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Journal Radioengineering №10 for 2015 г.
Article in number:
Design of broadband high power amplifier modules over the range of 2-4 GHz with an output power of 50 W
Keywords: amplifier microwave frequency range bipolar transistor amplitude-frequency characteristic voltage standing wave ratio (VSWR) S­parameters power gain
Authors:
M.P. Apin - Ph. D. (Econ.), First Deputy General Director - Main Engineer, JSC «SPE «Almaz» (Saratov) L.S. Sotov - Dr. Sc. (Eng.), Professor, Saratov State University named after N.G. Chernyshevsky A.L. Khvalin - Dr. Sc. (Eng.), Associate Professor, Saratov State University named after N.G. Chernyshevsky
Abstract:
The problem of obtaining large values of microwave power in a wide frequency band is relevant for a number of radio systems. Power amplifiers of radio systems determine the most important tactical and technical parameters of the systems, such as radiated and consumed power, operating frequency range, size and weight, reliability and cost. The article presents the results of numerical investigation of the parameters of high-power broadband amplifiers according to the scheme of multichannel power summation of serially produced domestic broadband transistors over the range of 2-4 GHz. The characteristic features of designing the amplifier modules with an output power of 50 W in continuous operation mode are discussed. Power transmission coefficient of the amplifier is more than 24 dB. The complexity of building amplifiers in a single package is caused by a large number of channels to be summated, by thermal problems and difficulties in tuning. One of the ways to solve this problem is to use identical amplifiers with further summation of their output powers with the use of summing circuits with low losses. This article presents an experience of the authors on the creation of high-power broadband amplifiers operating in continuous mode over the range of 2-4 GHz on a domestic element base. This work is resulted in creation of the design of high-power broadband amplifiers and its main units such as dividers / combiners for 2, 4, 8, 16 channels of microstrip implementation, and the basic two-stage amplifier module. The computer project of high-power broadband amplifier is presented, and its optimum performances are obtained over the frequency range from 2 to 4 GHz.
Pages: 87-92
References

 

  1. KHvalin A.L., Sotov L.S. Ispolzovanie MICROWAVE OFFICE 2007 dlja modelirovanija nelinejjnykh analogovykh usilitelejj // Geteromagnitnaja mikroehlektronika. 2008. № 5. S. 112−121.
  2. Khvalin A.L. A multiple parameter problem of modeling of characteristics of the feld transistor in a super wide range of frequencies // Geteromagnitnajamikroehlektronika. 2010. № 8. S. 16− 24.
  3. Sotov L.S., KHvalin A.L. Sredstva razrabotki i issledovanija arkhitekturnykh modelejj v SAPR System Studio. CHast 1. Ispolzovanie instrumentov System Studio pri modelirovanii matrichnogo generatora perestanovok // Geteromagnitnaja mikroehlektronika. 2008. № 5. S. 121− 145.
  4. KHvalin A.L., Ignatev A.A., Ljashenko A.V., Vasilev A.V., Samoldanov V.N. EHlektrodinamicheskoe modelirovanie SVCH-usilitelejj s geteromagnitnym upravleniem // Geteromagnitnaja mikroehlektronika. 2004. № 1. Mnogofunkcionalnye kompleksirovannye ustrojjstva i sistemy SVCH- i KVCH-diapazonov. S. 99−105.
  5. Samoldanov V.N., Ignatev A.A., Ljashenko A.V., Solopov A.A., KHvalin A.L., Marinin A.V., Kovalenko M.L. Kompjuternoe modelirovanie ferritovykh rezonatorov vo vnutrennikh cepjakh bipoljarnogo tranzistora v usilitelnom rezhime raboty // Geteromagnitnaja mikroehlektronika. 2004. № 1. Mnogofunkcionalnye kompleksirovannye ustrojjstva i sistemy SVCH- i KVCH-diapazonov. S. 110−118.
  6. KHvalin A.L. Fizicheskie principy modelirovanija polevykh tranzistorov v UVCH-diapazone // Geteromagnitnaja mikroehlektronika. 2008. № 4. Geteromagnitnaja mikro- i nanoehlektronika. Prikladnye aspekty. Ustrojjstva razlichnogo naznachenija. S. 59−67.
  7. Kac B.M., Meshhanov V.P., Feldshtejjn A.L. Optimalnyjj sintez ustrojjstv SVCH s T­volnami / Pod red. V.P. Meshhanova. M.: Radio i svjaz. 1984. 288 s.
  8. Meshhanov V.P., Tupikin V.D., CHernyshev S.L. Koaksialnye passivnye ustrojjstva / Pod red. V.P. Meshhanova. Saratov: Saratovskijj gosudarstvennyjj un-t. 1993. 447 s.
  9. Sverkhshirokopolosnye mikrovolnovye ustrojjstva / Pod red. A.P. Krenickogo, V.P. Meshhanova. M.: Radio i svjaz. 2001. 560 s.
  10. Sintez sverkhshirokopolosnykh mikrovolnovykh struktur / Pod red. V.P. Meshhanova, A.P. Krenickogo. M.: Radio i svjaz. 2005. 411 s.
  11. Kac B.M., Meshhanov V.P. Maksimalno ploskaja approksimacija v zadachakh sinteza ustrojjstv SVCH // Radiotekhnika i ehlektronika. 1978. T. 23. № 4. S. 690−698.
  12. KHvalin A.L., Vasilev A.V. Optimalnyjj sintez kharakteristik tranzistornogo usilitelja UVCH-diapazona v integralnom ispolnenii // Pribory i sistemy. Upravlenie, kontrol, diagnostika. 2010. № 10. S. 29−33.
  13. Meshhanov V.P., KHvalin A.L. Metodika utochnenija kharakteristik modeli Materka polevogo tranzistora // Radiotekhnika. 2010. № 5. S. 111−115.
  14. KHvalin A.L. Vektornyjj magnitometr slabykh magnitnykh polejj // Izmeritelnaja tekhnika. 2014. № 10. S. 45−48.
  15. KHvalin A.L. Fizicheskie principy modelirovanija polevykh tranzistorov v UVCH-diapazone // Geteromagnitnaja mikroehlektronika. 2008. № 4. S. 59−67.
  16. KHvalin A.L., Samoldanov V.N. Razrabotka bipoljarnykh magnitoehlektronnykh tranzistorov v usilitelnom rezhime dlja reguljarnykh signalov na vysokom urovne moshhnosti v UVCH-diapazone // Geteromagnitnaja mikroehlektronika. 2005. № 2. S. 63−73.