Search Results for “Lyakh Y. O.” – Collected book of scientific-technical articles https://journal.yuzhnoye.com Space technology. Missile armaments Tue, 05 Nov 2024 21:17:59 +0000 en-GB hourly 1 https://journal.yuzhnoye.com/wp-content/uploads/2020/11/logo_1.svg Search Results for “Lyakh Y. O.” – Collected book of scientific-technical articles https://journal.yuzhnoye.com 32 32 10.1.2024 METHOD OF AUTONOMOUS DETERMINATION OF THE ROCKET’S REFERENCE ATTITUDE DURING PRE-LAUNCH PROCESSING https://journal.yuzhnoye.com/content_2024_1-en/annot_10_1_2024-en/ Mon, 17 Jun 2024 08:44:04 +0000 https://journal.yuzhnoye.com/?page_id=35018
Zmenshennya chasovykh pokhibok inertsialnogo vymiryuvalnogo modulya shlyakhom realizatsii yogo strukturnoi nadlyshkovosti na bazi tryvisnykh micromekhanichnykh vymiruvachiv.
]]>

10. Method of autonomous determination of the rocket’s reference attitude during pre-launch processing

Organization:

Yangel Yuzhnoye State Design Office, Dnipro, Ukraine

Page: Kosm. teh. Raket. vooruž. 2024, (1); 85-92

DOI: https://doi.org/10.33136/stma2024.01.085

Language: Ukrainian

Annotation: To solve the navigation tasks (determination of the apparent accelerations and angular velocities and calculation of rocket orientation angles) in the rocket engineering, the data from the sensing elements (angular velocity sensors and accelerometers) is used. Accuracy of reference attitude determination of the rocket in the steady mode (at lift-off) has great influence on accuracy of the received navigation data during the flight. Gimballess inertial navigation system, built on the basis of inertial MEMS-sensors of Industry class (three angular velocity sensors and three accelerometers), is taken as the navigation device. In the classical version, the integration of data from angular velocity sensors and from accelerometers is the basis of gimballess inertial navigation system operation. It results in accumulation of errors when solving the navigation task (in particular due to the integration of data from angular velocity sensors). Taking it into consideration, the alternative method of rocket’s reference attitude determination during the pre-launch processing is offered. This method does not use mathematical operations of integration and is autonomous. Initial data, received from the gimballess inertial navigation system, is used as the output data. This data is used to determine the rocket’s reference attitude (orientation of object-centered coordinates in the geographical reference system) in the steady mode. Orientation angles are determined without the integration of data picked up from the angular velocity sensors. The comparative analysis to define the processing efficiency of the navigation device initial data was held during the determination of the rocket’s orientation angles in the steady mode, using the proposed method and Runge-Kutta method. The received results showed that accuracy of the reference attitude determination with the proposed method is higher. Thus, the proposed method will help reduce the errors in determination of the rocket’s reference attitude in the steady mode that in the future will improve the accuracy in determination of navigational parameters during the rocket’s flight.

Key words: navigation system, mems-sensors, accelerometers, angular velocity sensors, reference attitude

Bibliography:
  1. Meleshko V.V., Nesterenko O.I. Besplatformennye inertsialnye navigatsionnye systemy. Ucheb. posobie. Kirovograd: POLIMED – Service, 2011. 164 s.
  2. Vlasik S.N., Gerasimov S.V., Zhuravlyov A.A. Matematicheskaya model besplatformennoy inertsialnoy navigatsionnoy systemy i apparatury potrebitelya sputnikovoi navigatsionnoy systemy aeroballisticheskogo apparata. Nauka i technika Povitryannykh Sil Zbroinykh Sil Ukrainy. 2013. № 2(11). s. 166-169.
  3. Waldenmayer G.G. Protsedura pochatkovoi vystavki besplatformennoy inertsialnoy navigatsionoy systemy z vykorystannyam magnitometra ta rozshirennogo filtra Kalmana. Aeronavigatsini systemy. 2012. s. 8.
  4. Korolyov V.M., Luchuk Ye.V., Zaets Ya.G., Korolyova O.I., Miroshnichenko Yu.V. Analiz svitovykh tendentsiy rozvytku system navigatsii dlya sukhoputnykh viysk. Rozroblennya ta modernizatsia OVT. 2011. №1(4). s.19-29. https://doi.org/10.33577/2312-4458.4.2011.19-29
  5. Avrutov V.V., Ryzhkov L.M. Pro alternativniy metod avtonomnogo vyznachennya shyroty i dovgoty rukhomykh obiektiv. Mekhanika gyroskopichnykh system. 2021. №41. s.  122-131. https://doi.org/10.20535/0203-3771412021269255
  6. Bugayov D.V., Avrutov V.V., Nesterenko O.I. Experimentalne porivnyannya algoritmiv vyznachennya orientatsii na bazi complimentarnogo filtru ta filtru Madjvika. Avtomatizatsiya technologichnykh i biznes-protsesiv. 2020. T. 12, №3. s. 10-19.
  7. Chernyak M.G., Kolesnik V.O. Zmenshennya chasovykh pokhibok inertsialnogo vymiryuvalnogo modulya shlyakhom realizatsii yogo strukturnoi nadlyshkovosti na bazi tryvisnykh micromekhanichnykh vymiruvachiv. Mekhanika giroskopichnykh system. 2020. №39. s. 66-80. https://doi.org/10.20535/0203-3771392020229096
  8. Rudik A.V. Matematichna model pokhibok accelerometriv bezplatformenoi inertsialnoi navigatsinoi systemy. Visnyk Vynnitskogo politechnychnogo institutu. 2017. №2. s. 7-13.
  9. Naiko D.A., Shevchuk O.F. Teoriya iomovirnostey ta matematychna statistika: navch. posib. Vinnytsya: VNAU. 2020. 382 s.
  10. Matveev V.V., Raspopov V.Ya. Osnovy postroeniya bezplatformennykh inertsialnykh navigatsionnykh system. SPb.: GNTs RF OAO «Kontsern «TsNII «Electropribor». 2009. 280 s.
  11. Novatorskiy M.A. Algoritmy ta metody obchislen’ [Electronniy resurs]: navch. posib. dlya stud. KPI im. Igorya Sikorskogo. Kiyv: KPI im. Igorya Sikorskogo. 2019. 407 s.
Downloads: 21
Abstract views: 
888
Dynamics of article downloads
Dynamics of abstract views
Downloads geography
CountryCityDownloads
USA San Jose; San Francisco; Clearwater; Chicago; Los Angeles; Ashburn; Buffalo; Los Angeles; Portland;10
Germany Falkenstein; Düsseldorf;; Falkenstein4
Singapore Singapore; Singapore2
Ukraine Uzhhorod; Kremenchuk2
France1
Unknown1
China Shenzhen1
10.1.2024 METHOD OF AUTONOMOUS DETERMINATION OF THE ROCKET’S REFERENCE ATTITUDE DURING PRE-LAUNCH PROCESSING
10.1.2024 METHOD OF AUTONOMOUS DETERMINATION OF THE ROCKET’S REFERENCE ATTITUDE DURING PRE-LAUNCH PROCESSING
10.1.2024 METHOD OF AUTONOMOUS DETERMINATION OF THE ROCKET’S REFERENCE ATTITUDE DURING PRE-LAUNCH PROCESSING

Keywords cloud

Your browser doesn't support the HTML5 CANVAS tag.
]]>
6.1.2016 Ensuring Solid Rocket Motor Moisture Resistance by Design https://journal.yuzhnoye.com/content_2016_1/annot_6_1_2016-en/ Tue, 23 May 2023 13:01:12 +0000 https://journal.yuzhnoye.com/?page_id=27610
, Lyakh Y. The list of problems is given, solution of which using the results of evaluation of parameters of heat-and-moisture transfer in multi-layer shells made of composite materials will allow to structurally ensure the moisture resistance of hardware operated in non-isothermal conditions during warranty period. Key words: Bibliography: Full text (PDF) || P., Lyakh Y. O., Babey Y. (2016) "Ensuring Solid Rocket Motor Moisture Resistance by Design" Космическая техника. Space technology. Space technology. P., Lyakh Y. O., Babey Y. Space technology. P., Lyakh Y. O., Babey Y. Space technology. P., Lyakh Y. O., Babey Y. Space technology. P., Lyakh Y. O., Babey Y. Space technology. P., Lyakh Y. O., Babey Y. Space technology.
]]>

6. Ensuring Solid Rocket Motor Moisture Resistance by Design

Organization:

Yangel Yuzhnoye State Design Office, Dnipro, Ukraine

Page: Kosm. teh. Raket. vooruž. 2016 (1); 46-51

Language: Russian

Annotation: The issues are considered of exclusion of influence of moisture exchange processes on moisturesensitive elements of hardware assemblies. The list of problems is given, solution of which using the results of evaluation of parameters of heat-and-moisture transfer in multi-layer shells made of composite materials will allow to structurally ensure the moisture resistance of hardware operated in non-isothermal conditions during warranty period.

Key words:

Bibliography:
Downloads: 33
Abstract views: 
798
Dynamics of article downloads
Dynamics of abstract views
Downloads geography
CountryCityDownloads
USA Boardman; Baltimore; Columbus; Phoenix; Phoenix; Monroe; Ashburn; Columbus; Ashburn; Seattle; Tappahannock; Portland; San Mateo; San Mateo; San Mateo; San Mateo; Columbus; Des Moines; Boardman; Ashburn; Ashburn; Boardman; Seattle23
Singapore Singapore; Singapore; Singapore; Singapore4
Ukraine Dnipro; Dnipro; Odessa3
Germany Falkenstein1
Romania Voluntari1
Netherlands Amsterdam1
6.1.2016 Ensuring Solid Rocket Motor Moisture Resistance by Design
6.1.2016 Ensuring Solid Rocket Motor Moisture Resistance by Design
6.1.2016 Ensuring Solid Rocket Motor Moisture Resistance by Design
]]>