SU476570A1 - Method for specifying the delay in calculating the correlation function of pulsed random signals - Google Patents

Description

Thus, with each playback, the delay is increased by the smallest time interval found during the previous playback, the realizations of both processes are summed up, and the smallest time interval between pulses in the total implementation is found to increase the delay during the next playback. In addition, in the process of each reproduction, the delay of one process with respect to / fugo is left unchanged during the integration interval of duration.

As a result of such a change in the delay in a sequential correlation analysis, a set of discrete values of the correlation function is obtained, separated by the shortest time intervals found in aggregate realizations with corresponding replays. At the same time, the number of reproductions of implementations M does not depend on the size of the selected sampling interval and is found by the formula

M,

-with me

 -the average arithmetic value of the smallest time intervals.

It can be shown that the total analysis time in the described method is always less than in the prototype method, since it is always longer than the sampling interval.

The described method for determining the values of the correlation function of pulsed random processes reduces the total time of sequential analysis by reducing the number of plays of the recorded realizations of pulsed random processes. With this method, the total time of sequential analysis does not depend on the choice of the sampling interval, which makes this method especially effective with short durations of pulses of random processes, taking into account that the sampling interval should be less than the duration of any of the pulses of random processes.

The drawing shows a variant of the device that implements the described method.

The device contains a delay adder 1, a control circuit 2, a charger 3, a shaper 4 positive pulses, a shaper 5 negative pulses, an inverter 6, a coincidence circuit 7, a mixer 8, a meter 9 time intervals, a selection circuit 10 of the smallest time interval (NVI).

The device works as follows.

Before starting work on the delay adder 1, set the initial delay code. In this case, the control circuit 2 from the delay adder 1 receives a code corresponding to the initial delay. After that, the playbacks of the impulse random processes recorded in the memory 3 are reproduced. During the first playback, one implementation, for example, the second, is delayed relative to the first by the amount of the initial delay. Of

The memory 3 pulses of the first implementation arrive at the shaper 4. At the instants of the appearance of the pulses on the shaper 4, positive pulses in amplitude and duration are formed, regardless of their polarity. The pulses of the second implementation arrive at the shaper 5. At the instants of the pulses appearing on the shaper 5, regardless of their polarity, negative pulses are amplified by amplitude and duration and are fed through inverter 6 to the coincidence circuit 7. The last also receives the ground light pulses from the shaper 4. The positive pulses from the imaging unit 4 and the negative pulses from the imaging generator 5 are fed to the mixer 8, where they are summed in time. With the coincidence in time of the pulses from the formers 4 and 5, they mutually

are compensated at the input of the mixer 8, but at this time a coincidence pulse appears at the output of the matching circuit 7, which is fed to the meter 9 time slots. The impulse flow from the mixer 8 also

enters the meter 9. The measurement of the time intervals between pulses in the total flow is carried out from the moment when the meter 9 arrives at the input of a positive pulse from mixer 8 or from the coincident 7 circuit until the moment of arrival of a negative pulse from mixer 8 or the next positive pulse from the coincidence circuit 7. Thus in total pulse

The flow measures the intervals between adjacent ones:

a) positive and negative impulses;

b) coincidence pulses and negative pulses;

c) positive pulses and coincidence pulses;

d) coincidence pulses.

Such measurement of time intervals is a prerequisite for calculating non-zero values of the correlation function of impulse stochastic processes. Codes of measured time intervals with

The meter 9 is fed to the circuit 10, from where the code of the MBC, selected from all the measured time intervals during this playback, is fed to the delay adder 1 and is summed with the contents of the adder. The resulting total delay is applied to control circuit 2. In the next iteration, the second implementation is delayed by the amount of the total delay and is summed with the first implementation. Re located

the value of the smallest time interval for a given playback to increase the total delay by that value during subsequent playback. With each reproduction of the implementation

impulse random processes recorded

in memory 3, is fed to a correlator multiplier to determine the values of the correlation function.

During each playback, the delay of the second implementation with respect to the first one remains unchanged during the integration interval with the duration TQ.

The described method can be used in broadband communication systems for receiving synchronization signals of a complex structure and determining the phase of a received signal relative to the reference sequence.

The method can also be applied in correlation receivers, where the threshold is chosen so that the receiver turns out to be asymptotically nonparametric in the noise class, possessing their given correlation function.

In addition, the method can be used in automatic control for identifying linear dynamic systems based on the analysis of the obtained values of the correlation function.

Subject invention

The method of defining the delay in calculating the correlation function of pulsed random signals, based on a stepwise change in the delay of one signal relative to another when they are repeatedly reproduced by an amount constant during one calculation cycle, differs

so that, in order to reduce the computation time, during the previous reproduction, both signals sum up and find the smallest time interval between pulses in the sum signal, by the value of which the dead time is measured: ki at the subsequent reproduction of the signals.