RU141787U1 - TACT SYNCHRONIZATION INSTALLATION DEVICE FOR INFORMATION SIGNALS WITH ORTHOGONAL FREQUENCY DIVISION OF CHANNELS - Google Patents

Abstract

A device for establishing clock synchronization for information signals with orthogonal frequency division of channels, comprising an analog-to-digital converter, a first multiplier, an adder, a decision block, characterized in that the first accumulation block is introduced, which accumulates the received signal samples received from the analog-to-digital converter, for a duration of two characters, the input of which is connected to the output of the analog-to-digital converter, the output of the first accumulation unit is connected to the input of the calculating unit phase difference calculation, which performs the calculation of phase differences between the two halves of the obtained array of samples received from the first accumulation unit, the output of the phase difference calculation unit is connected to the input of the first multiplier, which multiplies the obtained phase differences at the frequencies used by the number of possible positions of the phase differences used currently, the first output of the first multiplier is connected to the input of the phase sine calculation unit, and the second is to the input of the phase cosine calculation unit, the output is bl The phase sine calculation eye is connected to the input of the second multiplier, which squares the obtained values, and the output of the phase cosine calculation block, is connected to the input of the third multiplier, which also squares the obtained values, the output of the second multiplier is connected to the first adder input, and the output of the third multiplier connected to the second input of the adder, the output of which is connected to the input of the root calculation unit, the output of which is connected to the input of the second accumulation unit, which accumulates

Description

The utility model relates to the field of electro-radio engineering, namely to radio communication technology, and can be used in data transmission systems using signals with orthogonal frequency division of channels, when working in a given frequency band without introducing redundancy, to establish and maintain clock synchronization.

To ensure stable operation of the data transmission system, it is necessary to establish and maintain clock synchronization, i.e. determine the start / end time of the elementary signal sending.

Closest to the claimed technical solution is a clock synchronization device (RF patent for the invention No. 2423798), adopted as a prototype.

The device contains an analog-to-digital converter, a multiplier, an adder, a decision block.

The disadvantages of the prototype include the fact that the device does not provide an adaptive change in the thresholds for estimating the amplitude, which leads to a decrease in the accuracy of setting clock synchronization in the presence of fading of the signal amplitude in the communication channel, and as a result to a decrease in noise immunity as a whole.

The purpose of the utility model is to establish and maintain clock synchronization during operation of the data transmission system, but to information signals with orthogonal frequency division of channels, without interrupting the transmission of useful information.

This goal is achieved by the fact that in the device for establishing clock synchronization containing an analog-to-digital converter, a multiplier, an adder, a decision unit, an accumulation unit and a phase difference calculation unit are inserted between the analog-to-digital converter and the multiplier. In this case, the first output of the multiplier is connected to the phase sine calculation unit, and the second is to the input of the phase cosine calculation unit, the outputs of which are connected to the multipliers and connected to the adder. The output from the adder is connected to the root calculation unit, which is connected to the accumulation unit, the output of which is connected to the decision unit.

The block diagram of the proposed device is shown in FIG. one.

The device for establishing clock synchronization (see Fig. 1) contains an analog-to-digital converter 1 connected to the accumulation unit 2, the output of which is connected to the phase difference calculator 3, connected to the multiplier 4. In this case, the outputs of the multiplier 4 are connected to the input of the sine calculation unit phase 5 and the cosine phase 6 calculation unit connected to the multiplier 7 and the multiplier 8. The outputs of the multiplier 7 and the multiplier 8 are the input of the adder 9 connected to the root calculation unit 10 to which the unit is connected accumulation 11, the output of which is connected to the decision block 12.

The proposed device can be used for communication systems using signals with orthogonal frequency division of communication channels. A distinctive feature of the described device is the ability to establish and maintain clock synchronization when using signals with relative or absolute phase modulation in conditions of dense frequency filling of the communication channel without introducing additional redundancy. The presence of such a device eliminates the use of test signals to establish and maintain clock synchronization. In this case, the allocated frequency band can be used completely for data transmission, which leads to an increase in the data transfer rate. The proposed device can also work in the presence of fading signal amplitude in the communication channel.

The structure of the proposed device clock synchronization is obtained from the following assumptions.

A signal with orthogonal frequency division of channels (OFDM) and phase modulation (relative or absolute) of various multiplicity over the duration of the elementary transmission T, such a signal can be represented in the following form:

,

,

where N is the number of frequencies used, A _m is the amplitude and f _m is the face value of m - that frequency:

,

,

Δf = 1 / T, ψ _m is the specified initial phase of the signal s (t). Assume that n - multiple relative phase modulation is used, i.e. Δψ _m can take any of the given 2 ⁿ positions on the phase plane.

In this case, the density W (Δψ) can be represented as follows:

,

,

where n is the modulation factor, δ is the delta function.

, полученных с выхода демодулятора с шагом в один отсчет, то плотность W_k(Δφ) будет деформироваться и стремиться к двум предельным видам:If you restore this density from an array of phase difference values

obtained from the output of the demodulator in increments of one count, then the density W _k (Δφ) will deform and tend to two limiting forms:

,

,

at precisely set clock synchronization, and

,

,

in the absence of clock synchronization.

In this case, the distance between the reconstructed and known densities can be used as a contrast indicator of the position of the synchronization moment. In this paper, the indicated distance K was calculated for the kth step as follows:

,

,

where W ₀ (Δφ) is the uniform density.

It should be noted that the choice of the type of functional is of great importance. So, if we take a different value as a functional, for example:

,

,

then the maximum value that R _k can take in this case is 2. And for real densities this value does not exceed 2. At the same time, if we take the Euclidean distance as an indicator

R _k = || W _k (Δφ) -W ₀ (Δφ) ||

then at those times when the k-th sample will correspond to the start time of the package, R _k will take maximum values and vice versa, when the k-th sample will correspond to the middle of the package, R _k will take the minimum values. Strictly speaking, in the first case, R _k → ∞, and in the second, R _k → 0.

This implies an obvious criterion for establishing clock synchronization: we assume that the start time of the sending on the selected interval is that moment in time t ₀ when the indicator R _k takes the maximum value:

.

.

Thus, regardless of the transmitted information and the modulation frequency used, it is possible to use this approach.

на соседних посылках на всех поднесущих частотах, двигаясь окном длительностью T с шагом в один отсчет. Тогда для каждого k-того шага можно восстановить плотность распределения разности фаз в виде следующего разложения:For practical use in real conditions, a constructive task of the desired density W _k (Δφ) is necessary. As indicated above, starting from a certain point in time, it is possible to calculate the differences of the initial phases

on neighboring packages at all subcarrier frequencies, moving a window of duration T in increments of one count. Then, for each k-th step, it is possible to restore the distribution density of the phase difference in the form of the following decomposition:

,

,

и

являются коэффициентами разложения и оцениваются по выборке следующим образом:Where

and

are the decomposition coefficients and are estimated from the sample as follows:

,

,

,

,

- выборочные значения.where M is the sample size of the phase differences,

- sampled values.

This form of recording is adequate to periodic multimodal density with an undefined initial position (shift). Then R _k can be defined as follows:

.

.

новый, по следующему правилу:It should also be noted that to calculate R _k it is necessary to use only those members of the series that are multiples of 2 ⁿ . Such an action is equivalent to the fact that the modulation removal procedure is preliminarily carried out and is put in accordance with the accepted array

new, according to the following rule:

where 2 ⁿ is the number of allowed positions of the phase differences.

It is also necessary to consider that for practical use the presence of noise imposes restrictions. So, for example, to calculate R _k, it is necessary to use a finite series expansion (the series should be limited to those terms that do not yet make a significant noise contribution). In addition, it is obvious that for a given SNR and the volume of the array of phase differences, it is most reliable to establish the position of the clock synchronization for signals with on-off OFM.

The operation of the device is as follows.

The received signal is fed to an analog-to-digital converter 1, in which signal samples are obtained, which are then fed to accumulation unit 2, in which the accumulated received signal samples are accumulated over a duration of two symbols. Next, the accumulated array of samples is transferred to the phase difference calculation unit 3, where the phase differences between the two halves of the received array of samples of the received signal at all used frequencies are calculated. Next, an array of the calculated phase differences at the frequencies used is fed to the multiplier 4, in which the calculated phase differences are multiplied by the number of possible positions of the phase differences (modulation ratio) currently used. Then, the array of calculated values is transferred to the phase 5 sine calculation unit and the phase 6 cosine calculation unit, in which the sines and cosines of the obtained values are respectively calculated. Next, the calculated array is transferred to the multiplier 7 and the multiplier 8, in which the obtained values are squared. Next, both arrays are passed to the adder 9, in which the summation of all elements of both arrays is performed. The summation result is transferred to the root calculation block 10, in which the root of the obtained value is calculated and transferred to the accumulation block 11, in which the received values are accumulated for a duration of one symbol. Next, the resulting array of values is passed to the decision block, in which the maximum value and its position in the array are determined, thus obtaining the desired position of the clock synchronization.

The proposed device compared with the prototype device has the following advantage:

- provides greater accuracy in establishing synchronization in channels with amplitude fading, such as short-wave communication channels.

Claims (1)

A device for establishing clock synchronization for information signals with orthogonal frequency division of channels, comprising an analog-to-digital converter, a first multiplier, an adder, a decision block, characterized in that the first accumulation block is introduced, which accumulates the received signal samples received from the analog-to-digital converter, for a duration of two characters, the input of which is connected to the output of the analog-to-digital converter, the output of the first accumulation unit is connected to the input of the calculating unit phase difference calculation, which performs the calculation of phase differences between the two halves of the obtained array of samples received from the first accumulation unit, the output of the phase difference calculation unit is connected to the input of the first multiplier, which multiplies the obtained phase differences at the frequencies used by the number of possible positions of the phase differences used currently, the first output of the first multiplier is connected to the input of the phase sine calculation unit, and the second is to the input of the phase cosine calculation unit, the output is bl The phase sine calculation eye is connected to the input of the second multiplier, which squares the obtained values, and the output of the phase cosine calculation unit, is connected to the input of the third multiplier, which also squares the obtained values, the output of the second multiplier is connected to the first adder input, and the output of the third multiplier connected to the second input of the adder, the output of which is connected to the input of the root calculation unit, the output of which is connected to the input of the second accumulation unit, which accumulates inyatyh values for the duration of one symbol, the second storage unit output is connected to the input of a decision block, which determines the maximum value in the received temporary array and its position in the array, which corresponds to the start time of sending.

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