SU840964A1 - Device for simulating mass servicing systems - Google Patents

Description

The invention relates to computing technology.

A device is known for modeling queuing systems, containing a sensor for a random sequence of binary numbers, ’pulse generator, counter, decoders, typesetting field, registers, AND elements, noise generator

The disadvantage of the known device is its complex functional diagram.

Closest to the technical nature of the proposed device is a device containing random voltage generators, a distribution block, a simulation block queue, a measuring unit [2].

₍ A disadvantage of the known device is the complex functional diagram of the device.

The purpose of the invention ⁷ is to simplify the device! state.

This goal is achieved by the fact that in the device for modeling queuing systems, containing the first and second random voltage generators, a measuring unit, an adder, a quantizer, a clock generator, an integrator, a comparator, the first and second elements And, are added, and the outputs of the first and second random voltage generators are connected to the inputs of the adder, the output of which is connected to the first input of the quantizer, the second input of which is connected to the first output of the clock the second output of which is connected to the first inputs of the first element And and the measuring unit, the output of the quantizer is connected to the input of the integrator, the output of which is connected to the input of the comparator, with the second input of the measuring unit and with the first input of the second element And, the output of which is connected to the input of the integrator, the output the comparator is connected to the second input of the first element And, the output of which is connected to the third input of the measuring unit and to the second input of the second element I.

The drawing shows a diagram of the proposed device.

The device comprises random voltage generators 1 and 2, an adder 3, a quantizer 4, an I 5 element, an integrator 6, a comparator 7, an I 8 element, a measuring unit 9, and a clock generator 10. . 10

The device operates as follows.

Generator 1 generates a random, continuously varying voltage, the amplitude of which is distributed in co- ^'15 otvetstvii law distribution of time intervals between pulses, and the generator 2 - random, continuously varying voltage, the amplitude θ ₂ is distributed in accordance with service law. Each of these oscillators may be formed by known circuits containing, as a primary source of noise semi- conductor element _25, and amplifier. functional converter. The voltage from the outputs of the generators is fed to the inputs of the adder 3. Quantizer 4 converts the output voltage of the sum ₃ θ torus into a discrete-continuous signal. As a quantizer, it is advisable to use well-known storage sampling schemes consisting of a key, a memory encoder and a separation amplifier ₃₅ . The work of the quantizer 4 is controlled by a clock generator 10, the output of which is formed by a periodic sequence of pulses.

A discrete-continuous signal from the output of the quantizer _4Q is fed to the input of the integrator 6. If, at the time of quantization, the voltage amplitude simulating the time interval between requests is greater than the voltage amplitude simulating the service time ₄₅ , a linearly increasing voltage is generated at the integrator output, which leads to the operation of the comparator 7 and the opening of the element And 8. The pulse of the periodic sequence preceding the moments of quantization, from the second output of the generator 10 through the element And 8 using the element And 5 It pours zero initial conditions at the integrator's output, preparing _5J for the next modeling stage. The presence of a pulse at the output of element And 8 indicates that the application is being served without waiting, and the voltage value at the output of the integrator characterizes a simple servicing apparatus, which is simultaneously recorded by measuring unit 9. If, at the time of quantization, the voltage amplitude simulates the time interval between applications, less than the amplitude of the voltage modeling the service time, a linearly increasing negative voltage is generated at the output of the integrator 6, which, with the help of the comparator 7, prevents them from passing pulse via the AND gate 8 and the zero setting of the initial conditions. A negative voltage formed at the integrator’s output characterizes the overload of the servicing apparatus, and the absence of a pulse at the valve output indicates the organization of the queue. The subsequent results of the comparison of the amplitude samples, formed at the output of the quantizer, are summed with the voltage of the integrator until the voltage at its output becomes positive - the moment the queue is finished serving. The number of terms (quantization times) involved in the summation characterizes the length of the queue and is recorded using the measuring unit.

The presence of new blocks and the relationships between them allows us to simplify the functional diagram of the device for modeling queuing systems.

Claims (2)

1. USSR author's certificate N 190О60, cl. GOGG 7/48, 1967. 2. USSR Author's Certificate No. 190О79, cl. G06G 7/48, 1967 (prototype).