tag:blogger.com,1999:blog-30995985808124161622024-03-14T04:02:32.394+01:00de draaggolf ~~~~~Joachim's Ham-Radio and Radio-Frequency Blog (A Solderful of Secrets) - from Longwave to MicrowavesJoachim Seiberthttp://www.blogger.com/profile/01766975824128341507noreply@blogger.comBlogger395125tag:blogger.com,1999:blog-3099598580812416162.post-39266066980039543522022-10-01T00:54:00.001+02:002022-10-01T00:54:26.431+02:00IKEA HiFi<p>It is obvious, not only did I not post a lot lately, I am also very late in the game what IKEA electronics is concerned. After having talked about HiFi gear made from PVC-tubing, there was not much left to degrade my standards in high fidelity audio, I figure. And here I am, talking about IKEA as the next audiophile (maybe not) source of gear.</p><p>A while ago, I contemplated using JBL Flip4 speakers as improvised stereo setup. This worked all fine, one the app recognized the speakers and finally configured those into a stereo pair. Maybe that was the tech of that time, I don't know, but, it (finally) turned out that an easier way is possible.</p><p>Coming onto the scene, the IKEA Eneby gen 2 BT speakers. Not only those speakers are 60% of the price I paid for the JBLs, they also remember the (stereo) configuration they were set up in.<br />While the original Eneby speakers might sound equally good as the 2nd generation, stereo pairing of those was not an option. Solely for that reason, I could not be bothered with the Enebys. <br />However, this has all changed now. One can configure two identical Eneby gen 2 speakers to act as a stereo pair and the speakers will keep this setup, unless reset to factory settings.</p><p>What the sound is concerned, I think they sound very nice. Initially my impression was that they are a bit bass heavy, however, this might have been due to the music I tested them with in the first attempt. Listening to "Sweet Smoke" now, the speakers seem well balanced and the stereo image is very pleasing, just like I remember the record when played on vinyl on a big rig years ago.</p><p>The speakers can get surprisingly loud. </p><p>Even as a stereo pair, one can control the balance by individually adjusting the volume of the respective speaker. While this makes sense with balance, this also can be done to the bass and treble response of the individual speaker... I am not sure if that makes any sense.</p><p>The Eneby gen 2 speakers do have an analog jack input. I have not yet tested if one can run a stereo paired setup with analog input. That's a test for a future post.</p><p><br /></p>Joachim Seiberthttp://www.blogger.com/profile/01766975824128341507noreply@blogger.comtag:blogger.com,1999:blog-3099598580812416162.post-56546869407842166362021-02-10T02:21:00.000+01:002021-02-10T02:21:16.732+01:00The Bullseye LNB for QO-100<p>It finally arrived in the Netherlands, the most expensive LNB I ever bought. For a whopping €25 and many weeks of waiting, the Bullseye LNB was mine. Well, nothing to complain about really, I knew how long shipping will take, and, seen reviews on YouTube, the LNB seemed worth the money and the wait, in particular when compared to competing products.</p><p>So, the shipment came in, finally. Of course, I waited until after midnight before I finally got the LNB installed in the focus of my downlink dish. You can't do those things in daylight... it just would not be cool... literally, with have a winter wave with temperatures about -9C. <br />Anyway, the LNB is installed and was surprisingly easy to find in the spectrum. Well done! Also, for the time being, the LNB appears to be very stable. Again, well done!</p><p>If the positive experience holds true, I will be hooking up my FT-736 again. Something I really looked forward to since I first learned about QO-100.</p><p><br /></p>Joachim Seiberthttp://www.blogger.com/profile/01766975824128341507noreply@blogger.comtag:blogger.com,1999:blog-3099598580812416162.post-15053007382217238912021-01-17T15:20:00.004+01:002021-01-17T15:20:58.124+01:00QO-100 Up-Link -- So Many Things Wrong<p>There are so many things wrong with my up-link feed:</p><p></p><ol style="text-align: left;"><li>RG-6 75 Ohms feed line from a 50 Ohms PA</li><li>the base of the helix is embedded in hot-glue</li><li>the material is Zn-plated Cu-wire (Zn corroding)</li><li>the spacing of the helix is off and narrows towards the end</li></ol><p></p><table align="center" cellpadding="0" cellspacing="0" class="tr-caption-container" style="margin-left: auto; margin-right: auto;"><tbody><tr><td style="text-align: center;"><a href="https://blogger.googleusercontent.com/img/b/R29vZ2xl/AVvXsEh961d9EOyLyb3fw1FTIrHIE_s3boT4ePQfP74sOF-Nj7NfUX8eofCe4tx11aRhI86_em9c5o6T-vMD1prHjKyxJg5kcWSKBZjM3xR6U-nJ_PlXkpVMDkzoQGpyF5CibKSYMNexfHV2iz0/s2048/feed.jpg" imageanchor="1" style="margin-left: auto; margin-right: auto;"><img border="0" data-original-height="1536" data-original-width="2048" height="300" src="https://blogger.googleusercontent.com/img/b/R29vZ2xl/AVvXsEh961d9EOyLyb3fw1FTIrHIE_s3boT4ePQfP74sOF-Nj7NfUX8eofCe4tx11aRhI86_em9c5o6T-vMD1prHjKyxJg5kcWSKBZjM3xR6U-nJ_PlXkpVMDkzoQGpyF5CibKSYMNexfHV2iz0/w400-h300/feed.jpg" width="400" /></a></td></tr><tr><td class="tr-caption" style="text-align: center;">2.4 GHz up-link helix feed</td></tr></tbody></table><p>You are seeing the result of ignorance and tweaking, which resulted in the feature of point 4).</p><p>I hooked a nanoVNA2 up to the PA side of the RG-6, then pushed and pulled on various parts of the helix to minimize the SWR. This procedure included the 75 Ohms transmission line of course. Thereby, I improving the SWR from 4.6:1 to 2.4:1.</p><p>Next step you probably be to play with a wire-cutter again. As you can see, the helix has 3+3/4 turns, so, there might be room for improvement still.</p><p>For the time being, I am pretty happy with my up-link signal anyway.</p>Joachim Seiberthttp://www.blogger.com/profile/01766975824128341507noreply@blogger.comtag:blogger.com,1999:blog-3099598580812416162.post-62689399513957874152020-11-29T20:44:00.002+01:002020-11-30T17:41:01.576+01:00Ender 3 and the Black-and-White Dog<p>In the past, I was proud enough to fabricate every little piece of hardware from either plastic, metal of wood, with traditional tools. It's 2020 now, so the decision was made to modernize my tinkering and add 3D-printing to the arsenal.</p><p>My Black Friday choice of purchase was a <a href="https://www.creality3dofficial.com/products/official-creality-ender-3-3d-printer" target="_blank">Creality Ender 3</a>. Mainly for the reason hat it is so widely spread. </p><p>The printer came semi-assembled and was easy to put together. There are some very good tutorials how to do that on YouTube. I followed one by "3D Printing Canada", which explains the alignment and bed-leveling very well.<br />For all you experts out there, the model I got is version 1.1.6.2 with a Melzi board.</p><table align="center" cellpadding="0" cellspacing="0" class="tr-caption-container" style="margin-left: auto; margin-right: auto;"><tbody><tr><td style="text-align: center;"><a href="https://blogger.googleusercontent.com/img/b/R29vZ2xl/AVvXsEgFVzdVlS2bPI14sTTJkiA8j9tjh74l7TGpt7mhkVXVH7B05mYPdFrO6_LQLAwjoKS9xgc-KvxvheVuL47XshlfW3l7z5L8M02lryypv7P3UqXPfqQtPv7xuSD5MzjLPygNiRExM3RmvQo/s2048/IMG_20201129_101842.jpg" style="margin-left: auto; margin-right: auto;"><img border="0" data-original-height="1186" data-original-width="2048" height="231" src="https://blogger.googleusercontent.com/img/b/R29vZ2xl/AVvXsEgFVzdVlS2bPI14sTTJkiA8j9tjh74l7TGpt7mhkVXVH7B05mYPdFrO6_LQLAwjoKS9xgc-KvxvheVuL47XshlfW3l7z5L8M02lryypv7P3UqXPfqQtPv7xuSD5MzjLPygNiRExM3RmvQo/w400-h231/IMG_20201129_101842.jpg" width="400" /></a></td></tr><tr><td class="tr-caption" style="text-align: center;">before assembly<br /></td></tr></tbody></table><p>The printer came with a small roll of white filament. With the printer all being setup and aligned, I dcided to print the dog for which a gcode file is supplied with the printer. The dog took 3h 01m 46s to print. In the process, the printer ran out of the white filament. In principle a very good thing, so I could practice changing filament in mid-print on a object of low importance. That of course created the black and white dog, as referenced in the title of this post.</p><p></p><table align="center" cellpadding="0" cellspacing="0" class="tr-caption-container" style="margin-left: auto; margin-right: auto;"><tbody><tr><td style="text-align: center;"><a href="https://blogger.googleusercontent.com/img/b/R29vZ2xl/AVvXsEjoeW9e6LOljxPbSYMzfIQMek1aV2cAIyvm-nRUHXNhr0HBSnWV-_BF0jDYH6DzO96JCD5l-kg3fZke4lIiz4your1Qy5ucy4NjzwkLZeHT8s99T48gg79h_QefkEs0OQRVqBwavNB7PZE/s1437/IMG_20201129_163854.jpg" style="margin-left: auto; margin-right: auto;"><img border="0" data-original-height="1437" data-original-width="1423" height="400" src="https://blogger.googleusercontent.com/img/b/R29vZ2xl/AVvXsEjoeW9e6LOljxPbSYMzfIQMek1aV2cAIyvm-nRUHXNhr0HBSnWV-_BF0jDYH6DzO96JCD5l-kg3fZke4lIiz4your1Qy5ucy4NjzwkLZeHT8s99T48gg79h_QefkEs0OQRVqBwavNB7PZE/w396-h400/IMG_20201129_163854.jpg" width="396" /></a></td></tr><tr><td class="tr-caption" style="text-align: center;">the black and white dog<br /></td></tr></tbody></table>Note the little white lock which came from the remainder of the white filament in the extruder chamber. <br />After having changed the filament, still 2 or so layers of white came out, perfectly aligned with the first part of the print. However, the first black layer is slightly shifted in the Y-axis. Could that be due to the different filament? It is still PLA... <p></p><p>By now I printed several essential improvements found on <a href="https://www.thingiverse.com/" target="_blank">thingiverse</a>. The STL-files of those parts were slized by <a href="https://slic3r.org/" target="_blank">Sliz3r</a> on a Raspberry Pi 400. <br />The first one came out a bit rough, but usable. For nozzle temperature for this print was set to 185C. The dog was printed at 200C and came out fine. So, for the next few parts, I created gcode files for a nozzle temperature of 200C and a bed temperature of of 60C.</p><p>As a design software for my own projects, I found that <a href="https://solvespace.com/index.pl" target="_blank">solvespace</a> would serve my needs perfectly. The program is available from the Raspberry Pi OS repositories and work fine OOB. Solvespace is similar to many other CAD programs.</p><p>This is my first attempt of becoming less of a dinosaur, however, I am not sure about this yet. With a decently equipped workshop, with materials at hand, making a part from a block of metal or plastic appears to be much less time consuming. Not only do I not have to use a computer to design the piece, I also do not have to wait until the printer is done. Even worse, one has to babysit the printer, just in case something goes wrong. Further, if the printed part is not perfect, there is very little one can do to improve the part. When working with a lump of metal, I tend to make the part just a tiny little bit bigger here and there and use a file, the one from the toolbox, not the one sitting in your computer, and adjust to the proper dimensions manually. <br />Well, his is my first day playing with 3D-printing, however, I already feel the disadvantages.<br />To be honest, there is an advantage to CAD and 3D-printing, which is huge. Once a part is successfully made, it is easily shareable with others. With hand-made parts, this might be different, in particular when a single piece is made in some sort of workshop.<br />Concerning ham radio, one might think of driven element holders for Yagi-Uda-arrays or base plates for a variable capacitor, printed in ABS.</p><p>So, in conclusion, I look forward to becoming more efficient with 3D-printing over time. For now, there is a learning curve ahead, which might slow down my projects by some good amount of time.</p>Joachim Seiberthttp://www.blogger.com/profile/01766975824128341507noreply@blogger.comtag:blogger.com,1999:blog-3099598580812416162.post-39484351125821187132020-11-16T23:21:00.002+01:002020-11-18T21:05:01.057+01:00QO-100 observations<p>Having a satellite in a geosynchronous orbit available is a great privilege for the amateur radio community. In my few months being active on the transponder of this precious satellite I observed the good, the bad and the ugly.</p><p>Writing about the ugly. I was listening to a conversation in Spanish. Si puedo comprara... At the end, the DX station was calling CQ. Well, someone else was faster than me. Fair enough, I waited. At their end, I called and was picked up by S0S in West Sahara. What a pleasant QSO, he even spoke some Dutch, respectful of my call sign. What a gentleman! Our QSO ended undisturbed.<br />I stayed on frequency, since I had some in shack business to conduct. Moments later, some from OE-land (aka Austria) <b>SHOUTED</b> his call (<u>noted but not disclosed</u>) at the transponder, over everybody else, of course triggering Leila. However, his signal was that strong that his call was audible the entire time. <b>HOW RUDE!</b> Of course he had the next QSO, so that he shut the f##k up. <br />Is that how we want this transponder to be for the next 15 years?!</p><p>Honestly, the behavior of our Austrian friend reminded me of the reasons for which I decided to ignore the 80m-band 40 years ago. Unfriendly, unpleasant, un-HAM-ish behavior.</p><p>Dear friend from Austria, YOU SUCK!</p><p><br /></p><p><br /></p>Joachim Seiberthttp://www.blogger.com/profile/01766975824128341507noreply@blogger.comtag:blogger.com,1999:blog-3099598580812416162.post-56469359732103718662020-11-03T00:35:00.001+01:002020-11-03T00:35:29.873+01:00QO-100 Uplink Setup ChangesMy original setup used 10m RG6 between the PA and the feed, with a 100cm SMA patch cable between the converter and the PA.<div>When I reduced the length of the RG6, I also reduced the length of the SMA patch cable to 10cm. After this change, I had some QSOs, no complains. However, when I looked at my own spectrum, I was not so happy seeing splatter on the wrong side-band.</div><div>Probably, my converter, outputting 200mW, saturated the PA, which input is rated 100mW. Just as an experiment, I changed the patch back to 100cm. Having had some test transmissions, I can now state that my signal is clean again.</div><div>Sometimes, it only needs a little bit of coax in the right place to solve a problem.</div><div><br /></div>Joachim Seiberthttp://www.blogger.com/profile/01766975824128341507noreply@blogger.comtag:blogger.com,1999:blog-3099598580812416162.post-25848138282986988872020-10-21T02:27:00.002+02:002020-11-16T21:09:33.492+01:00QO-100 LNB Comparison<p>My downlink (DL) is realized by using an old 35cm off-set dish on my roof deck, something I mentioned before. On recommendation of an old friend, I bought a <a href="https://forum.amsat-dl.org/index.php?thread/2819-venton-exl-s-modification/&postID=8830">Venton EXL-S Rocket Single LNB</a>. So far so good, this LNB served me on many contacts. Using the beacon feature of SDR-Console made it possible to have those contacts. However, during my tests using analogue equipment, drift from this particular LNB was noticeable.<br />I understood the Venton LNB is primarily useful with with POTY "dual band" feed, as it keeps the centre hole to a minimum. Fair enough. </p><p>For my setup, I decided to use two separate dishes for UL and DL, hence, the size of the DL LNB is irrelevant to the UL feed geometry. As a matter of experimentation, I replaced the Venton LNB with an <a href="https://www.octagon-germany.eu/produkte/lnb/optima-serie/oslo/">Octagon OSLO LNB</a> in the 35cm DL dish setup. This LNB was purchased many years ago, when I was active on 3cm rain scatter and wanted to experiment a little bit with commodity gear. To my surprise, the Octagon LNB is a lot more stable, once at temperature. It also appears to be more sensitive than the Venton. Aperture is the name of the game here, I figure. Hmmm, maybe I should have used this LNB from the get-go and saved the few Euros by not buying the Venton LNB.</p><p>Still, there might be a use for the Venton LNB. As mentioned in my previous post, I am considering to use a single dish for DL and UL. With its smaller form-factor, the Venton Rocket might be the better choice when placed inside the UL feed helix in a single dish arrangement.</p><p>I will post my further experiment on this blog, so, stay tuned.</p><p>BTW, occasionally, you might be able to hear me on the transponder. Feel free to give my a call ;-)</p><p><br /></p>Joachim Seiberthttp://www.blogger.com/profile/01766975824128341507noreply@blogger.comtag:blogger.com,1999:blog-3099598580812416162.post-36609848854723117102020-10-19T23:35:00.003+02:002020-10-19T23:35:23.111+02:00QO-100 update<p>Not much to report, other than I shortened the RG-6 coax for the Up-Link. The length should be about 3.5m, however, I have not measured the length yet. In order to achieve the shorter transmission line, drilled a hole into a window frame relatively close to the UL dish. This allows the power amplifier to be indoors. </p><p>By now, I made contacts in side-band from Brazil to Thailand. The occasional rag chew QSO confirmed that my signal is loud enough to not be difficult to listen to.</p><p>There is a plan of using the UL dish also for reception. The added gain in the DL might make it easier to operate with a full analogue setup. Although, the LNB being placed in the center of the feed-helix might compromise the UL signal. Something to experiment with...<br />Further down the line, I might acquire a larger off-set dish, e.g. 1m, mainly to add some gain to the UL.</p><p><br /></p><p><br /></p>Joachim Seiberthttp://www.blogger.com/profile/01766975824128341507noreply@blogger.comtag:blogger.com,1999:blog-3099598580812416162.post-6303650954969690972020-10-11T01:38:00.000+02:002020-10-11T01:38:00.035+02:00QO-100 thoughts<p>The humble listener/follower of my station or posts might have experienced a certain lack of enthusiasm about operating on QO-100/ Please do not interpret much into this. The satellite is great. Probably the greatest any Oscars had ever been by this date.<br />However, once the setup is done, the fine tuning is somewhat frustrating.</p><p>What to look for?</p><p>Ideally, in my world, one would be going fully analogue, i.e. using only pure receivers and transmitters.<br />Does that justify the effort by the operators of the satellite? I don't think so!<br />Hence, we also should look into modern techniques, such as SDR.<br /></p><p>Well, this is exactly the spot I am struggling with. I got the equipment for both, analogue down link and digital down link. I operated with the satellite using both. Concerning the up link, I an analogue only. <br /></p><p>What I used so far (RX - TX):</p><p></p><ul style="text-align: left;"><li>RSP1a - FT817</li><li>FT290R2 - FT790R2</li><li>FT736R (RX+TX)</li></ul><div>Any of the setups has advantages and disadvantages. </div><div><br /></div><div>For the time being, I am using the RSP1a - FT817 the most. However, I have a strong desire to move towards using the FT736R only. </div><div><br /></div><p></p><p><br /></p>Joachim Seiberthttp://www.blogger.com/profile/01766975824128341507noreply@blogger.comtag:blogger.com,1999:blog-3099598580812416162.post-6875599080284285162020-09-22T01:47:00.000+02:002020-09-22T01:47:37.377+02:00QO-100 Analogue Ground Station<p>Yes, it can be done. One can use a fully analogue ground station for QO-100 operations.</p><p>My first attempt included a Yaesu FT-290R2 for reception, along a Yeasu FT-817 for transmission on 70cm. Once a TX frequency has been established, following the drift of the LNB was an OK-ish task during QSOs. Changing frequencies was an unpleasant juggle of setting the receive frequency and trying to find the transmit frequency without annoying everybody else of the transponder. This ballet is performed with VFO controls of two different radios.</p><p>Second attempt: Yaesu FT-736R, the satellite machine from the past. It was doing great, in particular when changing frequencies, using the satellite mode. However, my cheap LNB kept drifting in sunlight, while the up-link converter stayed rock-solid. Hence, using the FT-736R was a constant switching between SAT-mode and RX-QRG. Once a frequency was established, TX-QRG needed to be adjusted. I am not sure how many actuations the little SAT-switch can take. What I am concerned, it took a lot of focusing in order to not adjust the VFO in the wrong setting, thereby messing up the RX/TX-offset.<br />With a stabilized LNB, this might be a different story.<br />I liked the possibility to use the VFO-knob to scan up and down over the band, knowing that, whenever I pushed the PTT, the frequency would be at least close.</p><p>The FT-736R is back in its box for now. In terms of having contacts, the SDR-option seems a lot more convenient, in particular when locking the reception to the satellite's beacon. Transmission is stable enough, in my experience, so nothing to be bothered about.<br />As an added bonus of the SDR solution of the analogue way, there is signal processing available when using a computer for reception. </p><p>Further, I tried to use a Yaesu FT-790R2 as baseband up-link transmitter. It did work. However, there are two observations to share: 1) some weird spurious transmission were visible in A1A, 2) the audio in J3E was OK but not punchy at all.</p><p>Consequently, I will be using the Yaesu FT-817 as a baseband TX and the SDR receive setup, for the time being.</p><p><br /></p>Joachim Seiberthttp://www.blogger.com/profile/01766975824128341507noreply@blogger.comtag:blogger.com,1999:blog-3099598580812416162.post-84150688918200116962020-08-29T01:56:00.000+02:002020-08-29T01:56:20.458+02:00QO-100 A1A up-link idea<p>This is something I had in mind for quite some time by now. What about an A1A only up-link for QO-100?</p><p>This is an old idea. At the time, this idea was to create a CW transmitter for 70cm based of a 2m signal. I have seen similar attempts to get something transmitting on 3cm. So, why not on 13cm?</p><div>Having done some "maths", I came up with a carrier of 96MHz, which is available as a regular crystal.</div><p>With a factor of 25, this will result in a 2.4GHz frequency.</p><p>Now, why is that interesting? The multiplication of 25 can be achieved with 5 x 5 .... dahhhh. Yes, sounds simple enough. Here is the interesting thing, it should be easy with a square-wave oscillator to generate 480MHz. At this frequency, it is pretty easy to build a strip-line filter or cavity resonator to clean the signal. Now, we just have to multiply the signal again. So, we might want to use a non-linear amplifier again, in order to create all the wonderful harmonics. Again, a 2.4GHz resonator should not be to hard to build.<br />And here is the idea. What if we used a rather high powered amplifier at 480MHz, which is easy to build, and a non-linear element to generate all those harmonics at decent power.</p><p>With a VTCXO of 96MHz, slightly pulled by a few kHz, one should be easily creating a signal in the CW band of QO-100, using the above mentioned method.</p><p><br /></p>Joachim Seiberthttp://www.blogger.com/profile/01766975824128341507noreply@blogger.comtag:blogger.com,1999:blog-3099598580812416162.post-4914212758217650012020-08-29T01:31:00.006+02:002020-10-19T23:17:55.027+02:00QO-100 Up-link update<p> The last few days have seen a little bit of modification and optimization to my setup. Mainly, the shortening of the helix feed. While I was monitoring my A1A signal on the downlink, I gradually cut windings of the the uplink helix. I was not sure if I could see any difference in signal strength, to be honest. Anyway, I ended up with this:</p><table align="center" cellpadding="0" cellspacing="0" class="tr-caption-container" style="margin-left: auto; margin-right: auto;"><tbody><tr><td style="text-align: center;"><a href="https://blogger.googleusercontent.com/img/b/R29vZ2xl/AVvXsEjJxbPPbjN2IyBLWTh4rho4nny0LUphFBxkRb5y1Rsgv1C1pZpMfJ3H3xPj2UxDKwsmOjmY2bvzs0CN2XDSuCDKbDuwnlZeT5t_sMi91c0-cPytD5MWhsIJuRT6R8h5eCF02GP6j65PYMs/s800/qo100+-+UL%252BDL.jpg" style="margin-left: auto; margin-right: auto;"><img border="0" data-original-height="600" data-original-width="800" src="https://blogger.googleusercontent.com/img/b/R29vZ2xl/AVvXsEjJxbPPbjN2IyBLWTh4rho4nny0LUphFBxkRb5y1Rsgv1C1pZpMfJ3H3xPj2UxDKwsmOjmY2bvzs0CN2XDSuCDKbDuwnlZeT5t_sMi91c0-cPytD5MWhsIJuRT6R8h5eCF02GP6j65PYMs/s640/qo100+-+UL%252BDL.jpg" width="640" /></a></td></tr><tr><td class="tr-caption" style="text-align: center;">Downlink (left) and Uplink (right)</td></tr></tbody></table>The dishes are ducked down for a reason. This is my roof deck, we often experience heavy winds in the Netherlands. With the dishes sitting low, weighted down, the positions will be stable over the course of the year.<div><br /></div><div>Presently, the UL uses 10m of RG-6 cable, the original one with the hollow dielectric. This length is certainly not ideal. In the near future, I will build an outdoor unit, sitting next to the UL feed, housing the converter and the PA. This should improve my signal by some dB.</div><div><br /></div><div>For the time being, all I heard was that my signal could be stronger, but was fine to copy... what more do you want?</div><div><br /></div><div>73!</div><div><br /><p><br /></p></div>Joachim Seiberthttp://www.blogger.com/profile/01766975824128341507noreply@blogger.comtag:blogger.com,1999:blog-3099598580812416162.post-51057447085604295372020-08-25T06:52:00.002+02:002020-08-25T06:53:00.299+02:00SDR and the DJ-Tech DJ-Mouse<p>Here is what you have missed, if you are not in the world of DJs.<br />The DJ-Tech Mouse, which employs a super-nice big wheel in the center. Have a look:<br /><a href="https://djtechtools.com/2009/08/20/the-dj-mouse/">https://djtechtools.com/2009/08/20/the-dj-mouse/</a></p><p></p><div class="separator" style="clear: both; text-align: center;"><a href="https://images-sdj.netdna-ssl.com/D/DJ-Tech-DJ-Mouse-Includes-Deckadance-Traktor-Edition-with-Scratch-Controller-Jog-Wheel-detailed-image-3.jpg" imageanchor="1" style="margin-left: 1em; margin-right: 1em;"><img border="0" data-original-height="558" data-original-width="800" height="279" src="https://images-sdj.netdna-ssl.com/D/DJ-Tech-DJ-Mouse-Includes-Deckadance-Traktor-Edition-with-Scratch-Controller-Jog-Wheel-detailed-image-3.jpg" width="400" /></a></div>Guess what this wheel can be used for in any random SDR software.... a VFO.<p></p><p><br /></p>Joachim Seiberthttp://www.blogger.com/profile/01766975824128341507noreply@blogger.comtag:blogger.com,1999:blog-3099598580812416162.post-40958059341131843122020-08-25T01:11:00.002+02:002020-08-25T01:12:22.208+02:00QO-100 ground station update<p>My previous post show tons of opportunities for improvement. The more I was thinking about those, the closer I came to my initial gut feel, i.e. using a helix as a feed for the up-link dish.<br />In fact, the helix was sitting on my desk for quite some time by now. I had doubts how to mount the helix in the first place, also matching appeared to be a big deal, without the help of any decent GHz-capable measurement equipment.</p><p>However, seen that no matter what I did, I could not really improve the performance of the up-link. Essentially, I spent two entire night to find the best position of the dish. (Night-time, so nobody is on the satellite, avoiding to disturb more senior users)</p><p>When listening to traffic on Es'hail 2, I often heard that operators switched from patch feeds to helical feeds for their up-links and reported better results with those. Was my gut feeling correct?!</p><div>So, today, I returned to trusting my gut feeling. So I removed the patch from the weird reflector / holder shown in the last post. I used a small piece of PCB to form a base, essentially a mount, for the helix. Yes, I could pretend that this was a carefully calculated matching strip for matching my 75Ohm SatTV cable to the helix, but it wasn't. I dimensioned and adjusted the PCB just such that the helix would be - more or less - in the center of the reflector.</div><table align="center" cellpadding="0" cellspacing="0" class="tr-caption-container" style="margin-left: auto; margin-right: auto;"><tbody><tr><td style="text-align: center;"><a href="https://blogger.googleusercontent.com/img/b/R29vZ2xl/AVvXsEgDSueVjwDRAwSZche-J8Qz89-t5ODIbTJUwcgriYfKmawMYNG_FiJZsg2wVGLthK8t9cVDPILHDv096fh9p8pGp84t3sf2qFIKMEINQUzP7_NkuTTgVcbO9r-5XucERdyIPFP7zoqXE8I/s3648/IMG_20200825_001651.jpg" imageanchor="1" style="margin-left: auto; margin-right: auto;"><img border="0" data-original-height="2736" data-original-width="3648" height="480" src="https://blogger.googleusercontent.com/img/b/R29vZ2xl/AVvXsEgDSueVjwDRAwSZche-J8Qz89-t5ODIbTJUwcgriYfKmawMYNG_FiJZsg2wVGLthK8t9cVDPILHDv096fh9p8pGp84t3sf2qFIKMEINQUzP7_NkuTTgVcbO9r-5XucERdyIPFP7zoqXE8I/w640-h480/IMG_20200825_001651.jpg" width="640" /></a></td></tr><tr><td class="tr-caption" style="text-align: center;">note the remainders of glue where the patch was<br /></td></tr></tbody></table><p>Feel free to count the turns, which would result in a little of 6. My idea was, that I could always cut some off. It is much harder to cut wire on ;-)</p><p>The photo shows, it is night-time again. So, why not firing up the station and do some test transmissions?<br />And how right was my gut?!</p><table align="center" cellpadding="0" cellspacing="0" class="tr-caption-container" style="margin-left: auto; margin-right: auto;"><tbody><tr><td style="text-align: center;"><a href="https://blogger.googleusercontent.com/img/b/R29vZ2xl/AVvXsEi0qqQ7DbIY3hKoUhFiJpZa-NyYrv9mMkh8b_T1glnR0aJWAn2IAA9hOCOhKDwPjjEjpLwLNEqZFVKLHryF_Tr-buSqRiqV5iGhRhYe7g1X93E0GhqMpFMWwwbT60jYGNEGsZV6n4KrObg/s947/qo100+helix+feed.JPG" imageanchor="1" style="margin-left: auto; margin-right: auto;"><img border="0" data-original-height="362" data-original-width="947" src="https://blogger.googleusercontent.com/img/b/R29vZ2xl/AVvXsEi0qqQ7DbIY3hKoUhFiJpZa-NyYrv9mMkh8b_T1glnR0aJWAn2IAA9hOCOhKDwPjjEjpLwLNEqZFVKLHryF_Tr-buSqRiqV5iGhRhYe7g1X93E0GhqMpFMWwwbT60jYGNEGsZV6n4KrObg/s640/qo100+helix+feed.JPG" width="640" /></a></td></tr><tr><td class="tr-caption" style="text-align: center;">lower beacon at 69dBuV</td></tr></tbody></table><p>What a difference! My signal is now just 9dB weaker than the lower beacon!<br />Of course I had to do some side-band test. And yes, now I think I am QSO worthy.</p><p>The present setup still employs the "attenuator" made of about 10m of 70Ohm SatTV cable. So, as long as I still have not yet figured out how to build an outdoor unit (PSU,TX-converter and PA in a weather-proof box), I still will be able to do one or the other QSO.</p><p><br /></p>Joachim Seiberthttp://www.blogger.com/profile/01766975824128341507noreply@blogger.comtag:blogger.com,1999:blog-3099598580812416162.post-73249694216297834592020-08-21T02:29:00.005+02:002020-11-16T21:07:23.307+01:00QO-100 Es'hail-2 ground station<p>It has been a while since I was busy with a ground station for the geosynchronous (geostationary) satellite Es'hail-2 also known as Qatar Oscar 100 or QO-100.</p><p>The major delay in the beginning of the project was to receive an assortment of coax adapters. Finally, those were in, now, the down-link was sorted rather quickly. There was a disused 35cm dish, which I used to analog ASTRA reception. When ASTRA satellites turned digital, I lost interest in watching those, so I never upgraded the equipment. Although, I never dumped any of that stuff either.</p><p>So, here was my down-link receiver, PLL-LNB with the old 35cm dish in a FUNcube SDR dongle. That worked perfectly. I later replaced the FUNcube dingle with an SDRplay RSP1A, so that I could receive the entire bandwidth of QO-100's narrow band transponder, allowing for locking on the mid-beacon for frequency stabilization.</p><p>Concerning the up-link, I decided to go for a DXpatrol converter. I like the possibility to select the baseband, although, I will probably stick with 432MHz.<br />To amplify the 2.4GHz signal, I went for the omni-present chinese 8W WiFi-PA.</p><p>Then came a long struggle of what to do about the up-link hardware.<br />Initially, I considered an RHCP helical antenna, something in the realm of 15 to 20 turns.<br />Then I found a 60cm offset dish in the trash. So, what about a 4 to 6 turn LHCP feeding helix? And yes, I wound that thing. But, the mechanical details of holding the thing in place put me off again.<br />Finally, I decided on a K3TX LHCP patch feed for the 60cm dish. <br />I know, 60cm is rather small for a 13cm wavelengnth... 10 lambda upwards make the deal... I know. However, 60cm is what I got.</p><p>The dish I got had not LNB/feed mounting hardware, so this is what I came up with.</p><table align="center" cellpadding="0" cellspacing="0" class="tr-caption-container" style="margin-left: auto; margin-right: auto;"><tbody><tr><td style="text-align: center;"><a href="https://blogger.googleusercontent.com/img/b/R29vZ2xl/AVvXsEiqM1ZXXCgKr9HcCXmk0Be7LUl9TxY6A58GJEnQZu9QegGhbvGuLaYmsxfps4c5IUNToIEfJqhYERp3h5iZO054JTLly55rXZnKpiRctDd6WIajBLaeZ1R75cBRwYQI19MtbjMmLH9HFIM/s3648/IMG_20200819_145039.jpg" style="margin-left: auto; margin-right: auto;"><img border="0" data-original-height="2736" data-original-width="3648" height="300" src="https://blogger.googleusercontent.com/img/b/R29vZ2xl/AVvXsEiqM1ZXXCgKr9HcCXmk0Be7LUl9TxY6A58GJEnQZu9QegGhbvGuLaYmsxfps4c5IUNToIEfJqhYERp3h5iZO054JTLly55rXZnKpiRctDd6WIajBLaeZ1R75cBRwYQI19MtbjMmLH9HFIM/w400-h300/IMG_20200819_145039.jpg" width="400" /></a></td></tr><tr><td class="tr-caption" style="text-align: center;">K3TZ LHCP patch, PCB over Al</td></tr></tbody></table><p>You may wonder what the strange structure to the left is, this will be the mount to the dish.<br />Something not obvious from the above picture, I am using a F-connector for this feed.<br />Please note that this picture was taken before I filed down the edges to of the reflector to the circle seen scratched into the aluminium sheet.</p><table align="center" cellpadding="0" cellspacing="0" class="tr-caption-container" style="margin-left: auto; margin-right: auto;"><tbody><tr><td style="text-align: center;"><a href="https://blogger.googleusercontent.com/img/b/R29vZ2xl/AVvXsEhOYtgBs0CuveCxjGhaAstjc2Wq0Vwno23VUMBoPqu-avgcC24whZ5yFg5VKhzUblmbM_GqCCWx9Ztvee8OFbn6LB88m2X2MsxGysAIM-mpgGDZU-qu6Zy3PUeVDA7ezFz0S1QpL0-rX3U/s3648/IMG_20200819_172019.jpg" style="margin-left: auto; margin-right: auto;"><img border="0" data-original-height="2736" data-original-width="3648" height="300" src="https://blogger.googleusercontent.com/img/b/R29vZ2xl/AVvXsEhOYtgBs0CuveCxjGhaAstjc2Wq0Vwno23VUMBoPqu-avgcC24whZ5yFg5VKhzUblmbM_GqCCWx9Ztvee8OFbn6LB88m2X2MsxGysAIM-mpgGDZU-qu6Zy3PUeVDA7ezFz0S1QpL0-rX3U/w400-h300/IMG_20200819_172019.jpg" width="400" /></a></td></tr><tr><td class="tr-caption" style="text-align: center;">The patch feed added to the up-link dish<br /></td></tr></tbody></table><p>Winds can be pretty strong over here, so I mounted the dish to a concrete parasol stand.</p><p><br /></p><table align="center" cellpadding="0" cellspacing="0" class="tr-caption-container" style="margin-left: auto; margin-right: auto;"><tbody><tr><td style="text-align: center;"><a href="https://blogger.googleusercontent.com/img/b/R29vZ2xl/AVvXsEis4E1GSRhOO8acSDOtqKI-cLqVFNkYyC2QYUQ3DMF_XW0HgVmu5kkbrxmNRLzPlBRR2bGuoj6ryoqjfYPEPueGwN5nCiG1luZMlsv0hze8AWiP_MkSwgboowzJCQuhABHGG4mRbhLzqKY/s3648/IMG_20200819_172039.jpg" style="margin-left: auto; margin-right: auto;"><img border="0" data-original-height="3648" data-original-width="2736" height="400" src="https://blogger.googleusercontent.com/img/b/R29vZ2xl/AVvXsEis4E1GSRhOO8acSDOtqKI-cLqVFNkYyC2QYUQ3DMF_XW0HgVmu5kkbrxmNRLzPlBRR2bGuoj6ryoqjfYPEPueGwN5nCiG1luZMlsv0hze8AWiP_MkSwgboowzJCQuhABHGG4mRbhLzqKY/w300-h400/IMG_20200819_172039.jpg" width="300" /></a></td></tr><tr><td class="tr-caption" style="text-align: center;">Up-link (grey) and down-link (white)<br /></td></tr></tbody></table><p>Note that both channels are using 75Ohms satellite cable. While for the down-link this is fine, the up-link will experience this as an attenuator, in particular over the length I am using for this experimental setup (about 20m).</p><p>Having done some experiments, I could hear my signals in both CW and SSB (USB). While CW was easy, single side band was somewhat challenging. I would not count for any SSB QSO with the attenuator in place.<br />However, CW should be just fine. Have a look how the signal compares to the lower beacon:</p><table align="center" cellpadding="0" cellspacing="0" class="tr-caption-container" style="margin-left: auto; margin-right: auto;"><tbody><tr><td style="text-align: center;"><a href="https://blogger.googleusercontent.com/img/b/R29vZ2xl/AVvXsEj7GsAnadoAJxePBnAD_i_ifZD19nFr2_27POtqjCfuAAEC8iIO3En_OH0NqCBfqZ_hyB2L8HEtQNb8KVKVYhtQvxCwNjoRW0vmbIC1ricdJFTGGTIkNGhhg_GtOJfpDV1JQRK_EKEpWA0/s1273/uplink_downlink.jpg" style="margin-left: auto; margin-right: auto;"><img border="0" data-original-height="768" data-original-width="1273" src="https://blogger.googleusercontent.com/img/b/R29vZ2xl/AVvXsEj7GsAnadoAJxePBnAD_i_ifZD19nFr2_27POtqjCfuAAEC8iIO3En_OH0NqCBfqZ_hyB2L8HEtQNb8KVKVYhtQvxCwNjoRW0vmbIC1ricdJFTGGTIkNGhhg_GtOJfpDV1JQRK_EKEpWA0/s640/uplink_downlink.jpg" width="640" /></a></td></tr><tr><td class="tr-caption" style="text-align: center;">Lower beacon and pa1gsj carrier<br /></td></tr></tbody></table><p>This was my first day of bouncing signals from QO-100. I know what I need to do now, i.e. building an outdoors cabinet next to the up-link dish.</p><p>I hope to be QRV as an audible station on Es'hail-2 soon.</p><p><br /></p><p><b>Update</b></p><p>After further improvements, I can now provide relative signal strengths from my receive setup:<br /></p><ul style="text-align: left;"><li>transponder noise about 32 dBuV</li><li>CW beacon 58 dBuV</li><li>my own signal 41 dBuV</li></ul><div>I can also report that I made two CW contacts by now, the lower report was 589. </div><div><br /></div><p></p>Joachim Seiberthttp://www.blogger.com/profile/01766975824128341507noreply@blogger.comtag:blogger.com,1999:blog-3099598580812416162.post-42745326049915919502020-05-14T22:20:00.002+02:002020-05-14T22:22:34.043+02:00Boom boom pafffffSomething totally off topic today, OK, it's audio, no electronics involved however.<br />
<br />
IKEA is known for some interesting projects here and there, beyond the famous bookshelf. Lately, they introduced a product range which appears to be a collection of random stuff, the collection being "<a href="https://www.ikea.com/nl/en/search/products/?q=FREKVENS" target="_blank">FREKVENS</a>". There are even products that could be interesting for a blog concerned with electronics. No worries, I wont be writing about a silver rain coat or a silver cushion cover either.<br />
Let's have a closer look at the only real IKEA flat pack product in the collections, the <a href="https://www.ikea.com/nl/en/p/frekvens-cajon-drum-plywood-40420297/" target="_blank">FREKVENS Cajón (drum)</a>.<br />
No, this is not a drum, this is a cajón, and instrument well known in Spanish and Afro-Cuban music. A cajón can create sounds similar to various parts of a drum kit, which is a matter of great skill, which I don't have.<br />
There are a few more things wrong in the product listing, at least what the images are concerned. The side with the big whole is the back-side (or reverse, depending on your style of English). Hence, the guy in the photo sits on it the wrong way. Also, he appears to be slapping the sides of the instrument, which are made of much thicker material and not supposed to be the main playing surface.<br />
<br />
Anyways, I bought one of those flat-pack instrument kits and build it according to the provided instructions. BIG mistake! The more I learn about the instrument, the more obvious this should have been.<br />
The assembly instructions take a similar order to something like a nightstand. Which, seen from IKEA's perspective, does make sense. However, when following the leaflet, it is almost inevitable to create a misaligned box that does not sound right.<br />
<br />
<u>Step 1</u><br />
The instructions start with mounting the snares to the (front of the) bottom-plate, so far so good.<br />
<br />
<u>Step 2</u><br />
The side-walls are screwed to the bottom-plate. This is the first instance where things can go wrong. The alignment of the outer edges of bottom-plate and side-walls needs to be precise. This might not be that important on the bottom-plate, desirable however.<br />
<br />
<u>Steps 3 and 4</u><br />
According to the instructions, the top-plate is now mounted to the side walls, very similar to bookshelves, nightstands, etc. I cannot emphasize enough, <b>don't do this yet</b>. I did it and I ended up with a slightly misaligned top-plate. This misalignment kills the instrument!<br />
<br />
<u>Step 5</u><br />
In this step, the playing surface, i.e. the front, is mounted. Remember, the front is where the snares are. This is very important for the functioning of the instrument and not clear from the instructions.<br />
This step should be done after step 2, if not before...<br />
If you followed up to now, you will understand that it is important to not tie down any of those screws yet.<br />
<br />
<u>Step 6</u><br />
Here, the back-plate of the cajón is screwed to what we assembled so far. Please note, we skipped steps 3 and 4, so there wont be any (I should have written about that in step 5, sorry!).<br />
<br />
<u>Final assembly according to me</u><br />
If you followed my advice, you skipped steps 3 and 4. What you should have by now should be a square wobbly bucket with no lid.<br />
At this stage, carefully work the top-plate into its position. This might be a bit tricky, therefore, we did not tighten those screws. Once the top-plate is in place, we want to first tighten the screws of the front-plate including the ones we skipped. This will auto-align the top-plate to the side-walls. This alignment is most important to the good functioning of the instrument.<br />
Once this alignment is established, screw down and tighten the 2 front screws on the top and the side-walls.<br />
Now apply all the remaining screws. And tighten all screws on the back and the lower half of the screws on the front.<br />
<br />
<u>Tune up</u><br />
In case of all screws being tight, you will have to hit the cajón very hard to get the snare effect. This will result in an imbalance between the snare and the bass drum sounds.<br />
Therefore, what you are looking for is a small gap between the top-plate and the front-plate. To realize a somewhat even gap to your liking, you have 5 screws in the top half of the front-plate to play with, i.e. loosen and tighten. Every little bit of tension here and there will change the tone and snare sound created by the cajón. It took me a while to balance the right and left corners of the upper playing surface.<br />
<br />
<u>Conclusion</u><br />
IKEA is good in creating wooden flap-pack products. The FREKVENS Cajón is no exception, when built and aligned correctly.<br />
There are competing products available from musical instruments suppliers, here is an <a href="https://www.thomann.de/ie/thomann_cajon_construction_kit.htm?ref=intl&shp=eyJjb3VudHJ5IjoiaWUiLCJjdXJyZW5jeSI6IjIiLCJsYW5ndWFnZSI6ImVuIn0%3D&glp=1" target="_blank">example</a>. This example supposedly requires additional materials for assembly, although at a lower price.<br />
What I am concerned, after having aligned my cajón, I am pretty happy with the sounds it can create and look forward to learning this instrument.<br />
<br />
<br />
<u><br /></u>Joachim Seiberthttp://www.blogger.com/profile/01766975824128341507noreply@blogger.comtag:blogger.com,1999:blog-3099598580812416162.post-88852657857856010722020-04-22T00:26:00.000+02:002020-04-22T00:26:16.387+02:0060m Region 1 Crystal CombinationSorry for having been silent for so long. There was a lot going on over the last few years.<br />
<br />
Anyway, the present situation brought me back to Ham Radio and thinking of building stuff. However, I have to mention that this post should be considered more as a note to myself or inspiration of fellow RF designers, rather than a fully worked out recipe.<br />
<br />
The topic of one of my next projects will be building some QRP rig for 60m. Over here in the Netherlands and in Region 1, we got a very small slot from 5351.5kHz to 5366.5kHz assigned as secondary service with a maximum EIRP of 15W. This is a range which appears to me to be almost ideal for building some QRP gear.<br />
In modern times, we could use DDS systems to get us anywhere with anything, I must admit. In the older days, using combinations of readily available inexpensive crystals was the #1 choice for QRP.<br />
Whilst having CW in mind, some of my thoughts my actually be useful for a side-band superhet design.<br />
<br />
Here is what I found:<br />
<br />
<ul>
<li>15.360 MHz crystals for use in a VXO (or superVXO)</li>
<li>10.000 MHz crystals and oscillators for BFO and filter stages.</li>
</ul>
<div>
To be honest, I just cooked up the idea and have not thought is through entirely. But here is what my mind came up right away.</div>
<div>
As a side remark, subtractively mixing of crystal oscillators is a well known method of eliminating temperature drifts. So, effectively, this could lead to very stable designs, when done properly.</div>
<div>
<br /></div>
<div>
<b>Transmitter</b></div>
<div>
Option A is a canned 10.000MHz oscillator and push the signal through a 10MHz crystal in order to produce a sine wave.</div>
<div>
Option B would be a regular crystal controlled discrete beat oscillator.</div>
<div>
Mix any of option A or B with a 15.360MHz VXO to generate a 5.360MHz output signal. Should the pull be insufficient (not very likely at 15MHz) one could still use a superVXO.</div>
<div>
<br /></div>
<div>
<b>Receiver</b></div>
<div>
Here is where the concept presently struggles. </div>
<div>
Of course you would think building a crystal filter with inexpensive 10MHz crystals. However, this would probably exclude option A for the TX. Here is where the struggle lies, would it be possible to create a filter design with 10.000MHz crystals that pulls 600 or 800Hz away?</div>
<div>
When using option B for the TX, of course, one would add a simple RIT design.</div>
<div>
<br /></div>
<div>
<b>CW</b></div>
<div>
You have seen me writing about two different options. Why bother, you might ask yourself. Well, to me, it is all about simplicity. </div>
<div>
For a mere transmitter, in option A, I might just use a canned 10.000MHz high precision oscillator and key just said oscillator, rather than a buffer stage for CW operations. Experimentation will have to show how that sounds. In terms of simplicity, this would be pretty neat. Such a TX could be combined with some sort of SDR receiver or maybe a Polyakov direct conversion RX based on a 2.68MHz VFO.</div>
<div>
Option B would allow for a fairly regular QRP CW transceiver. Nothing to write home about, however, this will certainly be a more complex design.</div>
<div>
<br /></div>
<div>
<b>SSB</b></div>
<div>
Obviously, option A is no longer available here. However, seen that it is recommended to use USB on the Region 1 assigned 30m band, it would be an obvious measure to use a pulled 10MHz BFO for both RX and TX. However, mind the mirror, we are subtractively mixing here.</div>
<div>
Having in mind the upper portion of the 60m band, i.e. the weak signal band from 5366.0 to 5366.5kHz, option A might just come into play again. Mind you, QRSS & Co, don't mind about the sideband too much, as long as the operator knows what she/he is doing.</div>
<div>
<br /></div>
<div>
Over the upcoming days, I will work on a concept/prototype and hopefully will be able to report on some progress soon.</div>
<div>
</div>
<br />
<br />
<br />Joachim Seiberthttp://www.blogger.com/profile/01766975824128341507noreply@blogger.comtag:blogger.com,1999:blog-3099598580812416162.post-31715696063027548592019-06-15T21:12:00.000+02:002019-06-15T21:12:40.916+02:00Portable Stereo StageThis channel has been silent for some time by now, sorry for that! Will be getting more active in the near future.<br />
While this blog started as a RF only outlet, slowly I drifted to all sort of electronics, including speaker enclosure designs using PVC piping material. Yes, those pipes are still in my living room, connected to a class A tube amplifier and fed by some CD players. While sounding pretty good, this is not really portable per se, although, seen against cement speaker enclosure, this is probably relatively portable.<br />
Travelling back and forth nowadays, I was searching for an alternative.<br />
<br />
Lately, I found said alternative. Got a couple of JBL Flip 4 BT speakers. Those are connected to my phone using BT.<br />
<br />
Those JBL Flip 4 BT speakers can be used as a pair of stereo speakers. Not having read any instructions, I took me some to to figure out how to actually create that stereo stage. Having tested the setup with different kind of listening, from Vivaldi over Herbie Hancock to Dream Theater, I am deeply impressed!<br />Seen that the setup is that small and inexpensive that fact that I could not find any flaw in the sound experience tells me that I found my next stereo system.<br />
Although in comparison to my tube class A amplifier, some additional noise is evident.<br />
<br />
For aesthetic reasons, I chose both Flip 4s to be black. Of course this makes them a little bit more difficult to setup in the right way. A small sticker indicating which is left and which is right should not be a bit deal however.<br />
<br />
If you can live with a little bit of pink noise, a setup of dual JBL Flip 4 speakers is highly recommended.<br />
<br />
<br />Joachim Seiberthttp://www.blogger.com/profile/01766975824128341507noreply@blogger.comtag:blogger.com,1999:blog-3099598580812416162.post-14897357312714896032018-04-08T21:52:00.000+02:002018-04-08T21:52:40.617+02:00PVC Tubes Driven by TubesDear reader,<br />
<br />
please accept my apologies for keeping you in suspense over my latest projects for so long. 2017 was a very intense year for me. During said year, I changed my day-jobs twice, so, the radio hobby and the audio hobby had to take a break. Concerning jobs, I believe to have finally found the position of my dreams with a lot a really nice people in the company... I believe I have never been happier before!<br />
Anyway, this is not about life, this is about driving tubes, PVC that is, with tubes, such as in vacuum.<br />
<br />
My pipe dreams, as you know, are employing 3W (8Ohms) broadband drivers, which came with a super-cheap set. By now, I am convinced that those drivers were the most valuable part in the entire kit.<br />
<br />
In search for a 2 x 3W class A amplifier, I came across a Chinese kit supplier (Douk Audio, cf. ebay), who sells single-ended class A amp kits based on 6N1 and 6P1 tubes. Said kits are comparably inexpensive and, while provide good quality parts, come without a mains-transformer.<br />
<br />
My choice of mains transformer fell on a 100W transformer offered by a supplier in the UK, search for "big.daddy!" on ebay.<br />
<br />
The combo works as a charm! The amplifier kit seems to be made for my pipe dreams.<br />
<br />
As an audio source, I am presently using a professional grade table top DJ CD player by Numark.<br />
In the future I consider to add a passive equalizer / tone control circuit to the setup in order to allow for compensating deficits from compressed digital audio formats. For now, I am pretty pleased with the raw performance from CDs.<br />
<div>
<br /></div>
Joachim Seiberthttp://www.blogger.com/profile/01766975824128341507noreply@blogger.comtag:blogger.com,1999:blog-3099598580812416162.post-16330037204158063822017-02-11T21:39:00.001+01:002017-02-11T21:40:07.742+01:00More Pipe Speaker ImprovementsThe last issue I had with all of my PVC-Voigt-Pipes: resonance of the horn. I read about it, I knew about it... and now, I was bugged by it too.<br />
<br />
The solution is very simple: a tripe of cleaning cloth, just below the joint of the driver unit to the horn. The effectiveness of which can be tested by slapping a flat hand on either end of the horn. Without the damping cleaning cloth sound would resonate creating some BOONNNNNG BOONNNNG. With the cloth inserted, this changes to BooB BooB.<br />
<br />
BTW, this was effective with the designs I published on this blog.<br />
<br />Joachim Seiberthttp://www.blogger.com/profile/01766975824128341507noreply@blogger.comtag:blogger.com,1999:blog-3099598580812416162.post-49480910315520336092017-01-21T22:02:00.001+01:002017-01-21T22:02:14.351+01:00Pipe Dreams revampedMy prototype pipes always lacked a certain tonal depth. In the past, I laid that down by the fact that I was using 2" pipes (<a href="http://draaggolf.blogspot.nl/2014/03/pipe-dreams-xxl.html" target="_blank">have a look</a>).<br />
The drivers I was using to that time came from a TV set. While this drivers taught me a lot and enabled some experimenting, which lead to the latter <a href="http://draaggolf.blogspot.nl/2014/03/3-inch-hifi-pvc-pipe-alphorn-mltqwp.html" target="_blank">3" design</a>, which sits in my living room, now in a <a href="http://draaggolf.blogspot.nl/2016/07/pvc-pipe-dreams-updated-design-audio.html" target="_blank">folded</a> manner.<br />
Strangely, the 3" drivers seem not to be of that much better quality... however, the 3" setup a much butter punch in all aspects.<br />
<br />
Willing to further experiment with the PVC prototypes, I ordered a pair of 2" 3W drivers, similar to <a href="http://www.banggood.com/2-Inch-4Ohm-4-3W-Full-Range-Audio-Stereo-Woofer-Speaker-Loudspeaker-p-1005600.html" target="_blank">those</a>.<br />
Yep, those cost next to nothing. They sound surprisingly good when driving my folded "XXL PVC" prototypes.<br />
<br />
The question remains if it would be worth to further fold the pipes for improved portability.<br />
<br />Joachim Seiberthttp://www.blogger.com/profile/01766975824128341507noreply@blogger.comtag:blogger.com,1999:blog-3099598580812416162.post-60234346992711629442016-07-24T23:29:00.000+02:002016-07-24T23:29:08.065+02:00PVC Pipe Dreams updated design (audio)My PVC Voigt pipe speakers were in heavy use during the last 2 years. My study allows for housing those slim monsters.<br />
<br />
Anyway, I found 2 problems with them:<br />
<br />
<ol>
<li>too tall</li>
<li>very directional</li>
</ol>
<div>
So, very easily, since those things are all pipes, I slightly changed the design. Have a look!</div>
<div>
<br /></div>
<table align="center" cellpadding="0" cellspacing="0" class="tr-caption-container" style="margin-left: auto; margin-right: auto; text-align: center;"><tbody>
<tr><td style="text-align: center;"><a href="https://blogger.googleusercontent.com/img/b/R29vZ2xl/AVvXsEjbWu7s-uiWvICZZNRn8Qr5qKGCdn0BGmx-_oGYVjHzcHMWtjle1I9i5HtFguUg41jm9F6bXz-0r4Hb3_-P00bwxSj9gNfxH8hLdsXL6ABTpPw7DSyuZb8jqoXWLdSqMuGlu5gM8P3IbdY/s1600/L1030192.jpg" imageanchor="1" style="margin-left: auto; margin-right: auto;"><img border="0" height="216" src="https://blogger.googleusercontent.com/img/b/R29vZ2xl/AVvXsEjbWu7s-uiWvICZZNRn8Qr5qKGCdn0BGmx-_oGYVjHzcHMWtjle1I9i5HtFguUg41jm9F6bXz-0r4Hb3_-P00bwxSj9gNfxH8hLdsXL6ABTpPw7DSyuZb8jqoXWLdSqMuGlu5gM8P3IbdY/s400/L1030192.jpg" width="400" /></a></td></tr>
<tr><td class="tr-caption" style="text-align: center;">modified PVC Voigt pipe design</td></tr>
</tbody></table>
<div>
To reduce the length, I changed the position of the speaker in the T-piece and added an elbow to bend the resonator parallel to the the horn. The above image shows the 2 different designs I posted earlier.</div>
<div>
<br /></div>
<div>
Also, I inverted the orientation of the full range drivers. There are some advantages:</div>
<div>
<ul>
<li>the drivers breathe directly into the resonator (similar to the folded TQWT)</li>
<li>the direct audio of the driver is less directional</li>
<li>the drivers are better protected</li>
</ul>
<div>
As a first observation I would like to mention that treble and bass seem prominently present in the horn, while the mids are emitted by the driver directly.</div>
</div>
<div>
As a consequence, that could mean that the horn should be above the driver, since the stereo field is determined by high frequencies.</div>
<div>
The next step would be to put a wooden box around the T-piece driver part of the design. This way, the contraption can be held upright and all the ugly part would be hidden away nicely.</div>
<div>
<br /></div>
<div>
If it all seems rubbish what I write about PVC plumbing, give it a try yourself. All parts are readily available in your local hardware store. </div>
<div>
<br /></div>
<div>
Concerning the inverted speakers, I am not yet sure myself. However, for the time being they appear to create a pleasant listening experience.</div>
<div>
<br /></div>
Joachim Seiberthttp://www.blogger.com/profile/01766975824128341507noreply@blogger.comtag:blogger.com,1999:blog-3099598580812416162.post-29265275588486176762015-07-12T00:35:00.001+02:002015-07-12T00:35:47.820+02:00The Mobile ShackFollowers of my <a href="http://homebrew-it.blogspot.com/" target="_blank">IT blog</a> already are aware of the fact that I am fitting out a worker's van for camping and other spare time activities.<br />
Over the last years (maybe even decade) I was neglecting my radio hobby. The van is meant to be one of the remedies. It is presently arranged to survive a few days in it, however, the van still lacks radio equipment.<br />
<br />
<br />
Readily available options are the following:<br />
<ul>
<li>20m PSK as base gear</li>
<li>the 20m Pex-Al-Pex loop</li>
<li>fishing-pole elevated dipole</li>
<li>30m PSK for mail </li>
<li>TenTec Scout #555 (low power consumption and punchy audio)</li>
<li>Icom IC-M710 (even punchier audio) w/ respective auto-tuner</li>
<li>Vertex Standard VX-1700</li>
<li>PCT-IIe </li>
</ul>
<br />
Further thoughts add digital radio such as D-STAR or DMR. Since I got zero experience in that field, I just started my research. As appealing the digital world is, as confusing it is!<br />
<br />
<br />
Presently, I am somewhat sure about the computing device I will use:<br />
<ul>
<li>HP Stylistic ST4120</li>
<li>respective docking station</li>
<li>respective 12V power supply </li>
</ul>
<br />
This thing presently runs WinXP. Years ago, I bought this thing (used) to be the board computer of my sailing boat. For unknown reasons, the PC never made it aboard. <br />
<br />
<br />
Things I need to do before getting serious with radio in the van:<br />
<ul>
<li>install one or more service batteries</li>
<li>install a charger for the service batteries</li>
<li>install a VHF/UHF antenna</li>
<li>solar panels?</li>
<li>create an RF-ground device </li>
</ul>
<br />
The van also needs a decent WiFi solution. I presently research the possibilities.<br />
<br />
BTW, the van is a Mercedes-Benz Vito (2008). Some told me that Vito's are supposed to be like regular cars. Well, driving one, I can tell you that the allover feel of a Vito is more like driving a semi than a people carrier.<br />
<br />
73 for now, stay tuned....<br />
<br />Joachim Seiberthttp://www.blogger.com/profile/01766975824128341507noreply@blogger.comtag:blogger.com,1999:blog-3099598580812416162.post-35129472608491696722014-04-02T00:02:00.001+02:002017-04-20T20:04:00.132+02:00Finally: The PEx/Al/PEx Loop!Yeah, that was a good one today. I took a couple of hours for tinkering and finally got to build my long planned magnetic loop aerial made from the recently discovered light weight copper substitute PEx/Al/PEx.<br />
<br />
As previously mentioned, RG213 snug fits into the tubing material. This gave me the idea to actually slide in the coax cable in order to form a Galvanically isolated capacitor. Two reasons not wanting connect anything electrically to the aluminum: 1) it is nearly impossible to solder and 2) it will corrode in rapid rate.<br />
<br />
As a result, the coax needs to be inserted in both open end of the loop, thereby closing the same capacitively. In principle this is like any other magnetic loop using a butterfly capacitor.<br />
Just to remind you, this means that 2 capacitors are in series, i.e. they don't add up their capacities, they do this instead:<br />
<div class="separator" style="clear: both; text-align: center;">
<a href="https://blogger.googleusercontent.com/img/b/R29vZ2xl/AVvXsEi5dBeB5fqIVUHdGeiQcBkqSfubkatVkpDvWSm8I3kWORcbUtvaMz0cQm3hcNb0hbAin9PcLYOBTL0_bLqS5ONKF-QrL-RqUCcCGhQUZz8tqCQ7rGvXgAjEih6XXbH0OQDYLd254qHZ8i0/s1600/series_C.png" imageanchor="1" style="margin-left: 1em; margin-right: 1em;"><img border="0" height="153" src="https://blogger.googleusercontent.com/img/b/R29vZ2xl/AVvXsEi5dBeB5fqIVUHdGeiQcBkqSfubkatVkpDvWSm8I3kWORcbUtvaMz0cQm3hcNb0hbAin9PcLYOBTL0_bLqS5ONKF-QrL-RqUCcCGhQUZz8tqCQ7rGvXgAjEih6XXbH0OQDYLd254qHZ8i0/s1600/series_C.png" width="200" /></a></div>
with C<span style="font-size: x-small;">r</span> being the right capacitor and C<span style="font-size: x-small;">l</span> the left capacitor.<br />
<br />
There is a second benefit from series capacitors (in magnetic loops), they act a voltage dividers, thereby increasing the sparkling maximum voltage, allowing for higher power, in particular in the case of magnetic loop aerials.<br />
<br />
Back to the capacitance story: the butterfly capacitor symmetrical, i.e. both capacitor have the same capacitance. What if the use variable capacitors having different capacitances?<br />
Lets go through this with an example:<br />
Assume that:<br />
C<span style="font-size: x-small;">r</span> = 10pF<br />
C<span style="font-size: x-small;">l</span> = 100pF<br />
What will be the change in 1pF on either capacitor on the resulting capacitance?<br />
<ul>
<li>no change: (10*100)/(10+100) = 1000/110 = 9.091</li>
<li>C<span style="font-size: x-small;">l</span> lowered by 1pF: (10*99)/(10+99) = 990/109 = 9.083</li>
<li>C<span style="font-size: x-small;">r</span> lowered by 1pF: (9*100)/(9+100) = 900/109 = 8.257</li>
</ul>
Very obviously changing the higher capacitance has less influence than changing the lower capacitance.<br />
<br />
And this is a fact I make use of in my most recent design: a magnetic loop aerial with an asymmetric series of capacitors.<br />
<br />
Pictures say more than words: <br />
<br />
<table align="center" cellpadding="0" cellspacing="0" class="tr-caption-container" style="margin-left: auto; margin-right: auto; text-align: center;"><tbody>
<tr><td style="text-align: center;"><a href="https://blogger.googleusercontent.com/img/b/R29vZ2xl/AVvXsEginRXOAK2K-X33RSwg8bOF_i42oLN2ktVVo6cn3s8sQZFJpNJhe1KhIhqmD3jfpv-50zWBH0yVlXymrXDHA4AyLXCnlu1jYhlM9hMD_XJ8BimKpjDek0CTCxKaSuvbjUDPwX4GqgQI6_Q/s1600/capacitor_2.png" imageanchor="1" style="margin-left: auto; margin-right: auto;"><img border="0" height="110" src="https://blogger.googleusercontent.com/img/b/R29vZ2xl/AVvXsEginRXOAK2K-X33RSwg8bOF_i42oLN2ktVVo6cn3s8sQZFJpNJhe1KhIhqmD3jfpv-50zWBH0yVlXymrXDHA4AyLXCnlu1jYhlM9hMD_XJ8BimKpjDek0CTCxKaSuvbjUDPwX4GqgQI6_Q/s1600/capacitor_2.png" width="400" /></a></td></tr>
<tr><td class="tr-caption" style="text-align: center;">Fig.1: asymmetric series of capacitors (purple) terminating a magnetic loop</td></tr>
</tbody></table>
<br />
<table align="center" cellpadding="0" cellspacing="0" class="tr-caption-container" style="margin-left: auto; margin-right: auto; text-align: center;"><tbody>
<tr><td style="text-align: center;"><a href="https://blogger.googleusercontent.com/img/b/R29vZ2xl/AVvXsEhHt59dGH628S8eLL4XoyM8UIQyioTws2D3iA6E1z44oG3AZHvnGzdWGGRq3agDYhjosDSjhZQF_gE-B3oIyjb1Ee5NhKBTtLRpEMuzEUidNa_n5_cF43pykrJB8deu_WnQcMlFg2tDB5Y/s1600/loop_C.png" imageanchor="1" style="margin-left: auto; margin-right: auto;"><img border="0" height="298" src="https://blogger.googleusercontent.com/img/b/R29vZ2xl/AVvXsEhHt59dGH628S8eLL4XoyM8UIQyioTws2D3iA6E1z44oG3AZHvnGzdWGGRq3agDYhjosDSjhZQF_gE-B3oIyjb1Ee5NhKBTtLRpEMuzEUidNa_n5_cF43pykrJB8deu_WnQcMlFg2tDB5Y/s1600/loop_C.png" width="400" /></a></td></tr>
<tr><td class="tr-caption" style="text-align: center;">Pic.1: real life look of the terminating capacitance</td></tr>
</tbody></table>
<div class="separator" style="clear: both; text-align: center;">
</div>
<table align="center" cellpadding="0" cellspacing="0" class="tr-caption-container" style="margin-left: auto; margin-right: auto; text-align: center;"><tbody>
<tr><td style="text-align: center;"><a href="https://blogger.googleusercontent.com/img/b/R29vZ2xl/AVvXsEiUVxjcTWWCnJh4QE9BoWSVLsErUT9FTycPo70jm2PINbv3gR_cUxHvTvr0hNwBMYzVT4ems_Ibd3YoYSr4ZSuswwWm8GrjEGVmVHb5vM6sONHw2aN9EkfAXXvVsft9GJ5uizhveZXftyk/s1600/capacitor.png" imageanchor="1" style="margin-left: auto; margin-right: auto;"><img border="0" height="193" src="https://blogger.googleusercontent.com/img/b/R29vZ2xl/AVvXsEiUVxjcTWWCnJh4QE9BoWSVLsErUT9FTycPo70jm2PINbv3gR_cUxHvTvr0hNwBMYzVT4ems_Ibd3YoYSr4ZSuswwWm8GrjEGVmVHb5vM6sONHw2aN9EkfAXXvVsft9GJ5uizhveZXftyk/s1600/capacitor.png" width="400" /></a></td></tr>
<tr><td class="tr-caption" style="text-align: center;">Fig.2: Dimensions used for the 20m band, blueish stuff being RG213</td></tr>
</tbody></table>
<br />
<table align="center" cellpadding="0" cellspacing="0" class="tr-caption-container" style="margin-left: auto; margin-right: auto; text-align: center;"><tbody>
<tr><td style="text-align: center;"><a href="https://blogger.googleusercontent.com/img/b/R29vZ2xl/AVvXsEirGw0WeK1ftQCD23-xu9SKCnf4GelyBBnJ8tG-dhiizlaj_QlSWAM6_tmcyF6N4HTp-r9h9Qw_T-Wy8Hm_2gKnUolTB-xoYnlzPKTWLXVBAwu2LK1yAE0EsRf4VCIsufpba6YiDdDYrgM/s1600/loop_C_open.png" imageanchor="1" style="margin-left: auto; margin-right: auto;"><img border="0" height="298" src="https://blogger.googleusercontent.com/img/b/R29vZ2xl/AVvXsEirGw0WeK1ftQCD23-xu9SKCnf4GelyBBnJ8tG-dhiizlaj_QlSWAM6_tmcyF6N4HTp-r9h9Qw_T-Wy8Hm_2gKnUolTB-xoYnlzPKTWLXVBAwu2LK1yAE0EsRf4VCIsufpba6YiDdDYrgM/s1600/loop_C_open.png" width="400" /></a></td></tr>
<tr><td class="tr-caption" style="text-align: center;">Pic.2: this is more than half a meter of RG213 dangling out the loop</td></tr>
</tbody></table>
Speaking of dimensions (finally), I need to add that the loop conductor itself is made from precisely 4m of 14x2 PEx/Al/PEx (out diameter 14mm, wall thickness 2mm).<br />
<br />
Of course, a magnetic loop aerial needs a primary loop: <br />
<table align="center" cellpadding="0" cellspacing="0" class="tr-caption-container" style="margin-left: auto; margin-right: auto; text-align: center;"><tbody>
<tr><td style="text-align: center;"><a href="https://blogger.googleusercontent.com/img/b/R29vZ2xl/AVvXsEiT_PgXCs4fd4jYmck_ZyYN5sw5PbUXHWqlHsskQBFikGnT0FWE-LKAJgUzgBTuA53h0LUvJFWRZ1vfYGg09qLZbhtCWaz-4O0gYhlrvqabEnqv6BjJReh8gCJJeFJvJGVhabEH87VLzww/s1600/loop_primary.png" imageanchor="1" style="margin-left: auto; margin-right: auto;"><img border="0" height="320" src="https://blogger.googleusercontent.com/img/b/R29vZ2xl/AVvXsEiT_PgXCs4fd4jYmck_ZyYN5sw5PbUXHWqlHsskQBFikGnT0FWE-LKAJgUzgBTuA53h0LUvJFWRZ1vfYGg09qLZbhtCWaz-4O0gYhlrvqabEnqv6BjJReh8gCJJeFJvJGVhabEH87VLzww/s1600/loop_primary.png" width="239" /></a></td></tr>
<tr><td class="tr-caption" style="text-align: center;">Pic.3: primary loop</td></tr>
</tbody></table>
Dimensions for the primary have a thumb rule: 1/6 diameter of the radiator when placed very far from objects, 1/5 in average situations and 1/4 when used in doors. Mine is made from 80cm of copper installation wire, i.e. 1/5 diameter of the radiator. Of course is very easily exchanged when going indoors. <br />
<br />
<br />
<i>Why are those dimensions selected?</i><br />
As to the loop diameter, having a loop with a generic resonance not much above the future operating frequency allow for small capacitance values to terminate (tune) the loop. Having a low terminating capacitance lower the voltage across the capacitor and broadens the bandwidth of the loop.<br />
The length of 4m of said material, when bent into a circle, deliver a natural resonance at about 15.5MHz. Starting from there, very little capacitance is required to resonate the loop at 14MHz.<br />
The 70cm for the length of the "insert" were a lucky scientific a precise guestimate... <br />
<br />
<i>How to tune this loop and why is it asymmetric in capacitance?</i><br />
Both these question seem unrelated, but they are not! The beauty of this entire design is found in asymmetry actually. Remember the section about changing the larger or smaller capacitors in a series of capacitors? The shorter end of the coax (when inserted into the tubing) acts like a "band set", the longer end like a "fine tune".<br />
Inserting the coax entirely in a symmetrical fashion, the resonance drops to close to 9MHz, tuning here is very fiddly...<br />
Having the coax in asymmetric configuration, the longer end provides relatively smooth tuning.<br />
<br />
<i>What is the bandwidth?</i><br />
Well, I have not yet tested the aerial decently, but, first measurements with an MFJ-269Pro indicated that the loop, tuned to 14.060MHz is good for +/- 20kHz. <br />
Certainly there are ways to calculate the bandwidth, the radiator 12mm has a circumference of 4m. There must be some web-application to evaluate such a loop (<a href="http://www.66pacific.com/calculators/small_tx_loop_calc.aspx">http://www.66pacific.com/calculators/small_tx_loop_calc.aspx</a>) indicating a bandwidth of about 40kHz... (see below).<br />
<br />
My plans for the loop are: QRP and PSK on 20m. Hence, I taped down the short end, as to have my band set. Of course, WSPR and QRSS are also in the reach of this loop...<br />
This loop still is in experimental stage. For a more permanent solution, I will install an electrical box over the terminating capacitor, as to prevent water to collect within the tubing. For the same reason I may even drill a small hole into the bottom of the loop, allowing for drainage.<br />
<br />
Concerning the dimensions of such a loop, 30m may still be an option. However, I rather see myself building this loop for the higher bands in the near future.<br />
<br />
<br />
<br />
Results from 66pacific.com:<br />
<br />
<span style="font-size: 11pt;"><b>RESULTS:</b><br />
</span>
<span id="ctl00_newshole_in_content_page_LabelEfficiencyPercent" style="font-weight: normal;">Antenna efficiency: 68% (-1.7 dB below 100%)</span><br />
<span id="ctl00_newshole_in_content_page_LabelBandwidth" style="font-weight: normal;">Antenna bandwidth: 40.3 kHz</span><br />
<span id="ctl00_newshole_in_content_page_LabelTuningCapacitor" style="font-weight: normal;">Tuning Capacitance: 50 pF</span><br />
<br />
<span id="ctl00_newshole_in_content_page_LabelCapacitorVoltage" style="font-weight: normal;">Capacitor voltage: 631 volts RMS</span><br />
<span id="ctl00_newshole_in_content_page_LabelCirculatingCurrent" style="font-weight: normal;">Resonant circulating current: 2.77 A</span><br />
<span id="ctl00_newshole_in_content_page_LabelRadiationResistance" style="font-weight: normal;">Radiation resistance: 0.223 ohms</span><br />
<span id="ctl00_newshole_in_content_page_LabelLossResistance" style="font-weight: normal;">Loss Resistance: 0.104 ohms</span><br />
<span id="ctl00_newshole_in_content_page_LabelInductance" style="font-weight: normal;">Inductance: 2.58 microhenrys</span><br />
<span id="ctl00_newshole_in_content_page_LabelInductiveReactance" style="font-weight: normal;">Inductive Reactance: 228 ohms</span><br />
<span id="ctl00_newshole_in_content_page_LabelQualityFactor" style="font-weight: normal;">Quality Factor (Q): 349</span><br />
<span id="ctl00_newshole_in_content_page_LabelDistributedCapacity" style="font-weight: normal;">Distributed capacity: 11 pF</span><br />
<br />
<span id="ctl00_newshole_in_content_page_circumferenceLabel" style="font-weight: normal;">Antenna "circumference": 4 meters</span><br />
<br />
<table style="width: 300px;">
<tbody>
<tr>
<td style="width: 100px;"><img alt="Loop antenna" id="ctl00_newshole_in_content_page_loopDiagram" src="https://www.66pacific.com/calculators/images/octagonal_loop_100x100.gif" style="border-width: 0px; height: 100px; width: 100px;" /></td>
<td style="width: 190px;"><span id="ctl00_newshole_in_content_page_sideLengthLabel" style="font-weight: normal;">Side length: 0.500 meters</span></td>
</tr>
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<span id="ctl00_newshole_in_content_page_diameterLabel" style="font-weight: normal;">Antenna diameter: 1.2 meters</span><br />
<br />
<span id="ctl00_newshole_in_content_page_commentsAreaLabel" style="font-weight: bold;">Comments:</span><br />
<span id="ctl00_newshole_in_content_page_lengthGoNoGoLabel" style="color: green;">The specified conductor length of 4 meters is OK.</span><br />
<br />
<span id="ctl00_newshole_in_content_page_lengthAdviceLabel"><b>Conductor length should be between 2.59 and 5.17 meters at the specified frequency of 14.06 MHz.</b> <br /> <br />
For highest efficiency, the conductor length for a small transmitting
loop antenna should be greater than 1/8 wavelength (greater than about
2.59 meters at the specified frequency of 14.06 MHz).<br /><br /> To avoid
self-resonance, the conductor length for a small transmitting loop
antenna should be less than 1/4 wavelength (less than about 5.17 meters
at the specified frequency of 14.06 MHz).</span><br />
<br />
<span id="ctl00_newshole_in_content_page_LabelInputValues" style="font-weight: bold;">Input Values:</span><br />
<span id="ctl00_newshole_in_content_page_LabelLength" style="font-weight: normal;">Length of conductor: 4 meters</span><br />
<span id="ctl00_newshole_in_content_page_LabelDiameter" style="font-weight: normal;">Diameter of conductor: 1.2 centimeters</span><br />
<span id="ctl00_newshole_in_content_page_LabelFrequency" style="font-weight: normal;">Frequency: 14.06 MHz</span><br />
<span id="ctl00_newshole_in_content_page_LabelPower" style="font-weight: normal;">Transmitter power: 5 watts</span>Joachim Seiberthttp://www.blogger.com/profile/01766975824128341507noreply@blogger.comtag:blogger.com,1999:blog-3099598580812416162.post-41838740442506232732014-03-30T01:09:00.001+01:002018-03-30T22:37:08.874+02:003 Inch HiFi PVC Pipe - The Alphorn (MLTQWP)Finally I found some time to tell/show a little bit more about the speaker enclosures I was bragging about so much lately.<br />
<br />
Most importantly, why was this so interesting to be posted on a blog concerned with RF. Well, to my very own understanding, the principles behind emitting sound waves it somewhat similar to the principles of emitting radio waves.<br />
Here is why:<br />
<table align="center" cellpadding="0" cellspacing="0" class="tr-caption-container" style="margin-left: auto; margin-right: auto; text-align: center;"><tbody>
<tr><td style="text-align: center;"><a href="https://blogger.googleusercontent.com/img/b/R29vZ2xl/AVvXsEjJPJSuGzs8mmKGT8_Svb6BkABpCsktFZKQDiTuxs2YShDHru_eV7CehQi2QCrGPCCCIk6EVm1-z-AYx2QMNKPjpdBF0feCbCWzRJsH29MHOTKkWeF-7lkm8Qd-e8sMjw8aJyqmfM144co/s1600/pipe.gif" imageanchor="1" style="margin-left: auto; margin-right: auto;"><img border="0" height="400" src="https://blogger.googleusercontent.com/img/b/R29vZ2xl/AVvXsEjJPJSuGzs8mmKGT8_Svb6BkABpCsktFZKQDiTuxs2YShDHru_eV7CehQi2QCrGPCCCIk6EVm1-z-AYx2QMNKPjpdBF0feCbCWzRJsH29MHOTKkWeF-7lkm8Qd-e8sMjw8aJyqmfM144co/s1600/pipe.gif" width="250" /></a></td></tr>
<tr><td class="tr-caption" style="text-align: center;">Analogy between a quarter-wave vertical and a quarter-wave speaker enclosure</td></tr>
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On the left hand side, the above sketch shows the good old vertical quarter-wave antenna driven by a gamma-match. Indicated in blue, the current distribution along the radiator. Of course, this current will emit a magnetic fields (green), which was the purpose of the antenna in the first place.<br />
<br />
On the right hand side, you see a loudspeaker cabinet called quarter wave pipe (QWP). In such a pipe design, similar to the gamma-match of the vertical, a <i>driver</i> (in acoustics loudspeaker chassis are called drivers) creates pressure waves (green) somewhere in the middle of the "conductor". Similar to a quarter-wave antenna, the conductor is excited at a resonance frequency. The blue line indicates the air speed, i.e. current, through the pipe. The red arrows indicate sound emissions.<br />
<ul>
<li>The driver emits sound to the front side of the cabinet.</li>
<li>The standing wave emits sound at the open end of the pipe. </li>
</ul>
While the driver emits what ever is present in the AF signal, the pipe predominantly emits sound at its resonant frequency and harmonics thereof. The latter, of course, is a problem! In musical terms, this could lead to a "One Bass Note Samba", something nobody would enjoy, contrary to the "One Note Samba" having quite some more notes than one only.<br />
Consequently, the bandwidth of the pipe needs some severe broadening!<br />
<br />
Back to aerials, there are 2 ways to make an antenna broadband:<br />
<ol>
<li>add more resonators (e.g. log-per, dipole fan)</li>
<li>add Ohmic resistance (e.g. T2FD, Beverage antenna)</li>
</ol>
In acoustics, both can be done too. As I indicated before, antennas and speaker cabinets have a lot in common!<br />
In acoustics, one can add more resonators by tapering a restrictive volume and add resistance by stuffing said volume with dampening material. <br />
<br />
For a HiFi speaker cabinets one needs a very homogenous emission over several octaves, i.e. close to 0Hz up to 22kHz (those are, of course, extremes). A mixture of multiple resonances and some severe resistance is used. Actually, there is an added bonus on the resistive part of things... not only does stuffing material add resistance, it also lowers the velocity of sound within the medium. A stuffed enclosure looks larger to sound-waves than the same enclosure not being stuffed.<br />
<br />
PVC piping, at last we leave the theory part of things, is a very convenient stuff to work with. Now we talk about pipe in the sense of water pipe. Have I forgotten to mention that the word pipe could have several interpretations, sewage pipe, water pipe, organ pipe, pipes of bagpipes, etc. OK, pipes, i.e. PVC pipes, fittings and stuff thereof. Here is the B.o.M:<br />
<table align="center" cellpadding="0" cellspacing="0" class="tr-caption-container" style="margin-left: auto; margin-right: auto; text-align: center;"><tbody>
<tr><td style="text-align: center;"><a href="https://blogger.googleusercontent.com/img/b/R29vZ2xl/AVvXsEge1w0vyMQjKowDX-_6katsK_tvUTvpG5uvI8wB5omj7birb_NHOmBUVN0t8aAsdSEX60LOYkRGW_HhP3vTYz4OqEq_jJNFwPo3wLumWrfKDud1wFF7Kwz_vjHxi5_3IT2a9zHW7z_N3y4/s1600/parts.png" imageanchor="1" style="margin-left: auto; margin-right: auto;"><img border="0" height="115" src="https://blogger.googleusercontent.com/img/b/R29vZ2xl/AVvXsEge1w0vyMQjKowDX-_6katsK_tvUTvpG5uvI8wB5omj7birb_NHOmBUVN0t8aAsdSEX60LOYkRGW_HhP3vTYz4OqEq_jJNFwPo3wLumWrfKDud1wFF7Kwz_vjHxi5_3IT2a9zHW7z_N3y4/s1600/parts.png" width="400" /></a></td></tr>
<tr><td class="tr-caption" style="text-align: center;">PVC parts</td></tr>
</tbody></table>
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The parts serve the following functions:<br />
<ul>
<li>tubing form the pipe's body, obviously</li>
<li>the elbow is the resonator's "mouth", bending pressure waves towards the listener</li>
<li>the T-piece is to the driver</li>
<li>the reduction pieces will taper the resonator</li>
<li>and the end cap will be the end cap, i.e. terminating the resonator.</li>
</ul>
The elbow, T-connector and fat tube form the lower part of the pipe. This is all 3" piping. The length of the tube it 1m.<br />
The upper part of the pipe is tapered down to 2" and 1.5" PVC tubing. The respective tubes have a length of 50cm each. Obviously, fittings add length to the final product.<br />
Adding 1 additional diameter to the taper, will just add 1 more resonance (and its harmonics). Hmmm, "Two Not Bass Samba", really?! No, that does not help!<br />
The tubes therefore receive insets. The process of making those is pretty easy. My preferred method is using heating pipe insulation foam tubing. Cut in half, the stuff can be easily be cut diagonally. A result of this is tapering for pressure waves.<br />
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<tr><td style="text-align: center;"><a href="https://blogger.googleusercontent.com/img/b/R29vZ2xl/AVvXsEj2X54AlhZnYY07ffOowcSodYV3ZJKiJSzjBc99Hu7RmLhKgi8E1yhbUYkqVW1nsSTK8aoJJySobvFJ12IePo01sKVLFSwRLk9S6UbuDVP2zlur1dECCcxWIIZjMTt4Y17W8XHCebZNP_w/s1600/inserts.png" imageanchor="1" style="margin-left: auto; margin-right: auto;"><img border="0" height="253" src="https://blogger.googleusercontent.com/img/b/R29vZ2xl/AVvXsEj2X54AlhZnYY07ffOowcSodYV3ZJKiJSzjBc99Hu7RmLhKgi8E1yhbUYkqVW1nsSTK8aoJJySobvFJ12IePo01sKVLFSwRLk9S6UbuDVP2zlur1dECCcxWIIZjMTt4Y17W8XHCebZNP_w/s1600/inserts.png" width="400" /></a></td></tr>
<tr><td class="tr-caption" style="text-align: center;">Tapering inserts</td><td class="tr-caption" style="text-align: center;"><br /></td></tr>
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That's the tapering part dealt with... Those speakers are called TQWP.<br />
<br />
However, before putting everything together, we need to address the resistive part of broadening the bandwidth of the pipe and lowering its resonance. There is no photo of this step. The material involved is polyester from an IKEA pillow, the cheapest acoustic stuffing on the market!<br />
I complemented the inserts with the pillow stuffing and shoved it down the respective 50cm PVC tube.<br />
<br />
We are nearly finished... there is just one other addition, before the "cabinet" can be assembled. In order to prevent the creations of unwanted harmonics, dampening material (cleaning cloth!) has to be added behind the driver (within the T-piece).<br />
<br />
Here is a photo of the finished speaker:<br />
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<tr><td style="text-align: center;"><a href="https://blogger.googleusercontent.com/img/b/R29vZ2xl/AVvXsEgSSYsO6qfz3zg15Nqzw3i8R3MqvWi-MXhdFn9jiadqzSKBemsNfWuRO3V0et6gseoSGRp9FDCG51gQgNbCEQ7DHzT6advGsoG_bmHZ3-_k7oOCgGPQev2BLze-AiCIzcVyPiqUuMAEYTk/s1600/pipe_speaker.png" imageanchor="1" style="margin-left: auto; margin-right: auto;"><img border="0" height="640" src="https://blogger.googleusercontent.com/img/b/R29vZ2xl/AVvXsEgSSYsO6qfz3zg15Nqzw3i8R3MqvWi-MXhdFn9jiadqzSKBemsNfWuRO3V0et6gseoSGRp9FDCG51gQgNbCEQ7DHzT6advGsoG_bmHZ3-_k7oOCgGPQev2BLze-AiCIzcVyPiqUuMAEYTk/s1600/pipe_speaker.png" width="88" /></a></td></tr>
<tr><td class="tr-caption" style="text-align: center;">The Alphorn speaker</td><td class="tr-caption" style="text-align: center;"><br /></td></tr>
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Yeah, this is a very tall speaker. For obvious reasons, I call this speaker "Alphorn". The image above shows the thing from floor to ceiling, as installed in my attic.<br />
The sound of those speakers is amazing! From classical to hiphop, via kizomba, funk and rock... the sound of those speakers blows me away!<br />
Mind you, those are very cheap 3" drivers...<br />
<br />
The drivers came in a stereo set priced less than €40. <br />
Why am I mentioning this? The price for the PVC plumbing parts, used for this project, is actually > €42.The passive parts of the project exceed the price of the active ones... not sure what that means in the context of modern electronics.<br />
Speaking money, the Alphorn speakers sound like speakers in excess of at least 1k€.<br />
<br />
Back to theory... the total length of the pipe is about 225cm. 2,25m in quarter-wave reflects 9m of wavelength, which in itself equates to a sound frequency of about 33Hz. This would be the resonance of the empty (non-tapered) pipe.<br />
As said before, the upper part of the pipe is stuffed with IKEA pillow material, hence the real resonance frequency will be even lower. Stuffing enclosures is called "Mass Loading".<br />
<br />
There are 2 sharp steps in the taper, one at 120cm and one at 175cm. Those steps add resonances at 62.5Hz and 43Hz, which of course will also have harmonics too. <br />
<br />
The resulting speaker enclosures qualify for the MLTQWP... and... they sound amazing!<br />
<br />
<b>UPDATE</b> on alternative design thoughts. Thoughts only. On the internet a couple of designs float showing curved structures, involving a plurality of bends and elbows. Similarly to stepped tapers, those bents create reflections and disturb the air-column of the standing wave pretty good. Bending the design to limit height of the speakers seems however a very attractive thing to do.<br />
My gut feeling tells me that 45º bents at carefully selected lengths could work. Maybe two of those just above the feeding T, followed by a reducer and two more 45º bents. Such a design would keep the tallness of the speaker at about 140cm. However, I still believe that such a measure will reduce the amplitudes of the lowest frequencies.<br />
<br />
<br />Joachim Seiberthttp://www.blogger.com/profile/01766975824128341507noreply@blogger.com