SU1179330A1 - Random pulse flow generator - Google Patents

Abstract

A GENERATOR OF A RANDOM FLOW OF PULSES, containing a Poisson pulse generator, the output of which is connected to the information input of the code-intensity converter, the output of which is connected to the information input of a frequency divider, the transfer output of which is a generator of random numbers, the output of which is connected with the address input of the memory unit, the output of which is connected to the control input of a frequency divider, characterized in that, in order to expand the functional, possibility of producing the generator due to generalized Erlang law, it comprises a second memory unit, whose output is connected to the control input of the converter m yup9 code-rate, and with the address input of the second block memory is connected to the data output of the divider (L frequency ./.

Description

The invention relates to an auxiliary technique and can be used in the simulation of restoration flows (Palm flows) of the field of Marcozian processes and non-Glossonian queuing systems. The aim of the invention is to enhance the functionality of the generator by obtaining a stream of pulses, subject to the generalized Erlang law. . FIG. 1 shows a structural diagram of the generator in FIG. 2 is a state graph of frequency divider. The random pulse generator contains a generator 1 of a Poisson pulse stream, a code-intensity converter 2, a divider 3 frequencies, the first 4 and second 5 memory blocks, a generator of 6 random numbers. The generator works as follows. Let the divider of the 3 frequencies be in an arbitrary state at the initial moment of time. To the control input of converter 2, the code stored in the second memory block 5 is located at the address specified by the code of the divider 3. The converter 2 code - the intensity is a controlled probability gate, which pulses the generator with a given probability 1. At the moment of appearance of a pulse during the converter 2, the state of the divide 3 frequency increases by one, which leads to a change in the code at its output. The process of changing the order of the 3 frequency divider is a cyclic Markov process. The state graph of this process is shown in FIG. 2. From the graph it follows that the pulse at the output of the generator is formed through the time necessary for the divider to perform 3 frequencies of one cycle. The time sought is the sum of random intervals, subject to indicative laws with different parameters. At the moment when the divider 3 reaches the zero-state frequency, a pulse of the output stream is generated, which polls generator 6. In accordance with the probability distribution in generator 6, the first memory block 4 is randomly extracted and added to divider 3 frequencies in the additional code to form another pulse in the output of one generator stream. The values of the division factors of the 3 frequency divider are stored in additional codes in the first memory block 4. The transition intensities are set using the codes recorded in the second memory block 5. Depending on the nature of the information in the two memory blocks 4 and 5, the proposed generator generates random streams of pulses, for the description of which the following laws are used: the Erlang law (Rl) -ro, if the values of the control codes in the first 4 and second 5 memory blocks These are the same, respectively (prototype function) J a mixed Erlang law with weights P, if the values of the control codes in the first memory block 4 are different, and in the second memory block 5 the same (prototype function) 5 generalized Erlang law (Rl) - ro oka if s The control codes in the first memory block 4 are the same, and in the second memory block 5 - different (new generator function)} a mixed generalized Erlang law with weights if the value of the control codes in the first 4 and second 5 memory blocks are different respectively (new generator function). Thus, the proposed generator provides for the reproduction of a wider class of distributions of time intervals between pulses as compared with a proto-generator.

Claims (1)

A random pulse stream generator containing a Poisson pulse stream generator, the output of which is connected to the information input of the code-intensity converter, the output of which is connected to the information input of the frequency divider, the transfer output of which is the generator output and connected to the Poll generator input, the output of which is connected with the address input of the memory unit, the output of which is connected to the control input of the frequency divider, characterized in that, in order to expand the functional capabilities generator, by obtaining generalized Erlang laws, it contains a second memory block, the output of which is connected to the control input of the code-intensity converter, and the address input of the second memory block is connected to the information output of the frequency divider. e co £ figure 1> 1179330 2