SU783960A1 - Generator of pseudorandom pulse trains - Google Patents

Description

The invention relates to a pulse technique and can be used in the construction of instrumentation for discrete communication systems and computer technology.

A known generator of pseudo-random pulse sequences £ 1], · containing two shift registers with adders modulo two in the feedback circuit, an adder unit modulo two, an assembly circuit, a delay element, a matching circuit, and the shift register synchronization inputs are combined and connected to the output of the clock generator, and the adders are connected to the corresponding outputs of both shift registers.

The disadvantages of this generator are its complexity and insufficiently high performance.

The closest in technical essence to the proposed one is a pseudo-random pulse sequence generator £ 2 ^, containing 25 clock pulses, two shift registers and an adder modulo two.

The disadvantage of this generator is also its low speed. / 30

The aim of the invention is to increase performance, i.e. the limiting frequency of the formation of a pseudo-random sequence.

This is achieved by the fact that the generator of pseudorandom sequences of pulses containing a clock generator, the output of which is connected to the synchronization input of the first shift register, the output of which is connected to the first input $ of the adder modulo two, the output of which is connected to the information input of the first shift register, the second input modulo two adders is connected to the output of the second shift register, an inverter is introduced, and the output of the clock pulse generator is connected through the inverter to the synchronization input of the second register and shift, the information input of which is connected to the output of the adder modulo two.

The drawing shows a structural diagram of the proposed generator.

The generator contains a clock generator 1, shift registers 2, 3, an adder 4 modulo two, an inverter 5. The output bus 6 is also shown in the drawing.

The device operates as follows. If there is a clock pulse (unit) at the output of the generator 1, the state of the output of the adder 4 modulo two is written to the shift register 2, and if there is a pause (unit at the output of the inverter 5), the output state of the adder 4 modulo two is written to the register 3, which ensures separation of the sequence at the output of the adder 4 modulo two into a sequence of even and odd pulses having a half frequency. At the output of register 2, the sequence of odd pulses is shifted by H clocks, and at the output of register 3, the sequence of even pulses is shifted to clock cycles, and the sequences of even and odd pulses within each cycle have a mutual shift by the duration of the clock pulse. When summing modulo two sequences of even and odd pulses at the output of adder 4, a pseudo-random sequence is formed with a frequency twice that of the frequency of sequences of even and odd pulses.

To obtain the largest period of pseudorandom sequences, the number (2n-1) must be equal to the odd coefficient of the irreducible polynomial, and the number 2K must be equal to the even coefficient of the irreducible polynomial. To ensure the same duration of even and odd pulses in the sequence at the output of the adder 4 modulo-two, the duration of the clock pulse, neglecting the delay of the inverter 5, should be equal to half the period of the clock frequency.

The limiting frequencies of the sequences of even and odd pulses are equal to the limiting synchronization frequency of the applied shift registers 2, 3. The sequence at the output of adder 4 modulo two has a frequency twice that of a sequence of even and odd pulses, which means that its limit frequency is twice as large as the limit frequency of the synchronization of registers 2, 3 of shift I, therefore, than the limit frequency of the formation of a sequence in known devices.

Thus, in the proposed generator of pseudo-random sequences of pulses increases the frequency of formation of a pseudo-random sequence, which can be twice as high as the limiting synchronization frequency of the shift registers used. This allows for a given 15 frequency of sequence formation to use the element base with lower speed, but more economical.

Claims (1)

Claim . A pseudo-random pulse sequence generator, comprising: a clock pulse generator, the output of which is connected to the synchronization input of the first shift register, the output of which is connected to the first input of the adder modulo two? the output of which is connected to the information input 30 of the first shift register, the second input of the adder modulo is connected to the output of the second shift register, which means that in order to increase the speed, an inverter is introduced into the 35th, and the output of the clock generator is connected through inverter to the synchronization input of the second shift register, the information input of which is connected to the output of the adder modulo two.