Thank you. Glad I could help.

As far as an update, it's still going fine. Haven't had any reason to disassemble the cabinet I put it in and start over. Though it might be too quiet, but I'm not sure if the amp is too weak or if the box is limiting the output. If I ever need to get it louder, I might re-do this video and get more accurate parameters.

Thank you. I'm actually building a cab for it right now. I hope to have that video up in a couple weeks.

Good luck to you. I hope it all works out. My numbers ended up kinda weird, but the cabinet still sounds pretty good, just not very loud. But the amp has a DI, so I guess it doesn't matter all that much. However, I haven't tried it with an actual drummer, so I have no idea if I can even hear it. Thanks for watching.

have you heard about software called WinISD, its basically a software to design a box based on the parameters, but more complex than the website version

I have not heard of that software. Even so, my goal was to keep the project as inexpensive as possible. And even if it were free, I am very wary of downloading software from random websites. Besides, the website versions were good enough to show me the speaker was probably junk.

its free, i've download it, and i already scanned it with my bitdefender anti-virus and its fine, yeah you're right, there's no point to use complicated software for such a cheap speaker tho, if you curious about the software, you can check it here www.linearteam.org/ . Anyway i already measure my speaker, it's turn out my speaker Qes is worse than yours, mine about 6.22, its cheap tho for a 5" woofer with no brand, around $3-4, its so hard to get a good quality speaker without a lot of money here, so yeah maybe i just stick with this woofer for awhile.. , there's an alternative for the rice, you can use kinetic sand, its not sticky and easy to clean.

If it's a sealed enclosure, don't forget to try the Linkwitz Filter before anything too expensive or time consuming.

Those are great and innovative solutions. Great job. My biggest resonant sources are two glass cabinet doors. That is, each cabinet door has a pane of glass in a wooden frame. I'm sure a little hot glue will fix it, it's just low on my list of priorities. I usually forget about them until I'm playing bass and they start rattling. But at that point, I'd usually prefer to just play and ignore the rattle rather than fix it. I'd make a mental note about it, then promptly forget. :D

Excellent! This is great information. I will definitely use this in other projects I plan on doing. Especially the note about the digital meters and errors at low resistance. Thank you for watching and commenting.

While generally not as accurate, old Analog Ohmmeters, like my Micronta 43-491 (Radio Shack in Amsterdam) were subject to battery aging and had a Zero adjustment, also perfect for zeroing lead resistance. Whenever I worked on world-wide CTs or MRIs in the 70s, 80s and 90s, I always scouted the local Radio Shacks as soon as I arrived in town. You can't believe how many multi-million $$$ scanners were diagnosed with, and actually contained Radio Shack parts.

HA! That's awesome. I miss Radio Shack. :(

The described technique can also be used to measure the 10ohm resistor, or any low value resistor for that matter. If you have a lab PSU, it is very easy to set some reasonable current limit, then measure the voltage drop directly on the resistor or resistive-anything. If you don't trust the current reading of the PSU, then either include an amper meter in series too, but is cruical to always measure the voltage drop on the device under test, as close as possible. You can measure miliohms this way if you can pump out amps from your PSU (and the device can tolerate it, eg. you measuring a cable). I'd like to point out that measuring AC voltage might be inaccurate with multimeters if the signal is way off of 50/60 Hz. Might be accurate, but you can only be sure, if the datasheet guarantees it in some frequency range, or if you check it with either a known accurate flat response function generator or an another known accurate voltmeter. It's not a problem in this subwoofer range, but might be higher up in the audio spectrum.

I agree with Gabor. Whenever you're doing low resistance measurements, the 4 terminal or Kelvin connection overcomes lead and contact resistance by ensuring no substantial current flows through the Digital Multi-meter's test leads. When you measure a low value resistor using the DMM, by itself, the small, but significant current the DMM applies to the resistor-under-test also flows through the DMM's test leads, causing an (I)(R) product Voltage drop. By itself, the DMM can't separate the lead's (I)(R) drop from the resistor-under-test (I)(R) drop. You have to subtract the test lead (I)(R). On an old analog meter, you can usually re-zero or null the test lead (I)(R) drop. Or you can use the Kelvin connection. en.wikipedia.org/wiki/Four-terminal_sensing Lord Kelvin is the same engineer/physicist who gave us the first two Laws of Thermodynamics. The Kelvin temperature scale is also named after him. 0 degrees K ~ - 273.16 degrees Celsius or Absolute Zero, where (at least in 2022) all molecular or entropic motion ceases and all pure resistances become noiseless. en.wikipedia.org/wiki/William_Thomson,_1st_Baron_Kelvin

You're welcome. When I made this, there were no other videos on this subject that I could find. I thought it needed to more available. This was also my very first youtube video. Now I occasionally see other videos show up in my feed by more established channels. So even if mine wasn't the best, it was the first. :D Thanks for taking the time to watch and comment.

Now that you mention it, that makes complete sense. I didn't have any clay on-hand, however. Though I agree that in music, especially rock based music, such errors are attractive to some listeners. The Kinks were famous (infamous, maybe?) for poking holes in the speaker cones to get the sound they were after. I guess at that point T/S parameters really aren't worth much. Thanks for watching.

@depunkt Yeah, I probably should have used some clay. But I didn't have that available. If you are trying to get the T/S parameters then you can use this method (substitute the clay for rice). Thanks for watching.

Thank you. I think a lot of people disliked that I used rice instead of clay or playdoh to weight the cone. But other than that I think most other things went pretty well. There is another video where I attempt to design an enclosure for this speaker that didn't go very well due a misprint of a formula on the website. I should go back and fix it, but it's pretty low on my priority list.

@@HandlebarWorkshops Thanks for letting me know, you are still monitoring this video. I have a question, that may/may not relate to your measurement parameters: the amplifier you showed, does it fit the stipulated requirements -ie. 1-10W RMS, & an output impedance of

@@citizengkar7824 While doing research for this video, I did not read anything about output impedance, nor about the RMS. This method isn't meant to be (nor can it be) extremely accurate, but doable for someone to do once or twice without investing in expensive tools. It's meant to get close enough to get a good (but not necessarily a HiFi) sound out of a speaker. After all, since it is a fairly unknown speaker, you probably didn't pay much for it anyway. You just want to make it sound as good as possible without spending too much more money. It would be cheaper to buy a new speaker with known parameters than to buy all of the scientific tools to do this at a high level of accuracy.

@@HandlebarWorkshops I do agree all you've said. Though, it does state those requirements, on the Elliott site, you've linked. "1.1 Measuring Re, Fs, Qes, Qms and Qts To measure these parameters using the method outlined below, you'll need to have the following items: A power amplifier, rated at 1-10 Watts (RMS) or thereabouts (must have low output impedance

That Elliott site has changed since I used it for this video. For a while it was a 404, then when it came back one of the formulas was different. I haven't gone back to see if that new formula would result in a better end result with this speaker. I don't remember any of that list being there, but it's been years, so my memory of all that may be a bit off.

Since you have all of the T/S Parameters, you can skip to about 23:00 and use what you already have to start designing a cabinet. Thanks for watching.

I use this speaker in the cabinet of my bass guitar amp. This is by no means a high quality amp. My friend who gave it to me said it was from a cheap 80's keyboard amp that got ruined when his basement flooded. I wasn't looking for high fidelity nor infrasonic frequencies (I'm really not that good of a bass player... yet). But the guitars hanging on my wall will audibly resonate with the low E on the bass. As will the glass panels in my cabinet. It's not annoying enough to me to spend the time fixing all the rattling. Especially knowing that I will be remodeling the room in the not too distant future. And I think some part of me likes it. Though I may not be very good, I can say my bass playing is "room rattling". One of the main things I love about live music is being able to feel the kick drum and bass. I wonder if that Velodyne could recreate that.

The final build was a couple of videos later. kzbin.info/www/bejne/aJ2qnKOKq69-hrM Thanks for watching.

I start talking about it at 20:08 (I know, it's a long and dry video and difficult to focus on. Sorry about that.) Vr is Ir * Rs. Ir is calculated just before Vr and Rs is the actual measured value of the physical resistor in the circuit.

@@HandlebarWorkshops Don't be sorry please. Your explanation is very easier to understand. Thanks for the reply.

Well, a 52mm diameter is about 2 inches. The whole point of the T/S parameters is to design and build a cabinet that tuned to the speaker so it can properly reproduce the low frequencies. As such, it mainly applies to bass guitar amp speakers and sub-woofers. I'm not sure such a small speaker has enough mass to require a tuned cabinet. Nor would it be able to reproduce the low frequencies accurately enough to require a tuned cabinet.

@@HandlebarWorkshopsThanks for the answer. I am a newbie. So how is it possible to design a speaker enclosure for small speakers then? Generally, small speakers come with a sealed enclosure but there are bass reflex speakers too for instance. How to design those?

Honestly, I don't know how to design a cabinet for that small of a speaker. I'm rather new to all of this as well. I'm just trying to figure it all out as I go. Until I recorded that video, I had never really done anything like that before, nor have I've done it since. However, I would assume that the size of the cabinet wouldn't matter with such a small speaker. A port (a hole cut into the speaker baffle - sometimes with a tube - to allow air to escape) may or may not help depending on the size of the cabinet. A speaker that size will not move much air (that's how speakers work, the paper cone pushes air which causes pressure waves that our ears and brains interpret as sound). And since air is rather springy, if the enclosure is rather large, it won't matter at all. I would suggest you experiment. I don't think you can get the T/S parameters for such a small speaker. Make some enclosures out of cheap wood at different sizes and see what sounds the best. You can even record it and post a link here.

That would be ideal, but speakers can be expensive. This one was free and my method got close enough. If I can find a cheap enough speaker, I will do just as you suggest. However, I still have to go back and do some re-calculations. The ESP website put out some new equations that should help me get an even better result. I just have to find the time to do it.

I realized that the formula I was using was incorrect. And the website that gave me those formulas updated them after my video came out. Either way, I just went ahead and made a cabinet for it by copying a commercially available cab. It may not be the best for that speaker, but it's fine for what I need.

Yeah, it didn't even occur to me at the time. Thanks for watching and the comment.

i`m having the same problem, have you got any help for this?

i`ve got it! They have changed the domain, so after some digging around i found the new page, it`s this one sound-au.com/tsp.htm hope you can take advantage if this.

For optimal bass response, you could try to design a tuned cabinet, but I don't think it would be worth the time and effort. If you look at commercial high end speakers that use the same size, you'll find that all of the cabinets are around the same dimensions. I would just use measurements similar to those and call it good. That's what I ultimately did with my bass cabinet since this video didn't give me useful results. Thanks for watching.

Playdough works great

It's just a frequency generator app. I'm not even sure that that particular one exists anymore. Just grab the highest rated one off the app store or google play.

Yes. That is totally a valid option. I just didn't have any on hand and didn't want to go buy some for this single use. Thanks for watching!

That is true, but I was trying to see how close I could get on a limited budget. That Dayton Dats is more expensive than a new speaker. I guess it would be worth the expense if I were dealing with unknown speakers on a daily basis, but so far, this is the only one I've ever come across. Thanks for watching.

@@HandlebarWorkshops I totally agree. A lot of money, for a once, or twice-off.

I have no idea what the sampling rate of my meter is. I bought it used without a manual. I guess I could go look it up online, but I don't think it's necessary. Using an oscilloscope would be much better, but they're rather expensive and most people (like me at the time) don't have them. I was trying to do this in a way that was relatively easy and cheap with tools that a lot of people have or have access to. I've since purchased a used scope but I already put the speaker in a cabinet and had been playing it often.

First Point - the integration time of a Dual Slope meter is 100 milliseconds, intentionally 6 cycles at 60 Hz and 5 cycles at 50 Hertz. If you can remember from Calculus, the integral of a sine wave over a full cycle is zero. 100 milliseconds is the lowest integration time that's an integer of both 50 and 60 Hertz. Why? According to Sampling theory, 50 and 60 Hertz will both fall in the bottoms a deep notches. That way, you can do a very low-level DC measurement in the presence of a significant line voltage pickup and your DC measurement will hardly be affected. The display will barely flicker. A wonderful invention. I believe Weston Instruments may have held the original Patent. Second Point - I came to this website because I managed to install a 12" shallow Subwoofer in a 36" by 18" by 5" , 1 .1 cubic inch enclosure that fits PERFECTLY under the tonneau bar of my 2016 Toyota RAV4. I love classical organ and tried to get down to 16 Hz, without spending $$$$. I was able to get down to 24 Hz before the cone started breaking up - unlike my TV room's (modified) Sunfire True Subwoofer that will eek out a 115 dB SPL at 16 Hz. I need a subwoofer with a breakup-resistant, stiff Aluminum cone and about a 2 cubic foot enclosure. What I also discovered - don't expect decent bass from a shallow subwoofer. Physically, the cone is too shallow. You need a real, deep, stiff conical cone to minimize breakup, multi-mode, doubling (2nd Harmonic) or tripling (3rd Harmonic) or higher-order Harmonic distortion. So, I've just found a reasonably-priced Harmony HA-A122, 12" Anodized aluminum cone subwoofer, with no published Thiele-Small parameters. Their prime retailers have no TS data. I haven't yet reached Harmony's engineers. I have a small electronics lab in my garage. I designed medical electronics for 40 years before recently retiring. I thought it would be fun to do my own TS stuff if there were no published data, and I had to buy a sub to test it myself. Instead of clay, we have some of our granddaughter's leftover Play Doh. Since she's 17, I need it more than she does. The Doh is still flexible after 13 years. A full Play Doh container fits the vent of a legacy Radio Shack 12" subwoofer, allowing closed v ported frequency response comparisons. Third Point - a Linkwitz Filter is excellent for open-loop flattening of a subwoofer's response in a sealed enclosure. It removes the resonant hump and significantly raises the bass response if your sub cone doesn't distort and your amplifier power is sufficient. A vented enclosure can also be done, but it's very tricky and requires much more amplifier power.

Thanks for all of the information. I hope that Harmony gets as low as you want it. I'm surprised you can even hear 16Hz. Or are you just feeling it? That said, I wonder if my video might be a bit too remedial for you. Sounds like you have a pretty decent setup and can probably put a video with much more technical information than this aimed at an engineering or very experienced audience. This video was more aimed at musicians. ;)

That is the resonance frequency, the frequency where the the voice coil in the speaker has to do the least amount of work (lowest voltage) to move the cone. It all depends on what the cone is made of, how big the magnet is, what kind of glue is used to attach the paper cone to the metal structure of the speaker and how it all works together (resonates). I am at a loss to come up with a good analogy, at the moment, but think of holding a pool noodle at its center point. If you move your hand back and forth, the ends start to wiggle. If you experiment with the speed of your hand, you will find a frequency where the ends flop around in a very consistent pattern and it will be very easy for you to keep that pattern going - this is the resonance frequency of the pool noodle. If you try to speed up or slow down, either you have to use more strength in your arm or the ends of the pool noodle get chaotic.

Handlebar Workshops thanx for attention sir..

Handlebar Workshops is there any other way for talk to you like instagram or facebook

You'd have to measure it to see, but probably not. Most cellphones require some kind of powered speakers (much like computer speakers) that have an amplifier built into the speaker enclosure that you have to plug into the mains outlet of your house. The current provided by the cellphone is probably not high enough to drive a speaker by itself.

Handlebar Workshops can i use PAM8403 class D amplifire which have 5w output

Thank you for watching!

Well, in this case, I was trying to get a good approximation using items most people would have easy access to, or possibly already own. I just used my stereo receiver with the EQ set to flat. I have no idea what it's frequency response is like along the spectrum since I don't own a spectrum analyzer. Maybe the lows should have been boosted, I don't know. I believe that both classes of amps can be designed in such a way to output a flat response to all frequencies in the audible spectrum, only that the class AB would probably cost more. They would also most likely be lab equipment (like a frequency generator) since such a flat response is usually not very pleasing to listen to. Thanks for watching.

If you're testing a speaker, the Class of the amplifier is probably unimportant, because the Total Harmonic Distortion (THD) or Linearity of the speaker is, at minimum, 10 times worse, and likely more. If the Amplifier's Frequency Response isn't flat, you can make up for it with a Radio Shack or similar Sound Level Meter that's been tweaked (on paper) for flat frequency response. Or you can use Reciprocity to measure and correct for it. B & K makes excellent, professional Sound Level Meters. Frequency Response is usually not considered a nonlinearity. It's just a frequency-dependent loss. True amplitude nonlinearity creates harmonic frequencies that don't exist in the original source material. What a lot of people consider "good" bass is simply nonlinearity-based harmonics, overtones or multi-mode cone breakup. You generally can't hear 16 Hz fed to a good subwoofer. If you do, it's likely 32, 48, 64, 80 Hz or higher-order cross-products.

Thanks for the info Ron. I only understood about half of what you wrote, but hopefully it will help other people out.

I'm doing a very quick and dirty job here. Just looking for good enough. In this case, any capacitance introduced by the alligator clips is negligible. Thanks for watching.

I am just using a stereo receiver as an amp. But you could use a computer sound card or even a guitar/bass amp (as long as it is not a tube based amp - using a tube based amp without a proper speaker load will burn the tubes out). Thanks for watching!

The reason for the resistor is to split the voltage so as not to blow the speaker accidentally. It also makes a very convenient way of calculating the current, measured voltage divided by the measured resistance. Speakers are an impedance load, that is their 'resistance' changes with the frequency. The resistor is always a static 10.4 Ohms and can be used as such when calculating current any any frequency.

Thanks for the reply. I haven't got a resistor atm but I tried to find the resonant frequency but I don't see the voltage drop. Would doing the test without one cause this to happen?

Be very careful with that. You risk blowing the speaker without the resistor. If you're measuring across the speaker, you would would be looking for a voltage maximum - the opposite of what you'd look for across the resistor. The voltage would be set by the amp and then shared between the resistor and the speaker. So when the voltage is at a minimum across the resistor, it's at its max across the speaker and vice-versa.

That's great, makes perfect sense. Would you mind if I message you direct. I'm new to this and have some other questions you might be able to help with? Thanks again

Sure, you can email me at additola(at)gmail.com

That was one suggestion that I saw, but I didn't have any modeling clay. And I figured most people were more likely to have rice than modeling clay, as well.

I dunno if this might be the reason for the surprising numbers, but loose rice is not good. The added known mass should directly and consistently alter the mass of the driver (piston). The mass should remain affixed to the cone during the measurement; the combined mass of the rice (or other loose additional mass) and cone will only be stable at rest - a state that never occurs during the measurement. Sticking stuff to the cone is obviously not desirable, but necessary for accurate results. It might be worth trying to find if anyone has figured out a solution to this problem - either mathematical (an algorithm that accounts for a loosely added mass) or practical. Thanks for walking through the process. I have to do this at some point down the road. Familiarizing myself with the procedure in advance :)

I hadn't thought about that. Interesting. I was looking to get a uniform distribution of weight, and I thought something like the rice would be both economical and easier to spread out. Good luck with your T/S Parameters journey. If you figure something out, let me know. Thanks for watching.

I have an idea. How about some magnets on the front and back of the cone. I have seen people using coins and blutac before. I think stong masking tape and supergluing coins on is a better idea.

LOL! not an option here!

weight is not the same as mass.

That measuring tape is wonky. It takes into account the length of the plastic box. The number shown on the tape is the distance from the plastic tab to the end of the plastic box. Really confusing, but that was all I had at the time that could span that distance. Thanks for watching.

@@HandlebarWorkshops Okay, thanks for clarifying. :)

I should have just run out and grabbed some Play-Doh. It is readily accessible to most people and pretty cheap. And that was the ultimate point of the video series - to allow people to figure out the T/S parameters with easily accessible (off the shelf) and inexpensive items. Thank you for watching and commenting.

@@HandlebarWorkshops how is my doh idea 😁.. after testing , you can eat it too.. I think I should make a video with that ... The second part will be , me enjoying music and eating a pancake made from the doh .. .. Crazy scientist ... 🤣

I'd watch that! >D

@@HandlebarWorkshops I will try , I am inspired.. ♥️😇

Awesome! Inspiring people to do crazy stuff is why I started this channel.

You can convert a sealed enclosure to a vented enclosure with a Passive Radiator (drone). The bass will be extended, but 1) the time response (dynamics) won't be as clean and 2) the very bottom end response will drop off 24 dB per Octave v. 12 dB per Octave, which is essentially the same as point 1).

I can't see a reason why you'd want/need to do that for a tweeter. These parameters dictate the size (volume - cubic feet or meters) of the cabinet needed so that it works with the big speaker to resonate properly. Usually tweeters are just stuck in a cabinet with little consideration about the tweeter other than how much space/volume the tweeter takes up and thus needs to be added to the size of the cabinet. That said, I'm not sure it's possible, A lot of tweeters I've seen are fully enclosed with a horn. Without an easily accessible speaker cone, you won't be able to reproduce my rice/clay step. Thanks for watching!

I assume you are talking about what I say @ 4:59? You're absolutely correct. I misspoke and didn't catch it. Thanks for watching.

Thanks!

From what I was able to find online, they did manufacture speakers, mainly for off and store brand amps and speakers. The actual cabinet was long gone by the time the speaker was given to me, but I suspect it was an 80's era Guitar Center house brand. Thanks for watching.

You are absolutely correct. I've also heard it called a "seal" or "gasket". Thank you for watching.

Great video, I’m going to do these measurements myself on some pioneer speakers. You definitely measured the diameter wrong in the video. The diameter is closer to 375mm. You are not within 0,1g of 50g the scale shows 50g at 49,5g rounding up so you are within 0,1g of 49,5g. :) Rref calculated should be 506,22mV ( Vs*Rs/(Rs+Re) with Measurements at 2 Octaves above Fs maybe wrong 292mV? Finally Qes = Qms/(r0-1)*(Re/(Rs+Re)) witch with a Vref of 506,22 would give you a Qes of 0,94 and thereby a Qts of 0,84 (below 1) :) Vas = 360 Litres I hope this helps you.

Thanks for all of the info. You are absolutely correct on the diameter and weight of rice. It's a 15" speaker which would translate to 381mm. Even if it's not exactly 15", 322mm was way off. But I am confused as to where you came up with "Rref" (which I think you meant to type "Vref" since you call it that later on and the units are in volts not ohms). And your Qes formula is different from what I was using. Why? I'm glad you came up with a much saner value for Qts than I did (which leads me to believe you are correct), but I can't blindly accept that without and explanation. Thanks for watching.

I just put your measurements into the sheet you refer to, there the formula for Qes is as I wrote above :). Your measurement for Vref was the only thing off, and when I put in 292mV I got the same values that you got.

Ah,I see. The Elliot Sound Products page was updated in June of 2018, three months after I posted this video. It looks like the Qes formula was updated with the note, "While this is supposed to be the correct formula, many have found it gives Qes that's much too high," then gives the formula that you used. It also looks like he updated the formula for r0 as well. I'll add a sticky comment to highlight the changes. Thank you so much!

Thank you for the update, but I can't find Rod Elliott's article on that site. The link in the description still works. Could you provide a direct link to Rod Elliott's article on diyaudioprojects.com, please? I will update my links.

there must have been a problem with the server (sound.whsites.net/tsp.htm) when I was looking last week, it's working now.