Return-Path: Received: from mtain-me01.r1000.mx.aol.com (mtain-me01.r1000.mx.aol.com [172.29.96.137]) by air-da08.mail.aol.com (v128.1) with ESMTP id MAILINDA084-86924bae063b213; Sat, 27 Mar 2010 09:20:59 -0400 Received: from post.thorcom.com (post.thorcom.com [193.82.116.20]) by mtain-me01.r1000.mx.aol.com (Internet Inbound) with ESMTP id C9E863800008E; Sat, 27 Mar 2010 09:20:57 -0400 (EDT) Received: from majordom by post.thorcom.com with local (Exim 4.14) id 1NvVvL-0002DQ-Pn for rs_out_1@blacksheep.org; Sat, 27 Mar 2010 13:19:35 +0000 Received: from [193.82.116.32] (helo=relay1.thorcom.net) by post.thorcom.com with esmtp (Exim 4.14) id 1NvVvL-0002DH-Br for rsgb_lf_group@blacksheep.org; Sat, 27 Mar 2010 13:19:35 +0000 Received: from smtp822.mail.ird.yahoo.com ([217.146.188.232]) by relay1.thorcom.net with smtp (Exim 4.63) (envelope-from ) id 1NvVvJ-0005Ct-H8 for rsgb_lf_group@blacksheep.org; Sat, 27 Mar 2010 13:19:35 +0000 Received: (qmail 18117 invoked from network); 27 Mar 2010 13:19:27 -0000 DomainKey-Signature: a=rsa-sha1; q=dns; c=nofws; s=s1024; d=btinternet.com; h=DKIM-Signature:Received:X-Yahoo-SMTP:X-YMail-OSG:X-Yahoo-Newman-Property:Message-ID:From:To:References:Subject:Date:MIME-Version:Content-Type:Content-Transfer-Encoding:X-Priority:X-MSMail-Priority:X-Mailer:X-MimeOLE; b=Tp1EB+IKPDGI9B7W5e/NJBrAw3QpWJGZlMvO9Z46ktUKvuEpJoo0nPg0pJNWUkIhVYMyjFdQh6Q7k2wOAZnsRc4MV8AFbi5uwg/UwmN3gvb5oX4PSaa5BymFY5DUmVEWTi9al5n0pIFWj5KoszP71o90lDyGH5GMaZvq1is7R2c= ; DKIM-Signature: v=1; a=rsa-sha256; c=relaxed/relaxed; d=btinternet.com; s=s1024; t=1269695967; bh=9kPp9ZN7FoUYIh29yAqpIt2RIsxDzvGY1871aSDNFSI=; h=Received:X-Yahoo-SMTP:X-YMail-OSG:X-Yahoo-Newman-Property:Message-ID:From:To:References:Subject:Date:MIME-Version:Content-Type:Content-Transfer-Encoding:X-Priority:X-MSMail-Priority:X-Mailer:X-MimeOLE; b=vzmvvggGLyLFBSlk/X45fqbvgsX/6x07/5cAQ6xzJlRFDrTBY36Uo9z7IoJKhjZeCunUJKLjT5oEQxwLkevRWMBk9IEGQPeRouStt1qablZyJc1ZyUOphaPHHREBylfSJDsI+4IHjAvgtEF8PLCkl/g+3zLcpWUiby5re7z5opA= Received: from lark (alan.melia@81.131.45.207 with login) by smtp822.mail.ird.yahoo.com with SMTP; 27 Mar 2010 06:19:26 -0700 PDT X-Yahoo-SMTP: fpz.2VeswBBs59bVshRPmMN51lcO2lgFRIvE4XTqE8dRwOxd70E- X-YMail-OSG: _zsRN_oVM1lkpMtUGflb1r4NkI7NoyMvtImCr.QM5uG_sO09U8hnfn9iZIsE0z8hXlly.F6oWRxAW2Tjquj.kvQVXZmAS9bGQUKDuU6j3EiiejePJ6vfekiy7wcXkmge.wPpn_FbIHhv_jNgAeLm50pnyl1smHT743FoCjacXw3K6J91m0vR0ulv_itgD0fx0KEswMpmzx4GtxlFMFOkDAqHWXCwApTNqD6mrYvfj2fateMaY00YeWDgXqSUVa1Jm_LR7CyudeiavkRG6h9xRhJpY4qrq89BFPgNdPErKfVlYZUY2f1VeqCaymycT7rEjk0- X-Yahoo-Newman-Property: ymail-3 Message-ID: <006e01cacdb0$2699eb00$0901a8c0@lark> From: "Alan Melia" To: References: <4BAD19D0.300@telia.com> <56DF8C4BED71466A80EB2EB1D99F6788@JimPC> <38A51B74B884D74083D7950AD0DD85E82A1BA3@File-Server-HST.hst.e-technik.tu-darmstadt.de> Date: Sat, 27 Mar 2010 13:15:08 -0000 MIME-Version: 1.0 X-Priority: 3 X-MSMail-Priority: Normal X-Mailer: Microsoft Outlook Express 6.00.2800.1983 X-MimeOLE: Produced By Microsoft MimeOLE V6.00.2800.1983 DomainKey-Status: good (testing) X-Spam-Score: 0.0 (/) X-Spam-Report: autolearn=disabled,UNPARSEABLE_RELAY=0.001 Subject: Re: LF: Question about ground impedance at 8.97 KHZ Stefan. Content-Type: text/plain; charset="iso-8859-1" X-Spam-Checker-Version: SpamAssassin 2.63 (2004-01-11) on post.thorcom.com X-Spam-Level: X-Spam-Status: No, hits=0.0 required=5.0 tests=none autolearn=no version=2.63 X-SA-Exim-Scanned: Yes Sender: owner-rsgb_lf_group@blacksheep.org Precedence: bulk Reply-To: rsgb_lf_group@blacksheep.org X-Listname: rsgb_lf_group X-SA-Exim-Rcpt-To: rs_out_1@blacksheep.org X-SA-Exim-Scanned: No; SAEximRunCond expanded to false x-aol-global-disposition: G X-AOL-SCOLL-AUTHENTICATION: mail_rly_antispam_dkim-m203.2 ; domain : btinternet.com DKIM : pass x-aol-sid: 3039ac1d60894bae06391c80 X-AOL-IP: 193.82.116.20 Content-Transfer-Encoding: quoted-printable Dont forgett here is a small inductance component in a wire antenna as= well, this can become insignificant as you move well away from resonance. bu= t the series capacitance I measured at various frequencies (but not as low= as 9kHz) was sensibly the same....there used to be a ball park figure (on= 136) for a low L or T antennas of 5-6pF per metre. As you move toward reson= ance if you calculate the inductive component and allow for it, then the se= ries capacitance component remains the same. Alan G3NYK ----- Original Message -----=20 From: "Stefan Sch=E4fer" To: Sent: Saturday, March 27, 2010 12:27 PM Subject: AW: LF: Question about ground impedance at 8.97 KHZ Stefan. Jim, What do you think is the reason why you measure just 340pF on a 55m wi= re? And which C do you measure at 137kHz on the same antenna? What do you= think is the accuracy of your measurement? 300 Ohm earth+surroundings losses is very good compared to my values= on the hill, although i have just one small tree in a radius of >100m. What= about your ground conductivity? Maybe i have to try other additional earth systems on VLF... Will you prepare a TX system on the dreamers band as well? Than we cou= ld repeat our CW QSO just like on 137kHz ;-) 73, Stefan/DK7FC ________________________________ Von: owner-rsgb_lf_group@blacksheep.org im Auftrag von James Moritz Gesendet: Sa 27.03.2010 13:06 An: rsgb_lf_group@blacksheep.org Betreff: Re: LF: Question about ground impedance at 8.97 KHZ Stefan. Dear Paul, LF Group, For Stefan's benefit, 1' =3D 0.3048m, so we are talking about a 52m lo= ng wire. I measured my home QTH inv-L antenna (about 55m of wire in total, abou= t 10m height) at 10kHz to have a capacitance of about 340pF, in series with= a resistance of about 300ohms. This is in a location with several small= trees, etc., so you could possibly expect lower resistance in an open locatio= n, or higher if you are in a forest! As has been pointed out, it depends on the type of bridge whether you= are measuring a series or parallel RC equivalent - for the above antenna,= the parallel equivalent would be about 340pF/7.3Megohms. The magnitude of= the impedance at 9kHz would be about 52kohms These are much higher impedances than are commonly measured using amat= eur RF bridges. If you look at old textbooks on AC bridge measurements, you= will see elaborate shielding/guarding measures are often required for high impedance measurements. The basic problem is you are trying to measure= a small resistance component while balancing out a much larger, quadratu= re, capacitive component. So anything that affects the balance of the brid= ge (e.g. stray coupling between the components, or source or detector),= can cause large errors. I imagine good electrostatic shielding between th= e bridge components and antenna wire would be essential. A first step wo= uld be to check the bridge works accurately on some known impedances (e.g. a low-loss capacitor of a few 100pF with a series resistor). The way I did my measurements was to resonate the antenna at the measu= rement frequency with a series inductor, then measure the relatively low resi= stive impedance of the combination with a simple resistance bridge. The loss resistance of the coil was measured by replacing the antenna with a calibrated air-variable capacitor, measuring the resistance again, and subtracting it from the antenna+coil resistance. This still has some potential errors (e.g. due to the stray capacitance of the inductor to ground) but avoids the need to resolve the R/C components, and reflect= s the way the antenna will actually be used. Cheers, Jim Moritz 73 de M0BMU