Новые книги

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Опубліковано в: :	Технология и конструирование в электронной аппаратуре
Дата:	2014
Формат:	Стаття
Мова:	Російська
Опубліковано:	Інститут фізики напівпровідників імені В.Є. Лашкарьова НАН України 2014
Онлайн доступ:	https://nasplib.isofts.kiev.ua/handle/123456789/70576
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Назва журналу:	Digital Library of Periodicals of National Academy of Sciences of Ukraine
Цитувати:	Новые книги // Технология и конструирование в электронной аппаратуре. — 2014. — № 4. — С. 12, 20, 32. — рос.

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Digital Library of Periodicals of National Academy of Sciences of Ukraine

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citation_txt	Новые книги // Технология и конструирование в электронной аппаратуре. — 2014. — № 4. — С. 12, 20, 32. — рос.
collection	DSpace DC
container_title	Технология и конструирование в электронной аппаратуре
first_indexed	2025-12-07T15:47:44Z
format	Article
fulltext	Òåõíîëîãèÿ è êîíñòðóèðîâàíèå â ýëåêòðîííîé àïïàðàòóðå, 2014, ¹ 4 12 ÑÂ×-ÒÅÕÍÈÊÀ ISSN 2225-5818 V. I. CHASNYK Ukraine, Kiev, RDI “Orion” E-mail: ndiorion@tsua.net MICROWAVE ENERGY ATTENUATORS ON THE BASIS OF ALUMINUM NITRIDE WITH HIGH LEVEL OF MICROWAVE ENERGY ABSORPTION Results of experimental studies of aluminum nitride based composites with addition of silicon carbide and molybdenum having high microwave absorption are presented. The interconnection between high level of absorption and volume electrical resistance was observed: maximum absorption of 6.5±1,0 dB/mm corresponds to the electrical resistance of (4—5)∙105 Ohm∙m. Level of absorption of 3.5±0,5 dB/mm is revealed for the dielectric material with electrical conductivity of 1012 Ohm∙m. The patterns detected during the study allow to predict the minimum and maximum levels of absorption of microwave energy in the two-phase composites based on aluminum nitride with molybdenum or silicon carbide, based on the measured volume of electrical resistance. Keywords: volume attenuators, absorption factor of electromagnetic energy, composite, volume electrical resistance, aluminum nitride. REFERENCES 1. Pavlova M. A., Rybkin V. N., Nemogai I. K. [Microwave energy absorbers and their compounds with metals]. Elektronnaya tekhnika. Ser. 1. SVCh-tekhnika, 2009, iss. 4, pp. 42-47. (in Russian) 2. ÒСО.027.029 ÒУ. [Technical specifications for CT-30 material] 3. Bukharin E. N., Vlasov A. S., Alekseev A. A. [New highly voluminous microwave absorbers]. Elektronnaya tekhnika. Ser. Materialy, 1988, iss. 6, pp. 66-70. (in Russian) 4. Pozdnyakov L. V., Selikhova T. Yu. [Energy absorbers in vacuum microwave devices. Chapter II. Methods for calculating and measuring] Obzory po elektronnoi tekhnike. Ser. 1. Elektronika SVCh, 1978. iss. 3, 72 p. (in Russian) 5. Chasnyk V.I. [The impact of structural hierarchy of particles of conducting phase in the volume absorber material on the absorption process of microwave energy]. Elektronika i svyaz', 2011, no 1, pp. 43-47. (in Russian) 6. Chasnyk V.I., Fesenko I.P. [Thermal conductivity of vacuum volume attenuators of microwave energy]. Tekhnika i pribory SVCh, 2011, no 2, pp. 47-51. (in Russian) 7. Chasnyk V.I. High absorption of the microwave energy in a system with strongly elongated molybdenum grains in aluminum nitride matrix at frequences of 9,5—10,5 GHz. J. Super. Mat., 2012, vol. 34, no 1, pp. 71-73. 8. Chasnyk V. I., Fesenko I. P. [Microwave energy attenuators of high thermal conductivity based on AlN and SiC with addition of molybdenum]. Tekhnologiya i konstruirovanie v elektronnoi apparature, 2014, no 1, pp. 11-14. (in Russian) DOI: 10.15222/TKEA2014.4.08 UDC 621.315:615.5 ÍÎÂÛÅ ÊÍÈÃÈ Í Î Â Û Å Ê Í È Ã È Гилмор-мл. À. Ñ. Лампы с бегущей волной.— Ìîñêâà: Òåõíîñôåðà, 2013. Кíèãà îñíîâàíà íà мàòåðèàëàõ ëåêцèé è ñåмèíàðîâ ïî СВЧ- ëàмïàм, êîòîðыå àâòîð мíîãîêðàòíî ïðåдñòàâëÿë â âåдóщèõ фèðмàõ è óíèâåðñèòåòàõ США. В íåé ñîñðåдîòîчåíы бàзî- âыå зíàíèÿ ïî òåîðèè è òåõíèêå íàèбîëåå âîñòðåбîâàííîãî â òåчåíèå мíîãèõ, â òîм чèñëå è ïîñëåдíèõ дåñÿòèëåòèé, ïðè- бора — лампы с бегущей волной (ЛБВ). Книга написана до- ñòóïíым дëÿ шèðîêîãî êðóãà чèòàòåëåé è îбðàзíым ÿзыêîм, мåòîдèчåñêè ñбàëàíñèðîâàíà. Шèðîêî èñïîëьзóåмыå цèòàòы èз ðàбîò èзâåñòíыõ ñïåцèàëèñòîâ è îбшèðíàÿ бèбëèîãðàфèÿ ñïîñîбñòâóюò бîëåå ãëóбîêîмó âîñïðèÿòèю èзëàãàåмîãî мàòå- ðèàëà. Кíèãà мîжåò быòь ïîëåзíà êàê дëÿ ïîдãîòîâêè ñòóдåí- òîâ ñòàðшèõ êóðñîâ è àñïèðàíòîâ âóзîâ, òàê è ñïåцèàëèñòîâ, зàíÿòыõ ðàзðàбîò- êîé è ïðèмåíåíèåм ЛБВ â ðàзëèчíыõ îбëàñòÿõ ðàдèîýëåêòðîíèêè. Òåõíîëîãèÿ è êîíñòðóèðîâàíèå â ýëåêòðîííîé àïïàðàòóðå, 2014, ¹ 4 20 ÑÈÑÒÅÌÛ ÏÅÐÅÄÀЧÈ È ÎÁÐÀÁÎÒÊÈ ÑÈÃÍÀËÎÂ ISSN 2225-5818 REFERENCES 1. Feder E. [Fraktals] Moscow, Mir, 1991, 261 p. (in Russian) 2. Bolotov V. N., Kolesnikov S. E., Tkach Yu.V., Tkach Ya.Yu., Khupchenko P. V. Fractal Communication System. Electromagnetic Phenomena. 2007, vol. 7, no 1 (18), pp. 174-179. 3. Novikova O. B. Fraktal`nii splain-model` shirokos- mugovogo signalu [Fraktal spline-model of wideband signal] Visnik Natsional`nogo universitetu «L`vivs`ka politekhnika». Radioelektronika ta telekomunikatsiyi. 2012, no 738, pp. 28-33. (in Russian) 4. Lazorenko O. V., Potapov A. A., Chernogor L. F. Fraktal`nye sverkhshirokopolosnye signaly [Fractal UWB signals]. In book: Strukov A. V., Potapov A. A., Chernogor L. F. et al. Informatsionnaya bezopasnost`: metody shifrovaniya [Informative safety: methods of encoding]. Book 7. Moscow, Radio engineering, 2011, pp. 151-187. (in Russian) 5. Politans`kii R. L., Klimash M. M. Metod klasternogo koduvannya [Cluster coding method]. Vostochno-Evropeiskii zhurnal peredovykh tekhnologii. 2012, vol. 5, no 3(39), pp. 50-53. (in Russian) 6. Bolotov V. N., Tkach Yu. V. Vydelenie fraktal`nykh signalov v usloviyakh slozhnoi elektromagnitnoi obstanovki [Extracting of fractal signals in conditions of complex elec- tromagnetic conditions] Elektromagnitnye yavleniya. 2003, vol. 3, no 2(10), pp. 211-227. (in Russian) 7. Veriga A. D., Politans`kii R. L. Generator fraktal`nikh signaliv tipu «pryamokutneyi impul`s» na mikrokontroleri [Generator of the fractal signals of „rectangular pulse” type on microcontroller]. Proceed. of the IV international scientific- practical conference «Processing of signals and non-gaussian processes». Ukraine, Cherkasy. 2013, pp. 132-134. (in Russian) 8. Veriga A. D., Politans`kii R. L. Dekoder fraktal`nikh signaliv grebinkovoyi strukturi [Decoder of fraktal signals of comb strukture]. Proceed. of the IIІ international scienrific- practical conference «Physical and technological problems of radio engineering devices, telecommunication, nano- and micro- electronics». Ukraine, Chernivtsi. 2013, pp. 84-85. (in Russian) 9. ww1.microchip.com/downloads/en/devicedoc/ 30292c.pdf 10. http://www.geyer-electronic.com/uploads/ tx_userartikelfrequenz/GEYER-KXO-210_02.pdf 11. www.ti.com/lit/ds/symlink/max232.pdf 12. www.fairchildsemi.com/ds/LM/LM7805.pdf 13. Ugryumov Ye. P. Tsifrovaya shemotekhnika [Digital circuitry]. St. Petersburg. BKhV-Peterburg, 2004. 14. www.analog.com/static/imported-files/data_ sheets/AD810.pdf. 15. www.analog.com/static/imported-files/data_ sheets/AD9051.pdf. 16. www.analog.com/static/imported-files/data_ sheets/AD820.pdf 17. www.analog.com/static/imported-files/data_ sheets/AD8041.pdf. are then transmitted to the computer. The developed algorithm of the program for the microcontroller of the decoder is carried out by determination of order of fractal impulse after the value of sum of amplitudes of elementary impulses, constituents fractal signal. The programs for coder and decoder are written in “C”. In the most critical places of the program influencing on the fast-acting of chart “assembler” insertions are done. The blocks of the coder and decoder were connected with a coaxial 10 meters long cable with an impendance of 75 Ohm. The signals generated by the developed coder of FSCS, were studied using a digital oscillograph. On the basis of the obtained spectrums, it is possible to draw a conclusion, that the fractal signals formed by the coder are wideband and can be used in noise-resistant and protected communication systems. Keywords: fractal, microcontroller, transmitter, coder, receiver, decoder. ÍÎÂÛÅ ÊÍÈÃÈ Í Î Â Û Å Ê Í È Ã È Ñправочник по радиолокации. Â двух кн. / Ïод ред. Ì.È. Ñкол- ника.— Ìосква: Òехносфера, 2014. Эòî òðåòьå èздàíèå «Сïðàâîчíèêà ïî ðàдèîëîêàцèè». Рà- дèîëîêàцèîííàÿ òåõíèêà êàê дëÿ ãðàждàíñêîãî ïðèмåíå- íèÿ, òàê è дëÿ âîåííыõ цåëåé ïðîдîëжàåò ðàзâèâàòьñÿ â íàïðàâëåíèÿõ ðàñшèðåíèÿ îбëàñòè ïðèмåíåíèÿ è ñîâåð- шåíñòâîâàíèè òåõíîëîãèè. Нåêîòîðыå òåмы, îòðàжåííыå â ïðåдыдóщèõ èздàíèÿõ ñïðàâîчíèêà, êîòîðыå ïðåдñòàâ- ëÿюò ñåéчàñ мåíьшèé èíòåðåñ, быëè èñêëючåíы èз òåêó- щåãî èздàíèÿ. Òåõíîëîãèÿ è êîíñòðóèðîâàíèå â ýëåêòðîííîé àïïàðàòóðå, 2014, ¹ 4 32 ÁÈÎÌÅÄÈÖÈÍÑÊÀЯ ÝËÅÊÒÐÎÍÈÊÀ ISSN 2225-5818 provide an electronic medical thermometer power supply, particularly in the unmatched load mode with the converter efficiency dropping down five to tenfold. The work confirms the possibility of a thermoelectric converter of human body application for an electronic medical thermometer power supply. Keywords: thermoelectric converters, thermoelectric source of electricity, electronic medical thermometer. REFERENCES 1. Anatychuk L.I. Termoelementy i termoelektricheskie ustroistva [Thermoelements and thermoelectric devices]. Kiev, Naukova Dumka, 1979, 766 p. 2. Anatychuk L.I. Termoelektrichestvo. T. 2. Termoelektri- cheskie preobrazovateli energii [Thermoelectricity. Vol. 2. Thermoelectric power converters]. Kyiv, Chernivtsi, Institute of Thermoelectricity, 2003, 376 p. 3. Strutynskaya L.T. [Thermoelectric microgenerators. Current status and prospects of employment]. Tekhnologiya i konstruirovanie v elektronnoi apparature, 2008, no 4, pp. 5-13. (in Russian) 4. Pat. 6222114 USA. Portable Wrist Device. Mitamura Gen, 2001. 5. Snyder G.J. Small thermoelectric generators. The Electrochemical Society Interface. Fall, 2008, pp. 54-56. 6. Rowe D.M. Low powered thermoelectric generators and devices. Proc. of the 12th International Conference on Thermoelectrics, Japan, Yokohama, 1993, pp. 429-438. 7. Watkins C., Shen B., Venkatasubramanian R. Low- grade-heat energy harvesting using superlattice thermoelectrics for applications in implantable medical devices and sensors. Proc. of the 24th International Conference on Thermoelectrics, USA, Clemson, 2005, pp. 250-252. 8. Leonov V., Torfs T., Hoof C.V., Vullers R.J.M. Smart wireless sensors integrated in clothing: an electrocardiography system in a shirt powered using human body heat. Sensors & Transducers Journal, 2009, vol. 107, no 8, pp. 165-176. 9. Pat. 87400 UA. [Electronic medical thermometer with thermoelectric power supply]. L.І. Аnatychuk, R.R. Kobylyanskyi, S.B. Romanyuk, 2014. 10. Pat. 89035 UA. [Electronic medical thermometer with thermoelectric power supply]. L.І. Аnatychuk, 2014. 11. Pat. u201315453 UA. [Electronic medical thermom- eter with thermoelectric power supply] L.І. Аnatychuk, R.R. Kobylyanskyi, O.M. Manyk, 2013. 12. Аnatychuk L.І., Kobylyanskyi R.R. On the ac- curacy of temperature measurement by electronic medical thermometer with thermoelectric power supply. Journal of Thermoelectricity, 2013, no 5, pp. 68-72. ÍÎÂÛÅ ÊÍÈÃÈ Í Î Â Û Å Ê Í È Ã È Áогуш Ì. В. Проектирование пьезоэлектрических датчиков на основе пространственных электротермоупругих моделей.— Ìосква: Òехно сфера, 2013. Êíèãà ïîñâÿщåíà ïðîåêòèðîâàíèю ïьåзîýëåêòðèчåñêèõ дàòчèêîâ ñ èñïîëьзîâàíèåм ñîâðåмåííыõ мåòîдîâ мàòåмà- òèчåñêîãî мîдåëèðîâàíèÿ. Оïèñàíы êðèòåðèè, àëãîðèò- мы è ïðîцåдóðы дëÿ ðàцèîíàëьíîãî è цåëåíàïðàâëåííî- ãî âыбîðà êîíñòðóêцèè дàòчèêà, мàòåðèàëîâ è ðàзмåðîâ дåòàëåé ñ ïîмîщью óíèâåðñàëьíыõ îòíîñèòåëьíî ãåîмå- òðèè èздåëèÿ è ñïîñîбîâ ïðèëîжåíèÿ íàãðóзêè чèñëåí- íыõ ïðîñòðàíñòâåííыõ ýëåêòðîòåðмîóïðóãèõ мîдåëåé. Эòî ïîзâîëÿåò óëóчшèòь òåõíèчåñêèå õàðàêòåðèñòèêè ïьåзîýëåêòðèчåñêèõ дàòчèêîâ зà ñчåò îбîñíîâàííîãî âы- бîðà êîмïðîмèññà мåждó èíфîðмàòèâíîñòью è íàдåжíî- ñòью èздåëèÿ â ïðåдïîëàãàåмыõ óñëîâèÿõ ýêñïëóàòàцèè. Эффåêòèâíîñòь ïðåдëîжåííыõ мåòîдîâ ïîдòâåðждàåòñÿ ðàзðàбîòêîé ñåðèè ïьåзîýëåêòðèчåñêèõ дàòчèêîâ ñ óíè- êàëьíымè ñâîéñòâàмè, íàшåдшèõ шèðîêîå ïðèмåíåíèå â âèõðåâыõ è óëьòðàзâóêîâыõ ðàñõîдîмåðàõ жèдêîñòè, ãàзà è ïàðà дëÿ ñèñòåм ïðîмышëåííîé àâòîмàòèêè, íàшåдшèõ шèðîêîå ïðèмåíåíèå â ïðîмышëåííîñòè. Пðåдíàзíàчåíà дëÿ ñïåцèàëèñòîâ, зàíèмàющèõñÿ ïðîåêòèðîâàíèåм è ïðèмåíåíè- åм ïьåзîýëåêòðèчåñêèõ ïðåîбðàзîâàòåëåé è дàòчèêîâ â èзмåðèòåëьíыõ è óïðàâëÿ- ющèõ ñèñòåмàõ, à òàêжå àñïèðàíòîâ è ñòóдåíòîâ òåõíèчåñêèõ âóзîâ.
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institution	Digital Library of Periodicals of National Academy of Sciences of Ukraine
issn	2225-5818
language	Russian
last_indexed	2025-12-07T15:47:44Z
publishDate	2014
publisher	Інститут фізики напівпровідників імені В.Є. Лашкарьова НАН України
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spelling	2014-11-08T13:44:21Z 2014-11-08T13:44:21Z 2014 Новые книги // Технология и конструирование в электронной аппаратуре. — 2014. — № 4. — С. 12, 20, 32. — рос. 2225-5818 https://nasplib.isofts.kiev.ua/handle/123456789/70576 ru Інститут фізики напівпровідників імені В.Є. Лашкарьова НАН України Технология и конструирование в электронной аппаратуре Новые книги Article published earlier
spellingShingle	Новые книги
title	Новые книги
title_full	Новые книги
title_fullStr	Новые книги
title_full_unstemmed	Новые книги
title_short	Новые книги
title_sort	новые книги
url	https://nasplib.isofts.kiev.ua/handle/123456789/70576

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