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Lee Hanken
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Episode: 3145
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Title: HPR3145: A light bulb moment, part 1
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Source: https://hub.hackerpublicradio.org/ccdn.php?filename=/eps/hpr3145/hpr3145.mp3
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Transcribed: 2025-10-24 17:45:56
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---
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This is Hacker Public Radio Episode 3145 for Friday 21 August 2020. Today's show is entitled
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A Light Bulb Moment. Part 1
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It is hosted by Mr. X
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and is about 11 minutes long
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and carries an explicit flag. The summary is
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finding the working voltage of a bulb.
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This episode of HPR is brought to you by An Honesthost.com.
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Get 15% discount on all shared hosting with the offer code
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HPR15. That's HPR15.
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Better web hosting that's Honest and Fair at An Honesthost.com
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.
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Hello and welcome Hacker Public Radio audience. My name is Mr. X
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and welcome to this podcast.
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As usual I'd like to start by thanking the people at HPR for making this service available to us all.
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HPR as a community led podcast provided by the community for the community.
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I mean you can contribute to why you just pick up a microphone, any recording device
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and send something in. I'm sure you must have something that's worth well sending in.
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If I can do that sort of thing I'm sure you can.
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And right now I'm sure a lot of you all have a bit more spare time on your hands
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because of the thing that's going on. The thing that I won't talk about.
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Anyway, on with the show.
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So this podcast came about because of an email I received from a good friend Dave Morris
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on the 4th of March, no less.
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This is currently the 30th of March.
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I just think we've had to pull this show together.
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And I haven't noticed when I shall actually get uploaded.
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Anyway, that's sort of it was that Dave came into possession of an illuminated lantern
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that he wanted to use. He had a problem however as the lantern and question was sealed
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and he didn't know the working voltage of the bulb within.
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He asked me if there was a way of working out.
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Well, first of all, before I go any further, I should probably say I'm not a bulb expert.
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However, I said about doing until investigating.
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What I discovered was that conquering this is not as straightforward as you might think.
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One thing you might think to do is to use a meter to measure the resistance of the bulb.
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Even doing this however is fraught with difficulty because measuring the resistance of a cold bulb
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not working at temperature will give a misleading answer.
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This is because the resistance of a standard bulb changes with temperature.
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And I can demonstrate this by measuring the resistance of two bulbs I have lying around the house.
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So the first bulb I have is a clear traditional bayonet tungsten filament house bulb
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rated at 40 watts. I live in the UK so its operating voltage is 240 volts.
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I use my trusty fluke 77 digital o-meter but any meter capable of measuring resistance will do.
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The bulb at room temperature merged a resistance of 108 ohms.
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The other bulb was a halogen E14 screw in bulb rated at 28 watts.
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And its operating voltage, like the previous bulb, was 240 volts.
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Its measured resistance at room temperature with 144 ohms.
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Okay so from this we can do a few calculations.
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There's a couple of formulae that we could put to use.
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There's the standard ohms law of VIR and the power PVI sort of thing.
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So what I've done is I've drawn this diagram, the diagrams for the two formulae.
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And I'll include that in the show notes.
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These were created using LibreOffice draw version 6-073.
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It's not too bad actually. I haven't really tried it before.
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So that was a bit of fun.
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So an easy way of dealing with these formulae is to...
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I've described the diagrams that I've created.
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If you think of a neculatical triangle as a good pick word.
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And you've got this triangle and you split it horizontally with a line.
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So you've got two sections, you've got an upper section and a lower section.
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It's a horizontal line that bisects the equilateral triangle in the mid point.
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So that makes sense.
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Now on the bottom area, bottom section, draw a vertical line to split that lower section in two.
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So you now have three areas atop, bottom left and bottom right.
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In the top, you put a V for volts.
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On the bottom left, you put an I for current or amps.
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And in the bottom right, you put an R for resistance and ohms.
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So we know the voltage and we know the resistance.
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What we don't know is a current.
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So with one of these diagrams, what you do is if you want to know the current,
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you stick a thermal over the I and what's left is a V on the top and the R underneath.
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So it's V divided by R.
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So 240 volts divided by R, which is 108 ohms.
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That comes out with a current of 2.2 amps.
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So that bulb, if it had a steady resistance of 108 ohms,
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would in theory draw 2.2 amps.
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Now the next formula, which again, the same triangle,
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but you put different letters on it, you put P, V and I,
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P for power, which is measured in watts.
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That's in the top segment.
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The bottom left segment, you put V for volts.
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And the bottom right, you put I for current.
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So putting a thermal over the P, the top section,
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you can find that by multiplying V times I.
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So that's 240 volts times 2.2 amps,
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because remember we're decarculated that.
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And that comes out at 520 watts,
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where that's not quite right, is it?
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520 watt bulb, I don't think so.
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I think it was a 60 watt, did I say it was a 60 watt?
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But did I say 40 watt in fact?
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So that's complete nonsense.
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So what happens is as the resistance of the bulb,
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sorry, as a attempt of the bulb goes up,
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the resistance also goes up.
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So you can't do that.
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Again, we'll do it for the halogen one as well.
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So we've got 240 volts, V, divided by R.
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It's 240 volts, divided by 144 ohms.
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That comes in at 1.7 amps.
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That's for the halogen one.
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So then you go to the second formula, which is V times I,
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for the power or watts.
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So that's 240 volts times 1.7.
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And that comes out at 408 watts, again.
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Rubbish, that's not really good.
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So I did a wee bit digging around,
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and as per usual, I used Google and came up with somebody
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who asked a very similar sort of questions on candelpowerforums.com.
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They obviously specialize on an electrical bulbs and whatnot.
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I don't know what their 40 is, but yeah,
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it seems like there's a forum for just about anything you can think of.
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So one person, I'll put that link in the show notes obviously.
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One person and a forum made the point that there really isn't such a thing
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as a working voltage.
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It just depends on how long you want the bulb to last.
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For this reason, I always turn down the brightness on any car I own
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that has dimmable dashboard lights.
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Changing these bulbs can be a real pain and can be expensive.
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Sometimes a stated working voltage for a bulb can be misleading.
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For example, a car bulb will often state a working voltage of 12 volts,
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but it's likely to be running at a higher voltage
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when the engine is running due to the operation of the car's alternator.
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Another person suggested trying to estimate the length of the filament
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and using this to determine the working voltage.
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Yet somebody else suggested just using a variable supply
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and to just slowly increase the voltage until a reasonable amount of light is generated.
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This might be quite simple if it's a low voltage bulb
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and you could even use some batteries lying around,
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connecting them in series, adding one batch at a time
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until the required brightness is achieved.
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It isn't so simple if the bulb requires a higher voltage.
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In the end, I just passed this information on to Dave,
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wishing him luck and his path to discovering the optimal working voltage for his lantern.
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Feel free to write a comment if any of you out there
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have any other ideas on finding the working voltage of a bulb.
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This way, it can be shared with rest of us during the community news.
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Better still, it's sending your own show.
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So there we go, that's the end of this podcast.
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This will probably just, but might well be a multi-part show
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because there's quite a bit to do bulbs.
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I'll maybe cover them in later shows.
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So stay tuned.
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Anyway, thanks for listening to this,
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and I hope you found it kind of interesting.
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And if you want to contact me,
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I can be contacted at www.hpr.googlemail.com.
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That's MRX-AT-HPR-TheAT symbol-googlemail.com.
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So until next time,
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thank you, and goodbye.
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Thanks for watching.
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Thanks for watching.
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