Schlagwortverzeichnis Muster Uli.Qxd

Total Page:16

File Type:pdf, Size:1020Kb

Schlagwortverzeichnis Muster Uli.Qxd Index Schlagwortverzeichnis Aktivantenne..................476–477, 480, 954, 982 Aktive Antenne .......................471–472, 480, 954 Abgleich.........................................................171, Alford-Loop ...........................................723, 728 177, 205, 274, 322, 324–325, 376, 436, 460, Allband ..........................................................285, 482, 492, 498–503, 511–512, 515, 523, 536, 288, 292–295, 298, 310, 318–320, 323–324, 538, 540, 543–544, 547, 552–554, 562, 613, 331–332, 355, 387, 401, 441, 455, 641–642, 615, 618, 625, 629, 646, 652, 655–656, 670, 649–650, 660–661, 666, 927, 943, 981, 1448 728, 736, 739, 781, 784, 786, 789, 806–807, AM ...................................................................49, 835, 869, 871, 916, 950, 987, 1003, 1014, 1027, 56–58, 60, 63–64, 69–71, 75, 77–81, 83–85, 87, 1030, 1037, 1040, 1058–1059, 1254, 1298, 106, 109, 111, 130, 134, 140, 149–154, 156– 1304–1305, 1310, 1374, 1448 161, 164–165, 167–171, 173, 177, 183, 185– Ableitung.........................................................42, 188, 194–195, 201–203, 206–207, 211, 217, 631, 635, 651, 661, 772, 844, 939, 949, 954, 220–222, 227–232, 234, 236, 238–240, 242– 961, 1134–1135, 1137, 1140–1141, 1146, 246, 248–249, 256, 258–261, 267, 269, 271, 1156–1157 273–276, 278, 280, 282, 288, 290, 292–296, Abrahamscher Erreger...................95, 103, 599 301, 304–306, 308–311, 313, 316, 319, 323– Abschirmbox.................................................187, 324, 326, 329, 335–336, 340, 343–344, 346, 378, 1029, 1304, 1027, 1029, 1030, 1311 348–349, 351–352, 359–364, 366, 369, 371– Abschirmung.................................................144, 373, 377–378, 380, 382, 384, 387, 393–394, 186, 220, 316–317, 392, 609, 721, 835, 932, 399–402, 404–405, 409–410, 412, 414–417, 1010, 1027, 1029, 1041, 1051, 1059–1060, 1154, 421, 423, 428, 431, 435–436, 439–441, 443, 1188, 1303–1305 447, 450, 452, 455, 457–458, 462–464, 466– Abschlusswiderstand....................................115, 467, 471, 473–474, 477, 479, 482, 488–490, 153–154, 156, 164–165, 199, 344, 350–352, 493, 496–497, 500, 502, 504, 508–509, 513, 362, 364, 605–606, 700, 811–813, 951, 986, 515, 517, 519, 521, 523, 529–530, 535–538, 1027, 1031, 1057–1058, 1061, 1084, 1167, 1254 540–546, 548–551, 553–556, 562, 565, 567– Abschwächer......................................1049, 1245 568, 577–578, 580–581, 585–586, 588, 593, Absorber........................................................209, 595–597, 599, 601, 604–605, 607, 609, 611, 214–215, 222, 567, 892, 975, 1059–1061, 1315 614, 617–622, 624–628, 630, 632–633, 638, Absorptionsfrequenzmesser .............1014, 1019 641–644, 646, 648–660, 664, 670, 675–679, Abspannung ..................................................116, 684–685, 687, 692, 696–697, 700, 703–707, 252, 502–503, 511, 642, 659, 661, 672, 675, 711–712, 714, 717–721, 725, 728–730, 734– 698, 836, 925, 939, 943, 1099, 1116–1118, 1120 737, 747, 750–751, 757–758, 762–763, 771– Abstimmelement............................................160 773, 775, 777, 781–782, 784–787, 794–795, Abstimmung..................................................102, 799, 801, 804, 807, 812–813, 827–828, 832, 106, 118, 195, 204–205, 230–233, 239–240, 835–836, 840, 842–844, 846, 851, 853–855, 244–246, 259, 274, 281, 286, 294, 307, 315, 859, 861, 864, 869, 873, 875, 878, 883, 885, 327, 330, 358, 403, 423, 428, 431, 436, 461, 889–890, 892, 895–897, 901–902, 909–914, 501, 503–504, 517, 531, 533, 543–544, 552, 916, 918–921, 923–928, 930, 932, 934, 936, 554, 561, 591, 618, 646, 652, 661, 676, 678– 938–941, 945–948, 953–955, 961–963, 969– 679, 696, 712, 738, 810, 835, 863, 873, 914, 970, 972–974, 977, 981, 984, 986, 988–989, 919, 932, 953, 984, 989, 1010, 1012, 1025, 1063, 991, 993, 997–998, 1001, 1003, 1012, 1014– 1151, 1185, 1302, 1312, 1330, 1374 1015, 1017–1018, 1021, 1024, 1026, 1030, ACE–HF Pro ............................1357–1358, 1367 1032–1033, 1039–1045, 1049, 1052–1056, Achterstagantenne.........................................939 1073–1074, 1080, 1094, 1099–1100, 1107, Adcock-Antenne ......................1175–1176, 1189 1111–1112, 1116, 1118–1124, 1126, 1133, Admittanz.......................40–41, 580, 1036, 1070 1135, 1138–1139, 1149–1152, 1157–1159, AFuG ..................................................1319, 1340 1165–1167, 1171, 1176–1177, 1182, 1186, AFuV ..................................................1319, 1340 1188, 1192–1195, 1202–1204, 1208, 1214, A-Index.......................................83, 85–86, 1435 1217, 1225, 1227–1228, 1236–1237, 1239, 1451 1241, 1245–1252, 1255, 1257, 1261–1262, 1028–1030, 1039, 1041–1043, 1062 1266, 1268, 1270, 1272–1278, 1281–1282, Antennenabstimmgerät ...............................232, 1289, 1291, 1295, 1298–1300, 1302, 1308– 280, 284–285, 289–290, 340, 922 1309, 1311–1313, 1324, 1326, 1328–1329, Antennenaufbau ...........................................298, 1331–1333, 1336, 1344, 1347, 1359–1360, 314, 361, 635, 1122–1124, 1131 1363, 1367, 1374, 1385, 1395, 1400, 1427, Antennenbau.................................................453, 1434, 1438–1440, 1442–1444, 1446 614, 764, 981, 1063, 1089–1091, 1110, 1129– Amateurfunkgeräteversicherung...............1129 1131, 1262, 1371, 1377–1378, 1380 Amateurfunkgesetz (AFuG) .............1319, 1340 Antennenerdung.........................................1100, Amateurfunkpeilen .......................928–929, 943 1154–1155, 1158, 1162–1163 Amateurfunkprüfung........................1309, 1317 Antennenfaktor.....................................130–133, Amateurfunkverordnung (AFuV) ...1319, 1340 473–474, 605–606, 891, 1278–1280, 1282– Amplitudenmodulation................................945, 1284, 1290–1291, 1328–1330, 1437, 1224, 1017, 1064, 1071, 1191, 1295, 1395, 1400 1280, 1329 Amtsblattverfügungen ................................1319 Antennenfuß .................................................244, Analysatoren ................................................1035 586, 588, 618, 910, 921, 923, 938, 943, 970, Analyzer ........................................................145, 996, 1187 222, 277, 280, 304, 572, 718, 1035–1036, 1038, Antennengenehmigung .............275, 1126, 1131 1063, 1350, 1354, 1359, 1438 Antennengewinn...........................................109, Ankopplung...........................................228–232, 114, 135, 249, 568, 606, 677, 780, 838, 937, 256, 258, 286, 289, 307, 434, 437, 536, 552, 975, 993, 1045–1046, 1049, 1064, 1171, 1207, 683, 715, 803, 1016, 1030, 1038, 1041 1267–1268, 1271, 1282, 1321–1322, 1334, Anode..............................1015, 1095, 1135, 1141 1357, 1359, 1425, 1436 Anpassgerät...........................................178–179, Antennengrundstruktur .................................49 227, 232–233, 239, 243–224, 246, 228, 290, Antennenhöhe...............................................104, 296, 305, 310, 320, 337, 343, 345, 403–404, 312, 320, 346, 359, 526, 536, 581–582, 598– 450, 641, 679, 682, 987, 926–927, 938–939, 599, 636, 700, 832–833, 836, 983, 1100, 1177, 1186, 1188, 1360, 1441 1263, 1265, 1269, 1329, 1352 Anpassung.......................................................48, Antennenimpedanz.......................................101, 101–102, 106, 114–115, 153–154, 156–157, 131, 169, 244, 251, 309, 385, 473, 597, 677, 169–177, 180–183, 185–188, 190, 197, 201, 813, 1009, 1032, 1040, 1087, 1203, 1329 203–204, 207, 218–221, 224, 227, 231, 233, Antennenkenngrößen...................................101, 240, 243–244, 246, 248, 261, 278, 288, 290, 108, 111, 134, 262–263, 596, 1435, 1444 292, 294–295, 304, 310, 314, 320–321, 343, Antennenkoppler..................................196–197, 351, 357–358, 373, 375, 377, 382–383, 414– 232–233, 239–240, 244, 248, 340, 502, 695, 416, 430, 434–435, 443, 446, 448, 451–452, 1190–1191, 1441 460, 462, 489, 493, 496, 505, 509, 512, 514, Antennenlänge ................................................95, 521, 523, 532, 536–538, 540, 553, 562–563, 105, 116, 252, 258–259, 275, 280, 284–285, 565, 567–569, 572, 574, 585, 609–614, 618, 292, 302, 304–305, 307, 329, 335, 337, 342, 625–628, 630–631, 635, 638, 643–644, 646, 345–346, 348, 365–366, 369, 384, 422, 438– 648–649, 653, 655–656, 664, 669, 675, 677– 439, 474, 483, 582, 596–600, 602, 624, 646, 678, 690, 693, 700, 705, 712, 715–716, 725, 669, 675, 710, 757–759, 765–771, 774, 776, 732, 736–739, 741, 746, 749, 752, 770–771, 778, 780, 787, 793, 795, 797, 801, 803, 805– 773–774, 776, 778–779, 784, 786, 792, 800– 806, 809, 839, 841, 848–850, 867, 876, 895– 802, 807–808, 812, 816, 826, 828, 833, 838, 896, 903, 911–913, 948–949, 955–959, 961, 845, 867, 869, 873, 878, 901–902, 914, 922– 965, 968, 996, 1059, 1198, 1436 923, 938, 942–943, 948–949, 951, 987, 989, Antennenmast...............................................431, 991, 1001–1002, 1004, 1009, 1025, 1036, 1039, 551, 697–698, 763, 768, 787, 790, 806, 1092, 1042, 1048, 1053–1054, 1057, 1071, 1075, 1100, 1125, 1131, 1149, 1155–1156, 1158, 1268 1083–1084, 1129, 1145, 1151, 1187, 1198, Antennenmessbrücke ..............1031, 1062–1063 1208, 1219, 1224, 1230, 1262, 1266, 1278, Antennenprogramm.....................................335, 1282, 1295, 1308, 1369, 1439, 1441, 1445, 1448 410, 487, 579, 581, 675, 682, 697, 700, 764, Ansprechspannung...........................1137–1138, 840, 921, 957, 1338, 1347–1348, 1353–1355 1145, 1147, 1149–1151 Antennenrauschbrücke................................132, Ansprechzeit.......................................1137, 1152 280, 463, 1028, 1031–1032, 1040, 1063, 1074,
Recommended publications
  • ZS6BKW Vs G5RV Antenna
    ZZS6BS6BKWKW vsvs G5RG5RVV Antenna Patterns/SWR at 40 ft Center height, 27 ft end height ~148 Degree Included Angle Compiled By: Larry James LeBlanc 2010 For the AARA Ham Radio Club Note: All graphs computed using MMANA GAL http://mmhamsoft.amateur-radio.ca/mmana/index.htm ZSZS6BK6BKWW // G5RVG5RV WhaWhatt isis it?it? In the mid-1980s, Brian Austin (ZS6BKW) ran computer analysis to develop an antenna System that, for the maximum number of HF bands possible, would permit a low Standing Wave Ratio (SWR) without antenna tuner to interface with a 50-Ohm coaxial cable as the main feed line. He identified a range of lengths which, when combined with a matching ladder line length, would provide this characteristic. According to an acknowledged expert in computer antenna design and modeling, L. B. Cebik: “Of all the G5RV antenna system cousins, the ZS6BKW antenna system has come closest to achieving the goal that is part of the G5RV mythology: a multi-band HF antenna consisting of a single wire and simple matching system to cover as many of the amateur HF bands as possible.” Both are “good” antennas and will work well in defined situations. This presentation is not designed to “bash” the G5RV, but to possibly convince you or a new ham to enjoy the benefits of lower SWR, lower loss, and greater signal strength by using the ZS6BKW version of a ladder line fed dipole. ZZSS66BBKWKW // GG55RRVV WWhhyy II liklikee itit 1. Has low swr in several ham bands at the matching point at the end of the ladder line resulting in lower losses in the coax cable.
    [Show full text]
  • The G5rv Antenna
    SUCCESSFUL WIRE ANTENNAS Band (metres) 80 40 30 20 17 15 12 10 6 2 L1 end (2) 168 89.4 63.2 45 35.3 30 25.6 22.4 12.7 4.37 L2 centre (2) 65 34.7 24.6 17.5 13.7 11.7 9.97 8.72 4.95 1.70 L3 total size 467 248 176 125 98 83.3 71.2 62.3 35.4 12.2 L4 stubs 48.6 25.8 18.3 13 10.2 8.66 7.4 6.47 3.68 1.26 L5 height 120 64 45 32 25 21 18 16 10 10 Inductor (μH) 25.9 11.7 7.3 4.9 3.4 2.8 2.2 1.9 0.85 0.13 Gain (dBi) 11.4 11.4 11.3 11.2 11.1 11.0 11.0 11.0 11.4 10.9 Freq (MHz) 3.8 7.15 10.1 14.2 18.12 21.3 24.93 28.5 50.2 146 Table 4.3: Lengths (in feet) of an HGSW beam for 10 amateur bands. insulators as shown. The lower ends of the two lines should be stripped and bent over and soldered together. The resultant active line length must be 13ft. The dis- tance from the centre insulator to the ladder line should be 17.5ft. If you have a lot of wind in your area you might want to tie a 1oz lead fishing sinker to the bottom of each of the phasing lines. Alternately a string can be attached and tied to some secure point below the antenna.
    [Show full text]
  • High Frequency (HF)
    Calhoun: The NPS Institutional Archive Theses and Dissertations Thesis Collection 1990-06 High Frequency (HF) radio signal amplitude characteristics, HF receiver site performance criteria, and expanding the dynamic range of HF digital new energy receivers by strong signal elimination Lott, Gus K., Jr. Monterey, California: Naval Postgraduate School http://hdl.handle.net/10945/34806 NPS62-90-006 NAVAL POSTGRADUATE SCHOOL Monterey, ,California DISSERTATION HIGH FREQUENCY (HF) RADIO SIGNAL AMPLITUDE CHARACTERISTICS, HF RECEIVER SITE PERFORMANCE CRITERIA, and EXPANDING THE DYNAMIC RANGE OF HF DIGITAL NEW ENERGY RECEIVERS BY STRONG SIGNAL ELIMINATION by Gus K. lott, Jr. June 1990 Dissertation Supervisor: Stephen Jauregui !)1!tmlmtmOlt tlMm!rJ to tJ.s. eave"ilIE'il Jlcg6iielw olil, 10 piolecl ailicallecl",olog't dU'ie 18S8. Btl,s, refttteste fer litis dOCdiii6i,1 i'lust be ,ele"ed to Sapeihil6iiddiil, 80de «Me, "aial Postg;aduulG Sclleel, MOli'CIG" S,e, 98918 &988 SF 8o'iUiid'ids" PM::; 'zt6lI44,Spawd"d t4aoal \\'&u 'al a a,Sloi,1S eai"i,al'~. 'Nsslal.;gtePl. Be 29S&B &198 .isthe 9aleMBe leclu,sicaf ,.,FO'iciaKe" 6alite., ea,.idiO'. Statio", AlexB •• d.is, VA. !!!eN 8'4!. ,;M.41148 'fl'is dUcO,.Mill W'ilai.,s aliilical data wlrose expo,l is idst,icted by tli6 Arlil! Eurse" SSPItial "at FRIis ee, 1:I.9.e. gec. ii'S1 sl. seq.) 01 tlls Exr;01l ftle!lIi"isllatioli Act 0' 19i'9, as 1tI'I'I0"e!ee!, "Filill ell, W.S.€'I ,0,,,,, 1i!4Q1, III: IIlIiI. 'o'iolatioils of ltrese expo,lla;;s ale subject to 960616 an.iudl pSiiaities.
    [Show full text]
  • The Development of HF Broadcast Antennas
    Development of HF Broadcast Antennas FEATURES FEATURES Development of HF Broadcast Antennas the 50% power loss, but made the Rhombic fre - Free Europe and Radio Liberty sites. quency-sensitive, consequently losing the wide- Rhombic antennas are no longer recommend - The Development of HF bandwidth feature. The available bandwidth ed for HF broadcasting as the main lobe is nar - depends on the length of the wire and, using dif - row in both horizontal and vertical planes which ferent lengths of transmission line, it is possible to can result in the required service area not being Broadcast Antennas access two or three different broadcast bands. reliably covered because of the variations in the A typical rhombic antenna design uses side ionosphere. There are also a large number of lengths of several wavelengths and is at a height side lobes of a size sufficient to cause interfer - Former BBC Senior Transmitter Engineer Dave Porter G4OYX continues the story of the of between 0.5-1.0 λ at the middle of the operat - ence to other broadcasters, and a significant pro - development of HF broadcast antennas from curtain arrays to Allis antennas ing frequency range. portion of the transmitter power is dissipated in the terminating resistance. THE CORNER QUADRANT ANTENNA Post War it was found that if the Rhombic Antenna was stripped down and, instead of the four elements, had just two end-fed half-wave dipoles placed at a right angle to each other (as shown in Fig. 1) the result was a simple cost- effective antenna which had properties similar to the re-entrant Rhombic but with a much smaller footprint.
    [Show full text]
  • MFJ 2004 Ham Buyers Guide
    QSTCatP01.qxd 10/16/2003 10:03 AM Page 1 MFJ 2004 Ham Buyers Guide See inside for these New MFJ Products! 300W Automatic Tuner Tiny Travel Tuner DC Multi-Outlet Strips Ultra-fast, 2000 memories, antenna Fits in the palm of your hand! 150 has both 5-way binding posts switch, 4:1 balun, Cross-Needle and Watts, 80-10 Meters, Bypass Switch and Digital SWR/Wattmeter, 1.8-30 MHz Anderson PowerPole® connectors MFJ-902 $7995 $ 95 MFJ-1129 $ 95 109 MFJ-993 259 Four New models -- balun, Four new high current 150, 300, 600 Watt models. SWR/Wattmeter . DC multi-outlet strips . See Back Cover See Page 6 See Page 16 Balanced Line Dummy Load Manual Mic/Radio Switch Antenna Tuner SWR/Wattmeter Screwdriver Switch any 2 mics 1.5kW, to any 2 rigs Superb Antenna peak reading Covers 40-2 Meters balance, switchable 1.8-54 MHz, to external MFJ-1662 $ 95 $ 95 300 Watts antenna 129 MFJ-1263 99 $ 95 $ 95 MFJ-974H 189 MFJ-267 149 Four new models . Three new models . See Page 7 See Page 9 See Page 42 See Page 21 10 foot Antenna 160-6 Meter 1.5 kW 4:1 Glazed 4 Foot Telescopic Tripod Doublet current balun ceramic Ground Whip 40-inch Antenna /insulator insulator Rod MFJ-1954 between legs Copper bonded steel MFJ- $ 95 MFJ-1918 MFJ-919 MFJ-16C01 MFJ-1934 19 1777 $ 95 $ 95 $ 95 59 $ 95 3 lengths . 39 49 69c 4 See Page 42 See Page 42 See Page 43 See Page 43 See Page 43 See Page 7 Mobile Discone Atomic Atomic Wireless Speaker/Mic Antennas Antenna 24/12 Clock 24/12 Watch Weather for Yaesu VX-7R MFJ-1456, $14995 25-1300 Station MHz 40/20/15/10/6/2M MFJ- MFJ- MFJ-295R $ 95 $ 95 MFJ-1868 132RC 186RC MFJ-192 MFJ-1438, 99 $ 95 19 10/6/2M/440 MHz $5995 $1495 $2995 59 See Page 41, 39 See Page 40 See Page 29 See Page 30 See Page 30 See Page 35 Ameritron Ameritron Ameritron Hy-Gain Screwdriver Digital Screwdriver flat Mobile 80-10 M Vertical Antenna Antenna Controller SWR/Wattmeter The Classic is Back! 5 1.2 kW, Pittman Super bright high- Just 1 /8” thick, AV-18AVQII Commercial Gear Motor intensity LEDs flat mounts on $ 95 dashboard 229 SDA-100 SDC-100 MK-80, $79.95.
    [Show full text]
  • Wire Antennas for Ham Radio
    Wire Antennas for Ham Radio Iulian Rosu YO3DAC / VA3IUL http://www.qsl.net/va3iul 01 - Tee Antenna 02 - Half-Lamda Tee Antenna 03 - Twin-Led Marconi Antenna 04 - Swallow-Tail Antenna 05 - Random Length Radiator Wire Antenna 06 - Windom Antenna 07 - Windom Antenna - Feed with coax cable 08 - Quarter Wavelength Vertical Antenna 09 - Folded Marconi Tee Antenna 10 - Zeppelin Antenna 11 - EWE Antenna 12 - Dipole Antenna - Balun 13 - Multiband Dipole Antenna 14 - Inverted-Vee Antenna 15 - Sloping Dipole Antenna 16 - Vertical Dipole 17 - Delta Fed Dipole Antenna 18 - Bow-Tie Dipole Antenna 19 - Bow-Tie Folded Dipole Antenna for RX 20 - Multiband Tuned Doublet Antenna 21 - G5RV Antenna 22 - Wideband Dipole Antenna 23 - Wideband Dipole for Receiving 24 - Tilted Folded Dipole Antenna 25 - Right Angle Marconi Antenna 26 - Linearly Loaded Tee Antenna 27 - Reduced Size Dipole Antenna 28 - Doublet Dipole Antenna 29 - Delta Loop Antenna 30 - Half Delta Loop Antenna 31 - Collinear Franklin Antenna 32 - Four Element Broadside Antenna 33 - The Lazy-H Array Antenna 34 - Sterba Curtain Array Antenna 35 - T-L DX Antenna 36 - 1.9 MHz Full-wave Loop Antenna 37 - Multi-Band Portable Antenna 38 - Off-center-fed Full-wave Doublet Antenna 39 - Terminated Sloper Antenna 40 - Double Extended Zepp Antenna 41 - TCFTFD Dipole Antenna 42 - Vee-Sloper Antenna 43 - Rhombic Inverted-Vee Antenna 44 - Counterpoise Longwire 45 - Bisquare Loop Antenna 46 - Piggyback Antenna for 10m 47 - Vertical Sleeve Antenna for 10m 48 - Double Windom Antenna 49 - Double Windom for 9 Bands
    [Show full text]
  • I the 'II Log-Periodic Yagi Bandpass Beam Antenna
    I the 7 LPY + this month cw transceiver 14 measuring antenna gain 26 solid-state crystal oscillators 33 * six-meter transverter 44 glass semiconductors 54 'II log-periodic yagi bandpass beam antenna ... but not for the KWM-2 At 100,000 miles, it's still the liveliest rig on the road. Amateurs punch through the QRM on 20 meters with Mosley's A-203-C, an optimum spaced 20 meter antenna designed for full power. The outstanding. maximum gain performance excells most four to six element arrays. This clean-I ine rugged beam incorporates a spe- cia1 type of element design that virtually eliminates element flutter and boom vibration. Wide spaced; gamna matched for 52 ohm ck"1, line with a boom length of 24 feet and\/ elements of 37 feet. Turning radius is 22 feet. Assembled weight - 40 Ibs. 5-401 for 40 meters A-31 5-C for 15 meters \ Full powered rotary dipole. Top signal for Full sized, full power. full spaced 3-element DX performance. 100% rustproof hardware. arrays. 100% rustproof all stainless steel Low SWR. Heavy duty construction. Link hardware; low SWR over entire bandwidth; cou~linaresults in excellent match. Lenath Max. Gain; Gamma matched for 52 ohm line . is 43' 15 3/8"; Assembled weight - 25 lk. - - - - - - -117. m lcatlons and pel e data, write De --"- -"6 4610 N. Lindbergh Blvd.. Bridgeton. h& july 1969 1 / A 5 BAND 260 WATT SSB r- TRANSCEIVER WITH BUILT-IN AC AND DC SUPPLY, AND LOUDSPEAKER, IN ONE PORTABLE PACKAGE. Thc Swii~lCv~liet IS the most versatile and portable transce~ver on the market, and certa~nlythe best posslble value.
    [Show full text]
  • Significant Papers from the First 50 Years of the Boulder Labs
    B 0 U l 0 I R LABORATORIES u.s. Depan:ment • "'.."'c:omn-..""""....... 1954 - 2004 NISTIR 6618 and NTIA SP-04-416 Significant Papers from the First 50 Years of the Boulder Labs Edited by M.E. DeWeese M.A. Luebs H.L. McCullough u.s. Department of Commerce Boulder Laboratories NotionallnstitlJte of Standards and Technology Notional Oc::eonic and Atmospheric Mministration Notional Telecommunications and Informofion Administration NISTIR 6618 and NTIA SP-04-416 Significant Papers from the First 50 Years of the Boulder Labs Edited by M.E. DeWeese, NIST M.A. Luebs, NTIA H.L. McCullough, NOAA Sponsored by National Institute of Standards and Technology National Telecommunications and Information Administration National Oceanic and Atmospheric Administration Boulder, Colorado August 2004 U.S. Department of Commerce Donald L. Evans, Secretary National Institute of Standards and Technology Arden L. Bement, Jr., Director National Oceanic and Atmospheric Administration Conrad C. Lautenbacher, Jr., Undersecretary of Commerce for Oceans and Atmosphere and NOAA Administrator National Telecommunications and Information Administration Michael D. Gallagher, Assistant Secretary for Communications and Information ii Acronym Definitions CEL Cryogenic Engineering Laboratory CIRES Cooperative Institute for Research in Environmental Sciences CRPL Central Radio Propagation Laboratory CU University of Colorado DOC Department of Commerce EDS Environmental Data Service ERL ESSA Research Laboratory ESSA Environmental Science Services Administration ITS Institute for
    [Show full text]
  • For Real DX'ers
    AESCoverAdOpt1_Layout 1 2/4/13 2:12 PM Page 1 AMATEUR ELECTRONIC SUPPLY TS-990S HAM RADIO CATALOG HF/50MHz TRANSCEIVER SPRING/SUMMER 2013 5710 W. Good Hope Rd. Milwaukee, WI 53223 For Real DX’ers 414-358-0333 1-800-558-0411 Fax 414-358-3337 [email protected] 28940 Euclid Ave. Cleveland, OH 44092 440-585-7388 1-800-321-3594 Fax 440-585-1024 [email protected] 621 Commonwealth Ave. Orlando, FL 32803 407-894-3238 1-800-327-1917 Fax 407-894-7553 [email protected] Vendedores Hispanos 4640 South Polaris Ave. Las Vegas, NV 89103 702-647-3114 1-800-634-6227 Fax 702-647-3412 [email protected] Deutsch Sprechend Verkäufer Vendedores Hispanos Store Hours Monday – Friday • 9am to 5:30pm Saturday • 9am to 3pm 1-800-558-0411 www.aesham.com Check Out The New AESHAM.COM Easy Shopping Experience! VHF/UHF Dual Band Transceiver new id- 51a .V TVYL WSHJLZ [OHU L]LY ILMVYL +\HS^H[JO ^P[O (4-4 9LJLP]L Receives two bands simultaneously with AM/FM broadcast station receiver :SPT *VTWHJ[ TPJYV:+ 9LHK` Packed with multiple features in a compact size including voice and data storage and memory data cloning* *Optional microSD required 0U[LNYH[LK .7: Provides position reporting for near repeater and GPS logging* functions *Optional microSD required Information & Downloads AMATEUR TOOL KIT COMIC BOOKS VIDEOS WWW.ICOMAMERICA.COM Electronic advertisements feature active links ©2013 Icom America Inc. The Icom logo is a registered trademark of Icom Inc. All specifications are subject to change without notice or obligation.
    [Show full text]
  • Itoring the Full- Spectrum Radio Magazine
    Vol. 1`, No. 6 June 1996 itoring The Full- Spectrum Radio Magazine A Phlication of Grove Enterprises, Inc. INSIDE: A huge list of agencies and frequencies to monitor at the XXVI Olympiad! Eth Wl An i Voic "F Ma poradic sum n 11 33932 74654 8 Printed in the United States www.americanradiohistory.com Ca ture th &out® Reaction Tune ® brings you all the action. Whether it is police, fire, commercial or just everyday communications monitoring, the Scout will bring you closer to the action. The Scout will not only capture the frequency, but it automatically tunes the receiver to that frequency at the same time; (see receivers appl. below). Let the Scout Reaction Tune your way into the world of communications. FEATURES Records up to 400 unique frequencies in memo ry Records up to 255 hits on each frequency in memory. 10MHz - 1.4GHz single frequency range. Records frequencies automatically with Patented Digital Auto Filter & Digital Auto Capture. Reaction Tune the AOR AR8000, AR2700, ICOM R7000, R7I00, R9000, Radio Shack Pro 2005 /2006 with 05456 installed, and the Radio Shack Pro 2035/2042 with 0S535 installed. All frequencies are automatically saved until deleted. I Interface to a PC with the optional OPTOLINX or CX12AR for data download. Custom 10 digit LCD display with automatic EL backlighting. 16 segment RF signal strength bargraph. Pager style vibrator for discreet recording. Distinctive beeper indicates frequency detection. Rapid charge NiCads with AC charger supplied; 2 hour recharge and 8 -10 hour battery discharge. Frequency Range: 10MHz - 1.4GHz 41) Operating Time: 8 - 10 hours 50 <2:1 Input Amplifier: Ohm vswr Power 2VDC 1 Amp wall plug adapter for rapid - Using the optional SAC8000 is a snap -Just Sensitivity lmV 30MHz 900MHz charging.
    [Show full text]
  • Comtittet, Ication
    1...t • August 1984 M u' COMTittet, ication QSL CARDS RECENTLY AMATEUR RADIO STATION RECEIVED AT RSGB 6B4 D - DAY HQ COMMEMORATING TWO UNIQUE OCCASIONS ON RIGHT The card of GB4DD through which messages were exchanged with HM The Queen, as featured on last month's cover BELO W The front and one inside page of the four-page card ERATION OV RD commemorating the first amateur radio operation in UTAH OMAHA ,I,CLD JUNO SWORD space FLIG HT OF COLU MBIA ItIASA STS-9/Spacelab-1 Launched on November 28, 1983 and alter 247 hrs. 47 min landed at Edwards A F B. on December 8, 1983 • First launch of Spacelab Iprovided by the European Space Agency/ • Longest Orbiter flight to date • First European crewmember • First 'Payload Specialists" Irian:career astronautst • First six-person spaceflight * First Amateur Radio station in space. W5LFL Transceiver moddied Motorola MX-300 2-meter FM transceiver, hand-DUllt by the Motorola Amateur Radio Club in Florida. Antenna. directionat ring radiator with cavity, designed lo lit in the upper window of the spacecraft; built for NASA by volunteer employees of Lockheed Power 45 watts Mode. FM, CW (by keying carrier) All transmit and receive audio were tape recorded, which constitutes the station log. Operating orbits 400. 560. 62A. 710, 91A, 96A. 97A&0, 110D. 111A&D, 112A. 113A, 129A. laoA, 134A, 1340, 135A&D, 144A&D, 145A&D, 146A, 1490 and 15011 4 111 - 3 _A s k Stations. 2-way contact: over 350 It" SWL approximately 10,000 cards received Countries 23 STS-9/Spacelab-1 I 21MSA T, ; Total operating lime abOut 4 hrs.
    [Show full text]
  • Theory and Application of Antenna Arrays
    THEORY AND APPLICATION OF ANTENNA ARRAYS M.T.Ma Senior Member of the Technical Staff Institute for Telecommunication Sciences Office of Telecommunications U. S. Department of Commerce Boulder, Colorado and Professor-Adjoint of Electrical Engineering University of Colorado A Wiley-Interscience Publication John Wiley & Sons New York London Sydney Toronto Copyright @ 1974, by John Wiley & Sons, Inc. All rights reserved. Published simultaneously in Canada. No part of this book may be reproduced by any means, nor transmitted, nor translated into a machine language with- out the written permission of the publisher. Library of Congress Cataloging in Publication Data: Ma,M.T. Theory and application of antenna arrays. "A Wiley-Interscience publication." Includes bibliographies. 1. Antenna arrays. I. Title. TK7871.6.M3 621.38'0283 73-15615 ISBN 0-471-55795-1 Printed in the United States of America 10 9 8 7 6 5 4 3 2 I To Simone, Beverly, and John PREFACE Since early 1959when I was first engaged in research on antenna arrays at Syracuse University, my interest in this subject has been divided into two major phases. One of these, which occupied most of my attention from 1959 to 1966, was concerned primarily with basic analysis and synthesis techniques pertinent to antenna arrays, which, for the most part, is an applied mathematics problem. The goals then were to produce a particular class of radiation patterns, to reduce sidelobe levels, to maximize the directivity, and to synthesize an array with a relatively broad frequency band, or to achieve some combinations of these. Isotropic elements were mostly used for the sole purpose of developing general mathematical models, which should not be limited to any particular kind of antennas or frequency bands.
    [Show full text]