KR100817015B1 - Method and apparatus for tracking clock frequency in mb-ofdm system - Google Patents

Abstract

A method and an apparatus for tracking a clock frequency in an MB-OFDM communication system are provided to improve a timing error tracking performance of a receiver and the accuracy of timing between a transmitter and the receiver by reducing a clock frequency error. A method for tracking a clock frequency in an MB-OFDM communication system comprises the steps of: detecting a beacon from a received frame; forecasting a time to detect the next beacon from a detection time of the beacon; calculating the time difference(N) between the time to detect the next beacon and the forecasted time; and tracking the clock frequency using the time difference. If the forecasted time is faster than the time to receive the beacon, the clock frequency of a terminal is lessened as much as the time difference.

Description

Method and apparatus for tracking clock frequency in MB-OFDM communication system {Method and Apparatus for Tracking clock frequency in MB-OFDM System}

1 is a structure of a transmission frame (Superframe) of the MB-OFDM communication system,

2 is a view schematically showing the configuration of a transmitting end and a receiving end of the MB-OFDM communication system according to an embodiment of the present invention;

3 is a timing diagram illustrating a clock frequency synchronization acquisition method according to an embodiment of the present invention.

The present invention relates to a clock frequency tracking method and apparatus of a transmitting end and a receiving end of an MB-OFDM communication system, and more particularly, to a clock frequency tracking method and apparatus using a beacon.

It is essential to obtain and maintain timing synchronization and sampling timing synchronization of a transmitter and a receiver in a TDMA system, for example, an MB-OFDM communication system. In addition, a difference in demodulation performance occurs according to the accuracy, and if the transmitter does not transmit at a predetermined timing, the TDMA system may collide with data of adjacent timing, thereby adversely affecting performance.

Timing synchronization and sampling timing synchronization of the transmitter and receiver are caused basically because the clock frequency between the transceiver is not correct. However, the clock frequency of the transceiver cannot be synchronized unless the clock frequency of the transceiver is shared. Therefore, the function of tracking timing synchronization and sampling timing synchronization should be performed in a wireless communication system.

An object of the present invention according to the above-described requirements of the prior art, by using the beacon (beacon) signal periodically transmitted from the transmitter, the receiver tracks the clock frequency of the transmitter, thereby reducing the clock frequency error of the transmitter and receiver, clock The present invention provides an apparatus and method for reducing the complexity of a receiver demodulation algorithm and improving demodulator performance by improving the timing error tracking performance of a receiver by reducing the frequency error and improving the accuracy of the timing between the transmitter and the receiver.

The present invention for achieving the above object comprises the steps of detecting a beacon from the received frame; Predicting a time for the next beacon to be detected from the time when the beacon is detected; Calculating a time difference (N) between the time when the next beacon was actually detected and the predicted time; And a clock frequency tracking method reflecting the time difference (N), the clock frequency tracking method of the MB-OFDM communication system.

In addition, the present invention is a beacon receiving means for receiving a frame, detecting and demodulating a beacon from the received frame; Clock timing offset measuring means for predicting a time when the next beacon is detected from the time when the beacon is detected and calculating a time difference N between the time when the next beacon is actually detected and the predicted time; And a clock frequency tracking means for tracking the clock frequency by reflecting the time difference N. The clock frequency tracking apparatus of the MB-OFDM communication system is disclosed.

In addition, when the predicted time is faster than the actual beacon received time, the clock frequency of the terminal is modified to be smaller by the time difference N, and when the predicted time is slower than the time when the actual beacon is received, the time difference of the clock frequency of the terminal The correction is as large as (N).

The above objects, features and advantages will become more apparent from the following detailed description taken in conjunction with the accompanying drawings. First of all, in adding reference numerals to the components of each drawing, it should be noted that the same components as much as possible even if displayed on different drawings. In addition, in describing the present invention, when it is determined that the detailed description of the related known technology may unnecessarily obscure the subject matter of the present invention, the detailed description thereof will be omitted. Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1 is a structure of a transmission frame (Superframe) of the MB-OFDM communication system.

All transmission resources (time) are classified in units of superframes, and each superframe is divided into a beacon slot and a medium access slot as shown in FIG. At this time, all transmitters periodically transmit beacons to predetermined beacon slots.

The present invention tracks clock synchronization between terminals using a beacon slot transmitted periodically.

2 is a diagram schematically showing the configuration of a transmitting end and a receiving end of an MB-OFDM communication system according to an exemplary embodiment of the present invention.

Referring to FIG. 2, the terminal A (transmitter) is a 1 / T _C clock generator 110 generating a clock having a period T _C present in a Beacon transmitter, and a beacon at a period of T _S using a clock having the period T _C. It comprises a beacon transmission timing generator 120 for generating a beacon transmission timing to transmit the transmission, and a transmitter 130 for transmitting the beacon according to the beacon transmission timing. Here, the transmitter 130 inserts a beacon into the beacon slot of the above-described superframe and transmits it, but it should be noted that it is described as transmitting a beacon for convenience of description.

Terminal B (receiving end) is a receiving end having a clock frequency tracking device according to the present invention, the receiving unit 210 detects and demodulates a beacon from a receiving frame, and predicts the time when the next beacon is detected from the time the beacon is detected; A clock timing offset estimator 220 for calculating a time difference N (time offset of a transmitter and a receiver) between the time when the next beacon is actually detected and the predicted time, and the transmitter and receiver measured by the clock timing offset estimator. And a loop filter 230 that estimates the clock frequency by reflecting the estimated error value in the clock error value estimate. In addition, the variable oscillator 240 of the terminal B generates a clock of a desired frequency according to the output value of the loop filter.

Hereinafter, a method of tracking a clock frequency in the terminal B will be described in detail.

3 is a timing diagram illustrating a clock frequency synchronization acquisition method according to an embodiment of the present invention.

Method for tracking the clock frequency in the terminal B comprises the steps of detecting a beacon from the received frame; Predicting a time for the next beacon to be detected from the time when the beacon is detected; Calculating a time difference (N) between the time when the next beacon was actually detected and the predicted time; And tracking the clock frequency by reflecting the time difference (N).

Terminal A transmits a beacon signal to a beacon slot determined once every superframe. Terminal B for communicating with terminal A receives the beacon of A, and detects the beacon of terminal A.

Referring to FIG. 3, UE B detects a first beacon (n-1th beacon) of UE A and may predict a time when the next beacon transmitted from UE A is detected using a timer present in UE B. FIG. This predicted time may be earlier or later by N clock durations than the next beacon transmitted by the A terminal. If it is as fast as N clock intervals, terminal B means that the clock has a faster frequency than terminal A, and vice versa, it means that it has a late frequency.

Assumptions: Superframe period is assumed to be Ts.

The clock cycle of the A terminal for clock tracking is called Tc. The frequency is called Fc.

The clock cycle of the B terminal is referred to as Tc '. The frequency is called Fc '.

If the estimated timing of UE B is N * Tc 'fast, which is N durations of Tc, the clock tracking function is modified by estimating Tc as shown in X of FIG. Perform. On the contrary, if the expected timing of UE B is N * Tc 'which is N durations of Tc, it is slow, and as shown in Y of FIG. Of course, as shown in FIG. 2, it is preferable to include a structure capable of smoothing the estimation error of the clock error estimated through the loop filter 230 to perform a clock tracking function.

By performing the above-described procedure, after performing an initialization process in which clock synchronization tracking of the terminal A and the terminal B is performed, when performing data transmission (medium meaningful data, not control data) through a medium access slot, receiver performance is improved. And the complexity can be reduced.

Current clock frequency accuracy specifications for transceivers in MB-OFDM UWB systems should be less than +/- 20 ppm.

The performance improvement in terms of timing error tracking through clock frequency tracking is described below.

If the clock error of the transceiver is L ppm, the timing error that can occur at intervals of M OFDM symbols (1 OFDM symbol: N samples) is M * N * L * 10-6 sampling clock duration.

Assumptions: L = 40 (20ppm transmitter + 20ppm receiver), M = 6 OFDM symbols, N = 165 samples (1 OFDM symbol consists of 165 samples in time)

The timing error that occurs only for 6 OFDM symbols in the above assumption is 6 * 165 * 40 ppm = 0.0396 sampling clock duration.

If all the synchronization except timing error is perfect, if the sampling position error (timing error) is 0.0396, the constellation point of the received signal due to this error will deviate up to about +/- 7 degrees. If this is combined with multipath, noise, and other received sync errors, then timing sync accuracy performance will suffer even further when tracking timing errors.

If the clock error of the transceiver can be traced to L 'ppm which is smaller than the above clock error L ppm, the distortion of the received signal due to this clock error is reduced. In this case, even with the combination of multipath, noise, and other receive synchronization errors, the accuracy of tracking timing errors can be improved over time without clock frequency tracking.

In addition, the following description will be given from the transmitter timing point of view as an example.

If the clock error of the transceiver is L ppm, even if the initial transmission timing is correct, the transmission timing error increases L * 65,536 * 10-12 (1: L us = 65,536us: transmission timing error) for every Superframe. Refer to [Drawing 1] (Superframe period: 65,536us)

Assumptions: L = 40 ppm (+20 ppm (transmitter)-(-20 ppm (receiver)))

The transmission timing error that occurs in 1 superframe occurring in the above assumption is 2.62144 us. Of course, it will perform the function of adjusting the transmission timing in Medium Access Control (MAC), but simply compensating the transmission timing error that occurs in clock frequency error of transmitter / receiver through clock frequency tracking algorithm will improve the system complexity and performance. It becomes possible.

While the invention has been described above based on the preferred embodiments thereof, these embodiments are intended to illustrate rather than limit the invention. It will be apparent to those skilled in the art that various changes, modifications, or adjustments to the above embodiments can be made without departing from the spirit of the invention. Therefore, the protection scope of the present invention should be construed to include not only the appended claims but also all of the above changes, modifications or adjustments.

As described above, by using a beacon signal periodically transmitted from the transmitter, the receiver tracks the clock frequency of the transmitter, thereby reducing the clock frequency error of the transmitter and the receiver, the clock frequency error is small, the timing of the receiver It has the effect of improving the error tracking performance and improving the accuracy of the timing between the transmitter and the receiver.

Claims (8)

A clock frequency tracking method of an MB-OFDM communication system, Detecting a beacon from the received frame; Predicting a time for the next beacon to be detected from the time when the beacon is detected; Calculating a time difference (N) between the time when the next beacon was actually detected and the predicted time; And Tracking the clock frequency reflecting the time difference (N) Including but not limited to: The tracking of the clock frequency by reflecting the time difference N may include: If the estimated time is earlier than the actual beacon received time to modify the clock frequency of the terminal as small as the time difference (N) Clock frequency tracking method of MB-OFDM communication system .. The method of claim 1, wherein the beacon Clock frequency tracking method of the MB-OFDM communication system, characterized in that inserted in the beacon slot of the received frame. delete The method according to any one of claims 1 to 2, The clock frequency tracking method of the MB-OFDM communication system, characterized in that for modifying the clock frequency of the terminal as large as the time difference (N) when the estimated time is slower than the actual beacon received time. A clock frequency tracking device of MB-OFDM communication system, Beacon receiving means for receiving a frame and detecting and demodulating a beacon from the received frame; Clock timing offset estimating means for predicting a time when a next beacon is detected from the time when the beacon is detected and calculating a time difference N between the time when the next beacon is actually detected and the predicted time; And Clock frequency tracking means for tracking the clock frequency by reflecting the time difference (N) Including, The clock frequency tracking means If the estimated time is earlier than the actual beacon received time to modify the clock frequency of the terminal as small as the time difference (N) Clock frequency tracking device of MB-OFDM communication system. The method of claim 5, wherein the beacon Clock frequency tracking device of the MB-OFDM communication system, characterized in that inserted into the beacon slot of the received frame. delete The method according to any one of claims 5 to 6, Clock frequency tracking device of the MB-OFDM communication system, characterized in that to modify the clock frequency of the terminal as large as the time difference (N) when the estimated time is slower than the actual beacon received time.

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