computer 140 are connected to the LAN 150 again.

The IP camera device 110 includes a camera module, an image compression chip, a CPU, and a network transmission chip, which can be used by being connected to a wired / wireless Internet. The analog signal received from the camera module is converted from the image compression chip to digital, compressed, and transmitted to the first network modem device 120 through the network transmission chip. In the present invention, Ethernet packet data is described as digital data output from the IP camera apparatus 110, for example.

The first network modem device 120 receives the digital data transmitted from the IP camera device 110 and converts the digital data into an analog signal suitable for the coaxial cable 160 and outputs the analog signal. The analog signal transmitted from the first network modem device 120 is received at the second network modem device 130 via the coaxial cable 160. The second network modem device 130 converts the received analog signal into digital data and outputs the digital data.

The second network modem device 130 receives a commercial power source to generate a predetermined DC voltage, generates necessary internal voltages using the generated predetermined DC voltage, and transmits the generated generated DC voltage to the second network modem device 130 via the coaxial cable 160 And supplies a predetermined DC voltage to the first network modem apparatus 120. The first network modem device 120 generates necessary internal voltages using the predetermined DC voltage supplied from the second network modem device 130 and also supplies the predetermined DC voltage to the IP camera device 110 .

The computer 140 receives the digital data transmitted from the second network modem device 130 via the LAN 150, and stores the received data in the memory.

2 is a block diagram of the first network modem apparatus shown in FIG.

2, the first network modem apparatus 120 includes an external connection unit 210, a data conversion unit 220, a voltage conversion unit 230, and an external power supply unit 240. Unit is a term introduced to help understand the configuration, not the term introduced to physically distinguish the configuration.

As shown in FIG. 1, the external connection unit 210 includes an RJ-45 connector 212 for connecting the IP camera apparatus 110, which is an external terminal apparatus, with a LAN 150, and another network modem apparatus, for example, And a coaxial connector 214 for connecting to the network modem device 130 via a coaxial cable 160.

The data conversion unit 220 includes an Ethernet PHY chip 221, a data conversion chip 222, a flash memory 223, a DRAM 224, and the like in order to convert digital data into an analog signal and also convert an analog signal into digital data. A security button 225, an analog front end chip 226, a transmit filter 227, a receive filter 228 and a matching transform 229.

The Ethernet PHY chip 221 receives the digital data input from the RJ-45 connector 212, that is, the Ethernet packet data, and provides it to the data conversion chip 222.

The data conversion chip 222 converts the Ethernet packet data input from the Ethernet PHY chip 221 into an Orthogonal Frequency Division Multiplexing (OFDM) signal for a coaxial cable that multiplexes the Ethernet packet data with a plurality of orthogonal narrow band carriers.

The data conversion chip 222 internally incorporates an Ethernet-based MAC / PHY and can support a PHY speed of up to 200 Mbps, satisfying a home plug AV standard. The data conversion chip 222 may also support Internet Group Management Protocol (IGMP) for supporting multicast sessions and QoS (Quality of Service) functions for various types of quality. The data conversion chip 222 also internally includes a DAC and an ADC.

The flash memory 223 may store not only the firmware associated with the data communication but also values that can be used to set the output intensity in the analog signal transmission.

The DRAM 224 temporarily stores the Ethernet packet data provided from the Ethernet PHY chip 221 during the process of converting the data packet from the data conversion chip 222 to the OFDM signal for coaxial cable.

The security button 225 is a button that enables security settings that allow only network modem equipment having the same password, such as password 1234567, to communicate the coaxial cable 160 analog signal.

The analog front end chip 226 amplifies the OFDM signal for the coaxial cable output from the data conversion chip 222 and outputs it to the transmission filter 227 or the OFDM signal for the coaxial cable provided by the reception filter 228, And outputs it to the chip 222. On the other hand, the analog front-end chip 226 can control the gain and adjust the output intensity of the OFDM signal,

The transmission filter 227 is a filter for transmitting the amplified OFDM signal from the analog front end chip 226 to the matching transformer 229 and also for removing noise. The reception filter 228 is a filter for transmitting the OFDM signal provided from the matching transformer 229 to the analog front end chip 226 and also for removing noise.

The matching transformer 229 enables impedance matching with the external coaxial cable 160 and also transmits the OFDM signal provided through the transmission filter 227 to the coaxial connector 214 and the external coaxial cable 160 And coupling the OFDM signal provided to the coaxial connector 214 to the receive filter 228.

A voltage of 48 V is supplied to the voltage conversion unit 230 from the DC voltage generation device 140 shown in FIG. 1 or through the coaxial cable 160. The voltage conversion unit 230 converts the voltage of 48V to the 12V voltage to be supplied to the analog front end chip 226 and the 1.26V voltage to be supplied to the data conversion chip 222 and the 3.3V Voltage is obtained.

In the case of the voltage conversion unit 230, since a predetermined DC voltage, for example, a rated voltage to which 48 V is input, or a coaxial cable 160 becomes long, a voltage drop occurs many times.

The external power supply unit 240 is a unit for supplying power to the LAN 150. When the commercial power is not supplied to the external terminal device such as the IP camera device 110, It is a supply unit. The external power supply unit 240 can detect the required power of the external terminal device and supply either one of two power levels, for example, 15W and 30W.

3 is a circuit diagram of the external power supply unit shown in FIG.

3, the external power supply unit 240 includes a terminal power detection unit 310, a switching unit 320, a switching driving unit 330, a terminal power level detection unit 340, and a microcomputer unit 350 do.

The terminal power detection unit 310 detects whether the commercial power is supplied to the IP camera apparatus 110. To this end, the terminal power detection unit 310 includes a resistor R1 connected to the Input_PD terminal of the microcomputer 350, a resistor R2 connected to the 3.3V voltage, and a diode D1 connected to the node of the resistor R1 and the resistor R2 and the external terminal Power + . Since the terminal power detection unit is connected to the external terminal Power + with a resistance of 27 K? Of the IP camera apparatus 110, it is possible to detect whether the commercial power is supplied to the IP camera apparatus 110.

The switching unit 320 includes a switching device Q1 connected to the 48V voltage and a capacitor C1 connected to the drain terminal and the source terminal of the switching device Q1 in order to supply a predetermined DC voltage to the IP camera device 110. [

The switching driver 330 includes a resistor R3 connected to the DRV terminal of the microcomputer 350 for turning on or off the switching unit 320, a capacitor C2, a comparator OP1, A resistor R6 connected to the output terminal of the comparator OP1, a resistor R8 connected to the switching transistors TR1 and 48V, and a resistor R8 connected to the collector terminal of the switching transistor TR1 so that the output of the switching transistor TR1 is connected to the base of the switching element Q1 Lt; RTI ID = 0.0 > R9 < / RTI >

The terminal power level detector 340 detects the power level required in the IP camera apparatus 110 by using the Zener diode ZD1 connected to the external terminal Power + and the external terminal Power-, the resistor R10 and the resistor R11 connected to the external terminal Power- A resistor R12 connected to the 3.3V voltage, a comparator OP2, a capacitor C3 connected to the output terminal of the comparator OP2, a resistor R13 and a resistor R15, and a resistor R14 connected between the resistor R13 and the ground.

The terminal power level detector 340 detects a power level required for the IP camera apparatus 110 by using a time difference of a timing signal input from the IP camera apparatus 110. For example, And the second power level may be 30W.

The microcomputer 350 outputs a turn-on signal to the switching driver 330 when it is determined that the commercial power is not supplied to the IP camera apparatus 110 by the detection voltage detected by the terminal power detector 310. [

The microcomputer 350 also supplies a continuous turn-on signal to the switching driver 330 if the power level detected by the terminal power level detector 340 is a first power level. If the power level is a second power level, It is possible to supply a turn-on signal having a predetermined duty ratio.

4 is a block diagram of the second network modem apparatus shown in FIG.

4, the second network modem apparatus 130 includes an external connection unit 410, a data conversion unit 420, a voltage conversion unit 430, and a DC voltage generation unit 440, (410) includes an RJ-45 connector (412) and a coaxial connector (414).

Here, the external connection unit 410, the data conversion unit 420, and the voltage conversion unit 430 are substantially the same as the external connection unit 210, the data conversion unit 220, and the voltage conversion unit 230 shown in FIG. 2 , Description of these configurations will be omitted.

The DC voltage generating unit 440 receives a commercial power source and generates and outputs a predetermined DC voltage or more, that is, a voltage of 48V or more required by the first network modem device.

5 is a block diagram of the DC voltage generating unit shown in Fig.

5, the DC voltage generating unit 440 includes a commercial power rectifying unit 510, a voltage transformer T1 520, a switching unit 530, a switching control unit 532, an output voltage rectifying unit 540, An output voltage selection unit 560, an output voltage smoothing unit 570, and a voltage regulator unit 580. The voltage detection unit 550 includes a photocoupler PC1 552, an output voltage selection unit 560,

The commercial power rectifier 510 rectifies the AC voltage of the commercial power source and outputs the rectified DC voltage. In this case, a bridge diode can be used to rectify the AC voltage.

The voltage transformer T1 520 transfers the rectified DC voltage supplied to the primary side when the switching unit 530 is turned on to the secondary side. The switching unit 530 is for supplying a rectified DC voltage to the primary side of the voltage transformer T1 520 and may include a field effect transistor FET as a switching element. The switching control unit 532 is for turning on or off the switching elements of the switching unit 530 and may include a switching control IC.

The output voltage rectifying unit 540 is for rectifying the output voltage generated in the voltage transformer T1 520 and may include a diode. The output voltage detector 550 detects whether the rectified output voltage is equal to or higher than a predetermined desired voltage. When the output voltage rectified by the output voltage detector 550 is higher than a predetermined desired voltage, the photodiode of the photocoupler PC1 552 emits light, receives the light from the photodiode through the phototransistor, and outputs the signal to the switching controller 532 ).

The data signals of the first network modem apparatus 120 and the second network modem apparatus 130 according to the present invention are transmitted and received up to 2 km but the data signals transmitted from the second network modem apparatus 130 to the first network modem apparatus 120 The first network modem apparatus 120 does not operate at a voltage higher than 500 m due to power loss in the coaxial cable 160 when only the 48V voltage required by the voltage conversion unit 230 is supplied. Therefore, in the present invention, the output voltage selecting unit 560 is provided to select the output voltage according to the communication distance between the first network modem apparatus 120 and the second network modem apparatus 130.

The output voltage selection unit 560 is for setting the output voltage of the secondary side of the voltage transformer T1 520. The output voltage selection unit 560 selects the output voltage of the voltage transformer T1 520 according to the communication distance, for example, 48V, 60V, 72V, 84V and 96V Can be selected. When the desired output voltage is set in the output voltage selecting unit 560, the output voltage detecting unit 550 detects whether the rectified output voltage is greater than the newly selected desired voltage.

Meanwhile, the output voltage selector 560 can automatically set the output voltage. In this case, the second network modem apparatus 130 sequentially supplies the DC voltage to the first network modem apparatus 120 from 48V, receives the DC voltage detected from the first network modem apparatus 120, The voltage can be set.

The output voltage smoothing unit 570 smoothes the output voltage rectified by the output voltage rectifying unit 540. The smoothed DC voltage at the output voltage smoothing unit 570 is supplied to the first network modem apparatus 120 through the coaxial connector 414. [

The voltage regulator unit 580 converts the smoothed direct current voltage from the output voltage smoothing unit 570 into the necessary voltage of 48V in the voltage conversion unit 430 and outputs it.

Hereinafter, operations of the second network modem apparatus and the first network modem apparatus will be briefly described with reference to FIGS. 1 to 5. FIG.

1, when the commercial power is supplied to the second network modem apparatus 130, the DC voltage generating unit 440 generates a DC voltage selected by the output voltage selecting unit 560, that is, A voltage of 48 V or more is supplied to the coaxial cable 160, and a voltage of 48 V is supplied to the voltage conversion unit 430. A voltage of more than 48V supplied to the coaxial cable 160 is supplied to the first network modem device 120 at a voltage of approximately 48V due to the power loss in the coaxial cable 160. [

The voltage conversion unit 430 of the second network modem device 130 converts the approximately 48V voltage to the voltages required for the internal configuration. As a result, the second network modem apparatus 130 is ready for communication.

The voltage conversion unit 230 of the first network modem device 120 also converts the approximately 48V voltage supplied through the coaxial cable 160 to the voltages necessary for the internal configuration. As a result, the first network modem apparatus 120 is also ready for communication.

The terminal power detection unit 310 in the external power supply unit 240 of the first network modem apparatus 120 detects whether the commercial power is supplied to the IP camera apparatus 110 and operates, On signal to the switching driver 330 when it is determined that the commercial power is not supplied to the IP camera apparatus 110 by the detection voltage detected by the terminal power detector 310. [ Accordingly, the switching unit 320 is turned on and a 48V voltage is supplied to the IP camera apparatus 110 through the LAN 150. [

Then, the terminal power level detector 340 detects a power level required for the IP camera apparatus 110 using the time difference of the timing signal input from the IP camera apparatus 110. The microcomputer 350 supplies a continuous turn-on signal to the switching driver 330 if the power level detected by the terminal power level detector 340 is a first power level, On signal having a duty ratio of " 1 "

When the IP camera apparatus 110 becomes operable by the 48V voltage supplied by the external power supply unit 240, the IP camera apparatus 110 receives an analog signal from the camera module, And transmits the compressed data to the first network modem device 120 through the network transmission chip.

The first network modem device 120 converts the Ethernet packet data into an OFDM signal for a coaxial cable and outputs it to the second network modem device 130. The second network modem device 130 converts the OFDM signal for the coaxial cable into digital data and outputs it to the computer 140.

The computer 140 receives the digital data transmitted from the second network modem device 130 via the LAN 150, and stores the received data in the memory.

The embodiments of the present invention described above are merely illustrative of the technical idea of the present invention, and the scope of protection of the present invention should be interpreted according to the claims. It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit and scope of the invention as defined by the appended claims. It should be interpreted that it is included in the scope of right.

110: IP camera device 120: first network modem device
130: second network modem device 140: computer
150: LAN cable 160: Coaxial cable
210: external connection unit 220: data conversion unit
230: voltage conversion unit 240: external power supply unit
310: terminal power detector 320:
330: Switching driver 340: Terminal power level detector
350: Microcomputer 410: External connection
420: Data conversion unit 430: Voltage conversion unit
440: DC voltage generating unit 510: Commercial power rectifying unit
520: voltage transformer 530:
532: Switching control section 540: Output voltage rectifying section
550: Output voltage detecting unit 552: Photocoupler
560: Output voltage selection unit 570: Output voltage smoothing unit
580: voltage regulator section

Claims (10)

A coaxial connector to which a coaxial cable can be connected,
A data conversion unit for converting the digital data into an analog signal and outputting the analog signal,
A direct-current voltage generating unit that receives a commercial voltage and generates and outputs a direct-current voltage equal to or higher than a predetermined direct-current voltage required for the voltage converting unit;
And a voltage conversion unit that receives the DC voltage output from the DC voltage generation unit and converts the DC voltage into a plurality of rated voltages required by the power supply network modem apparatus,
Wherein the coaxial connector is supplied with an analog signal output from the data conversion unit and a DC voltage output from the DC voltage generation unit. The method according to claim 1,
Wherein the direct-current voltage generating unit includes a voltage selecting unit capable of selecting a plurality of direct-current voltages based on a predetermined direct-current voltage required for the voltage converting unit. 3. The method of claim 2,
Wherein the voltage selector selects the desired DC voltage automatically by receiving the DC voltage information detected by the other network modem apparatus. 4. The method according to any one of claims 1 to 3,
Wherein the DC voltage generating unit includes a voltage regulator for converting a DC voltage of a predetermined DC voltage or higher to a predetermined DC voltage required for the voltage converting unit and outputting the DC voltage. 4. The method according to any one of claims 1 to 3,
Wherein the data conversion unit receives Ethernet packet data as digital data and outputs an OFDM signal as an analog signal. 6. The method of claim 5,
Wherein the data conversion unit includes a data conversion chip for converting the Ethernet packet data into an OFDM signal for a coaxial cable and an analog front end chip for amplifying and outputting an OFDM signal for a coaxial cable outputted from the data conversion chip Power supply network modem device. A first network modem device having a coaxial connector to which a coaxial cable can be connected and a data conversion unit for converting digital data into an analog signal and outputting the same, and a power supply network modem system In this case,
Wherein the first network modem device comprises: a voltage conversion unit that receives a DC voltage supplied through the coaxial cable from the second network modem device and converts the DC voltage into a plurality of rated voltages required for the first network modem device; And an external power supply unit for supplying power to an external terminal device via an external local area network,
Wherein the second network modem device includes a DC voltage generating unit that receives a commercial voltage and generates and outputs a DC voltage of a predetermined DC voltage or more required for the voltage converting unit. 8. The method of claim 7,
Wherein the DC voltage generation unit includes a voltage selection unit that can select a plurality of DC voltages based on a predetermined DC voltage required for the voltage conversion unit. 9. The method according to claim 7 or 8,
Wherein the external power supply unit includes a terminal power detector for detecting whether or not commercial power is being supplied to the external terminal device. 10. The method of claim 9,
The external power supply unit includes a switching unit for supplying the DC voltage to the external terminal device, a switching driver for turning the switching unit on or off, Further comprising a microcomputer for outputting a turn-on signal to the switching driver when it is determined that commercial power is not being supplied to the power supply network modem system.

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