RU2472286C1 - Digital generator of chaotic signal - Google Patents

Abstract

FIELD: radio engineering.SUBSTANCE: invention relates to the field of radio engineering and may be used in contemporary, noise-protected and confidential systems of information protection to develop a noise signal, in control and measurement systems for measurement of frequency characteristics, and also in coding systems for generation of random numbers and sequences. The invention consists in the fact that the device comprising a clock pulse oscillator, an N-digit shift register, a summator by module two, a start circuit, and besides, the output of the clock pulse oscillator is connected with the input "C" of the shift register, the output of m digit of which is connected with the first input of the summator by module two, the second input of which is connected with the output of the circuit of start and initial initialisation of shift register, one of inputs of which is connected with the output of the last digit of the shift register, the input "D" of which is connected with the output of the summator by module two, additionally comprises an analog chaotic generator G1, a controlled source of reference voltage and an analog comparator DA1 of the level of the chaotic generator signal with the level of the reference signal, set by the controlled source of reference voltage, arranged on a potentiometer R1.EFFECT: creation of a digital generator of a chaotic signal, having, in contrast to a prototype, a truly random nature of an output signal, with preservation of a sheet-oriented simplicity and comparably small dimensions.1 cl, 3 dwg

Description

The invention relates to the field of radio engineering and can be used in modern, noise-protected and confidential communication systems, in information protection systems for creating a noise signal, in control and measuring systems for measuring frequency characteristics, as well as in coding systems for generating random numbers and sequences.

Known broadband digital noise generator, consisting of a clock, a shift register, an adder modulo two and a trigger circuit. The output of the clock generator is connected to the input "C" of the shift register, the output of the nth discharge of which is connected to the first input of the adder modulo two, the second input of which is connected to the output of the trigger circuit, the input of which is connected to the output of the last bit of the shift register, input "D" which is connected to the output of the adder modulo two. In addition, a series-connected power amplifier, a multiplying diode and a strip line are additionally introduced into the generator, while the output of the last bit of the shift register is connected to the input of the power amplifier, the output of which is connected through a multiplying diode to the strip line (RF Patent No. 2208289, Н03В 29/00, publ. 07/10/2003).

Also known is a digital noise generator containing a shift register, an adder modulo two, a clock generator, a start circuit, and low-passive filters (Marder M., Fedosov V. Digital noise generators. / Radio, 1990. No. 8, p. 68-71) .

The closest in technical essence to the claimed invention adopted as a prototype is a digital noise generator, which contains an eight-bit (in the general case, N-bit) shift register, an adder modulo two, a clock generator, a start and initialization register for the shift register. The output of the clock generator is connected to the input of the shift register, the output of the first bit of the shift register is connected to the first input of the adder modulo two, the second input of the adder modulo two is connected to the output of the trigger circuit, one of the inputs of which is connected to the output of the last digit of the shift register, the input the shift register is connected to the output of the adder modulo two. There are elements that also provide initialization of the shift register with a non-zero value when the power is turned on, and some of them specify the time interval during which the initialization takes place (see Andrianov V.I., Borodin V.A., Sokolov A.V. " Spyware and devices for protecting information objects. ”St. Petersburg: Doe, 1996, p.146).

The disadvantage of the prototype, as well as the above analogues, is the pseudo-random nature of the generated chaotic sequence of digital pulses, the duration of which depends on the number of bits of the shift register - N. This dependence complicates the generator (increase the number of bits of the shift register N) to achieve an acceptable pseudorandom duration sequence.

The technical task of the claimed technical solution is to create a digital chaotic signal generator, which, in contrast to the prototype, has a truly random output signal, while observing the circuit simplicity and relatively small structural dimensions.

The required technical result is achieved by the fact that in a digital chaotic signal generator containing a clock generator, an N-bit shift register, an adder modulo two, a shift register start and initialization circuit, the output of the clock generator being connected to the shift register input “C”, output m the second discharge of which is connected modulo two to the first input of the adder, the second input of which is connected to the output of the start-up and initialization circuit, the input of which is connected to the output of the last bit of the shift register, whose input "D" The modulus two adder ods, according to the technical solution, an analog chaotic generator, an adjustable reference voltage source and an analog comparator of the signal level of a chaotic generator with a reference voltage level from the output of the adjustable reference voltage source, made, in particular, in the form of a potentiometer, are additionally introduced. The output of the analog chaotic generator is connected to one of the inputs of the analog comparator, to the second input of which the output of the adjustable reference voltage source is connected, while the output of the analog comparator is connected to one of the inputs of the start and initialization circuit, the reference signal source and the analog comparator of the signal level of the chaotic generator with a level of the reference voltage allow aperiodically initializing the shift register with a random non-zero value and obtain chaotically at the output of the shift register sky sets of random sequences.

The claimed technical solution differs from the prototype in the presence of new units: an analog chaotic generator, an analog comparator, an adjustable voltage reference source (made, in particular, in the form of a potentiometer) and their connections with other circuit elements. These differences allow us to conclude that the proposed solution meets the criterion of "novelty."

The required result is achieved by the entire newly introduced set of essential features that are not found in the well-known patent and scientific literature at the filing date of the application. Therefore, the technical solution meets the criterion of "inventive step".

The proposed solution is illustrated by drawings, where figure 1 shows a diagram of the proposed device. The following notation is used in the drawing: G - clock; DD1 ... DD8 (N) - shift register; D2 - adder modulo two; D1, D3, R, C - a chain of start and initialization of the shift register; G1 - analog chaotic generator; DA1 - analog comparator; R1 - potentiometer, which is an adjustable voltage reference source.

Figure 2 and figure 3 presents the plot of the signals at the characteristic points of the device. So, plot a in figure 2 shows the output signal of the chaotic generator G1 used in the device. Diagram b in figure 2 illustrates the signal passed through the comparator circuit DA1, converted into a sequence of logical pulses with randomly varying duration.

The control analog chaotic signal supplied to the input 1 of the element D1 is shown in FIG. 3. And on the plot b of figure 3 shows the output signal of the shift register, to achieve clarity, converted into analog using a digital-to-analog converter. This signal has an aperiodic random character as a result of the action of the control signal, the form of which is shown in diagram b of figure 2.

According to the scheme shown in figure 1, the output of the clock generator G is connected to the input "C" of the shift register DD1 ... DD8 (N), the output of the mth discharge of which is connected to the first input of the adder modulo two D2, the second input of which is connected to the output of the trigger circuit D3, the input of the element D3 of which is connected to the output of the last bit of the shift register DD1 ... DD8 (N), the input "D" of which is connected to the output of the adder modulo two D2. To the second input of the start circuit element D3 of the start and shift register initialization, the output of the start circuit element D1 is connected, which generates a pulse of duration τ ~ RC, the value of which is determined by the values of the elements R and C connected to one of the inputs of the element D1. The output of the analog comparator DA1 is connected to another input of element D1, which compares the analog signal from the output of the chaotic generator G1 connected to one of the inputs of the comparator DA1, with the reference voltage supplied to the other input of the analog comparator DA1 from the output of the adjustable reference voltage source, made on the potentiometer R1 .

Digital chaotic signal generator operates as follows.

The shift register DD1 ... DD8 (N), having a length of N bits, is clocked by rectangular pulses of a given frequency supplied from the output of the clock generator G. Using an adder modulo two D2, a serial signal is applied to the register input, which is the sum modulo two of the mth and the last bit of the register DD1 ... DD8 (N). To output the shift register DD1 ... DD8 (N) from the zero state when the power was turned on, the circuit for starting and initializing the shift register (D1, D3, R, C) with a nonzero value was introduced into the circuit, which forms a logical unit signal at the output ~ RC, which is fed to the input of the adder modulo two D2. At the output of the shift register DD1 ... DD8 (N), pseudorandom sequences of pulses are formed, the duration and nature of which are determined by the output signal of the chaotic generator G1, through the comparator DA1 and the start and initialization circuit, aperiodically initializing the shift register DD1 ... DD8 (N) with a random value other than zero.

To achieve the correct operation of the digital chaotic signal generator, the repeat period T _N must be less than or equal to the maximum duration of the initialization pulse generated by the comparator DA1 from the analog chaotic signal of the generator G1 by comparison with the level of the reference signal U ₀ generated by the potentiometer R1.

The element D1 of the start-up and initialization circuit of the shift register is an AND gate, transparent by the signal of a logical unit at one of its inputs. When the device is turned on, the capacitor C is not charged and holds at one of the inputs of the valve D1 a logic zero for the time of charging its own capacitance through the resistor R to the value of a logical unit. During this time interval τ ~ RC, the shift register DD1 ... DD8 (N) is initialized with an initial non-zero value, and the signal from the output of the comparator DA1 does not affect the operation of the device as a whole. After the voltage across the capacitor C reaches the level of a logical unit, the gate D1 becomes transparent to the chaotic signal from the output of the comparator DA1, which intermittently interrupts the operation of the shift register and initializes it with a new random number until the repeat period T _{N is} reached.

Thus, at the output of the shift register DD1 ... DD8 (N), non-repeating pseudorandom sequences of pulses are formed, the duration and nature of which are randomly determined by the output signal of the chaotic generator G1. As a generator G1, one should use, for example, one of the schemes of dynamic chaos generators, the randomness of the output signal of which is strictly proved by modern methods of nonlinear dynamics.

For experimental verification of the claimed technical solution, a specific version of a digital chaotic signal generator was developed, similar to the circuit of Fig. 1. As a chaotic generator G1, a magneto-controlled bipolar generator with negative differential resistance was used, the chaotic nature of the output signal of which is strictly proved.

The output signal of the chaotic generator G1 used in the device is shown in the diagram in FIG. 2. Since this signal is analog and does not contain a constant component, then, being passed through the comparator circuit DA1, in comparison with the level of the reference voltage U _{0 of} zero value, it will be converted into a sequence of logic pulses with randomly varying duration, the form of which is shown in diagram b of FIG. 2.

After the capacitor C is charged through the resistor R at the input 2 of the element D1, the potential of the logical unit is established, the element D3 will become a repeater of the logical state of the register output and will not affect the operation of the driver. When one of the inputs of the logic gate D3 of the type “exclusive OR” or “adder modulo two” of a logical unit is received, this element will become an inverter of the logical state of the second input.

Thus, changing the logical state at the input of the element D3, you can change the polarity of the signal in the feedback circuit, and therefore the nature of the output signal. By changing the control signal in a chaotic manner, one can obtain chaotic sets of random sequences at the output of the shifting register.

If a chaotic control signal generated at the output of the comparator DA1 is fed to input 1 of element D1 (diagram a in Fig. 3), then under its influence the output signal of the shift register acquires an aperiodic random character (diagram b in Fig. 3).

Thus, controlling the shift register of limited bit depth using a chaotic generator allows, with limited elemental resources, to realize a compact digital generator of a random sequence, which is a chaotic signal. As chaotic generators in order to increase stability in the device, it is convenient to use their modern implementations in integrated design.

Claims (1)

A digital chaotic signal generator, consisting of a clock generator, an N-bit shift register, an adder modulo two, a shift register start and initialization circuit, the output of the clock generator being connected to the shift register input C, the output of the mth discharge of which is connected to the first the adder input modulo two, the second input of which is connected to the output of the start and initialization circuit, the input of which is connected to the output of the last bit of the shift register, the input "D" of which is connected to the output of the adder modulo two, characterized in then it additionally introduces an analog chaotic generator, an adjustable reference voltage source and an analog comparator of the signal level of a chaotic generator with a reference voltage level, while the output of an analog chaotic generator is connected to one of the inputs of an analog comparator, to the second input of which an output of an adjustable reference voltage source is connected, and the output of the analog comparator is connected to one of the inputs of the start and initialize the shift register.

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