SU926779A2 - Device for determining optimum working frequencies - Google Patents

Description

(54) DEVICE FOR DETERMINING OPTIMAL OPERATING FREQUENCIES

The invention relates to radio, can be used to determine the operating frequencies and the transmission rate of a discrete information in adaptive communication systems with sounding.

According to the main author. St. No. 651488, a device dp for determining operating frequencies is known, comprising on the transmitting side a command encoder and a serially connected broadband signal modulator, a wideband transmitter, and on the receiving side. suboptimal frequency selection unit and subsequently connected wideband receiver, broadband multi-frequency demodulator and command decoder, the output of the wideband receiver connected to the input of the suboptimal frequency selection unit, as well as on the transmitting side 6jioK synchronous control and connected in series sounding probe generator and switch whose output is

Claims (2)

The second and third inputs of the switch are connected to the outputs of the command encoder, to the control input of which the first output of the synchronous control unit is connected, the second output of which is connected to the control input of the wideband transmitter, and the additional output of the command encoder connected to the input of the sounding pulse generator, the second input.-of which is connected to the second input of the switch, as well as on the receiving side the synchronous control unit and the series-connected unit and multipath measurements and a processing unit, to the control input of which the first output of the synchronous control unit is connected, the second and third outputs of which are connected respectively to the control inputs of the wideband receiver and the suboptimal frequency selection unit, the output of which is connected to the first input of the multipath measurement unit, the second input of which is connected to the output of the GI command decoder. However, the known device has an insufficient accuracy in the selection of optimal operating frequencies. The purpose of the invention is to increase accuracy. For this purpose, the device for estimating the depth of fading, the output of which is connected to the second input of the result processing unit, the first, second, third, fourth inputs of which are connected to the fourth output of the synchronous control unit, is entered into the device for determining the optimum operating frequencies. the suboptimal frequency selection block, with the input of the synchronous control unit, with the third output of the suboptimal frequency selection block and the third input of the result processing unit, moreover, the output deco The command cabinet is connected respectively to the third input of the sub-optimal frequency selector and to the input of the synchronous control unit. Moreover, the fading depth estimation unit is made in the form of the first And element, the minimum value selection block, accumulating adder, quad, divider, adder and second And element, sequentially connected control unit, operational storage ycTpojicTBa, memory register and storage device, sequentially connected the second and third outputs of the control unit are directly, and the fourth output through the element is NOT connected to the second input of the storage device, respectively, to the second input is accumulated And the second input and the output of the second element I are connected respectively to the fourth output of the control unit and the second input of the minimum value selection unit, the second output of which is connected to the second input of the memory register, the second input of the first element I, The auxiliary input of the divider and the output of the memory device are respectively the inputs and input of the fade depth estimator. FIG. 1 shows a structural electrical circuit of the device; FIG. 2 is a structural electrical circuit for evaluating the depth of the fading. The device for determining the optimal operating frequencies contains on the transmitting side a synchronous control unit 1, a command encoder 2, a transmitter of 3 probing pulses, a switch 4, a broadband modulator 5, a wideband transmitter 6, on the receiving side a synchronous control unit 7, a wideband receiver 8 , suboptimal frequency selection unit 9, multipath measurement unit 1O, result processing unit 11, broadband multi-frequency signal demodulator 12, command decoder 13, fading depth estimation unit 14. Moreover, the evaluation unit 14 of the fading depth contains AND elements 15 and 16, accumulating adder 17, quad 18, divider 19, adder 2O, minimum value selection unit 21, HE element 22, control unit 23, memory register 24, random access memory (RAM ) 25i the storage device (memory) 26, the device for determining the optimal operating frequencies (Fig. 1) works as follows. In a session, sounding at each of the sounding frequencies by a signal from the synchronous control unit 1, the command encoder 2 generates a periodically repeating sounding pattern during the interval Td, the sounding time of the broadband continuous signal, which through the switch 4 goes to the modulator 5 of the wideband signal. In modulator 5, the formation of a continuous C-frequency wideband probe signal and modulation according to a certain law (for example, phase-difference modulation or frequency telegraphy) is carried out. The generated signal from the output of the modulator 5 is fed to the input of the wideband transmitter 6 and is radiated. After transmitting the last combination of the probing feature, the command coder 2 generates a combination of the probing end by a wideband continuous signal, after transmitting the last symbol from the output of the coder 2 commands to the driver of the 3 probing pulses of the probing signal and the switch 4, the signal is sent that allows the driver 3 to work and its output connected via switch 4 to the input of the modulator 5. Shaper 3 generates a sequence of probe pulses during the interval T synchronously with the clock Encoder 2 sequence. The period of the probe pulses and their duration is chosen accordingly from the conditions of the maximum possible delay of the beams of the signal reflected from the ionosphere and the required resolution of the multipath structure. The pulse sequence from the output of the imaging unit 3 through the switch 4 and the modulator 5 enters the transmitter 6 and is radiated. At the receiving side during the time interval T, preceding the interval Td of sounding with a continuous test signal, sub-optimal frequency selection unit 9 by a command from the receiving unit 7 of the synchronous control Evmer power of interference on the packet of communication frequencies on the call (wideband receiver 8) measurements of the corresponding information bandwidth of each gradation of the speed of transmission of information modes of operation / and V-frequency components of the probing continuous broadband signal, respectively, in frequency sections of parpy frequency channels. Then, block 9 selects K from C ((c) partial frequent channels with a minimum interference power, in which, at the next probe interval Trt, it measures the average power and time of the test signal over It frequency channels, and also selects a parked channel with a minimum interference power, the frequency of which is connected in the interval T to the input of the multipath measurement unit for measuring the maximum delay of the beams on the pulse sounding signal. At the same time, on the TD interval, block 9 transmits samples of the envelope values of the Ic signals of the frequency partial channels to the second. roi of the fade depth estimator 14, controlled from the synchronous control unit 7 and the 13 coma decoder. The beginning of the Td interval for measuring the signal power in block 9 and the fading depth estimator in the estimator 14 is controlled by the demodulator 12 of the wideband signal and decoded by the decoder 13 commands for the indication of the sounding attribute, and the end of this interval and the beginning of the next interval T of measuring the delay of rays in the measuring unit 10 of multipath, respectively, by combining the end of the probed broadband continuous signal. Measured at the interval T. values of the average interference power for the communication frequencies and the value 9 96 of the signal power at the interval Td, the block 9 outputs at the end of these intervals, respectively, the interference and the signal to the third auxiliary input of the processing unit 11 and only the signal to the fourth input of the evaluation unit depth of fading, which works as follows (Fig. 2). It is known that, for the Nakagami law of the dimming signal, there is a relationship between the quantile Ad. order C (, and the average power parameter D in the form of XQ Ac ((ivi). Independent sampling (code) of the 1c frequency channels that have been played on the interval Td are received alternately through the first element I, 15, controlled through the HE element 22 by the control unit 23 to the input of the minimum value selection block 21. The block 21 selects from each incoming, for example, eight current independent samples, a sample with a minimum value and writes it to the accumulating adder 17 with a shift controlled from the control block 23. In the accumulating adder 17 by O such samples (n 2) defined By summing and shifting by bits, the average in time and frequency value of the quantile Xq is about 0 О; -1/9, which is squared in the quadrant 18. AO from the output of the quad 18 Value, where the input to the divider is measured value L o and Q power of the signal coming from block 9 to additional input of divider 19, is calculated by dividing by Ci. Coefficient estimate AdCm). The calculated value of coefficient Ad (. Mn) is fed to the input of adder 2O, to which additional input and register 24 memory from the release of RAM 25 are received alternately The coefficients Aa (vn) recorded in RAM 25. In the adder 2O, the difference between the measured value of the Act (fli) and the values of the estimates of the coefficient A & (t) recorded in the RAM 25 is alternately calculated and the values of the differences alternately post the second element 16, to the control input of which, during this comparison, the enabling signal from control unit 23 was fed, to the auxiliary input of block 21. If the previous value of the difference is less than the current compared value of the difference (in absolute value), then the second output and 21 is prohibited from writing to the register 24, the memory current sravni9 Bai meanings koeffshshenta Aa (t) -. if the opposite condition is met, then the current value of the coefficient is recorded in register 24. Thus, in register 24, the comparison result records the approximate approximation value AaCt closest to the measured value, the value code of which is fed to the input of Address of the Memory 26, C to the control input of the memory 26 from the second output of the control unit 23 from the output of the memory 26, the value of the coefficient d of the factor d arriving at the second auxiliary input of the result processing unit 11 is read. In block 11 of processing the results of the fledged ia fetium, the input of mosh sshnal values and interference power forms for each communication frequency of the packet and the gradation of the transmission rate AND; Eformations are the average signal-to-interference ratio, which are corrected in accordance with the coefficient | d.-, taking into account the depth of the fading signal. On the received 1Sh receiving side and decoded by the decoder, 13 teams of combinations of con. and probing with a broadband continuous signal the measuring unit of 10 multiplicity for the duration of the time interval Ti measures the maximum delay of the beam along the stream of reflected pulses coming from the output of the wideband reception 8 through the block 9 at a frequency with a minimum level of interference on the input of the unit 10 1-1 Multipath measurements. Using the measured thresholds of the maximum delay of the beams in the result processing unit 11, calculates the maximum allowable for a packet of communication frequencies, the threshold transmission rate of the information format. Then, the corrected values of the Signal / Interference ratio for information transmission rates lower than the threshold speed determined by the threshold maximum delay of the beams are compared with the threshold values of the signal / interference and the frequency of communication with the maximum transmission rate of information is selected that satisfies both threshold values, which remembered. After the measurement is completed on one frequency band, unit 1 and block 7 switch the broadband transmitter 6 and broadband receiver 8 to the new frequency band, respectively, and the signal from block 1 to encoder 2 begins the measurement cycle on the new frequency packet, similar to that considered. Via windows 9. In the course of measuring cycles at all communication frequencies, the synchronous control unit 7 outputs to the control input 11 a result signal, which in block 1 selects the operating frequency with the maximum of all maximum df of each frequency-rate packet. The value of the operating frequency and the transmission rate of the it formation at this frequency is fed to the output of the processing unit 11. In the intervals between probing sessions, the device periodically checks at all communication frequencies the disturbance situation, and in the results processing unit 11, the information on disturbances is periodically updated, taking into account which the working frequency and speed are percocially repeated. The proposed device will allow to increase the accuracy of selection in the conditions of multipath signal and transient time and frequency of interference by taking into account when choosing the depth of total fading of the signal envelope and measuring interference at communication frequencies in the information band of each gradation of information transfer rate. In addition, the measurement of the average in time and frequency of the fading depth at the best partial channels in terms of interference can reduce the analysis time and improve the accuracy of the estimation of the depth of the signal fading. The use of the proposed device as part of an adaptive radio link will increase the reliability of communication, the capacity of the adaptive radio link. Claim 1. Device for determining the optimal operating frequencies according to the author. St. No. 651488, characterized in that, with an accuracy chain, a fade depth evaluation unit is inserted at the receiving side, the output of which is connected to the second input of the result processing unit, the first, second, third, fourth inputs of which are connected respectively to the fourth output of the synchronous control unit , with the second output of the suboptimal selection block, with the input of the synchronous control unit, with the third output of the suboptimal frequency selection block and the third input of the result processing unit, with the output of the command decoder connected respectively to the input of the suboptimal frequency selection unit and to the input of the synchronous control unit. 2. The device according to claim 1, characterized in that the block for evaluating the depth of fading is fulfilled in terms of the serially connected first element AND, the minimum value selection block, accumulating adder, quad, divider, adder and second element AND, sequentially connected to the control unit , random access memory, memory register and storage device, the second and third outputs of the control unit directly, and the fourth output via the element is NOT connected respectively to the second input, I memorize its devices, to the second input of the accumulating adder and to the input of the first element I, while the second input and output of the second element I are connected respectively to the fourth output of the control unit and the second input of the minimum value selection unit, the second output of which is connected to the second input of the register the memory, the second input of the first element And, j the additional input of the divider and the output of the memory device are respectively the inputs and the output of the evaluation unit and the depth of the fading. Sources of information taken into account in the examination li USSR author's certificate number 651488, cl. H 04 B 7/24, 1977 (prototype). / e eat i / as fPt / l1