KR960012809A - Clock recovery device and its operation method in discontinuous multitone (DMT: DISCRETE MULTITONE) system - Google Patents

Abstract

Disclosed are a clock recovery apparatus and method in a DMT system. The device is provided at the receiving end of a Discrete MultiTone (DMT) device, for converting the signal conversion means, the first filter means for reducing the channel length, and the signals output in series. A temporary storage means for storing, a demodulation means, a phase compensating means, a frequency offset means for removing the frequency offset and tracking and removing the frequency offset, a phase offset means for tracking and removing the phase offset, and a signal conversion means. And a second filter means for adjusting the sampling rate, and a clock restoring method in the DMT apparatus includes a signal conversion step of converting an analog signal to digital, a first initialization preparation step, A frequency off stage, comprising: an initialization preparation step, a tone angular velocity calculation step, a determination step of determining a change in the angular speed, and a frequency adjustment step And a data offset step, a phase offset step of removing the offset, and an offset tracking step of removing a frequency and phase offset, wherein the first tone is used in the clock recovery initialization of the DMT system. When the frequency algorithm is used, the synchronization is maintained using the second tone, and the clock synchronization in the DMT system can be stably maintained by using the first tone in the initialization and the second tone in the steady state.

Description

Clock recovery device and its operation method in discontinuous multitone (DMT: DISCRETE MULTITONE) system

As this is a public information case, the full text was not included.

1 is a block diagram illustrating a clock restoration apparatus in a discontinuous multitone system according to the present invention.

2 is a flowchart for explaining a clock recovery method in a discrete multitone system according to the present invention.

3 is a flowchart for explaining in detail the flowchart shown in FIG.

4 is a detailed configuration diagram of the second filter unit illustrated in FIG. 1.

Claims (4)

At a receiving end of a discrete multitone (DMT) device, signal converting means for receiving an analog signal received at the receiving end and converting the received analog signal into a digital signal; First filter means for reducing the length of the channel to reduce distortion of the signal to receive the output of the signal converting means and to eliminate interference between units performing fast Fourier transform; Temporary storage means for receiving the digitized signals output in series from the first filter means and storing the signals for outputting in parallel; Demodulation means for receiving an output of the temporary storage means and performing demodulation corresponding to modulation of a transmitting end of the DMT device; Phase compensation means for receiving the demodulated digital signal to compensate for phase distortion generated in the channel and generating sub-channel tones in a low frequency band; In order to synchronize the clock of the transmitter and the synchronization of the receiver, the frequency offset of the signal is removed using a first tone, which is one of the subchannel tones, in a first mode which is an initialization process of the DMT device. Frequency offset means for tracking and eliminating the frequency offset to a second tone, the other of said subchannel tones, in a second mode during normal operation of the apparatus; In order to match the synchronization of the transmitter and the receiver clocks, in the first and second modes, the second tone is received and the phase error is calculated so that the phase compensating means compensates the phase of each subchannel. Phase offset means for supplying an error value to the phase compensating means and tracking and removing the phase offset of the signal while updating the coefficient of the phase compensating means; A frequency control means controlled by the frequency offset unit, the internal frequency of which is to be adjusted to match the sampling clock of the signal conversion means of the transmitter, and a sampling rate of the signal conversion means for adjusting the frequency offset; ; And a second filter means for effectively tracking the frequency offset, making the frequency control means insensitive to noise, and supplying an output to the frequency control means. 2. The clock recovery apparatus of claim 1, wherein the demodulation means and the phase compensating means align the data of the signal to recognize the time and the end of the signal transmitted from the DMT device. Device. A signal conversion step of receiving and converting an analog signal into a digital signal in order to synchronize the transmitting and receiving clocks of the DMT device at a receiving end of the DMT device; A first initialization preparation step of reducing distortion of the signal at an initial stage of the first mode, which is an initialization process of the device, and demodulating the signal at an initial stage of the first mode after the first initialization preparation stage, and phase offset of the signal A second initialization preparatory step of compensating for the sub-channel frequency tones generated after the second initialization preparatory step to remove the frequency offset of the signal in the first mode and the second mode which is a normal operation of the apparatus. A tone angular velocity calculation step of calculating an angular velocity of one of the first tones, a determination step of determining whether the change in the angular velocity is greater than or equal to a threshold value, and a frequency offset if the determination step is not satisfied. A frequency offset step of controlling the signal conversion step; And a data sorting step of sorting data of the signal so that the start and end of the signal can be recognized if the determination step is satisfied. A phase offset step of removing the phase offset of the signal after the data alignment step; After the phase offset step, the frequency and phase offset of the signal are tracked in the second mode so that the frequency offset tracking result proceeds to the determination step, and the phase offset tracking result proceeds to the phase offset step to adjust the frequency and phase offset. And an offset tracking step for removing the clock. 4. The method of claim 3, wherein the initializing step includes removing the frequency and phase offsets for clock recovery of the DMT device and including the frequency offset step, the data alignment step, and the offset step to align the data of the signal. Clock recovery method of the DMT device characterized in that. ※ Note: The disclosure is based on the initial application.