Your search keyword '"O. M. Patoka"' showing total 15 results

1. AERONOMIC RADIO SPECTROMETRY WITH CALIBRATION BY SIGNALS FROM VIRTUAL SOURCES

Author

A. M. Korolev, Yu. V. Karelin, O. V. Antyufeyev, V. M. Shulga, V. V. Myshenko, D. L. Chechotkin, D. V. Shulga, O. M. Patoka, and K. V. Marynko

Subjects

aeronomy, ozone, calibration, millimeter wavelengths, Astronomy, QB1-991

Abstract

Subject and Purpose. The work has been aimed at developing and implementing a novel method of aeronomic observations in the Earth's stratosphere, applicable in the microwave range of the electromagnetic spectrum. The research is centered on a study of the measurement errors arising when the method proposed is employed for observations of the ozone spectral line (142 GHz). Methods and Methodology. The method is based on a simplified calibration procedure, in what concerns the hardware and the technology employed. In contrast to the common calibration techniques using special-purpose sources of the reference signal, we suggest resorting to natural sources, like internal noise of the receiver and the thermal radiation from the Earth's surface and the lower atmospheric layer. The measurement errors (both calculated and evaluated experimentally) have been analyzed within standard mathematical statistics techniques. Results. The tests performed during observations of the spectral line (142 GHz) of atmospheric ozone allow considering the new method as a success. The estimated magnitude of the relative error specific to the observation method proposed does not exceed 1.5%. The experimental estimate accounting for all potential error sources does not exceed 5% (with a 1 hour accumulation period), which result corresponds to the current state of the art. Conclusions. The possibility of an essential simplification of the radio optical part of the spectrometer has been demonstrated. The novel calibration technique, as well as the technical implementation thereof, can be recommended as a basis for prospective spectrometers at microwave frequencies.

Published

2022

2. CREATING THE RT-32 RADIO TELESCOPE ON THE BASIC OF MARK-4B ANTENNA SYSTEM. 2. ESTIMATION OF THE POSSIBILITY FOR MAKING SPECTRAL OBSERVATIONS OF RADIO ASTRONOMICAL OBJECTS

Author

A. V. Antyufeyev, A. M. Korolev, O. M. Patoka, V. M. Shulga, O. M. Ulyanov, O. M. Reznichenko, V. V. Zakharenko, V. I. Prisiazhnii, A. V. Poichalo, V. V. Voityuk, V. N. Mamarev, V. V. Ozhinskii, V. P. Vlasenko, V. M. Chmil, V. I. Lebed, M. I. Palamar, A. V. Chaikovskii, Yu. V. Pasternak, M. A. Strembitskii, M. P. Natarov, S. O. Steshenko, V. V. Glamazdyn, A. S. Shubny, A. A. Kirilenko, D. Y. Kulik, and A. M. Pylypenko

Subjects

antenna, calibration, masers, mark-4b, receiving system, polarization, radio source, radio telescope, spectrum analyzer, Astronomy, QB1-991

Abstract

Purpose: Technical capabilities of the MARK-4B antenna system necessary for its further using as a 32-meter radiotelescope (RT-32) and making simultaneous spectral radioastronomical observations in the C and K frequency ranges, are investigated. Design/methodology/approach:The studies use the results of our own measurements made with the МАRK-4В antenna system, expert reviews, open information sources, technical documentation of the MARK-4B antenna system, radio astronomy and computer simulation methods and comparative analysis of this antenna main parameters with the corresponding parameters of the world’s best active radio telescopes. Combining different approaches allows us to determine the requirements for the receiving system, parameters of the spectrometer, calibration techniques and optimize the МАRK-4В antenna system modernization procedure. Findings: The radio telescope main parameters required for spectral observations in the C and K frequency ranges are determined. The antenna pointing system capabilities are specified. For the MARK-4B antenna system working frequency range, the main spectral lines of various molecules available for research have been considered. The transitions radiating the most intensive spectral lines are listed. The radio astronomical problems that can be solved using the MARK-4B in the mode of spectral observations are formulated. The required parameters of the spectrum analyzer and the receiver’s self-noise temperature are determined. Calibration techniques of the recorded signal are described, which are necessary for carrying out spectral observations. Conclusions: The here presented studies show that for making spectral observations based on the beam-waveguide MARK-4B antenna system, it is technically possible to create the RT-32 radio telescope with quality technical characteristics corresponding to the world-best analogs. Modernization of the beamwaveguide MARK-4B antenna system will allow at the first stage to create in Ukraine the dual-band radio-telescope permitting to make simultaneous spectral and/or continued observations in the C and K ranges. Henceforth, the amount of simultaneously working ranges can be increased.

Published

2019

3. CREATING THE RT-32 RADIO TELESCOPE ON THE BASIC OF MARK-4B ANTENNA SYSTEM. 1. MODERNIZATION PROJECT AND FIRST RESULTS

Author

O. M. Ulyanov, O. M. Reznichenko, V. V. Zakharenko, A. V. Antyufeyev, A. M. Korolev, O. M. Patoka, V. I. Prisiazhnii, A. V. Poichalo, V. V. Voityuk, V. N. Mamarev, V. V. Ozhinskii, V. P. Vlasenko, V. M. Chmil, V. I. Lebed, M. I. Palamar, A. V. Chaikovskii, Yu. V. Pasternak, M. A. Strembitskii, M. P. Natarov, S. O. Steshenko, V. V. Glamazdyn, A. S. Shubny, A. A. Kirilenko, D. Y. Kulik, A. A. Konovalenko, L. M. Lytvynenko, and Ya. S. Yatskiv

Subjects

antenna, feed, interferometry, polarization, radio astronomy, radio source, radio telescope, server, frequency standard, Astronomy, QB1-991

Abstract

Purpose: Creating a radio telescope based on the MARK-4B antenna system being developed for telecommunication applications, determining the possibilities of using the broadband multirange operation of a beam wave-guided antenna system and to evaluate the antenna characteristics using the radioastronomical measurements. Design/methodology/approach: Acomprehensive analysis of all the MARK-4B systems allows to select the blocks and nodes to be replaced or upgraded. The analysis of the reflector and subreflector design, beam wave-guide, corrugated horn, and feeder system allows determining the possible frequency ranges of the radio telescope being created. Installing a broadband receiver with the stipulated calibration capabilities using cooled and uncooled load attenuators allows to determine the antenna system temperature. Guiding the antenna to the calibration sources and recording scans due to the Earth rotation eliminates the systematic errors or errors of the pointing system. In this way the width of the radiation pattern and the effective area of the radio telescope are determined. Findings: An analysis of the antenna design was made and the priority stages of the reconstruction of the MARK-4B antenna system were determined. The narrow-band transmitter and the C-band receiver were dismantled and a wide-band receiver (range 4.6 - 5.1 GHz) with a detector and the possibility of changing the signal integration time were installed. The observed results have allowed to initially estimate the system temperature mea-surements which allow us to hope that the RT-32 radio telescope (Zolotchiv, Lviv region, Ukraine) together with the cooled receiver will have low self noise. A new antenna pointing system has been calculated and installed which using in the C-band has allowed astronomical tests of the radiation pattern width (≈7.2') and the level of its side lobes (–12.5 dB), effective area (≈680 m2) and surface utilization factor (≈0.84). Conclusions: The completed measurements and calculations show that the MARK-4B antenna system allows to createhighly efficient radio astronomy instrument. The developed for now receiving and pointing systems for the RT-32 radio telescope testify to the high potential of Ukrainian science. Further cooperation between scientific research and high technologies will lead to the creation of an effective Ukrainian radio telescope of the centimeter wavelength range.

Published

2019

4. LOCAL OSCILLATORS FOR MM-WAVELENGTH AERONOMIC RECEIVERS

Author

V. V. Myshenko, V. M. Shulga, A. M. Korolev, Yu. V. Karelin, D. L. Chechotkin, O. V. Antyufeyev, and O. M. Patoka

Subjects

millimeter waves, local oscillator, economy, stability, phase locked loop, Astronomy, QB1-991

Abstract

Purpose: A description of the original technical solutions of the solid-state highly stable local oscillators of the millimeter range and the results of the study of the main characteristics of the developed devices are given. The goal of the work is the development of small-sized stabilized generators with low power consumption for the use in the composition of superheterodyne receivers of the 2 mm and 3 mm ranges for aeronomic research. Design/methodology/approach: The created local oscillators are based on multiple multiplication of the reference signal with a phase locked loop. The output generator on the Gunn diode works without a varactor, with the frequency tuning by changing the voltage on the diode. To measure the spectral characteristics, a test signal of a separate highly stable heterodyne of an astronomical receiver was used. The spectrum of the investigated local oscillator was recorded by a parallel Fourier spectrum analyzer with the frequency resolution of 1 kHz per channel. Methods for the study of other basic characteristics were standard methods of radio measurements. Findings: Compact sources of the heterodyne signal of the mm-wavelength range with low power consumption (less than 20 W) were designed and tested. The output power of the local oscillators is at least 50 mW. The measured relative frequency instability is better than 10-8 when working with a thermostatted quartz reference source. The time resource of continuous work exceeds 2 years. Conclusions: Relative instability of frequency (10-8 ) and launch power (more than 50 mW) of the presented generators correspond to the characteristics of industrial mm-wavelength precision generators, the here developed generators (devices) being more economical, compact and cheaper. A number of proposed circuit and design solutions can be used by designers of similar equipment in the mm-wavelength range.

Published

2019

5. REGIONS OF EXISTENCE OF THE CLASS II METHANOL MASERS. STATISTICAL FEATURES OF EMISSION IN CS (J = 2 - 1) LINE

Author

O. M. Patoka, V. M. Shulga, O. V. Antyufeyev, S. Y. Zubrin, V. V. Myshenko, A. M. Korolev, and V. I. Piddyachiy

Subjects

methanol masers, cs, dense cores, star formation, Astronomy, QB1-991

Abstract

Purpose: The statistical features of emission in CS (J = 2 - 1) line, Class II methanol masers and IR sources in the regions associated with the Class II methanol masers are studied. Design/methodology/approach: The survey is performed at the CS (J = 2 - 1) line transition frequency, since this molecule is a solid gas tracer in which the conditions for the existence of methanol masers should arise. Findings: For the sources with which the Class II methanol masers are associated the dependences logLSC - logLbol , logLmeth - logLSC, and logLmeth - logLbol have been found. It is shown that on the average, the emission in the CS (J = 2 - 1) line toward Class II methanol masers is more often detected in those sources which are associated with the higher bolometric luminosity IR sources. Conclusions: The survey of the emission in the CS (J = 2 - 1) line toward Class II methanol masers for the northern celestial hemisphere was carried out. The statistical features of the emission in the CS (J = 2 - 1) line, Class II methanol masers and IR sources are shown.

Published

2017

6. OBSERVATIONS OF NON TYPICAL MASERS AT THE RT-22 RADIO TELESCOPE IN 2004–2013

Author

V. M. Shulga, O. V. Antyufeyev, S. Y. Zubrin, V. V. Myshenko, V. I. Piddyachiy, A. M. Korolev, and O. M. Patoka

Subjects

maser radiation, supernova remnants, molecular clouds, methanol, sio, Astronomy, QB1-991

Abstract

Purpose: Some peculiarities of emission of Class I methanol masers on the 80–71A+ transition at 95 GHz in sources closely associated with protostar-forming regions and in supernova remnants are studied. Here belongs the investigation of SiO (J=2–1) maser variability in R Cassiopeiaе, too. Design/methodology/approach: Search for Class I methanol masers is based on the idea of coincidence of regions of their emission with sources of OH masing transition in the bottom level of energy at frequency of 1720 MHz (2Π3/2 J=3/2 F=2–1). Findings: Two methanol masers on transition 80–71A+ (95 GHz) in the supernova remnants IC 443 and Kes 79 are detected. Variabilities of SiO maser emission on transition J=2–1 in R Cassiopeiaе are shown for the first time. Conclusions: Variability of methanol and SiO masers is their general feature. On the example of three objects, the possibility of using the 1720 MHz OH maser as an indicator in the search for Class I methanol masers is shown. Especially it is important in the study of methanol maser emission in supernova remnants that has been proved to be true by detection of methanol masers on transition 80–71A+ (95 GHz) in IC 443 and Kes 79. Features of spectra variability of emission in R Cassiopeiaе testify to formation and disappearance of SiO (J=2–1) masers.

Published

2017

7. CREATING THE RT-32 RADIO TELESCOPE ON THE BASIC OF MARK-4B ANTENNA SYSTEM. 2. ESTIMATION OF THE POSSIBILITY FOR MAKING SPECTRAL OBSERVATIONS OF RADIO ASTRONOMICAL OBJECTS

Author

Yu. V. Pasternak, V. V. Ozhinskii, A. M. Korolev, V. V. Glamazdyn, V. M. Shulga, V. N. Mamarev, A. V. Chaikovskii, M. A. Strembitskii, A. M. Pylypenko, A. V. Antyufeyev, V. V. Voityuk, A. V. Poichalo, S. O. Steshenko, O. M. Ulyanov, V. P. Vlasenko, V. I. Prisiazhnii, V. I. Lebed, D. Kulik, O. M. Reznichenko, Mykhaylo Palamar, O. M. Patoka, A. S. Shubny, V. V. Zakharenko, A. A. Kirilenko, V. M. Chmil, and M. P. Natarov

Subjects

Astronomical Objects, Spectrum analyzer, Physics and Astronomy (miscellaneous), spectrum analyzer, lcsh:Astronomy, law.invention, antenna, Radio telescope, lcsh:QB1-991, Optics, mark-4b, law, masers, Electrical and Electronic Engineering, Maser, Physics, polarization, business.industry, receiving system, Astrophysics::Instrumentation and Methods for Astrophysics, Astronomy and Astrophysics, Polarization (waves), calibration, Space and Planetary Science, radio telescope, radio source, business

Abstract

Purpose: Technical capabilities of the MARK-4B antenna system necessary for its further using as a 32-meter radiotelescope (RT-32) and making simultaneous spectral radioastronomical observations in the C and K frequency ranges, are investigated. Design/methodology/approach:The studies use the results of our own measurements made with the МАRK-4В antenna system, expert reviews, open information sources, technical documentation of the MARK-4B antenna system, radio astronomy and computer simulation methods and comparative analysis of this antenna main parameters with the corresponding parameters of the world’s best active radio telescopes. Combining different approaches allows us to determine the requirements for the receiving system, parameters of the spectrometer, calibration techniques and optimize the МАRK-4В antenna system modernization procedure. Findings: The radio telescope main parameters required for spectral observations in the C and K frequency ranges are determined. The antenna pointing system capabilities are specified. For the MARK-4B antenna system working frequency range, the main spectral lines of various molecules available for research have been considered. The transitions radiating the most intensive spectral lines are listed. The radio astronomical problems that can be solved using the MARK-4B in the mode of spectral observations are formulated. The required parameters of the spectrum analyzer and the receiver’s self-noise temperature are determined. Calibration techniques of the recorded signal are described, which are necessary for carrying out spectral observations. Conclusions: The here presented studies show that for making spectral observations based on the beam-waveguide MARK-4B antenna system, it is technically possible to create the RT-32 radio telescope with quality technical characteristics corresponding to the world-best analogs. Modernization of the beamwaveguide MARK-4B antenna system will allow at the first stage to create in Ukraine the dual-band radio-telescope permitting to make simultaneous spectral and/or continued observations in the C and K ranges. Henceforth, the amount of simultaneously working ranges can be increased.

Published

2019

8. CREATING THE RT-32 RADIO TELESCOPE ON THE BASIC OF MARK-4B ANTENNA SYSTEM. 1. MODERNIZATION PROJECT AND FIRST RESULTS

Author

V. I. Prisiazhnii, A. S. Shubny, O. M. Reznichenko, A. M. Korolev, V. V. Glamazdyn, V. V. Ozhinskii, Ya. S. Yatskiv, Yu. V. Pasternak, Alexandr A. Konovalenko, V. M. Chmil, M. P. Natarov, Leonid M. Lytvynenko, Mykhaylo Palamar, D. Kulik, V. V. Zakharenko, O. M. Ulyanov, M. A. Strembitskii, V. N. Mamarev, A. V. Chaikovskii, A. A. Kirilenko, A. V. Antyufeyev, O. M. Patoka, V. V. Voityuk, A. V. Poichalo, S. O. Steshenko, V. P. Vlasenko, and V. I. Lebed

Subjects

010504 meteorology & atmospheric sciences, Physics and Astronomy (miscellaneous), lcsh:Astronomy, Vinogradov, radio astronomy, 01 natural sciences, antenna, lcsh:QB1-991, Radio telescope, server, 0103 physical sciences, Shevchenko, Electrical and Electronic Engineering, 010303 astronomy & astrophysics, 0105 earth and related environmental sciences, Physics, polarization, feed, Astrophysics::Instrumentation and Methods for Astrophysics, Astronomy and Astrophysics, interferometry, radio telescope, Space and Planetary Science, frequency standard, radio source, Humanities

Abstract

УДК 520.272.2:621.396.677.494 PACS number: 95.55.-Jz Предмет и цель работы: Создание радиотелескопа на основе антенной системы МАRК-4В, которая была разработана для телекоммуникационных приложений, определение возможностей использования лучеводной антенной системы в широкополосном многодиапазонном режиме работы и оценка характеристик антенны с помощью радиоастрономических измерений. Методы и методология: Комплексный анализ всех систем МАRК-4В дает возможность выделить блоки и узлы, которые подлежат замене или модернизации. Анализ конструкции рефлектора и субрефлектора, лучевода, гофрированного рупора и волноводной системы позволяет определить возможные частотные диапазоны работы создаваемого радиотелескопа. Установка широкополосного приемника с предусмотренной возможностью калибровки по охлаждаемой и неохлаждаемой нагрузке позволяет определить температуру антенной системы. Наведение антенны на калибровочные источники и запись сканов за счет вращения Земли исключает систематические ошибки или погрешности системы наведения. Таким образом определяется ширина диаграммы направленности и эффективная площадь радиотелескопа. Результаты: Произведен анализ конструкции антенны и определены первоочередные этапы реконструкции антенной системы МАRК-4В. Демонтированы узкополосные передатчик и приемник диапазона С и установлен широкополосный приемник (диапазон 4.6÷5.1 ГГц ) с детектором и возможностью изменения времени интегрирования сигнала. По результатам наблюдений сделаны первоначальные оценки температуры шумов системы, которые позволяют надеяться на то, что радиотелескоп РТ-32 (г. Золочев, Львовская обл., Украина) совместно с охлаждаемым приемником будет обладать низкими собственными шумами. Рассчитана и установлена новая система наведения антенны, с помощью которой в С диапазоне проведены астрономические тесты ширины диаграммы направленности ( ≈ 7.2 ′ ) и уровня ее боковых лепестков (–12.5 дБ), эффективной площади ( ≈ 680 м 2 ) и коэффициента использования поверхности ( ≈ 0.84 ). Заключение: Выполненные измерения и расчеты показывают, что на базе антенной системы МАRК-4В возможно создать высокоэффективный радиоастрономический инструмент. Разработанные на данный момент системы приема и наведения для радиотелескопа РТ-32 свидетельствуют о высоком потенциале украинской науки. Дальнейшая кооперация научных исследований и высоких технологий приведет к созданию эффективного украинского радиотелескопа сантиметрового диапазона. Ключевые слова: антенна, излучатель, интерферометрия, поляризация, радиоастрономия, радиоисточник, радиотелескоп, сервер, стандарт частоты Статья поступила в редакцию 11.03.2019 Radio phys. radio astron. 2019, 24(2): 87-116 СПИСОК ЛИТЕРАТУРЫ 1. Woodburn L., Natusch T., Weston S., Thomasson P., Godwin M., Granet C., and Gulyaev S. Conversion of a New Zealand 30-metre telecommunications antenna into a radio telescope. Publ. Astron. Soc. Aust. 2015. Vol. 32. id. e017. DOI: 10.1017/pasa.2015.13 2. Petrov L., Natusch T., Weston S., McCallum J., Ellingsen S., and Gulyaev S. First scientific VLBI observations using New Zealand 30 meter radio telescope WARK30M. Publ. Astron. Soc. Pac. 2015. Vol. 127, No. 952. P. 516–522. DOI: 10.1086/681965 3. Yonekura Y., Saito Y., Sugiyama K., Soon K. L., Momose M., Yokosawa M., Ogawa H., Kimura K., Abe Y., Nishimura A., Hasegawa Y., Fujisawa K., Ohyama T., Kono Y., Miyamoto Y., Sawada-Satoh S., Kobayashi H., Kawaguchi N., Honma M., Shibata K. M., Sato K., Ueno Y., Jike T., Tamura Y., Hirota T., Miyazaki A., Niinuma K., Sorai K., Takaba H., Hachisuka K., Kondo T., Sekido M., Murata Y., Nakai N., and Omodaka T. The Hitachi and Takahagi 32 m radio telescopes: Upgrade of the antennas from satellite communication to radio astronomy. Publ. Astron. Soc. Jpn. 2016. Vol. 68, Is. 5. id. 74. DOI: 10.1093/pasj/psw045 4. Venter M. and Bolli P. Electromagnetic analysis and preliminary commissioning results of the shaped dual-reflector 32-m Ghana radio telescope. IOP Conf. Ser. Mater. Sci. Eng. 2018. Vol. 321, Is. 1. id. 12003. DOI: 10.1088/1757-899X/321/1/012003 5. Imbriale W. A. Evolution of the Deep Space Network 34-m diameter antennas. IEEE Aerospace Conference Proceedings. (March 21–28, 1998. Snowmass). Snowmass, CO, USA, 1998. Vol. 3. P. 403–430 DOI: 10.1109/AERO.1998.685847 6. Imbriale W. A. Large Antennas of theDeep Space Network. Hoboken, NJ, USA: John Wiley & Sons, Inc., 2003. 320 p. 7. Mizusawa M. and Kitsuregawa T. A Beam-waveguide Feed Having a Symmetric Beam for Cassegrain Antennas. IEEE Trans. Antennas Propag. 1973. Vol. 21, Is. 6. P. 884–886. DOI: 10.1109/TAP.1973.1140628 8. Korolev A. M., Zakharenko V. V., and Ulyanov O. M. Radio astronomy ultra-low-noise amplifier for operation at 91 cm wavelength in high RFI environment. Exp. Astron. 2016. Vol. 41, Is. 1-2. P. 215–221. DOi: 10.1007/s10686-015-9466-x 9. Konovalenko A., Sodin L., Zakharenko V., Zarka P., Ulyanov O., Sidorchuk M., Stepkin S., Tokarsky P., Melnik V., Kalinichenko N., Stanislavsky A., Koliadin V., Shepelev V., Dorovskyy V., Ryabov V., Koval A., Bubnov I., Yerin S., Gridin A., Kulishenko V., Reznichenko A., Bortsov V., Lisachenko V., Reznik A., Kvasov G., Mukha D., Litvinenko G., Khristenko A., Shevchenko V. V., Shevchen-ko V. A., Belov A., Rudavin E., Vasylieva I., Miroshnichenko A., Vasilenko N., Olyak M., Mylostna K., Skoryk A., Shevtsova A., Plakhov M., Kravtsov I., Volvach Y., Lytvinenko O., Shevchuk N., Zhouk I., Bovkun V., Antonov A., Vavriv D., Vinogradov V., Kozhin R., Kravtsov A., Bulakh E., Kuzin A., Vasilyev A., Brazhenko A., Vashchishin R., Pylaev O., Koshovyy V., Lozinsky A., Ivantyshin O., Rucker H. O., Panchenko M., Fischer G., Lecacheux A., Denis L., Coffre A., Griesmeier J.-M., Tagger M., Girard J., Charrier D., Briand C., and Mann G. The modern radio astronomy network in Ukraine: UTR-2, URAN and GURT. Exp. Astron. 2016. Vol. 42, Is. 1. P. 11–48. DOI: 10.1007/s10686-016-9498-x 10. Zakharenko V., Konovalenko A., Zarka P., Ulyanov O., Sidorchuk M., Stepkin S., Koliadin V., Kalinichenko N., Stanislavsky A., Dorovskyy V., Shepelev V., Bubnov I., Yerin S., Melnik V., Koval A., Shevchuk N., Vasylieva I., Mylostna K., Shevtsova A., Skoryk A., Kravtsov I., Volvach Y., Plakhov M., Vasilenko N., Vasylkivskyi Y., Vavriv D., Vinogradov V., Kozhin R., Kravtsov A., Bulakh E., Kuzin A., Vasilyev A., Ryabov V., Reznichenko A., Bortsov V., Lisachenko V., Kvasov G., Mukha D., Litvinenko G., Brazhenko A., Vashchishin R., Pylaev O., Koshovyy V., Lozinsky A., Ivantyshyn O., Rucker H. O., Panchenko M., Fischer G., Lecacheux A., Denis L., Coffre A., and Gries-meier J.-M. Digital Receivers for Low-Frequency Radio Telescopes UTR-2, URAN, GURT. J. Astron. Instrum. 2016. Vol. 5, Is. 4. id. 1641010. DOI: 10.1142/S2251171716410105

Published

2019

9. LOCAL OSCILLATORS FOR MM-WAVELENGTH AERONOMIC RECEIVERS

Author

Yu. V. Karelin, V. V. Myshenko, D. L. Chechotkin, Oleksandr Antyufeyev, O. M. Patoka, V. M. Shulga, and A. M. Korolev

Subjects

Physics, 010504 meteorology & atmospheric sciences, Physics and Astronomy (miscellaneous), lcsh:Astronomy, local oscillator, Analytical chemistry, phase locked loop, Astronomy and Astrophysics, stability, millimeter waves, Microwave oscillators, 01 natural sciences, Low noise, lcsh:QB1-991, Wavelength, economy, Space and Planetary Science, 0103 physical sciences, Electrical and Electronic Engineering, Microwave radiometry, 010303 astronomy & astrophysics, Atmospheric ozone, 0105 earth and related environmental sciences

Abstract

УДК 537.962:621.382.32 PACS numbers: 95.85.Bh, 97.10.Bt, 98.38.Ez Предмет и цель работы: Приводятся описание оригинальных технических решений твердотельных высокостабильных гетеродинов миллиметрового диапазона и результаты исследования основных характеристик разработанных устройств. Цель работы – разработка малогабаритных стабилизированных генераторов с малой потребляемой мощностью для использования в составе супергетеродинных приемников 2-мм и 3-мм диапазонов для аэрономических исследований. Методы и методология: Созданные гетеродины основаны на многократном умножении опорного сигнала с фазовой автоподстройкой частоты. Выходной генератор на диоде Ганна работает без варактора, с перестройкой по частоте путем изменения напряжения на диоде. Для измерения спектральных характеристик использовался тестовый сигнал отдельного высокостабильного гетеродина астрономического приемника. Регистрация спектра сигнала исследуемого гетеродина осуществлялась параллельным фурье-анализатором спектра с частотным разрешением 1 кГц/канал. Методы исследования прочих базовых характеристик – стандартные методы радиоизмерений. Результаты: Разработаны и протестированы компактные источники гетеродинного сигнала миллиметрового диапазона длин волн с низкой потребляемой мощностью (менее 20 Вт). Выходная мощность генераторов – не менее 50 мВт. Измеренная относительная нестабильность частоты лучше 10 -8 при работе с термостатированным кварцевым опорным источником. Временной ресурс непрерывной работы превышает 2 года. Заключение: Относительная нестабильность частоты ( 10 -8 ) и выходная мощность (более 50 мВт) представленных генераторов соответствуют характеристикам промышленных прецизионных генераторов миллиметрового диапазона, при этом разработанные устройства экономичнее, компактнее и дешевле. Ряд предложенных схемных и конструктивных решений может использоваться проектировщиками аналогичной техники в миллиметровом диапазоне длин волн. Ключевые слова: миллиметровые волны, гетеродин, экономичность, стабильность, фазовая автоподстройка частоты Статья поступила в редакцию 11.04.2019 Radio phys. radio astron. 2019, 24(2): 144-153 СПИСОК ЛИТЕРАТУРЫ 1. Hoffmann C. G., Raffalski U., Palm M., Funke B., Golchert S. H. W., Hochschild G., and Notholt J. Observation of strato-mesospheric CO above Kiruna with ground-based microwave radiometry – retrieval and satellite comparison. Atmos. Meas. Tech. 2011. Vol. 4, Is. 11. P. 389–2408. DOI: 10.5194/amt-4-2389-2011 2. Straub C., Espy P. J., Hibbins R. E., and Newnham D. A. Mesospheric CO above Troll station, Antarctica observed by a ground based microwave radiometer. Earth Syst. Sci. Data. 2013. Vol. 5, Is. 1. P. 199–208. DOI: 10.5194/essd-5-199-2013 3. Hagen J., Murk A., Rufenacht R., Khaykin S., Hauchecorne A., and Kampfer N. WIRA- C: a compact 142-GHz- radiometer for continuous middle-atmospheric wind measurements. Atmos. Meas. Tech. 2018. Vol. 11, Is 9. P. 5007–5024. DOI: 10.5194/amt-11-5007-2018. 4. Rufenacht R., Kampfer N., and Murk A. First middle-atmospheric zonal wind profile measurements with a new ground-based microwave Doppler-spectro-radiometer. Atmos. Meas. Tech. 2012. Vol. 5, Is. 11. P. 2647–2659. DOI: 10.5194/amt-5-2647-2012 5. Антюфеев А. В., Шульга В. А. Спектроанализатор на базе персонального компьютера. Радиотехника. 2005. No 5. С. 145–148. 6. Karelin Yu. V., Antyufeyev O. V., Myshenko V. V., and Shulga V. M. An FPGA-based fourier FFTS-160 spectrometer for atmospheric molecular radiation research. Telecomm. Radio Eng. 2017. Vol. 76, Is. 4. P. 305–313. DOI: 10.1615/TelecomRadEng.v76.i4.30 7. Forkman P., Piddyachiy V., Korolev A., Myshenko V., Myshenko A., and Shulga V. An uncooled very low noise Schottky diode receiver front-end for middle atmospheric ozone and carbon monoxide measurements. Int. J. Infrared Millimeter Waves. 2006. Vol. 27, Is. 1. P. 25–35. DOI: 10.1007/s10762-006-9061-3 8. Piddyachiy V. I., Shulga V. M., Myshenko V. V., Korolev A. M., Myshenko A. V., Antyufeyev A. V., Poladich A. V., and Shkodin V. I. 3-mm wave spectroradiometer for studies of atmospheric trace gases. Radiophys. Quantum El. 2010. Vol. 53, Is. 5-6. P. 326–333. DOI: 10.1007/s11141-010-9231-y 9. Piddyachiy V., Shulga V., Myshenko V., Korolev A., Antyfeyev O., Shulga D., and Forkman P. Microwave radiometer for spectral observations of mesospheric carbon monoxide at 115 GHz over Kharkiv, Ukraine. J. Infrared Millim. Terahertz Waves. 2017. Vol. 38, Is. 3. P. 292–302. DOI: 10.1007/s10762-016-0334-1 10. Подъячий В. И., Короев А. М., Мышенко В. В., Шульга В. М. Приемный модуль 2-мм диапазона для наблюдений линии излучения атмосферного озона на частоте142.2 ГГц Радіофізика і радіоастрономія. 2015. Т. 20, No 3. С. 261–268. DOI: 10.15407/rpra20.03.261 11. Подъячий В. И. Утроитель частоты на диодах с барьером Шоттки в приемнике 3-мм диапазона для исследований линий излучения атмосферных газов. Радіофізика і радіоастрономія. 2015. Т. 20, No 1. С. 86–93. DOI: 10.15407/rpra20.01.086 12. Алексеев Е. А., Захаренко В. В. Синтезатор прямого цифрового синтеза в микроволновой спектроскопии. Радіофізика і радіоастрономія. 2007. Т. 12, No 2. С. 205–213. 13. Алексеев Е. А., Илюшин В. В., Мещеряков А. А. Высокоточный радиоспектрометр с субдоплеровским спектральным разрешением. Радіофізика і радіоастрономія. 2014. Т. 19, No4. С. 364–374. DOI: 10.15407/rpra19.04.364 14. Королев А. М. Усилитель промежуточной частоты супергетеродинного радиоастрономического приемника. Приборы и техника эксперимента. 2011. No 1. С. 88–90. 15. Королев А. М., Шульга В. М. Ненасыщенный режим как альтернативный метод обеспечения устойчивости малошумящих усилителей на полевых транзисторных гетероструктурах. Радіофізика і радіоастрономія. 2011. Т. 16, No 4. С. 433–439. 16. Antyufeyev A. V., Myshenko A. V., and Myshenko V. V. Microwave oscillator’s spectral observation with a radio astronomy receiver. Proceedings of the 23-th International Crimean conference “Microwave and Telecommunication Technology” (CriMiCo’2013). (Sept. 8-14, 2013. Sevastopol, Ukraine). Sevastopol, Ukraine: IEEE, 2013. P. 949–950.

Published

2019

10. New ex-OH maser detections in the northern celestial hemisphere

Author

O. M. Patoka, A. Aberfelds, Valerii Shulga, A. Orbidans, Vl. Bezrukovs, I. Shmeld, Oleksandr Antyufeyev, and M. Bleiders

Subjects

Physics, Southern Celestial Hemisphere, Northern Hemisphere, FOS: Physical sciences, Astronomy and Astrophysics, Astrophysics, Astrophysics - Astrophysics of Galaxies, law.invention, Radio telescope, Space and Planetary Science, law, Excited state, Astrophysics of Galaxies (astro-ph.GA), Astrophysics::Solar and Stellar Astrophysics, Maser, Circular polarization, Astrophysics::Galaxy Astrophysics, Radio astronomy, Northern Celestial Hemisphere

Abstract

Aims.Molecular masers, including methanol and hydroxyl masers, and in particular the ones in excited rotational states (ex-OHmasers), are one of the most informative tools for studying star-forming regions. So, the discovery, of new maser sources in theseregions is of great importance. Many studies and surveys of ex-OH maser sources have been carried out in the southern celestialhemisphere, but only a few have been done in the northern hemisphere. The specific aim of this work is to close this gap.Methods.The star-forming regions in the northern hemisphere with known active methanol masers were observed to search for newex-OH maser sources with the 32 m and 16 m radio telescopes of the Ventspils International Radio Astronomy Centre (VIRAC).Results.Three OH maser lines in the excited state at the 6035 MHz in three northern hemisphere star-forming regions are detected.The maser 189.030+0.783 was previously known, but we suggest this maser is a possible variable. We confirm recent detections ofthe ex-OH masers 85.41+0.00 and 90.92+1.49 by other authors. The magnetic field strength in the masering regions is estimated byusing right circular polarization (RCP) and left circular polarization (LCP) pair splitting. The high-velocity resolution provides uswith an estimation of a comparatively small magnetic field strength for the 189.030+0.783 and 90.92+1.49 star-forming regions, 6 pages 1 figure 4 tables

Published

2021

11. Spectral Line Registration Backend Based on USRP X300 Software Defined Radio

Author

A. Orbidans, J. Steinbergs, Vladislavs Bezrukovs, Oleksandr Antyufeyev, M. Bleiders, I. Shmeld, A. Aberfelds, and O. M. Patoka

Subjects

Spectrometer, Universal Software Radio Peripheral, business.industry, Computer science, 020206 networking & telecommunications, Astronomy and Astrophysics, 02 engineering and technology, Software-defined radio, 01 natural sciences, Spectral line, Software, 0103 physical sciences, 0202 electrical engineering, electronic engineering, information engineering, business, 010303 astronomy & astrophysics, Instrumentation, Computer hardware, Daughterboard

Abstract

This paper presents implementation of spectrometer based on off-the-shelf software defined radio (SDR) Ettus Research USRP X300 equipped with TwinRX daughterboard. Parallelized software, employing Fast Fourier Transform (FFT), is developed which allows two channel spectrum processing in real time with bandwidths up to 50[Formula: see text]MHz per channel, sample resolution of 14 bits and FFT lengths up to 32k points. Measured Allan stability time of the spectrometer is at least 750 sin laboratory environment. Software has network server-type interface that allows to conveniently integrate the spectrometer in radio telescope observation control and monitoring system with versatility of SDR allowing to implement various observation modes, for example, total power detection functionality with high frequency selectivity, which allows to carry continuum amplitude calibration in presence of near-by radio frequency interference. Presented spectrometer has been successfully integrated and used at RT-32 and RT-16 radio telescopes of Ventspils International Radio Astronomy Centre.

Published

2020

12. The survey of the regions with methanol masers in CS (J = 2–1) line emission. Statistical characteristics of the radiations

Author

O. Antyufeyev, V. I. Piddyachiy, O. M. Patoka, V. V. Myshenko, A. M. Korolev, and Valerii Shulga

Subjects

Physics, chemistry.chemical_compound, chemistry, law, Methanol, Astrophysics, Maser, law.invention, Line (formation)

Published

2018

13. Survey of Regions with Methanol Masers in the CS (J = 2–1) Line: Statistical Characteristics of Radiation

Author

O. M. Patoka, A. M. Korolev, Oleksandr Antyufeyev, V. I. Piddyachiy, V. M. Shulga, and V. V. Myshenko

Subjects

Physics, 010308 nuclear & particles physics, Infrared, Star formation, media_common.quotation_subject, Astronomy and Astrophysics, Astrophysics::Cosmology and Extragalactic Astrophysics, Astrophysics, 01 natural sciences, Spectral line, Luminosity, law.invention, Radio telescope, Space and Planetary Science, law, Sky, 0103 physical sciences, Astrophysics::Solar and Stellar Astrophysics, Maser, 010303 astronomy & astrophysics, Astrophysics::Galaxy Astrophysics, Line (formation), media_common

Abstract

The paper aims at establishing relations between the parameters of methanol maser emission that originates in dense star-forming regions and parameters of a dense core using emission of the CS molecule. A total of 164 sources toward the positions of methanol masers using the RT-22 radio telescope at CrAO, Ukraine, have been observed. For 85 sources, the CS (J = 2–1) line emission was detected. Most of the sources have been selected from catalogs of the class I and class II methanol masers. For methanol masers, this is the most complete survey in the CS (J = 2–1) line on the northern sky. A comparative analysis of parameters of methanol masers spectra in the CS (J = 2–1) line, and methanol masers, luminosities of dense cores, and infrared sources, has been performed. The detection rates of the CS (J = 2–1) line emission, its intensities and widths, the differences between the systematic velocities and velocities of the maser line centers have been investigated. The radiation detection rates in the CS (J = 2–1) line are shown to differ for various source samplings. The form of the dependences lgLcs – lgLbol, lgLmas – lgLcs and lgLmas – lgLbol has been found for sources with which methanol masers are associated. Based on the luminosity of infrared sources, samples of sources in which the CS (J = 2–1) line emission is detected with a higher probability have been determined.

Published

2018

14. OBSERVATIONS OF NON TYPICAL MASERS AT THE RT-22 RADIO TELESCOPE IN 2004–2013

Author

O. M. Patoka, Oleksandr Antyufeyev, V. M. Shulga, A. M. Korolev, V. V. Myshenko, S. Y. Zubrin, and V. I. Piddyachiy

Subjects

Physics, supernova remnants, 010504 meteorology & atmospheric sciences, Physics and Astronomy (miscellaneous), lcsh:Astronomy, Astrophysics::High Energy Astrophysical Phenomena, Astronomy, Astronomy and Astrophysics, molecular clouds, 01 natural sciences, law.invention, Radio telescope, lcsh:QB1-991, Space and Planetary Science, law, sio, 0103 physical sciences, maser radiation, Astrophysics::Solar and Stellar Astrophysics, Electrical and Electronic Engineering, Maser, 010303 astronomy & astrophysics, Astrophysics::Galaxy Astrophysics, 0105 earth and related environmental sciences, methanol

Abstract

Purpose: Some peculiarities of emission of Class I methanol masers on the 80–71A+ transition at 95 GHz in sources closely associated with protostar-forming regions and in supernova remnants are studied. Here belongs the investigation of SiO (J=2–1) maser variability in R Cassiopeiaе, too. Design/methodology/approach: Search for Class I methanol masers is based on the idea of coincidence of regions of their emission with sources of OH masing transition in the bottom level of energy at frequency of 1720 MHz (2Π3/2 J=3/2 F=2–1). Findings: Two methanol masers on transition 80–71A+ (95 GHz) in the supernova remnants IC 443 and Kes 79 are detected. Variabilities of SiO maser emission on transition J=2–1 in R Cassiopeiaе are shown for the first time. Conclusions: Variability of methanol and SiO masers is their general feature. On the example of three objects, the possibility of using the 1720 MHz OH maser as an indicator in the search for Class I methanol masers is shown. Especially it is important in the study of methanol maser emission in supernova remnants that has been proved to be true by detection of methanol masers on transition 80–71A+ (95 GHz) in IC 443 and Kes 79. Features of spectra variability of emission in R Cassiopeiaе testify to formation and disappearance of SiO (J=2–1) masers.

Published

2017

15. Estimation of errors at the calibration of spectral data at the irbene RT-32 radio telescope

Author

A. Aberfelds, I. Shmeld, Valerii Shulga, A. Orbidans, M. Bleiders, O. M. Patoka, Oleksandr Antyufeyev, Vladislavs Bezrukovs, and J. Steinbergs

Subjects

Radio telescope, Physics, Calibration (statistics), Astronomy and Astrophysics, Spectral data, Instrumentation, Remote sensing

Abstract

We analyze calibration errors that occur during the single-dish observations at the Irbene RT-32 radio telescope when calibration is done using noise diode. Only frequency switched mode of spectral line observations is considered. The purpose of the article is to find possible values of noise diode temperature Tcal and period of switching oscillator frequency 2tq. For this, we have analyzed the formula for calculating the antenna temperature of the source. It is shown that noise diode temperature affects the standard deviation of source antenna temperature σTs and the error of source antenna temperature δTs caused by instability of system temperature. tq affects the stability of the characteristics of the receiving system. In this article, the dependencies between Tcal, tq, σTs and δTs were found and analyzed. Based on these dependencies, possible values of Tcal and tq are found.