Return-Path: Received: (qmail 23426 invoked from network); 12 Jan 2000 01:49:02 -0000 Received: from unknown (HELO post.thorcom.com) (212.172.148.70) by bells.core.plus.net.uk with SMTP; 12 Jan 2000 01:49:02 -0000 Received: from majordom by post.thorcom.com with local (Exim 3.02 #1) id 128Clt-0008Og-00 for rsgb_lf_group-outgoing@blacksheep.org; Wed, 12 Jan 2000 01:40:25 +0000 Received: from tk1.ihug.co.nz ([203.29.160.13] helo=smtp1.ihug.co.nz) by post.thorcom.com with esmtp (Exim 3.02 #1) id 128Clr-0008Ob-00 for rsgb_lf_group@blacksheep.org; Wed, 12 Jan 2000 01:40:23 +0000 Received: from test (p6-max1.chc.ihug.co.nz [207.214.13.198]) by smtp1.ihug.co.nz (8.9.3/8.9.3/Debian/GNU) with SMTP id OAA21031 for ; Wed, 12 Jan 2000 14:40:13 +1300 Message-ID: <005701bf5c9e$23b33b00$c60dd6cf@test> From: "Dave Brown" To: rsgb_lf_group@blacksheep.org References: <000e01bf5ba5$6bc57f60$60d725c3@194.95.193.10.fen.baynet.de><387ABC73.EB1AE1BB@qsl.net> Subject: Re: LF: Calculating distributed C for inductors Date: Wed, 12 Jan 2000 14:41:22 +1300 MIME-Version: 1.0 Content-Type: text/plain; charset=iso-8859-1; format=flowed Content-Transfer-Encoding: 8bit X-Priority: 3 X-MSMail-Priority: Normal X-Mailer: Microsoft Outlook Express 5.00.2314.1300 X-MimeOLE: Produced By Microsoft MimeOLE V6.00.2800.1106 Precedence: bulk Reply-To: rsgb_lf_group@blacksheep.org X-Listname: rsgb_lf_group Sender: The classic method for determining self capacitance of an inductor is to measure the resonant frequency (freq) with several values of parallel capacitance.(C) Making a plot of 1/(freq)squared on the vertical axis v. resonating capacitance on the horizontal axis yields a straight line(or should!!) that intersects the HORIZONTAL or capacitance axis at a negative C value when extrapolated. The negative C value is the self capacitance of the inductor in question. As well, the slope of the straight line is a measure of the TRUE inductance value of the coil and can be taken from the relation L (henries) = 0.0253M, where M is the slope of the line.(freq in MHz and C in pF). A more practical method based on the above is the F/2F method where the inductor is resonated at an initial frequency, F1, the added parallel C value measured (C1). The inductor is then re-resonated at TWICE the first frequency, say F2, and again the resonating C measured(C2). The inductor self-capacitance is then given by Cself = (C1 - 4C2)/3. Measuring the inductance and then the parallel resonating capacitance and trying to predict the stray C from the required result correction will only give an approximate answer, as will direct measument of the self-resonant frequency (and thence to the self-C) but for accurate work the F/2F method is better. 73 Dave ZL3FJ