RU2639657C1 - Method of adaptation of short-wave communication system with ofdm-signals - Google Patents

Abstract

FIELD: radio engineering, communication.SUBSTANCE: in the number of optimized parameters in the implementation of the radiocommunication system adaptation process, the parameter, the diversion value in the frequency of adjacent subcarriers of the OFDM-signal, is additionally introduced, while changing the diversity value of Δƒin the frequency, the duration of the OFDM-signal Talso varies according to law T=1/Δƒ. In this case, the state of the communication channel is estimated from the values of frequency scattering, time scattering, and the signal-to-noise ratio measured in the process of receiving the route-sounding signals. The values of the optimized parameters of the communication system are determined using predefined compliance tables, in each of which for each pair of frequency and time scattering values possible in the communication channel they determine: the minimum value of the signal-to-noise ratio required to provide communication with a given quality, as well as the number signal-code structure from the number implemented by the communication system and the frequency diversity value of adjacent subcarriers of the OFDM-signal, at which the minimum value of the signal-to-noise ratio is achieved.EFFECT: increasing the capacity of the adaptive communication system with OFDM-signals.4 cl

Description

The invention relates to the field of radio communications and can be used in the construction of adaptive systems and complexes of HF radio communications.

There is a method of adapting a radio communication system in frequency [1-2], based on an assessment of the quality of the channel at several allowed frequencies and the choice of frequency for transmitting information with a minimum level of interference. The disadvantage of this method is the use for adaptation of only one parameter (frequency), which requires the use of a large number of operating frequencies to ensure reliable communication of information to the consumer. This is not always possible due to the scarcity of the frequency resource.

A known method of adapting a radio communication system for data transfer speed [3], which can be implemented by changing the duration of the transmission, changing the redundancy of the code, changing the type of modulation. The disadvantage of the adaptation method for the transmission speed of the message is the need to reduce the transmission speed when the quality of the channel is degraded, which leads to a low average transmission rate of information. The same will happen in the case of multi-parameter adaptation (in terms of operating frequency and speed) under conditions of a limited frequency resource.

The development trend of modern adaptive HF radio communication systems is aimed at increasing the speed of information transfer, in particular, by using high-speed modems that use OFDM technology (Orthogonal frequency-division multiplexing - multiplexing with orthogonal frequency division of channels), as well as improving communication reliability by applying multi-parameter adaptation. Examples of constructing an adaptive HF radio communication system using OFDM technology are the PIRS, Serdolik complexes, and a number of others.

The closest technical solution (prototype) to the claimed invention is the adaptation method implemented in the adaptive HF radio communication system "PIRS" [4]. The adaptation method implemented in the Pierce system is based on OFDM technology, since the system uses a high-speed parallel modem. In accordance with this method, when conducting communication, trace sounding is carried out by transmitting a control combination with a subsequent assessment of the quality of the received signal. Based on the results of route sounding, the parameters of the communication channel are evaluated: the multipath analysis is carried out, the level of interference is estimated, and the number of errors detected by the code is calculated.

According to the results of assessing the propagation conditions of radio waves and interference conditions, multi-parameter adaptation is provided by automatically choosing the best frequency during communication, changing the data transfer rate (within 300-9600 bit / s) and code rate (from 0.4 to 0.8) .

The disadvantage of this adaptation method is that when evaluating the quality of the channel, multipath and the level of interference are taken into account, but frequency scattering is not taken into account, which reduces the accuracy of the estimation of the communication channel and the probability of the correct choice of both the best frequency for communication and the optimal transmission speed for the selected operating frequency . Another disadvantage of the adaptation method is the need to reduce the information data transfer rate with a deterioration in channel quality, which leads to a decrease in the average information transfer rate.

The problem to which the invention is directed, is to increase the throughput provided by an adaptive communication system using OFDM signals to transmit information.

The solution of this problem is achieved by the fact that in the known method of multi-parameter adaptation, based on the procedure of entering into communication, conducting route sounding, assessing the status of the message channel, finding the values of optimized parameters of the communication system that provide the maximum bandwidth of the radio line, transmitting the values of the selected parameters to your correspondent, exchange of information messages, among the optimized parameters in the process of adaptation of the radio communication system additionally administered parameter - the value of the frequency diversity adjacent subcarriers OFDM - signal, wherein, to the extent of diversity Δƒ _lifted frequency OFDM-signal duration T _OFDM, also varies as T _OFDM = 1 / Δƒ _lifted.

At the same time, the state of the communication channel is estimated by the values of the channel parameters (frequency scattering, time scattering, and signal-to-noise ratio), measured during the reception of path-sensing signals. The required values of the optimized parameters of the communication system are determined using pre-prepared correspondence tables, in each of which, for each pair of frequency and time scattering values possible in the communication channel, the following are determined: the minimum signal-to-noise ratio sufficient to ensure communication with a given quality, and also the type (or number) of the signal-code construction from the number implemented by this communication system and the frequency diversity of adjacent OFDM signal subcarriers at which Goes the minimum signal / noise ratio.

Correspondence tables are preliminarily obtained by simulation modeling using a radio line model including simulation models of the receiving and transmitting sides of the communication system, as well as the communication channel model, by repeatedly running on the obtained model of communication sessions until a statistically stable result is obtained, the number of such tables should be equal to the number of information speeds implemented in this radio link. From the correspondence tables, starting from the table for the maximum speed, the minimum signal-to-noise ratio is found from the values of the frequency and time scattering measured during the route sounding, at which the connection with the required quality is provided, while if the indicated value is less than the measured in the channel, then choose the speed value corresponding to this table, otherwise they go to the table with a lower speed and so on until there is a table in which the cell corresponding to the measured values frequency and time channel scattering, will contain the value of the signal / noise ratio lower than measured in the channel. In this case, the information transfer rate, the type of signal-code structure (CCM) from the number implemented by this communication system, and the frequency diversity spacing of adjacent OFDM signal subcarriers corresponding to the cell of the found table are stored.

If there are several operating frequencies, i.e. adaptation is possible also in frequency, then sounding is carried out at all operating frequencies, for each parameter of the communication channel is determined, and for each frequency, by the method described above, the values of the information transmission rate, such as CCM and the frequency spacing of neighboring OFDM signal subcarriers, are determined. Next, the operating frequency is selected at which the maximum information transfer rate is achieved, while ensuring communication quality no worse than the specified one. The type of CCM and the frequency spacing of adjacent OFDM signal subcarriers are also determined from the table corresponding to the found information transmission rate.

Thus, according to the measured values of the parameters of the communication channel, the maximum possible transmission speed, the value of the operating frequency at which the maximum speed is reached, the frequency diversity value of the adjacent OFDM subcarriers - signal and the type (or number) of the signal-code structure from the number implemented by the communication system are determined .

Comparative analysis with the prototype shows that the introduction of significant distinguishing features is new and allows, as will be shown below, to solve the problem.

According to the recommendation ITU-R F.1487 [7], the modem’s efficiency should be determined not by a separate noise immunity curve, but by a characteristic performance surface (CI), which is a three-dimensional surface showing the dependence of the signal-to-noise ratio necessary for transmitting a message with a given communication quality from magnitude of frequency and time scattering. Since the OFDM modem is an integral part of the radio line using OFDM signals, this recommendation also applies to the radio line. In practice, the approximation of the CSP by a rectangle and the projection of the approximated characteristic surface onto a plane formed by the axes of frequency and time scattering can be used [4].

The basic principle of implementing OFDM modems suggests that increasing or decreasing the distance between subcarriers should lead to an inversely proportional increase or decrease in symbol duration. With an increase in the subcarrier spacing in frequency, the modem's resistance to the frequency scattering of the communication channel increases, while the time-scattering resistance also decreases. signal duration decreases. Conversely, as the frequency subcarrier spacing decreases, the modem’s resistance to the frequency scattering of the communication channel decreases, and the time-scattering resistance increases.

Thus, obtaining, for example, using periodically conducted trace sounding, information on the current frequency and time scattering in the channel and changing, according to these data, the distance between subcarriers in the OFDM signal, it is possible to adapt the modem operation parameters to the propagation conditions in the ionospheric radio channel. Moreover, adaptation in terms of the separation between subcarriers does not lead to a change in the information rate realized by the modem. The simulation performed by the authors showed the effectiveness of the proposed adaptation method.

The proposed adaptation method is implemented as follows.

After the entry into communication took place, which can be done by any of the known methods, the necessity of conducting route sounding is determined. Tracking sounding can be carried out in the pauses that occur during the transmission of messages, periodically after a time shorter than the interval of stationarity of the communication channel, or at the request of the receiving side, with a decrease in reception quality. If trace sensing is necessary, the transmitting side transmits a test probe sound signal at each of the frequencies allocated for communication. On the receiving side, test signals transmitted through the channel are received and digitally processed, during which the amplitude-frequency, phase-frequency and pulse characteristics of the communication channel (frequency response, phase response and frequency response) are determined. Based on the obtained impulse characteristics, the channel scattering function (PRF) is found and the time and frequency scattering values are determined, and the signal-to-noise ratio is also found.

Using the obtained values of the channel parameters (time scattering, frequency scattering, signal-to-noise ratio) using the previously calculated correspondence table, optimized parameters of the radio line are found (operating frequency, information data transfer rate, distance between subcarriers, type or conditional number of the signal-code structure), which provide the maximum bandwidth of a radio link.

The found values of the optimized parameters of the radio line are transmitted for installation on the transmitting side. After setting new parameters on the receiving and transmitting side, the transmission of the information signal continues until the end of the communication, or until the next sensing session.

As signals of path sounding, which allow to obtain current values of the characteristics of the communication channel, phase and frequency keying signals, serial modem signals, linear frequency shift keying (LFM) signals transmitted in the information signal band can be used.

Further, for definiteness, we consider that the sequences of chirp signals transmitted in the band of the information signal are used as the signals of path sounding. A method for determining PRK when receiving a sequence of chirp signals transmitted in the band of an information signal is presented in [5]. The method of obtaining the values of the parameters of the frequency and time scattering, as well as the signal-to-noise ratio, is described in [6].

Correspondence tables are pre-calculated tables of the minimum signal-to-noise ratio values required to provide the modem with the specified quality of the received signal (given error probability) for the given values of time and frequency scattering in the channel). In addition to the minimum signal-to-noise ratio values, the tables also indicate the number of the signal-code structure and frequency subcarrier spacing at which the minimum value is achieved. The number of such tables should be equal to the number of possible speeds implemented by the OFDM modem. For example, for a 3.1 kHz signal band, the following series of speeds accepted for use in the HF radio channel can be adopted: 75, 100, 200, 300, 500, 1200, 2400, 4800, 7200, 9600 bit / s, while for implementation A whole series of information speeds use how many different signal-code constructions (CCMs).

The time and frequency scatter values used in the tables are taken in accordance with Recommendation ITU-R F.1487 [7]. Thus, the temporal scattering of the channel can take the following values:

0.5; one; 1.5; 2; 2.5; 3; 3.5; four; 5; 6; 7; 8; 9; 10; eleven; 12; fourteen; 16; eighteen; 20 ms

Frequency scattering can take the following values:

0.1; 0.5; one; 1.5; 2; 2.5; 3; 3.5; four; 6; 8; 10; 12; fourteen; 16; eighteen; twenty; 24; 28; 32; 36; 40 Hz

The correspondence table, in this case, is a matrix of all possible channel states of dimension [20 × 22], in each cell of which the minimum signal-to-noise value is established, which is necessary to ensure a given value of the error probability, as well as the type of CCM and the magnitude of the detuning in frequency of neighboring subcarriers OFDM signal at which this minimum is achieved. The ranges of the calculated signal-to-noise ratio values can also be selected from the recommendation [7], however, depending on the purpose of the system and the modem used, this range can be changed. The set value of the error probability that should be provided at the modem output (in a demodulated and decoded signal) is determined mainly by the characteristics of the terminal equipment used. The number of such correspondence tables should be equal to the number of possible information transfer rates.

The calculation of the correspondence tables is carried out by the method of simulation using simulation models of the communication system and the communication channel by repeatedly running on the obtained model of communication sessions until a statistically stable result is obtained. The Watterson model recommended by ITU-R is adopted as the model of the communication channel.

When modeling each pair of frequency and time scattering values that are possible in the channel, it is necessary to compare the minimum signal-to-noise ratio at which the specified quality of the received signal is achieved, the frequency mismatch between the OFDM signal subcarriers, and the number of the signal-code structure, from implemented by the modem. The necessity of introducing a CCM number is determined by the fact that different information rates can be implemented by different CCMs, in addition, in some cases, the same information rate determined by the signal bandwidth, modulation type, code rate, and the percentage of pilot signals relative to the total number of subcarriers can be implemented using different CCM. In the latter case, the CCM must be used that provides the lower required signal-to-noise ratio for realizing communication with a given quality (a given probability of errors).

When calculating the tables of conformity it is necessary:

- set the quality of reception, for example, R _OSH = 0.001;

- fix the data transfer rate, which is determined by the band, type of modulation, code rate, percentage of pilot signals relative to the total number of subcarriers,

- determine the range and the step of changing the set values of the signal / noise ratio, for example, from 0 dB to 50 dB with a step of 1 dB,

- determine the range and the step of changing the distances between subcarriers, the recommended values are from 4 Hz to 64 Hz with a step of 4 Hz.

For a number of fixed distances between subcarriers, which are determined by possible values of frequency and time scattering (recommended values are from 4 Hz to 64 Hz in steps of 4 Hz), a simulation experiment is conducted to pass the modem signal through a channel with predetermined fading. An experiment with a given signal / noise ratio is carried out until a predetermined number of errors has accumulated, which provides statistical stability of the simulation result.

Next, an error probability is estimated for a given signal to noise ratio. If the estimated value of the error probability is greater than the required, then we increase the signal-to-noise ratio by 1 dB and conduct tests again. If the signal-to-noise ratio exceeded the level of 50 dB, the experiment is terminated and the frequency and time scattering changes. If at some step of changing the signal-to-noise ratio it was possible to achieve a reception quality value that meets the specified requirements, then the calculations are stopped and the signal-to-noise ratio is calculated by linear interpolation, at which the specified error probability is reached.

After determining the signal-to-noise ratio for a fixed point of the channel state matrix, we proceed to the next value of the frequency and time scattering. After the required signal-to-noise ratio is determined for all points of the state matrix of the communication channel, we proceed to the next distance between the subcarriers.

As a result, a correspondence table is obtained for each speed, in which, for each pair of possible frequency and time scattering values in the channel, the minimum signal-to-noise value is determined at which the probability of error of received messages does not exceed a predetermined value of _Rosh , as well as the signal-code number the design and frequency diversity of adjacent OFDM signal subcarriers at which this minimum was reached.

The determination of the values of the optimized parameters of the radio communication system is carried out starting from the correspondence table for the maximum information speed as follows, using the values of the frequency and time scattering measured during the routing sounding, find the cell of the correspondence table corresponding to these values, compare the signal-to-noise ratio recorded in the table with the value signal-to-noise ratio, changed in the channel during the course of sounding. Moreover, if the signal-to-noise ratio indicated in the table cell is less than or equal to that measured in the channel, then the value of the information speed corresponding to this table is chosen, otherwise they go to the table with a lower speed and repeat the comparison process until they find the information speed, for where the signal-to-noise ratio indicated in the corresponding cell of the table is less than or equal to that measured in the channel. Track sensing is carried out at all operating frequencies allocated for communication, and for each frequency the maximum speed is determined at which a given communication quality is achieved, then the working frequency is selected at which the maximum information speed is provided, the frequency diversity value of adjacent OFDM subcarriers and the number of the used signal-code construction is selected from the table cell corresponding to the found information rate.

The optimization of the frequency detuning between the subcarriers of the OFDM signal allows adapting the emitted signal to the current channel parameters without changing the modem information speed, which increases the average speed and throughput realized by the modem. The proposed method for determining the optimal parameters of a communication system based on the results of route sounding also contributes to an increase in throughput. Pre-calculated correspondence tables allow more accurately determine the required values of the characteristics of the communication system, in comparison with other known methods.

Thus, the use of the proposed method allows to solve the problem.

Information sources

1. Komarovich V.F., Sosunov V.N. Random radio interference and HF communications reliability. - M.: Communication, 1977, 135 p.

2. RF patent No. 2139926, filed January 11, 1995, publ. 09/27/1999, a Method and device for adaptive selection of communication strategies in a radio communication system with selective calling of subscribers. Leitch K.D., Schwendeman R.D., McNack F.P. Applicant Motorola, Inc. (US).

3. RF patent No. 2284659, filed April 28, 2004, published September 27, 2006 in Bull. Number 27. Method and device for adaptive radio communication. Balybin V.M., Ryzhov P.P. and etc.

4. A set of technical means of adaptive data and speech transmission over the HF channels of the Pier series, http://www.rimr.ru/adm/uploaded/f10690-b03.doc.

5. Ivanov V.A., Ryabova N.V., Tsarev I.E. Diagnostics of the scattering function of decameter narrow-band stochastic radio channels // Radio Engineering and Electronics. Volume 55, No. 3, Moscow: Academic Publishing Center “Nauka”, 2009. - S. 1-7.

6. Ivanov V.A., Ryabova N.V., Tsarev I.E. A channel probe for studying the scattering function of ionospheric high-frequency radio channels // Proceedings of the symposium of the XXII-th All-Russian Scientific Conference "Radio Wave Propagation", September 2008, No. 2, p. 45-48.

7. Recommendation ITU-R F.1487, Testing of HF modems with bandwidths of up to about 12 kHz using ionospheric channel simulators - ITU-R. - 2000

8. W. Henkel, V. Azis, "Partial Transmit Sequences and Trellis Shaping," 5th International ITG Conference on Source and Channel Coding (SCC), Erlangen, January 14-16, 2004.

Claims (5)

1. A method for multi-parameter adaptation of a radio communication system using OFDM signals, based on the procedure of entering into communication, conducting route sensing, assessing the state of the message channel, finding the values of optimized parameters of the radio communication system, transmitting the values of the selected parameters to the transmitting end of the radio line, tuning the receiver and transmitter to new optimized parameters, information exchange, characterized in that the number of optimized parameters in the process Radiocommunication system adaptation ca additionally introduced quantity frequency diversity adjacent subcarriers OFDM-signal, wherein when changing the frequency diversity adjacent subcarriers

also change the duration of the OFDM signal T _OFDM according to the law

, the state of the communication channel is estimated by determining the values of frequency scattering, time scattering, and the signal-to-noise ratio based on the results of the routing sounding sessions, the values of the optimized parameters that provide the maximum bandwidth of the radio line are determined using pre-prepared correspondence tables, each of which for each pairs of possible frequency and time scattering values in the communication channel indicate the minimum signal-to-noise ratio necessary for communication with a given quality, as well as the type of signal-code construction and the frequency diversity of adjacent OFDM signal subcarriers at which this minimum value is achieved, and for each information transfer rate possible in the communication system, its own correspondence table is calculated. 2. The method according to p. 1, characterized in that the calculation of the correspondence tables is carried out using simulation models of the communication system and the communication channel by repeatedly running on the obtained model of communication sessions until a statistically stable result is obtained, while for each pair of frequency and the scattering time, the dependences of the probability of error on the signal-to-noise ratio are determined for all possible frequency diversity values of adjacent OFDM signal subcarriers in the system and for all possible in the system variants of the signal-code design, then, from the given value of the probability of error R _osh , which determines the necessary communication quality, from the obtained dependencies find the signal-to-noise ratio values corresponding to the given value of R _osh , from the obtained signal-to-noise ratios find the minimum value and write it in the corresponding cell of the correspondence table, the frequency diversity spacing of adjacent OFDM signal subcarriers and a variant of the signal-code construction corresponding to the found one are recorded in the same cell the minimum value of the signal-to-noise ratio, after which the calculation is repeated for the next cell of the table and so on until the table is filled, and for each information speed implemented by the system, its own table must be filled. 3. The method according to p. 1, characterized in that the determination of the values of the optimized parameters of the radio communication system is carried out, starting from the correspondence table for the maximum information speed, as follows, using the values of the frequency and time scattering measured during the route sounding, find the table cell corresponding to these values, compare the value of the signal-to-noise ratio recorded in the table with the signal-to-noise ratio changed in the channel during the path sounding, in this case, if the signal-to-noise ratio indicated in the table cell is less than that measured in the channel, then select the information speed value corresponding to this table, otherwise go to the table at a lower speed and repeat the comparison process until you find the information speed for which the signal-to-noise ratio value, indicated in the cell of the table corresponding to the measured values of the frequency and time scattering of the channel is less than the signal-to-noise ratio measured in the channel, while the type of signal o-code design (CCM) and the frequency diversity value of adjacent OFDM signal subcarriers. 4. The method according to p. 1, characterized in that in the presence of several operating frequencies, trace sounding is carried out at all operating frequencies allocated for communication, and for each frequency, the maximum speed is determined at which the specified communication quality is achieved, then the operating frequency is selected, at which the maximum information speed is provided, the value of the frequency diversity value of neighboring OFDM signal subcarriers and the number of the used signal-code structure are selected from the table cell corresponding to the found ormatsionnoy speed.