KR100270353B1 - Speed variable type data transmission device for copper wire - Google Patents

Abstract

PURPOSE: A device for transceiving very high speed data of a speed variable type for a copper wiring is provided to transmit normal data after confirming a maximum transmission speed. Therefore, it is possible to apply a very high speed data transceiving device of a speed variable type of a network device or a terminal. CONSTITUTION: A very high speed data trasceiver(1-1) transmits test data, or transmits normal very high speed data from a network device or a terminal. A speed converter(1-2) sets up a transmission data selecting signal in order to transmit the test data at a determined speed, and sets up a variable clock. If a normal state is decided from a BER(Bit Error Rate) detecting signal, the speed converter(1-2) fixes a transmission data speed and the variable clock, and controls to perform a data transceiving. A DMT(Discrete Multi Tone) transmitter(1-3) performs an analog modulation for received digital transmitting buffer output data as a DMT modulation method, and passes an LPF(Low Pass Filter). A hybrid transceiver(1-4) receives a low band analog transmission signal, and amplifies a signal power to transmit the signal power to a copper wiring. The hybrid transceiver(1-4) extracts the BER detecting signal, and supplies the BER detecting signal to the speed converter(1-2).

Description

Speed variable type data transmission device for copper wire

The present invention relates to a super-high-speed data transmission apparatus for a high-speed variable-speed transmission system for transmitting super high-speed data of up to 51.84 Mbps (bit per second) on a copper wire, such as a conventional telephone line, Speed digital data transmission such as Internet, VOD, digital CATV, video data, and HDTV service as well as low-speed data exchange in a copper subscriber network section or a copper drop section of a fiber to the curb subscriber network Can be used.

The present invention also provides a downlink transmission rate of 51.84 Mbps, 25.92 Mbps, which is equivalent to the "short-range baseband asymmetric PMD (subframe) specification on copper / coaxial cable" of DAVIC (Digital Audio-Visual Council) 1.0 Specification And a transmission rate of 12.96 Mbps.

The technical field to which the present invention pertains is a transmitting apparatus for transmitting a large amount of data such as Internet, VOD (Video On Demand) and multimedia service at high speed on a copper line. Conventional technologies include a PC modem, an Asymmetric Digital Subscriber Line modems and very high rate digital subscriber line (VDSL) modems.

The conventional PC modem is widely used as a digital data transmission device such as document exchange, Internet connection, and still image exchange on a telephone line. However, since the maximum transmission speed is 36,600 bps, it is suitable for data transmission with a small capacity. It takes a lot of time to transmit a large amount of data. The conventional ADSL modem transmits data at a maximum transmission rate of 9 Mbps, which is relatively higher than that of the PC modem, but it takes a long time to transmit a large amount of data. In addition, the conventional VDSL modem improves the ADSL modem to transmit ultra high-speed data at a maximum rate of 51.84 Mbps, but has a disadvantage in that it only provides a fixed transmission rate set by the user.

The present invention is capable of transmitting super high speed data of up to 51.84 Mbps on a copper line within 1.5 Km by using a DMT (Discrete Multi Tone) transmitter, which is a multicarrier modulation method, and by adding a function of automatically converting a transmission speed, Speed data transmission apparatus that transmits normal data after confirming the maximum possible transmission rate.

1 is a block diagram of a high-speed data transmission apparatus for a copper wire of the present invention,

FIG. 2 is a block diagram of an ultra-high speed data transmission unit according to the present invention,

3 is a block diagram of a configuration of a velocity conversion unit according to the present invention,

4 is a block diagram of a DMT (Discrete Multi Tone) transmitter of the present invention.

In order to accomplish the above object, the present invention provides a high-speed data transmission unit for transmitting test data to confirm a data transmission capability of a copper wire or transmitting normal high-speed data from a network device or a terminal, The transmission data selection signal is set so that the test data of the ultra high-speed data transmission unit can be transmitted at a predetermined rate, and the variable clock is set. After a predetermined time, A speed converter for controlling data transmission by fixing the transmission data rate and the variable clock when the BER detection signal is determined to be a normal state from a BER detection signal transmitted from the BER detection signal, To modulate the low-pass filter And a hybrid transceiver for receiving a low-band analog transmission signal from the DMT transmission unit, amplifying the signal power and transmitting it through a copper line, extracting a BER detection signal from the reception apparatus, and providing the BER detection signal to the rate conversion unit do.

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

1 is a configuration diagram of a speed variable type high-speed data transmission apparatus according to the present invention.

The super high-speed data transmission unit 1-1 transmits test data to confirm the data transmission capability of the copper line, or transmits normal high-speed data from the network device or the terminal. That is, when the transmission data selection signal of the speed converter (1-2) is at the TTL level 0, the test data is transmitted. When the transmission data selection signal is at the TTL level 1, the normal high speed data is transmitted. When the variable clock of the speed converting unit 1-2 is received and the variable clock is 6.48 MHz, test data of 51.84 Mbps or normal high speed data is transmitted. When the variable clock is 3.24 MHz, test data of 25.92 Mbps or normal When the variable clock is 1.62 MHz, it transmits 12.96 Mbps test data or normal super-high-speed data and transmits it to the "Short-Range Baseband Asymmetric PMD (Physical Medium Dependent sub-layer specification ". The transmission data of the super high-speed data transmission unit 1-1 is transmitted to the DMT transmission unit 1-3 in synchronism with the QAM encoder clock of the rate conversion unit 1-2 in the form of transmission buffer output data of 8 bits (Bits) do.

The speed converting unit 1-2 provides the variable clock and the QAM encoder clock to the super high speed data transmitting unit 1-1 and the QAM encoder clock and the IFFT clock to the DMT transmitting unit 1-3. The speed conversion unit 1-2 sets the transmission data selection signal to the TTL level 0 in order to confirm the data transmission capability of the copper line at the initial time when the power is turned on and sets the test data of the ultra high speed data transmission unit 1-1 to 51.84 The variable clock is transmitted at 6.48 MHz for transmission at the rate of Mbps. The BER detection signal from the hybrid transceiver 1-4 that is feedbacked from the receiving device after transmitting the test data is detected after a predetermined time, and when the BER (Bit Error Rate) detection signal is at the TTL level 1, The variable clock is fixed to 6.48 MHz and the transmission data selection signal is set to the TTL level 1 so that the super high speed data transmission unit 1-1 can transmit normal super high speed data of 51.84 Mbps. If the BER detection signal is at the TTL level 0, it is in an abnormal state. Secondly, the variable clock is reduced to 3.24 MHz by one step and transmitted to the super high-speed data transmission unit 1-1. After the test data is transmitted, the BER detection signal from the hybrid transceiver (1-4) is detected after a predetermined time. When the BER detection signal is at the TTL level 1, the variable clock is fixed at 3.24 MHz and the transmission data selection signal is at the TTL level 1 so that the super high-speed data transmission unit 1-1 can transmit normal super-high-speed data of 25.92 Mbps. If the BER detection signal is at the TTL level 0, it is in an abnormal state. Thirdly, the variable clock is reduced to 1.62 MHz by two steps and transmitted to the super high-speed data transmission unit 1-1. After the test data is transmitted, the BER detection signal from the hybrid transceiver (1-4) is detected after a predetermined time. If the BER detection signal is at the TTL level 1, the variable clock is fixed at 1.62 MHz and the transmission data selection signal is at the TTL level 1 so that the super high-speed data transmission unit 1-1 can transmit normal super-high-speed data of 12.96 Mbps.

The DMT transmitter 1-3 transmits a low-band analog transmission signal obtained by analog-modulating the digital transmission buffer output data received from the super-high-speed data transmitter 1-1 to a hybrid transceiver 1-4. The hybrid transceiver 1-4 receives a low-band analog transmission signal, amplifies the signal power, and transmits the amplified signal to a copper wire. The hybrid transceiver 1-4 extracts a BER detection signal from the reception device and transmits the BER detection signal to the rate conversion unit 1-2 .

2 is a detailed configuration diagram of the ultra high-speed data transmission unit, and the operation of the super-high speed data transmission unit 1-1 will be described in more detail with reference to the drawings.

The super high-speed transmission data interface unit 2-1 is connected to the data transmission unit of the network device or the terminal and receives a variable clock of 6.48 MHz, 3.24 MHz, or 1.62 MHz from the speed converter 1-2, And transmits normal high-speed transmission data in synchronized 8-bit units to the 2-input multiplexer 2-3 together with the super high-speed transmission clock. The test data generator 2-2 receives a variable clock signal of 6.48 MHz, 3.24 MHz, or 1.62 MHz from the rate converter 1-2 to check the data transmission capability of the copper line, And transmits the 8-bit test transmission data to the 2-input multiplexer 2-3 together with the super high-speed transmission clock.

The 2-input multiplexer 2-3 transmits the super-high-speed transmission data of the input A to the multiplexer data of the output Y when the transmission data selection signal of the speed converter 1-2 is TTL level 0, The clock is passed to the multiplexer clock of output Yc. If the transmit data select signal is at TTL level 1, the test transmit data at input B is passed to the multiplexer data at output Y, and the test transmit clock at input Bc is passed to the multiplexer clock at output Yc. Also, the multiplexer data is transmitted to the transmission buffer 2-4 in synchronization with the multiplexer clock. The transmission buffer 2-4 receives and stores multiplexer data in units of 8 bits synchronized with the multiplexer clock and the multiplexer clock and then synchronizes with the QAM encoder clock of the speed converter 1-2 to store 8 And transmits the transmission buffer output data in units of bits to the DMT transmission unit 1-3.

3 is a detailed configuration diagram of the speed converting unit 1-2, and the operation of the speed converting unit 1-2 will be described in more detail with reference to the drawings.

The system clock 3-1 self-oscillates the main clock of 51.84 MHz and delivers it to the clock distributor 3-2. The clock divider 3-2 divides the main clock of 51.84 MHz to generate a QAM encoder clock, an IFFT clock, a feedback control clock, a 6.48 MHz clock, a 3.24 MHz clock, and a 1.62 MHz clock. The 4-input multiplexer 3-3 multiplexes a 6.48 MHz clock, a 3.24 MHz clock, or a 1.62 MHz clock as a variable clock by a 2-bit (multiplexed) multiplexer control signal from the feedback controller (3-5) . That is, if the TTL level of the multiplexer control signal is (1,1), the 6.48 MHz clock of the input C3 is transmitted to the variable clock of the output Cy. If the TTL level of the multiplexer control signal is (1,0) When the TTL level of the multiplexer control signal is (0, 1), the 1.62 MHz clock of the input C1 is transferred to the variable clock of the output Cy.

The BER latch 3-4 latches the BER detection signal received from the hybrid transceiver 1-4, converts the BER latch signal into a BER latch signal, and transmits the BER latch signal to the feedback controller 3-5. The feedback control section (3-5) is the initial initial setting when the power is turned on. The transmission data selection signal is set to the TTL level 0 and the multiplexer control signal is set to the TTL level (1,1). The BER latch signal from the BER latch 3-4 is sensed after a predetermined time calculated by the feedback control clock of the clock distributor 3-2, and if the BER latch signal is at the TTL level 1 The transmission data selection signal is fixed at TTL level 1 and the multiplexer control signal is fixed at TTL level (1,1), thereby transmitting normal high-speed data at 51.84 Mbps. If the BER latch signal is TTL level 0, the transmit data select signal is set to TTL level 0 as the second setting and the multiplexer control signal is set to TTL level (1,0). A BER latch signal from the BER latch 3-4 is sensed after a predetermined time by the feedback control clock of the clock distributor 3-2 and if the BER latch signal is at the TTL level 1, The selection signal is fixed at TTL level 1 and the multiplexer control signal is set at TTL level (1,0) to transmit normal high-speed data at 25.92 Mbps. If the BER latch signal is TTL level 0, the transmit data select signal is set to TTL level 0 as the third setting and the multiplexer control signal is set to the TTL level (0,1). A BER latch signal from the BER latch 3-4 is sensed after a predetermined time by the feedback control clock of the clock distributor 3-2 and if the BER latch signal is at the TTL level 1, The selection signal is fixed to TTL level 1 and the multiplexer control signal is set to TTL level (0,1) to transmit normal high-speed data at 12.96 Mbps.

4 is a detailed configuration diagram of the DMT transmission unit 1-3, and the operation of the DMT transmission unit 1-3 will be described in more detail with reference to the drawings.

The QAM encoder 4-1 converts the 8-bit transmission buffer output data received from the super high-speed data transmission unit 1-1 into a 256-bit transmission buffer output data using the QAM encoder clock from the rate converter 1-2. (QAM) transmission symbol on a subchannel and transmits it to an IFFT (Inverse Fast Fourier Transform) modulator 4-2. The IFFT modulator 4-2 modulates the QAM transmission symbols on 256 subchannels into 256 time-domain parallel transmission data, which are time-domain samples, using the IFFT clock from the rate converter 1-2, (4-3). The parallel-to-serial converter 4-3 converts 256 time-domain parallel transmission data into serial transmission data in units of 1 bit, and transmits the serial transmission data to the digital-analog converter 4-4. The digital-to-analog converter 4-4 converts the analog serial transmission signal to a low-pass filter 4-5 so that the digital serial transmission data can be transmitted on a line. The low-pass filter 4-5 removes the high-frequency component of the analog transmission signal and transmits the low-band analog transmission signal passed through only the low-frequency component to the hybrid transceiver 1-4.

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 or scope of the invention. It is not.

According to the present invention configured to operate as described above, it is possible to transmit super high-speed data of up to 51.84 Mbps on a copper line, such as a conventional telephone line, within a transmission distance of 1.5 Km, Speed variable data transmission apparatus of a network device or a terminal in a copper drop period of a subscriber network.

Claims (4)

Speed data transmission means for transmitting test data to confirm the data transmission capability of a copper wire or transmitting normal high-speed data from a network device or a terminal; In order to confirm the data transmission capability of the copper line at the initial stage of power-on, a transmission data selection signal is set so that the test data of the ultra-high speed data transmission means can be transmitted at a predetermined rate, a variable clock is set, Rate control means for controlling the data transmission so as to fix the transmission data rate and the variable clock by determining a normal state from a bit error rate detection signal fed back from the mobile station; DMT transmission means for analog-modulating the digital transmission buffer output data received from the super high-speed data transmission means by a DMT modulation method and passing the digital transmission buffer output data through a low-pass filter; And And a hybrid transceiver for receiving the low-band analog transmission signal from the DMT transmission means, amplifying the signal power and then transmitting the signal through a copper line, extracting a bit error rate detection signal from the reception device, and providing the bit error rate detection signal to the speed conversion means Speed high-speed data transmission apparatus. The method according to claim 1, Wherein the super-high- Speed transmission data interface means connected to a network device or a data transmission portion of the terminal and receiving a variable clock from the speed conversion means and synchronizing normal high-speed transmission data with a variable clock, together with a super-high-speed transmission clock; A test data generation means for receiving a variable clock from the speed conversion means and generating test transmission data in units of 8 bits synchronized with the variable clock to confirm a data transmission capability of the copper line; Speed transmission data and the test transmission data from the test data generation means and the test transmission clock from the super-high-speed transmission data interface means in accordance with the transmission data selection signal from the speed conversion means Multiplexing means for outputting the multiplexed data; And And transmission buffering means for receiving and storing the multiplexed data output from the multiplexing means and the multiplexed data synchronized with the multiplexed clock and outputting the transmission buffer data in synchronization with the QAM encoder clock of the rate conversion means. Speed variable data transmission device. The method of claim 1, wherein Wherein the speed converting means comprises: A system clock generating means for generating a main clock by itself; A clock distribution means for dividing the main clock to generate a QAM encoder clock, an IFFT clock, a feedback control clock, and a plurality of clocks for variable speed; Latch means for latching a bit error rate detection signal from the receiving apparatus side; Feedback control means for receiving a feedback control clock from the clock distribution means and a bit error rate latch signal from the latch means and outputting a multiplexing control signal and a transmission data selection signal to be sent to the super high speed data transmission means; And And a multiplexing means for selecting one of the outputs of the feedback control means and one of the clocks for variable speed output from the clock distributing means according to the multiplexing control signal and outputting the selected one to the super high speed data transmitting means. Data transmission device. The method according to claim 1, Wherein the DMT transmitting means comprises: (QAM) encoder for encoding and outputting 8-bit transmission buffer output data received from the super-high-speed data transmission means to a QAM transmission symbol on 256 subchannels using a QAM encoder clock from the speed conversion means, Encoding means; IFFT (Inverse Fast Fourier Transform) modulation means for modulating the QAM transmission symbol of the QAM encoding means on the subchannel into time-domain parallel transmission data, which is time-domain samples, using the IFFT clock from the rate conversion means; Serial-to-serial conversion means for converting the time-domain parallel transmission data from the IFFT modulation means into serial transmission data in units of 1 bit and outputting the serial transmission data; Digital-to-analog conversion means for converting the digital serial transmission data from the parallel / serial conversion means into an analog transmission signal so as to be transmitted in a co-linear manner and outputting the analog transmission signal; And And a low-pass filtering means for removing a high-frequency component of an analog transmission signal from the digital-to-analog conversion means and transmitting a low-band analog transmission signal passed through only low-frequency components to the hybrid transceiver. Data transmission device.