The Multipactor Test results on the X Band filter of Space Qualification Model appropriated for the Geostationary Satellite

DC Field Value Language
dc.contributor.advisor김영길-
dc.contributor.author박종희-
dc.date.accessioned2019-10-21T07:30:29Z-
dc.date.available2019-10-21T07:30:29Z-
dc.date.issued2017-08-
dc.identifier.other25426-
dc.identifier.urihttps://dspace.ajou.ac.kr/handle/2018.oak/19066-
dc.description학위논문(석사)--아주대학교 IT융합대학원 :IT융합공학과,2017. 8-
dc.description.tableofcontentsCHAPTER 1. INTRODUCTION 1 CHAPTER 2. X BAND OUTPUT FILTER 2 2.1. X Band Output Filter Overview 2 2.2. Engineering Model of X Band Output Filter 8 2.3. Qualification Model of X Band Output Filter 11 2.4. Tests Procedures 13 2.4.1. Ambient Conditions 13 2.4.2. Tolerance of Test Conditions 14 2.4.3. Calibration of Instruments 16 CHAPTER 3. QUALIFICATION TEST 17 3.1. Qualification Test Flow 17 3.2. Electrical Performance Test 18 3.3. Vibration Test 21 3.4. Shock Test 23 3.5. Thermal Vacuum Test 25 3.6. EMC Test 29 CHAPTER 4. MULTIPACTOR ANALYSIS 30 4.1. Multipactor Effect 30 4.2. Secondary Electron Emission 30 4.3. Multipactor Testing 33 4.4. Multipactor Analysis using ECSS Tool 37 4.4.1. Engineering Model of X Band Output Filter 38 4.4.2. Qualification Model of X Band Output Filter 43 4.5. Multipactor Analysis using VMF method 45 CHAPTER 5. MULTIPACTOR TEST 49 5.1. Multipactor Test Preparation 49 5.1.1. Cleanroom Conditions 49 5.1.2. Device Under Test 49 5.1.3. RF Breakdown Test bed 50 5.1.4. General Test Equipment 51 5.1.5. RF Breakdown Detection Systems 52 5.1.6. Test Parameters 52 5.2. Multipactor Test Procedure 53 5.2.1. Electron seeding 53 5.2.2. Measurements 53 5.2.3. Multipactor through evaluation test procedure 53 5.2.4. RF Breakdown reference sample test procedure 54 5.3. Multipactor Test Set-Up 55 5.3.1. Integration of DUT inside thermal vacuum chamber 55 5.3.2. Electron seeding – Center section of BPF 55 5.3.3. Electron seeding – Joint section of BPF & LPF 56 5.3.4. Electron seeding – Center section of LPF 57 5.3.5. Local methods of RF Breakdown detection system 57 5.4. Bake-out Test at 85℃ 60 5.5. Multipactor Test 62 5.5.1. Multipactor test 62 5.5.2. Second Multipactor test 66 5.6. Multipactor Test Results 70 5.6.1. Test results by Measurements 70 CHAPTER 6. CONCLUSIONS 72 BIBLIOGRAPHY 73 국문 초록 77-
dc.language.isoeng-
dc.publisherThe Graduate School, Ajou University-
dc.rights아주대학교 논문은 저작권에 의해 보호받습니다.-
dc.titleThe Multipactor Test results on the X Band filter of Space Qualification Model appropriated for the Geostationary Satellite-
dc.title.alternativeThe Multipactor Test results on the X Band filter of Space Qualification Model appropriated for the Geostationary Satellite-
dc.typeThesis-
dc.contributor.affiliation아주대학교 IT융합대학원-
dc.contributor.alternativeNameJong-hee Park-
dc.contributor.departmentIT융합대학원 IT융합공학과-
dc.date.awarded2017. 8-
dc.description.degreeMaster-
dc.identifier.localId788536-
dc.identifier.urlhttp://dcoll.ajou.ac.kr:9080/dcollection/jsp/common/DcLoOrgPer.jsp?sItemId=000000025426-
dc.subject.keywordMultipactor test-
dc.subject.keywordSpace Qualification-
dc.subject.keywordGeostationary Satellite-
dc.description.alternativeAbstractIn this thesis, regarding as the X Band Output Filter applied to geostationary satellite, qualification tests including multipactor analysis should be performed in the stage of design. The analysis is performed using the ECSS multipactor tool and the VMF method etc. Based on some papers, the ECSS multipactor tool is underestimated the breakdown threshold than the VMF method. In case of multipactor analysis for X Band Output Filter EM with the center frequency 8,212.5 MHz, channel band width 100 MHz, 2 mm Gap and 100 W input is shown the margin of 6.2 dB. In this reason, the multipactor test is required. But according to the changes of requirement for the X Band Output Filter QM, the changes are as follows, the center frequency 8,200 MHz(2B)/8,300 MHz(2A), channel band width 62.2 MHz and 120 W input power handling capability and 2.5 mm Gap. By reflecting these requirements and extended Gap, the analysis by using ECSS multipactor tool is shown the margin more than 8 dB. The multipactor test is not required. However, using VMF method, since multipactor margin is less than 8 dB, this multipactor test should be performed according to the ECSS Standard. To do multipactor test, multipactor test parameter of input power is decided by the choice of more than 4 dB higher value based on the peak input power (120 W) of X Band Output Filter. The 4 dB higher value is 300 W, considering the relaxation of the test, 540 W input power is selected in this multipactor test. The locations of the electron seeding by strontium radioactive beta sources are decided by the results of thermal, thermo-elastic analysis and random vibration analysis. The critical areas for electron seeding are the center section of BPF & LPF respectively and the joint section between BPF and LPF. In multipactor test, the RF Breakdown detections systems are using both global methods with third harmonic monitoring, nulling detection system and local methods with electron avalanche detection and optical detection system. Through from 100 W input to 540 W input, the multipactor test for X Band Output Filter is performed successfully and there is no abnormal behavior on the filter. This means that the X Band Output Filter is well designed for the space qualification model. The multipactor test is reaffirmed and verified for the multipactor-free X Band Output Filter. In case of having sufficient multipactor margin over 8 dB using thorough multipactor analysis, additional multipactor test is not required according to the recommendation of ECSS Standard.-
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Special Graduate Schools > Graduate School of IT Convergence > Department of IT Convergence Engineering > 3. Theses(Master)
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