№2 2019


Prognostic potential of mathematical experiment planning


1,2A.A. Kovel


1Siberian Federal University
Krasnoyarsk, Russian Federation
2Siberian Fire and Rescue Academy EMERCOM of Russia
Zheleznogorsk, Krasnoyarsk region, Russian Federation


The ground-experimental testing of the elements of space technology is a crucial stage in the creation of space products, in fact, this is the ground «flight» of the devices being created. And how well the operating conditions will be reproduced at this stage and the successful functioning of the devices under the expected conditions is ensured, its successful operation in real flight during the service life depends. Electronic equipment (apparatus) of the spacecraft is one of the essential elements that ensure the fulfillment of target tasks, which should confirm their readiness for the forthcoming work at the stage of ground-based experimental testing. The technology of experimental development at a time when the scientific and production association of applied mechanics (now the JSC Academician M. F. Reshetnev Information Satellite Systems) was part of the circle of enterprises that created space technology. And at the same time, the peak of research and implementation in the engineering practice of mathematical experiment planning turned out to be very timely. There was a backlog of applied work in various branches of science and technology and a minimum of work on radio-electronic topics, since the element base of the latter did not allow managing the internal parameters of electronic components, i. e., to reveal the influence of internal factors. This became an obstacle to the implementation of the capabilities of the method in research and improvement of electronic equipment. The article shows how the developers of the enterprise equipment overcame the existing limitations and successfully applied mathematical planning of the experiment for the first time in Russian space technology. Using the capabilities of the methodology, the tasks of optimization of circuit design and design implementation of devices, the choice of the element base for space equipment, the establishment of tolerances and the formation of test modes, etc. were solved.


factors, planning matrix, mathematical experiment planning, full factorial experiment, factorogram, response corridor, factor niche


[1] Adler Yu. P., Granovsky Yu. V. // Pravda, 1973, March 23. (In Russian)

[2] Ivobatenko B. A., Ilinsky N. F., Kopylov I. P. Planirovanie eksperimenta v elektrotekhnike [Planning of an experiment in electrical engineering]. Moscow, Energy, 1971, 185 p. (In Russian)

[3] Mizylov V. I., Fedosov K. M. Planirovanie eksperimenta v sudostroenii [Planning of an experiment in shipbuilding]. Leningrad, Sudostroenie, 1978. 159 p. (In Russian)

[4] Barabashchuk V. I., Kredentser B. P., Miroshnichenko V. I. Planirovanie eksperimenta v tekhnike [Planning an experiment in engineering]. Kiev, Technics, 1984. 198 p. (In Russian)

[5] Sindyaev N. I. Teoriya planirovaniya eksperimenta i analiz statisticheskih dannyh [The theory of experiment planning and analysis of statistical data]. Moscow, Yurayt, 2011. 399 p. (In Russian)

[6] Kovel A. A., Pokidko S. V. Matematicheskoe planirovanie eksperimenta pri otrabotke elektronnyh ustrojstv [Mathematical planning of the experiment when developing electronic devices] // Journal of Instrument Engineering, 2008, vol. 51, no. 8, pp. 13–18. (In Russian)

[7] Smirnov N. V., Dunin-Barkovsky I. V. Kurs teorii veroyatnostej i matematicheskoj statistiki dlya tekhnicheskih prilozhenij [Course of probability theory and mathematical statistics for technical applications]. Moscow, Science, 1965. 556 p. (In Russian)

[8] Kovel A. A. Ustanovlenie dopuskov na parametry elektronnyh ustrojstv po rezul'tatam mnogofaktornogo eksperimenta [Establishment of tolerances on the parameters of electronic devices based on the results of a multifactor experiment] // Journal of Instrument Engineering, 2008, vol. 51, no. 8, pp. 18–22. (In Russian)

[9] Kovel A. A. Kapustin A. N. Sposob formirovaniya ispytatel'nyh testov [The method of forming the test tests]. Patent RU 2469372, 2012, bulletin no. 31.

[10] Kovel A. A., Pokidko S. V. Matematicheskoe planirovanie eksperimenta v usloviyah faktornoj nishi [Mathematical planning of the experiment in a factor niche] // Journal of Instrument Engineering, 2011, vol. 54, no. 4, pp. 47–50. (In Russian)

[11] Kovel A. A., Pokidko S. V. Issledovanie elementnoj bazy bortovoj apparatury v usloviyah kosmicheskogo prostranstva [Investigation of the element base of onboard equipment in space conditions] // Journal of Instrument Engineering, 2011, vol. 54, no. 4, pp. 54–57. (In Russian)

[12] Kovel A. A., Pokidko S. V., Verkhoturov V. I. Sposob izmereniya parametrov elementov radioelektronnoj apparatury v usloviyah vozdejstviya faktorov kosmicheskogo prostranstva [A method for measuring the parameters of radioelectronic equipment elements under the influence of space factors] : author's certificate USSR 289851, 1990.

For citing this article

Kovel A.A. Prognostic potential of mathematical experiment planning // Spacecrafts & Technologies, 2019, vol. 3, no. 2, pp. 87-93. doi: 10.26732/2618-7957-2019-2-87-93

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