KR100453766B1 - Dmt system and method measuring timing advance in the dmt system - Google Patents

Abstract

The present invention relates to a method for determining timing advance in a DMT system. According to this method, first, when the remote transceiver receives a signal for starting training from the central station transceiver, the response signal is transmitted by a first timing advance before the end of the sample interval of the received signal. When the central station transceiver receives the response signal, it calculates the number of delay samples in the transmission signal section and the reception signal section in the central station transceiver and determines the second timing advance in consideration of the delay sample number and the first timing advance. Next, the second timing advance is transmitted to the remote transmitting / receiving unit, and the remote transmitting / receiving unit transmits the response signal by the second timing advance before the end of the sample period of the received signal.

Description

DMT system and method for determining timing advance in the system {DMT SYSTEM AND METHOD MEASURING TIMING ADVANCE IN THE DMT SYSTEM}

The present invention relates to a method for determining timing advance in a discrete multi-tone (hereinafter referred to as DMT) system.

Recently, the demand for multimedia services through communication networks has increased, and xDSL (digital) to provide data transmission rates of several hundred kbps to tens of Mbps using existing copper telephone lines without amplifiers or repeaters to meet these demands. Subscriber line schemes have been developed.

xDSL has been developed in various forms such as high-data-rate DSL (HDSL), single-line HDSL (SDSL), asymmetry DSL (ADSL), universal ADSL (UDASL), and very-high-bit-rate DSL (VDSL). VDSL has been developed to transfer data at high speed over short distances of 300 to 1500 meters.

The modulation and demodulation method used in the xDSL includes carrier-less AM / PM (CAP), quadrature amplitude modulation (QAM), and multi-carrier modulation (DMC), discrete multi-tone (CMM), which are single-carrier modulation (SCM). And the like.

The DMT scheme divides the entire transmission band into a plurality of narrowband subchannels and transmits the transmission period in each subchannel by the number of subchannels, thereby compensating for channel distortion with a simple single tap equalizer. In addition, by adding a cyclic prefix to the DMT symbol as a guard interval, the inter-symbol interference can be eliminated by maintaining orthogonality between subchannels, thereby simplifying the equalizer structure at the receiving end. In addition, the modulation and demodulation process can be implemented at high speed using inverse fast fourier transform (IFFT) and fast fourier transform (FFT), respectively.

The biggest performance degradation factors of such DMT systems include near end cross-talk signals and echo signals. The near-end crosstalk signal is a noise generated when two different transmitters transmit data at the same time, and is generated when data of the same frequency band is simultaneously transmitted in both directions in the same binder group. An echo signal is noise that affects a signal received when data is transmitted from the transmitting end of the same stage.

To prevent such near-end crosstalk signals and echo signals, the DMT system adds a cyclic suffix to the end of the signal in addition to the cyclic prefix. In order to minimize interference between near-end crosstalk signals and echo signals, orthogonality between frequencies should be maintained. Accordingly, in order to guarantee orthogonality between frequencies, the DMT system adds and transmits a cyclic suffix to the original signal so that only one symbol of the near-end crosstalk signal and the echo signal is included in the symbol period of the received signal of each network end.

In addition, when the DMT is based on the U2 interface, the DMT transmits a signal by timing advance ahead of the start point of the symbol period of the received signal in the U2 interface of the remote transceiver to transmit the signal simultaneously. In the prior art, the number of samples of the periodic suffix is made longer than the number of samples of the timing advance to eliminate the effects of near-end crosstalk and echo.

The prior art also determined this timing advance from the shock response or transfer function of the channel. In this way, in order to determine timing advance, an estimation process of a shock response and a transfer function of a channel is required.

The technical problem of the present invention is to simultaneously transmit and receive signals from the central station transceiver and the remote transceiver based on the U2 interface.

In addition, the present invention is to remove the near-end crosstalk signal and the echo signal by using only a cyclic suffix of the minimum length.

In addition, the technical problem is to determine the timing advance by measuring the group delay of the channel.

1 is a block diagram illustrating a DMT transmission / reception system according to an embodiment of the present invention.

2 is a diagram showing the number of samples of one symbol used in the DMT transmission and reception system according to an embodiment of the present invention.

3A to 3C are time diagrams illustrating a timing advance measurement method according to an embodiment of the present invention.

The present invention achieves this task by measuring the group delay to determine timing advance.

According to one aspect of the present invention, there is provided a DM system including a central station transceiver and a remote transceiver. The central station transceiver includes a first transmit buffer, a first transmit sample counter, a first receive buffer, and a first receive sample counter, wherein the first transmit buffer temporarily stores the sample to be transmitted and the first transmit sample counter is the first transmit buffer. Set a first transmit sample counter value representing a position within a symbol of an output sample of a first receive buffer temporarily storing the received sample and a first receive sample counter indicating a position within a symbol of an input sample of the first receive buffer; Set a first received sample counter value. The remote transceiver includes a second transmit buffer, a second transmit sample counter, a second receive buffer, and a second receive sample counter, wherein the second transmit buffer temporarily stores the sample to be transmitted and the second transmit sample counter is a portion of the second transmit buffer. Set a second transmit sample counter value representing a position within a symbol of the output sample, the second receive buffer temporarily storing the received sample and a second receive sample counter indicating a position within the symbol of the input sample of the second receive buffer; 2 Set the received sample counter value.

At this time, the remote transceiver transmits a signal by a first timing advance before the end of the sample interval of the received signal at the U2 interface of the remote transceiver by changing the second transmission sample counter value, and transmits the second timing advance from the central station transceiver. When receiving, the U2 interface of the remote transceiver transmits a signal ahead of the end of the sample interval of the received signal by a second timing advance. The central station transceiver calculates the number of delay samples in the transmission signal section and the reception signal section in the U2 interface of the central station transceiver and determines the second timing advance in consideration of the first timing advance and the delay sample.

In this case, the central station transceiver and the remote transceiver preferably update the periodic prefix and the periodic prefix, and the updated periodic prefix becomes (cyclic prefix + first timing advance-second timing advance) and the updated periodic suffix. Becomes (cyclic suffix-first timing advance + second timing advance).

According to another feature of the invention there is provided a method of determining timing advance in such a system. According to this method, first, when the remote transceiver receives a signal for starting training from the central station transceiver, the response signal is transmitted by the first timing advance before the end of the sample interval of the received signal at the U2 interface of the remote transceiver. . When the central station transceiver receives the response signal, it calculates the number of delay samples in the transmission signal section and the reception signal section in the central station transceiver and determines the second timing advance in consideration of the delay sample number and the first timing advance. Next, the second timing advance is transmitted to the remote transmission / reception unit, and the remote transmission / reception unit transmits the response signal by the second timing advance before the end of the sample period of the received signal at the U2 interface of the remote transmission / reception unit.

At this time, it is preferable to update the periodic prefix to (periodic prefix + first timing advance-second timing advance) and to update the periodic prefix to (periodic suffix-first timing advance + second timing advance).

At this time, the number of delay samples is the group delay from the transmitting side of the central station transceiver to the U2 interface of the central station transceiver and the receiving side of the central station transceiver from the U2 interface of the central station transceiver in the transmission sample count value indicating the position in the symbol of the transmitted sample. It is desirable to determine this by subtracting the group delay.

In addition, the second timing advance Where TA is the second timing advance, TA ₀ is the first timing advance, Δ is the number of delayed samples, N _T is the length of the sample, and mod is a modulo operation.

Next, a DMT system for determining timing advance and a method for determining timing advance in the system will be described with reference to the accompanying drawings.

Detailed description of the O-SIGNATURE, R-MSG1, R-ACK, O-UPDATE, and R-IDLE messages described in the present invention can be found in the T1E1.4 VDSL Recommendation (VDSL Metallic Interface, Part 3: Technical Specification of a Multi-). Carrier Modulation Transceiver.

First, a DMT transmission / reception system according to an embodiment of the present invention will be described with reference to FIGS. 1 and 2.

1 is a block diagram illustrating a DMT transmission / reception system according to an embodiment of the present invention. 2 is a diagram showing the number of samples of one symbol used in the DMT transmission and reception system according to an embodiment of the present invention.

As shown in FIG. 1, a DMT transmission / reception system according to an embodiment of the present invention includes an optical network unit transceiver 100 and a remote site transceiver 200, and these transceivers 100 and 200 are connected at respective U2 interfaces 400 and 500 via channel 300. These channels are typically UTP (unshielded twisted pair) cables.

The transceivers 100 and 200 convert the digital signals into physical layer signals at the U2 interfaces 400 and 500 or vice versa, and convert the physical layer signals into digital signals, respectively. 220, transmit sample counters 130, 230, receivers 140, 240, receive buffers 150, 250, receive sample counters 160, 260 and analog front end (AFE) 170, 270 ).

The transmitters 110 and 210 include Tx front-end controllers 111 and 211, and the transmitters 111 and 211 include inverse fast Fourier transforms in the transmitters 110 and 210. IFFT) temporarily stores the data in the transmission buffers 120 and 220, extracts data from the transmission buffers 120 and 220 according to the counts of the transmission sample counters 130 and 230, and transfers the data to the analog front ends 170 and 270. do. In addition, the transmission control units 111 and 211 adjust the count values of the transmission sample counters 130 and 230.

The receivers 140 and 240 include Rx front-end controllers 141 and 241, and the reception controllers 141 and 241 receive data from the analog front ends 170 and 270. 250 is temporarily stored and data is extracted from the reception buffers 150 and 250 according to the counts of the reception sample counters 160 and 260, and the fast Fourier transform (FFT) unit in the reception units 140 and 240 is extracted. Deliver to (not shown). In addition, the reception controllers 141 and 241 adjust the count values of the reception sample counters 160 and 260.

The analog front ends 170 and 270 convert digital signals from the transmitters 110 and 210 into physical layer signals (analog signals) and transmit and receive the remote transceiver 200 and the central station through the U2-interfaces 400 and 500, respectively. Transmitting to the transceiver 100, and converts the physical layer signal received from the remote transceiver 200 and the central station transceiver 100 through the U2-interfaces 400 and 500, respectively, into a digital signal and receives the receiver 140. , 240).

As shown in FIG. 2, when the number of symbol tones is N _SC , a symbol of the DMT includes L _CP periodic prefix samples, 2N _SC samples, and L _CS periodic suffix samples. That is, the number of samples N _T of one symbol is expressed by Equation 1 below.

The transmit sample count values (OTxSampleCnt, RTxSampleCnt), which are the count values of the transmit sample counters 130 and 230, represent positions in symbols of the output samples of the transmit buffers 120 and 220, which represent values from 0 to N _T -1. Have The transmit sample counter values (OTxSampleCntAtU2, RTxSampleCntAtU2) on the U2 interface 400, 500 represent the positions within the symbols of the transmit samples of the U2 interface 400, 500, which indicate the transmit buffer (at the transmit sample count value (OTxSampleCnt, RTxSampleCnt). Equation 2 takes into account the group delays Δ _OTx and Δ _RTx from the outputs of 120 and 220 to the U2 interfaces 400 and 500.

OTxSampleCntAtU2 = OTxSampleCnt-ΔOTx

RTxSampleCntAtU2 = RTxSampleCnt-Δ _RTx

Similarly, the received sample count values ORxSampleCnt and RRxSampleCnt, which are the count values of the received sample counters 160 and 260, represent positions in symbols of the input samples of the receive buffers 150 and 250, which are values from 0 to N _T -1. Has The received sample counter values ORxSampleCntAtU2 and RRxSampleCntAtU2 on the U2 interfaces 400 and 500 represent locations within the symbols of the received samples of the U2 interfaces 400 and 500, which represent the U2 interfaces (ORxSampleCnt and RRxSampleCnt) on the received sample count values ORxSampleCnt and RRxSampleCnt. Equation 3 takes into account the group delays Δ _ORx and Δ _RRx from 400 and 500 to inputs of the reception buffers 120 and 220.

ORxSampleCntAtU2 = ORxSampleCnt + ΔORx

RRxSampleCntAtU2 = RRxSampleCnt + Δ _RRx

In general, in order to transmit data in such a DMT system, an initialization step must be performed first. This initialization phase consists of an activation (handshake) phase, a training phase, and a channel analysis exchange phase. The start (handshake) step is to find out whether a signal is ready to be transmitted between the transmitting and receiving ends. In the training step, symbol synchronization and equalizer training are performed, and the channel analysis and exchange step is performed for each subchannel. The signal-to-noise ratio (SNR) is measured to generate a bit table having bit loading information for each, and at this time, the various parameters determined are exchanged between the transmitting and receiving terminals.

At this time, the timing advance is determined in the training phase.

Hereinafter, a timing advance determination method according to an embodiment of the present invention will be described with reference to FIGS. 3A to 3C.

3A to 3C are time diagrams illustrating a timing advance measurement method according to an embodiment of the present invention.

After initializing the training phase in the training phase, the central station transceiver 100 repeatedly transmits the O-SIGNATURE message to the remote transceiver 200 and receives the R-MSG1 message from the remote transceiver 200. Repeat until (S301). The O-SIGNATURE message includes fields such as band, RFI band, and PSD to be used to set default values for data transmission. The remote transceiver 200 completes symbol synchronization and starts equalizer convergence (S302).

When the remote transceiver 200 has completed the equalizer convergence, it receives an O-SIGNATURE message, and the transmission controller 211 sets the transmission sample count (RTxSampleCnt) of the remote transceiver 200 when the O-SIGNATURE reception starts. _T + TA ₀ + Δ _RTx + Δ _RRx are set (S303). At this time, the sample count (RTxSampleCntAtU2) in the U2-R interface 500 becomes N _T + TA ₀ + Δ _RRx in consideration of the channel delay.

Next, the remote transceiver 200 repeatedly transmits an R-MSG1 acknowledgment message indicating that it has received an O-SIGNATURE message to the central station transceiver 100, and starts transmitting when the transmission sample count (RTxSampleCnt) becomes zero. (S304). Then, transfer the sample count (RTxSampleCnt) and the sample count is 0 in the U2-R interface 500 if the _RTx Δ, that is, R-MSG1 begins to transmit in the U2-R interface 500. In this way, in the U2-R interface 500, the transmission message is transmitted TA ₀ ahead of the reception message.

Next, upon completion of symbol synchronization in the central station transceiver 100, the equalizer begins to converge, and the difference in the number of samples (Δ) between the transmitted signal and the received signal on the U2-O interface 400 is determined by OTxSampleCnt-Δ _ORx- . Δ _OTx is set (S305). When the equalizer converges, the central station transceiver 100 receives the R-MSG1 message (S306) and transmits an O-UPDATE message before the sample interval of the R-MSG1 is completed (S307). At this time, the O-UPDATE message is transmitted when the R-MSG1 message is received and the transmission sample count (OTxSampleCnt) becomes zero. This O-UPDATE message includes a field in which the correction value of the timing advance is recorded, and the corrected timing advance is recorded and transmitted in this field. This corrected timing advance is given by equation (4).

Here, TA denotes a corrected timing advance, TA ₀ denotes a previous timing advance, N _T denotes a length of a sample, and mod denotes a modulo operation.

When the remote transceiver 200 receives the O-UPDATE message, it stores the TA included therein (S308). Thereafter, when the transmission sample counter value RTxSampleCnt becomes 0, the R-ACK message indicating that it has been received is transmitted to the central station transceiver 100 (S309). After transmitting the R-ACK message, the R-IDLE message, which is a meaningless signal, is repeatedly transmitted (S310).

Receiving the R-IDLE message, the control unit of the central station transceiver 100 sets the transmit sample count (OTxSampleCnt) to 0 when the transmit sample count (OTxSampleCnt) is N _T- (TA-Δ), and the new periodic prefix and periodic The suffix is set to L _CP + TA ₀ -TA and L _CS- (TA ₀ -TA), respectively, to transmit a new message (S311). At this time, when the transmission sample count (RTxSampleCnt) is 0, the controller of the remote transceiver 200 sets the new periodic prefix and the periodic suffix to L _CP + TA ₀ -TA and L _CS- (TA ₀ -TA), respectively. Send a new message.

The central station transceiver 100 calculates the number of delay samples and the new timing advance in the same manner as the above process, and repeats the above process if the new timing advance is different from the previous timing advance.

In this way, timing advance can only be determined by measuring the group delay of the channel, and the length of the cyclic suffix can be reduced by the difference between the existing timing advance and the new timing advance. Also, by setting the timing advance in this manner, the central station transceiver and the remote transceiver can simultaneously transmit and receive signals based on the U2 interface.

Claims (7)

A first transmit buffer for temporarily storing a sample to be transmitted, a first transmit sample counter for indicating a first transmit sample counter value indicating a position in a symbol of an output sample of the first transmit buffer, and a first receive buffer for temporarily storing a received sample And a first received sample counter indicative of a first received sample counter value indicative of a position in a symbol of an input sample in the first receive buffer, the sample being received from the first transmit buffer in accordance with the first transmitted sample counter value. A central station transceiver unit which extracts and transmits and extracts and receives a sample from the first reception buffer according to the first received sample counter value; A second transmit buffer for temporarily storing a sample to be transmitted, a second transmit sample counter for indicating a second transmit sample counter value indicating a position in a symbol of an output sample of the second transmit buffer, and a second receive buffer for temporarily storing a received sample And a second received sample counter indicating a second received sample counter value indicating a position in a symbol of an input sample of the second received buffer, wherein the second received sample counter indicates a sample from the second transmit buffer according to the second transmitted sample counter value. A remote transceiver configured to extract and receive a sample from the second receive buffer according to the second received sample counter value Including; The remote transceiver transmits a signal by a first timing advance before the end of the sample interval of the received signal on the U2 interface of the remote transceiver by changing the second transmission sample counter value, and transmits a signal from the central station transceiver. When the timing advance is received, a signal is transmitted at the U2 interface of the remote transceiver unit before the end of the sample interval of the received signal by the second timing advance, The central station transceiver unit calculates the number of delay samples of the transmission signal interval and the reception signal interval at the U2 interface of the central station transceiver and determines the second timing advance in consideration of the first timing advance and the delay sample. Discrete multi-tone system. In claim 1, The central station transceiver and the remote transceiver Update the cyclic prefix to (the cyclic prefix + the first timing advance-the second timing advance), Update the periodic suffix to (the cyclic suffix-the first timing advance + the second timing advance). DM System. The method of claim 1 or 2, The remote transceiver transmits the second timing advance. Where TA is the second timing advance, TA ₀ is the first timing advance, Δ is the number of delayed samples, N _T is the length of the sample, and mod is a modulo operation. The central station transceiver receives the delay sample count. (Where, OTxSampleCnt is a first transmission sample count value, Δ _OTx is a group delay from the transmitting side of the central station transceiver unit to the U2 interface of the central station transceiver _unit , and Δ _ORx is a transmission / reception of the central station from the U2 interface of the central station transceiver unit) Group delay to the negative receiver) DM System. In a DM system in which a central station transceiver and a remote transceiver exchange data, When the remote transceiver receives a signal for starting training from the central station transceiver, a first signal for transmitting a response signal by a first timing advance ahead of the end of the sample interval of the received signal on the U2 interface of the remote transceiver; step, A second step of calculating the number of delayed samples in the transmission signal section and the reception signal section in the central station transceiver, when the central station transceiver receives the response signal; A third step of determining, by the central station transceiver, a second timing advance in consideration of the number of delayed samples and the first timing advance; A fourth step of transmitting the second timing advance to the remote transceiver; A fifth step of transmitting, by the remote transceiver, a response signal by the second timing advance before the end of the sample interval of the received signal on the U2 interface of the remote transceiver; Timing advance determination method in a DM system comprising a. In claim 4, The fifth step is Update the cyclic prefix to (the cyclic prefix + the first timing advance-the second timing advance), Updating the periodic suffix with (the cyclic suffix-the first timing advance + the second timing advance). Timing advance determination method further comprising a. The method of claim 4 or 5, The second step includes the group delay from the transmitting side of the central station transceiver to the U2 interface of the central station transceiver and the U2 interface of the central station transceiver in a transmission sample count value indicating the number of delay samples in a symbol position of a transmission sample. And a value determined by subtracting the group delay from the receiving station to the receiving side of the central station transceiver. The method of claim 4 or 5, The third step is to perform the second timing advance. Where TA is the second timing advance, TA ₀ is the first timing advance, Δ is the number of delay samples, N _T is the length of the sample, and mod is a modulo operation.